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      Referee #3

      Evidence, reproducibility and clarity

      Summary

      The authors observe that proteasomal protein and activity is increased in skeletal muscle of mice fed a high fat diet. Concordant with this, they find increased expression of Nfe2l1 (NRF1), an ER localized protein that can be cleaved to produce a transcription factor that activates a set of genes that includes most proteasome subunits. To test the role of Nfe2l1 in the response to high fat feeding, the authors generated muscle specific KO of Nfe2l1 and characterized the muscles using fiber typing, proteomic, ubiquitinomic, RNAseq and metabolomic analysis on the muscle of these mice. Gastrocnemius muscle fast twitch fibers appeared most affected and modulated towards slow twitch phenotype, whilst soleus muscle appeared unaffected. Mitochondrial function was decreased as were levels of complex III. Ubiquitinome analysis showed differential ubiquitination of proteins involved in muscle structure and function and increased K48 ubiquitin chain linkages. Metabolomic studies showed altered amino acid metabolism, glucose metabolism and induction of a Warburg effect. Finally, upon high fat feeding, the Nfe2l1 mKO mice gained less weight, had higher energy expenditure, and were more insulin sensitive.

      Major comments

      1. The authors have conducted a multi-omics analysis of the skeletal muscle of mice bearing a muscle specific KO of Nfe2l1 and have attempted to integrate the findings. However, despite reading the manuscript several times, I have trouble trying to identify the key message of the paper and so feel that a lot of data was presented, but without a clear sense of how all the data (or some of it) really ties together. I suggest that the authors identify the main message, select the relevant data for the main body of the text and assign the remaining data to supplementary figures. The discussion should emphasize the main message.
      2. Metabolically, the most impressive result was the minimal weight gain on high fat feeding. The authors vaguely suggest that Nfe2l1 might be a therapeutic target 'to preserve muscle mass and healthy metabolism in obesity and beyond'. Since the main effect of Nfe2l1 seemed to be downregulation of the proteasome, should the authors have tested the effects of low dose proteasome inhibitors in WT mice to mimic the partial loss of proteasome activity seen in the Nfe2l1 mKO on the response to high fat feeding? This could confirm or support the idea that the main effect is due to Nfe2l1 modulation of the proteasome.
      3. The authors claim that there is rewiring of the UPS in obesity through the induction of Nfe2l1. What do the authors mean by rewiring? If the main effect of Nfe2l1 is to modulate proteasome activity, presumably all upstream processes (ubiquitination by various E3s) are affected. Indeed, in the ubiquitinomic analysis in figure 4F, there do not appear any pathways that are downregulated. Regardless, there is no data presented to show that specific pathways of ubiquitination are altered and therefore 'rewired'. The 'rewiring' strikes me as a fancy term used inappropriately here.
      4. I was surprised that the authors did not use the tamoxifen inducible Cre to inactivate Nfe2l1 in adult muscle. As such, the interpretation of the results of their study is limited by the effects of loss of Nfe2l1 during development and so inhibit to some degree potential links to translation. The authors should note this limitation in their discussion.
      5. Relevant to the above point about KO from development, in the first characterization of the mKO of Nfe2l1, (Figures 2G, 2I) the muscles actually look dystrophic. There appear to be central nuclei in the muscle of the mKO in Fig 2G and sarcomeric dysorganization in Fig 2I and the authors mention the presence of inflammatory cytokines and regenerative isoforms (Fig 2H) in the muscle. Are the mKO dystrophic, undergoing damage and regeneration? This is an important point to address with quantification of central nuclei, inflammatory cytokine expression, infiltration by mononuclear cells, fibrosis, blood levels of creatine kinase.

      Minor comments

      1. Abstract - the authors used the fancy term 'hormetic'. My understanding is that this refers to a phenomenon where effects at low dose (usually positive) are different or opposite from effects at high dose (usually negative). I didn't see such a biphasic phenomenon in the Nfe2li mKO mice. Also the authors should specify that it is a muscle specific KO.
      2. Text on page 3 'In human muscle, we noted that NFE2L1 is highly expressed, at much higher levels compared to other established muscle regulators, such as NFE2L2 or PPARGC1A (Fig. 1K)'. Discerning the importance of a transcription factor by comparing its expression at the mRNA level is dubious. It is the protein that acts and the extent of gene transcriptional activity that is important.
      3. Figure 2A-C - The mKO mice are smaller and have less lean mass and fat mass. Were the mKO mice born with smaller muscles and therefore had trouble feeding or competing for breast milk prior to weaning? This again relates to the issue of not having used a tamoxifen inducible KO. Are the muscle sizes proportionate to body weight or more importantly body length or tibial length?
      4. Figure 2G - As mentioned in general comment 5, the mKO muscle looks dystrophic. Also the % fibers of each type should be quantified to demonstrate the fiber type shifting. This should ideally be done in the complex zone of the gastrocnemius where all the fiber types are present. Also, the fibers look bigger in the mKO. It is standard to do an analysis of the distribution of cross-sectional areas of the muscle fibers and this can be done in a fiber specific manner from the stained images in the middle panels (with laminin staining added to delineate the fibers).
      5. Figure 2J - remarkably complex III (cytochrome C reductase) levels are significantly decreased. Any explanation for this? Does Nf2el1 bind to the promoter or regulate its transcription?
      6. Figure 2H - state in legend whether the 'relative expression levels' are for protein or for mRNA.
      7. Figure 3C, 3G - why does the trypsin-like activity of the proteasome go up when the other 2 activities of the proteasome go down?
      8. Figure 4E - Why is there a set of proteasome genes that are upregulated in the mKO? Most of these (except Psmd9/Rnp4) encode subunits of the PA28 activator. Is this a compensatory response or a response to inflammation in the dystrophic muscle? This needs some comment in the paper.
      9. Figure 5D, text page 8 - 'we found several genes to be oppositely regulated between soleus and GC'. What genes were these and are they enriched in a particular pathway e.g. one that modulates fiber type phenotype?
      10. Figure 6D, 6E - The increased energy expenditure and increased food intake may simply be due to increased heat loss from the smaller mKO mice (they have a relatively larger body surface area).
      11. Figures 7A, 7B - Was the body composition different in the mKO mice fed a high fat diet vis WT HFD mice?
      12. Figure 7E - What is the insulin tolerance like when normalized to starting glucose?
      13. Discussion - Please insert figure numbers in the discussion so reader can refer back to the data on which the conclusions in the discussion are being made.
      14. Figure 1G and Discussion first paragraph - It would be more quantitatively precise to measure the ubiquitinated proteins by western blot (as done in Fig 3I) than to sum up the ubiquitin linkages.
      15. Discussion para 2, ref 26. This reference is to a paper on effects of lipid peroxidation on muscle atrophy in aging or disuse and not to obesity. Revise to be more precise.
      16. Discussion page 12 last para - 'some components of the proteasome'. As mentioned earlier, these appear to be mostly subunits of the PA28 proteasome activator. Should state this and discuss.
      17. Discussion page 13, para 3 and extended data Fig 2A-2D. What is the significance of the higher FGF21 and GDF15 expression in mKO muscle? Could they be involved in the improved glucose tolerance or the decreased fat mass respectively?
      18. Methods section 2.8 - many abbreviations for reagents that are not defined e.g. SDC, CAA, TCEP, etc
      19. Methods 2.11 - the authors did whole muscle proteomics and ubiquitinomics which they recognized would be limited by the overwhelming representation by myofibrillar proteins. Did they try any manoeuvres to enhance detection of non-myofibrillar proteins?
      20. Methods, section 2.13 - the mitochondria were quantified by protein assay. Since the 8000g pellet used to isolate the mitochondria may contain other proteins, should the mitochondria be quantified in a more specific way e.g. assaying several mitochondrial proteins or measuring mitochondria DNA content? This is important vis a vis figure 2L which showed decreased mitochondrial respiration in the mKO.
      21. Extended data Fig 1D. Were these measures of markers of atrophy done at the protein level or mRNA level? They should be done at the mRNA level as this is a more sensitive and precise marker of atrophy than the protein levels (which don't change as much and for which many antibodies are not specific).
      22. There is a lot of useful omics data here. Where will they be shared for use by the research community?

      Referees cross-commenting

      The overall tenor of the three reviews is similar. Comments are both overlapping and complementary. I realize that I forgot two other specific comments:

      • (a) In extended fig 1C, the authors quantify the slower migrating LC3B-I band, but it is the faster migrating lipidated LC3B-II band that is a marker of autophagasomes that should have been quantified.
      • (b) Some references e.g. 37, 40 are missing information.

      Significance

      The authors have carried out what appears to be a thorough multi-level omics study of a muscle specific KO of Nfe2l1. It appears to have been technically well done, but I do not have expertise in such analyses and so cannot be rigorously critical in this aspect. (My expertise is in UPS function in skeletal muscle.) The major limitations of the present manuscript are highlighted in my major comments.

      In view of the important role of Nfe2l1 in regulation of expression of the proteasome, the muscle specific KO provided a partial inhibition of proteasome activity and therefore a unique view into the role of the proteasome in muscle particularly under the condition of high fat feeding. Therefore, the potential audience could be quite broad including researchers in muscle biology, UPS and obesity. However, Nfe2l1 has other effects besides induction of expression of proteasome genes, thereby limiting the confidence that all effects observed are related to the modulation of the proteasome and the consequences of such modulation on levels of UPS substrates

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      Referee #2

      Evidence, reproducibility and clarity

      In this paper, Lemmer and colleagues explore the role of the endoplasmic reticulum (ER)-resident transcription factor Nfe2l1 in muscle metabolism in mice following high-fat diet (HFD). Here, the authors made the interesting observation that HFD is associated with increased proteasome activity in skeletal muscles (Fig.1), a process known to rely on Nfe2l1 and confirmed by Figs. 2 and 3. By using a tissue-specific Nfe2l1 knockout (KO) mouse model, the authors show that Nfe2l1 is also critical in preserving mitochondria and oxidative phosphorylation in muscles during HFD (Figs. 4, 5 and 6). Finally, the authors show that fast/glycolytic muscle fiber growth in Nfe2l1 KO mice is accompanied by reduced body weight and improved glucose tolerance (Fig. 7).

      This paper is potentially interesting and addresses the important issue of energy metabolism regulation in diet-induced obesity (DIO) using an original mouse model. However, the argument presented in this paper has sometimes logical gaps, making it difficult for the reader to connect all the dots. For instance, what is the relationship between proteasome function and energy metabolism in DIO? Is there any relationship at all? Ultimately, Nfe2l1 has other target genes than the proteasome ones, particularly those related to mitophagy process (PMID: 30135079, this paper should be cited and discussed) which could easily explain the observations made by the authors regarding respiration and metabolism...

      1. The authors failed to explain why muscle cells upregulate their proteasomes during HFD. My prediction is that this happening because of increased protein synthesis which itself occurs as a consequence of sustained mTOR signaling. Increased translation would then result in increased supply of defective ribosomal products (DRiPs) which need to be timely cleared by the ubiquitin-proteasome system (UPS). I leave to the authors the possibility to address this hypothesis experimentally.
      2. The authors consistently show a correlation between HFD and increased Nfe2l1 expression. These observations, however, do not imply that Nfe2l1 is activated in DIO. The authors should assess Nfe2l1 processing - or at least nuclear translocation - in muscles over time
      3. If Nfe2l1 is indeed activated by HFD, what would be the stimulus? Compromised proteasome function? Oxidative stress? Cholesterol changes? This point needs to be clarified.
      4. Fig. 1C: the increased proteasome subunit expression in DIO seems minuscule... How about Western-blotting the native gel for proteasome subunits to check whether the observed proteasome activity matches the proteasomes amounts under these conditions?
      5. Fig. 2J: a densitometry quantification of the WB would be welcome.
      6. Fig. 2K. captions are incomplete. What is PMG, SUC or FCCP?
      7. Discussion:" Furthermore, we found that some components of proteasome activity are higher in cells or tissues lacking Nfe2l1, indicating a potential compensatory posttranslational modification of proteasome function." What components?? Is it shown in the manuscript? Unclear.
      8. Discussion: Next to changes in total amount and activity, we also found that proteasome subunits accumulated in a hyperubiquitylated state (Extended Data Fig. 1A), but the relevance of this observation will need further investigation. These proteasome subunits are not assembled ones, but likely derive from DRiPs, as a consequence of increased translation (see point 1).
      9. Discussion: "Clearly, disturbances in UPS and ERAD cause ER stress and inflammation (10), which we also observe in our model." Where are the data in this regard? Do the authors mean Fig. 5B? I do not see any convincing data on inflammation here (BTW, what is Gm11517?).

      Significance

      General assessment:

      As previously discussed, this work from Bartel's lab is interesting but not suitable for publication in its present form. It should be revised to clarify the role of Nfe2l1-induced proteasomes in DIO.

      Advance

      Although the role of Nfe2l in mitochondrial function is known (PMID: 30135079, this paper should be cited and discussed), the consequences on energy metabolism in skeletal muscles described in this paper are novel.

      Audience

      If appropriately revised, this manuscript should be of interest to a wide readership.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      In the manuscript entitled "Nfe2l1-mediated proteasome function controls muscle energy metabolism in obesity", Lemmer and colleagues observe elevated 20S proteasome activity along with increased expression of the transcription factor Nfe2l1, a known stimulator of proteasome subunit biogenesis, in muscle tissue of diet-induced obese mice. To understand the role of Nfe2l1 in regulating skeletal muscle proteostasis, they use siRNA to knockdown Nfe2l1 in cultured C2C12 muscle cells and cross Nfe2l1 floxed mice with and Acta1-Cre line to KO Nfe2l1 specifically in muscle fibers. Nfe2l1mKO mice show reduced body and muscle size, impaired enzymatic activity of some proteasome subunits, an accumulation of ubiquitylated proteins, a fast-to-slow shift in muscle fiber phenotype and metabolic abnormalities, including impaired mitochondrial function and mild increases in relative energy expenditure. Multi-omics analysis at transcript, protein, ubiquitinated protein and metabolite levels indicate a strong influence of Nfe2l1 loss on muscle homeostasis. These affects appear to predominately affect fast-type (i.e. Gastrocnemius) rather than slow-type (i.e. soleus) muscles. Finally, Nfe2l1mKO mice fail to gain weight on a high fat diet and are therefore spared the typical metabolic alterations associated with obesity.

      Major comments:

      1. The authors push the idea that the UPS, via Nfe2l1, plays an 'adaptive' role in regulating muscle proteostasis, however, all signaling experiments investigating the effect of muscle fiber Nfe2l1 KO are performed under basal conditions.
      2. Due to the use of ACTA1-Cre to conditionally KO Nfe2l1 in muscle fibers, Nfe2l1 is also absent during development. It is therefore difficult to distinguish the acute effects of Nfe2l1 on muscle proteostasis from those that may result from developmental impairment. It is conceivable that remodeling of muscle architecture would be more active during development than in mature muscle and therefore perhaps more sensitive to impairments in proteasome biogenesis. Use of an inducible Cre system (e.g. the tamoxifen inducible HSA-MerCreMer model) and/or the addition of acute Nfe2l1 overexpression experiments would be needed to dissociate acute, primary effects of Nfe2l1 from the secondary features of long term Nfe2l1 KO and disruption of proteostasis.
      3. It is unclear what the HFD experiments reported in Figure 7 add to our understanding of the role of Nfe2l1 in skeletal muscle. I could understand if an inducible Nfe2l1mKO system was used to test the role of Nfe2l1 in already obese mice... but a failure of a mouse displaying myopathic features to put on weight is not the same as an alteration that improves metabolic health. As Nfe2l1mKO mice do not become obese, the authors are unable to directly test what role the upregulation of muscle Nfe2l1 plays in maintaining proteostasis in obesity. On the other hand, I find it hard to conclude that the absence of muscle Nfe2l1 is beneficial for metabolic health if fed a HFD, especially given the reported increase in p62 and LC3B (indicative of autophagy impairment) and the impaired muscle mitochondrial function. Further investigations in older mice would be required to determine the long-term impact of muscle Nfe2l1 KO on whole-body health under both normal and high-fat diet feeding conditions.
      4. The authors note several interesting muscle phenotypes, including a fast-to-slow fiber type transition and an increased expression of neonatal myosin heavy chain isoforms (Myh3 & 8). The representative images seem to indicate that IIA (green) fibers are larger in Nfe2l1mKO mice. I would recommend quantifying fiber type-specific cross sectional area in Gastrocnemius muscle sections from these mice, as well as confirming the increased 'regeneration' phenotype by quantifying the prevalence of centralized nuclei.
      5. Figure 3D: Why would Nfe2l1 KD lead to a larger increase in ubiquitylated proteins after proteasome inhibition? If Nfe2l1 KD reduces proteasome subunit gene expression (presumably also protein content) and proteasome activity (although this effect is rather mild), then blocking a proteasome with lower activity should lead to a lower accumulation of ubiquitylated proteins, despite an accumulation of ubiquitylated proteins under basal conditions.
      6. Fig3C&G: The finding that Nfe2l1 KD/KO mildly reduces chymotrypsin-like and caspase-like (in mice) activity, but strongly increases trypsin-like activity is surprising. As these activities are mediated by different Beta subunits within the 20S core particle, it would be important to also test whether protein levels of PSMB5 (Chymotrypsin), PSMB6 (Caspase) and PSMB7 (trypsin) are altered by Nfe2l1 in accordance with differences in their measured activity.
      7. The authors have a tendency to use vague terms to describe changes in proteostasis resulting from Nfe2l1 KO, for example: 'recalibration', 'adaptive', 'fine-tuning', 'remolding', 'remodeling', 'rewiring'. While it is understandable that Nfe2l1 and the UPS will have different roles under different conditions, the use of vague language makes it difficult to understand whether they are referring to reduced or increased proteasome activity. Please be clear and precise as the direction of the changes observed. The same goes for the extension of conclusions made on measures of proteasome activity to mean activity of the UPS / protein breakdown. Specific examples are described within the minor comments section.

      Minor comments:

      Introduction: Nfe2l1 does not restore proteasome activity per se, but stimulates proteasome subunit biogenesis and thereby increases proteasome content. This would not necessarily influence activity, which also relies on the presence of substrate/ubiquitination.

      Introduction: 'we investigate remodeling of the muscle UPS in obesity and define the role of Nfe2l1 as a new regulator of muscle biology'. This statement is an overreach, particularly seeing as a role for Nfe2l1 has already been described in skeletal muscle, albeit under a different context (ref. 29).

      Results: "Of note, leptin levels in chow-fed animals were indifferent". I guess this is a typo? Should be 'different' not 'indifferent'.

      Results: "These global changes are in line with the notion that UPS is activity is rewired and metabolism impacted by HFD feeding." Please use specific language to describe the changes you see.

      Results: "The data supported the hypothesis that Nfe2l1 stimulates protein degradation via the proteasome, as the dominant lysine-linkage was the proteasome-targeting linkage K48, accounting for more than 86 % and being significantly higher in muscle of mKO mice compared to tissue of WT controls (Fig. 4G)." While it is clear that depleting a protein contributing to proteasome biogenesis would impair proteasome function, this would not be sufficient to say that Nfe2l1 promotes protein degradation via the proteasome. So far, there is no evidence that increasing Nfe2l1 increases protein degradation.

      Figure 1L: What is the unit of measurement for gene expression?

      Figure 2G: There appears to be significant freeze damage in H&E and SDH sections from Nfe2l1mKO mice. Perhaps you can find better representative images.

      Results: "In summary, these results establish Nfe2l1 as an adaptive regulator of proteasomal activity and ubiquitylation in cultured myocytes". Why do these results establish Nfe2l1 as an 'adaptive' regulator? These are steady state conditions. Results so far would only indicate that Nfe2l1 controls proteasome subunit biogenesis in myocytes, which is well known in other cell types and has also been shown in skeletal muscle tissue.

      Results: "The proteome showed many significantly regulated proteins and in general a higher protein load in the mKO condition (Fig. 4A), potentially caused by impaired proteasomal protein degradation." What is meant by a 'higher protein load'

      Discussion: "Here, we show that proteasomal activity and management of ubiquitin levels in muscle is a regulated and critical process in obesity, as proteasome levels and function are increased in obesity." This is actually not shown. As Nfe2l1 KO mice do not become obese, it is unclear what role this increase plays under the conditions of obesity.

      Discussion: "Interestingly, at the same time, total ubiquitin levels are largely unchanged, which suggests a dynamic recalibration of the rates of protein synthesis and degradation, including the processes necessary for ubiquitylation and its targets". The authors seem to be interpreting ex vivo proteasome activity assays as a readout of protein breakdown rates in vivo. These Proteasome activity assays are only a readout of proteasome content, not activity, since substrate entry into the 26S proteasome is tightly controlled by its cap structure. Ex vivo, substrates able to independently access the inside of the 20S proteasome (and hence the active protease sites) are provided in abundance.

      Discussion: "However, overall proteasomal activity was lower and ubiquitin levels higher, indicating the predominant role of Nfe2l1 determining rates of UPS in myocytes." The reduction in activity was not so strong that it could be considered predominant. Furthermore, proof is only provided for Nfe2l1 regulating proteasome content... not rates of UPS breakdown, which also relies on the ubiquitination part of the system.

      Discussion: "There seems to be profound crosstalk between proteostatic mechanisms in muscle, as we found in the proteome of Nfe2l1 mKO muscle that autophagy pathways are markedly upregulated, including p62 and LC3B levels (Extended Data Fig. 1B-C)". This should be first introduced into the results section.

      Discussion: "Uncoupling of mitochondria and loss of mitochondrial membrane potential in myocytes are associated with the induction of FGF21 (33), a myokine that is implicated in regulating energy metabolism. We find that FGF21 and GDF15 expression were higher in muscle of mKO mice compared to WT controls, and for GDF15 also plasma levels were elevated (Extended Data Fig. 2A-D)." This should be included in results section.

      Significance

      General assessment: after identifying increased proteasome activity and an associated increase in Nfe2l1 expression in the muscle of obese mice, this work provides strong evidence that muscle fiber Nfe2l1 expression is necessary for muscle fiber development / homeostasis, with wide ranging effects of muscle fiber Nfe2l1 KO, including on body and muscle size, fiber type composition and mitochondrial content and function. On the other hand, muscle fiber Nfe2l1 KO mice fail to become obese, making it hard to draw conclusions on the role of increased Nfe2l1 in the muscle of obese mice.

      Advance: This study complements recent work showing a role for increased Nfe2l1 expression in maintaining proteostasis under a different proteostatic challenge, and suggests a role for muscle Nfe2l1 in response to obesity.

      Audience: This study is likely to be of interest to readers interested in proteostasis, the UPS and muscle biology.

      Expertise: Muscle proteostasis and aging.

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      Reply to the reviewers

      We thank the reviewers for their careful and constructive evaluation. We believe the requested revisions are feasible will substantially strengthen the manuscript.

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      Referee #3

      Evidence, reproducibility and clarity

      In this manuscript, Halter and colleagues propose a novel approach to sample level analysis of single cell disease atlas by only considering cellular proportion. They perform an evaluation with several SOTA approaches including ones using both pseudo-bulk or combination of compositional and transcriptional changes. While bench-marking results are positive, the design of the study including selected data and evaluated statistics differs from previous studies possibly indicating some bias selections. The paper has also strong statements on the fact their method is not affected by batches, while this is only shown in a single data set and some of the evaluated data has batched samples removed. These results are very likely misleading and authors need to either remove such strong claims or show strong evidence supporting it.

      Main points

      Authors indicate only samples with 500 cells are included. How would the method work without such a filter? Evaluation should also be done on sparse data, as this might be frequent in single cell studies. Otherwise, tgus should be also discussed as a limitation of the study. Authors should discuss the potential risk of this variance-based thresholding inadvertently filtering out rare, low-variance cell populations that carry critical biological significance. Also, could it be that this filter simply selects condition specific cells (cancer cells in cancer samples?). Regarding the previous concern, it is unclear if this performance retention is unique to ECODA's log-ratio approach. For a fair comparison, the authors should benchmark the competing compositional methods using the exact same HVC subset to determine if the performance advantage stems from the algorithm itself or simply the feature selection. In this case, some methods, such as PILOT, need cell types. To comprehensively demonstrate ECODA's performance, the authors should compare their approach against recently introduced sample-level representation methods. QOT: https://academic.oup.com/bib/article/26/1/bbae713/7953914. Joodaki, M. (n.d.). PILOT-GM-VAE: patient-level analysis of single-cell disease atlas with optimal transport of Gaussian mixture variational autoencoders. Pang, K. (n.d.). PULSAR: a Foundation Model for Multi-scale and Multi-cellular Biology. Regarding the data selection, authors should include all the previous data as in previous studies. See PILOT, PILOT-GM-VEA or QOT for a larger selection of data sets. The current approach uses k-means but some of the evaluated methods are shown to work better with other clustering methods (Leiden) or similarity metrics (Cosine). Authors should improve the benchmarking to also include richer strategies on how to perform clustering and include metrics evaluating the distances directly (silhouette index). Data has very strong filters that remove confounding factors. For example, the authors handle demographic confounders (such as age) in the Gong & Sharma dataset by severely restricting the cohort (males <= 40 years), which limits real-world clinical applicability where cohorts have complex, overlapping covariates. Can ECODA deal with the data sets without any kind of filter on confounding factors?

      In the Stephenson dataset, the authors manually restricted the data to a single clinical location ("Ncl site"). If ECODA is as robust to batch effects as claimed, manual exclusion of multi-center data should be unnecessary. The authors should explain why this pre-filtering was required and evaluate if ECODA can accurately stratify patients when all multi-center data is included. Another example of a batch rich data is the KPMP Kidney data, which include multicenter and multi protocols single nuc vs. single cell data. The claim that ECODA is robust to batch effects is currently supported only by ANOSIM scores on two datasets, which is insufficient by current single-cell benchmarking standards. To rigorously demonstrate that ECODA effectively resists batch effects while conserving biological variance, the authors should evaluate their sample-level embeddings by using more data and also utilizing metrics such as Silhouette batch, LISI, and so on (take a look at scvi-tools, https://docs.scvi-tools.org/en/1.3.3/tutorials/notebooks/scrna/harmonization.html). Besides, they need to drop all filters based on clinical variables and include additional data sets as previously discussed.

      Referees cross-commenting

      Reviewers do focus on distinct but non conflicting aspects, while some similar points regarding benchmarking are quite similar between us and reviewer 2. I would like however to stress the batch correction aspect, which is currently a big statement on the manuscript, but we could capture several design issues with this aspect.

      Significance

      The discussion on how to analyze single cell data of patients cohorts is of strong significance. Authors make an interesting point that cell frequencies can work well, but the results are clearly biased by data selection and experimental design. The study will have a greater value if authors can tune down most of their claims and instead have a more balanced analysis on when compositional analysis is best and when transcriptional signatures are best. This is likelly to be very study/data dependent.

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      Referee #2

      Evidence, reproducibility and clarity

      This manuscript benchmarks scRNA-seq sample representation methods for unsupervised patient stratification. The authors demonstrate that centered log-ratio (CLR)-transformed cell-type proportions (ECODA) match or outperform more complex state-of-the-art methods while requiring orders of magnitude fewer computational resources. The accompanying scECODA R package facilitates practical adoption.

      Software availability. scECODA, integrated into Bioconductor and Seurat workflows as an open-source R package, substantially increases the practical impact of this work. scECODA comes with proper documentation and meaningful tutorials.

      Major Concerns

      1. The benchmark conflates methods with fundamentally different objectives. Several benchmarked methods were not designed primarily for unsupervised patient stratification by clustering. MrVI, for instance, explicitly targets the identification of local gene expression shifts that would be missed by a composition-based approach (scPoli likely behaves similarly though this manuscript lacks analysis). These methods are likely complementary to ECODA rather than competing with it. This is already partly visible in the benchmark: MrVI performs superior to ECODA on the Adams and Stephenson datasets while underperforming elsewhere. The authors should investigate and discuss why ECODA underperforms in these specific cases for example, whether transcriptional reprogramming rather than compositional shifts dominates the biological signal in those datasets. Such an analysis would provide practical guidance for method selection and reframe the benchmark as a characterization of complementary use cases rather than a simple ranking.
      2. The Leiden clustering benchmark requires clarification and extension. This concern has several distinct components that should each be addressed:
        • Batch correction dependency: ECODA's robustness to batch effects may derive partly from cell types being called in batch-corrected embedding spaces (e.g., Harmony or scVI), rather than from ECODA itself. The authors should clarify whether cell-typing in batch-corrected embeddings are a prerequisite for ECODA's batch robustness, and if so, make this explicit in the workflow recommendations.
        • Performance in challenging compositional scenarios: The Gong Sharma dataset, which requires fine-grained immune cell-type resolution to separate CMV-positive from CMV-negative individuals, is arguably the most demanding test case for Leiden-based annotation. Would unsupervised Leiden clustering achieve comparable performance to expert labels in this scenario? This is not addressed in the current analysis.
        • Resolution parameter guidance: The manuscript implies that higher Leiden resolutions are generally better for ECODA, but there must be practical limits to this - overclustering introduces noisy, sparsely populated clusters that destabilize CLR estimates. The authors should provide clearer guidance on how to select the resolution parameter in the absence of expert labels.
        • Stability of the identified marker cell types: Figure 3B shows that the top contributing cell types identified by ECODA differ substantially between HiTME and authors_HR annotations for the Adams dataset. How stable are these "marker" cell types across annotation strategies, and what are the implications for biological interpretation?
      3. The range of zero-handling values tested is too narrow. The benchmarked pseudocount values are in a relatively small range, and performance differences among them are minimal. To establish that the recommended default (pseudocount of 0.5) is genuinely optimal rather than arbitrarily chosen, the authors should extend the analysis to much smaller values (e.g., 1×10⁻³) and much larger values (e.g., 100). This would demonstrate that performance degrades at the extremes and that the current default sits in a robust optimum.
      4. The HVC analysis would benefit from a more rigorous feature selection framework. The current approach selects highly variable cell types based on unsupervised variance ranking. Since the goal is patient stratification, it would be informative to compare this approach against supervised feature selection methods (e.g., LASSO-penalized classification). This comparison would clarify whether the variance-based approach approximates supervised selection, or whether meaningful discriminative signal is being left on the table. Separately, the claim that HVC-based ratios are directly translatable to clinical platforms such as flow cytometry should be made more carefully: several of the identified marker cell types (e.g., KLRF1⁻ GZMB⁺ CD27⁻ memory CD4 T cells) require multi-parameter panels that are not routinely employed in clinical practice.
      5. Cell-type annotation subjectivity introduces a potential source of bias not discussed. The authors evaluate annotation robustness across strategies but do not discuss a related concern: future studies may define cell types in a manner that, intentionally or not, introduces a desired sample stratification, while cell populations associated with unwanted variation (e.g., technical confounders) may be merged or excluded. This subjectivity could inflate ECODA's apparent performance in practice and should be acknowledged explicitly in the Discussion as a caveat of annotation-dependent methods.
      6. The title and framing overstate a causal claim. "Cell type composition drives patient stratification" implies that compositional differences causally determine clinical phenotypes. The benchmark establishes that compositional representations perform well for stratification, not that composition causes the underlying biology. The title and several passages in the manuscript should be revised to reflect this distinction for example, replacing "drives" with "predicts" or "reflects."
      7. Foundation model-based methods should be discussed and ideally benchmarked. PULSAR, which uses the Universal Cell Embeddings (UCE) foundation model as a basis for sample-level representations, was recently introduced and represents an emerging class of methods not covered in this benchmark. Including PULSAR would future-proof the comparison. If the computational burden of full benchmarking is prohibitive, it would be a valuable addition to the Discussion.
      8. The benchmark should address large-scale and multi-study scenarios. Studies with thousands of samples (e.g., OneK1K) and multi-study atlases (e.g., the Human Lung Cell Atlas) represent the trajectory of the field. Including at least one such dataset would substantially strengthen the claim that ECODA is scalable and robust to batch effects. This is especially critical as deep-learning based methods might scale favorably with the number of samples.

      Minor Points

      • The number of nearest neighbors used for modularity computation is three, which is small and may introduce instability. A sensitivity analysis across a range of neighbor values is warranted.
      • A comparison to the cLISI (cell-type Local Inverse Simpson's Index) metric, widely used in single-cell integration benchmarks, would be appreciated, though cLISI operates at the cell level rather than the sample level and adaptation for this setting might be necessary.

      Significance

      Given rapidly increasing scRNA-seq cohort sizes, rigorous evaluation of sample-level representation strategies is pressing. The field has invested heavily in complex methods, making this comparative analysis valuable.

      This is a well-executed benchmarking study that delivers a clear and practically useful message: properly handled cell-type compositional data is a powerful and underappreciated representation for scRNA-seq cohort analysis.

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      Referee #1

      Evidence, reproducibility and clarity

      This paper presents the ECODA method and scECODA package, which uses simple sample-level representations based on transformed cell-type abundances to recover biological stratification of the samples. This compares favourably to more complex embedding-based methods across 11 datasets.

      I would like to congratulate the authors on a well written and interesting manuscript. My most important concern is that there is potentially some circularity in the labels and disease classifications used for evaluation. Some of this is mitigated by the cluster-derived cell labels, but not all of it, since part of the concern relates to how the sample-level disease labels were defined. A negative-control benchmark using labels not expected to be composition-driven would help clarify this.

      The manuscript appears to motivate ECODA partly as a tool for de novo exploratory patient stratification, but the benchmark mainly evaluates recovery of known biological labels. This is a reasonable validation strategy, but it does not directly assess whether the method can discover previously unknown patient subgroups, or determine the number and clinical relevance of such groups without label guidance. This distinction should be made clearer early in the paper.

      p3:

      'across 11 patient cohorts' - are there common aspects to these? It would be good to indicate why these were chosen and what the strategy is.

      p7, Fig 2 A:

      The runtime for ECODA and GloProp seem to be significantly less than the shuffled baseline, but the implication is that they do more calculations, which seems surprising. Is this an artifact?

      p8/9:

      A possible limitation is that the benchmark may be enriched for studies where compositional shifts are already expected to be strong.

      In a similar sense, for disease states that are conventionally defined in a specific cell type, the analysis could be recovering label-associated annotation structure rather than independent disease biology. This is especially relevant for high-resolution manual annotations, where disease-associated cell states may already encode part of the biological contrast being evaluated.

      A negative-control or stratified benchmark on labels not expected a priori to be composition-driven, or on composition-matched sample groups, would be a useful cross-check here.

      p10:

      It would also be interesting to see the robustness to small sample sizes, as this isn't mentioned elsewhere, but potentially could be a confounder in many patient derived samples.

      p11:

      The distinction between ECODA and scECODA could be a little clearer here. As far as I understand scECODA is the R tool and ECODA is the general method?

      p13:

      The claim that inter-sample biological variation is largely explained by cell-type abundance may need some qualification, because some of the disease or disease-state labels may themselves be partly compositionally defined. If disease state was assigned or refined using histopathology, cellular composition, or the presence of particular cell populations, then a composition-based method is partly being evaluated against labels that already contain composition-like information. This might weaken the interpretation that composition is an independent driver of disease biology, rather than a correlate of how the disease category was operationally defined.

      It would therefore be useful to give more detail on how these disease labels were derived. This concern is not removed by using cluster-derived cell labels, because the possible circularity is in the disease-state definition rather than the cell annotation procedure.

      'For example, ratios...immunotherapy response.' - A citation here would be good.

      'Cost effective diagnostic assays...' - Perhaps a bit of an overstatement. This would likely require validation across larger cohorts, clinical sample-processing conditions, sequencing depth/cell recovery difference, etc. This claim could be softened or framed as a future direction.

      p14:

      'Expert author annotations...' - this could be clarified. Were these all manually curated annotations from the original studies, or did some original studies use automated/reference-based annotation followed by curation?

      p15:

      'We further controlled...' - was the analysis also evaluated over these separate subsets (other than just males <= 40) as a cross check?

      p19:

      HVCs: Could you comment on this procedure, versus something more akin to highly variable gene selection?

      Significance

      This paper presents a fast and interpretable method for sample-level stratification of single-cell RNA-seq cohorts, based primarily on compositional differences in cell-type abundance. This makes it of broad interest to researchers performing cohort-level scRNA-seq analysis, since its speed and simplicity make it an attractive baseline even when more involved downstream analyses are planned. However, as presented, its performance is less well established for datasets without reliable high-resolution annotations, for settings where the relevant structure is not primarily compositional, and for genuine de novo discovery of patient subgroups rather than recovery of known labels.

      My background is in computational biology and biophysics.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary

      During mitosis transcription is silenced (except at centromeres) and the majority of chromatin-bound RNA is removed from chromosomes. Previous work has shown that retention of elongating RNAPII on mitotic chromosomes through a WAPL degron leads to transcription-dependent chromosome segregation errors. Additionally, retention of chromatin bound RNAs through mutation of HNRNPU/SAF-A also leads to chromosome segregation errors. However, the field lacks a complete understanding of the mechanisms that remove RNA from chromatin in mitosis. Previous work from the Oliveira lab (and others) demonstrated that depletion of Lds/TTF2 also leads to chromosome segregation errors, but it was not possible to directly link chromosome segregation defects to persistent mitotic transcription. In this current work the authors examine the role of TTF2 in mitosis in human cells. They nicely show that TTF2 is required to release transcripts from chromatin during mitosis and that retention of transcripts on chromatin leads to chromosome segregation errors. Interestingly the authors find that depletion of TTF2 leads to an increase in the number of R-loops present on mitotic chromosomes and that R-loop-containing DNA is a major component of anaphase bridges. The results presented in the manuscript are high quality and the data support the conclusions. This work is important because it provides further evidence that the removal of RNA and transcription complexes from mitotic chromosomes is important for accurate chromosome segregation. There are a couple of points that the authors should consider prior to publication listed below and some minor issues with data presentation that should be corrected.

      Major points

      1. The authors use RNAi to deplete TTF2 and examine mitosis following depletion. The authors state that TTF2 depletion requires 48 hours, or approximately 2 cell cycles. Since TTF2 is depleted for the entire cell cycle it is possible that transcription termination defects caused by TTF2 depletion during interphase causes defects in mitosis and that the observed phenotypes are not a result of mitotic function of TTF2. This concern is somewhat addressed by the observation where the authors inhibit transcription using triptolide and show that this treatment rescues chromosome segregation defects observed following TTF2 depletion. However, the TRP treatment is for 4 hours, which includes a substantial portion of interphase. The length of TTF2 depletion is a significant concern and I think there are two ways that this could be addressed:

      a. Create a TTF2-AID (or dTAG) cell line and analyze chromosome segregation defects following TTF2 depletion only in mitosis. This is a difficult and time-consuming experiment but is also the most direct test of the role of TTF2 in mitosis. This experimental system would be required for publication in a high-impact journal.

      b. Include a section in their discussion acknowledging that indirect effects could be a cause of the chromosome segregation errors observed following TTF2 depletion. 2. The authors nicely show that TTF2 depletion leads to a significant retention of EU-labeled RNA on mitotic chromosomes but do not address the nature of these transcripts. Additionally, the authors do not show that TTF2 depletion leads to changes in transcription in interphase cells. This work could be improved by the addition of EU-RNA sequencing data showing that TTF2 depletion leads to transcriptional changes in interphase (e.g. transcription past the normal termination site) and EU-RNA sequencing to identify that transcripts that are retained on mitotic chromosomes. Neither of these experiments are absolutely necessary for publication but would significantly improve the general interest of this work. 3. The authors show that TTF2 depletion leads to an increase of R-loops on anaphase bridges. Previous work has shown that R-loops are present at mitotic centromeres (29170278) and that activation of ATR through these R-loops is necessary for accurate chromosome segregation. This work is clearly relevant to the authors results and has not been cited or discussed. This previous work should be included in the discussion and interpretation of the authors' work.

      Minor points

      1. In Figure 1 the authors show a comparison of the levels of EU-labeled RNA in control and TTF2-depleted cells at each stage of mitosis. The graphs in B and D would be much easier to compare if these were combined into a single graph.
      2. There are a number of quantitative plots that are lacking statistical comparisons between key groups. These are: Figure 1B and D, Figure 1F, S2B, Figure 4DE, S6C,

      Significance

      This advance is incremental but adds to accumulating evidence that transcription termination is important for normal chromosome segregation.

      The strengths of this work are high quality data, careful analysis, and the fact that conclusions follow directly from the data presented.

      The weaknesses are that the model system in not optimal to address the question being posed and that the authors have not completely characterized their model system.

      This work will primarily be of interest to groups working on mitotic chromatin:RNA and transcriptional regulation.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      In this original article, authors attempt to define the molecular and cellular consequences of retaining spurious transcriptional activity in mitotic chromosomes. The study uses the depletion of TTF2 (transcription termination factor 4) in tissue culture of HeLa cells as a model. Results show the accumulation of nascent RNAs and R-loops as a product of such aberrant transcription which, strikingly, increases the incidence of chromosome segregation errors. Importantly, authors elegantly show that these errors are corrected by inhibition of RNA Polymerase2 activity with previously reported drugs. This reviewer finds the study very interesting and compelling, very well written and structured. However, I consider that the adjustment of several aspects might improve the manuscript:

      Major comments.

      1. The main limitation of the study relies on the approach followed to deplete TTF2. Authors used siRNAs in order to decrease the levels of this factor, which implies an incubation time of 48h. This might represent a limitation. Regarding this aspect, this referee request to show the proof of TTF2 depletion in the main figure with accurate quantification when possible.
      2. Most of the main conclusions are very well supported by quantification of imaging data. However, this referee suggests the generation of superplots (ref) where values and average for each replicate can be clearly visualized. Statistical analyses comparing the median from each different conditions by t-student (unpaired test) will better support the outcome.
      3. Authors show a beautiful correlation between the presence of R-loops and chromosome segregation errors (Figure 6). I request the authors to replicate the experiment with cn or TTF2 siRNAs in combination with the triptolide treatment. Additionally, and to provide further evidence about the functional consequences of retaining R-loops, I wonder if authors can drive specific R-loop depletion by using RNase H activity. This will definitely reveal whether transcription activity or/and its product underlies the chromosome segregation defect.

      Minor comments.

      1. I highly recommend to include the value of all the statistic tests in each plot.
      2. I would suggest the incorporation of a final paragraph at the end of the introduction summarizing the most important results of the study.
      3. In the introduction, and based on wide evidences showing transcriptional activity at centromere regions (Chan 2012, Liu 2016, Perea-Resa 2024), and to a much lower extend, at the chromosome arms of mitotic chromosomes (Palozola, 2017), I would rephrase to make clear that transcription is generally repressed rather than globally silenced in mitosis.

      Referees cross-commenting

      After reading the comments from the other two referees, I maintain my view about the quality/interest of the manuscript. I endorse the potential publication of this work, after addressing the recommendations, in a reasonable period of time.

      Significance

      Authors provide a compelling study addressing the functional relevance of repressing transcription early in mitosis to properly segregate chromatids to daughter cells. In addition, the study also pursuits to illuminate the molecular and cellular consequences of inactivating TTF2 function and to provide insight into the chromosome segregation defects found under TTF2 misfunction. The study considers and discusses the most important aspects of the literature relevant for the proposed questions. The results are very encouraging and mostly confirmed by several orthogonal approaches.

      The major strength is the direct correlation found between R-loop retention and chromosome segregation defects. The major limitation is, however, the usage of slow siRNA-based strategies to deplete TTF2. The use of degron-protac alternatives would be very beneficial although I do not consider this an essential aspect.

      The study is sound and address very interesting still open questions. The publication of the results will influence and benefit a wide audience specially researches working on the mitosis and transcription fields. Research on R-loops, a field full of open questions, would also acknowledge the insights from this study.

      Overall, I consider the study very interesting and compelling. I support the evaluation and envision that its publication, once addressed the above described comments, will be feasible within roughly 3-6 months of revision.

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      Referee #1

      Evidence, reproducibility and clarity

      In this manuscript, Tovini and colleagues investigate the role of transcriptional silencing during mitosis using depletion of TTF2, a factor implicated in mitotic transcription termination. The authors show that TTF2 depletion leads to retention of elongating transcripts on mitotic chromatin, defects in chromosome organization and compaction, delayed mitotic progression, and increased chromosome segregation errors, particularly DNA bridges and UFBs. They further report accumulation of R-loops and demonstrate that transcription inhibition largely suppresses the observed segregation defects.

      Overall, this manuscript is interesting and potentially important, and the study is technically sound. In particular, I liked the experiments showing continued transcript elongation during mitosis in TTF2-depleted cells. The rescue experiments with triptolide also support the conclusion that transcription contributes significantly to the observed phenotypes. The methods and statistical analyses appear generally appropriate and sufficient for reproducibility.

      At the same time, I think that several aspects of the mechanistic interpretation are somewhat overstated, and some important alternative explanations remain insufficiently addressed. For these reasons, I believe the manuscript would benefit from substantial revision before publication.

      Major comments

      1. The authors favor a model where persistent transcription and R-loop accumulation interfere with Top2A-mediated sister chromatid resolution. While this is certainly possible, I do not think the presented data fully support such a specific interpretation. The authors demonstrate a pronounced chromosome organization phenotype. TTF2 depletion causes broadened metaphase plates and approximately 1.5-fold increased chromosome volume. These observations suggest a substantial defect in mitotic chromosome compaction. An important alternative possibility should be considered, namely that persistent mitotic transcription interferes with Condensin I and/or Condensin II loading and/or retention. Given the current understanding that chromosome condensation and loop organization are highly dynamic processes, it is conceivable that ongoing transcription could impair Condensin-mediated chromosome assembly. At minimum, the authors should assess chromosomal localization of Condensin I and II in mitotic cells after TTF2 depletion (for example CAP-H/CAP-D2 and CAP-H2/CAP-D3). Such analysis, ideally also including triptolide rescue, would substantially strengthen the mechanistic interpretation and help distinguish between a primarily transcription/R-loop-mediated defect and a more global chromosome assembly defect.
      2. The authors conclude that kinetochore-microtubule attachments are largely normal, based on Mad2 localization, inter-centromere distance, and the absence of strongly uncongressed chromosomes. In my opinion, these measurements are indirect and do not sufficiently demonstrate robust mature end-on attachments. Given the observed metaphase spreading, mild congression defects, and SAC-dependent delay, it remains possible that TTF2 depletion causes more subtle defects in k-fiber stability or attachment robustness. I think a cold-stability assay of spindle microtubules would be important here. Such experiment would directly address whether cold-stable k-fibers are normally formed and maintained in TTF2-depleted cells. Ideally, this should be combined with kinetochore markers and quantification of k-fiber intensity. Without such analysis, the statement that KT-MT attachments are unaffected should be toned down.
      3. The manuscript generally frames mitotic transcription as detrimental to chromosome segregation. However, several previous studies, including work from Hongtao Yu's lab, reported that localized centromeric/kinetochore transcription during mitosis contributes positively to chromosome segregation, including correct Sgo1 localization and centromeric function (this literature is not discussed, despite appearing conceptually relevant to the present study). This is not necessarily a contradiction; it seems possible that a limited and spatially restricted mitotic transcription program at centromeres may be beneficial, whereas persistent chromosome-wide elongation caused by TTF2 depletion becomes pathological. However, this distinction should be discussed explicitly. As currently written, the manuscript risks giving the impression that mitotic transcription is generally deleterious, which would not be fully consistent with the literature. The authors should check whether Sgo1 is localized correctly after TTF2 depletion in both Noc-arrested and metaphase (MG132- or ProTAME-arrested) cells.
      4. I was somewhat confused by the interpretation of RPA70-positive fibers. The authors state that they "did not detect a major increase" in RPA70-coated UFBs, arguing against an important contribution of replication-associated intermediates. However, in the next sentence, they report that approximately 20% of TTF2-depleted anaphases display an RPA70-positive fiber and, importantly, this phenotype is largely reverted by triptolide. In my opinion, this is not a trivial observation and appears difficult to fully reconcile with the conclusion that replication-associated events contribute minimally to the phenotype. In principle, RPA70 positivity should not necessarily be interpreted exclusively as evidence of replication stress. Persistent transcription, R-loops, or transcription-associated topological stress could generate ssDNA intermediates that can recruit RPA. Do RPA-positive fibers co-localize with R-loops? Therefore, the Discussion would benefit from a more balanced interpretation of these findings.
      5. The rescue experiments with triptolide are convincing and support a transcription-dependent contribution to the phenotype. However, because triptolide treatment was performed over several hours, these experiments do not formally distinguish between ongoing transcription elongation during mitosis and perturbations arising earlier in the cell cycle, including possible transcription-replication conflicts during late S/G2. This limitation should be acknowledged more clearly in the Discussion, especially given the recently described role of TTF2 in replisome eviction. It would be informative to perform a time-course analysis of triptolide rescue. Demonstration that the phenotype can be substantially reverted within ~30 minutes of treatment would strongly support the interpretation that persistent transcription during mitosis, as opposed to earlier cell-cycle perturbations, is the major contributor to the observed defects.

      Minor comment:

      It would be useful to check whether RHINO-positive/R-loop-associated structures preferentially localize to centromeric versus chromosome arm regions. Such information may help distinguish physiological mitotic transcription from pathological transcript retention.

      Referees cross-commenting

      I have carefully read the other reviews and they do not change my overall assessment of the manuscript or my recommendations.

      Significance

      General assessment:

      This is an interesting and potentially important study addressing how transcriptional silencing contributes to mitotic fidelity. The strongest aspect of the work is the convincing demonstration that transcription elongation persists during mitosis after TTF2 depletion and contributes to chromosome segregation defects. The main limitation is that the mechanistic interpretation currently appears somewhat narrower than supported by the data.

      Advance:

      The study extends previous work on TTF2 by linking defective mitotic transcriptional silencing to chromosome organization and chromosome segregation defects. The demonstration of transcription elongation during mitosis after TTF2 depletion is particularly interesting.

      Audience

      The work will likely be of interest to researchers studying mitosis, chromosome biology, transcription, genome stability, and chromosome organization.

      Expertise:

      mitosis, chromosome organization, nuclear organization, cell biology, biochemistry. I do not consider myself an expert in R-loop biology or transcription-coupled repair.

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      Reply to the reviewers

      Reviewer #1:

      Major comments:

      1. Lines 103-116 (first paragraph of the results section) describe mainly published data that is more suitable for the introduction section. It is annoying to refer to different published articles in the Results section to strengthen the results instead of showing them. The same goes for paragraphs two and three. Why mention those data in the Results section if they are already published and known?

      We have reorganized this material by moving some background information to the Introduction. Our intention was not to incorporate published data to strengthen our results, but rather to provide essential context for interpreting our findings. We have therefore left some of this foundational information in the results section to create a clear narrative flow, enabling readers to understand the basis for our experimental design and interpretations without needing to recall details from earlier paragraphs in the Introduction. For example, we considered it crucial to restate the earlier report of the BiP:sfGFP:HDEL phenotype in Atlastin mutants, since our results supporting luminal ER protein displacement contradict the previous fragmentation model.

      The following concept was in line 103 in the Results section, and is now in the introduction in lines 82-92: "Conventional light microscopy, commonly used in studies of neuronal ER structure, lacks the resolution necessary to visualize individual ER tubules in small structures, such as presynaptic terminals. The ER is highly sensitive to fixation, and live imaging experiments in neurons in vivo have been conducted on upright microscopes using water dipping objectives with a typical axial resolution limit of >300 nm, which cannot distinguish the densely packed ER tubules at presynaptic terminals (3,8,21,28,39-42). Electron microscopy offers higher resolution, but cannot be used in live samples and has typically been limited to thin 2D sampling (in which it is difficult to distinguish ER cross-sections from synaptic vesicles) (8,20,22)."

      Figure Legends-(in all Figures): The number of experimental repeats must be mentioned in the figure legends.

      This information is provided in Supplementary Table 1, which contains detailed information about the genotype, statistical analysis, and number of larvae and NMJs analyzed. If the journal requires this information in figure legends, we can move it.

      The way the figures are labeled is worrisome; supplementary figures are not ordered numerically.

      We will be happy to rename supplementary figures according to journal guidelines.

      The tubule extension in Figure 2D is not convincing. Is there a movie showing those changes? Better images are needed. It is essential to show which supplemental movie corresponds to which panel.

      We have now included a corresponding video of the same neuron used as an example of tubule extension. We also added another frame to the figure to provide further information on the tubule event we captured. (Figure 2D, Movie S10)

      This is unnecessary in the results section: "To investigate the relationship between ER structure and function at synapses, we examined mutants of Atlastin, a GTPase that regulates ER tubule fusion. Drosophila has a single homolog while mammals have three Atlastin homologs, with Atlastin-1 enriched in the brain (Rismanchi et al., 2008)."

      This information was moved to the introduction.

      "This reduction in ER membrane marker intensity has also been observed in other HSP mutants, suggesting this is a common feature of ER shaping mutants and could indicate changes in ER membrane composition, integrity, or tubule thickness (Perez-Moreno et al., 2023)." This comparison is important and should be shown in the same settings as for the Atlastin mutant rather than referring to published data.

      We agree with the reviewer that it is important to determine whether other ER-shaping proteins, besides Atlastin, also show a decrease in tdTomato:Sec61b to support our claim that this could be a common feature among ER-shaping mutants. To do this, we examined mutants of another ER-shaping protein, Reticulon 1, which regulates membrane bending and stabilization in ER tubules. These loss-of-function mutants were a gift from Dr. Cahir O'Kane at the University of Cambridge and were used in his lab's Pérez-Moreno et al., 2023 publication. We found that in our hands tdTomato:Sec61b levels were reduced in Reticulon 1 mutants, consistent with the results reported by Pérez-Moreno et al. (2023). These results are in Figure 3E-F. We also examined the synaptic distribution of the luminal ER marker, BiP:sfGFP:HDEL, in Reticulon 1 mutants to see if it is displaced to the cytosol. Notably, it remained ER-associated, unlike in Atlastin mutants. These results are in Figure 6F-G, results lines 267-270, and discussion lines 542-545.

      Does the distribution of the luminal ER marker in Figure 6F diffuse due to mislocalization or reflux after being localized to the ER and then refluxed to the cytosol as was previously shown for the ER to Cytosol signaling (ERCYS) mechanism? Could you assess other ER-luminal protein localization biochemically? It is highly recommended to look at another soluble ER-protein localization in the Atlastin mutant without overexpression, which can be an artifact.

      ER stressors can induce ERCYS, in which some luminal proteins, including PDIA3, DNAJB11, ERp29, and an eroGFP reporter, reflux by 30-70% to the cytoplasm without subsequent degradation (unlike ERAD (ER-associated degradation). This phenomenon has only previously been observed in yeast and glioblastoma tumor cells from mice and human . We believe that our work provide the first suggestion that this may occur in neurons, and particularly in a neurological disease model.

      We do not believe that the reflux phenotype for BiP:sfGFP:HDEL is due to its overexpression for two reasons: (1) we observe reflux in our neuronal Atlastin knockdown experiments, even when the levels of BiP:sfGFP:HDEL are significantly reduced artificially because of titration of the GAL4 between the RNAi and the reporter (Figure 7A), and (2) BiP:sfGFP:HDEL overexpression somewhat suppresses endogenous BiP upregulation ((Figure 10 and see Reviewer 1.10), arguing that the transgene does not induce ER stress). We included a new "limitations of the study" section to be transparent about the caveats of the BiP:sfGFP:HDEL reporter (lines 639-664).

      Identifying potential endogenous neuronal ERCYS substrates in our in vivo preparation poses several challenges. First, biochemical approaches, such as fractionation, are not possible in our complex in vivo sample because neuronal ER proteins would mix with ER from other tissues upon homogenization. Second, detecting endogenous proteins with antibodies requires fixation and permeabilization, which notoriously disrupts ER structure and even causes our reporter BiP:sfGFP:HDEL to collapse from a smooth distribution, as visualized by live imaging and FRAP, to a punctate distribution. Third, using antibodies rather than neuronally restricted transgenes makes it challenging to determine whether the signal originates from the neuron or from dense ER structures in the surrounding muscle. Fourth, some ER luminal proteins can displace as little as 30% in the ERCYS examples cited above, and the sensitivity of our imaging assays may limit our ability to detect these small changes. Finally, the limited availability of tagged transgenes and antibodies specific to Drosophila luminal ER proteins (see next paragraph) poses additional challenges. These limitations highlight the need for future studies to develop novel tools and techniques to more definitively test whether we are indeed observing ERCYS. We have included a paragraph on these future challenges in our discussion in lines 639-664. Identifying endogenous targets of ERCYS in fly neurons is a worthwhile goal, but beyond the scope of the current study. These next steps will particularly benefit from identifying the machinery involved in the reflux of our BiP:sfGFP:HDEL reporter.

      Tools we tested: We investigated several options: (1) a tagged PDI transgene (a gift from Karen Hibbard), which was not detectable at presynaptic terminals, (2) a tagged BiP (FlyORF; F000956) that did not localize to the ER, and (3) full-length endogenous BiP detected by antibody staining. We did not detect obvious reflux of endogenous BiP to the cytoplasm (Figure 9), with the caveat that in fixed samples, the BiP signal was not tightly co-localized with the ER marker even under control conditions. However, we did use this antibody to detect an increase in BiP in Atlastin mutant presynaptic terminals, indicating ER stress (see Reviewer 1.10).

      Though we have not identified endogenous targets, we believe that our studies with the exogenous reporter will be of great interest to the field, as they clarify the previously reported Atlastin phenotype and provide the first report of a new defect in a human disease animal model.

      In comparison to Summerville et al. (2016) in Figure 7, the experiment was not done in the same way. It is important to keep the same settings for comparison

      In Figure 7D-E, we compare the distribution of BiP:sfGFP:HDEL in cell bodies, axons, and muscles between controls and Atlastin mutants. To clarify the experimental approach relative to Summerville et al. (2016): while both our studies examined the same cellular compartments (cell bodies, axons and nerve terminals) using the BiP:sfGFP:HDEL reporter, we employed super-resolution Airyscan microscopy. This enhanced resolution was critical for definitively demonstrating that this is a functional rather than a structural phenotype and that ER displacement is progressive, and repeating this experiment at lower resolution as previously reported does not provide any new information. We identified two distinct distribution phenotypes in Atlastin mutants expressing BiP:sfGFP:HDEL, which were not described in the Summerville et al., 2016 paper. From our manuscript (lines 249-251): "We identified two distinct ER network phenotypes in Atlastin mutants expressing BiP:sfGFP:HDEL: "Partial loss" NMJs retained both diffuse signal and identifiable ER network structures, while "Complete loss" NMJs showed no visible ER network structures. Note that the "Complete loss" phenotype in Atlastin mutants reflects the absence of detectable luminal marker signal in organized ER structures, but not the complete absence of ER membranes, as demonstrated by our ER membrane marker tdTomato:Sec61β results."

      Does the Atlastin mutant induce the unfolded protein response and stress within the ER? It is necessary to look for UPR markers in those settings. It was shown previously that ER stress leads to protein reflux from the ER to the cytosol. Is there a difference in the ER stress markers in the presynaptic terminal?

      The reviewer suggested that Atlastin mutant synapses may exhibit ER stress. To address this, we examined levels of the ER chaperone BiP, a well-established ER stress marker whose expression increases during UPR activation. We first validated that our BiP antibody can detect changes in ER stress by feeding control larvae with 50mM DTT for 24 hours. These results are in the new Figure 10A. Note that we were unable to test sensitivity to ER stress in this way in Atlastin mutant larvae because they did not consume the DTT-treated food, as assessed by blue food coloring in the larvae's guts.

      Using this antibody, we measured baseline BiP levels at NMJs of Atlastin mutants on normal food, and found they were slightly increased compared to controls. We conclude from these experiments that Atlastin mutant synapses have mild ER stress. Notably however, Atlastin mutants co-expressing UAS-BiP:sfGFP:HDEL or UAS-tdTomato:Sec61b did not show significantly increased endogenous BiP levels, suggesting that transgene expression at least partly suppresses the mild ER stress response, even though there is extensive cytosolic displacement. These results argue (1) that the mild ER stress in Atl mutants does not strictly correlate with the reflux phenotype, and (2) that the reflux phenotype is not an artifact of overexpression-induced stress. These results are described on lines 430-436 in the results section and shown in Figure 10B-E, and their implications discussed on lines 585-598.

      We also explored another strategy to detect ER stress by assessing eIF2α phosphorylation, a key event in the Unfolded Protein Response (UPR) pathway. We obtained a phospho-eIF2α antibody (Cell Signaling; #3597) that was reported to work in Drosophila. However, when we tested this antibody by Western blot, we were unable to detect a band at the expected molecular weight for phosphorylated eIF2α, even in positive-control samples treated with DTT to induce ER stress. We therefore concluded that this antibody is not suitable for reliably detecting ER stress in our experimental system. The failure of this antibody highlights the challenges of finding robust tools to measure ER stress in Drosophila.

      It is important to add biochemical experiments to show that no fragmentation of the ER membrane occurred. It can be simply demonstrated by looking at the redox state of the ER, which would change if it were mixed with the reducing cytosol. Moreover, this can be shown by using an ER-targeted redox-sensitive fluorescent protein that is tethered to the ER membrane to follow changes in the redox state of the ER.

      The reviewer asked us to test whether the redox state of the ER is disrupted, which could indicate exchange between the cytosol and ER due to membrane rupture. As noted above, biochemical approaches such as fractionation are not possible in this in vivo sample. We attempted to address this concern by creating a UAS-Sec61β:roGFP construct, using the roGFP sequence from Igbaria et al. (2019) to monitor the ER lumen redox environment in Atlastin mutants. Since Sec61β is membrane-tethered, it should remain in the ER and not undergo reflux, making it an ideal sensor for detecting any mixing between the reducing cytosolic environment and the oxidizing ER lumen that would occur if membrane fragmentation and/or ruptures were present. We tested this approach in wild-type Drosophila S2 cells and used the Gal4-UAS binary expression system to co-express Actin-Gal4 (to drive expression of UAS constructs), UAS-Sec61β:roGFP (redox sensor), and UAS-BiP:Halo:HDEL (as a control reporter insensitive to DTT treatment).

      Our experiments showed no detectable changes in the fluorescent properties of UAS-Sec61β:roGFP following 30 min 10mM DTT treatment compared to DMSO vehicle control, including no increase in 405-nm excitation fluorescence or changes in 488nm/405nm excitation ratios. These results suggest that either the roGFP sensor requires further optimization for sensitivity in this cellular system or that additional controls and calibration steps are needed to establish the dynamic range of the assay. We believe this experiment falls beyond the scope of the current study, given the extensive optimization required. However, it represents an important future direction for testing membrane fragmentation as a mechanism underlying the phenotypes observed in Atlastin mutants. The possibility of ER integrity defects is mentioned in the discussion on lines 547-559.

      Minor comments:

      1. It is important to call figures by order. Figure 2C is called before 2A-B. Figure 2B is called before Figure 2A.

      The revised manuscript has all figures in order of appearance in the text.

      Figure legends (Figure 2): "The same control dataset used in E-G was used in Figure 5 and Figure 5_Supplement." Why is this relevant?

      We wanted to be transparent about reusing the same control dataset across multiple figures to avoid any appearance of data duplication. This notation clarifies that, although the data appear in different contexts (Figures 2 and 5. This version does not contain a Figure 5_Supplement), it represents the same biological samples analyzed for different parameters, ensuring readers understand that these are not independent datasets.

      Figure 4F is called before Figure-4D-E which are not called.

      We revised our manuscript and reorganized Figure 4 to ensure that all figure panels are referenced in sequential order and that panels 4D-E, which were previously not cited in the text, are now properly referenced when discussing their corresponding results.

      Figure 5B is called before the previous ones. Same for Figure 5A supplement.

      We referenced Figure 5A in lines 211-212, which precedes our discussion of Figure 5B. To clarify the figure order, we removed the early references to Figures 2D-G and Movies 7-14, which were mentioned only to indicate that we were analyzing the same dataset in different ways.

      The revised manuscript has all figures in order of appearance in the text.

      Referees cross-commenting

      I agree with the comments raised by reviewer2 and 3. Basically it is highly important to validate those data by genetic rescue. Moreover, it is essential to know the source of the displaced luminal marker to the cytosol. Is it mislocalization or it is a reflux of pre-existing protein to the cytosol after insertion to the ER. It is also recommended by me and the reviewers and me to test the endogenous protein rather than overexpression.

      We have addressed these points in our responses to the following reviewer questions:

      • Genetic rescue: Please see our responses to Reviewer 1/Question #10 and Reviewer 2/Question #1.
      • Source of displaced luminal marker: We provide some evidence addressing this in our response to Reviewer 3/Question #1.
      • Endogenous protein localization: We have examined this and detailed our findings in our responses to Reviewer 1/Question #7 and Reviewer 2/Question #6.

        Reviewer #1 (Significance (Required)):

      General assessment: This interesting paper shows that proteins can escape the ER under special conditions. However, the authors need more evidence to show that and rely less on the overexpression system, especially of BIP-GFP, which can cause proteostasis stress within the ER. Advance: The results have been oversimplified in their explanations, and some points and complexities of the study need to be addressed further to make the most of them. These are often some of the more interesting concepts in the paper. I think many points can be addressed in the text by the authors being clear and concise with their reporting. At the same time, other experiments would turn this paper from an observational one into a very interesting mechanistic one. This paper is based on previously published articles from the group and other groups, and it is a nice progression. However, as mentioned, this paper depends primarily on published data, and the novelty is somehow lost between all the comparisons to other published data instead of emphasizing that. Without a substantial mechanistic improvement, the paper would remain observatory.

      Audience: The microscopy tools can be great addition to researchers in the field to monitor protein trafficking especially Cell biologists (basic research)

      My expertise: ER homeostasis, protein trafficking, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary The endoplasmic reticulum (ER) is a continuous organelle that extends throughout neurons to regulate fundamental processes. The analysis of ER dynamics at synaptic terminals is limited by the challenge of imaging these structures at high resolution. In this manuscript, the authors use super-resolution (~170 nm) live imaging and a combination of membrane and luminal ER markers at the Drosophila larval NMJ, an important model synapse, to investigate dynamic ER architecture in vivo. They report a detailed characterization of the presynaptic ER organization and dynamics at wild-type and GTPase Atlastin mutant NMJs. Their analysis using the ER membrane marker tdTomato:Sec61b reveals the presence of an intact ER network in Atlastin mutants. This contrasts with the apparent ER fragmentation phenotype previously reported and replicated here when using a luminal marker. Their findings instead point to the progressive displacement of luminal proteins to the cytosol in Atlastin mutants specifically at synapses. The authors propose that the disruption of ER protein dynamics at synapses is a compartment-specific ER stress response. The manuscript is well written, results are clearly presented, and experiments are technically rigorous.

      Major comments

      1. The baseline ER phenotypes in Atlastin mutants are mild with complete loss of ER network only observed in terminal boutons. This interesting and unexpected result should be further confirmed by genetic rescue. The authors can use a UAS rescue line previously reported in PMID: 19341724.

      We tested the UAS-Atl-myc rescue line and unfortunately found that even in wild-type neurons, overexpression of Atlastin produced strong ER organization defects that precluded the rescue experiment. Instead, to confirm the cell autonomy of the phenotype and to test it wth an independent tool, we performed a presynaptic knockdown of Atlastin by RNAi and found that BiP:sfGFP:HDEL is displaced, as observed in the Atlastin null mutant. These results are in now shown in Figure 7A-C.

      Lines 204-7: It's not clear how a greater coefficient of variation indicates that the marker is more concentrated in subsynaptic structures or what is meant by 'subsynaptic structures.'

      We added the following text to explain, in lines 181-183: "A higher CoV indicates an uneven distribution of tdTomato:Sec61β within the presynaptic terminal, with some areas showing higher concentrations than others (in contrast to the uniform, diffuse signal expected from fragmentation)." To avoid confusion with postsynaptic structures called the subsynaptic reticulum, we have removed the term "subsynaptic". The intended meaning is distinct structures found within the presynaptic terminal.

      There's a mistake in Figure 6C and the associated text. The summed percentage of the three phenotypic categories adds up to 110% for Atlastin mutants. *

      The reviewer noted that the summed percentage of the three phenotypic categories in Figure 6C adds up to 110% for Atlastin mutants, which appears to be a mathematical error. However, this is not an error, but rather a reflection of our quantification methodology, in which a single bouton can exhibit more than one type of ER dynamics per movie recorded. Our quantification counts each phenotype independently, so boutons displaying multiple phenotypes contribute to more than one category. This approach provides a more comprehensive view of the range of ER dynamics present in Atlastin mutants, as restricting the analysis to mutually exclusive categories would underrepresent the complexity of the phenotypes observed. To make this point clear, we made the following change to the text in lines 257-259: "We note that the sum of these percentages exceeds 100% because one NMJ exhibited multiple phenotypes: one branch had a complete loss, while the other branch had no phenotype. These phenotypes were counted separately."

      Figure 8: the ER looks fragmented in 1st instar controls and mutants. The authors should address this difference from more mature NMJs.

      We would like to clarify that the bulk of experiments in this manuscript (including all ER dynamics, luminal marker redistribution, and membrane marker analyses discussed throughout the Results) were performed in 3rd instar larvae, which are more mature larval NMJ preparations standard in the field. Figure 8 was included specifically to test whether the Atlastin mutant phenotype we describe throughout the paper is also detectable at an earlier developmental stage, not to replace or reinterpret our primary findings.

      Regarding the specific observation that the ER appears more fragmented in Figure 7F-H relative to the more mature NMJs shown elsewhere: this fragmentation, observed similarly in both control and Atlastin mutant 1st instar larvae, likely reflects technical challenges associated with dissecting these smaller, more delicate early-stage specimens rather than a genotype-specific effect. Because fragmentation occurred similarly in both genotypes, we could still reliably assess the redistribution of BiP:sfGFP:HDEL as our primary phenotypic readout in this experiment. We have added the following text (lines 306-309) to clarify this point: "Note that in 1st instar larvae, both normal networks in controls and residual networks in Atlastin mutants appeared more fragmented than in 3rd instar preparations, likely due to the technical challenges of dissecting these smaller, more delicate specimens. Since ER fragmentation occurred similarly in both genotypes, we could still reliably assess the redistribution of BiP:sfGFP:HDEL as our primary phenotypic readout.

      The images in figure 9B do not seem representative of the quantification in Figure 9D. Specifically, the partial loss Atlastin NMJ appears to have recovered as fully as the complete loss Atlastin NMJ.

      The images showed FRAP recovery across the entire bouton, but we photobleached only a small region within each bouton and quantified only this region. We have now added outlines to clearly delineate the specific FRAP regions that were analyzed in each image, which clarify that the partial loss Atlastin showed less recovery than the overall bouton. We have also reordered the figures to more clearly convey our message (Figure 9 is now Figure 8).

      We also made a few changes to the paragraph on lines 347-350 to clarify our experimental reasoning: "We photobleached en passant boutons using a defined region of 6.8 x 7.8 microns (dashed box in Figure 8D) to ensure that BiP:sfGFP:HDEL could recover from the ER networks surrounding the FRAP region (Movies S20-S23)."

      We also added this sentence to the figure legends of Figure 8: "The dashed boxes in (D) indicate areas that were photobleached and analyzed for recovery quantification in (E-F)."

      Optional: An overexpressed luminal marker is displaced to the cytoplasm in Atlastin mutants. It would be interesting to know and increase the significance of the findings if the same is true of endogenous luminal proteins under biological stress conditions.

      As noted in our response to Reviewer #1 suggested that Atlastin mutant synapses may exhibit ER stress. To address this, we examined levels of the ER chaperone BiP, a well-established ER stress marker whose expression increases during UPR activation. We first validated that our BiP antibody can detect changes in ER stress by feeding control larvae with 50mM DTT for 24 hours. We were unable to perform this experiment in Atlastin mutant larvae because they did not consume the DTT-treated food, as assessed by blue food coloring in the larvae's guts. These results are in Figure 10A. In the future, it will be of interest to establish a protocol to examine Atlastin mutants by feeding or treating larval fillets with DTT.

      We measured BiP levels at NMJs of Atlastin mutants and found they were slightly increased compared to controls. Atlastin mutants co-expressing UAS-BiP:sfGFP:HDEL or UAS-tdTomato:Sec61b did not show significantly increased endogenous BiP levels, suggesting that transgene expression suppresses the mild ER stress response. We conclude from these experiments that Atlastin mutant synapses have mild ER stress. These results are in Figure 10B-E).

      Optional: Applying this approach in stimulated conditions (high potassium, increased temperature) might reveal a greater activity-dependent role for Atlastin at synaptic terminals.

      This is a very interesting idea, as we have only examined synapses at rest. However, this is beyond the scope of this paper.

      Minor Comments

      1. Line 16: Atlastin should be italicized.

      Thank you for catching this typo. We have fixed it.

      Figure 5A: Based on the relative intensities, it appears that control and mutant images are not contrast matched but this isn't stated.

      Thank you for catching this omission. We added to the figure legend: "Control and Atlastin mutant images are not contrast matched."

      Line 822: The number of static Atlastin mutant boutons used for analysis is missing.

      Thank you for catching this omission. We have fixed this supplementary table.

      Figure 9: The blue arrows are not annotated in the figure legend.

      Thank you for catching this omission. We have fixed this figure legend.

      Reviewer #2 (Significance (Required)):

      Atlastin is linked to Hereditary Spastic Paraplegia (HSP) and this study changes our understanding of the compartment-specific impacts of its loss. This study reveals the importance of using both membrane and luminal ER markers to accurately interpret phenotypes as well as the importance of considering compartment-specific effects on ER. These findings represent significant mechanistic and conceptual advances. The lack of genetic rescue is a limitation and adding an investigation of an endogenous luminal protein under basal and stress conditions would add significantly to our understanding of Atlastin dysfunction in HSP. Notably, the in vivo imaging approach introduced here can be adapted broadly for live imaging of Drosophila larvae. Thus, this work will be of interest to both neuronal cell biologists and the wider Drosophila community. This review is based on our expertise in neuronal cell biology.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      In this manuscript, the authors investigate the structural dynamics of the endoplasmic reticulum (ER) in Drosophila neurons and examine the role of the ER-shaping protein Atlastin in ER morphology. Their discovery on the neuromuscular junction (NMJ)-specific contribution of Atlastin to ER integrity is intriguing and may provide valuable insights into the pathological mechanisms underlying Atlastin mutations associated with hereditary spastic paraplegia (HSP) and hereditary sensory neuropathy. The key observation on ER protein showing an aberrant cytoplasmic localisation in mutant cells appears convincing. Though this phenomenon's characterisation stays at the point of primary observation with its mechanics unclarified, establishing this new and unexpected functional rather than structural Atl effect is important and useful for the field. The observation that ER is structurally preserved in this mutant with absolute lack of Atl are also extremely useful.

      It is unclear if the cytoplasmic localisation affects an exogenous overexpressed ER marker or endogenous protein would also appear in cytoplams, the authors should consider adding an immunostaining data to test that.

      Authors offer speculations on potential reasons for the cyto localisation of the ER marker suggesting that relocation at the cell periphery specifically combined with slow clearance there is the most likely explanation (still unclear what stops the marker from spreading through the entire cell). They suggest that decrease in cotranslational translocation is unlikely as this would result in somatic accumulation of the marker. However, if the clearance in the periphery is less efficient than in soma, the accumulation there might reflect a compromised translocation. Any clarifying experiments, if practical, to directly demonstrate how ER proteins in relocates to the cytoplasm in atl mutant would help understanding better the phenomenon. For example, would proteasomal inhibition make the marker accumulate more across the cell? Authors also suggest links to ER stress. Would stress induction phenocopy the mutant?

      Reviewer #3 asked whether defective proteasomal clearance underlies the cytosolic accumulation of BiP:sfGFP:HDEL in Atlastin mutants. We addressed this directly. First, proteasome function appears intact in the mutants: baseline ubiquitinated protein levels (FK1 antibody) were comparable between control and Atlastin mutants, and MG132 treatment produced a similar increase in ubiquitination in both genotypes, confirming both antibody specificity and normal proteasome activity. We then examined BiP:sfGFP:HDEL directly. In controls, MG132 caused the marker to accumulate at axons and presynaptic terminals, showing that it is normally cleared from these compartments by the proteasome. Critically, this accumulated marker remained associated with intact ER networks: MG132 did not induce diffuse cytosolic BiP:sfGFP:HDEL in any compartment (cell bodies, axons, or presynaptic terminals), even where levels rose substantially. Thus, blocking proteasomal clearance raises ER-localized marker but does not generate the cytosolic pool seen in Atlastin mutants, indicating that impaired clearance is not sufficient to cause the displacement phenotype. We separately noted that BiP:sfGFP:HDEL was already elevated in Atlastin mutant axons without MG132, paralleling the axonal tdTomato:Sec61β accumulation in Figure 4, consistent with reduced baseline clearance specifically in mutant axons, but this does not lead to cytosolic displacement. This experiment is now shown in Figure 11, described in Results (lines 445-475), and discussed in lines 576-581.

      Minor comments:

      Line 146:

      "fast dynamics (Thank you for catching this mistake. We have corrected it.

      Fig. 2D: The data representation of "Tubule displacement" image is unclear. The ER tubule indicated by the red arrow does not seem to show any changes over time (like static). time 0 in stamp appears behind the image.

      Thank you for catching the typo. We have fixed it. Additionally, we added black arrows to highlight a tubule that is not moving, allowing the reader to compare it with the moving tubule. We also included a video of all types of ER tubule dynamics to ensure the reader can also look at the raw data (Movies S9-11).

        • Line 157-158 (and relevant method sections):

      The definition of static and dynamic boutons is ambiguous. The author should describe in more detail this point including how long they observed the structure to define the changes in ER tubule dynamics.

      We provide in the methods (lines 779-791) a detailed explanation of how we categorized boutons as dynamic or static. In addition, we added the following to explain in the results section how we defined static vs dynamic:

      Old sentence: We qualitatively categorized boutons as "static" if we observed no change in ER network structure or "dynamic" if we observed at least one change.

      New sentence in lines 143-147: "We imaged boutons for 40 sec at 0.92 sec intervals to capture ER dynamics over this observation period. Boutons were qualitatively categorized as "static" if we observed no detectable changes in ER network structure throughout the entire 40 sec imaging session, or "dynamic" if we observed at least one of the three defined dynamic events during this time window."

      Fig. 2E: What n=75 and n=29 represent is unclear, are these the number of boutons in en passant and terminal subjected for qualitative analysis?

      We removed these n values from the figure and added this information to the Supplementary Table 1, which contains detailed information about the genotype, statistical analysis, and number of larvae and NMJs analyzed.

      Fig. 2: What the qualitative analysis represents is unclear, are the points pulled from different experiments?

      The data in Fig. 2 E-F comes from movies acquired in the same experiment. The number of independent animals and NMJs imaged is described in Table 1.

      * *Line 231: Regarding "...we found a small but significant reduction in dynamic boutons in Atlastin mutants (76%), ...", how do the authors assess significance. If proportion of static/dynamic ER in boutons was obtained from multiple experiments, it should be presented e.g. as in average {plus minus} standard deviation, or clarify that the proportion is representative of x independent experiments.

      The videos used for this figure were acquired from a single experiment. We use a chi-square test to determine significance relative to the "expected" distribution of dynamics types from controls, as these are categorical rather than continuous data (see PMID 31145670). Information regarding genotype, statistical analysis and number of larvae and NMJs can also be found in Supplementary Table 1.

      Line 267-269 and Fig. 6B: The author's conclusion that "Complete loss of ER network structure in NMJ of BiP:sfGFP:HDEL overexpressing Atl mutant" seem to be based on the lack of signal from luminal marker, which may be undetectable due to changes to tubular volume or marker loss to the cytoplasm, as suggested by the authors, while the membranous ER structure is intact. It would be useful to discuss this point and potentially add ER membrane-stained control.

      We agree with the reviewer that Atlastin mutants categorized as 'complete loss mutants' do not actually lack ER at synapses. We think this is an important point so we added the following to the results in lines 251-254: "Note that the "Complete loss" phenotype in Atlastin mutants reflects the absence of detectable luminal marker signal in organized ER structures, not the complete absence of ER membranes, as demonstrated by our ER membrane marker tdTomato:Sec61β results."

      We attempted to co-label the ER membrane and ER lumen, but these crosses yielded very few live larvae (in either controls or Atlastin mutants, and those that survived had severely deformed NMJs. We added Figure 6-Supplement showing the results of this experiment, and described them on lines 270-273.

      Fig. 6C: In Atl mutant, why does the total of the proportion exceed 100% (10 + 45 + 55)?

      The reviewer noted that the summed percentage of the three phenotypic categories in Figure 6C adds up to 110% for Atlastin mutants. This is not an error, but rather a reflection of our quantification methodology because a single bouton can exhibit more than one type of ER dynamics per movie recorded. Our quantification counts each phenotype independently, so boutons displaying multiple phenotypes contribute to more than one category. This approach provides a more comprehensive view of the range of ER dynamics present in Atlastin mutants, as restricting the analysis to mutually exclusive categories would underrepresent the complexity of the phenotypes observed. To make this point clear, we made the following change to the text in lines 257-259: "We note that the sum of these percentages exceeds 100% because one NMJ exhibited multiple phenotypes: one branch had a complete loss, while the other branch had no phenotype. These phenotypes were counted separately."

      Fig. 9C, line 342-344: In FRAP experiment using CD8, it seems that the Partial loss Atl mutant shows slower recovery that control. There seems to be a mismatch in triangle symbols of Partial loss Atl mutant between legend and plot (one is filled and the other is empty). This should be clarified.

      Thank you for catching this mistake. We have fixed the figure.

      fig. 10 is a clever way to verify the cytoplasmic localization of the ER marker; however, its description and annotation can be improved, and it would be stronger if 4 curves in F for mutant and controls with the trap and normal were shown.

      The reviewer suggested merging our graphs but we believe that keeping them separate is clearer.

      Line 495: Drosophila have ReepA and ReepB, but not Reep1-4. If the authors discuss their speculation based on their observation (using Drosophila), the gene names should be unified in the same species, and explain the corresponding genes to mammalian cells.

      We made the following changes to address the reviewer's concern about gene nomenclature consistency (lines 502-506): "These ER-derived vesicles are likely to involve ReepA and ReepB, the Drosophila orthologs of mammalian REEP1-4, which regulate ER vesicle formation in mammalian cells (67). Notably, while overexpression of Atlastin can regulate REEP vesicle fusion in mammalian systems (67), it is not essential for vesicle formation, suggesting similar regulatory relationships may exist between Atlastin and Reep genes in Drosophila."

      Line 548; should UPR be Unfolded Protein Response?

      Thank you for catching the typo. We have fixed it.

      Reviewer #3 (Significance (Required)):

      This study advances the understanding of how ER morphogens affect neuronal cells specifically, the lack of which limits researchers ability to comprehend the neuronal pathologies associated with ER structure-function. The observation on ER content aberrant localisation caused by the lack of key structural protein should be of a great interest for cell and neuronal biologists and researchers of the associated diseases and shows the field a new direction. Though, mechanistic details remain to be unraveled, it constitutes a fundamental, conceptual advance.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #3

      Evidence, reproducibility and clarity

      In this manuscript, the authors investigate the structural dynamics of the endoplasmic reticulum (ER) in Drosophila neurons and examine the role of the ER-shaping protein Atlastin in ER morphology. Their discovery on the neuromuscular junction (NMJ)-specific contribution of Atlastin to ER integrity is intriguing and may provide valuable insights into the pathological mechanisms underlying Atlastin mutations associated with hereditary spastic paraplegia (HSP) and hereditary sensory neuropathy. The key observation on ER protein showing an aberrant cytoplasmic localisation in mutant cells appears convincing. Though this phenomenon's characterisation stays at the point of primary observation with its mechanics unclarified, establishing this new and unexpected functional rather than structural Atl effect is important and useful for the field. The observation that ER is structurally preserved in this mutant with absolute lack of Atl are also extremely useful.

      It is unclear if the cytoplasmic localisation affects an exogenous overexpressed ER marker or endogenous protein would also appear in cytoplams, the authors should consider adding an immunostaining data to test that.

      Authors offer speculations on potential reasons for the cyto localisation of the ER marker suggesting that relocation at the cell periphery specifically combined with slow clearance there is the most likely explanation (still unclear what stops the marker from spreading through the entire cell). They suggest that decrease in cotranslational translocation is unlikely as this would result in somatic accumulation of the marker. However, if the clearance in the periphery is less efficient than in soma, the accumulation there might reflect a compromised translocation. Any clarifying experiments, if practical, to directly demonstrate how ER proteins in relocates to the cytoplasm in atl mutant would help understanding better the phenomenon. For example, would proteasomal inhibition make the marker accumulate more across the cell? Authors also suggest links to ER stress. Would stress induction phenocopy the mutant?

      Minor comments:

      Line 146: "fast dynamics (<1 sec)" a velocity should be presented as distance/time

      Fig. 2D: The data representation of "Tubule displacement" image is unclear. The ER tubule indicated by the red arrow does not seem to show any changes over time (like static). time 0 in stamp appears behind the image.

      Line 157-158 (and relevant method sections): The definition of static and dynamic boutons is ambiguous. The author should describe in more detail this point including how long they observed the structure to define the changes in ER tubule dynamics.

      Fig. 2E: What n=75 and n=29 represent is unclear, are these the number of boutons in en passant and terminal subjected for qualitative analysis?

      Fig. 2: What the qualitative analysis represents is unclear, are the points pulled from different experiments?

      Line 231: Regarding "...we found a small but significant reduction in dynamic boutons in Atlastin mutants (76%), ...", how do the authors assess significance. If proportion of static/dynamic ER in boutons was obtained from multiple experiments, it should be presented e.g. as in average {plus minus} standard deviation, or clarify that the proportion is representative of x independent experiments.

      Line 267-269 and Fig. 6B: The author's conclusion that "Complete loss of ER network structure in NMJ of BiP:sfGFP:HDEL overexpressing Atl mutant" seem to be based on the lack of signal from luminal marker, which may be undetectable due to changes to tubular volume or marker loss to the cytoplasm, as suggested by the authors, while the membranous ER structure is intact. It would be useful to discuss this point and potentially add ER membrane-stained control.

      Fig. 6C: In Atl mutant, why does the total of the proportion exceed 100% (10 + 45 + 55)?

      Fig. 9C, line 342-344: In FRAP experiment using CD8, it seems that the Partial loss Atl mutant shows slower recovery that control. There seems to be a mismatch in triangle symbols of Partial loss Atl mutant between legend and plot (one is filled and the other is empty). This should be clarified

      fig. 10 is a clever way to verify the cytoplasmic localisatoin of the ER marker, however its description and annotation can be improved, and it would be stronger if 4 curves in F for mutant and controls with the trap and normal were shown.

      Line 495: Drosophila have ReepA and ReepB, but not Reep1-4. If the authors discuss their speculation based on their observation (using Drosophila), the gene names should be unified in the same species, and explain the corresponding genes to mammalian cells.

      Line 548; should UPR be Unfolded Protein Response?

      Significance

      This study advances the understanding of how ER morphogens affect neuronal cells specifically, the lack of which limits researchers ability to comprehend the neuronal pathologies associated with ER structure-function. The observation on ER content aberrant localisation caused by the lack of key structural protein should be of a great interest for cell and neuronal biologists and researchers of the associated diseases and shows the field a new direction. Though, mechanistic details remain to be unraveled, it constitutes a fundamental, conceptual advance.

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      Summary

      The endoplasmic reticulum (ER) is a continuous organelle that extends throughout neurons to regulate fundamental processes. The analysis of ER dynamics at synaptic terminals is limited by the challenge of imaging these structures at high resolution. In this manuscript, the authors use super-resolution (~170 nm) live imaging and a combination of membrane and luminal ER markers at the Drosophila larval NMJ, an important model synapse, to investigate dynamic ER architecture in vivo. They report a detailed characterization of the presynaptic ER organization and dynamics at wild-type and GTPase Atlastin mutant NMJs. Their analysis using the ER membrane marker tdTomato:Sec61b reveals the presence of an intact ER network in Atlastin mutants. This contrasts with the apparent ER fragmentation phenotype previously reported and replicated here when using a luminal marker. Their findings instead point to the progressive displacement of luminal proteins to the cytosol in Atlastin mutants specifically at synapses. The authors propose that the disruption of ER protein dynamics at synapses is a compartment-specific ER stress response. The manuscript is well written, results are clearly presented, and experiments are technically rigorous.

      Major comments

      1. The baseline ER phenotypes in Atlastin mutants are mild with complete loss of ER network only observed in terminal boutons. This interesting and unexpected result should be further confirmed by genetic rescue. The authors can use a UAS rescue line previously reported in PMID: 19341724.
      2. Lines 204-7: It's not clear how a greater coefficient of variation indicates that the marker is more concentrated in subsynaptic structures or what is meant by 'subsynaptic structures.'
      3. There's a mistake in Figure 6C and the associated text. The summed percentage of the three phenotypic categories adds up to 110% for Atlastin mutants.
      4. Figure 8: the ER looks fragmented in 1st instar controls and mutants. The authors should address this difference from more mature NMJs.
      5. The images in figure 9B do not seem representative of the quantification in Figure 9D. Specifically, the partial loss Atlastin NMJ appears to have recovered as fully as the complete loss Atlastin NMJ.
      6. Optional: An overexpressed luminal marker is displaced to the cytoplasm in Atlastin mutants. It would be interesting to know and increase the significance of the findings if the same is true of endogenous luminal proteins under biological stress conditions.
      7. Optional: Applying this approach in stimulated conditions (high potassium, increased temperature) might reveal a greater activity-dependent role for Atlastin at synaptic terminals.

      Minor Comments

      1. Line 16: Atlastin should be italicized.
      2. Figure 5A: Based on the relative intensities, it appears that control and mutant images are not contrast matched but this isn't stated.
      3. Line 822: The number of static Atlastin mutant boutons used for analysis is missing.
      4. Figure 9: The blue arrows are not annotated in the figure legend.

      Significance

      Atlastin is linked to Hereditary Spastic Paraplegia (HSP) and this study changes our understanding of the compartment-specific impacts of its loss. This study reveals the importance of using both membrane and luminal ER markers to accurately interpret phenotypes as well as the importance of considering compartment-specific effects on ER. These findings represent significant mechanistic and conceptual advances. The lack of genetic rescue is a limitation and adding an investigation of an endogenous luminal protein under basal and stress conditions would add significantly to our understanding of Atlastin dysfunction in HSP. Notably, the in vivo imaging approach introduced here can be adapted broadly for live imaging of Drosophila larvae. Thus, this work will be of interest to both neuronal cell biologists and the wider Drosophila community. This review is based on our expertise in neuronal cell biology.

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      Referee #1

      Evidence, reproducibility and clarity

      In the present manuscript, the authors address an important question related to the ultrastructure and the dynamics of the ER in HSP. In contrast to previous studies, the authors here show (by using a membrane and luminal protein markers) that in the presynaptic terminals, the overexpressed BIP "mislocalizes" to the cytosol without affecting (or with minimal effect) the integrity of the ER membrane. Although they used an artificial system by overexpressing (overexpression) of BIP-sfGFP-HDEL (fused protein), the findings lack validation of the endogenous protein by biochemical and fluorescent tools.

      Concerns:

      I am worried about how the article is presented, mainly in the results section, as most of it refers to published data. The Results section is reserved for presenting new findings without external interpretation or comparison. The paper is written mainly as a comparison paper with other studies or relies on previous studies to strengthen their findings rather than coming up with novel findings. Up to figure 4, I missed the relevance of the new findings. The manuscript needs rewriting to emphasize its novelty and significance without comparing it to previous data. Moreover, the manuscript emphasizes the technology and the findings of the localization of the ER luminal proteins to the cytosol (which is not novel and was previously reported in other settings). Those two aspects were not given enough focus. Here are the main major and minor comments:

      Major comments:

      1. Lines 103-116 (first paragraph of the results section) describe mainly published data that is more suitable for the introduction section. It is annoying to refer to different published articles in the Results section to strengthen the results instead of showing them. The same goes for paragraphs two and three. Why mention those data in the Results section if they are already published and known?
      2. Figure Legends-(in all Figures): The number of experimental repeats must be mentioned in the figure legends.
      3. The way the figures are labeled is worrisome; supplementary figures are not ordered numerically.
      4. The tubule extension in Figure 2D is not convincing. Is there a movie showing those changes? Better images are needed. It is essential to show which supplemental movie corresponds to which panel.
      5. This is unnecessary in the results section: "To investigate the relationship between ER structure and function at synapses, we examined mutants of Atlastin, a GTPase that regulates ER tubule fusion. Drosophila has a single homolog while mammals have three Atlastin homologs, with Atlastin-1 enriched in the brain (Rismanchi et al., 2008)."
      6. "This reduction in ER membrane marker intensity has also been observed in other HSP mutants, suggesting this is a common feature of ER shaping mutants and could indicate changes in ER membrane composition, integrity, or tubule thickness (P.rez-Moreno et al., 2023)." This comparison is important and should be shown in the same settings as for the Atlastin mutant rather than referring to published data.
      7. Does the distribution of the luminal ER marker in Figure 6F diffuse due to mislocalization or reflux after being localized to the ER and then refluxed to the cytosol as was previously shown for the ER to Cytosol signaling (ERCYS) mechanism? Could you assess other ER-luminal protein localization biochemically? It is highly recommended to look at another soluble ER-protein localization in the Atlastin mutant without overexpression, which can be an artifact
      8. "(data not shown)" in line 288. This affects the process of judging those data.
      9. In comparison to Summerville et al. (2016) in Figure 7, the experiment was not done in the same way. It is important to keep the same settings for comparison
      10. Does the Atlastin mutant induce the unfolded protein response and stress within the ER? It is necessary to look for UPR markers in those settings. It was shown previously that ER stress leads to protein reflux from the ER to the cytosol. Is there a difference in the ER stress markers in the presynaptic terminal?
      11. It is important to add biochemical experiments to show that no fragmentation of the ER membrane occurred. It can be simply demonstrated by looking at the redox state of the ER, which would change if it were mixed with the reducing cytosol. Moreover, this can be shown by using an ER-targeted redox-sensitive fluorescent protein that is tethered to the ER membrane to follow changes in the redox state of the ER.

      Minor comments:

      1. It is important to call figures by order. Figure 2C is called before 2A-B. Figure 2B is called before Figure 2A.
      2. Figure legends (Figure 2): "The same control dataset used in E-G was used in Figure 5 and Figure 5_Supplement." Why is this relevant?
      3. Figure 4F is called before Figure-4D-E which are not called.
      4. Figure 5B is called before the previous ones. Same for Figure 5A supplement.

      Referees cross-commenting

      I agree with the comments raised by reviewer2 and 3. Basically it is highly important to validate those data by genetic rescue. Moreover, it is essential to know the source of the displaced luminal marker to the cytosol. Is it mislocalization or it is a reflux of pre-existing protein to the cytosol after insertion to the ER. It is also recommended by me and the reviewers to test the endogenous protein rather than overexpression.

      Significance

      General assessment: This interesting paper shows that proteins can escape the ER under special conditions. However, the authors need more evidence to show that and rely less on the overexpression system, especially of BIP-GFP, which can cause proteostasis stress within the ER.

      Advance: The results have been oversimplified in their explanations, and some points and complexities of the study need to be addressed further to make the most of them. These are often some of the more interesting concepts in the paper. I think many points can be addressed in the text by the authors being clear and concise with their reporting. At the same time, other experiments would turn this paper from an observational one into a very interesting mechanistic one. This paper is based on previously published articles from the group and other groups, and it is a nice progression. However, as mentioned, this paper depends primarily on published data, and the novelty is somehow lost between all the comparisons to other published data instead of emphasizing that. Without a substantial mechanistic improvement, the paper would remain observatory.

      Audience: The microscopy tools can be great addition to researchers in the field to monitor protein trafficking especially Cell biologists (basic research)

      My expertise: ER homeostasis, protein trafficking, cell biology

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      Reply to the reviewers

      1. __ General Statements__ We thank the reviewers for their thoughtful and constructive evaluations of our work. We are particularly encouraged that both recognize the value of this study as a scalable and systematic framework for the functional exploration of the human KZFP family and agree that the resource generated here will be of broad interest to the KZFP, transposable element, and genome regulation communities. Reviewer 1 explicitly notes that "the screening framework itself represents a potentially useful resource for prioritizing candidate KZFPs for downstream study" and that "the study may nonetheless serve as a useful starting point for future investigations into KZFP biology and transcriptional regulation." Reviewer 2 similarly emphasizes that "the authors provide an efficient and valuable screening platform that can identify promising candidates for further investigation" and that "the methodological advance represents the primary contribution of the work."

      We can only concur with these assessments. The principal goal of this study was not to elucidate the physiological roles of all or even a subset of individual KZFPs, but rather to provide a scalable framework that enables their systematic prioritization and generates experimentally testable hypotheses regarding their functions. To support our argument, we ventured into some mechanistic analyses, but these could not pretend to be complete and definitive. In that respect, we hear the reviewers when they note that the original manuscript does not always sufficiently distinguish candidate discovery from mechanistic validation. In its revised version, we will therefore more clearly frame the inducible K562 overexpression assay as a standardized and sensitive readout of regulatory potency rather than as a direct surrogate of physiological function. Within this framework, K562 fitness defects are interpreted as a quantitative measure of the extent to which ectopic KZFP expression perturbs transcriptional homeostasis in a controlled cellular context, while the direct targets and transcriptional networks identified through our integrative analyses are presented as hypotheses to be tested in more physiologically relevant systems. Accordingly, the revised manuscript preserves the broad scope and resource aspect of the study while incorporating additional experimental validation, expanded methodological descriptions, and a more cautious interpretation of the proposed biological functions of the selected KZFPs.

      __Although this document is submitted as a Revision Plan, we have already incorporated a substantial number of revisions into the transferred manuscript. In particular, we have implemented most of the presentation, methodological, and conceptual modifications requested by the reviewers, including clarification of the scope of the study, extensive revisions of the Results and Discussion, expanded Materials and Methods, and numerous figure and text corrections. These revisions are detailed in Section 3 ("Description of the revisions that have already been incorporated into the transferred manuscript"). __

      The remaining points requiring additional experimentation or more extensive analyses are described in Section 2 ("Description of the planned revisions").

      __ Description of the planned revisions__

      Reviewer 1 Major comment 1

      “Finally, several aspects of the data presentation are currently difficult to reconcile. In Fig. 1D, the meaning of the purple category is unclear, and the percentage scaling on the x-axis is difficult to reconcile with the cumulative values displayed. For instance, the sum of all the bars would not reach 100%, as the values of the bars span percentages up to 4% at most (for 105 MYO KZFPs) according to this plot. Similarly, the reported numbers of TE-binding KZFPs in Fig. 1E-F and Fig. S1D appear internally inconsistent and should be clarified. Specifically, 53+14=67 KZFPs are reported to bind TEs in total, yet a larger number of KZFPs appears associated with individual TE families (e.g., 86 for LTR.ERV1). If the values shown correspond to percentages rather than absolute counts, this should be explicitly clarified in both the figure and legend. In addition, Fig. S1D appears inconsistent with the counts reported in Fig. 1E-F, as only 5 out of the 53 toxic KZFPs displayed in the plot show no enrichment for any of the highlighted TE families.”

      We thank the reviewer for this insightful comment, which has helped us identify areas where the presentation of our data can be substantially improved. We agree that the current presentation of the TE-binding analyses could be clearer and that revising these figures will improve both their readability and the overall consistency of the manuscript. In the revised manuscript, we will clarify the apparent inconsistencies in the presentation of the TE-binding KZFP analyses and revise the corresponding figures and legends accordingly. Importantly, these inconsistencies do not arise from errors in the underlying data but rather from an insufficient explanation of the statistical enrichment analyses and the way the results are represented. We will therefore redesign the relevant figures and expand their legends to more clearly describe the analytical approach, the enrichment criteria, and the interpretation of the results. We believe that these revisions will improve the clarity, transparency, and internal consistency of the manuscript, allowing readers to more readily interpret the TE-binding analyses. Minor comments of the reviewer 1 were extremely useful to detect mistakes and we are grateful for that. All the modifications that were asked see below were included in the manuscript.

      Reviewer 1 Major comment 2

      “Finally, while the proteomics results aimed at identifying SCAN-dependent interactors are of interest, several aspects of the experimental design and data analysis remain unclear. In particular, it is not specified whether the experiment was performed in biological replicates or as a single measurement. This is important, as it directly affects how the data can be interpreted and how stringent downstream filtering can be. In the Results section, the authors state that "we identified a set of SCAN-dependent interactors, i.e., proteins that co-immunoprecipitated with the full-length construct but were absent in controls and lost upon deletion of the SCAN domain," which suggests a relatively binary, "presence/absence" filtering strategy. However, this description does not specify whether any quantitative threshold (e.g., enrichment ratio) was applied when comparing full-length constructs to deletion mutants. In contrast, the Methods section states that "proteins lacking signal above background were excluded and proteins were additionally required to show stronger signal in at least one bait condition than in GFP controls based on heatmap clustering (see script)," which instead suggests that a threshold-based criterion was used to define enrichment relative to controls and deletion mutants. If this is the case, the exact criteria and thresholds used for filtering should be clearly stated and consistently reported between the Results and Methods sections. If replicate measurements were not performed, this should be explicitly acknowledged, as peptide-level variability may substantially influence the identification of high-confidence interactors, particularly if the applied cutoffs are not highly stringent.”

      We agree that a more detailed description of the experimental design and analysis strategy, together with additional validation, will strengthen the interpretation of the proteomic data. In the revised manuscript, we expanded the Results and Materials and Methods sections to provide a clearer and more quantitative description of the filtering strategy, including the enrichment criteria and thresholds used to define SCAN-dependent interactors. To further strengthen these findings, we propose to perform an independent biological replicate of the co-immunoprecipitation mass spectrometry experiment. This additional experiment will increase confidence in the identified SCAN-dependent interactors and further support the conclusions drawn from the proteomic analysis.

      Reviewer 1 Minor comments

      • In Fig. 2A, readability could be improved by adjusting the layering of points, as the darker dots (in particular the red ones) are currently obscured by lighter ones. Alternatively, removing the outline of the points (which is not transparent) may also improve visibility, but in that case the legend for point size would need to be updated accordingly.

      Thank you for this helpful suggestion. We will revise Figure 2A to improve its readability by reworking the layering of the points in accordance with the reviewer's recommendation. We will also evaluate the point outlines and, if appropriate, remove them and update the point-size legend accordingly to ensure the figure is clear and easy to interpret.

      Reviewer 2 – Major comment

      “- The authors looked at available chromatin data in either K562 cells or HEK293 cells, which I think is a very good way of utilizing publicly available data. Since the authors showed that different KZFPs might be functionally relevant in different cell types/tissues, I was wondering if they checked if there is available ChIP Seq or CUT&RUN data in those specific cell types/tissues. If yes, that data should be included in the manuscript.”

      We agree that integrating KZFP binding data generated in biologically relevant cell types or tissues would further strengthen the proposed regulatory models. As described in the revised manuscript, we have already adopted this approach for ZNF43 by integrating chromatin landscape data from thymus and liver, where suitable datasets were available.

      To further address this point, we propose to systematically explore publicly available ChIP-seq, CUT&RUN, CUT&Tag, and related chromatin profiling datasets for the other KZFPs investigated in this study. Where suitable datasets are available, these analyses will be incorporated into the revised manuscript to further support the proposed tissue-specific regulatory models and provide additional biological context for the identified target genes.

      __ Description of the revisions that have already been incorporated in the transferred manuscript__

      Reviewer 1 Major comment 1

      “The large-scale overexpression screen represents the foundation of the manuscript and provides a potentially valuable resource for prioritizing candidate KZFPs for downstream study. However, several aspects of the experimental setup and data presentation currently limit the interpretation of the reported proliferation defects. First, key details regarding the screening workflow remain unclear. While the Methods section describes the overall procedure, it is difficult to determine when cells were seeded relative to doxycycline induction, in which plate format the cells were maintained throughout the experiment, and whether medium exchange was performed during the 9-day assay. These points are particularly relevant given the use of suspension K562 cells (which can complicate medium exchange in a 96-well plate format and make long-term culture more difficult to control) and a metabolic viability readout (PrestoBlue), as differences in nutrient depletion or overgrowth could also influence the signal independently of reduced proliferation or toxicity. Additional clarification regarding seeding density, timing of induction, plate format, culture handling throughout the assay, and whether cell morphology/density was visually monitored would substantially improve interpretability and reproducibility. Second, it is unclear whether the observed proliferation phenotypes may be influenced by differences in transgene expression levels or integration effects. Were all constructs validated for comparable expression following induction? In the absence of such controls, it remains difficult to determine whether the reported phenotypes reflect specific KZFP activities or differences in overexpression efficiency. While it may not be possible to conclusively distinguish KZFP-specific effects from toxicity associated with high transgene expression levels, this limitation should at least be acknowledged. In addition, the possibility that some phenotypes may be influenced by transgene integration effects should also be considered. Unless independent transductions were validated for the KZFPs classified as toxic, it remains difficult to exclude integration-site-specific contributions to the observed proliferation defects. Third, the normalization strategy would benefit from additional clarification. In Fig. S1A, the LacZ control appears variably affected by doxycycline treatment across plates, whereas the GFP control appears more stable. Since normalization relies on the mean behavior of both controls within each batch and condition, the authors should clarify whether this variability could influence hit calling.”

      We agree that additional methodological details improve the clarity and reproducibility of the screening assay. Accordingly, we substantially expanded the Materials and Methods section to describe the experimental workflow, quality controls, data normalization, and hit-calling criteria. The revised paragraph is reproduced below.

      Arrayed overexpression screen

      To systematically assess the effect of human KZFP overexpression on cellular fitness, K562 cells were individually transduced with doxycycline-inducible lentiviral vectors encoding 366 human KZFPs. Lentiviral particles were produced as described above and used to transduce cells without MOI calculation. __Instead, a fixed volume of viral supernatant (200µL per × 104 cells in 48 well plate filled with 200ul of RPMI) was used for all transductions to ensure comparable experimental conditions. Transduced cells were selected with puromycin before doxycycline induction. Following puromycin selection (1µg/mL for 3 days), cells were seeded at 20 000 cells per well in 24-well plates filled with 1ml of medium in technical triplicate for each KZFP. Following puromycin selection and prior to doxycycline induction, cell survival was visually assessed as a quality control metric for each KZFP construct (Supp __Table 2____). Doxycycline (1µg/mL) was added immediately after cell seeding to induce expression of the HA-tagged KZFPs. At each time point, metabolic activity was measured using PrestoBlue™ reagent according to the manufacturer's instructions (10µL reagent added to 100µL culture medium, incubated for 3h in a 96 plates). Absorbance was recorded at 570 nm and 600 nm using a plate reader (Hidex Sense Microplate Reader), GFP- and LacZ-expressing control wells were included on every plate to account for plate-to-plate and batch-to-batch variability. Peripheral wells were filled with culture medium to minimize evaporation-induced edge effects. Cells were maintained in RPMI supplemented with 10% fetal bovine serum (FBS) and 1× penicillin–streptomycin, and splited (1/10) with aspiration of the surface medium every three days throughout the assay while maintaining doxycycline at 1µg/mL. Cell proliferation was assessed after 4, 7, and 9 days of induction. and the A570/A600 ratio was used as a surrogate measure of viable cell number and proliferative capacity. For computational normalization, raw A570/A600 values were first background-corrected by subtracting the signal from medium-only controls and then normalized in two steps. First, each value was divided by the mean signal obtained from the GFP and LacZ control wells from the corresponding batch and induction condition to correct for inter-batch variability. Second, the resulting value was normalized to the corresponding −Dox condition for the same KZFP and time point to correct for seeding variability, yielding a relative proliferation score that reflects the effect of KZFP induction. KZFPs with a normalized proliferation score ≤ 0.85 at day 9 were arbitrarily classified as proliferation-impairing hits in this screening framework.

      After doxycycline induction, dot blot analysis using anti-HA and anti-actin antibodies was systematically performed to assess KZFP expression and sample loading, respectively (Supplementary DotBlot.pdf). The HA signal following doxycycline induction (HA_Dox) and actin signal following doxycycline induction (Actin_Dox) were visually scored from the dot blot signals (__Supp __Table 2).

      In addition, to strengthen the methodological description and address these concerns more directly, we will:

      1/ Include a supplementary table summarizing our experimental observations for each individual KZFP throughout the screening process (See preliminary Supp Table 2). -> See header here:

      2/ Perform and include Dot Blot analyses, to assess and compare transgene expression levels across KZFP constructs. (Supplementary File DotBlot.pdf____). Generation of these files is in progress, with a few missing dot blots still being completed (we have done 303 over 366 already). However, preliminary versions have already been submitted. -> See header of the .pdf here:

      In addition, we agree that a more explicit discussion of the limitations of our screening approach improves the interpretation of our findings. Accordingly, we expanded the Discussion to address the limitations associated with variable transgene integration, heterogeneous transgene expression, potential toxicity due to ectopic KZFP overexpression, and the use of K562 cells as a standardized rather than physiological cellular model.

      “Several methodological considerations should be taken into account when interpreting these results. As with any lentiviral overexpression screen, three potential sources of technical variability may influence the observed phenotypes: differences in transgene integration sites, heterogeneity in transgene expression levels, and non-specific toxicity resulting from ectopic overexpression. Variable integration sites are unlikely to represent a major source of bias in the present study because all analyses were performed on polyclonal populations of transduced cells rather than individual clones, thereby averaging integration-site effects across many independent events. In contrast, heterogeneity in transgene expression levels is expected, as the abundance of each KZFP depends not only on transduction efficiency but also on intrinsic differences in mRNA stability, translational efficiency, and protein stability. To minimize these sources of variability, all constructs underwent systematic quality control, including assessment of cell survival following puromycin selection and evaluation of transgene expression by HA dot blot after doxycycline induction. Although transgene expression levels varied across KZFPs (Supplementary File DotBlot.pdf), this variability showed no systematic relationship with the proliferation phenotypes, suggesting that differences in overexpression efficiency are unlikely to be the primary determinant of toxicity. Nevertheless, ectopic expression exposes cells to supraphysiological concentrations of KZFPs capable of generating non-physiological interactions or regulatory effects. Therefore, while the screening strategy is well suited for identifying candidate functional regulators, independent validation under endogenous expression conditions remains essential to confirm KZFP-specific functions.”

      Reviewer 1 Major comment 2:

      “A central conceptual issue throughout the manuscript is that the downstream functional analyses of the selected KZFPs remain largely disconnected from the original screening phenotype. The four candidates were prioritized based on proliferation defects observed upon overexpression in K562 cells; however, the subsequent analyses (with the only exception being a more in-depth experimental analysis of ZNF498 in ciliogenesis, which stands out as comparatively more directly supported by experimental evidence) primarily rely on correlative expression patterns and KZFP ChIP-seq datasets to infer potential biological functions in unrelated cellular contexts. As a result, it remains unclear whether the proposed transcriptional programs are mechanistically linked to the proliferation phenotypes that motivated candidate selection in the first place. This issue is evident across multiple sections of the manuscript. For example, the proposed role of ZNF43 in regulating fatty acid metabolism and detoxification pathways is primarily inferred from tissue-level expression correlations. While these analyses focus on genes identified as potential ZNF43 targets, the underlying ChIP-seq datasets were themselves generated under ZNF43 overexpression conditions. Therefore, the current analyses do not establish whether ZNF43 regulates these pathways under physiological expression levels or within a relevant cellular context, nor how such regulation relates to the proliferation defect observed in K562 cells. Moreover, several proposed target genes remain substantially expressed in tissues where ZNF43 expression is not particularly low (e.g., kidney and heart muscle), suggesting that additional regulators are likely involved. Similarly, the proposed model of ZNF257-mediated regulation of MAGEA genes during spermatogenesis is intriguing but does not fully account for the expression behavior of all MAGEA family members, particularly MAGEA2B, which displays strong expression in spermatocytes despite high ZNF257 expression. This expression pattern should be acknowledged in the main text and reflected in Fig. 3K. In addition, the labels for MAGEA6 and MAGEA2B in Fig. 3C appear to be inverted. More broadly, the proposed regulatory model is difficult to reconcile with the generally restricted expression pattern of MAGEA genes across adult tissues, as their expression does not appear to consistently correlate with ZNF257 levels outside the germline context. Related concerns also apply to the analyses of ZNF498 and ZNF18, where the proposed functions in cilium formation and sperm maturation remain disconnected from the proliferation defects identified in the initial screen.”

      We agree that this comment raises an important conceptual point and has helped us clarify the scope of the study and the interpretation of our findings. In the revised manuscript, we explicitly distinguish hypothesis generation from mechanistic validation by clarifying that the proliferation phenotype observed in K562 cells reflects the regulatory potential of ectopically expressed KZFPs rather than their physiological functions. We also adopted a more cautious interpretation of the functional analyses, emphasizing that the proposed regulatory networks are hypothesis-generating and that individual KZFPs are unlikely to act as sole regulators. More broadly, we emphasize that the primary objective of this study is to establish a scalable screening platform for prioritizing KZFPs and identifying biologically relevant contexts for future investigation, rather than to provide a comprehensive functional characterization of individual KZFPs. We agree that this comment highlights an important limitation of our proposed regulatory model. In the revised manuscript, we adopted a more nuanced interpretation by presenting ZNF257 as a contributor to, rather than the sole regulator of, the MAGEA transcriptional program, and by explicitly discussing the exceptions identified by the reviewer.

      Modification in the revised manuscript:

      1/

      “Integrative transcriptomic, chromatin and proteomic analyses reveal diverse mechanisms, including transposable element–linked repression (ZNF43), promoter-proximal regulation (ZNF257), and SCAN domain–dependent transcriptional activation (ZNF498/ZSCAN25 and ZNF18).”

      Is now:

      “Integrative transcriptomic, chromatin and proteomic analyses identify distinct regulatory properties and generate testable hypotheses regarding diverse mechanisms, including transposable element-associated repression (ZNF43), promoter-proximal regulation (ZNF257), and SCAN domain-dependent transcriptional activation (ZNF498/ZSCAN25 and ZNF18).”

      2/

      “Detailed follow-up of four such candidates, ZNF43, ZNF257, ZNF498 and ZNF18, revealed as hypothesized distinct modes of action, ranging from TE-linked transcriptional repression to promoter-proximal gene silencing and SCAN domain-mediated transcriptional activation. These findings reinforce the view that KZFPs, while often viewed as a homogeneous family of TE-repressive TFs, are rather functionally diverse regulators with wide-ranging impacts on human biology.”

      Is now:

      “Detailed follow-up of four such candidates, ZNF43, ZNF257, ZNF498 and ZNF18, identified distinct regulatory properties and generated hypotheses regarding their physiological functions. By integrating overexpression-induced transcriptional responses, chromatin occupancy, proteomic analyses and tissue-specific expression data, we propose candidate biological contexts in which these KZFPs may operate. These hypotheses now provide a framework for future mechanistic studies performed under physiological conditions. Together, these findings reinforce the view that KZFPs, while often viewed as a homogeneous family of TE-repressive transcription factors, comprise functionally diverse regulators with broad potential roles in human biology.”

      3/

      “We conclude from these data that ZNF43 regulates a transcriptional program related to fatty acid metabolism and detoxification, allowing for the preferential expression of its effectors in the liver (Fig. 2G). Interestingly, neither expression nor chromatin state followed the same pattern at the functionally unrelated DNAI4 locus, indicating that this gene is subjected to other dominant regulators.”

      Is now:

      “Together, these observations identify a small set of candidates ZNF43 target genes involved in fatty acid metabolism and detoxification and suggest that ZNF43 may contribute to the regulation of these transcriptional programmes in appropriate physiological contexts (Fig. 2G). However, these conclusions are derived from overexpression-based datasets and tissue-level expression analyses and should therefore be considered hypothesis-generating. Interestingly, neither expression nor chromatin state followed the same pattern at the functionally unrelated DNAI4 locus, indicating that additional regulatory mechanisms contribute to the control of these genes.”

      4/

      “It strongly suggests that ZNF257 contributes to initiating the transcriptional repression of these two MAGEA genes during early spermiogenesis, after which their silencing may be stabilized through stable epigenetic mechanisms such as DNA methylation.”

      Is now:

      “These observations suggest that ZNF257 may contribute to the initiation of transcriptional repression of a subset of MAGEA genes during the spermatogonia-to-spermatocyte transition, after which their silencing may be stabilized through epigenetic mechanisms such as DNA methylation.”

      5/

      “Together, these results identify ZNF498 as a transcriptional activator of gene modules controlling cytoskeleton-dependent processes and suggest that this TF may act as a regulator of neuronal cytoskeletal architecture, warranting investigation in relevant neural models.”

      Is now:

      “Together, these results indicate that ZNF498 functions as a transcriptional activator in our overexpression system and support the hypothesis that it contributes to transcriptional programmes controlling cytoskeleton-dependent processes in physiologically relevant neural contexts, warranting further investigation in dedicated neural models.”

      6/

      “The co-expression of ZNF18 and its target genes at the spermatid stage suggests that ZNF18 activates a transcriptional program supporting these processes.”

      Is now:

      “The co-expression of ZNF18 and its candidate target genes at the spermatid stage is consistent with the hypothesis that ZNF18 contributes to transcriptional programmes supporting these processes.”

      7/

      “The four KZFPs characterised here illustrate this diversity. ZNF43 represses a coherent set of genes involved in fatty acid metabolism and detoxification through binding to nearby LTR/ERV1 integrants, with its expression anticorrelating that of its targets: i.e., highly expressed in thymus and bone marrow, where these metabolic genes are silent, and lowly expressed in liver, where they are most active. This represents a clear example of host genomes coopting TE-derived sequences and shaping their regulatory activities in a cell-type specific manner by the differential expression of KZFPs. ZNF257, by contrast, acts as a promoter-proximal repressor whose targets show accelerated sequence evolution at their promoters, consistent with integration into a KZFP-orchestrated GRN through rapid promoter diversification, a feature previously described for KZFPs (Farmiloe et al., 2023). Its regulation of the MAGEA gene cluster exemplifies a distinct evolutionary mechanism: an ancestral intronic binding site, present in MAGEA6 gene body, before ZNF257 emerged, was propagated across the cluster through tandem duplication, enabling coordinated regulation of multiple paralogs. Temporal expression analysis during spermatogenesis further suggests that ZNF257 initiates MAGEA repression at the spermatogonia-to-spermatocyte transition, after which silencing may be maintained through epigenetic mechanisms such as DNA methylation. ZNF498 and ZNF18, both SCAN-containing KZFPs with variant KRAB domains, on the other hand acted as transcriptional activators. ZNF498 activates a programme centred on microtubule cytoskeleton organisation, as demonstrated by the disruption of ciliogenesis upon its overexpression, and both ZNF498 and its targets are broadly expressed in the central nervous system, particularly in excitatory neurons where microtubule dynamics are essential for axonal architecture. ZNF18 similarly activates genes involved in chromatin remodelling and cytoskeletal reorganisation at the spermatid stage, processes that are hallmarks of spermiogenesis. Together, these case studies demonstrate that even within a single screen, KZFPs with fundamentally different regulatory logics can be identified through a single unifying phenotype and then mechanistically dissected to uncover their unique properties.”

      Is now:

      “The four KZFPs characterized here illustrate the functional diversity that can be uncovered using this screening strategy. For ZNF43, integration of overexpression transcriptomics with ChIP-exo binding data identified a small set of candidate direct target genes located near LTR/ERV1 elements. Their tissue-specific expression patterns are consistent with the hypothesis that ZNF43 contributes to transcriptional programmes associated with fatty acid metabolism and detoxification, although these analyses, which rely on overexpression-derived datasets and tissue-wide correlations, do not establish physiological regulation or causality. Rather, they identify a candidate regulatory network whose functional relevance will require investigation in appropriate biological models. More generally, these observations support the concept that host genomes may exploit TE-derived regulatory sequences in a tissue-specific manner through differential KZFP expression, while recognizing that additional transcription factors almost certainly participate in controlling these gene expression programmes. Similarly, ZNF257 emerged as a promoter-associated transcriptional repressor in our overexpression system. Evolutionary analyses suggest that tandem duplication propagated an ancestral ZNF257-binding sequence across the MAGEA locus, generating the hypothesis that ZNF257 may contribute to coordinated regulation of this gene cluster during spermatogenesis. The temporal expression profiles of ZNF257 and the MAGEA genes are compatible with such a model but remain correlative and therefore require direct functional validation. ZNF498 and ZNF18, two SCAN-containing KZFPs with variant KRAB domains, displayed transcriptional activation rather than repression following overexpression. For ZNF498, the integration of transcriptomic analyses with expression profiling pointed to microtubule cytoskeleton organization as a candidate biological process, a prediction that was further supported experimentally by the marked impairment of ciliogenesis following ZNF498 overexpression in hTERT-RPE1 cells. This represents the strongest functional validation presented in this study and supports the biological relevance of the analytical framework developed here. For ZNF18, the co-expression of the KZFP and its candidate target genes during spermatogenesis is consistent with the hypothesis that it contributes to transcriptional programmes involved in chromatin remodelling and cytoskeletal reorganization during spermatid differentiation. Together, these case studies illustrate how a standardized overexpression screen can identify KZFPs with distinct regulatory properties and generate biologically coherent hypotheses regarding their physiological functions. Rather than establishing definitive functions for individual KZFPs, this framework prioritizes candidates, proposes relevant cellular contexts, and provides a foundation for future mechanistic studies performed under physiological conditions.”

      “In addition, interpretation of the SCAN-deletion experiments is complicated by the reduced expression levels of the deletion constructs relative to the corresponding full-length proteins, making it difficult to determine whether the observed proliferation phenotypes are pathway-specific or partially driven by differential expression.”

      We thank the reviewer for this important observation and agree that differences in expression levels between the full-length and ΔSCAN constructs could complicate the interpretation of the observed phenotypes. To address this concern, we performed a quantitative comparison of the expression levels of full-length and ΔSCAN proteins using both western blotting and transgene expression using RNAseq, while accounting for differences in transgene length. This result are now added in (Fig S6C, D).

      With modification of the legend:

      • HA signal after OE of HA-tagged ZNF18, ZNF18∆SCAN, ZNF498, ZNF498∆SCAN or GFP in K562 cells. Actin as control.
      • Quantification of ZNF18, ZNF18∆SCAN, ZNF498, ZNF498∆SCAN It appears that the difference is small (Minor comments of the reviewer 1

      “- In the Abstract and in the "Limitations of the study" section, the term "annotation" is used. It would be preferable to specify "functional characterization" instead of "annotation".

      Done as suggested by the reviewer.

      • In the Introduction, there may be a minor citation confusion. Following the sentence: "Characterized by an N-terminal KRAB domain and a C-terminal tandem array of C2H2 zinc fingers, KZFPs primarily target transposable element (TE)-embedded sequences," the cited references are predominantly experimental studies supporting this statement. However, the inclusion of the review "Bruno, Mahgoub and Macfarlan, 2019" appears less appropriate in this context, as it does not directly present ChIP-seq data supporting this claim. More relevant primary studies from the same research area include "Wolf et al. 2020" and "Bruno et al. 2025.".

      Done as suggested by the reviewer.

      • In Fig. 1A, "D10" appears inconsistent with the text and other figures (Fig. 1B, 1G, 1H), which refer to 9 days post-induction.

      Done as suggested by the reviewer.

      • In Fig. S1, there may be a mismatch in the highlighted plate: the zoomed image appears to correspond to the first plate from the top. The correct plate should be highlighted for consistency.

      Done as suggested by the reviewer.

      • In Fig. 1B, there is a typographical error ("K ZFPs" instead of "KZFPs").

      Done as suggested by the reviewer.

      • In Fig. S1E, it is unclear what "other" refers to. Please clarify whether this represents the mean of all remaining KZFPs or a defined subset, ideally in the figure description.

      Done as suggested by the reviewer.

      • In Fig. S2E, "SetDB1" should be corrected to "SETDB1".

      Done as suggested by the reviewer.

      • In Fig. 3B, it is unclear what distinguishes the upper and lower "Diverse REs". A brief clarification in the figure legend would improve interpretability, particularly regarding the transposable element families included.

      Done as suggested by the reviewer.

      • In Fig. S3C, the x-axis labels appear slightly misaligned and shifted to the right.

      Done as suggested by the reviewer.

      • In Fig. 3C, the labels for MAGEA6 and MAGEA2B appear to be inverted.

      Done as suggested by the reviewer.

      • In Fig. 3K, "MAGE3" should be corrected to "MAGEA3".

      Done as suggested by the reviewer.

      • In the ZNF498 section, line 4, the punctuation should be corrected so that the period appears after the figure reference ("promoters (Fig. S1E).").

      Done as suggested by the reviewer.

      • In the final sentence of the ZNF498 section, a noun appears to be missing after "cytoskeleton-dependent," possibly "processes".

      Done as suggested by the reviewer.

      • In the last section of the Results and corresponding figures and their descriptions, "SCAN dependant" should be corrected to "SCAN-dependent".”

      Done as suggested by the reviewer.

      Major comments of the reviewer 2

      “- The authors chose four KZFPs to study in detail, but why they chose these 4 candidates is unlcear to me. It would be nice to add a more detailed description of the process by which they chose the four candidates.”

      We agree that the rationale for selecting the four KZFPs should be presented more explicitly. Accordingly, we revised the manuscript to clarify the selection criteria.

      “However, a modest correlation was noted between the number of transcription start sites (TSS) bound by KZFPs and the drop in PrestoBlue signal induced by their overexpression (Fig. 1G), and SCAN-containing KZFPs (SKZFPs) tended to induce proliferation defects more frequently than family members lacking this domain (Fig. 1H).”

      Is now:

      “However, a modest correlation was noted between the number of transcription start sites (TSS) bound by KZFPs and the drop in PrestoBlue signal induced by their overexpression (Fig. 1G), and SCAN-containing KZFPs (SKZFPs) tended to induce proliferation defects more frequently than family members lacking this domain (Fig. 1H). These observations indicated that KZFPs affecting proliferation do not constitute a homogeneous functional group, prompting us to select representative candidates spanning the evolutionary, structural, and genomic diversity of the KZFP family for mechanistic characterization.____”

      “- The materials and methods part of the manuscript is not detailed enough for other researchers to reproduce the study. They should add more details to both experiments and data analysis part of this section. Below I highlight some examples for sake of clarity, but the authors should revise the whole materials and methods section and add more details keeping these examples in mind:

      • The authors do not state the titer of lentiviral vectors they generate nor the MOI or amount of virus they use to transduce the cells

      • In many cases, the specific softwares and the software version is not stated e.g., the analysis of the Gene Ontology Biological Processes

      • It would be beneficial for the readers to get more details about the construct they used, for example a map of the plasmid.

      • It is unclear how many cells were used for RNA extraction

      • It is unclear which microscopes were used for imaging.

      • The concentration of antibodies used for staining and the product number, and provider of the antibody is not always depicted.”

      We agree that the additional methodological details requested by the reviewer will improve the reproducibility and transparency of the study. Accordingly, we have expanded the Methods section to provide a more detailed description of the experimental procedures and data analysis workflow.

      “Lentiviral particles were produced in HEK293T cells by transient co-transfection of transfer, packaging and envelope plasmids. Cells were transfected at approximately 70–80% confluence using a standard lipid-based transfection reagent. Viral supernatants were collected 48 h after transfection, cleared by centrifugation, filtered through 0.22-µm membranes, and used fresh or stored appropriately until use. Recipient K562 or hTERT-RPE1 cells were transduced under conditions optimized for efficient gene delivery.”

      Is now:

      “Lentiviral particles were produced in HEK293T cells. 105 cells were seeded in 24 well plates filled with 1ml DMEM the day before transfection. Cells were co-transfected individually with 0.15ug of each plasmids encoding KZFPs tagged with HA (pTRE-KZFPX-HA-PGK-puro), 0.1ug of the packaging plasmid (pR8.74) and 0.07ug of the envelope plasmid (pMD2G) using TransIT®-LT1 Transfection Reagent (MIR 2306), according to the manufacturer's instructions. Viral supernatants were harvested 24h after transfection, clarified by centrifugation, filtered through 0.45-µm filters and used immediately.”

      “Coding sequences were cloned into doxycycline-inducible lentiviral transfer vectors designed to express N-terminally HA-tagged proteins.”

      Is now:

      “Coding sequences corresponding to 366 human KZFP open reading frames were codon-optimized for human expression and cloned into doxycycline-inducible lentiviral transfer vectors expressing C-terminal HA-tagged proteins under the control of a tetracycline-responsive promoter pTRE-KZFPX-HA-PGK-puro. All expression constructs used in the primary overexpression screen have been deposited and are publicly available (De Tribolet et al., 2023). A schematic representation of the lentiviral expression cassette, including the promoter, HA tag, cloning site, antibiotic resistance cassette, and regulatory elements, is provided in Supplementary file. Selected constructs encoding ZNF43, ZNF257, ZNF498 and ZNF18 were used for follow-up mechanistic studies. For SCAN-domain functional analyses, deletion constructs lacking the SCAN domain (ΔSCAN) were generated for ZNF18 and ZNF498 in the same lentiviral backbone. Deletion were done using In-Fusion cloning with specific primers. PCR was performed with high-fidelity polymerase, followed by gel purification and recombination with the linearized plasmid using the In-Fusion HD Cloning Kit (Takara Bio©) according to the manufacturer’s protocol. The product was transformed into HB101 Escherichia coli cells, and colonies were screened by PCR. Positive clones were verified by Sanger sequencing, and confirmed plasmids were propagated and purified for further use.”

      “Total RNA was extracted...”

      Is now:

      “For each biological replicate, approximately 1 × 10⁶ K562 cells were harvested 72 h after doxycycline induction. Total RNA was extracted…”

      “Images were acquired by fluorescence microscopy under identical conditions across samples.”

      Is now:

      “Images were acquired using a confocal microscope Leica-SP8 (Leica Biosystems) with an objective HC PL APO 63x/1.40 and a pinhole size of 1 AU, using identical acquisition settings for all conditions. Images were processed using Fiji/ImageJ (version 2.9.0) without nonlinear intensity adjustments.”

      “Cells were fixed and stained with antibodies against ciliary markers (ARL13B)”

      Is now:

      “Cells were fixed in 4% paraformaldehyde, permeabilized with 0.1% Triton X-100, blocked with 2% BSA, and incubated with rabbit anti-ARL13B (Proteintech, Cat. No. 17711-1-AP, 1:200) followed by Alexa Fluor 568-conjugated donkey anti-rabbit IgG (Thermo Fisher Scientific, Cat. No. A-10042, 1:1000). Nuclei were stained with Hoechst (1 µg/mL).”

      “- The authors mention that KZFPs are usually expressed at a low level in the K562 cell line they use, but there is no figure showing the expression level of KZFPs in this cell type. It would be important to see the baseline KZFP expression in these cells, the level of overexpression and compare it to the endogenous expression levels they show in different cell types/tissues, at least for the four candidates studied more in depth. This would help to understand whether this level of activity is something that could occur naturally in a physiologically relevant context.”

      We thank the reviewer for this insightful suggestion and fully agree that providing additional context regarding endogenous and ectopic KZFP expression levels will help readers better assess the physiological relevance of our findings. As suggested, we included data showing the baseline expression levels of the four selected KZFPs in K562 cells together with the expression levels achieved following doxycycline-induced overexpression. We also compared these values with publicly available transcriptomic data from cell lines. Importantly, only cell lines are assessed as we need ground through (K562) to estimate transgene expression. We modified Fig. S2, Fig. S3, Fig. S4 and Fig. S5 to add the results of these analysis. Here is ZNF43 as an example:

      With the following legend:

      “(C) Distribution of endogenous expression levels, (using GFP control cells), of all expressed genes (light grey) and all KZFPs (dark grey) in K562 cells. The solid red line indicates endogenous ZNF43 expression in GFP control cells, whereas the dashed red line indicates the corrected transgene expression following doxycycline induction.

      (D) Endogenous ZNF43 expression across Human Protein Atlas cell lines, (https://www.proteinatlas.org/about/download#cell_line), following normalization to the local RNA-seq dataset. K562 cells are highlighted in red. The dashed red line indicates the corrected transgene level measured following doxycycline-induced overexpression in K562 cells overexpressing ZNF43.”

      Modified the result section:

      “ZNF43 is a ~43-million-year-old KZFP with a canonical TRIM28-recruiting KRAB domain and 19 zinc fingers that preferentially recognize an LTR/ERV1-embedded sequence (Fig. S1F). We first verified that ZNF43 overexpression impaired the growth of K562 cells (Fig. S2A, B). Endogenous ZNF43 expression was readily detectable in K562 cells and across human cell lines (Fig. S2C, D). Following doxycycline induction, transcript abundance markedly increased and exceeded the highest endogenous expression level observed among the analyzed cell lines (Fig. S2C, D).”

      We also updated the Methods section:

      Quantification of endogenous and transgene expression levels

      Endogenous KZFP expression in K562 cells was estimated from GFP control RNA-seq samples using normalized mean expression values obtained from the differential expression analyses. For ZNF18, whose transgene sequence is identical to the endogenous coding sequence (i.e., not codon-optimized), transgene-derived expression was estimated directly by subtracting the endogenous transcript abundance measured in GFP controls from the total transcript abundance measured following doxycycline induction (OE − GFP). For ZNF43, ZNF257 and ZNF498, the overexpression constructs were synthesized using codon-optimized coding sequences. RNA-seq reads were therefore additionally aligned against the codon-optimized transgene reference sequences to specifically quantify exogenous transcripts without interference from endogenous reads. Because these codon-specific counts are generated through an independent alignment strategy, they are not directly comparable to the endogenous RNA-seq expression values. To calibrate these measurements, a scaling factor was derived from the ZNF18 dataset by comparing the codon-specific read counts with the transgene abundance estimated from the differential expression analysis (OE − GFP). This empirically determined correction factor was subsequently applied to all codon-optimized constructs, thereby expressing transgene abundance on the same scale as the endogenous RNA-seq measurements. Corrected transgene expression values were then used for all downstream comparisons. To compare endogenous expression across physiological contexts, publicly available RNA-seq datasets from the Human Protein Atlas (cell lines) were downloaded and normalized to the local RNA-seq scale. A normalization factor was calculated from the median expression ratio of KZFPs detected in both the Human Protein Atlas K562 dataset and the local K562 GFP control RNA-seq dataset, and subsequently applied uniformly to all Human Protein Atlas datasets. This normalization enabled direct comparison of endogenous expression across biological contexts with the corrected transgene expression values. Global KZFP expression was calculated as the median normalized expression of all annotated KZFPs within each biological context. For the four KZFPs selected for detailed characterization, endogenous expression across Human Protein Atlas cell lines was compared with corrected transgene expression following doxycycline induction. Expression distributions of all genes and KZFPs were visualized using ranked expression plots and density histograms. All analyses were performed in R using the tidyverse package.”

      We fully acknowledge that the overexpression system used in this study was primarily designed as a discovery platform to identify candidate functions, targets, and interaction partners of KZFPs that are otherwise expressed at lower levels in K562 cells. As the reviewer correctly points out, determining whether these regulatory effects occur at endogenous expression levels in physiologically relevant cellular contexts represents an important next step. We Thereby also clarified this in the “Limitations to this study” paragraph:

      “To better place our experimental system into a physiological context, we compared endogenous KZFP expression in K562 cells with publicly available transcriptomic datasets from the Human Protein Atlas. These analyses showed that K562 cells do not exhibit unusually low global KZFP expression compared with other human cell lines. However, consistent with the restricted expression patterns of this protein family, KZFPs as a whole are expressed at substantially lower levels than the average human gene. For the four KZFPs characterized in detail, doxycycline induction produced transcript levels that exceeded the highest endogenous expression observed across the analyzed human cell lines. Accordingly, the overexpression system used in this study was not designed to recapitulate physiological expression levels but rather to maximize the identification of candidate target genes, interacting partners, and regulatory pathways for KZFPs that are otherwise expressed at low endogenous levels. Consequently, the molecular interactions identified here should be considered as hypotheses requiring validation under endogenous expression conditions in physiologically relevant cellular models.”

      “- RNA seq analysis: It is unclear how many cells were used in the RNA seq analysis, I would like to ask the authors to clarify that. Moreover, from my understanding the RNA seq analysis was done on day 3, while the Presto Blue analysis was done on days 4, 7 and 9. I would like to kindly ask the authors to motivate their choice for the day of the RNA sequencing analysis.”

      We agree that this information required clarification. The Methods section has been revised to specify the number of cells used for RNA-seq library preparation and to explain the rationale for performing RNA-seq after 3 days of doxycycline induction, before measurable proliferation defects emerge, in order to capture primary transcriptional responses to KZFP overexpression. The corresponding modification has also been added to the Results section when introducing the RNA-seq analyses.

      “For transcriptome profiling, K562 cells expressing the indicated inducible constructs were treated with doxycycline for 72 h before harvest. Total RNA was extracted using the NucleoSpin RNA plus kit (Macherey-Nagel) according to the manufacturer’s recommendations. RNA quantity and purity were assessed by spectrophotometry, and RNA integrity was evaluated before library preparation.”

      Is now:

      “For transcriptome profiling, 1 × 10⁶ K562 cells expressing the indicated inducible constructs were treated with doxycycline for 72 h before harvest. RNA was collected after 3 days of induction to capture the primary transcriptional responses to KZFP overexpression before substantial differences in proliferation became apparent. This early time point was chosen to minimize secondary transcriptional changes resulting from altered cell growth, cell-cycle distribution, or cellular stress, which become detectable in the proliferation assays performed after 4, 7, and 9 days of induction. Total RNA was extracted using the NucleoSpin RNA plus kit (Macherey-Nagel) according to the manufacturer’s recommendations. RNA quantity and purity were assessed by spectrophotometry, and RNA integrity was evaluated before library preparation.”

      “We then profiled the transcriptome of K562 cells overexpressing ZNF43 by deep RNA sequencing (RNA-seq)”

      Is now:

      “We then profiled the transcriptome of K562 cells overexpressing ZNF43 by deep RNA sequencing (RNA-seq) after 3 days of doxycycline induction, a time point selected to capture primary transcriptional responses before the onset of measurable proliferation defects.”

      Minor comments of the reviewer 2

      “- Figure S1D is not mentioned in the text before figure S1E. The order of the panels should be changed in the figure.

      Done as suggested by the reviewer.

      • "We selected genes that were downregulated upon ZNF43 overexpression and harboured a ZNF43 binding site within 10kb of their TSS (Fig. 1A) - don't the authors mean Fig. 2A?

      Done as suggested by the reviewer.

      • In Figure 4D, the GO terms cannot be read, as the sentences seem to be cut.

      Done as suggested by the reviewer.

      • All figures and figure legends need to be revised. In some cases, the letter size is too small, or the legend and explanation of colours is missing. Please see some examples below: Fig. S6C, Fig 6C, Fig S4C, Fig S5C (letter size too small) Fig S6G, Fig 4E (label/scale is missing)”

      Homogenized to Arial 6 by default as requested by most of journal guidelines

      __ Description of analyses that authors prefer not to carry out__

      We think that by proceeding as described above we will have addressed all major conceptual issues raised by the reviewers.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      Foley et al establishes a scalable framework to probe KZFP function. They performed an array of inducible overexpression screen of 366 human KZFPs in K562 cells. This screen, together with the analysis of transcriptomic and available chromatin and proteomic datasets revealed that KZFPs regulate many different mechanisms, highlighting the functional diversity of KZFPs. Understanding this functional diversity is a very interesting, timely and relevant question, but it is also challenging to study. Therefore, the approach the authors develop is promising. While the quality of the experiments and data analysis is high, the weakness I see in the manuscript is the lack of major biological insights in relevant model systems. Please see my detailed comment in the significance part.

      Major comments

      • The authors chose four KZFPs to study in detail, but why they chose these 4 candidates is unlcear to me. It would be nice to add a more detailed description of the process by which they chose the four candidates.
      • The materials and methods part of the manuscript is not detailed enough for other researchers to reproduce the study. They should add more details to both experiments and data analysis part of this section. Below I highlight some examples for sake of clarity, but the authors should revise the whole materials and methods section and add more details keeping these examples in mind:
        • The authors do not state the titer of lentiviral vectors they generate nor the MOI or amount of virus they use to transduce the cells
        • In many cases, the specific softwares and the software version is not stated e.g. the analysis of the Gene Ontology Biological Processes
        • It would be beneficial for the readers to get more details about the construct they used, for example a map of the plasmid.
        • It is unclear how many cells were used for RNA extraction
        • It is unclear which microscopes were used for imaging.
        • The concentration of antibodies used for staining and the product number, and provider of the antibody is not always depicted.
      • The authors looked at available chromatin data in either K562 cells or HEK293 cells, which I think is a very good way of utilizing publicly available data. Since the authors showed that different KZFPs might be functionally relevant in different cell types/tissues, I was wondering if they checked if there is available ChIP Seq or CUT&RUN data in those specific cell types/tissues. If yes, that data should be included in the manuscript.
      • The authors mention that KZFPs are usually expressed at a low level in the K562 cell line they use, but there is no figure showing the expression level of KZFPs in this cell type. It would be important to see the baseline KZFP expression in these cells, the level of overexpression and compare it to the endogenous expression levels they show in different cell types/tissues, at least for the four candidates studied more in depth. This would help to understand whether this level of activity is something that could occur naturally in a physiologically relevant context.
      • RNA seq analysis: It is unclear how many cells were used in the RNA seq analysis, I would like to ask the authors to clarify that. Moreover, from my understanding the RNA seq analysis was done on day 3, while the Presto Blue analysis was done on days 4, 7 and 10. I would like to kindly ask the authors to motivate their choice for the day of the RNA sequencing analysis.

      Minor comments

      • Figure S1D is not mentioned in the text before figure S1E. The order of the panels should be changed in the figure.
      • "We selected genes that were downregulated upon ZNF43 overexpression and harboured a ZNF43 binding site within 10kb of their TSS (Fig. 1A) - don't the authors mean Fig. 2A?
      • In Figure 4D, the GO terms cannot be read, as the sentences seem to be cut.
      • All figures and figure legends need to be revised. In some cases, the letter size is too small, or the legend and explanation of colours is missing. Please see some examples below: Fig. S6C, Fig 6C, Fig S4C, Fig S5C (letter size too small) Fig S6G, Fig 4E (label/scale is missing)

      Significance

      Understanding the diverse roles of KZFPs is an important and interesting research question. However, studying KZFPs is challenging, as many KZFP-mediated effects appear to be highly cell type- and tissue-specific. This complexity is also highlighted by the findings of the current manuscript.

      A major strength of this study is the development of a scalable system that enables the simultaneous investigation of the entire KZFP family. Performing such analyses on an individual basis would be extremely time-consuming. Therefore, the authors provide an efficient and valuable screening platform that can identify promising candidates for further investigation. In this regard, the methodological advance represents the primary contribution of the work.

      At the same time, the study lacks a clear biological conclusion. While the screen identifies KZFPs with potential functional effects, it would substantially increase the impact of the manuscript if the authors selected at least one candidate for in-depth characterization in a biologically relevant cellular context. The current study is still of high quality and importance without these experiments, but such follow-up analyses would greatly strengthen the biological significance of the findings.

      Another limitation is that the experiments were performed in a cell type in which many of the investigated KZFPs are not normally expressed. As a result, the forced overexpression strategy may not accurately reflect physiological conditions and could potentially generate false-positive results. This concern is particularly relevant in light of the authors' statement that "KZFPs with sufficient regulatory potency to perturb cellular fitness outside of their normal setting are strong candidates for playing important roles within it." While this may indeed be true for some KZFPs, it is also possible that certain observed phenotypes simply arise from ectopic expression in an inappropriate cellular environment.

      More generally, the observation that KZFPs can have functions beyond TE repression is already established in the literature. Therefore, the manuscript provides limited new biological insight into this concept. The authors could potentially strengthen the novelty of the study by placing greater emphasis on specific KZFP subfamilies, such as SCAN-containing zinc finger proteins, which are a novel direction and have been implicated in non-canonical regulatory roles.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      In the manuscript "An overexpression platform reveals the functional diversity of human KRAB-Zinc Finger Proteins in maintaining cellular homeostasis", the authors describe a scalable framework aimed at prioritizing individual KZFPs for functional characterization. The study is centered on a large-scale screening approach in which human erythroleukemia K562 cells were transduced with inducible constructs enabling the overexpression of 366 individual KZFPs. The effects of KZFP overexpression on cellular proliferation were then assessed using a cell viability assay comparing induced and non-induced conditions.

      Based on the results of this primary screen, the authors selected four KZFPs for further investigation among those whose overexpression was associated with proliferation defects. Follow-up analyses integrated tissue- and cell type-specific expression patterns of these KZFPs with expression analyses of putative target genes identified from previously published ChIP-seq datasets, with the aim of inferring potential biological functions. On the basis of these analyses, the authors propose that the selected KZFPs may regulate distinct gene networks involved in processes including fatty acid metabolism, spermatogenesis, and other aspects of cellular homeostasis.

      The study spans multiple biological contexts, but the evidence supporting several of the individual conclusions remains relatively preliminary, and the breadth of the manuscript often comes at the expense of mechanistic depth.

      Major comments

      1. Interpretation and robustness of the initial overexpression screen

      The large-scale overexpression screen represents the foundation of the manuscript and provides a potentially valuable resource for prioritizing candidate KZFPs for downstream study. However, several aspects of the experimental setup and data presentation currently limit the interpretation of the reported proliferation defects. First, key details regarding the screening workflow remain unclear. While the Methods section describes the overall procedure, it is difficult to determine when cells were seeded relative to doxycycline induction, in which plate format the cells were maintained throughout the experiment, and whether medium exchange was performed during the 9-day assay. These points are particularly relevant given the use of suspension K562 cells (which can complicate medium exchange in a 96-well plate format and make long-term culture more difficult to control) and a metabolic viability readout (PrestoBlue), as differences in nutrient depletion or overgrowth could also influence the signal independently of reduced proliferation or toxicity. Additional clarification regarding seeding density, timing of induction, plate format, culture handling throughout the assay, and whether cell morphology/density was visually monitored would substantially improve interpretability and reproducibility. Second, it is unclear whether the observed proliferation phenotypes may be influenced by differences in transgene expression levels or integration effects. Were all constructs validated for comparable expression following induction? In the absence of such controls, it remains difficult to determine whether the reported phenotypes reflect specific KZFP activities or differences in overexpression efficiency. While it may not be possible to conclusively distinguish KZFP-specific effects from toxicity associated with high transgene expression levels, this limitation should at least be acknowledged. In addition, the possibility that some phenotypes may be influenced by transgene integration effects should also be considered. Unless independent transductions were validated for the KZFPs classified as toxic, it remains difficult to exclude integration-site-specific contributions to the observed proliferation defects. Third, the normalization strategy would benefit from additional clarification. In Fig. S1A, the LacZ control appears variably affected by doxycycline treatment across plates, whereas the GFP control appears more stable. Since normalization relies on the mean behavior of both controls within each batch and condition, the authors should clarify whether this variability could influence hit calling. Finally, several aspects of the data presentation are currently difficult to reconcile. In Fig. 1D, the meaning of the purple category is unclear, and the percentage scaling on the x-axis is difficult to reconcile with the cumulative values displayed. For instance, the sum of all the bars would not reach 100%, as the values of the bars span percentages up to 4% at most (for 105 MYO KZFPs) according to this plot. Similarly, the reported numbers of TE-binding KZFPs in Fig. 1E-F and Fig. S1D appear internally inconsistent and should be clarified. Specifically, 53+14=67 KZFPs are reported to bind TEs in total, yet a larger number of KZFPs appears associated with individual TE families (e.g. 86 for LTR.ERV1). If the values shown correspond to percentages rather than absolute counts, this should be explicitly clarified in both the figure and legend. In addition, Fig. S1D appears inconsistent with the counts reported in Fig. 1E-F, as only 5 out of the 53 toxic KZFPs displayed in the plot show no enrichment for any of the highlighted TE families. 2. Relationship between the screening phenotype and the proposed biological functions of selected KZFPs

      A central conceptual issue throughout the manuscript is that the downstream functional analyses of the selected KZFPs remain largely disconnected from the original screening phenotype. The four candidates were prioritized based on proliferation defects observed upon overexpression in K562 cells; however, the subsequent analyses (with the only exception being a more in-depth experimental analysis of ZNF498 in ciliogenesis, which stands out as comparatively more directly supported by experimental evidence) primarily rely on correlative expression patterns and KZFP ChIP-seq datasets to infer potential biological functions in unrelated cellular contexts. As a result, it remains unclear whether the proposed transcriptional programs are mechanistically linked to the proliferation phenotypes that motivated candidate selection in the first place.

      This issue is evident across multiple sections of the manuscript. For example, the proposed role of ZNF43 in regulating fatty acid metabolism and detoxification pathways is primarily inferred from tissue-level expression correlations. While these analyses focus on genes identified as potential ZNF43 targets, the underlying ChIP-seq datasets were themselves generated under ZNF43 overexpression conditions. Therefore, the current analyses do not establish whether ZNF43 regulates these pathways under physiological expression levels or within a relevant cellular context, nor how such regulation relates to the proliferation defect observed in K562 cells. Moreover, several proposed target genes remain substantially expressed in tissues where ZNF43 expression is not particularly low (e.g. kidney and heart muscle), suggesting that additional regulators are likely involved.

      Similarly, the proposed model of ZNF257-mediated regulation of MAGEA genes during spermatogenesis is intriguing but does not fully account for the expression behavior of all MAGEA family members, particularly MAGEA2B, which displays strong expression in spermatocytes despite high ZNF257 expression. This expression pattern should be acknowledged in the main text and reflected in Fig. 3K. In addition, the labels for MAGEA6 and MAGEA2B in Fig. 3C appear to be inverted. More broadly, the proposed regulatory model is difficult to reconcile with the generally restricted expression pattern of MAGEA genes across adult tissues, as their expression does not appear to consistently correlate with ZNF257 levels outside the germline context.

      Related concerns also apply to the analyses of ZNF498 and ZNF18, where the proposed functions in cilium formation and sperm maturation remain disconnected from the proliferation defects identified in the initial screen. In addition, interpretation of the SCAN-deletion experiments is complicated by the reduced expression levels of the deletion constructs relative to the corresponding full-length proteins, making it difficult to determine whether the observed proliferation phenotypes are pathway-specific or partially driven by differential expression. Finally, while the proteomics results aimed at identifying SCAN-dependent interactors are of interest, several aspects of the experimental design and data analysis remain unclear. In particular, it is not specified whether the experiment was performed in biological replicates or as a single measurement. This is important, as it directly affects how the data can be interpreted and how stringent downstream filtering can be. In the Results section, the authors state that "we identified a set of SCAN-dependent interactors, i.e. proteins that co-immunoprecipitated with the full-length construct but were absent in controls and lost upon deletion of the SCAN domain," which suggests a relatively binary, "presence/absence" filtering strategy. However, this description does not specify whether any quantitative threshold (e.g. enrichment ratio) was applied when comparing full-length constructs to deletion mutants. In contrast, the Methods section states that "proteins lacking signal above background were excluded and proteins were additionally required to show stronger signal in at least one bait condition than in GFP controls based on heatmap clustering (see script)," which instead suggests that a threshold-based criterion was used to define enrichment relative to controls and deletion mutants. If this is the case, the exact criteria and thresholds used for filtering should be clearly stated and consistently reported between the Results and Methods sections. If replicate measurements were not performed, this should be explicitly acknowledged, as peptide-level variability may substantially influence the identification of high-confidence interactors, particularly if the applied cutoffs are not highly stringent.

      Overall, many of the proposed biological functions are currently supported primarily by correlative analyses and would benefit either from additional functional validation or from a more cautious framing of the conclusions.

      Minor comments

      • In the Abstract and in the "Limitations of the study" section, the term "annotation" is used. It would be preferable to specify "functional characterization" instead of "annotation".
      • In the Introduction, there may be a minor citation confusion. Following the sentence: "Characterized by an N-terminal KRAB domain and a C-terminal tandem array of C2H2 zinc fingers, KZFPs primarily target transposable element (TE)-embedded sequences," the cited references are predominantly experimental studies supporting this statement. However, the inclusion of the review "Bruno, Mahgoub and Macfarlan, 2019" appears less appropriate in this context, as it does not directly present ChIP-seq data supporting this claim. More relevant primary studies from the same research area include "Wolf et al. 2020" and "Bruno et al. 2025.".
      • In Fig. 1A, "D10" appears inconsistent with the text and other figures (Fig. 1B, 1G, 1H), which refer to 9 days post-induction.
      • In Fig. S1, there may be a mismatch in the highlighted plate: the zoomed image appears to correspond to the first plate from the top. The correct plate should be highlighted for consistency.
      • In Fig. 1B, there is a typographical error ("K ZFPs" instead of "KZFPs").
      • In Fig. S1E, it is unclear what "other" refers to. Please clarify whether this represents the mean of all remaining KZFPs or a defined subset, ideally in the figure description.
      • In Fig. 2A, readability could be improved by adjusting the layering of points, as the darker dots (in particular the red ones) are currently obscured by lighter ones. Alternatively, removing the outline of the points (which is not transparent) may also improve visibility, but in that case the legend for point size would need to be updated accordingly.
      • In Fig. S2E, "SetDB1" should be corrected to "SETDB1".
      • In Fig. 3B, it is unclear what distinguishes the upper and lower "Diverse REs". A brief clarification in the figure legend would improve interpretability, particularly regarding the transposable element families included.
      • In Fig. S3C, the x-axis labels appear slightly misaligned and shifted to the right.
      • In Fig. 3C, the labels for MAGEA6 and MAGEA2B appear to be inverted.
      • In Fig. 3K, "MAGE3" should be corrected to "MAGEA3".
      • In the ZNF498 section, line 4, the punctuation should be corrected so that the period appears after the figure reference ("promoters (Fig. S1E).").
      • In the final sentence of the ZNF498 section, a noun appears to be missing after "cytoskeleton-dependent," possibly "processes".
      • In the last section of the Results and corresponding figures and their descriptions, "SCAN dependant" should be corrected to "SCAN-dependent".

      Significance

      General assessment

      This study presents a large-scale inducible overexpression platform aimed at systematically exploring the functional diversity of human KZFPs. The screening framework itself represents a potentially useful resource for prioritizing candidate KZFPs for downstream investigation and may be of interest to researchers studying KZFPs, transcriptional regulation, and transposable element biology. A notable strength of the study is the breadth of the screening effort and the attempt to integrate multiple orthogonal datasets to generate functional hypotheses for relatively understudied KZFPs. The more in-depth experimental analysis of ZNF498-mediated ciliogenesis also provides an example of how the platform may be used to identify biologically relevant candidates for further characterization. At the same time, many of the functional conclusions currently remain preliminary and are supported primarily by correlative analyses integrating overexpression phenotypes, expression datasets, and KZFP binding preferences also determined by overexpressing KZFP constructs. In several cases, the proposed biological functions remain insufficiently connected to the original proliferation phenotype used for candidate prioritization. As a result, the current study is best viewed as an exploratory and hypothesis-generating framework rather than a definitive functional characterization of the selected KZFPs. Clarifying these limitations and moderating some of the broader conclusions would substantially strengthen the manuscript.

      Advance

      The principal advance of the work is therefore primarily technical and resource-oriented, providing a scalable experimental framework for systematic KZFP prioritization and downstream functional exploration. While the study does not yet provide extensive mechanistic validation for most proposed functions, it may nonetheless serve as a useful starting point for future investigations into KZFP biology and transcriptional regulation.

      Audience

      The manuscript will likely be of greatest interest to a specialized basic research audience working on KZFPs, transposable element regulation, epigenetic regulation, and transcriptional control. Researchers interested in large-scale functional screening approaches may also find the methodological framework useful.

      Field of expertise: transposable elements, KRAB-zinc finger proteins, epigenetic regulation, functional genomics, genome regulation.

    1. Note: This response was posted by the corresponding author to Review Commons. The content has not been altered except for formatting.

      Learn more at Review Commons


      Reply to the reviewers

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This interesting manuscript uses single cell RNAseq of developing C. elegans larvae to identify temporal pulses or oscillations in gene expression within glia and many other epithelial cell types - mostly in genes related to cuticle synthesis or remodeling. It identifies different sets of genes that oscillate within different cell types, and identifies many apparent oscillatory genes that were missed in prior studies because they are expressed in smaller populations of cells (whereas bulk data mainly report on oscillations within the major hypodermis).

      A second major contribution of this manuscript is to pioneer analysis methods for detecting oscillatory gene expression in scRNAseq datasets. That said, it's important to state that the methods for estimating phase coherence, GAM, perplexity, etc. make sense to me intuitively but I can't assess the math and other details, which are outside of my expertise.

      Most of my comments are minor ones about suggested clarifications to the text or figures. Some may require additional analyses, but none should require additional data collection.

      1. The manuscript focuses much of its analysis on one specific glial cell type (ILso), yet the authors tell us almost nothing about this cell type or why they would care about it. It would be helpful to include just a little more background on glial biology and the epithelial-like characteristics of socket glia.

      We added the following to the second paragraph of Results:

      "To this end, we used C. elegans strains expressing GFP specifically in ILso glia or in all glia (grl-18pro::GFP or mir-228pro::GFP, respectively). In C. elegans, all glia are found in sense organs. Most sense organs consist of one or more sensory neurons – each of which is specialized to detect different types of stimuli – and exactly two glia, called the sheath and socket. The sheath and socket glia form an epithelial tube continuous with the skin, through which the ciliated dendritic endings of sensory neurons protrude to sense cues in the external environment. In prior work we found that, in some sense organs, the socket glia produce cuticle specializations around specific sensory neuron cilia, but how these are coordinated with general cuticle synthesis was unknown (Fung et al. 2023)."

      Many transcriptomic studies of epithelia (including the Purice et al study of adult glia) use single NUCLEI RNAseq rather than single cells because of the challenges in separating cells connected by tight junctions. In C. elegans there are also various epithelial syncytia to contend with. In text or Methods, the authors should comment on why they think cells were appropriate to look at in this instance, and whether there are certain cell types that were missed or could only be obtained as cell fragments based on that choice.

      We added the following to the Methods section:

      "Presumably, fine cellular projections such as axons or glial processes are lost during cell dissociation, leaving mainly cell soma with nuclei. There is a risk that some cell types could be undersampled in cell sorting, as compared to sorting isolated nuclei, due to differences in how readily they undergo dissociation. On the other hand, retention of cytoplasmic material in this approach may better represent the total mRNA complement of the cell"

      1. Related to above, the authors do not mention any detection or exclusion of likely doublets. Is there reason to think that doublets were not present in any substantial numbers? I'm not super concerned about this since doublets containing hyp7 fragments should have worked against them in detecting glia-specific oscillations, but I do think the issue should be addressed in the text or Methods.

      We added the following in Methods:

      "Ambient RNA was subtracted using SoupX (Young and Behjati 2020). Potential doublets were assessed using DoubletFinder (McGinnis et al. 2019), but no cells were excluded on this basis. "

      1. p. 4 "previously unappreciated local differences in cuticle patterning." This statement should be tempered since many stage- or tissue-specific differences in cuticle patterning have been described previously (including in papers from the Heiman lab and others that are cited here). This study uncovers many additional examples but it's not a completely new finding.

      We have revised this:

      "Surprisingly, most pulsatile genes are specific to small sets of cell types, suggesting that previously unappreciated local differences in cuticle patterning are more widespread than previously recognized."

      1. Table 1 and text: the distinction between pulsatile and oscillatory should be explained more at the outset. These terms sometimes seem to be used interchangeably, but then Table 1 seems to make a distinction, not discussed until the final "limitations" section.

      We added the following definition to the Introduction:

      "Within a single larval stage, oscillatory genes display a characteristic sharp single peak of expression and we define rigorous metrics for identifying this signature, which we call "pulsatile expression."

      • *

      We also added a further clarification in the Results section under "De novo identification of pulsatile genes":

      "We reasoned that for individual genes, if gene expression in a given cell type were plotted as a function of pseudotime, oscillatory genes would display a distinct peak because they are expressed at a particular pseudotime (Fig. 4A). We refer to this transcriptional signature as "pulsatile" when viewed in a single developmental stage; genes with pulsatile expression are predicted to be oscillatory when viewed across all of larval development, but there may be important exceptions (see "Limitations of the study")."

      1. Figure 1 and Figure 3A,B. These UMAPs look very unusual, with no discernable individual dots. Is this just a resolution issue? Or, if relevant, please add info to legend and/or Methods explaining what data smoothing was done here to make them look this way and why.

      We have reduced the size of the dots (to point size 1 from point size 2) in the UMAPs in Fig. 1 and Fig. 3 to make individual dots more apparent. The noted effect is due only to the size of the dots; the UMAPs are plotted in the conventional way. The effect of different point sizes on the Fig. 3 UMAP is shown below [IMAGE CANNOT BE ATTACHED HERE]

      1. Figure 2C and Figure 6B. In the pseudotime plots, it would be natural for readers to assume that 0 is the beginning of the larval stage and 360 is the end, but that is not actually the way the Meeuse 2020 phase angles work - instead the beginning of the larval stage falls around 160. Please make sure this is made clear, especially when referring to "early and late groups" of TF targets. In Fig 6B, Early and Late categories appear reversed because of the way the data are plotted.

      We have replotted Fig. 6B using percent of larval stage progression rather than phase angles in degrees, with 0% corresponding to the peak of dpy-6 expression, to make the timing more intuitive. We have revised the description of the early and late groups in the Discussion.

      As Fig. 2C compares our data directly with the phases defined by Meeuse et al., we prefer to keep it consistent with that publication.

      1. Figure 3B and Figure 5D-G. The authors group many unidentified clusters into the catchall "skin" category but don't clearly define it in the main text. Table S2 suggests this category includes anterior and posterior skin cells but possibly also other cuticle-lined tubular epithelia that aren't properly referred to as skin (e.g. vulva cells, excretory socket or pore cells). It may also include things like rectum, buccal cavity, excretory duct. Please define your criteria for "skin" more precisely in the main text (any cuticle-lined cell type that is not glia?), and perhaps a more general term such as external epithelia would be more appropriate.

      We have changed this in the text to "skin-related cell types" to clarify that it includes hyp, seam, and some unidentified skin-related clusters (which may include some of the cell types you mention, for example the "skin_5" cluster may include vulval epithelia or their precursors as shown in Table S2).

      1. Also related to cluster assignments: please specify if "excretory" category includes canal, duct, pore, gland all together, or only a subset of these. Only the duct and pore are cuticle lined and therefore expected to have oscillatory matrix gene expression.

      We have changed this to "excretory cell" (or "exc cell") for clarity. We did not examine markers for the excretory duct, pore, or gland.

      1. Figure 5. This figure feels disjointed and could be broken up into two figures (panels A-C and panels D-G). The first 3 panels seem more related to Figures 3 & 4 - identifying which cell types have strong pulsatile gene expression - whereas the later panels get into the degree of cell type specificity in matrix gene expression.

      We appreciate the merit of this point and in fact we strongly considered splitting up this figure (in various ways) while writing. While we agree that the figure covers a lot of ground in this format, we feel that the subparts do not hold up as their own independent figures on equal footing with the other figures in the manuscript.

      1. Figure 5D-E. The very low degree of sharing is fascinating but could be an underestimate that depends on the thresholds chosen for calling a gene "pulsatile". It may be helpful to test a range of thresholds to see how much this matters. For those ~2,500 genes that appear pulsatile in just one cell type, are they called expressed but non-pulsatile in other cell types? That would seem odd to me biologically and most likely a threshold artifact.

      We have added the following caveat to the Results:

      "Put another way, 45% (2,390 of 5,268) of the genes we identified were expressed and pulsatile exclusively in a single cell type while only 17% (915 of 5,268) were pulsatile in five or more cell types (Fig. 5E). A potential caveat to this conclusion would be if some genes are not categorized as pulsatile in particular cell types due to lower expression (e.g., falling into Cluster 7 with high peak amplitude in one cell type, and Cluster 8 with low peak amplitude in other cell types; see Fig. 4B-C). However, if this occurs, it affects only a minority of cases: among genes categorized as pulsatile in only one cell type, 82% are not detected as expressed in any of the other oscillatory cell types, indicating that the apparent specificity most likely reflects cell-type-specific gene expression rather than thresholding effects."

      1. Figure 5F and p.21 Methods, the authors analyze only 140 collagen genes and 38 ZP domain genes retrieved from InterPro, but there are at least 173 cuticle collagen genes and 43 ZP domain genes described in the literature. Therefore, their lists are incomplete and the Methods should say so.

      Thank you for pointing this out. We changed the gene list to the cuticular collagens listed in Teuscher (2019). This did not affect the figure in a major way. We retrieved 44 ZP domain genes from InterPro, which match the ones listed by Cohen (2019) with the addition of cutl-19.

      1. If most oscillatory gene expression is truly a function of the molt cycle, as suggested by the matrix gene families in Figure 5, then one might expect that most of the detected oscillatory genes would no longer be expressed in adults, or at least wouldn't appear "pulsatile" in adults. Is this true? There now are a variety of published adult data sets, including the Purice et al data on glia, that could be examined to address this.

      PCA of adult cells does not exhibit the circular structure necessary to assess pulsatile expression. Previous work showed that most oscillatory genes are not expressed in adults, as expected (Meeuse et al. 2020).

      **Referees cross-commenting**

      I agree with the other reviewers' critiques, including the point of Reviewer #2 that orthogonal confirmation methods (such as by imaging) could have been nice but are not necessary. The question of Reviewer #3 about tissue synchrony/asynchrony is a very important one but I am not confident it can be addressed with these types of data.

      Reviewer #1 (Significance (Required)):

      As a molting invertebrate, C. elegans must build and shed its protective cuticle at multiple times across its life cycle, and this requires temporal control of many genes involved in matrix structure and processing. Although temporal oscillations were already well documented from bulk RNAseq data, this manuscript extends those prior findings by showing that different sets of genes oscillate within different cell types (including sensory glia), and by identifying many apparent oscillatory genes that were missed in prior studies because they are expressed in smaller populations of cells (whereas bulk data mainly report on oscillations within the major hypodermis). These data about cell-type specific temporal programs and gene sets emphasize the exquisite specificity of apical matrix and will be broadly useful to researchers in the C. elegans community.

      A second major contribution of this manuscript is to pioneer analysis methods for detecting oscillatory gene expression in scRNAseq datasets, even where bulk temporal data may not exist. This will be valuable for others doing sRNAseq studies in nematodes but also in other systems where cells may have molt cycle- or circadian-regulated oscillations.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      SECTION A - Evidence, reproducibility and clarity

      Summary:

      Provide a short summary of the findings and key conclusions (including methodology and model system(s) where appropriate).

      The authors use single cell sequencing (scRNA-Seq ) of cells obtained from larval stages of C elegans -- primarily the L4 stage, but also the L2. Worms are disrupted and individual cells are sorted by expression of fluorescent markers specific to glial cells, a cell type that is relatively rare in the population, and of particular interest to the focus of the study. In this fashion, the samples were enriched for glial cells but, bedcause the soting is not perfect, also contain representations of other cell populations, including hypodermal (skin) and other epithelial cells, muscles, and neurons. 2D representation of the scRNA-Seq data in principle component (PC) space reveals sets of cells of the same cell type (for example glia or skin cells) arranged in roughly circular patterns, indicative of rhythmic gene expression in those cell types. Much of this circular PC behavior is shown to be driven by genes that had previously been shown, by bulk RNAseq of staged larvae, to undergo rhythmic gene expression in conjunction with the larval stages and the molts that punctuate the larval stages. Based on the previously published relative timing of expression of these cycling genes, and the pattern of peak expression of each gene in the scRNA-Seq 2D PC space, the authors could calculate a phase angle of expression of each gene relative to its peak in each cell, and thereby calculate an average phase angle of all cycling gene for each cell, and place that metric in register with the roughly circular pattern of cell types in the 2D PC plot.

      The authors show that many of these rhythmic genes encode extracellular matrix (ECM) proteins or other proteins related to cuticle synthesis and assembly, or molting. Cell types exhibiting cyclic gene expression included skin, pharyngeal epithelial, as well as several types of glia, notably socket glia, which synthesize a specialized ECM that surrounds and protects sensory neurons.

      Finally, the authors analyze the patterns of cyclic gene expression in several cell types with respect to the expression of transcription factors (TFs) that are expressed in the cell type, including TFs that appear to likewise cycle, and whose predicted targets are enriched for cycling genes. From this computational analysis, the authors derive sets of hypothetical transcriptional regulatory circuits underlying phased expression of cycling genes.

      Major comments:

      • Are the key conclusions convincing?

      1) Yes, the data support the conclusion that the authors' approach and methodology can take a list of genes known to cycle in expression level at larval stages and identify the cycling gene expression profiles of those genes in single cell sequencing datasets. It is also convincing that the authors' data analysis methods can identify cycling genes from the scRNA-Seq data that had not been previously identified as cycling from bulk RNAseq. Furthermore, the enrichment of genes encoding collagens and other ECM components is clear from the data.

      2) The above being said, it is noteworthy that the conclusions of the manuscript - including the sets of predicted novel cycling genes, and the predicted transcription factor-target circuits -- were not confirmed experimentally using independent samples or orthogonal methodology. I think it is OK for the authors to leave these predictions for later experimental confirmation, but it would be appropriate for the authors to discuss this caveat about the need for strategic experimental tests to confirm the more novel findings presented here, while at the same time pointing out predictions from their analysis that fit with previous experimental findings (for example cases such as NHR-85 and NHR-23 where previous studies support that the relevant TF is involved in regulating molting-associated transcriptional activity.)

      We have added the following sentence to "Limitations of the study":

      "Further, while our results are consistent with other studies (Meeuse et al. 2020; Gaidatzis et al. 2025) and successfully identify known regulators such as NHR-23 and NHR-85, it will be important in future work to test expression of the novel oscillatory genes and the roles of novel regulators we have predicted."

      3) There is an issue of concern that is perhaps about terminology, and not necessarily conceptual: Throughout the manuscript the authors variously use the terms, "oscillatory", "transient", and "pulsatile" to refer to cyclic gene expression. It seems that each of these terms could have distinct meanings, based on their English usage: The term "oscillatory" gene expression would seem to be a general term for gene expression that varies in a regular, rhythmic fashion. "Transient" gene expression seems like a general term for ON/OFF dynamics, albeit not necessarily oscillatory. "Pulsatile" gene expression implies oscillatory dynamics where the rise and fall of gene expression is relatively abrupt and might also imply ON/Off dynamics (between zero to some positive value). These terms are used seemingly interchangeably in the early parts of the manuscript, and then later, "pulsatile" is used increasingly, so the reader starts to wonder why. The authors should define these terms precisely and use the terminology deliberately and consistently.

      We have clarified the important point about oscillatory vs. pulsatile in the text. Please see our response to Reviewer 1, Point 5. Additionally, we have removed the use of "transient" except in the context of the phrase "transient aECM" that has been established in the literature.

      4) Related to the above, the authors should address how lowly-expressed genes behave in scRNA-Seq data, where the transcriptome is not fully sampled in each cell, and how that phenomenon could affect the apparent variation of gene expression within a population. My understanding is that if the expression level of a gene goes below some threshold percentage of the total transcriptome, it may not show up at all in the reads from that cell, even though the gene may still be expressed. Therefore, a gene can display apparent on/off behavior within a population of cells whilst the underlying variation in mRNA levels for that gene may be far less abrupt. How might this phenomenon affect the interpretation of a gene's dynamics as "pulsatile"?

      We added the following to clarify that sampling variation among cells was mitigated by applying a smoothing function based on each cell's five nearest neighbors in PCA space:

      "We then fitted the expression pattern of each gene with a generalized additive model (GAM) to obtain smoothed expression profiles. Because the GAM is fitted across many cells ordered along pseudotime, it captures the underlying expression trend even when individual cells show zero counts due to incomplete transcriptome sampling (e.g., Fig. 4A, black dots at y = 0)."

      As further described in Methods, our pipeline also incorporates several features that mitigate this valid concern:

      • First, before fitting gene-level dynamics, we retain only genes detected in at least 20 cells and in at least 5% of cells of a given cell type (Methods). While this filter may exclude some genuinely low-expressed oscillating genes, it ensures that pulsatile calls are made on genes where expression is reliably measurable.
      • Second, we apply two levels of smoothing. Prior to PCA, k-nearest-neighbor smoothing ensures that each cell's expression profile reflects a local average of transcriptionally similar cells rather than a single noisy measurement. When modeling gene expression along pseudotime, we fit a generalized additive model (GAM) with cyclic cubic splines, pooling information across many cells. The curves we score as pulsatile therefore reflect averaged expression across neighborhoods of cells, rather than raw per-cell counts subject to dropout.
      • Critically, dropouts arising from incomplete transcriptome sampling are independent of pseudotime (e.g., see dnj-1 in Fig. S3A). Our pulsatility criterion explicitly requires a low baseline combined with a well-shaped, high-amplitude peak in a specific pseudotime window, which dropout noise alone cannot generate. Indeed, as shown in Fig. 4A, the method readily identifies peaks even when many individual cells have zero detected reads (black dots at y = 0), demonstrating that the smoothed fit recovers the underlying dynamics from sparse data.
      • Finally, during development we also tested a logistic GAM that models the probability of detecting at least one read per cell, rather than read counts directly, which produced comparable results, though it saturated for highly expressed genes.
        • Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether?

      5) Page 12: "Taken together, our results suggest that cuticle formation is the main commonality among pulsatile genes, and that distinct cell types use very different gene expression programs during this process. Thus, while cuticle aECM is typically perceived as a single homogeneous meshwork, our results suggest that the cuticle is actually a patchwork matrix with different patterning and composition contributed by distinct cell types."

      It is not necessarily surprising that the cuticle made by skin cells could have composition non-identical to the cuticle made by glial cells or pharyngeal cells. But by describing the cuticle as a 'patchwork' elicits in the reader's mind an image of the skin of the animal (seam + Hyp) being mosaic for distinct cuticle compositions. Is that what the authors intend to say? It would be interesting if there were differences in composition of cuticle between skin cell types, and so it would be helpful if the authors could comment on how the transcript profiles compare for hypodermal seam cells vs multinucleate Hyp cells.

      We have expanded on this idea:

      "Taken together, our results suggest that cuticle formation is the main commonality among pulsatile genes, and that distinct cell types use very different gene expression programs during this process. Classical work showed that the cuticle exhibits regionalized specializations – for example, alae are present only over seam cells; annuli and struts are present over hyp7 but not near the nose; the vulval cuticle is thought to present structural or chemical signatures for recognition during mating; and the pharyngeal cuticle exhibits three short projections in the buccal cavity, sieve-like fingers between the metacorpus and isthmus, and grinder elements in the posterior bulb. However, the extent to which these structural differences correspond to distinct molecular composition was not known. Thus, while cuticle aECM is typically perceived as a single homogeneous meshwork, our Our results suggest that the cuticle is actually a patchwork matrix with different patterning and molecular composition contributed by distinct cell types."

      • Would additional experiments be essential to support the claims of the paper?

      6) The data here are mostly from L4 stage larvae, with a possible (but unknown) contribution from L2 larvae. It would be helpful, in terms of broader understanding of their roles in larval progression, if some of the oscillatory genes identified here (especially the novel ones) were tested by orthogonal methodology (such as fluorescent protein tagging) for oscillatory expression at other stages. However, these experiments are arguably beyond the scope of this paper, and as long as the authors note the importance of such confirmatory experiments in their Discussion, I don't think that further experimentation is critical for this paper.

      We agree about the importance of these confirmatory experiments, and have added a comment in the Discussion (see response to Point 2 above).

      • Are the data and the methods presented in such a way that they can be reproduced?

      7) In general, yes.

      • Are the experiments adequately replicated and statistical analysis adequate?

      8) Yes.

      Minor comments:

      • Specific experimental issues that are easily addressable.

      9) Page 4: Regarding the single cell sequencing approach, the authors should comment on the extent to which mRNAs are efficiently recovered from hypodermal syncytial cells (Hyp), which are multinucleate. Could the data from Hyp be chiefly from nuclear transcripts? If so, how might that affect the interpretation of the data?

      We have added a comment in Methods related to caveats of cell sorting vs. nuclei sorting (see response to Reviewer 1, Point 2). As the proportion of immature (unspliced) mRNA and reads corresponding to the mitochondrial genome are not noticeably different in the hypodermal cells than in other cell types, we do not think the data are chiefly from nuclear transcripts.

      10) It is confusing that Table S1 lists male-enriched samples that were apparently sequenced, but only hermaphrodite data were analyzed for the paper. To prevent confusion, the male samples should not be listed.

      We have clarified in the Methods that these samples are included in Table S1 because we wanted to share the datasets with the community:

      "(Supp. Table S1; note this table includes related samples that were not used in the present analysis but that are deposited in the Gene Expression Omnibus (GEO) repository as a public resource)"

      11) Page 5, bottom: The following analysis requires clarification (at least for this reader): "To test if such oscillatory gene expression is present in ILso glia, we computed the average phase of each cell (Fig. 2B). Specifically, for each cell, we computed a weighted circular average of the peak phases of oscillating genes (derived from the previous bulk RNA-Seq data), using the gene expression levels in that cell as weights."

      In reading this part of the main text, this reader struggled to understand how one can compute the phase angle for a given gene in a cell by comparing its level of expression in that cell to measurement of the level of that gene in previous bulk RNA-Seq data. Of course, there is far more to the analysis than that, which the Methods and Materials section on page 18 describes in more detail, where one learns that the level if each gene in each cell is scaled to its maximum expression across all the cells analyzed, and that the previous bulk sequence analysis is used to simply provide a phase angle for the gene's peak expression relative to an arbitrary framework (which corresponds to a larval stage, one assumes). The presentation of this analysis on Page 5 in the main text should be revised to include a full description of what was done so the reader can follow along and understand it without having to read the Methods section. But moreover, the Methods section treatment of this analysis is still not entirely clear; for example, certain variables (W, s, and c) are not defined. The presentation of the mathematics should be clarified so that the reader can understand the analysis without having to look up scTransform-normalization.

      We have expanded and clarified this section:

      "To test if such oscillatory gene expression is present in ILso glia, we computed the average phase of each cell (Fig. 2B). Specifically, for each cell in our dataset, we considered its expression level of each of the 3,739 previously described oscillatory genes (Meeuse et al. 2020). To avoid biasing towards inherently highly-expressed genes (e.g., those encoding structural proteins), the expression of each gene in a given cell was scaled to its maximum expression across all cells. We then computed the average phase of each cell by taking the known phase for each gene (Meeuse et al. 2020) and calculating a weighted circular average, using the scaled expression of each gene in that cell as weights (Fig. 2B; each colored line represents one oscillatory gene with its angle representing its known phase and its length representing its scaled expression in that cell). we computed a weighted circular average of the peak phases of oscillating genes (derived from the previous bulk RNA-Seq data), using the gene expression levels in that cell as weights. This average results in a vector whose direction reflects the average phase of genes expressed in that cell, and whose length reflects how consistently the genes’ peak times align in that cell (Fig. 2B, black arrow)."

      In the Methods, we have moved the definitions of W, s, and c so that they precede the formula for the average angle .

      • Are prior studies referenced appropriately?

      12) yes

      • Are the text and figures clear and accurate? - Do you have suggestions that would help the authors improve the presentation of their data and conclusions?

      13) Figure S3 Panel A: What does the green line mean? Figure S3 Panel C: The use of the "predictors" tem is confusing because on page 8, the part of the narrative referring to Figure S3, the term used is "descriptors". Is that an meningful switch in terminology?

      We have expanded and clarified the Supp. Fig. S3 legend. For simplicity, we now use the term "metrics" to refer to the parameters used for hierarchical clustering of pulsatile expression (peak amplitude, baseline, fit, shape). This replaces our previous uses of "predictors" and "descriptors".

      14) The legend to Figure S3 requires more details to enable the reader understand the Figure. The same critique applies to most of the Supplemental Figure legends, where more details are required to allow the reader to understand each Figure without having to refer back to the main text.

      Thank you for pointing this out. We have revised and expanded all of the Supplemental Figure legends.

      15) Page 19: "The cells were grouped by cell type independent of the stage of collection (L2 or L4), and each cell type was processed individually."

      Why were L2s and L4s pooled? How does this affect the analysis and/or the outcomes? Could there be confounding effects from pooling the samples that could affect the analysis or the conclusions?

      We added the following clarification in the main text:

      "Because we found that cells clustered together based on their cell type rather than developmental stage, L2 and L4 cells of the same cell type were pooled for all downstream analyses (see Methods)."

      as well as the following explanation in the Methods:

      "The cells corresponding to the same cell type at different stages were then merged for subsequent analysis. After annotation, cells of the same cell type from L2 and L4 datasets were pooled for downstream analysis, such that each cell type is represented as a single combined cluster across stages. This provides two advantages: it increases statistical power by increasing the number of cells, and it favors genes that are oscillating in both larval stages. Because L2 representation is more limited (Table S1), the pooled pseudotime is dominated by L4 dynamics, ensuring that L2 cells are anchored on the L4-defined trajectory."

      **Referees cross-commenting**

      There is substantial agreement amongst all three reviewers, regarding the signifcance of the findings and that the conclusions are well enough supported by the data such that no additional experiments are required. We all recommend revisions to clarify or expand the description of the experiments and/or analysis. Many comments are reiterated by more than one Reviewer. I agree with all the other reviewers' critiques.

      Reviewer #2 (Significance (Required)):

      SECTION B - Significance

      • Describe the nature and significance of the advance (e.g. conceptual, technical, clinical) for the field.

      The finding of oscillatory and molting-related gene expression patterns in glial cells emphasizes the importance of molting-related ECM/cuticle production by these sensory-accessory cells and will serve as a platform for further studies and further understanding the structural and molecular basis of glial cell support functions, especially in the context of changing roles for sensory neurons during developmental progression.

      The methodology and data analysis of C. elegans scRNA-Seq data presented here offers several significant advances, especially since it had been known that thousands of genes cycle in rhythm with the C. elegans molting cycle, yet that was based on previous bulk sequencing, so it was not possible to resolve cell-type specific expression. This paper presents methods for analysis of cycling gene expression in specific cell types.

      The manuscript derives hypothetical TF-target regulatory interactions that are proposed do underly cyclic gene expression in specific cell types. This is a significant resource for future work to explore and delineate upstream oscillator mechanisms, and answer questions such as, Is there a central oscillator for all of larval stage rhythmic gene expression? and, How are different genes expressed with different phases of the larval stages? etc.

      • Place the work in the context of the existing literature (provide references, where appropriate).

      The authors cite important previous studeis that used scRNA-Seq to profile gene expression in specific C. elegans cell type in various developmental and physiological settings, and previous studies that used bulk RNAseq to identify genes whose transcripts cycle along with the larval stages. This manuscript reports the first study to examine cyclic gene express in C. elegans on the single-cell level.

      • State what audience might be interested in and influenced by the reported findings.

      Moderately broad audience of biologists interested in biological oscillators; developmental biologists interested in gene regulatory control of developmental cell fate timing and reiterative developmental processes; neurobiologists interested in glial cell function in developmental contexts.

      • Define your field of expertise with a few keywords to help the authors contextualize your point of view.

      • C. elegans larval development; temporal control of cell fate progression. Are there are any parts of the paper that you do not have sufficient expertise to evaluate.

      Honestly, some of the mathematical analysis is beyond my ability to judge whether the chosen approach is the best choice for the particular setting.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study describes both new scRNA-seq data from C. elegans, targeting glia/epidermal cell types and especially the ILso glial cell, and analytical approaches to identify periodically expressed genes in the dataset. Overall the data appear of high quality so have value as a resource, and the analysis provides a substantial improvement in our understanding of how different cell types vary in their cyclic expression across the molt cycles. While I have make many suggestions, overall this is a very nice study as is and definitely seems likely to be an impactful publication.

      Major

      Figure 2:

      • The dataset includes cells from multiple stages (L2 and L4 mentioned in the text, adult as well listed in Supplemental Table 1). There is a superficial display in Figure S1 which seems to imply that whether the same cell type clusters together across stages vs making stage specific clusters might be complex. But this isn't really discussed at all in the paper. For Figure 2 specifically it seems critical to know whether stages were pooled or separated for this analysis, and the question of whether the cyclic program varies across stages (at least for well sampled cells like ILso) is important.

      Please see our response to Reviewer 2, Point 15.

      Figure 3

      • This approach overall is good for cells that cycle in a way their signature comes up in Meeuse but would it detect rare cell type cycles? Maybe the PCA space velocity approach could be a way to screen for cell types that cycle in a way that isn't detected in the whole organism time course data (or rule out the presence of large cycling gene sets)? For example "pharyngeal gland" seems to have a weak cycling signature using the Meeuse gene set (Fig. 3D) but fairly clear "circular UMAP" structure (Fig 3B).

      We added the following to emphasize that our rationale for developing the perplexity metric is to identify oscillatory cell types de novo, i.e. without relying on the Meeuse et al. dataset:

      "We hypothesized that this [perplexity] metric would distinguish between pulsatile cell types (corresponding to relatively high perplexity) and non-pulsatile cell types (corresponding to low perplexity), without relying on prior bulk annotations that may be insensitive to rare cell types."

      Consistent with the reviewer's intuition, this approach does identify cell types missed by the Meeuse-based local phase coherence analysis, specifically coelomocytes and PHsh glia, which have perplexity >30 but did not reach significance by phase coherence (Fig. 5C).

      Regarding the pharyngeal gland, this cell type has intermediate scores by both metrics and falls below our conservative thresholds (Fig. 5C). It is possible that it has a genuine but weak oscillatory program that our methods are underpowered to detect given the number of cells recovered for this cell type.

      We considered using RNA velocity, but we have not succeeded in developing a satisfying quantitative score; therefore, the perplexity metric serves this role in our current analysis.

      • Do these data say anything about the question of whether all cell types in an organism are synchronized in the same phase as each other, or whether some might be systematically earlier or later in the cycle at a given time? It seems like if individual samples have enough stage bias (as an illustrative but made up example, if sample "230421_AM" has mostly early L4 while "230421_PM" has mostly late L4), then these data could be used to see if for example ILso cells tend to have earlier or later phases in the same sample compared to hyp cells. In my view, this is an important enough general question in the field to be worth addressing if the data are sufficient. And it could also provide an independent way to support/refute the presence of additional cycling cells (see Fig. 5 comments)

      This is an interesting idea, but unfortunately our synchronization at the population level is not sufficiently precise, and each sample contains cells spanning nearly the full phase range (shown below [IMAGE CANNOT BE ATTACHED HERE]). Under these conditions, between-sample phase offsets are dominated by within-sample dispersion, and we cannot reliably estimate systematic phase differences between cell types.

      Figure 5

      • This seems a nice approach to address the earlier question about detecting cell type specific oscillations. But then only results for the cell types previously identified as oscillatory are reported. It seems important to report the potential cycling genes for the other cell types (PHsh, Coelomocytes, maybe Pharyngeal Gland) so their cycling status could be tested by others in the future.

      We revised the text to highlight that these gene lists are in Supp. Tables S3 and S4.:

      "We limit our subsequent analyses to the 17 high-confidence cell types that appear oscillatory using both approaches (local phase coherence and perplexity), which together contain 5,268 pulsatile genes. Pulsatile gene lists for these and other cell types are provided in Supp. Tables S3 and S4 to facilitate independent assessment of their cycling status. A summary of pulsatile genes in these 17 cell types is shown in Table 1."

      • Regarding the last section ("only 17% were pulsatile in five or more cell types", "only 10 genes were pulsatile in all 17 oscillatory cell types" etc) - thresholding of a dataset like this can lead to false negatives resulting from incomplete (and cell type specific differences in power) which is a common source of technical non-overlap in this type of comparison. Indeed it is notable that the highest overlap was with ILso (specific sort target, likely to be especially well powered) and CEPso. There are various approaches to estimate not just confident overlap but also confident non-overlap, for example the "irreproducible discovery rate" (IDR) approach commonly used for ChIP-seq data. While clearly based on gene set enrichment there is cell type specificity, I'd suggest toning down the interpretation of the fractional overlap in the text if this can't be resolved.

      We toned down the interpretation of the fractional overlap:

      "To what extent are the same sets of pulsatile genes shared between cell types? To address this question, we examined the overlap between the pulsatile genes we identified in each cell type (Fig. 5D), noting that because power to detect pulsatile expression varies across cell types, the overlap values we report are likely to underestimate the true sharing between cell types.

      […]

      Put another way, 45% (2,390 of 5,268) of the genes we identified were detected as expressed and pulsatile exclusively in a single cell type while only 17% (915 of 5,268) were pulsatile in five or more cell types (Fig. 5E)."

      Minor

      Figure 1:

      • I was a little unclear about the coloring in Fig 1C (are the colors by annotated tissue or something else like clusters?) - suggest specifying in the legend.

      We updated the legend: "UMAP of the same cells as in B, with each cell colored by its annotated tissue identity."

      • More details on clustering and annotations approaches in the methods would be useful.

      We have substantially expanded the corresponding section.

      • I have mixed feelings about the word "skin" in the figure panels - while more accessible to a broad audience, hypodermis or hyp subset labels (hyp 7 etc) might be more precise.

      We have changed many of these to "skin-related." We cannot use the anatomical terms because we cannot confidently distinguish, for example, hyp1 vs hyp2, due to the lack of known markers for each cell type. We therefore refer to skin-related cluster 3 as "skin 3," because calling it "hyp 3" would lead to confusion with the anatomical term.

      • Table S2 would benefit from including the number of cells annotated with each cell type name

      We have added the number of cells per cell type to Supp. Table S2, with separate columns for L2, L4, and the total.

      Figure 2

      • Fig 2B is nice - clearly shows the difference in expression of phase specific genes in the two example cells and conceptual framework for averaging. I was struck by the relatively broad range of phase values though (For example the bottom cell has highly expressed genes with phases ranging from ~100 degrees to ~280). It seems this could reflect technical noise in the single cell data or imprecision in the phase calls in Meeuse. But there is also the interesting possibility that there is biological flexibility in the order/expression of phased genes at this single cell level. Not sure if there is an obvious way to address this or whether it should be in the scope of this work but maybe at least worthy of a mention

      A parsimonious explanation for the broad range of phase values in a single cell is the shape of the peak: examining the data from Meeuse et al, oscillatory genes do not generally display a sharp peak, but rather elevated expression over a span of ~3h (out of a larval stage of ~8h), which would correspond to expression over 100°. Indeed, the decentered genes in Fig. 2B correspond to the genes F53F4.2 and cutl-10 which have their peak expression at ~135° (26 h of larval development in the Meeuse dataset) but are still expressed at ~180° (28 h of larval development in the Meeuse dataset). Importantly, expression peaks tend to be roughly symmetric around the cell's true phase and therefore reduce the length of the phase vector but do not affect the average phase itself.

      Figure 3

      • The class Alter et al SVD paper https://www.pnas.org/doi/full/10.1073/pnas.97.18.10101 was the first use case of SVD/PCA in genome wide expression data and used (cell cycle) periodic expression as the main use case. The plots in Figures 2 and 3 are very similar to that approach, which basically used the relevant (~sin and ~cos correlated) principle components to define phases of both samples and genes. I mention this mostly in case it is useful to see how they approached the question and maybe as a relevant citation.

      We added the citation.

      Figure 4

      • Minor method clarification - how was DTW adapted to deal with circular data, specifically to identify cases where the peak is centered at pseudotime == 0/1? It seems from the figures that maybe some approach was used to center the raw data on the peak but I didn't see a description of how this was done (apologies if I missed it)

      We edited the Methods to make the connection with the previous section more explicit:

      "We used the trained model to predict expression of each gene along a grid of 128 regularly spaced pseudotime values, resulting in a smoothed expression profile. Further, for each gene, we shifted the pseudotime values to center the maximal expression value, and fitted a GAM as described above. To facilitate comparison of profile shapes across genes with different peak times, we additionally produced a centered version of each profile. For each gene, we identified the pseudotime at which the uncentered profile reached its maximum, then circularly shifted the pseudotime values so that this maximum fell at the center of the range (pseudotime 0.5). A new GAM was fit on the shifted data as described above, and used to predict expression along the same regular grid. This yielded a centered, smoothed expression profile for each gene in which all genes have their peak at the center of the pseudotime axis. These centered profiles were used in the subsequent section to compute both the baseline and shape metrics of each gene.

      […]

      We then scaled the curve by its maximum value and centered it around its maximal value. We then scaled the centered smoothed expression profile (defined in the previous section) by its maximum value. The Dynamic Time Warp distance between the scaled and centered expression and an ideal sharp peak defined as the density of a normal distribution of mean 0.5 and standard deviation 0.01 was computed with the dtw package."

      • The 2-PC view of ILso seems to align well with phase, but some of the other cell types (such as Seam in Figure 3C) are more complex - and also it seems possible that there could be cell types where the phase information is in e.g. PC2 and 3 instead of 1 and 2; how customizable is the approach and how dependent is it on a clean circular pattern in the PC plot?
      • *

      We have expanded the Discussion to include this point:

      "This could indicate either a genuine absence of oscillatory programs; the presence of oscillations driven by only a few genes that are insufficient to shape PCA structure; or oscillations that are present but reside in higher principal components dominated in PCs 1-2 by other sources of cell-to-cell variation."

      By using an Elastic Principal Cycle (ElPiGraph) to fit pseudotime rather than relying on angle from the origin (as is common for this type of data), we accommodate trajectories within PCs 1-2 that deviate from perfect circularity, including elongated or asymmetric shapes such as in seam cells (Fig. 3C). However, when phase information resides in higher-order PCs, in the absence of an independent timing reference there is no principled way to identify which PCs carry oscillatory signal versus other gradients of cell-to-cell variation. Recovering oscillations in such cell types would therefore require complementary approaches, such as synchronized time-course sampling, rather than a modification of the current pipeline.

      • It would be useful to annotate the examples (Fig 4A, lower panels) with whether they were newly identified or known from the bulk time course. And consider a larger supplemental figure with a sampling of newly identified genes in a similar format across a range of amplitudes etc

      We added Supplementary Figure S4C with examples across a range of amplitudes.

      • The examples are all relatively tight peaks (width We developed an approach to quantify the width of peaks in the Meeuse data (Methods); we display the distribution of peak width for genes expressed in ILso and seam cells in the new Supplementary Figure S4A. Our approach did not display a systematic bias to detect narrow or wide peaks. We added the following in the Results:

      “More generally, our classification captures a range of expression profile morphologies without apparent bias (Supp. Fig. S4).”

      Figure 5

      • There are important caveats in the interpretation of perplexity. For example a cell type that oscillates but with the vast majority of genes expressed uniformly or at one specific phase, would get a low perplexity, while a cell with multiple distinct states that don't cycle (this may be why body muscle has a modestly elevated sore) might achieve high perplexity. Worth addressing at some point.

      We added these caveats:

      "Potential caveats are that some non-oscillatory cell types might have high perplexity, for example if there are other sources of complex transcriptional heterogeneity among cells, while some oscillatory cell types might have low perplexity, for example if oscillating genes do not dominate the PCA structure."

      • Fig 5C raises the question of how power (for each of these metrics) relates to number of cycling genes in a cell type and the density of its sampling across time (for example is glia 4 just a poorly sampled cell type, or is it qualitatively different in what fraction of its transcriptome is cycling?). Just recoloring this plot by number of single cells per annotation might touch on this, or could try a subsampling approach.

      We added this with the new Supp. Fig. S5C:

      "To test whether differences in perplexity could be explained by differences in the number of sampled cells, we recomputed perplexity after subsampling to progressively smaller numbers of cells for several representative cell types. Perplexity values were largely stable across subsample sizes, indicating that the classification of cell types as oscillatory or non-oscillatory is not driven by differences in statistical power (Supp. Fig. S5C)."

      • The identification of pharyngeal muscle and epithelial oscillatory genes is a nice resource aspect of this paper given past work by EM showing these cells changing across the life cycle; it appears these cells have distinct enrichments (Fig 5G) and I think talking about these differences more explicitly could add to the closing paragraph in this section about aECM heterogeneity

      We have added the following:

      "In addition, the nematode astacin (NAS) metalloproteases appeared enriched in pulsatile genes in glia and pharynx, but not hypodermis (Fig. 5G, Supp. Table S6), consistent with ultrastructural observations that the pharyngeal muscle becomes secretory during molts and that the protease NAS-6 is required to digest the old pharyngeal cuticle (Sparacio et al., 2020)."

      Figure 6

      • This section is great and a very useful resource for future work. A detailed analysis may be beyond the scope of this work, but for Fig 6B I wondered whether the TF oscillation phase matched/preceded the timing of its predicted targets (for the subset of TFs that were themselves oscillatory in that cell type)? Even a qualitative analysis of this would be informative.

      We added a new supplementary Figure S7 and commented on it in the text:

      "__For the subset of TFs that are themselves pulsatile, we asked whether their peak expression coincides with or precedes that of their predicted targets. We found that pulsatile targets are modestly enriched in a temporal window around the TF's own peak (Supp. Fig S7), consistent with near-simultaneous expression of TFs and their targets, as previously observed for nhr-23 (Johnson et al., 2023). This temporal enrichment was most consistent for nhr-23 and nhr-25, which showed significant enrichment across most cell types, while other TFs showed more variable patterns (Supp. Fig. S7)."__

      Open-ended/discretionary

      A general challenge in single cell data analysis is that standard methods like clustering can give misleading or hard to interpret results when multiple processes occur simultaneously. For example, cells can have signatures of cell fate and cell cycle and depending on the genes used for clustering and strengths of those signals, naïve clustering may cause them to group by either fate of cell cycle phase. This is a long-winded way to say an application of the approach reported here would be to identify cycling genes shared between cell types that could be removed from the "variably expressed genes" lists prior to clustering to improve cell type separation, or used exclusively to allow clustering by phase rather than cell type. (definitely discretionary to consider this but could be mentioned in Discussion as a possible application)

      **Referees cross-commenting**

      I agree with all of this, including Reviewer #1 that asynchrony may be hard to address with current data, and with both reviewers that the dataset stands on its own.

      Reviewer #3 (Significance (Required)):

      This paper addresses the problem of how to identify cycling genes in single cell data, using the C. elegans larval/molt cycle as a model system. The system has emerged as a powerful model for understanding regulation of periodic gene expression, with past bulk RNA-seq time course have identified 1000s of cycling genes. However, how cyclic gene expression varies across cell types was not known. This study uses single cell RNA-seq and develops new analysis approaches to identify cycling genes across dozens of C. elegans cell types. Strengths are the generation of a new single cell data enriched for larval glia, identification of cyclic gene expression across many C. elegans cell types, an improved analytical framework for identifying cycling genes that could be applied in other datasets, and substantial analysis of pathways and regulators involved. Weaknesses are limited, and include minor overinterpretations of the data and missed opportunities for additional analyses. The work should be of interest to a broad audience including not just C. elegans researchers but also the single cell and chronobiology communities.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #3

      Evidence, reproducibility and clarity

      This study describes both new scRNA-seq data from C. elegans, targeting glia/epidermal cell types and especially the ILso glial cell, and analytical approaches to identify periodically expressed genes in the dataset. Overall the data appear of high quality so have value as a resource, and the analysis provides a substantial improvement in our understanding of how different cell types vary in their cyclic expression across the molt cycles. While I have make many suggestions, overall this is a very nice study as is and definitely seems likely to be an impactful publication.

      Major

      Figure 2:

      • The dataset includes cells from multiple stages (L2 and L4 mentioned in the text, adult as well listed in Supplemental Table 1). There is a superficial display in Figure S1 which seems to imply that whether the same cell type clusters together across stages vs making stage specific clusters might be complex. But this isn't really discussed at all in the paper. For Figure 2 specifically it seems critical to know whether stages were pooled or separated for this analysis, and the question of whether the cyclic program varies across stages (at least for well sampled cells like ILso) is important.

      Figure 3

      • This approach overall is good for cells that cycle in a way their signature comes up in Meeuse but would it detect rare cell type cycles? Maybe the PCA space velocity approach could be a way to screen for cell types that cycle in a way that isn't detected in the whole organism time course data (or rule out the presence of large cycling gene sets)? For example "pharyngeal gland" seems to have a weak cycling signature using the Meeuse gene set (Fig. 3D) but fairly clear "circular UMAP" structure (Fig 3B).
      • Do these data say anything about the question of whether all cell types in an organism are synchronized in the same phase as each other, or whether some might be systematically earlier or later in the cycle at a given time? It seems like if individual samples have enough stage bias (as an illustrative but made up example, if sample "230421_AM" has mostly early L4 while "230421_PM" has mostly late L4), then these data could be used to see if for example ILso cells tend to have earlier or later phases in the same sample compared to hyp cells. In my view, this is an important enough general question in the field to be worth addressing if the data are sufficient. And it could also provide an independent way to support/refute the presence of additional cycling cells (see Fig. 5 comments)

      Figure 5

      • This seems a nice approach to address the earlier question about detecting cell type specific oscillations. But then only results for the cell types previously identified as oscillatory are reported. It seems important to report the potential cycling genes for the other cell types (PHsh, Coelomocytes, maybe Pharyngeal Gland) so their cycling status could be tested by others in the future.
      • Regarding the last section ("only 17% were pulsatile in five or more cell types", "only 10 genes were pulsatile in all 17 oscillatory cell types" etc) - thresholding of a dataset like this can lead to false negatives resulting from incomplete (and cell type specific differences in power) which is a common source of technical non-overlap in this type of comparison. Indeed it is notable that the highest overlap was with ILso (specific sort target, likely to be especially well powered) and CEPso. There are various approaches to estimate not just confident overlap but also confident non-overlap, for example the "irreproducible discovery rate" (IDR) approach commonly used for ChIP-seq data. While clearly based on gene set enrichment there is cell type specificity, I'd suggest toning down the interpretation of the fractional overlap in the text if this can't be resolved.

      Minor

      Figure 1:

      • I was a little unclear about the coloring in Fig 1C (are the colors by annotated tissue or something else like clusters?) - suggest specifying in the legend.
      • More details on clustering and annotations approaches in the methods would be useful.
      • I have mixed feelings about the word "skin" in the figure panels - while more accessible to a broad audience, hypodermis or hyp subset labels (hyp 7 etc) might be more precise.
      • Table S2 would benefit from including the number of cells annotated with each cell type name

      Figure 2

      • Fig 2B is nice - clearly shows the difference in expression of phase specific genes in the two example cells and conceptual framework for averaging. I was struck by the relatively broad range of phase values though (For example the bottom cell has highly expressed genes with phases ranging from ~100 degrees to ~280). It seems this could reflect technical noise in the single cell data or imprecision in the phase calls in Meeuse. But there is also the interesting possibility that there is biological flexibility in the order/expression of phased genes at this single cell level. Not sure if there is an obvious way to address this or whether it should be in the scope of this work but maybe at least worthy of a mention

      Figure 3

      • The class Alter et al SVD paper https://www.pnas.org/doi/full/10.1073/pnas.97.18.10101 was the first use case of SVD/PCA in genome wide expression data and used (cell cycle) periodic expression as the main use case. The plots in Figures 2 and 3 are very similar to that approach, which basically used the relevant (~sin and ~cos correlated) principle components to define phases of both samples and genes. I mention this mostly in case it is useful to see how they approached the question and maybe as a relevant citation.

      Figure 4

      • Minor method clarification - how was DTW adapted to deal with circular data, specifically to identify cases where the peak is centered at pseudotime == 0/1? It seems from the figures that maybe some approach was used to center the raw data on the peak but I didn't see a description of how this was done (apologies if I missed it)
      • The 2-PC view of ILso seems to align well with phase, but some of the other cell types (such as Seam in Figure 3C) are more complex - and also it seems possible that there could be cell types where the phase information is in e.g. PC2 and 3 instead of 1 and 2; how customizable is the approach and how dependent is it on a clean circular pattern in the PC plot?
      • It would be useful to annotate the examples (Fig 4A, lower panels) with whether they were newly identified or known from the bulk time course. And consider a larger supplemental figure with a sampling of newly identified genes in a similar format across a range of amplitudes etc
      • The examples are all relatively tight peaks (width <0.5 pseudotime units) - is this approach able to identify genes with wider "plateau" patterns (and do such patterns exist?) Figure 5
      • There are important caveats in the interpretation of perplexity. For example a cell type that oscillates but with the vast majority of genes expressed uniformly or at one specific phase, would get a low perplexity, while a cell with multiple distinct states that don't cycle (this may be why body muscle has a modestly elevated sore) might achieve high perplexity. Worth addressing at some point.
      • Fig 5C raises the question of how power (for each of these metrics) relates to number of cycling genes in a cell type and the density of its sampling across time (for example is glia 4 just a poorly sampled cell type, or is it qualitatively different in what fraction of its transcriptome is cycling?). Just recoloring this plot by number of single cells per annotation might touch on this, or could try a subsampling approach.
      • The identification of pharyngeal muscle and epithelial oscillatory genes is a nice resource aspect of this paper given past work by EM showing these cells changing across the life cycle; it appears these cells have distinct enrichments (Fig 5G) and I think talking about these differences more explicitly could add to the closing paragraph in this section about aECM heterogeneity

      Figure 6

      • This section is great and a very useful resource for future work. A detailed analysis may be beyond the scope of this work, but for Fig 6B I wondered whether the TF oscillation phase matched/preceded the timing of its predicted targets (for the subset of TFs that were themselves oscillatory in that cell type)? Even a qualitative analysis of this would be informative.

      Open-ended/discretionary

      A general challenge in single cell data analysis is that standard methods like clustering can give misleading or hard to interpret results when multiple processes occur simultaneously. For example, cells can have signatures of cell fate and cell cycle and depending on the genes used for clustering and strengths of those signals, naïve clustering may cause them to group by either fate of cell cycle phase. This is a long-winded way to say an application of the approach reported here would be to identify cycling genes shared between cell types that could be removed from the "variably expressed genes" lists prior to clustering to improve cell type separation, or used exclusively to allow clustering by phase rather than cell type. (definitely discretionary to consider this but could be mentioned in Discussion as a possible application)

      Referees cross-commenting

      I agree with all of this, including Reviewer #1 that asynchrony may be hard to address with current data, and with both reviewers that the dataset stands on its own.

      Significance

      This paper addresses the problem of how to identify cycling genes in single cell data, using the C. elegans larval/molt cycle as a model system. The system has emerged as a powerful model for understanding regulation of periodic gene expression, with past bulk RNA-seq time course have identified 1000s of cycling genes. However, how cyclic gene expression varies across cell types was not known. This study uses single cell RNA-seq and develops new analysis approaches to identify cycling genes across dozens of C. elegans cell types. Strengths are the generation of a new single cell data enriched for larval glia, identification of cyclic gene expression across many C. elegans cell types, an improved analytical framework for identifying cycling genes that could be applied in other datasets, and substantial analysis of pathways and regulators involved. Weaknesses are limited, and include minor overinterpretations of the data and missed opportunities for additional analyses. The work should be of interest to a broad audience including not just C. elegans researchers but also the single cell and chronobiology communities.

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      Provide a short summary of the findings and key conclusions (including methodology and model system(s) where appropriate).

      The authors use single cell sequencing (scRNA-Seq ) of cells obtained from larval stages of C elegans -- primarily the L4 stage, but also the L2. Worms are disrupted and individual cells are sorted by expression of fluorescent markers specific to glial cells, a cell type that is relatively rare in the population, and of particular interest to the focus of the study. In this fashion, the samples were enriched for glial cells but, bedcause the soting is not perfect, also contain representations of other cell populations, including hypodermal (skin) and other epithelial cells, muscles, and neurons. 2D representation of the scRNA-Seq data in principle component (PC) space reveals sets of cells of the same cell type (for example glia or skin cells) arranged in roughly circular patterns, indicative of rhythmic gene expression in those cell types. Much of this circular PC behavior is shown to be driven by genes that had previously been shown, by bulk RNAseq of staged larvae, to undergo rhythmic gene expression in conjunction with the larval stages and the molts that punctuate the larval stages. Based on the previously published relative timing of expression of these cycling genes, and the pattern of peak expression of each gene in the scRNA-Seq 2D PC space, the authors could calculate a phase angle of expression of each gene relative to its peak in each cell, and thereby calculate an average phase angle of all cycling gene for each cell, and place that metric in register with the roughly circular pattern of cell types in the 2D PC plot.

      The authors show that many of these rhythmic genes encode extracellular matrix (ECM) proteins or other proteins related to cuticle synthesis and assembly, or molting. Cell types exhibiting cyclic gene expression included skin, pharyngeal epithelial, as well as several types of glia, notably socket glia, which synthesize a specialized ECM that surrounds and protects sensory neurons.

      Finally, the authors analyze the patterns of cyclic gene expression in several cell types with respect to the expression of transcription factors (TFs) that are expressed in the cell type, including TFs that appear to likewise cycle, and whose predicted targets are enriched for cycling genes. From this computational analysis, the authors derive sets of hypothetical transcriptional regulatory circuits underlying phased expression of cycling genes.

      Major comments:

      • Are the key conclusions convincing?

      1) Yes, the data support the conclusion that the authors' approach and methodology can take a list of genes known to cycle in expression level at larval stages and identify the cycling gene expression profiles of those genes in single cell sequencing datasets. It is also convincing that the authors' data analysis methods can identify cycling genes from the scRNA-Seq data that had not been previously identified as cycling from bulk RNAseq. Furthermore, the enrichment of genes encoding collagens and other ECM components is clear from the data.

      2) The above being said, it is noteworthy that the conclusions of the manuscript - including the sets of predicted novel cycling genes, and the predicted transcription factor-target circuits -- were not confirmed experimentally using independent samples or orthogonal methodology. I think it is OK for the authors to leave these predictions for later experimental confirmation, but it would be appropriate for the authors to discuss this caveat about the need for strategic experimental tests to confirm the more novel findings presented here, while at the same time pointing out predictions from their analysis that fit with previous experimental findings (for example cases such as NHR-85 and NHR-23 where previous studies support that the relevant TF is involved in regulating molting-associated transcriptional activity.)

      3) There is an issue of concern that is perhaps about terminology, and not necessarily conceptual: Throughout the manuscript the authors variously use the terms, "oscillatory", "transient", and "pulsatile" to refer to cyclic gene expression. It seems that each of these terms could have distinct meanings, based on their English usage: The term "oscillatory" gene expression would seem to be a general term for gene expression that varies in a regular, rhythmic fashion. "Transient" gene expression seems like a general term for ON/OFF dynamics, albeit not necessarily oscillatory. "Pulsatile" gene expression implies oscillatory dynamics where the rise and fall of gene expression is relatively abrupt and might also imply ON/Off dynamics (between zero to some positive value). These terms are used seemingly interchangeably in the early parts of the manuscript, and then later, "pulsatile" is used increasingly, so the reader starts to wonder why. The authors should define these terms precisely and use the terminology deliberately and consistently.

      4) Related to the above, the authors should address how lowly-expressed genes behave in scRNA-Seq data, where the transcriptome is not fully sampled in each cell, and how that phenomenon could affect the apparent variation of gene expression within a population. My understanding is that if the expression level of a gene goes below some threshold percentage of the total transcriptome, it may not show up at all in the reads from that cell, even though the gene may still be expressed. Therefore, a gene can display apparent on/off behavior within a population of cells whilst the underlying variation in mRNA levels for that gene may be far less abrupt. How might this phenomenon affect the interpretation of a gene's dynamics as "pulsatile"? - Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether?

      5) Page 12: "Taken together, our results suggest that cuticle formation is the main commonality among pulsatile genes, and that distinct cell types use very different gene expression programs during this process. Thus, while cuticle aECM is typically perceived as a single homogeneous meshwork, our results suggest that the cuticle is actually a patchwork matrix with different patterning and composition contributed by distinct cell types."

      It is not necessarily surprising that the cuticle made by skin cells could have composition non-identical to the cuticle made by glial cells or pharyngeal cells. But by describing the cuticle as a 'patchwork' elicits in the reader's mind an image of the skin of the animal (seam + Hyp) being mosaic for distinct cuticle compositions. Is that what the authors intend to say? It would be interesting if there were differences in composition of cuticle between skin cell types, and so it would be helpful if the authors could comment on how the transcript profiles compare for hypodermal seam cells vs multinucleate Hyp cells. - Would additional experiments be essential to support the claims of the paper?

      6) The data here are mostly from L4 stage larvae, with a possible (but unknown) contribution from L2 larvae. It would be helpful, in terms of broader understanding of their roles in larval progression, if some of the oscillatory genes identified here (especially the novel ones) were tested by orthogonal methodology (such as fluorescent protein tagging) for oscillatory expression at other stages. However, these experiments are arguably beyond the scope of this paper, and as long as the authors note the importance of such confirmatory experiments in their Discussion, I don't think that further experimentation is critical for this paper. - Are the data and the methods presented in such a way that they can be reproduced?

      7) In general, yes. - Are the experiments adequately replicated and statistical analysis adequate?

      8) Yes.

      Minor comments:

      • Specific experimental issues that are easily addressable.

      9) Page 4: Regarding the single cell sequencing approach, the authors should comment on the extent to which mRNAs are efficiently recovered from hypodermal syncytial cells (Hyp), which are multinucleate. Could the data from Hyp be chiefly from nuclear transcripts? If so, how might that affect the interpretation of the data?

      10) It is confusing that Table S1 lists male-enriched samples that were apparently sequenced, but only hermaphrodite data were analyzed for the paper. To prevent confusion, the male samples should not be listed.

      11) Page 5, bottom: The following analysis requires clarification (at least for this reader): "To test if such oscillatory gene expression is present in ILso glia, we computed the average phase of each cell (Fig. 2B). Specifically, for each cell, we computed a weighted circular average of the peak phases of oscillating genes (derived from the previous bulk RNA-Seq data), using the gene expression levels in that cell as weights."

      In reading this part of the main text, this reader struggled to understand how one can compute the phase angle for a given gene in a cell by comparing its level of expression in that cell to measurement of the level of that gene in previous bulk RNA-Seq data. Of course, there is far more to the analysis than that, which the Methods and Materials section on page 18 describes in more detail, where one learns that the level if each gene in each cell is scaled to its maximum expression across all the cells analyzed, and that the previous bulk sequence analysis is used to simply provide a phase angle for the gene's peak expression relative to an arbitrary framework (which corresponds to a larval stage, one assumes). The presentation of this analysis on Page 5 in the main text should be revised to include a full description of what was done so the reader can follow along and understand it without having to read the Methods section. But moreover, the Methods section treatment of this analysis is still not entirely clear; for example, certain variables (W, s, and c) are not defined. The presentation of the mathematics should be clarified so that the reader can understand the analysis without having to look up scTransform-normalization. - Are prior studies referenced appropriately?

      12) yes - Are the text and figures clear and accurate? - Do you have suggestions that would help the authors improve the presentation of their data and conclusions?

      13) Figure S3 Panel A: What does the green line mean? Figure S3 Panel C: The use of the "predictors" tem is confusing because on page 8, the part of the narrative referring to Figure S3, the term used is "descriptors". Is that an meningful switch in terminology?

      14) The legend to Figure S3 requires more details to enable the reader understand the Figure. The same critique applies to most of the Supplemental Figure legends, where more details are required to allow the reader to understand each Figure without having to refer back to the main text.

      15) Page 19: "The cells were grouped by cell type independent of the stage of collection (L2 or L4), and each cell type was processed individually."

      Why were L2s and L4s pooled? How does this affect the analysis and/or the outcomes? Could there be confounding effects from pooling the samples that could affect the analysis or the conclusions?

      Referees cross-commenting

      There is substantial agreement amongst all three reviewers, regarding the signifcance of the findings and that the conclusions are well enough supported by the data such that no additional experiments are required. We all recommend revisions to clarify or expand the description of the experiments and/or analysis. Many comments are reiterated by more than one Reviewer. I agree with all the other reviewers' critiques.

      Significance

      • Describe the nature and significance of the advance (e.g. conceptual, technical, clinical) for the field.

      The finding of oscillatory and molting-related gene expression patterns in glial cells emphasizes the importance of molting-related ECM/cuticle production by these sensory-accessory cells and will serve as a platform for further studies and further understanding the structural and molecular basis of glial cell support functions, especially in the context of changing roles for sensory neurons during developmental progression.

      The methodology and data analysis of C. elegans scRNA-Seq data presented here offers several significant advances, especially since it had been known that thousands of genes cycle in rhythm with the C. elegans molting cycle, yet that was based on previous bulk sequencing, so it was not possible to resolve cell-type specific expression. This paper presents methods for analysis of cycling gene expression in specific cell types.

      The manuscript derives hypothetical TF-target regulatory interactions that are proposed do underly cyclic gene expression in specific cell types. This is a significant resource for future work to explore and delineate upstream oscillator mechanisms, and answer questions such as, Is there a central oscillator for all of larval stage rhythmic gene expression? and, How are different genes expressed with different phases of the larval stages? etc. - Place the work in the context of the existing literature (provide references, where appropriate).

      The authors cite important previous studeis that used scRNA-Seq to profile gene expression in specific C. elegans cell type in various developmental and physiological settings, and previous studies that used bulk RNAseq to identify genes whose transcripts cycle along with the larval stages. This manuscript reports the first study to examine cyclic gene express in C. elegans on the single-cell level. - State what audience might be interested in and influenced by the reported findings.

      Moderately broad audience of biologists interested in biological oscillators; developmental biologists interested in gene regulatory control of developmental cell fate timing and reiterative developmental processes; neurobiologists interested in glial cell function in developmental contexts. - Define your field of expertise with a few keywords to help the authors contextualize your point of view.

      C. elegans larval development; temporal control of cell fate progression.

      Are there are any parts of the paper that you do not have sufficient expertise to evaluate.

      Honestly, some of the mathematical analysis is beyond my ability to judge whether the chosen approach is the best choice for the particular setting.

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      Referee #1

      Evidence, reproducibility and clarity

      This interesting manuscript uses single cell RNAseq of developing C. elegans larvae to identify temporal pulses or oscillations in gene expression within glia and many other epithelial cell types - mostly in genes related to cuticle synthesis or remodeling. It identifies different sets of genes that oscillate within different cell types, and identifies many apparent oscillatory genes that were missed in prior studies because they are expressed in smaller populations of cells (whereas bulk data mainly report on oscillations within the major hypodermis).

      A second major contribution of this manuscript is to pioneer analysis methods for detecting oscillatory gene expression in scRNAseq datasets. That said, it's important to state that the methods for estimating phase coherence, GAM, perplexity, etc. make sense to me intuitively but I can't assess the math and other details, which are outside of my expertise.

      Most of my comments are minor ones about suggested clarifications to the text or figures. Some may require additional analyses, but none should require additional data collection.

      1. The manuscript focuses much of its analysis on one specific glial cell type (ILso), yet the authors tell us almost nothing about this cell type or why they would care about it. It would be helpful to include just a little more background on glial biology and the epithelial-like characteristics of socket glia.
      2. Many transcriptomic studies of epithelia (including the Purice et al study of adult glia) use single NUCLEI RNAseq rather than single cells because of the challenges in separating cells connected by tight junctions. In C. elegans there are also various epithelial syncytia to contend with. In text or Methods, the authors should comment on why they think cells were appropriate to look at in this instance, and whether there are certain cell types that were missed or could only be obtained as cell fragments based on that choice.
      3. Related to above, the authors do not mention any detection or exclusion of likely doublets. Is there reason to think that doublets were not present in any substantial numbers? I'm not super concerned about this since doublets containing hyp7 fragments should have worked against them in detecting glia-specific oscillations, but I do think the issue should be addressed in the text or Methods.
      4. p. 4 "previously unappreciated local differences in cuticle patterning." This statement should be tempered since many stage- or tissue-specific differences in cuticle patterning have been described previously (including in papers from the Heiman lab and others that are cited here). This study uncovers many additional examples but it's not a completely new finding.
      5. Table 1 and text: the distinction between pulsatile and oscillatory should be explained more at the outset. These terms sometimes seem to be used interchangeably, but then Table 1 seems to make a distinction, not discussed until the final "limitations" section.
      6. Figure 1 and Figure 3A,B. These UMAPs look very unusual, with no discernable individual dots. Is this just a resolution issue? Or, if relevant, please add info to legend and/or Methods explaining what data smoothing was done here to make them look this way and why.
      7. Figure 2C and Figure 6B. In the pseudotime plots, it would be natural for readers to assume that 0 is the beginning of the larval stage and 360 is the end, but that is not actually the way the Meeuse 2020 phase angles work - instead the beginning of the larval stage falls around 160. Please make sure this is made clear, especially when referring to "early and late groups" of TF targets. In Fig 6B, Early and Late categories appear reversed because of the way the data are plotted.
      8. Figure 3B and Figure 5D-G. The authors group many unidentified clusters into the catchall "skin" category but don't clearly define it in the main text. Table S2 suggests this category includes anterior and posterior skin cells but possibly also other cuticle-lined tubular epithelia that aren't properly referred to as skin (e.g. vulva cells, excretory socket or pore cells). It may also include things like rectum, buccal cavity, excretory duct. Please define your criteria for "skin" more precisely in the main text (any cuticle-lined cell type that is not glia?), and perhaps a more general term such as external epithelia would be more appropriate.
      9. Also related to cluster assignments: please specify if "excretory" category includes canal, duct, pore, gland all together, or only a subset of these. Only the duct and pore are cuticle lined and therefore expected to have oscillatory matrix gene expression.
      10. Figure 5. This figure feels disjointed and could be broken up into two figures (panels A-C and panels D-G). The first 3 panels seem more related to Figures 3 & 4 - identifying which cell types have strong pulsatile gene expression - whereas the later panels get into the degree of cell type specificity in matrix gene expression.
      11. Figure 5D-E. The very low degree of sharing is fascinating but could be an underestimate that depends on the thresholds chosen for calling a gene "pulsatile". It may be helpful to test a range of thresholds to see how much this matters. For those ~2,500 genes that appear pulsatile in just one cell type, are they called expressed but non-pulsatile in other cell types? That would seem odd to me biologically and most likely a threshold artifact.
      12. Figure 5F and p.21 Methods, the authors analyze only 140 collagen genes and 38 ZP domain genes retrieved from InterPro, but there are at least 173 cuticle collagen genes and 43 ZP domain genes described in the literature. Therefore, their lists are incomplete and the Methods should say so.

      https://pubmed.ncbi.nlm.nih.gov/33543001/ https://pubmed.ncbi.nlm.nih.gov/30409789/ 13. If most oscillatory gene expression is truly a function of the molt cycle, as suggested by the matrix gene families in Figure 5, then one might expect that most of the detected oscillatory genes would no longer be expressed in adults, or at least wouldn't appear "pulsatile" in adults. Is this true? There now are a variety of published adult data sets, including the Purice et al data on glia, that could be examined to address this.

      Referees cross-commenting

      I agree with the other reviewers' critiques, including the point of Reviewer #2 that orthogonal confirmation methods (such as by imaging) could have been nice but are not necessary. The question of Reviewer #3 about tissue synchrony/asynchrony is a very important one but I am not confident it can be addressed with these types of data.

      Significance

      As a molting invertebrate, C. elegans must build and shed its protective cuticle at multiple times across its life cycle, and this requires temporal control of many genes involved in matrix structure and processing. Although temporal oscillations were already well documented from bulk RNAseq data, this manuscript extends those prior findings by showing that different sets of genes oscillate within different cell types (including sensory glia), and by identifying many apparent oscillatory genes that were missed in prior studies because they are expressed in smaller populations of cells (whereas bulk data mainly report on oscillations within the major hypodermis). These data about cell-type specific temporal programs and gene sets emphasize the exquisite specificity of apical matrix and will be broadly useful to researchers in the C. elegans community.

      A second major contribution of this manuscript is to pioneer analysis methods for detecting oscillatory gene expression in scRNAseq datasets, even where bulk temporal data may not exist. This will be valuable for others doing sRNAseq studies in nematodes but also in other systems where cells may have molt cycle- or circadian-regulated oscillations.

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      Reply to the reviewers

      __Reviewer #1 (Evidence, reproducibility and clarity (Required)):____

      Summary In this study, Phalora et al identified the selective autophagy receptor SQSTM1/p62 as a MR1 interacting protein by proteomics approach using a cell line overexpressing MR1. While SQSTM1/p62 is implicated in autophagy regulation and autophagosome formation, genetic ablation of SQSTM1/p62 resulted in enhanced MAIT cell activation upon challenge with E. coli, but not with a synthetic agonist 5-OP-RU. In contrast, knockout of Atg5 and Atg7, both of which are involved in phagophore expansion engendered increased activation of MAIT cells upon both stimuli. From these data, the authors concluded that some factors in autophagy controlled the MR1 activity, thus the autophagy is a pivotal regulator of cellular antigen presentation.

      Major comments: 1. The notion that "This regulation appears to occur at an early step in the trafficking pathway." in the summary appears not to be compatible with the present data. What the authors have shown in the study is possible implication of autophagy components such as SQSTM1/p62, Atg5, and Atg7 that are implicated in autophagosome and phagophore formation. Should the authors highlight an "early step of trafficking", Atg14L, Atg13, and/or Atg101 must be analyzed by genetic knockout in addition to PI3 kinase inhibitors that are supposed to affect an early step in autophagy. Such an approach could confirm whether the regulation of MR1 occurs at an early step of trafficking, or at least, at an early step of autophagy.__


      The reviewer may have misinterpreted our conclusion. When we state ‘an early step in the trafficking pathway’ we are referring to MR1 trafficking (from the ER to the PM) and not to early steps in the autophagy pathway. We have modified the text to make this clearer.

      __ In Figure 2, while the degree of β2M depletion from B1 appears to be superior to that in B6 (Figure 2A), why the former was more potent in producing IFN-γ relative to the latter upon E. coli and 5-OP-RU (Figure 2D)?__


      We cannot conclusively say why MAIT cell activation is reduced to a greater extent in clone B6 compared to clone B1, whereas the protein depletion is not as pronounced. Most likely as these are clonal cells there may be genetic/phenotypic differences apart from depletion of B2M that may impact upon antigen presentation. Importantly both B1 and B6 are significantly decreased in terms of MR1 surface expression and MAIT cell activation compared to the control as would be expected.

      __ In Figure 3B, right column, what is Ac-6-FP? The left histograms show MR1 expression level upon DMSO, E. coli, and 5-OP-RU challenge. There is no explanation.__


      We thank the reviewer for pointing this out. The bar chart was mislabelled and should read 5-OP-RU (as in the histogram). This has now been corrected in the figure.

      __ Also in the same figure, was MR1 geomeans in Control, 5-1, 5-2, 5-3, 7-1, 7-2, and 7-3 upon Ac-6-FP superior to DMSO? If so or not, please explain the rational.__


      The difference in MR1 geomeans between DMSO and 5-OP-RU treated cells was significantly different. However as stated in the text the difference between control and Atg depleted cells for each condition was not statistically significant although there is a trend for increasing MR1 expression in KD cells.


      __ Figure 3C is highly intentional. If the authors put two left panels together (Control, 5-1, 5-2, and 5-3), is there still statistical difference among them?__


      The data for Atg5.3 was displayed separately as the experiments for this cell line were performed at a later timepoint using different donor cells. Therefore, it would be inappropriate to combine and/or compare them with the data for Atg 5.1 and 5.2. For clarity the figure has now been modified and this explanation added to the figure legend.

      __ There was no explanation for Figure 4B why the authors used Hela-MR1-HA. Other cell lines were used in the rest of the experiments. It is highly desirable to perform the experiment with THP1-MR1-HA in terms of logical development.__


      As the reviewer correctly states, it would be ideal to use Thp.MR1.HA cells for these microscopy experiments as they have been used throughout the rest of the paper. However, Thp1 cells can be difficult to image and HeLa cells which are more amenable to this technique are commonly used instead, generally and for MR1 studies. We have validated the HeLa.MR1.HA cell lines and can show that they upregulate MR1 at the cell surface in response to antigen and can activate MAIT cells. This data is now included as a supplementary figure (Supplementary Figure 11) and the rationale for the use of these cells explained in the main text.

      __ In addition, Figure 4B represent only the non-activated status. Given that association of SQSTM1/p62 with MR1 is dependent on E.coli and/or 5-OP-RU (Figure 1A), the same immuno-fluorescent imaging in the presence of the inhibitors upon stimulation with these reagents would also be desirable. It will uncover whether MR1 and SQSTM1/p62 colocalize upon stimulation, and such colocalization is perturbed in the presence of the inhibitors.__


      The aim of this microscopy experiment was to demonstrate that perturbations to the autophagy pathway induced by different drug treatments also affected MR1 localisation and/or expression to complement the other experiments in that figure (Figure 4A and 4C). SQSTM1 expression was included as a control as it is known to be regulated by autophagy. Although assessing the interaction between MR1 and SQSTM1 under different autophagy conditions may be of interest we did not find it to be particularly relevant in this case as our focus shifted to the autophagy pathway in general rather than the specific interaction between MR1 and SQSTM1.

      __ Whereas the authors addressed the question as to at which stage MR1 is regulated in trafficking in Figure 5, there was no experiments with 5-OP-RU (an agonist for MAIT cells). This casts the doubt whether observed phenotype really represented the true MR1 trafficking, because there is no guarantee that the trafficking pathway for antagonist (Ac-6-FP) is same as that for agonist.__


      5-OP-RU and Ac-6-FP are small chemically synthesised molecules and an agonist and antagonist of MR1 antigen presentation respectively There is no evidence to suggest that apart from activation of MAIT cells (5-OP-RU is stimulatory, Ac-6-FP is not) that they would behave any differently in terms of trafficking and interaction with MR1. Indeed, both are used interchangeably in the MR1 field.

      __ Given the importance of MR1 overexpression in showing the association between MR1 and SQSTM1/p62, it is worthwhile to consider performing the knockout experiments with Thp1-MR1-HA rather than Thp1. It will further clarify the role(s) of SQSTM1/p62, Atg5, and Atg7 in MR1 trafficking and resultant MAIT cell activation.__

      The interaction studies had to be performed with overexpressed MR1 as the endogenous protein is very difficult to detect for these types of experiments. The majority of the functional studies were performed with the endogenous protein which avoids any issues concerned with the use of overexpressed and tagged proteins and addresses concerns that interactions observed with the overexpressed protein are simply artifactual. As the functional assays validate the interaction data, we believe it is not necessary to repeat the depletion experiments in the MR1 overexpressed cell lines.



      __ Minor comments: 1.Please explain why the authors failed to detect IL23A in the coimmunoprecipitation. Should MR1-IL23A interaction be specific, what is a biological significance?__


      This point is addressed in the discussion. It is sometimes the case that interactions identified by mass spec cannot be recapitulated by co-immunoprecipitation and alternative methods may need to be employed to verify the interaction. Since this work concentrates on the autophagy pathway further experiments involving IL23A were deemed beyond the scope of this manuscript. Of note, IL23A will be strongly induced over very low background levels by E coli, which would amplify the impact of any weak interactions.

      __ When Hela-MR1-HA was used, did the authors obtain the same results as Thp1-MR1-HA as shown in Figure 1C-D? This is relevant to the specificity in the interaction between MR1 and SQSTM1/p62 as shown in Figure 4B.__


      The interaction between MR1 and SQSTM1 in the presence of E.coli was not confirmed in the HeLa.MR1.HA cells. SQSTM1 is included as a positive control as it is known to be regulated by autophagy. As these experiments were performed in the absence of any antigen, we would not expect to observe an interaction in this instance.


      __ While S1, S2, S3, and S4 showed a similar degree of SQSTM1 depletion in Figure 2A, there was difference in the potential of IFN-γ production from MAIT cells among the clones. Only S4 showed decreased potential for IFN-γ upon 5-OP-RU, though E. coli failed to so. Contrary to 5-OP-RU, S1-S3 showed an enhanced potential while S4 failed to do so. Why is that so?__


      As the SQSTM1 knockout cells are clonal cells there may be other genetic/phenotypic differences, besides depletion of SQSTM1, that can account for the observed differences in MAIT cell activation. To mitigate for these differences, we tested 4 different clonal cell lines, with 3 out of 4 clones displaying the same phenotype with respect to activation of MAIT cells.

      __ Given that there was little correlation between MR1 expression level and the potential of S1-S4 to promote or inhibit the ligand-dependent production of IFN-γ (Figure 2C right panel and Figure 2D), it is difficult to conclude that the factors implicated in autophagy play a pivotal role in MR1-dependent MAIT cell activation.__


      Surface MR1 levels on the whole are difficult to detect even in the presence of antigen as MR1 surface expression appears to be very tightly controlled. Although MR1 surface expression levels between the different SQSTM1 clones appeared to be somewhat variable, in the Atg depleted cells they showed a more consistent upregulation compared to the control (although these differences were not statistically significant). In both cases, stimulation with E.coli resulted in increased MAIT activation demonstrating that these autophagy proteins did affect MR1 presentation and that small (perhaps undetectable in some cases) changes in surface expression did impact MR1 function. Therefore, we have concluded that autophagy factors are able to regulate MR1 antigen presentation but to what extent and how remains unclear. We have removed the word ‘pivotal’ from the abstract as we agree with the reviewer that the impact of these interactions has not been conclusively established.

      __ There was no consistency in the experimental design for Figure 5. Please explain the rational why the authors have used 7.1 in A and C, but not in B, D and E?__


      For some of the experiments it was not possible to display and thus quantify all the cell lines in one figure eg the western blot data for the EndoH experiments (Figure 5D). Therefore, one representative cell line from Atg5 and Atg7 depleted cells was chosen, as on the whole all the cell lines behaved similarly. This rationale is now included in the main text.

      __ The control appeared to behave as 7.1 did. Was there statistical difference between 7.1 and 7.2 in Figure 5C? If so, what is the interpretation.__


      As the reviewer correctly notes, in Figure 5C the Atg7.1 cell line had similar kinetics to the control cell line in terms of MR1 surface expression. In other experiments Atg7.1 shows increased MR1 surface expression compared to the control (Figure 3B, although not statistically significant). One major difference between these experiments is the timing, Figure 3B is measured after an overnight incubation while Figure 5C is measured over 6 hours. It may be the case that in this cell line MR1 takes slightly longer to accumulate at the cell surface compared to Atg7.2. As these are heterogenous cell populations, there may be other factors that account for these differences apart from depletion of Atg7. Statistical analysis has now also been included for this data.

      __ Time course over 6 h will be required to assess the MR1 expression in Figure 5C.__

      It has been demonstrated by others that MR1 is able to reach the cell surface within 4 hours of antigen exposure (McWilliams et al, 2016), therefore a time course over 6 hours to measure MR1 surface expression was deemed sufficient.__

      Reviewer #1 (Significance (Required)):

      The present study uncovered the possible implication of autophagy factors in MR1 trafficking, in other words, MAIT cell activation. Although the previous study has demonstrated the importance of the protein loading factors (McWilliam et al., PNAS,117 24974-24985 2020), this study adds another pathway for MAIT cell activation. However, the conceptual significance is limited in that depletion of the factors pertinent to autophagy such as Atg5 and Atg7 in Thp1 resulted in rather weak interference in terms of MR1 trafficking and MAIT cell activation. Thus, this study will interest those who work in basic immunology, in particular, in regulation of antigen-presentation molecules and T cells as well as those who are in the field of MAIT cell biology. Although the field of this reviewer covers biochemistry, molecular biology, developmental biology, immunology and regenerative medicine, proteomics approach (in detailed technique) as seen here to identify the associated molecules is somewhat beyond the reviewer's expert.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary

      The authors used a mass spectrometry proteomics approach to screen for proteins which interact with the MHC-I-related molecule MR1. In addition to expected interacting partners, they identified SQSTM1/p62, a selective autophagy mediator, and demonstrated that MAIT cell responses to fixed E. coli were increased with knockout of SQSTM1. The authors further investigated the role of autophagy in regulating MR1 ligand presentation through knockout of two key autophagy proteins, Atg5 and Atg7, or treatment with various autophagy inhibitors. MR1 surface expression and MAIT cell activation were variably increased following interruption of autophagy in the context of fixed E. coli or synthetic ligand treatment of human monocytes and B cell lines. The authors concluded that preformed pools of MR1 are regulated by autophagy.

      Major comments

      Overall, this is an interesting study that is the first to identify autophagy as a potential regulatory mechanism for MR1. There are a number of conceptual questions relevant to the model system. The main concerns regard a number of the conclusions made, given the analysis of the data as presented. These concerns are described in more detail below.

      Conceptual concerns:

      1. The investigators rightly note the challenge in studying MR1 protein due to low endogenous expression. However, the use of over-expressed MR1 protein begs some questions with regard to the identification of ER degradation and autophagy proteins (which as they note are also involved in the degradation of damaged and defective cellular components). Although they have previously shown that MR1-HA tagged protein goes to the cell surface and presents antigen, it is impossible to know what proportion of the over-expressed molecules are functional, and it is plausible that a proportion of these molecules that end up in ER degradation or autophagy pathways identified, but would still IP with the HA tag. In the data shown, it is not entirely clear that the impacts of the molecules are actually impacting MR1 protein absent overexpression. Example: In Figure 2, there is very little impact of the complete KO of SQSTM1 on MR1 protein expression in WT THP1 cells, despite this protein only interacting with MR1 in E.coli infected cells. In contrast, in the 5-OP-RU incubated cells, there is a difference in MR1 expression in the SQSTM1 mutant clones, but no impact to MAIT cell activation. The authors note these issues and discuss the possibility that the other functions of SQSTM1 are coming in to play and further look at Atg5 and Atg7, however the absence of these proteins also have no significant impact on the expression of MR1 protein. Can the authors comment on this? The authors state that the increase in MAIT cell responses to fixed E. coli-treated polyclonal populations of SQSTM1 KO cells (same cells as SF2D) was blocked by the use of an anti-MR1 antibody, but do not show this data. Why not done with clonal populations? It is unclear why this data was not shown as it would help to support that the impact of inhibited autophagy is really on the functional MR1 protein pool, rather than a pool of non-functional but still HA tagged MR1 that has been shunted to degradation or autophagy pathways.__

      The reviewer rightly acknowledges the challenges associated with detecting endogenous MR1 protein levels which can be difficult to measure even after antigen exposure. For this reason, many researchers use a tagged protein in overexpressing cell lines to study MR1 as we (and others) have done for the proteomics analysis and validation studies. The use of tagged overexpressed proteins can be problematic because they may not recapitulate endogenous protein structure, localisation and/or function. Although we have previously demonstrated that HA tagged MR1 behaves similarly to its endogenous counterpart in terms of trafficking to the cell surface and presentation to MAIT cells (Ussher et al, 2016), there is still a possibility that there is a population of non-functional protein that is targeted for degradation. As we understand, it is the reviewer’s concern that it is this protein pool that is immunoprecipitating with autophagy components.

      Firstly, although the interaction studies were necessarily performed using tagged overexpressed protein, the majority of the functional studies (ie measuring surface MR1 levels and MAIT cell activation in SQSTM1 and Atg depleted cells, Figures 2 and 3) were performed in wildtype Thp1 cells, expressing endogenous levels of MR1. As explained in response to reviewer 1, MR1 surface levels as displayed in Figures 2C and 3B, are very tightly controlled and can be difficult to detect even after antigen exposure as demonstrated in the accompanying histograms. Therefore, subtle differences in MR1 surface levels are to be expected especially when measuring an increase rather than a decrease in expression. Although for SQSTM1 depletion there was some variability in MR1 surface levels, for Atg depletion there was a clear trend towards increased expression, although these differences were not statistically significant. In both cases (depletion of SQSTM1 and Atg) there was a definite effect on MR1 presentation as MAIT cell activation was increased in nearly all cases. It is well established in the literature that MAIT activation, in the 5 hour timecourse of our experiments, is wholly MR1 dependent. Therefore, these subtle, and perhaps sometimes undetectable, differences on endogenous MR1 surface expression do have an effect on MR1 function and we believe this validates the data from the interaction studies using overexpressed protein.

      In addition, experiments performed with the MR1 blocking antibody would not necessarily address the reviewers concerns as again these were done on Thp1 cells expressing endogenous levels of MR1 and not the overexpressing cell lines. However, for completeness this data has now been included as a supplementary figure.

      Secondly one of the top hits from the proteomics analysis was B2M, a protein known to associate with MR1 and to be functionally important. Other proteins identified by our screen include components of the peptide loading complex which have also been reported to be important for MR1 trafficking and antigen presentation. It should also be noted that SQSTM1 was identified in a similar proteomics screen performed by a different lab (McWilliams et al, 2020). Therefore, we believe that these findings also validate use of the HA tagged MR1 construct to generate true protein interactions.

      __ The conclusion that "regulation of MR1 by autophagy is not dependent on new protein synthesis and is most likely occurring on pre-existing pools of MR1" is not strongly supported by the data. If MR1 is processed normally through the golgi in Atg5 and 7 deficient cells (Figure 5D), how can the conclusion be made that the pre-existing pools of MR1 are in the ER? There is a non-significant decrease in MR1 surface expression from CHX treatment in the context of Ac-6-FP stimulation in Atg KO cells. This data is not clear enough to support a firm conclusion in either direction. Have the authors performed this experiment using 5-OP-RU or fixed E. coli as ligand sources? Is there a similar trend seen using the Atg KO C1R cells? Further supporting experiments may be necessary to conclude whether or not this trend is biologically relevant.__


      We thank the reviewer for their comment. The statement that pre-existing pools of MR1 are in the ER is based on reports from the literature where it has been shown that unbound ligand receptive MR1 remains in the ER until it comes into contact with antigen. Since we were able to show that MR1 trafficked normally through the Golgi in Atg depleted cells, the effects of autophagy on MR1 expression and function must occur prior to Golgi processing. This would indicate the ER population of MR1 as the likely targets of regulation by autophagy especially considering the function of SQSTM1 which binds to proteins in the ER.

      The experiments with CHX treatment were used to establish whether it was new or pre existing protein that was targeted by autophagy. Since CHX had no effect on MR1 surface expression this would indicate that new protein synthesis is not required for MR1 trafficking in Atg depleted cells.

      __

      Analysis of Western Blot data:

      1. There are many places throughout the manuscript where statements are made with regard to increases and decreases in the protein expression level with treatment, or comparisons between control and knockout samples. Although the legends generally indicate these experiments were based on at least 3 replicates (except some cases, where noted), there is no quantification of any western blotting data. There is no information in the legends or methods as to how much sample was loaded. Specific examples:

      a. Figure 1/Supp Figure 1: Figure 1C and 1D: There are several differences in the inputs between the 2 blots, including differences in the no antigen samples (which should be the same) or presence of multiple bands in one blot for a given marker but not the other. Fig 1C: the band for Calreticulin in the immunoprecipitated E. coli-treated Thp1.MR1.HA samples (right lane) is very weak. Fig. 1D: the bands are weak and there is no clear difference for Calnexin in the immunoprecipitated 5-OP-RU treated Thp1.MR1.HA samples (right lane) compared to no ligand despite the conclusion that Calnexin weakly associates with MR1 in the context of 5-OP-RU ligand. Are some of these weak associations visible due to different inputs? Why are the input blots for anti-HA so different between the no antigen controls in the E coli vs 5-OP-RU blots? Supp Figure 1B: the +5-OP-RU pulldown of MR1.HA appears as to be more (like with E.coli), but no quantification. Why does so little B2M IP with 5-OP-RU MR1? Supp Figure 1D (and others): statements are made about increases and decreases without quantification. All: Presumably HSP90 is used as a loading control for the input, but this is not discussed nor is there quantification.__


      We thank the reviewer for this comment. As western blotting is a multi-step process often over more than one day, there are numerous points at which variation can occur between blots no matter how carefully the conditions are controlled to minimise this. It is for this reason that it is generally not good practice to compare samples that have been run on different gels. Therefore, we do not believe that comparisons between blots in Figures 1C and 1D, relating to differences in input proteins for example, are appropriate nor informative. If we take the top anti-HA blot for Figure 1C there is a big increase in protein expression in the Ip of E.coli treated cells (final lane) which is not as pronounced with 5-OP-RU treatment (Figure 1D, top blot, final lane). This sample will dictate the exposure time of the blot (so as to prevent saturation of this sample) which then affects detectable expression of less well expressing samples on the same blot (such as the input samples in Figure 1C). Therefore there may appear to be less input protein in Figure 1C than Figure 1D but there is also more protein in the E.coli treated pull down than in the 5-OP-RU treated one, which also needs to be taken into account. This is one example of why it is difficult to compare samples across blots. To accurately and correctly compare these input samples they would need to be run on the same gel.

      The only useful comparison that can be drawn is between samples from the same blot, so comparing input protein in the presence and absence of E.coli for instance. To take the reviewer’s example, for the anti-calreticulin blot in Figure 1C, there is a weak interaction of calreticulin with MR1 in the presence of E.coli. If we compare the input lanes on this blot (effectively the loading control), there actually appears to be slightly more protein in the E.coli negative sample that the positive one. This would argue against the reviewers claim that this weak interaction is actually due to differences in the input and it is instead more likely to simply be a weak interaction. It is important to point out that this interaction, and others involving components of the peptide loading complex, have also been validated by other groups.


      With regards to Calnexin association with MR1 in the presence of 5-OP-RU, we did not mean to imply that this association was only in the presence of 5-OP-RU as it is evident from the data that Calnexin weakly associates even in the absence of antigen. The text has now been changed to make this clearer.


      The anti-HSP90 blot has been included to show that a random protein, not identified by our proteomics screen, does not spuriously associate with MR1, and not as a loading control for the input samples per se. This explanation has now been included in the text.

      Finally with regard to quantification of the co-immunoprecipitation blots, while quantification of western blots in some cases can be informative (eg relative expression of a protein compared to a control), it is at best only a semi-quantitative technique and not generally applied to co-immunoprecipitation data. As we are looking for a binary result (presence/absence of a particular protein) rather than a relative value, we do not see how quantification of this data will make it any more informative. We have included more detail of the sample loading in the methods section as requested by the reviewer and have added quantification of other blots where appropriate. __

      b. Supp Figure 5: The authors conclude there are no difference in protein interactions with MR1 in Atg5 or 7 deficient cells. By eye, there appear to in fact be differences, but there is no quantification to support the conclusions either iway. These data are subsequently used to make interpretive statements about the data in Figure 5. There is no indication of the number of times this experiment was performed.__

      In supplementary figure 5, we aimed to determine whether depletion of Atg 5 or 7 negatively affected the MR1 proteome ie whether interactions that were previously observed were disrupted and whether this contributed to the effects on MR1 antigen presentation observed in these cell lines. The interactions between MR1 and the tested proteins remained intact in Atg depleted cells. However, as Atg depletion increased MR1 protein expression some of these interactions are more pronounced in the depleted cell lines compared to the control cell line. Thus, the reviewer is correct in stating that there are differences in the protein interactions between the cell lines but in all cases the protein interactions remain intact which was the focus of our analysis. We have modified the text to make this clearer. The figure legend now also includes the number of replicates for this experiment.

      __ Figure 4A: No quantification to support conclusions. Unclear why both blocking and inducing autophagy would both increase the amount of MR1 in cells.__


      Quantification of this western blot data has now been included in the figure. Blocking autophagy (3MA and Wort) has a much greater effect on total MR1 protein levels, while inducing autophagy (EBSS) has minimal effects compared to the control. As autophagy is a highly dynamic process with western blotting providing just a snapshot of this process, inhibiting and inducing autophagy can both lead to the same observed phenotype of increased autophagosomes, due to blocking fusion with lysosomes and increased autophagosome formation respectively.

      __

      Analysis of Fluorescence microscopy data (Figure 4B):

      1. There are several concerns with the conclusions drawn from the fluorescence microscopy images (Figure 4B). How many images/fields were taken and cells analyzed per condition? How were individual fields chosen for imaging to be unbiased? Overall, the conclusions are observational and require quantification. For example, the authors indicate "an increase in MR1 cytoplasmic signal intensity following treatment...", but there is not data analysis to support this statement. This could be quantified by analyzing average MR1-HA fluorescence intensity across the cell volume compared to the bright fluorescence intensity of the non-cytoplasmic MR1-HA regions. Similarly, the number and intensity of the SQSTM1 foci should be quantified. Quantification is required to make the stated conclusions.__

      We thank the reviewer for their helpful suggestions regarding the microscopy experiments. Quantification of the data has now been added, including MR1 fluorescent intensity and the number of SQSTM1 foci, which supports the data from Figure 4A. The methods and figure legend have been updated to include more details of the analysis pipeline.


      __ Other statistical concerns:

      1. Some of the figure legends do not clearly state the number of independent experiments performed (2D, 3C-D, 5A, SF2, SF3, SF5). If these experiments were only performed once, additional repeats and appropriate statistical analysis are necessary to validate any conclusions drawn from these results.__

      The number of replicates for each experiment are now included in the figure legends. __

      1. Was statistical analysis performed on the MR1 mRNA expression in Figure 5A, and how many independent experiments are shown? There appears to be a decrease in MR1 expression in the Stg7.1 KO cells, which might impact the overall MR1 expression. Also, statistical analysis seems to be missing from 5B and 5C.__

      This figure has now been altered to reflect the number of replicates (2 biological replicates each consisting of 3 technical replicates) and statistical analysis has also been included. Statistical analysis for Figures 5B and 5C has also now been included. __

      1. In figure 5E, were there statistical comparisons between the Atg KO and control cells in the Ac-6-FP-treated non-CHX condition? It is unclear whether the statement "As previously observed, there was an increase in surface MR1 levels in Atg-depleted cells compared to the control in the presence of Ac-6-FP" is referring to the non-significant results in 3B or to this data presented in 5E. This statement should be revised to reflect the statistical significance of these data.__

      We thank the reviewer for this point. This figure has been amended to include a timecourse of CHX treatment in control and Atg depleted cell lines and statistical analysis has also been included. The statement has been clarified to highlight the point that CHX treatment does not affect the level of MR1 upregulation in control and knockdown cell lines.

      __

      Throughout the figures, several bar plots are missing the individual data points of experimental or technical replicates.__


      All bar plots display either the individual data points where donor cells were used or the average of 3 or more independent experiments with error bars denoting the standard deviation for experiments using cell lines.__

      1. The data in Figures 3C-D could be presented and analyzed as paired data (comparing the response from MAIT cells of each PBMC donor to the Ctrl cells vs the Atg KO clones) to better represent the impact of the KO.__

      We thank the reviewer for this suggestion. We believe that analysis via ANOVA is more appropriate in this instance due to the number of comparisons made with the control cells.__

      Other minor concerns:

      1. The conclusion "Overall, in the absence of SQSTM1, cellular changes induced by E. coli result in increased antigen presentation, which is not replicated with 5-OP-RU where MAIT activation may be adversely affected, implying that regulation of MR1 function by SQSTM1 may be dependent on the nature of the antigen" (page 6) is confusing and may need re-wording.__

      We are sorry for the confusion and have reworded this sentence to make it clearer. __

      1. The x-axis in the bar plots of Fig 3B labels the right group as "Ac-6-FP" in contrast to the histogram label and figure legend, which indicate the cells were treated with 5-OP-RU.__

      We thank the reviewer for pointing this out, the bar plot was indeed mislabelled and has now been corrected. __

      1. The presentation of data in Figure 5B is confusing. Perhaps the DMSO and Ac-6-FP conditions are mis-labeled? For the DMSO-treated samples, it appears that the data presented are percent surface MR1 GeoMean compared to the 0hr timepoint per cell lines. However, treating cells with Ac-6-FP should result in an increased surface MR1 expression (as seen in the non-CHX samples of Fig 5E, for example). If the data presented are percent of the 0hr DMSO control, wouldn't the % MR1 expression be higher for the Ac-6-FP samples than the DMSO samples? Alternately, it might be clearer to separate these two conditions onto separate plots, with % MR1 calculated relative to the 0 hr control of DMSO or Ac-6-FP treatment, respectively.__

      We thank the reviewer for pointing this out, the graph was indeed mislabelled and has now been corrected. The DMSO and Ac-6-FP treated samples are normalised to their own 0-hour timepoint (set at 100%) in order to directly compare the rate of decline of MR1 surface expression between the two conditions. This is now more clearly explained in the figure legend.

      __ Unclear in Figures 3 and 5 (and supplements) why all or only some of the Atg5 and 7 clones are used from experiment to experiment.__


      Please see our response to reviewer 1 on this point.__

      1. The discussion mentions "we found no evidence of an interaction between MR1 and AAKI" on page 9. What data supports this statement?__

      We found no evidence of an interaction between MR1 and AAK1 from our proteomics screen, this is now explained in the text.

      __ The discussion indicates that "This increase in SQSTM1 protein levels still resulted in increased MR1 surface levels and activation of MAIT cells, the same phenotype observed in SQSTM1-depleted cells" as it relates to the presence of E.coli. This statement is not fully supported by the data as SQSTM1 depletion did not lead to an increase in surface MR1 in E.coli treated cells.__


      We thank the reviewer for pointing this out, this sentence has now been corrected. __

      1. In the Proteomics/Mass Spec methods section on page 13, the citations to MaxQuant and Andromeda may need to be fixed.__

      We thank the reviewer for pointing this out, this has now been corrected. __

      1. There is no materials/methods section in the supplement. While most of this is covered by the main manuscript M/M section, there is no information on the IL12 and IL18 cytokine treatment, or treating with il12/il18 or isotype blocking antibody in SF1.__

      A methods section for the supplementary data has now been included. __

      1. Throughout the manuscript, several full stops are missing following in-text citations (ex: page 1, line 6 "...and Granzyme B 2-4 The microbial...").__

      We thank the reviewer for pointing this out, this has now been corrected.__

      1. The figure 1 legend should read "LC-MS/MS" rather than "LC-LC/MS"__

      We thank the reviewer for pointing this out, this has now been corrected.__

      1. Several of the citations need updating. They are listed as "Preprint available at ..." but for several of these references, the DOI links to the fully peer-reviewed publications, not a preprint.__

      We thank the reviewer for pointing this out, this has now been corrected.

      __

      Reviewer #2 (Significance (Required)):

      Significance

      Overall, this work expands the field knowledge of MR1 regulation and antigen presentation. The authors are the first to describe the putative role of key autophagy mediators like SQSTM1 and Atg5/7 in regulating MR1/MAIT cell activation. This report builds upon previous works exploring MR1 trafficking (Huang et al. JEM 2008, McWilliam et al. Nat Imm 2016, Harriff et al. PLoS Path 2016, Karamooz et al. Sci Rep 2019, McWilliam PNAS 2020, Huber et al. Sci Rep 2020) and MR1 protein stability (Abós et al. Biochem Biophys Res Commun 2011, Ussher et al. Eur J Immunol 2016, McWilliam et al. PNAS 2020, Kulicke et al. JBC 2022).

      This report would be of interest to researchers in the field of MR1 trafficking and antigen presentation, particularly in the context of increasing interest in targeting MR1 therapeutically (e.g. in cancer immunobiology or autoimmunity). From these results, future work could include characterization of the specific autophagy mechanisms which target MR1 for degradation, the role of SQSTM1 in modulating MR1 function via direct binding through autophagy or additional mechanisms, the variable mechanisms of MR1 trafficking and antigen presentation in the context of internal vs external ligand sources, and exploring if bacterial modulation of autophagy might impact MR1 antigen presentation.

      Expertise: MR1 trafficking and antigen presentation, MAIT cell activation, cell and molecular techiques, statistical analyses. Difficult to assess: the relevance of these marker in the autophagy field and evaluating the technical methods for LC-MS/MS.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      In the current report, Phalora et al., have identified a number of proteins that bind to human MR1. Some of them, including those associated with the peptide-loading complex, such as tapasin, have been identified by others as well. However, these authors found that molecules associated with autophagy-specifically, SQST1/p62-were negative regulators of MR1 surface expression. In other words, knocking out the gene encoding this protein enhanced MR1 expression in THP-1 cells pulsed with E. coli and consequent MAIT cell activation. Moreover, CRISPR/Cas9-mediated deletion of the autophagy proteins, Atg5 and Atg7, resulted in an even greater enhancement of MR1 surface expression. Chemicals that block autophagy had similar effects in both THP-1 and primary PBMC monocytes. Thus, for the first time, it has been demonstrated that, like in classical HLA class I molecules, autophagy plays a role in the surface expression of the MR1 antigen presenting molecule. Overall, the study is very interesting and technically well-done. I do have a few questions, concerns and criticisms that are indicated in the sections below.

      Major Comments: 1. It was stated in the text that they used an anti-MR1 mAb to demonstrate the effects on MAIT cell activation were indeed MR1-dependent, yet these data were not shown. Those experiments should be included in the supplemental data section.__


      We thank the reviewer for this suggestion, this data has now been included as a supplementary figure.

      __ The Discussion lacks a "big picture" assessment/speculation about how these observations fit within a particular disease or set of diseases__


      The discussion has now been revised to include assessment of how these findings fit into the wider scope of MR1 restricted T cells in health and disease.

      __ THP-1 and C1R are essentially cancer cells and it has been shown that MR1T cells likely recognize a tumor antigen presented by MR1. Rather than using purified MAIT cells for this study, the authors used purified CD8+ T cells. MAIT cells represent a portion of them. How many of the non-MAIT cells were activated by THP-1 and/or C1R cells? One could compare MAIT vs. MR1T cell activation depending on the APC type.__


      We thank the reviewer for this suggestion. We re-analysed some of the data to focus on the non-MAIT population but we were unable to identify a population of non-MAIT cells stimulated by co-incubation with Thp1 or CR1 cells. In general, MR1T cells are quite rare and difficult to isolate solely from the non-MAIT cell population.


      __ As autophagy proteins have been shown to be important for MHC class I and, thanks to this work, MR1, it would have been helpful to discuss other antigen presenting molecules (e.g., CD1d) and what this could mean in immune responses overall. How does this help the host?__


      We have now included a section in the discussion to address the wider significance of these findings for immune responses via antigen presentation and the implications for other antigen presenting molecules.

      __ Minor Comment: 1. Some parts of some figures (e.g., Fig. 1B) have text so small that it is extremely difficult to read. This would be problematic in a journal article.__


      We thank the reviewer for pointing this out, the text in the figure has now been adjusted to make it easier to read.

      __

      Reviewer #3 (Significance (Required)):

      This study shows, for the first time, that autophagy processes impact cell surface expression of MR1 and this depends upon the antigen. Because this phenomenon has been demonstrated previously for classical MHC class I molecules (ref. 28) and the lipid-presenting antigen presenting molecule CD1d (Autophagy 13:1025-1036, 2017), the novelty of their findings is somewhat diminished.

      An audience who would be interested in this work would include investigators who study antigen presentation to both classical and innate T cells.

      Keywords: antigen presentation; MAIT cells; MR1; autophagy; innate immunity__

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #3

      Evidence, reproducibility and clarity

      In the current report, Phalora et al., have identified a number of proteins that bind to human MR1. Some of them, including those associated with the peptide-loading complex, such as tapasin, have been identified by others as well. However, these authors found that molecules associated with autophagy-specifically, SQST1/p62-were negative regulators of MR1 surface expression. In other words, knocking out the gene encoding this protein enhanced MR1 expression in THP-1 cells pulsed with E. coli and consequent MAIT cell activation. Moreover, CRISPR/Cas9-mediated deletion of the autophagy proteins, Atg5 and Atg7, resulted in an even greater enhancement of MR1 surface expression. Chemicals that block autophagy had similar effects in both THP-1 and primary PBMC monocytes. Thus, for the first time, it has been demonstrated that, like in classical HLA class I molecules, autophagy plays a role in the surface expression of the MR1 antigen presenting molecule. Overall, the study is very interesting and technically well-done. I do have a few questions, concerns and criticisms that are indicated in the sections below.

      Major Comments:

      1. It was stated in the text that they used an anti-MR1 mAb to demonstrate the effects on MAIT cell activation were indeed MR1-dependent, yet these data were not shown. Those experiments should be included in the supplemental data section.
      2. The Discussion lacks a "big picture" assessment/speculation about how these observations fit within a particular disease or set of diseases
      3. THP-1 and C1R are essentially cancer cells and it has been shown that MR1T cells likely recognize a tumor antigen presented by MR1. Rather than using purified MAIT cells for this study, the authors used purified CD8+ T cells. MAIT cells represent a portion of them. How many of the non-MAIT cells were activated by THP-1 and/or C1R cells? One could compare MAIT vs. MR1T cell activation depending on the APC type.
      4. As autophagy proteins have been shown to be important for MHC class I and, thanks to this work, MR1, it would have been helpful to discuss other antigen presenting molecules (e.g., CD1d) and what this could mean in immune responses overall. How does this help the host?

      Minor Comment:

      1. Some parts of some figures (e.g., Fig. 1B) have text so small that it is extremely difficult to read. This would be problematic in a journal article.

      Significance

      This study shows, for the first time, that autophagy processes impact cell surface expression of MR1 and this depends upon the antigen. Because this phenomenon has been demonstrated previously for classical MHC class I molecules (ref. 28) and the lipid-presenting antigen presenting molecule CD1d (Autophagy 13:1025-1036, 2017), the novelty of their findings is somewhat diminished.

      An audience who would be interested in this work would include investigators who study antigen presentation to both classical and innate T cells.

      Keywords: antigen presentation; MAIT cells; MR1; autophagy; innate immunity

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      Summary

      The authors used a mass spectrometry proteomics approach to screen for proteins which interact with the MHC-I-related molecule MR1. In addition to expected interacting partners, they identified SQSTM1/p62, a selective autophagy mediator, and demonstrated that MAIT cell responses to fixed E. coli were increased with knockout of SQSTM1. The authors further investigated the role of autophagy in regulating MR1 ligand presentation through knockout of two key autophagy proteins, Atg5 and Atg7, or treatment with various autophagy inhibitors. MR1 surface expression and MAIT cell activation were variably increased following interruption of autophagy in the context of fixed E. coli or synthetic ligand treatment of human monocytes and B cell lines. The authors concluded that preformed pools of MR1 are regulated by autophagy.

      Major comments

      Overall, this is an interesting study that is the first to identify autophagy as a potential regulatory mechanism for MR1. There are a number of conceptual questions relevant to the model system. The main concerns regard a number of the conclusions made, given the analysis of the data as presented. These concerns are described in more detail below.

      Conceptual concerns:

      1. The investigators rightly note the challenge in studying MR1 protein due to low endogenous expression. However, the use of over-expressed MR1 protein begs some questions with regard to the identification of ER degradation and autophagy proteins (which as they note are also involved in the degradation of damaged and defective cellular components). Although they have previously shown that MR1-HA tagged protein goes to the cell surface and presents antigen, it is impossible to know what proportion of the over-expressed molecules are functional, and it is plausible that a proportion of these molecules that end up in ER degradation or autophagy pathways identified, but would still IP with the HA tag. In the data shown, it is not entirely clear that the impacts of the molecules are actually impacting MR1 protein absent overexpression. Example: In Figure 2, there is very little impact of the complete KO of SQSTM1 on MR1 protein expression in WT THP1 cells, despite this protein only interacting with MR1 in E.coli infected cells. In contrast, in the 5-OP-RU incubated cells, there is a difference in MR1 expression in the SQSTM1 mutant clones, but no impact to MAIT cell activation. The authors note these issues and discuss the possibility that the other functions of SQSTM1 are coming in to play and further look at Atg5 and Atg7, however the absence of these proteins also have no significant impact on the expression of MR1 protein. Can the authors comment on this? The authors state that the increase in MAIT cell responses to fixed E. coli-treated polyclonal populations of SQSTM1 KO cells (same cells as SF2D) was blocked by the use of an anti-MR1 antibody, but do not show this data. Why not done with clonal populations? It is unclear why this data was not shown as it would help to support that the impact of inhibited autophagy is really on the functional MR1 protein pool, rather than a pool of non-functional but still HA tagged MR1 that has been shunted to degradation or autophagy pathways.
      2. The conclusion that "regulation of MR1 by autophagy is not dependent on new protein synthesis and is most likely occurring on pre-existing pools of MR1" is not strongly supported by the data. If MR1 is processed normally through the golgi in Atg5 and 7 deficient cells (Figure 5D), how can the conclusion be made that the pre-existing pools of MR1 are in the ER? There is a non-significant decrease in MR1 surface expression from CHX treatment in the context of Ac-6-FP stimulation in Atg KO cells. This data is not clear enough to support a firm conclusion in either direction. Have the authors performed this experiment using 5-OP-RU or fixed E. coli as ligand sources? Is there a similar trend seen using the Atg KO C1R cells? Further supporting experiments may be necessary to conclude whether or not this trend is biologically relevant.

      Analysis of Western Blot data:

      1. There are many places throughout the manuscript where statements are made with regard to increases and decreases in the protein expression level with treatment, or comparisons between control and knockout samples. Although the legends generally indicate these experiments were based on at least 3 replicates (except some cases, where noted), there is no quantification of any western blotting data. There is no information in the legends or methods as to how much sample was loaded. Specific examples:
        • a. Figure 1/Supp Figure 1: Figure 1C and 1D: There are several differences in the inputs between the 2 blots, including differences in the no antigen samples (which should be the same) or presence of multiple bands in one blot for a given marker but not the other. Fig 1C: the band for Calreticulin in the immunoprecipitated E. coli-treated Thp1.MR1.HA samples (right lane) is very weak. Fig. 1D: the bands are weak and there is no clear difference for Calnexin in the immunoprecipitated 5-OP-RU treated Thp1.MR1.HA samples (right lane) compared to no ligand despite the conclusion that Calnexin weakly associates with MR1 in the context of 5-OP-RU ligand. Are some of these weak associations visible due to different inputs? Why are the input blots for anti-HA so different between the no antigen controls in the E coli vs 5-OP-RU blots? Supp Figure 1B: the +5-OP-RU pulldown of MR1.HA appears as to be more (like with E.coli), but no quantification. Why does so little B2M IP with 5-OP-RU MR1? Supp Figure 1D (and others): statements are made about increases and decreases without quantification. All: Presumably HSP90 is used as a loading control for the input, but this is not discussed nor is there quantification.
        • b. Supp Figure 5: The authors conclude there are no difference in protein interactions with MR1 in Atg5 or 7 deficient cells. By eye, there appear to in fact be differences, but there is no quantification to support the conclusions either iway. These data are subsequently used to make interpretive statements about the data in Figure 5. There is no indication of the number of times this experiment was performed.
        • c. Figure 4A: No quantification to support conclusions. Unclear why both blocking and inducing autophagy would both increase the amount of MR1 in cells.

      Analysis of Fluorescence microscopy data (Figure 4B):

      1. There are several concerns with the conclusions drawn from the fluorescence microscopy images (Figure 4B). How many images/fields were taken and cells analyzed per condition? How were individual fields chosen for imaging to be unbiased? Overall, the conclusions are observational and require quantification. For example, the authors indicate "an increase in MR1 cytoplasmic signal intensity following treatment...", but there is not data analysis to support this statement. This could be quantified by analyzing average MR1-HA fluorescence intensity across the cell volume compared to the bright fluorescence intensity of the non-cytoplasmic MR1-HA regions. Similarly, the number and intensity of the SQSTM1 foci should be quantified. Quantification is required to make the stated conclusions.

      Other statistical concerns:

      1. Some of the figure legends do not clearly state the number of independent experiments performed (2D, 3C-D, 5A, SF2, SF3, SF5). If these experiments were only performed once, additional repeats and appropriate statistical analysis are necessary to validate any conclusions drawn from these results.
      2. Was statistical analysis performed on the MR1 mRNA expression in Figure 5A, and how many independent experiments are shown? There appears to be a decrease in MR1 expression in the Stg7.1 KO cells, which might impact the overall MR1 expression. Also, statistical analysis seems to be missing from 5B and 5C.
      3. In figure 5E, were there statistical comparisons between the Atg KO and control cells in the Ac-6-FP-treated non-CHX condition? It is unclear whether the statement "As previously observed, there was an increase in surface MR1 levels in Atg-depleted cells compared to the control in the presence of Ac-6-FP" is referring to the non-significant results in 3B or to this data presented in 5E. This statement should be revised to reflect the statistical significance of these data.
      4. Throughout the figures, several bar plots are missing the individual data points of experimental or technical replicates.
      5. The data in Figures 3C-D could be presented and analyzed as paired data (comparing the response from MAIT cells of each PBMC donor to the Ctrl cells vs the Atg KO clones) to better represent the impact of the KO.

      Other minor concerns:

      1. The conclusion "Overall, in the absence of SQSTM1, cellular changes induced by E. coli result in increased antigen presentation, which is not replicated with 5-OP-RU where MAIT activation may be adversely affected, implying that regulation of MR1 function by SQSTM1 may be dependent on the nature of the antigen" (page 6) is confusing and may need re-wording.
      2. The x-axis in the bar plots of Fig 3B labels the right group as "Ac-6-FP" in contrast to the histogram label and figure legend, which indicate the cells were treated with 5-OP-RU.
      3. The presentation of data in Figure 5B is confusing. Perhaps the DMSO and Ac-6-FP conditions are mis-labeled? For the DMSO-treated samples, it appears that the data presented are percent surface MR1 GeoMean compared to the 0hr timepoint per cell lines. However, treating cells with Ac-6-FP should result in an increased surface MR1 expression (as seen in the non-CHX samples of Fig 5E, for example). If the data presented are percent of the 0hr DMSO control, wouldn't the % MR1 expression be higher for the Ac-6-FP samples than the DMSO samples? Alternately, it might be clearer to separate these two conditions onto separate plots, with % MR1 calculated relative to the 0 hr control of DMSO or Ac-6-FP treatment, respectively.
      4. Unclear in Figures 3 and 5 (and supplements) why all or only some of the Atg5 and 7 clones are used from experiment to experiment.
      5. The discussion mentions "we found no evidence of an interaction between MR1 and AAKI" on page 9. What data supports this statement?
      6. The discussion indicates that "This increase in SQSTM1 protein levels still resulted in increased MR1 surface levels and activation of MAIT cells, the same phenotype observed in SQSTM1-depleted cells" as it relates to the presence of E.coli. This statement is not fully supported by the data as SQSTM1 depletion did not lead to an increase in surface MR1 in E.coli treated cells.
      7. In the Proteomics/Mass Spec methods section on page 13, the citations to MaxQuant and Andromeda may need to be fixed.
      8. There is no materials/methods section in the supplement. While most of this is covered by the main manuscript M/M section, there is no information on the IL12 and IL18 cytokine treatment, or treating with il12/il18 or isotype blocking antibody in SF1.
      9. Throughout the manuscript, several full stops are missing following in-text citations (ex: page 1, line 6 "...and Granzyme B 2-4 The microbial...").
      10. The figure 1 legend should read "LC-MS/MS" rather than "LC-LC/MS"
      11. Several of the citations need updating. They are listed as "Preprint available at ..." but for several of these references, the DOI links to the fully peer-reviewed publications, not a preprint.

      Significance

      Overall, this work expands the field knowledge of MR1 regulation and antigen presentation. The authors are the first to describe the putative role of key autophagy mediators like SQSTM1 and Atg5/7 in regulating MR1/MAIT cell activation. This report builds upon previous works exploring MR1 trafficking (Huang et al. JEM 2008, McWilliam et al. Nat Imm 2016, Harriff et al. PLoS Path 2016, Karamooz et al. Sci Rep 2019, McWilliam PNAS 2020, Huber et al. Sci Rep 2020) and MR1 protein stability (Abós et al. Biochem Biophys Res Commun 2011, Ussher et al. Eur J Immunol 2016, McWilliam et al. PNAS 2020, Kulicke et al. JBC 2022).

      This report would be of interest to researchers in the field of MR1 trafficking and antigen presentation, particularly in the context of increasing interest in targeting MR1 therapeutically (e.g. in cancer immunobiology or autoimmunity). From these results, future work could include characterization of the specific autophagy mechanisms which target MR1 for degradation, the role of SQSTM1 in modulating MR1 function via direct binding through autophagy or additional mechanisms, the variable mechanisms of MR1 trafficking and antigen presentation in the context of internal vs external ligand sources, and exploring if bacterial modulation of autophagy might impact MR1 antigen presentation.

      Expertise: MR1 trafficking and antigen presentation, MAIT cell activation, cell and molecular techiques, statistical analyses. Difficult to assess: the relevance of these marker in the autophagy field and evaluating the technical methods for LC-MS/MS.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      In this study, Phalora et al identified the selective autophagy receptor SQSTM1/p62 as a MR1 interacting protein by proteomics approach using a cell line overexpressing MR1. While SQSTM1/p62 is implicated in autophagy regulation and autophagosome formation, genetic ablation of SQSTM1/p62 resulted in enhanced MAIT cell activation upon challenge with E. coli, but not with a synthetic agonist 5-OP-RU. In contrast, knockout of Atg5 and Atg7, both of which are involved in phagophore expansion engendered increased activation of MAIT cells upon both stimuli. From these data, the authors concluded that some factors in autophagy controlled the MR1 activity, thus the autophagy is a pivotal regulator of cellular antigen presentation.

      Major comments:

      1. The notion that "This regulation appears to occur at an early step in the trafficking pathway." in the summary appears not to be compatible with the present data. What the authors have shown in the study is possible implication of autophagy components such as SQSTM1/p62, Atg5, and Atg7 that are implicated in autophagosome and phagophore formation. Should the authors highlight an "early step of trafficking", Atg14L, Atg13, and/or Atg101 must be analyzed by genetic knockout in addition to PI3 kinase inhibitors that are supposed to affect an early step in autophagy. Such an approach could confirm whether the regulation of MR1 occurs at an early step of trafficking, or at least, at an early step of autophagy.
      2. In Figure 2, while the degree of β2M depletion from B1 appears to be superior to that in B6 (Figure 2A), why the former was more potent in producing IFN-γ relative to the latter upon E. coli and 5-OP-RU (Figure 2D)?
      3. In Figure 3B, right column, what is Ac-6-FP? The left histograms show MR1 expression level upon DMSO, E. coli, and 5-OP-RU challenge. There is no explanation.
      4. Also in the same figure, was MR1 geomeans in Control, 5-1, 5-2, 5-3, 7-1, 7-2, and 7-3 upon Ac-6-FP superior to DMSO? If so or not, please explain the rational.
      5. Figure 3C is highly intentional. If the authors put two left panels together (Control, 5-1, 5-2, and 5-3), is there still statistical difference among them?
      6. There was no explanation for Figure 4B why the authors used Hela-MR1-HA. Other cell lines were used in the rest of the experiments. It is highly desirable to perform the experiment with THP1-MR1-HA in terms of logical development.
      7. In addition, Figure 4B represent only the non-activated status. Given that association of SQSTM1/p62 with MR1 is dependent on E.coli and/or 5-OP-RU (Figure 1A), the same immuno-fluorescent imaging in the presence of the inhibitors upon stimulation with these reagents would also be desirable. It will uncover whether MR1 and SQSTM1/p62 colocalize upon stimulation, and such colocalization is perturbed in the presence of the inhibitors.
      8. Whereas the authors addressed the question as to at which stage MR1 is regulated in trafficking in Figure 5, there was no experiments with 5-OP-RU (an agonist for MAIT cells). This casts the doubt whether observed phenotype really represented the true MR1 trafficking, because there is no guarantee that the trafficking pathway for antagonist (Ac-6-FP) is same as that for agonist.
      9. Given the importance of MR1 overexpression in showing the association between MR1 and SQSTM1/p62, it is worthwhile to consider performing the knockout experiments with Thp1-MR1-HA rather than Thp1. It will further clarify the role(s) of SQSTM1/p62, Atg5, and Atg7 in MR1 trafficking and resultant MAIT cell activation.

      Minor comments:

      1.Please explain why the authors failed to detect IL23A in the coimmunoprecipitation. Should MR1-IL23A interaction be specific, what is a biological significance? 2. When Hela-MR1-HA was used, did the authors obtain the same results as Thp1-MR1-HA as shown in Figure 1C-D? This is relevant to the specificity in the interaction between MR1 and SQSTM1/p62 as shown in Figure 4B. 3. While S1, S2, S3, and S4 showed a similar degree of SQSTM1 depletion in Figure 2A, there was difference in the potential of IFN-γ production from MAIT cells among the clones. Only S4 showed decreased potential for IFN-γ upon 5-OP-RU, though E. coli failed to so. Contrary to 5-OP-RU, S1-S3 showed an enhanced potential while S4 failed to do so. Why is that so? 4. Given that there was little correlation between MR1 expression level and the potential of S1-S4 to promote or inhibit the ligand-dependent production of IFN-γ (Figure 2C right panel and Figure 2D), it is difficult to conclude that the factors implicated in autophagy play a pivotal role in MR1-dependent MAIT cell activation. 5. There was no consistency in the experimental design for Figure 5. Please explain the rational why the authors have used 7.1 in A and C, but not in B, D and E? 6. The control appeared to behave as 7.1 did. Was there statistical difference between 7.1 and 7.2 in Figure 5C? If so, what is the interpretation. 7. Time course over 6 h will be required to assess the MR1 expression in Figure 5C.

      Significance

      The present study uncovered the possible implication of autophagy factors in MR1 trafficking, in other words, MAIT cell activation. Although the previous study has demonstrated the importance of the protein loading factors (McWilliam et al., PNAS,117 24974-24985 2020), this study adds another pathway for MAIT cell activation. However, the conceptual significance is limited in that depletion of the factors pertinent to autophagy such as Atg5 and Atg7 in Thp1 resulted in rather weak interference in terms of MR1 trafficking and MAIT cell activation. Thus, this study will interest those who work in basic immunology, in particular, in regulation of antigen-presentation molecules and T cells as well as those who are in the field of MAIT cell biology.

      Although the field of this reviewer covers biochemistry, molecular biology, developmental biology, immunology and regenerative medicine, proteomics approach (in detailed technique) as seen here to identify the associated molecules is somewhat beyond the reviewer's expert.

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      Reply to the reviewers

      Reviewer #1

      1. The inverse relationship between PGCLC and DE efficiency is intriguing but under-explored. The observation that lines efficient for PGCLCs (Podx1, Kolf2) are poor at DE differentiation, and vice versa, is one of the key findings. Yet this is presented almost in passing. It would strengthen the paper considerably if the authors discussed whether their Polycomb-regulated gene set predicts DE efficiency with an inverse sign, and whether the logistic regression model can be tested on the DE data directly.

      As suggested by the reviewer, we have enhanced our analysis of definitive endoderm (DE) differentiation efficiency and discussed it more prominently in the manuscript in the section “A subset of Polycomb targets is predictive of differentiation properties”. In particular, we now examine the correlation between gene expression from RNAseq and DE differentiation. For this purpose, we took the genes used to predict PGCLC efficiency (all of which are regulated by H3K27me3), and examined the correlation between their expression and the efficiencies of PGCLC and DE differentiation. We found that that differentiation is not a binary outcome for DEs, with many intermediate cases observed. Thus, instead of using a logistic regression, we employed a sigmoidal regression scheme for DEs. For this analysis, we used the absolute difference between observed and predicted efficiency, resulting in a mean absolute error of 12% [95% CI: 8-22%].

      We have now included an extra panel (Figure 7C) showing the correlations between expression of the H3K27me3 genes and the differentiation efficiencies in both PGCLC and DE fates. As anticipated by the reviewer, this plot reveals an inverse correlation, which we highlight in the main manuscript. Further, we now mention that these genes can also be used to predict DE differentiation efficiency, with satisfactory accuracy (although the confidence interval is wide due to the small sample size, as in the case of PGCLCs).

      The mathematical model is elegant but the choice to vary parameter E across cell lines needs stronger justification. The model assumes that inter-line differences are driven by variation in the overall rate of H3K27 methylation (parameter E). This is a reasonable starting assumption, but the authors should discuss alternative scenarios more explicitly. Could variation in demethylase activity, PRC2 recruitment strength, or replication timing equally well explain the data? The fact that EPOP is differentially expressed is mentioned as a potential mechanistic candidate for modulating E, which is compelling, but the link remains correlative. The authors should be more cautious in their language here, stating that EPOP "may be sufficient to completely switch the transcriptional regulation" goes beyond what the data show.

      We thank the Reviewer for these suggestions and have tightened our discussion of these points. It is correct that variation in demethylase activity can also explain our data. We now explicitly point this out in the section “The behaviour of H3K27me3 can be explained using a simple mathematical model”. However, this possibility does not fit as well with the RNA expression data. While we found differential expression of the PcG gene EPOP, we did not detect any differential expression of the KDM6 histone demethylases (KDM6A-KDM6C). Therefore, we still favour our original suggestion of variation in the methylation rates over this possibility. In addition, we have moderated our wording on EPOP, stating in the Discussion that changes in EPOP expression “may be sufficient to alter the transcriptional regulation of specific target genes.”

      The predictive model for differentiation efficiency is promising but the PGCLC training set is too small for confident generalisation claims.The authors acknowledge this (109 features, ~21 data points), and the L2 regularisation is appropriate. However, the claim of 91% accuracy with a 95% CI of 78-100% on the PGCLC data should be presented more cautiously. With such a small dataset, the confidence interval is very wide. The more convincing validation comes from the DN data (143 lines from Jerber et al.), where the model trained on PGCLC data performs comparably to the full-transcriptome model. This cross-fate generalisation is quite strong and should be emphasised more prominently as the primary evidence for the validity of the model.

      We have followed the reviewer’s guidance and revised our language, when discussing the PGCLC case in the section “A subset of Polycomb targets is predictive of differentiation properties”. We have also emphasised more clearly the successful validation of the DN data.

      1. The claim of "epigenetic memory" during differentiation (iPSC to pre-ME) is suggestive but would benefit from additional analysis. The authors show that 60% of pre-ME DEGs overlap with iPSC DEGs, and that H3K27me3-cluster genes maintain their expression patterns. However, 60% overlap could partly reflect genes that are simply not regulated during the short 12-hour pre-ME induction. To strengthen this claim, the authors should compare the overlap rate for H3K27me3-cluster genes specifically versus other clusters. If Polycomb targets show significantly higher overlap than, for example, K4&ATAC genes, this would more convincingly support a Polycomb-specific memory mechanism.

      We have now performed this analysis, examining the persistence of DEGs into the pre-ME state (i.e., whether a gene that was differentially expressed in hiPSCs remains differentially expressed in pre-ME). Excluding the H3K9me3 cluster (the smallest cluster containing fewer than 25 genes), the K27 cluster is the most persistent cluster in terms of fraction of genes per cluster. When the clusters were pooled into the different variables involved (ignoring H3K9me3), H3K27me3 again emerged as the most persistent chromatin feature. Unfortunately, however, these results were not statistically significant, so we are unable to include them in the manuscript.

      Lack of genetic background analysis. Ten lines from nine donors will harbour substantial genetic variation. The authors note that genetic variation has been linked to iPSC heterogeneity but do not analyse whether the three "outlier" lines (Kucg2, Sojd3, Yoch6) share genetic features. For instance, common variants at PRC2 component loci, EPOP regulatory variants, or structural variants that might alter H3K27me3 domain boundaries. The HipSci consortium provides genotyping data for these lines. A targeted analysis of variants at Polycomb-related loci would be feasible and could either strengthen the epigenetic interpretation or reveal a genetic confounder.

      We thank the Reviewer for raising this important point. To investigate potential confounding effects due to genetic variation between the hiPSC lines in our panel, we performed a targeted analysis of genetic variation across Polycomb-related loci (H3K27me3 occupied loci and Polycomb group genes) in all ten cell lines (using whole genome sequencing data from the HipSci consortium). This analysis specifically tested whether the three “compromised” lines (Yoch6, Sojd3 and Kucg2) share consistent genetic variants relative to the seven “normal” lines. We identified 15 indels (out of 4115) that satisfied this criterium. However, all are located in non-coding regions and none overlap with ATAC-seq peaks. Hence, they are unlikely to function as gene regulatory elements (e.g., enhancers), but we cannot exclude the possibility that they affect gene expression in other ways. We have added a new Results section “Genetic variants shared between differentiation-compromised hiPSC lines” to discuss these points, as well as adding new text to the Discussion and Methods.

      Minor Comments

      The promoter definition ({plus minus}1 kb from gene start) is non-standard; most studies use a window upstream of the TSS rather than gene start. The authors mention they confirmed robustness to an alternative definition (-1 kb to gene start) but do not show this data. It should be included in the supplement.

      We now show the data for the alternative promoter definition in Supplementary Fig. 5B and Supplementary Fig. 7C. These results demonstrate that our conclusions are robust to different promoter definitions.

      For CUT&Tag, no spike-in normalisation is mentioned. Given that the key conclusions is based on quantitative comparisons of H3K27me3 levels across cell lines, the absence of spike-in controls is a potential concern. The authors should discuss whether technical variation between CUT&Tag libraries could contribute to the observed bimodality. At minimum, the correlation between replicates for H3K27me3 should be shown (presumably it is high, but this should be documented).

      We thank the Reviewer for this suggestion. As now shown in Supplementary Fig. 4C, the correlation between our H3K27me3 replicates is indeed high (R between 0.93 and 0.96). Hence, technical variation between CUT&Tag libraries is unlikely to contribute to the observed bimodality.

      The statistical test for the PGCLC/H3K27me3 overlap (p We thank the reviewer for noticing this. Indeed, this is the case. The test assumes independence of lines, which is in general a reasonable assumption, but may not always hold. Specifically, the Kolf2 and Kolf3 lines are derived from the same donor, which implies they are not completely independent. However, for all other lines, we still think independence is a reasonable assumption and, thus, the overall result of the test should be a good approximation. We have added this caveat to the manuscript.

      Figure 6A: the heatmaps for H3K4, ATAC and H3K27 are shown side by side but at apparently different scales; this should be clarified or made consistent.

      Indeed, the scales in all heatmaps are the same. We have clarified this in the captions of the figures.

      Reviewer #2

      1.) Figure 2B. Are all GO terms shown in the figure or are these just the top terms? If this is a suset then all terms should be provided as a supplemental table. If this is all significant terms, this is relitavely modest considering the number of DEGs (712) and is probably due to the fact that DEGs are derived from all comparisons and so could be diluted by the presence of multiple opposing effects. If this is the case, you could identify DEGs that define the PCA groupings and then re-run the GO analysis to potentially provide a better definition of the functional differences between groups of cell lines.

      The GO terms previously displayed were the top hits. We have now included all the significant terms in Supplementary Files 4 and 5 (for the Molecular Function and the Biological Process ontologies, respectively).

      Chromatin accessibility at gene promoters is a poor predictor of transcription, but it is likely that accessibility at distal regions (e.g putative enhancers) might be a better predictor. Did the authors look at this? This possibility should at least be mentioned when discussing the ATC-seq data and the lack of correlation with transcription.

      • *

      We thank the reviewer for this suggestion. To locate additional regulatory regions, we downloaded tracks for the enhancer-associated marks H3K4me1 and H3K27ac for the ten cell lines from Todd and colleagues (Todd et al., Genome Biology, 2025; https://genomebiology.biomedcentral.com/articles/10.1186/s13059-025-03658-8). We then intersected the ATAC-seq peaks with the H3K4me1 peaks in each cell line to identify putative enhancers. For each protein coding gene, we then identified the closest ATAC and H3K4me1 positive peak (among all cell lines), which we assumed was the most likely enhancer for that gene. We then evaluated the ATAC, H3K27ac and H3K27me3 signal within these enhancers for each cell line. With this information, we tried using a version of our SVM-based pipeline to improve our understanding of transcriptional regulation in genes within the ‘origin’ cluster (for which we failed to get significant insights from our standard SVM approach). Thus, we used seven variables as an input for the SVM: The four of the standard approach and three additional variables from the ATAC/H3K27ac/H3K27me3 signal at the nearest enhancer. However, for genes with an enhancer closer than 100kb, the performance of the SVM with enhancer variables was similar to the standard SVM (or slightly worse). If we focused on genes with enhancers 10kb or closer to the TSS (75 genes), then the SVM with the enhancer signal did modestly improve the prediction. However, when analysing the results more closely, it was only for a handful of genes (around 10) where the usage of the enhancer data was beneficial, and, even then, it was mostly down to the H3K27me3 signal rather than the more standard enhancer marks, such as H3K27ac or chromatin accessibility. This lack of improvement in the accuracy is probably due to our inability to identify the correct enhancers, as distance on the linear genome scale is often a poor predictor of enhancer-promoter interactions.

      Ultimately, because the improvement is for such a small number of genes, we have not included this analysis in the manuscript. However, we do now mention in the manuscript in section “Chromatin accessibility does not always correlate with transcription” that we tried to include distal enhancers but that this approach was not successful.

      2.) Fig 1C. Statistic overview at end of legend should be moved under section describing panel C in the legend.

      We have now made this change.

      3.) 'Furthermore, the transition value of 30% enables repression to be stably maintained even after DNA replication, when, on average, histone modification levels will be transiently halved'. Whilst this is potentially true and a plausible interpretation, you cannot exclude that the signal is not derived from different cell populations in the culture due to cellular heterogeneity such as cell cycle or spontaneous differentiation. This possibility should be noted in the text.

      We thank the Reviewer for this suggestion. Due to the possible alternative explanations pointed out by the reviewer, and to minimise any possible misunderstandings, we decided to drop this sentence from the manuscript, which is not required for any of our main conclusions.

      4.) 'Higher values indicate stronger correlation or anticorrelation and, thus, stronger differences between cell lines.' I don't believe this makes sense as written. Do the authors mean stronger partitioning of different iPSC lines into clusters?

      Indeed, this sentence wasn’t very clear -- we have now rewritten it to improve clarity: “Because absolute correlation values were used, high values indicate that expression profiles between two cell lines are either highly correlated or highly anticorrelated. Across all pairwise comparisons, high values suggest strong partitioning of cell lines with highly similar or markedly different transcriptional profiles.”

      5.) 'We found that 60% of the DEGs in pre-ME were also DEGs in hiPSCs'. This needs to be made clearer. Do the authors mean DEGs between iPSCs following differentiation or DEGs between undifferentiated iPSCs and their differentiated derivatives? The former suggests that the iPSCs are already partially differentiated and that differentiation in promoted or constrained by this starting state whilst the latter would suggest that some lines are skewed towards the mesendoderm.

      We mean that of the genes that are differentially expressed between the 10 lines in pre-ME, 60% were also differentially expressed between the 10 lines in iPSCs (prior to differentiation). We have reworded this sentence to make it clearer.

      6.) 'Finally, histone marks in the iPSC state were also predictive of expression in the pre-ME state, albeit with slightly lower accuracy than for the iPSC state (Supplementary Fig. 8C, D), which may indicate the existence of an epigenetic memory system that is maintained during differentiation.' Or the retention of an epigenetic signature that failed to be erased during the initial generation of the iPSCs.

      We agree with the reviewer that this is entirely possible: our point is that memory states may persist from iPSCs to pre-ME. The memory state may of course predate the initial generation of the iPSCs. We have amended the section “Pre-ME transcriptomes suggest inheritance along the developmental trajectory” to include this possibility.

      7.) 'To minimise the risk of overfitting, only reliable targets were retained'. Whilst this is outlined in the methods as stated, a summary of what this means should be included in the body text.

      We thank the Reviewer for this suggestion. We have included the required extra text in the section “A subset of Polycomb targets is predictive of differentiation properties”. We have also revised the performance metrics so that they are strictly comparable with the results of Jerber and colleagues (which implies, in some cases, removing error bars, as in the results of Jerber et al., 2021). The reviewer may notice differences in the values reported but all our claims remain valid.

      Reviewer #3

      The major claim that among histone modifications that have been profiled in this manuscript, H3K27me3 is the most predictive for expression is supported by the analysis. However the analysis may be skewed because the RNAseq and the H3K27me3 difference are driven by the extreme skewing of the 3 cell lines Yoch6, Sojd3 and Kucg (Fig 2A, 2C and 6A). Two of these lines cannot form EBs at all, a major failure in their pluripotent characteristics.

      We thank the reviewer for raising this fundamental point. Our aim for this study was to use iPSC lines that have passed existing standards and could easily be chosen from a panel of lines by an unsuspecting user. Indeed, the differentiation-compromised lines in our study are indistinguishable from other PSCs from a validated source that extensively characterises the distributed material (HipSci resource, https://www.hipsci.org). This source categorises these cell lines as correctly reprogrammed and fully pluripotent. In addition, we now present PluriTest data (doi: 10.1038/nmeth.1580) from all normal lines available from the HipSci resource (835 lines) and highlight the ten cell lines used in this study (see Supplementary Fig. 1A). All cell lines in our panel have pluripotency scores over 20, and all but one (Bima1 – which notably differentiates efficiently into PGCLCs and DNs) have novelty scores below 1.67; these values have been empirically determined as pluripotency signature thresholds (Müller et al., 2011). This analysis clearly demonstrates that the cell lines in our study are not outliers, an important fact which we have now added to section “Marked differences in the developmental efficiency of hiPSC lines”.

      Furthermore, one of the key advances of our study is that we identify a chromatin and transcription signature that will enable researchers in the stem cell community to identify iPSC lines with compromised differentiation potential early on. We also note that compromised differentiation potential is widespread among human PSCs. For example, Jerber et al. report that 48 out of 183 hiPSC lines could not be differentiated successfully into dopaminergic neurons (doi:10.1038/s41588-021-00801-6). Thus, our study addresses an important and widespread issue in the stem cell field, a point we now emphasise in the introduction of the manuscript.

      Further, one of the lines that can form EBs, fails to make PGCLCs but can differentiate into DE, Letw5 has neither the RNA profile nor the H3K27me3 profile of the skewed iPSC lines. Therefore, whether H3K27me3 truly influences phenotype at least in terms of PGCLC and DE differentiation of iPSCs is not supported by the analysis in the manuscript.

      We agree that the behaviour of Letw5 is interesting, and we discuss its properties extensively in section “Marked differences in the developmental efficiency of hiPSC lines” and Fig. 1E. As we state, comparing Letw5 with Kucg2, “These findings suggest that Kucg2 hiPSCs have limited developmental competence to generate PGCLCs, while Letw5 hiPSCs are capable of PGCLC specification but fail to sustain the germ cell fate, pointing to a defect in fate maintenance rather than in initial developmental capacity.” Hence, the evidence points towards Letw5 having a separate defect which is unrelated to the impaired Polycomb regulation identified in the other three problematic lines. We also emphasise this point in section " A major role for H3K27me3 in hiPSC transcriptional heterogeneity", where we state that "[...] in this case [Letw5], a distinct mechanism, independent of H3K27me3 dysregulation, may result in impaired germ cell development."

      1. What are the predictions from applying SVM to data from only the 6 cell lines Podx, Kolf2, Kolf3, Bima 1, Qolg1, Wibj2. The DE differentiation potential will also have to be measured for each of these cell lines.

      Following the reviewer’s suggestion, we applied the SVM only to data from those six cell lines (which do not include any of the defective cell lines), see section “Linking variation in chromatin features with transcriptional output using SVMs”. Given that the SVM only takes as input data from differentially expressed genes, the set of genes used decreased markedly as there are fewer genes differentially expressed among these cell lines (125 DEGs). Nevertheless, for this subset of genes, the SVM still retains satisfactory accuracy (both AUROC and overall accuracy in the 70% to 75% range; now shown in Supplementary Fig. 6H). This result is particularly remarkable given that the SVM is operating with very little data (five datapoints for training and one for testing, per gene) and that the cell lines are very similar to each other. As the reviewer points out, we hope these results might encourage other researchers to pursue similar analysis approaches.

      For DE differentiation, we previously included data (Supplementary Fig. 3B, C) for the following lines: Podx1, Kolf2, Kucg2, Letw5, Sojd3, and Yoch6. Only Kolf3, Bima1, Qolg1 and Wibj2 were missing. We have also now measured DE differentiation in three remaining lines (Kolf3, Qolg1, and Wibj2).

      The above analysis may also shed light on howextreme the input parameters must be for SVM to be a good classifier? Such an analysis may also assist future users of the method to assess whether SVM would be useful for their datasets.

      Please see our previous answer. We argue that the results presented above for six similar cell lines imply that this type of computational approach can have general applicability and does not require extreme inputs. We have followed the Reviewer’s suggestion and now incorporate this finding in section “Linking variation in chromatin features with transcriptional output using SVMs”: “Furthermore, the SVM does not require extreme values or outliers, and hence the overall approach could be of rather general applicability. As a performance verification, we applied the SVM to a dataset containing only the cell lines that could generate PGCLCs with high or intermediate efficiency, and while the performance is slightly reduced, it remains satisfactory (accuracy 75%; Supplementary Fig. 6H).”

      If the SVM on the 6 lines does not predict a binary switch in H3K27me3 to be predictive could the authors incorporate DNA methylation and H3K4me1 from the same publication as the chromatin accessibility. Such an analysis may also assist future users of the SVM method to assess the number of parameters required to separate closely related phenotypes.

      See previous answer. We note that DNA methylation data for our hiPSC panel is not available; it is not part of the study that the reviewer mentions (https://link.springer.com/article/10.1186/s13059-025-03658-8). Although H3K4me1 data is available in Todd et al., we did not find that this data improved the ability of our model to make successful predictions (see reply to Reviewer #2, point 1).

      Most gene regulation occurs at the level of the enhancer, restricting analysis to promoter associated histone modifications is limiting.

      We thank the Reviewer for raising this very valid point. Please see response to Reviewer #2, point 1.

      One puzzling piece of data is the very high 60% of PGCLCs on day 1 of differentiation (Fig 1E) in the competent cell lines. BLIMP1 is expressed in hiPSCs, calling into question whether the initial differentiation into pre-ME was successful.

      We think there is a misunderstanding regarding the experimental timeline. Day 1 of differentiation in Fig. 1E refers to one day after PGCLC induction from the pre-ME stage following the addition of BMP4, SCF, LIF, and EGF (see schematic in Fig. 1A). We have revised the text to make this clearer. Furthermore, BLIMP1 (PRDM1) is not expressed in hiPSCs. To demonstrate this, we now show the expression levels of BLIMP1 (PRDM1), B2M (low to mid-level expression in most human cell types), SOX2 (highly expressed pluripotency marker), and HOXC10 (differentiation marker that is not expressed in PSCs) across our cell line panel. At this scale, BLIMP1/PRDM1 expression is not detectable. When SOX2 is omitted from this bar plot, the very low expression levels of BLIMP1/PRDM1 become apparent, as it is close to the levels for the differentiation marker HOXC10. We conclude that BLIMP1/PRDM1 is expressed at extremely low levels across our ten hiPSC lines.

      The H3K27me3 and H3K9me3 signals are integrated over the entire gene as inputs into the SVM, however PCA analysis to separate the cell lines is only shown for the promoter

      This is not quite correct. For the PCA analysis for the histone marks and ATAC-seq, we used both the promoter region (Fig. 2C, Supplementary Fig. 5B) and the gene body (Supplementary Fig. 5A), with similar results. For the SVM, for H3K27me3 and H3K9me3, we primarily used the entire gene region, but we also tested other regions (Supplementary Fig. 6A), with similar or slightly inferior results.

      SVMs have been used to predict enhancers from epigenomic data PMID: 22328731 and to classify cancers PMID: 11120680. Applying SVM as classifier for gene expression prediction is not very novel.

      We thank the Reviewer for raising this point. We did not claim that the use of SVMs was itself novel. It has certainly been used in other contexts, as the reviewer points out, to predict enhancers, for cancer classification, and to predict expression patterns. In fact, SVMs had already been used to predict gene expression from chromatin features (Cheng et al, 2011; already cited in our manuscript). What is novel in our work is the reverse-engineering of the method to extract mechanistic information about each gene (i.e., assign a chromatin feature set relevant to the changes in expression). This computational methodology, in conjunction with the rich experimental dataset produced, allows us to classify differentially expressed genes in terms of the chromatin features that enable prediction of transcription. This highlights the differences between cell lines and enables further downstream analysis such as, mechanistic models of histone modification dynamics and the prediction of iPSC differentiation efficiency. We have rewritten the Introduction to the manuscript to better emphasise these points.

      The biological insights are limited. For example, the observation that " a variety of forms of transcriptional regulation" Fig 4B. It is well known that H3K27me3 decorates lineage specifying genes and is part of the bivalent domain with H3K4me3. The anti-ATAC category could represent locations where a repressor is bound DNA which would also result in increased accessibility and is not a surprising result.

      We believe our work does offer significant biological insights. While we agree that it is well known that H3K27me3 decorates lineage specifying genes, it was not previously known that digital Polycomb dysregulation at specific loci was a key feature controlling the ability of pluripotent cell lines to differentiate properly. In addition, we have been able to identify a core set of genes whose H3K27me3 profiles are highly informative for differentiation efficiency. Moreover, we are able to explain the variation in H3K27me3 levels by simple, quantitative, mathematical model.

      Finally, the anti-ATAC category is a minor finding and not one of the central conclusions of this paper. Nevertheless, we appreciate the Reviewer’s suggestion and have incorporated this possible interpretation into section “Chromatin accessibility does not always correlate with transcription”.

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      Referee #3

      Evidence, reproducibility and clarity

      Human induced pluripotent stem cells (iPSCs) have variable differentiation capability and can demonstrate bias toward specific lineages. In this manuscript, try to identify epigenetic features that may explain biased differentiation. They perform RNAseq and CUT and TAG for H3K4me3, H3K27me3 and H3K9me3 on 10 hiPSC lines which some of which show a opposing differentiation potential toward primordial germ cell like cells (PGCLCs) or definitive endoderm (DE). Using a support vector machine per gene that is variably expressed, they identify combinations of epigenetic marks and accessibility that could explain the change in expression. They identify H3K27me3 as a binary switch with high enrichment of this modification, predicting repression.

      The major claim that among histone modifications that have been profiled in this manuscript, H3K27me3 is the most predictive for expression is supported by the analysis. However the analysis may be skewed because the RNAseq and the H3K27me3 difference are driven by the extreme skewing of the 3 cell lines Yoch6, Sojd3 and Kucg (Fig 2A, 2C and 6A). Two of these lines cannot form EBs at all, a major failure in their pluripotent characteristics. Further, one of the lines that can form EBs, fails to make PGCLCs but can differentiate into DE, Letw5 has neither the RNA profile nor the H3K27me3 profile of the skewed iPSC lines. Therefore, whether H3K27me3 truly influences phenotype at least in terms of PGCLC and DE differentiation of iPSCs is not supported by the analysis in the manuscript. Further analysis that may support their claim

      1. What are the predictions from applying SVM to data from only the 6 cell lines Podx, Kolf2, Kolf3, Bima 1, Qolg1, Wibj2. The DE differentiation potential will also have to be measured for each of these cell lines.
      2. The above analysis may also shed light on how extreme the input parameters must be for SVM to be a good classifier? Such an analysis may also assist future users of the method to assess whether SVM would be useful for their datasets.
      3. If the SVM on the 6 lines does not predict a binary switch in H3K27me3 to be predictive could the authors incorporate DNA methylation and H3K4me1 from the same publication as the chromatin accessibility. Such an analysis may also assist future users of the SVM method to assess the number of parameters required to separate closely related phenotypes.
      4. Most gene regulation occurs at the level of the enhancer, restricting analysis to promoter associated histone modifications is limiting.
      5. One puzzling piece of data is the very high 60% of PGCLCs on day 1 of differentiation (Fig 1E) in the competent cell lines. BLIMP1 is expressed in hiPSCs, calling into question whether the initial differentiation into pre-ME was successful.
      6. The H3K27me3 and H3K9me3 signals are integrated over the entire gene as inputs into the SVM, however PCA analysis to separate the cell lines is only shown for the promoter The recommended analysis above is not substantial because it only requires missing DE differentiation in terms of experiments. Data and methods have sufficient detail to be reproduced.

      Referee cross-commenting

      I agree with the other reviewer comments

      Significance

      The data generated and differentiation are useful for the hiPSCs community.

      SVMs have been used to predict enhancers from epigenomic data PMID: 22328731 and to classify cancers PMID: 11120680. Applying SVM as classifier for gene expression prediction is not very novel.

      The biological insights are limited. For example, the observation that " a variety of forms of transcriptional regulation" Fig 4B. It is well known that H3K27me3 decorates lineage specifying genes and is part of the bivalent domain with H3K4me3. The anti-ATAC category could represent locations where a repressor is bound DNA which would also result in increased accessibility and is not a surprising result.

      Specialized for an audience of epigenetics and iPSC.

      My expertise is in epigenetics, cell identity specification and pluripotency. I do not have expertise to evaluate accuracy of compuational method.

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      Referee #2

      Evidence, reproducibility and clarity

      In this manuscript, Miangolarra and colleagues explore functional heterogeneity in human iPSC, a characteristic which can impact on their translational utility. They characterise the capacity of ten iPSCs lines to differentiate in to either mesendoderm, primordial germ cell-like cells and/or definitive endoderm and explore the mechanistic basis of this potential by interrogating their transcriptional and epigenetic status using 'omics' approaches and mathematical modelling. The authors find that the iPSCs group based on differentiation capacity and their underlying transcriptional and epigenetic status, partitioning that is most tightly associated with H3K27me3 patterns that are binary in nature.

      Key findings/outputs of the study: Inter-iPSC line variability in the differentiation tendency is reciprocal between PGCLCs and definitive endoderm.

      Distinct differentiation/or maintenance capacities of iPSCs are governed/marked by altered H3K27me3 signatures.

      Grouping of iPSC lines based on developmental capacity is demarcated by transcription profiles and their corresponding H3K27me3 patterns.

      Chromatin accessibility at gene promoters is a relatively poor predictor of transcriptional status.

      The transcription state of iPSCs is a good predictor of gene expression patterns following subsequent differentiation.

      H3K27me3 shows a somewhat binary relationship with gene expression which the authors liken to a digital signature that is consistent with the read-write activity of PRC2.

      A subset of H3K27me3 targets is strongly predictive of transcriptional state and differentiation capacity.

      A machine learning approach that utilises integrated epigenome status to predicts high or low gene expression with high accuracy in iPSCs.

      The authors present a large amount of high-quality data that is of broad interest to various fields as it provides: 1. Mechanistic insight into the epigenetic basis of gene regulation in human pluripotent cells. 2. A metric for assessing differentiation potential of pluripotent cells with important translational implications 3. Machine learning tools that could be of broad utility to the field of epigenetics and gene regulation (provided as well annotated code in Github).

      Whilst this reviewer is unable to provide an in-depth assessment of the machine learning approach presented, the modelling and data handling is accessible. Whilst this study does not provide substantial biological insights, the collective works is of broad utility and interest to various fields and I believe can be published once the following minor comments/concerns are addressed.

      Comments

      Figure 2B. Are all GO terms shown in the figure or are these just the top terms? If this is a suset then all terms should be provided as a supplemental table. If this is all significant terms, this is relitavely modest considering the number of DEGs (712) and is probably due to the fact that DEGs are derived from all comparisons and so could be diluted by the presence of multiple opposing effects. If this is the case, you could identify DEGs that define the PCA groupings and then re-run the GO analysisto potentially provide a better definition of the functional differences between groups of cell lines. Chromatin accessibility at gene promoters is a poor predictor of transcription, but it is likely that accessibility at distal regions (e.g putative enhancers) might be a better predictor. Did the authors look at this? This possibility should at least be mentioned when discussing the ATC-seq data and the lack of correlation with transcription.

      Fig 1C. Statistic overview at end of legend should be moved under section describing panel C in the legend.

      'Furthermore, the transition value of 30% enables repression to be stably maintained even after DNA replication, when, on average, histone modification levels will be transiently halved'. Whilst this is potentially true and a plausible interpretation, you cannot exclude that the signal is not derived from different cell populations in the culture due to cellular heterogeneity such as cell cycle or spontaneous differentiation. This possibility should be noted in the text.

      'Higher values indicate stronger correlation or anticorrelation and, thus, stronger differences between cell lines.' I don't believe this makes sense as written. Do the authors mean stronger partitioning of different iPSC lines into clusters?

      'We found that 60% of the DEGs in pre-ME were also DEGs in hiPSCs'. This needs to be made clearer. Do the authors mean DEGs between iPSCs following differentiation or DEGs between undifferentiated iPSCs and their differentiated derivatives? The former suggests that the iPSCs are already partially differentiated and that differentiation in promoted or constrained by this starting state whilst the latter would suggest that some lines are skewed towards the mesendoderm.

      'Finally, histone marks in the iPSC state were also predictive of expression in the pre-ME state, albeit with slightly lower accuracy than for the iPSC state (Supplementary Fig. 8C, D), which may indicate the existence of an epigenetic memory system that is maintained during differentiation.' Or the retention of an epigenetic signature that failed to be erased during the initial generation of the iPSCs.

      'To minimise the risk of overfitting, only reliable targets were retained'. Whilst this is outlined in the methods as stated, a summary of what this means should be included in the body text.

      Referee cross-commenting

      I agree with the other reviewer's comments.

      Significance

      The presented manuscript investigates the molecular basis of developmental potential heterogeneity in human iPSCs. The study is clear, well presented and provides sufficient detail on methodology, reagents and computational tools to allow reproducibility. The claims made are supported by the data and analysis.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      This study investigates the molecular basis of inter-line variability in human iPSC differentiation efficiency. The authors profile ten HipSci consortium hiPSC lines for transcriptome (RNA-seq), chromatin accessibility (ATAC-seq, from a prior study), and three histone modifications (H3K4me3, H3K9me3, H3K27me3) by CUT&Tag. They develop an SVM-based computational pipeline to link epigenomic variation to transcriptional differences across lines. The central findings are that H3K27me3 variation shows the most consistent inter-line differences, displays a bimodal (digital ON/OFF) distribution consistent with a mathematical model of PRC2 read-write feedback, and that a small set of Polycomb-regulated genes can predict differentiation efficiency into both PGCLCs and dopaminergic neurons. The authors also show that these transcriptional differences propagate into the pre-mesendoderm intermediate state, suggesting epigenetic memory during early lineage commitment. This is overall a very good study, with interesting and novel findings for the field. However, some issues should be addressed before publication:

      Major Comments

      1. The inverse relationship between PGCLC and DE efficiency is intriguing but under-explored. The observation that lines efficient for PGCLCs (Podx1, Kolf2) are poor at DE differentiation, and vice versa, is one of the key findings. Yet this is presented almost in passing. It would strengthen the paper considerably if the authors discussed whether their Polycomb-regulated gene set predicts DE efficiency with an inverse sign, and whether the logistic regression model can be tested on the DE data directly.
      2. The mathematical model is elegant but the choice to vary parameter E across cell lines needs stronger justification. The model assumes that inter-line differences are driven by variation in the overall rate of H3K27 methylation (parameter E). This is a reasonable starting assumption, but the authors should discuss alternative scenarios more explicitly. Could variation in demethylase activity, PRC2 recruitment strength, or replication timing equally well explain the data? The fact that EPOP is differentially expressed is mentioned as a potential mechanistic candidate for modulating E, which is compelling, but the link remains correlative. The authors should be more cautious in their language here, stating that EPOP "may be sufficient to completely switch the transcriptional regulation" goes beyond what the data show.
      3. The predictive model for differentiation efficiency is promising but the PGCLC training set is too small for confident generalisation claims. The authors acknowledge this (109 features, ~21 data points), and the L2 regularisation is appropriate. However, the claim of 91% accuracy with a 95% CI of 78-100% on the PGCLC data should be presented more cautiously. With such a small dataset, the confidence interval is very wide. The more convincing validation comes from the DN data (143 lines from Jerber et al.), where the model trained on PGCLC data performs comparably to the full-transcriptome model. This cross-fate generalisation is quite strong and should be emphasised more prominently as the primary evidence for the validity of the model.
      4. The claim of "epigenetic memory" during differentiation (iPSC to pre-ME) is suggestive but would benefit from additional analysis. The authors show that 60% of pre-ME DEGs overlap with iPSC DEGs, and that H3K27me3-cluster genes maintain their expression patterns. However, 60% overlap could partly reflect genes that are simply not regulated during the short 12-hour pre-ME induction. To strengthen this claim, the authors should compare the overlap rate for H3K27me3-cluster genes specifically versus other clusters. If Polycomb targets show significantly higher overlap than, for example, K4&ATAC genes, this would more convincingly support a Polycomb-specific memory mechanism.
      5. Lack of genetic background analysis. Ten lines from nine donors will harbour substantial genetic variation. The authors note that genetic variation has been linked to iPSC heterogeneity but do not analyse whether the three "outlier" lines (Kucg2, Sojd3, Yoch6) share genetic features. For instance, common variants at PRC2 component loci, EPOP regulatory variants, or structural variants that might alter H3K27me3 domain boundaries. The HipSci consortium provides genotyping data for these lines. A targeted analysis of variants at Polycomb-related loci would be feasible and could either strengthen the epigenetic interpretation or reveal a genetic confounder.

      Minor Comments

      • The promoter definition ({plus minus}1 kb from gene start) is non-standard; most studies use a window upstream of the TSS rather than gene start. The authors mention they confirmed robustness to an alternative definition (-1 kb to gene start) but do not show this data. It should be included in the supplement.
      • For CUT&Tag, no spike-in normalisation is mentioned. Given that the key conclusions is based on quantitative comparisons of H3K27me3 levels across cell lines, the absence of spike-in controls is a potential concern. The authors should discuss whether technical variation between CUT&Tag libraries could contribute to the observed bimodality. At minimum, the correlation between replicates for H3K27me3 should be shown (presumably it is high, but this should be documented).
      • The statistical test for the PGCLC/H3K27me3 overlap (p < 0.04, combinatorial argument) assumes independence of lines, which may not hold if genetic relatedness or batch effects are present. This should be noted.
      • Figure 6A: the heatmaps for H3K4, ATAC and H3K27 are shown side by side but at apparently different scales; this should be clarified or made consistent.

      Referee cross-commenting

      I agree with the comments from other reviewers

      Significance

      This paper makes a primarily conceptual advance in understanding why iPSC lines differ in their differentiation capacity. The key insight is that Polycomb regulation operates in a digital (bistable) fashion at specific loci, and that this digital behaviour both explains the sharpness of inter-line transcriptional differences and enables prediction of differentiation outcomes from a small gene set. This work will be of broad interest to the stem cell biology community, particularly those working on iPSC-based disease modelling and cell therapy where line-to-line variability is a major practical challenge. The mathematical modelling component will appeal to quantitative/systems biologists interested in chromatin regulation. The computational pipeline may find applications beyond iPSCs, in any setting where epigenomic and transcriptomic data are available across multiple conditions.

      Reviewer expertise: Developmental biology, chromatin regulation, iPSC differentiation, epigenetics.

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      Reply to the reviewers

      Reviewer #1

      Evidence, reproducibility and clarity

      *Specific comments for revision - Major:

      1) The benchmarking framework relies heavily on simulated mixtures as ground truth. However, these mixtures are derived from intracellular RNA profiles and may not fully capture the biological characteristics of cfRNA, including fragmentation patterns, differential release mechanisms, and extracellular stability. This raises concerns about whether the reported performance truly reflects real-world cfRNA scenarios. The authors should explicitly discuss the limitations of this pseudo-ground truth and the potential biases introduced by the simulation design. Incorporating cfRNA-specific features or alternative validation strategies would strengthen the reliability of the conclusions.*

      Response: The reviewer highlights the framework's reliance on simulated mixtures, which may not fully capture the complexity of real-world cfRNA samples. We acknowledge this limitation and agree that simulated data cannot completely reproduce all biological and technical characteristics of cfRNA. Nevertheless, simulation-based benchmarking remains the current standard for systematically evaluating deconvolution methods because the true tissue and cell-type composition of cfRNA samples is not known. To improve the biological realism of our simulations, we incorporated two cfRNA-specific features: (i) the introduction of negative binomial noise to model technical and biological variability and (ii) the removal of rapidly degrading transcripts based on mRNA half-life, as published cfRNA data show rapidly degrading transcripts to be underrepresented.

      To further address the reviewer's comments, improving representation of simulations to cell free RNA, we will include an additional cfRNA-specific benchmarking scenario based on detectability-filtered simulations. The simulated mixtures will be restricted to genes that are consistently detected across multiple published cfRNA cohorts and diseases, thereby better reflecting the subset of transcripts that are reliably measurable in cell free RNA.

      2) The manuscript clearly demonstrates that cell type-of-origin deconvolution is substantially less robust than tissue-level inference. However, the explanation remains largely descriptive, focusing on transcriptional similarity and reference incompleteness. A deeper mechanistic analysis is needed to understand the root causes of this limitation. In particular, the authors should consider discussing the impact of collinearity between cell-type signatures, the identifiability of mixture models, and the role of signal-to-noise ratio in cfRNA data. Providing quantitative or theoretical insights would significantly enhance the contribution of the study.

      Response: The reviewer highlights that the difference in performance between tissue- and cell-type-level inference is not fully explained. Our discussion focused on the larger number of potential contributors in COO inference, its greater sensitivity in signal-to-noise, and the ability of different methods to handle correlated signatures. TOO was evaluated using approximately 30 merged tissue groups, whereas COO inference used approximately 80 merged cell-type groups. The larger COO label space increases model dimensionality and the number of potential misassignment routes. Regarding signal-to-noise ratio, noise and degradation perturbations affect both TOO and COO inference, but COO is expected to be more sensitive because the transcriptional differences separating related cell types are smaller than those separating broader tissue groups. We evaluated seven deconvolution methods with different underlying assumptions across multiple reference configurations using matched TOO and COO frameworks. The observed variation across method–reference combinations indicates that both reference design and method-specific handling of correlated signatures, model constraints, and noisy inputs influence deconvolution robustness. The reviewer also correctly points out that collinearity between cell-type signatures may contribute to the reduced performance. To investigate this, we will calculate pairwise similarities between the reference signatures for all tissue and cell-type categories in each TOO and COO reference matrix. Analysis that is being undertaken suggests higher collinearity among the COO signatures. We will further examine the relationship between signature collinearity and deconvolution error to support per-cell-type error than versus per-tissue error.

      3) The current evaluation focuses on reconstruction accuracy and correlation with biochemical markers, such as ALT. However, it remains unclear whether improved deconvolution performance translates into better clinical prediction or disease classification. Given the importance of cfRNA in biomarker discovery, the authors should consider evaluating the downstream utility of deconvolution outputs. For example, comparing predictive performance between raw cfRNA features and deconvolved proportions in classification or survival models would provide a more comprehensive assessment of practical value.

      Response: We thank the reviewer for this excellent suggestion regarding the clinical utility of deconvolution outputs. We agree that evaluating whether improved deconvolution performance translates into better disease classification, prediction, or prognostic models would be an important step toward demonstrating the practical value of cfRNA deconvolution. However, we believe that such analyses are beyond the scope of the current manuscript. The primary objective of this study was to systematically benchmark tissue- and cell-type-level cfRNA deconvolution in a whole-body setting by comparing multiple deconvolution methods across different parameter settings and reference configurations. Our focus was therefore on establishing the analytical performance and robustness of existing deconvolution approaches rather than evaluating their downstream clinical applications. Importantly, a rigorous assessment of predictive performance would require carefully curated disease-specific cohorts, appropriate clinical endpoints, and models tailored to individual clinical questions, all of which introduce additional sources of variability beyond the deconvolution task itself. We agree that comparing disease classification or survival models based on raw cfRNA expression with those incorporating deconvolved tissue or cell-type proportions is a valuable direction for future work, and we will highlight this in the Discussion.

      4) All evaluated methods belong to classical frameworks, including regression-based, Bayesian, and optimization-based approaches. Recent advances in machine learning, such as deep generative models and representation learning, are not considered in this study. The manuscript would benefit from discussing whether the observed limitations are intrinsic to the deconvolution problem or specific to current methodologies. Including a perspective on emerging approaches would improve the relevance of the work.

      Response: This point is similar to that raised by Reviewer 2 (Major Point 3), related to advanced machine learning-based deconvolution approaches absent in our benchmark. We focused on benchmarking methods that have previously been applied to cfRNA deconvolution. While deep learning methods have recently emerged for transcriptomic deconvolution in less complex settings (reviewed in https://doi.org/10.1016/j.csbj.2025.05.038), they have not yet been systematically evaluated in a body-wide cfRNA deconvolution framework. To address this point, we will expand our benchmark by including the recently developed deep learning-based deconvolution method DECODE and evaluate its performance in cell-free RNA settings. In addition, we will expand the Discussion to provide a broader perspective on emerging machine learning approaches for deconvolution, discussing whether the limitations identified in this study primarily reflect fundamental challenges of the cfRNA deconvolution problem (e.g., reference collinearity and low signal-to-noise ratio) or limitations of current methodologies, as well as the potential suitability of these emerging approaches for cell-free transcriptomic applications.

      *Specific comments for revision - Minor:

      1) The study primarily relies on mean absolute error and Pearson correlation. While these metrics are appropriate, they may not fully capture compositional differences in deconvolution results. Including additional evaluation metrics would provide a more comprehensive assessment.*

      Response: We thank the reviewer for this helpful suggestion. To provide an additional evaluation, we will include the Jensen–Shannon divergence (JSD) for each method–reference combination across the different deconvolution scenarios. As a distribution-based metric, JSD complements the existing performance measures by quantifying differences in the overall composition of the inferred tissue or cell type proportions. Because JSD depends on the number of categories in the composition, these comparisons will be performed within the same reference dataset, allowing us to assess how different deconvolution methods redistribute mass across a common set of tissues or cell types.

      2) Although the methods are described, it is not entirely clear whether default parameters were used consistently across tools or whether any tuning was performed. Providing more explicit details on parameter settings would improve reproducibility and allow fairer comparison across methods.

      Response: In the revised manuscript, we will provide more explicit details on the parameter settings to improve reproducibility. We will clarify whether the default parameters were used for each deconvolution method or whether any parameter tuning was performed, and include the relevant parameter settings in the Methods section.

      Significance

      This manuscript presents a comprehensive benchmarking study of tissue- and cell type-of-origin deconvolution methods in plasma cell-free RNA (cfRNA). The authors systematically evaluate seven widely used approaches across multiple simulated and clinical datasets, considering both methodological variability and reference-dependent effects. The inclusion of realistic simulation settings, such as noise and transcript degradation, together with validation on diverse clinical cohorts, strengthens the practical relevance of the work. The study addresses an important gap in the field, as cfRNA deconvolution is increasingly used in liquid biopsy applications but lacks standardized evaluation frameworks.

      Reviewer #2

      Evidence, reproducibility and clarity

      The authors are evaluating the performance of seven cell-type deconvolution methods using cytoplasm-free mRNA. More specifically, they are benchmarking these methods at tissue and cell type levels, assigning the tissue or cell type of origin (TOO or COO) to the mixture. Using a benchmark relevant to the cfRNA context, they demonstrate that determining TOO is simpler than estimating COO. They also demonstrate that, overall, BayesPrism is the most reliable method for deconvoluting the cfRNA signal. Finally, the study has a more translational focus, correlating cfRNA deconvolution from a published dataset with biomarkers linked to tissue damage. The authors found that the results of RNA deconvolution are linked to biomarkers and could potentially be used to retrieve the disease-associated signal produced by injured tissue. COO is less correlated with the biomarkers than TOO, and BayesPrism outperformed the other deconvolution tools tested, strengthening the previous benchmarks.

      Major comments: The manuscript is well structured and written relatively clearly. My main concern about the study is the choices made in its design. It is not always clear from the manuscript or the figures why these choices were made. While these choices are correct, their justification is either absent or poorly stated. This includes: - the removal of 10-40% of rapidly degrading rRNA from the signature matrices - central vs random (5, 10) reference profiles - maximum signature sizes - inner/outer merges on figure S7.

      Response: In the revised version, we will provide rationale for the design decisions used in the manuscript. We will provide clearer justification for the removal of rapidly degrading mRNA from the signature matrices, the use of central versus random reference profiles, the maximum signature sizes, and the inner versus outer merge strategies used in Figure S7.

      Another concern is that most end users are more interested in the relative differential abundance of cell types/tissues between samples than in the absolute proportions of cell types/tissues. Could the author create a figure showing which method can identify the cell types/tissues that are differentially present between samples, as the results can differ from the overall accuracy?

      Response: We thank the reviewer for this valuable suggestion. We agree that, in many applications, users are more interested in relative differences in tissue or cell type abundance between samples. In the current manuscript, relative abundances of tissues and cell types of interest are presented in several figures, including Figures 6 and 7 and Supplementary Figures S12, S14, and S15. To address the reviewer's suggestion more directly, we will include an additional figure in the revised manuscript showing the distribution of estimated proportions for each tissue or cell type across individual samples, stratified by disease group and by study cohort. This will facilitate the identification of tissues and cell types that are differentially abundant between samples and complement the overall benchmarking results.

      The panel of chosen deconvolution methods is fine. However, I would add Scaden or preferably DECODE to complete the methods with a deep learning approach. The analyses seem reproducible, and the code is already available and well organized.

      Response: This point is similar to that raised by Reviewer 1 (Major Point 4). We will include DECODE in the revised benchmark and are currently training and evaluating DECODE for multi-organ cell-free RNA deconvolution task. Compared with Scaden, DECODE is a more suitable deep learning approach for this application. It is computationally efficient, which is advantageous for this more complex task, and, by design, can accommodate heterogeneous reference datasets with substantial batch effects.

      Minor comments:

      There are too many commas in the affiliations.

      Response: This will be corrected in the resubmission.

      The manuscript needs to cite Svenningsen et al. (2024): https://doi.org/10.1002/jev2.12511, as, to my knowledge, it is the only previous study of deconvolution from extracellular RNA.

      Response: We will cite this reference in the revised manuscript.

      Correlation figures such as S2A should be colored by cell type/tissue. If this results in too many colours, some cell types should be merged.

      Response: This will be corrected in the resubmission. We will highlighting selected tissues and cell type examples. Including all 30 tissues and 80 cell types would make the figure uninterpretable, and merging would undermine the individual tissue and cell-type interpretation.

      • *

      Figure 4B: It is difficult to assess what constitutes a good result. Please add points of the ground truth if relevant.

      • *

      Response: Figure 4B shows the estimated proportions of brain cell types following deconvolution of bulk RNA-sequencing data derived from brain tissue. The expected total proportion across all inferred brain cell types is 100%. The purpose of this analysis is to evaluate how different method–reference combinations using the brain-augmented reference influence the inferred composition of brain cell types. We will revise the figure legend to clarify this.

      There is a repetition in the Fig S7 legend (augmented with augmented with).

      Response: This will be corrected in the resubmission.

      Significance

      *The use of deconvolution on cfRNA is novel and could contribute to bridging the gap between the development of deconvolution methods and their application, for example in a clinical context. This demonstrates that cell type (or tissue) deconvolution could be employed in personalized medicine applications.

      The study also provides insights into how to benchmark deconvolution in the context of cfRNA, such as depleting low-half-life mRNA.

      While this work does not present any new deconvolution methods, datasets or benchmarks outside the context of cfRNA, I believe its contribution is significant enough to be published and to reach a wide audience, ranging from deconvolution method developers to bioinformaticians working in the field of personalized medicine.

      An interesting development of this work would be to further close the gap between benchmarks and the clinical use of cfRNA deconvolution by providing clearer usage guidance and testing it experimentally. Expertise of the reviewer: OMICS analyses, cell-type deconvolution*

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      Referee #2

      Evidence, reproducibility and clarity

      The authors are evaluating the performance of seven cell-type deconvolution methods using cytoplasm-free mRNA. More specifically, they are benchmarking these methods at tissue and cell type levels, assigning the tissue or cell type of origin (TOO or COO) to the mixture. Using a benchmark relevant to the cfRNA context, they demonstrate that determining TOO is simpler than estimating COO. They also demonstrate that, overall, BayesPrism is the most reliable method for deconvoluting the cfRNA signal. Finally, the study has a more translational focus, correlating cfRNA deconvolution from a published dataset with biomarkers linked to tissue damage. The authors found that the results of RNA deconvolution are linked to biomarkers and could potentially be used to retrieve the disease-associated signal produced by injured tissue. COO is less correlated with the biomarkers than TOO, and BayesPrism outperformed the other deconvolution tools tested, strengthening the previous benchmarks.

      Major comments:

      The manuscript is well structured and written relatively clearly. My main concern about the study is the choices made in its design. It is not always clear from the manuscript or the figures why these choices were made. While these choices are correct, their justification is either absent or poorly stated. This includes:

      • the removal of 10-40% of rapidly degrading rRNA from the signature matrices
      • central vs random (5, 10) reference profiles
      • maximum signature sizes
      • inner/outer merges on figure S7.

      Another concern is that most end users are more interested in the relative differential abundance of cell types/tissues between samples than in the absolute proportions of cell types/tissues. Could the author create a figure showing which method can identify the cell types/tissues that are differentially present between samples, as the results can differ from the overall accuracy?

      The panel of chosen deconvolution methods is fine. However, I would add Scaden or preferably DECODE to complete the methods with a deep learning approach. The analyses seem reproducible, and the code is already available and well organized.

      Minor comments:

      There are too many commas in the affiliations.

      The manuscript needs to cite Svenningsen et al. (2024): https://doi.org/10.1002/jev2.12511, as, to my knowledge, it is the only previous study of deconvolution from extracellular RNA.

      Correlation figures such as S2A should be colored by cell type/tissue. If this results in too many colours, some cell types should be merged.

      Figure 4B: It is difficult to assess what constitutes a good result. Please add points of the ground truth if relevant.

      There is a repetition in the Fig S7 legend (augmented with augmented with).

      Referees cross-commenting

      I mostly agree with Reviewer #1. I would not consider the following two points to be mandatory: - A deeper mechanistic analysis to understand the root causes of the difference between COO and TOO. While the question of why is of the utmost interest, I feel it is outside the scope of the manuscript. However, the authors could discuss the potential causes of these differences in more detail in the discussion and leave the question open for future work in this domain. - The default parameters of the tools used are clear in the GitHub repository associated with the manuscript. I will leave it to the editor to decide whether it is sufficient or whether the methods section should be clearer, as Reviewer #1 suggests. I have no strong opinion about it.

      Significance

      The use of deconvolution on cfRNA is novel and could contribute to bridging the gap between the development of deconvolution methods and their application, for example in a clinical context. This demonstrates that cell type (or tissue) deconvolution could be employed in personalized medicine applications.

      The study also provides insights into how to benchmark deconvolution in the context of cfRNA, such as depleting low-half-life mRNA.

      While this work does not present any new deconvolution methods, datasets or benchmarks outside the context of cfRNA, I believe its contribution is significant enough to be published and to reach a wide audience, ranging from deconvolution method developers to bioinformaticians working in the field of personalized medicine.

      An interesting development of this work would be to further close the gap between benchmarks and the clinical use of cfRNA deconvolution by providing clearer usage guidance and testing it experimentally.

      Expertise of the reviewer: OMICS analyses, cell-type deconvolution

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      Referee #1

      Evidence, reproducibility and clarity

      Specific comments for revision - Major:

      1) The benchmarking framework relies heavily on simulated mixtures as ground truth. However, these mixtures are derived from intracellular RNA profiles and may not fully capture the biological characteristics of cfRNA, including fragmentation patterns, differential release mechanisms, and extracellular stability. This raises concerns about whether the reported performance truly reflects real-world cfRNA scenarios. The authors should explicitly discuss the limitations of this pseudo-ground truth and the potential biases introduced by the simulation design. Incorporating cfRNA-specific features or alternative validation strategies would strengthen the reliability of the conclusions.

      2) The manuscript clearly demonstrates that cell type-of-origin deconvolution is substantially less robust than tissue-level inference. However, the explanation remains largely descriptive, focusing on transcriptional similarity and reference incompleteness. A deeper mechanistic analysis is needed to understand the root causes of this limitation. In particular, the authors should consider discussing the impact of collinearity between cell-type signatures, the identifiability of mixture models, and the role of signal-to-noise ratio in cfRNA data. Providing quantitative or theoretical insights would significantly enhance the contribution of the study.

      3) The current evaluation focuses on reconstruction accuracy and correlation with biochemical markers, such as ALT. However, it remains unclear whether improved deconvolution performance translates into better clinical prediction or disease classification. Given the importance of cfRNA in biomarker discovery, the authors should consider evaluating the downstream utility of deconvolution outputs. For example, comparing predictive performance between raw cfRNA features and deconvolved proportions in classification or survival models would provide a more comprehensive assessment of practical value.

      4) All evaluated methods belong to classical frameworks, including regression-based, Bayesian, and optimization-based approaches. Recent advances in machine learning, such as deep generative models and representation learning, are not considered in this study. The manuscript would benefit from discussing whether the observed limitations are intrinsic to the deconvolution problem or specific to current methodologies. Including a perspective on emerging approaches would improve the relevance of the work.

      Specific comments for revision - Minor:

      1) The study primarily relies on mean absolute error and Pearson correlation. While these metrics are appropriate, they may not fully capture compositional differences in deconvolution results. Including additional evaluation metrics would provide a more comprehensive assessment.

      2) Although the methods are described, it is not entirely clear whether default parameters were used consistently across tools or whether any tuning was performed. Providing more explicit details on parameter settings would improve reproducibility and allow fairer comparison across methods.

      Significance

      This manuscript presents a comprehensive benchmarking study of tissue- and cell type-of-origin deconvolution methods in plasma cell-free RNA (cfRNA). The authors systematically evaluate seven widely used approaches across multiple simulated and clinical datasets, considering both methodological variability and reference-dependent effects. The inclusion of realistic simulation settings, such as noise and transcript degradation, together with validation on diverse clinical cohorts, strengthens the practical relevance of the work. The study addresses an important gap in the field, as cfRNA deconvolution is increasingly used in liquid biopsy applications but lacks standardized evaluation frameworks.

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      Reply to the reviewers

      Response to Reviewer's Comments

      We thank the reviewers for their careful, constructive, and encouraging assessment of our manuscript. As described in detail in the point-by-point response below, we have extensively revised the manuscript and Supplementary Information. Together, these changes provide further support for the role of Rlig1 in neural function and visually guided behaviour during zebrafish development.

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      Summary: Provide a short summary of the findings and key conclusions (including methodology and model system(s) where appropriate).

      This study characterizes the function of RNA ligase 1 (Rlig1) in the vertebrate model zebrafish. Rlig1 is one of only two known RNA ligases in vertebrates, and its biological roles remain poorly understood. The authors combine gene expression analysis, loss-of-function approaches, transcriptomic profiling, calcium imaging, and behavioral assays to investigate its function during development. They show that loss of rlig1 (including maternal-zygotic loss) has no major effects on development or morphology, but that it leads to impairments in visually-guided behavior and altered neuronal activity in response to visual stimuli. Transcriptomic analyses reveal widespread dysregulation across multiple developmental stages, nominating genes that may underly the observed neural phenotypes. Together, the findings support a role for Rlig1 in neural development and function in vertebrates.

      We thank the reviewer for this accurate and positive summary of our study and for recognising the complementary, multi-level approaches used to examine the in vivo role of Rlig1.

      Major comments: - Are the key conclusions convincing?

      The key conclusion of this study is that Rlig1 plays an important role in the development and function of vertebrate neural circuits. Overall, this overarching conclusion, as well as the individual conclusions from each set of experiments, are well supported by the data presented. The combination of tissue-specific expression of rlig1, robust behavioral phenotypes in mutants, transcriptomic changes across multiple developmental stages, and circuit differences observed through calcium imaging provides a coherent, multi-faceted argument for the importance of this enzyme in brain development and function. While the precise RNA substrates of Rlig1 and the mechanistic link between transcriptomic changes and neural phenotypes remain to be defined, the authors clearly acknowledge these next steps and limitations. This study is a critical foundation for those future experiments.

      We appreciate the reviewer’s positive assessment of the strength and coherence of the evidence.

      • Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether?

      The claims in the manuscript are generally well-supported. The authors clearly acknowledge limitations and future experiments to further dissect mechanism in the Discussion section.

      • Would additional experiments be essential to support the claims of the paper? Request additional experiments only where necessary for the paper as it is, and do not ask authors to open new lines of experimentation.

      No major additional experiments appear essential for supporting the current claims.

      • Are the suggested experiments realistic in terms of time and resources? It would help if you could add an estimated cost and time investment for substantial experiments.

      No experiments are required for the current claims of the manuscript.

      We thank the reviewer for this assessment.

      • Are the data and the methods presented in such a way that they can be reproduced?

      The methods are generally well described. I would suggest that the "raw images, data, and source code for custom scripts used in this work" be made accessible without having to request from the authors. Zenodo provides up to 50 GB of storage, which is likely sufficient for the data presented in this manuscript. In particular, I think it is important to share the behavior analysis, calcium imaging pipeline, and transcriptomics analysis. Even if all the data is too large, a sample dataset and analysis scripts should be publicly available.

      We agree and thank the reviewer for this important suggestion. To ensure that the study can be reproduced without the need to contact the authors, we have made the underlying data and custom analysis code publicly accessible. The RNA-seq data have been deposited in the GEO repository under accession number GSE308510 and are available at https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE308510.

      In addition, the raw imaging data, behavioural and calcium-imaging datasets, processed data, and custom scripts used for the behavioural, calcium-imaging, as well as the tRNA and rRNA sequencing data have been deposited on KonDATA (DOI: 10.48606/vpwgm69277srrgaj) – together more than 190 GB – and can be accessed using this link: https://kondata.uni-konstanz.de/radar/en/dataset/vpwgm69277srrgaj?token=gLEaYEENHjmHBhjhHUHK.

      We have revised the Data and code availability statement in the manuscript accordingly.

      • Are the experiments adequately replicated and statistical analysis adequate?

      The experiments appear adequately replicated, and statistical analyses are appropriate for the types of data presented.

      We thank the reviewer for this positive assessment. To further improve transparency, we have revised the figure legends and Methods to define sample-size notation consistently throughout the manuscript. As suggested by Reviewer 3, we now distinguish biological replicates or independent experiments (N) from individual embryos, larvae, cells, imaging planes, or trials (n), as appropriate.

      Minor comments: - Specific experimental issues that are easily addressable. - Are prior studies referenced appropriately? - Are the text and figures clear and accurate? - Do you have suggestions that would help the authors improve the presentation of their data and conclusions?

      Throughout the manuscript: use the prime symbol for 5/3 DNA/RNA instead of an apostrophe. The prime symbol is present in a small number of sentences, but mostly the apostrophe is used.

      We thank the reviewer for noting this. We have replaced apostrophes with prime symbols throughout the manuscript to ensure consistent notation of 5′ and 3′ RNA/DNA termini.

      Line 227: "Next, we compared the total number of neurons". The elavl3 driver labels brain cells in addition to neurons. - The authors compared to the total number of brain cells, but can they make any comments on the size of the brain across the various areas? I imagine this data is also accessible by analyzing the imaging already collected.

      The elavl3 promoter is widely used as a pan-neuronal driver in zebrafish. Our calcium-imaging experiments used the Tg(elavl3:H2B-GCaMP8s) line, in which nuclear-localised GCaMP8s is expressed under the control of the elavl3 regulatory region. This established configuration enables brain-wide functional imaging of neuronal activity in larval zebrafish.

      To assess whether differences in regional brain size might contribute to the observed phenotype, we quantified brain dimensions in 5 dpf larvae using the existing imaging data. Measurements were performed manually in Fiji in a blinded manner, with genotypes assigned only after completion of the analysis. We quantified tectum width, hindbrain width, and tectum length, as illustrated in the new Supplementary Figure 6.

      MZrlig1 larvae showed a modest reduction in tectum width (MZrlig1: 299 ± 14 µm; WT: 312 ± 10 µm; one-sided t-test, p = 0.00125) and tectum length (MZrlig1: 122 ± 5 µm; WT: 134 ± 9 µm; one-sided t-test, p = 1.03 × 10⁻⁵). In contrast, hindbrain width did not differ between genotypes (MZrlig1: 164 ± 10 µm; WT: 164 ± 10 µm; one-sided t-test, p = 0.52). Following assessment of data distribution, statistical significance was evaluated using one-sided t-tests with Bonferroni correction for three comparisons (n = 18 MZrlig1 and n = 20 WT larvae).

      Importantly, the unchanged hindbrain width indicates that the reduced number of motion-responsive hindbrain neurons in MZrlig1 larvae is unlikely to be explained by a gross difference in hindbrain size. These findings therefore support our interpretation that Rlig1 loss is associated with reduced neuronal responsiveness in the hindbrain.

      Given that there is already a mouse mutant for this gene and transcriptomics, can the authors do a more thorough job comparing the transcriptomics from that study with their own?

      We thank the reviewer for this helpful suggestion. When we applied the differential-expression thresholds used in our zebrafish analysis (absolute log₂ fold change ≥ 1.5 and adjusted p value ≤ 0.05) to the genes reported in the mouse study, only flg2 met these criteria. Thus, the available mouse dataset provides limited scope for a direct gene-by-gene comparison with our data.

      To extend our analysis beyond poly(A)-enriched mRNA sequencing, we additionally performed tRNA and rRNA sequencing using total RNA from 5 dpf WT and MZrlig1 larvae. The tRNA analysis identified 17 significantly altered tRNAs in MZrlig1 larvae, including seven upregulated and ten downregulated species (Figure 5i; Supplementary Tables 8–9). Notably, the affected tRNAs include tRNA-Lys-CTT, which was previously identified among RNAs enriched in human Rlig1 immunoprecipitates, and tRNA-Thr-CGT, which was reported to be increased in female rlig1 knockout mouse brains. Although the direction of change is not fully conserved across these studies, these overlaps further support the possibility that Rlig1 influences tRNA homeostasis.

      In parallel, rRNA sequencing revealed differential abundance of 122 5S rRNA transcripts, with 86 upregulated and 36 downregulated in MZrlig1 larvae (Figure 5h; Supplementary Tables 10–11). Together, these new analyses show that loss of Rlig1 is associated with altered abundance of both tRNA and rRNA species, consistent with previous evidence linking Rlig1 to RNA homeostasis. At the same time, we explicitly state that these data do not identify direct enzymatic substrates of Rlig1, but provide a resource and rationale for future mechanistic studies.

      A clearer statement on the similarities and differences of Rlig1 and RtcB would be helpful. Is it possible RtcB is compensating at all?

      We thank the reviewer for this comment. We have clarified the similarities and differences between Rlig1 and RtcB in the Introduction and Discussion. Although both enzymes catalyse RNA ligation, they act on distinct end chemistries. RtcB mediates 3′–5′ ligation of RNA ends generated during canonical tRNA splicing, joining a 5′-hydroxyl end to a 2′,3′-cyclic phosphate or 3′-phosphate end. In contrast, Rlig1 catalyses 5′–3′ ligation of RNA fragments bearing a 5′-phosphate and a 3′-hydroxyl group.

      These distinct substrate requirements make direct functional compensation by RtcB unlikely. RNA ends generated for ligation by Rlig1 would first require end processing to generate termini compatible with RtcB-mediated ligation. Nevertheless, indirect compensation or partial functional overlap after such processing cannot be excluded.

      We sought to address this question experimentally by obtaining rtcb mutants from the European Zebrafish Resource Center. However, subsequent genotyping showed that the supplied sperm did not contain the intended rtcb mutant alleles, precluding analysis in the present study. We have therefore explicitly acknowledged that the extent to which RtcB may compensate for loss of Rlig1 remains unresolved and will require analysis of validated rtcb mutant lines in future work.

      I examined the DEG tables, and I did not notice an obvious substantial enrichment of genes on chromosome 25 (White et al., 2022, https://doi.org/10.7554/eLife.72825). Were the different samples from different clutches or the same clutch? I may have missed it. Regardless, I would carefully check the DEGs that are important for conclusions and check that they are not on the same chromosome as rlig1. It is likely worth rerunning all of the GO/GSEA with genes on chromosome 25 excluded.

      We thank the reviewer for raising this potential confound. The RNA-seq samples were derived from independent clutches. To determine whether the observed transcriptional changes could be influenced by local effects associated with the rlig1 locus on chromosome 25, we performed two complementary analyses.

      First, we examined the chromosomal distribution of differentially expressed genes (DEGs) at each developmental stage. The chromosomal distribution was assessed using the original DEG analysis presented in the manuscript (no pre-filtering before DESeq2; DEGs defined as padj 1). Chromosome 25 contains 806 of 25,254 annotated protein-coding genes in the zebrafish genome, corresponding to 3.2% of all coding genes. Across developmental stages, the proportion of DEGs located on chromosome 25 ranged from 1.4% to 4.1% (cleavage: 12/419; sphere: 17/; shield: 37/892; bud: 26/781; 1 dpf: 3/216; 5 dpf: 8/587). Relative to the genomic expectation, this corresponds to enrichment values between 0.43- and 1.30-fold. Only the shield stage showed a modest increase in the proportion of chromosome 25 DEGs (1.30-fold), whereas all other stages were at or below the genomic expectation. Thus, genes on chromosome 25 are not globally overrepresented among the DEGs in the rlig1 mutant dataset.

      Second, we repeated the complete differential-expression analysis for each developmental stage after excluding all chromosome 25 genes before DESeq2 normalisation, size-factor estimation, and dispersion modelling. This re-analysis was performed using an updated workflow, including removal of genes with zero total counts prior to DESeq2, which changes the number of genes entering Benjamini–Hochberg correction and consequently the total number of detected DEGs; all other analysis parameters were identical to the original analysis. This approach ensured that chromosome 25 genes could not influence either normalisation or statistical inference for genes on other chromosomes. Using the same DEG thresholds as in the original analysis (padj 1), exclusion of chromosome 25 had only minimal effects on the remaining DEG sets.

      Stage

      Full DEGs

      Non-Chr25 DEGs

      Lost (Chr25)

      Lost (non-Chr25)

      Gained

      1 (4-cell)

      419

      415

      5

      0

      1

      2 (Sphere)

      913

      879

      34

      5

      5

      3 (Shield)

      592

      553

      37

      5

      3

      4 (Bud)

      349

      329

      20

      0

      0

      5 (1 dpf)

      7

      6

      1

      0

      0

      6 (5 dpf)

      168

      164

      4

      0

      0

      Across all six developmental stages, only ten non-chromosome-25 genes lost significance and nine genes gained significance. These minor changes were confined largely to the sphere and shield stages, which also showed the highest relative representation of chromosome 25 DEGs. At the 4-cell, bud, 1 dpf, and 5 dpf stages, no non-chromosome-25 genes lost significance after chromosome 25 was excluded.

      We also repeated the GO and GSEA analyses after excluding chromosome 25 genes. As expected, a small number of individual terms changed; however, the principal enrichment patterns and overall biological interpretation remained unchanged. Together, these analyses indicate that the transcriptomic phenotype is not substantially driven by chromosome 25-linked DEGs or by local effects associated with the edited rlig1 locus. While this analysis cannot exclude effects on individual linked genes, it shows that such effects do not substantially affect the main transcriptional or pathway-level conclusions of the study.

      **Referees cross-commenting**

      I missed the point about the RNA-seq samples being cousin-matched. While I am optimistic that the results won't change, I agree with Reviewer #3 that some confirmation is necessary. It was unclear to me whether the samples were from the same or different clutches - if they are from different clutches and share overlapping genes, that would also add support to the results. I think that detail was missing from the methods, and I had pointed it out. Either additional RNA-seq or even qPCR of some top genes from a heterozygous incross is a reasonable request.

      We thank the reviewer for raising this point and apologise that the breeding design for the transcriptomic experiments was not described sufficiently clearly. The developmental RNA-seq samples were not cousin-matched. Rather, WT and MZrlig1 embryos were collected from separate group matings and therefore originated from different clutches. Independent pooled samples were analysed at each developmental stage, as now described explicitly in the revised Methods.

      We agree that independent validation in a sibling-controlled genetic setting is important. We therefore performed RT-qPCR for eight genes selected from the 5 dpf mRNA-seq dataset using sibling-matched zygotic rlig1 mutants and WT larvae generated by heterozygous incrosses. For each genotype, three independent biological replicates were analysed, with four larvae per sample. Six of the eight selected genes showed changes in the same direction as in the original MZrlig1 RNA-seq dataset: cyp2p9, itln3, sult3st4, fabp7b, hamp, and rlig1 itself. In particular, itln3 remained strongly upregulated, whereas rlig1 expression was markedly reduced in the sibling-matched zygotic mutants. In contrast, gdf3 and gstp1.1 did not show the same directional change in this validation experiment.

      These results provide independent support that several of the transcriptional changes identified in the MZrlig1 RNA-seq dataset are also observed in sibling-matched zygotic mutants. At the same time, the incomplete concordance of individual genes is consistent with the fact that maternal-zygotic and zygotic mutants represent biologically distinct conditions and may differ in both effect size and molecular consequences. We have added these validation data as Supplementary Figure 7 and revised the Results and Methods accordingly.

      Reviewer #1 (Significance (Required)):

      • Describe the nature and significance of the advance (e.g. conceptual, technical, clinical) for the field.

      This study provides a conceptual and biological advance by identifying a role for a vertebrate RNA ligase in brain development, behavior, and transcriptional regulation.

      • Place the work in the context of the existing literature (provide references, where appropriate).

      Although RNA ligases from single-cell organisms and phage are well-characterized, the roles of RNA ligases in vertebrates are relatively understudied. There are only two, including the one the one that is the focus of this manuscript. This study demonstrates an in vivo function for Rlig1, linking molecular changes to neural development and function. The Rlig1 enzyme was only very recently discovered (2023), making this work timely and an important addition to an area with relatively few studies.

      A major strength of the study is its multi-level approach, integrating diverse techniques to coherently link this gene to organism-level phenotypes. This work provides a strong conceptual and functional advance by demonstrating a role for Rlig1 in vertebrate neural circuit function and behavior. A remaining mechanistic gap is that the direct RNA substrates of Rlig1 are not identified, and the observed transcriptomic changes in mRNA are likely downstream consequences of its loss. However, these points are clearly acknowledged in the discussion, making the study a well-balanced contribution. Given the existence of a mouse knockout model, further discussion comparing the zebrafish transcriptomic results and phenotypes to those observed in mouse would help place this work in the context of prior studies. Overall, the main conclusions are well supported, and the limitations do not undermine them. This study represents an important contribution that establishes a foundation for future mechanistic work linking Rlig1 substrates to the observed phenotypes.

      We thank the reviewer for this thoughtful and encouraging assessment.

      • State what audience might be interested in and influenced by the reported findings.

      Zebrafish basic science researchers, particuarly those studying how genes lead to altered neural circuits and behavior, are the most direct target audience. However, the work is of more broad interest to those in the fields of neurodevelopment, gene regulation, and RNA biology / processing.

      • Define your field of expertise with a few keywords to help the authors contextualize your point of view. Indicate if there are any parts of the paper that you do not have sufficient expertise to evaluate.

      I am comfortable evaluating zebrafish mutants, transcriptomics, and behavioral assay design. I have more limited experiment in neural circuit anaysis and interpretation of calcium imaging data, though this part of the manuscript was also clearly presented and understandable.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary Klusman et al have investigated the function of the RNA ligase rlig1 in zebrafish. They first document expression of the gene, by quantitative RT-PCR and HCR-fluorescent in situ hybridization. They then test ligase activity of the Rlig1 protein in vitro. They next generate a null mutant and test function of the visual system using behaviour as well as calcium imaging. The data indicate that rlig1 is broadly expressed and capable of ligating RNA; loss of rlig1 has mild effects on overall development and pronounced effects on behavioural and neuronal response to visual stimuli. Finally, the authors use bulk transcriptome analysis to identify changes in gene expression in the mutants.

      We thank the reviewer for this accurate summary of our study and for recognising that the behavioural and calcium-imaging results together support a role for rlig1 in visual processing and visually guided behaviour.

      **Referees cross-commenting**

      I agree that more details are required about the crosses would be useful.

      We also agree that further detail on the breeding schemes is important. We have therefore expanded the Methods and figure legends to describe the crosses used for each experiment, including the relationship between mutant and control animals and whether samples were sibling- or cousin-matched.

      Reviewer #2 (Significance (Required)):

      Overall, the conclusions that rlig1 is required for normal development of the embryo, especially of a fully functioning visual system, are well supported. The optomotor response experiments have high power and, together with functional imaging, show a clear difference between mutant and wildtype.

      One limitation of this manuscript is in the characterization of gene expression. The gene expression database in Zfin contains one image of rlig1 (https://zfin.org/ZDB-IMAGE-060710-1925#image), which shows broad expression in cells of the embryo and larvae and no expression in the yolk. The images here, with the exception of the mutant in Figure 3C, show expression in the yolk. This would suggest that the yolk signal is not autofluorescence, which is inconsistent with the Thisses' data. Additonally, Figure S1 indicates a variable level of non-specific signal, especially in panel g. Thus, the distribution of rlig1 mRNA is unclear.

      We agree that the yolk-associated signal should not be interpreted as specific rlig1 expression.

      rlig1 transcripts are completely absent from the RNA-seq datasets of MZrlig1 mutants at all developmental stages analysed. Thus, the variable fluorescence observed in the yolk and in the no-probe controls (Supplementary Figure 1) cannot represent residual rlig1 expression, but must reflect non-specific background signal and/or autofluorescence. We have clarified this point in the revised manuscript.

      The transcriptome analysis identified changes in gene expression in the mutant. This establishes a role for rlig1 in development, and identifies several processes that are disrupted by loss of rlig1. However, the molecular analysis sheds little light on direct targets of the ligase. Given the established effects on tRNA, for example, it is unclear why RNA was analysed only by short reads on poly(A) RNA. The reader is left wondering whether zebrafish tRNA contains introns that require Rlig1 for processing. In this context, it would be useful for the authors to provide more background on tRNA splicing in vertebrates, including a mention of tricRNA, and potentially the role of TSEN complex in brain development.

      We have expanded the Introduction as suggested to provide additional context on tRNA splicing in vertebrates. We now explain that canonical tRNA splicing is initiated by the TSEN complex and completed by RtcB, which ligates RNA ends with chemistries distinct from those used by Rlig1. We also discuss that excised tRNA introns can form stable tRNA intronic circular RNAs (tricRNAs), and that defects in TSEN complex components are associated with neurodevelopmental disorders, underscoring the importance of RNA processing for nervous-system development.

      We agree that our poly(A)-enriched RNA-seq data do not identify direct RNA substrates of Rlig1. We have clarified throughout the manuscript that these experiments were designed to characterise downstream transcriptional consequences of rlig1 loss.

      We have additionally analysed tRNA and rRNA abundance in total RNA from 5 dpf WT and MZrlig1 larvae. These analyses identified altered levels of specific tRNA and 5S rRNA species in MZrlig1 larvae (Figure 5h,i; Supplementary Tables 8–11), supporting an association between Rlig1 loss and altered RNA homeostasis.

      To summarize, this manuscript extends work in the mouse and in cell lines that demonstrate a requirement for rlig1. It does not shed light on direct targets of Rlig1, but provides a strong foundation for future work on the role of RNA ligation in vertebrate development and brain function.

      This paper is expected to be of interest to a specialised audience.

      Minor points: The images showing gene expression in Figure 2 are not easy to see, due to the LUT used and low intensity of the signal. To aid the reader, the HCR channel should be shown in grayscale, possibly with the contrast enhanced (to the same extent in all images).

      To improve the visibility and interpretation of the HCR signal, we have added a new Supplementary Figure 2 showing the rlig1 channel in greyscale. Within comparable developmental-stage panels, identical contrast settings were applied to all images.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      Summary This paper provides good evidence that a newly described enzyme that catalyzes 5'-3' RNA ligation - rlig1 - plays some role in early vertebrate neurodevelopment. Using embryonic and larval zebrafish as a model, they found that, while rlig1 mRNA is highly maternally deposited and ubiquitously expressed early on, expression later in development localizes to the brain and eyes. They generated a stable CRISPR/Cas9 large deletion mutant spanning from upstream the 5'UTR past the start codon. By comparing wild type and maternal-zygotic (MZ) rlig1 mutants, the authors found that animals developed overtly normally but did show reduced behavioral responsiveness to a visual stimulus experimental paradigm. By combining calcium imaging and poly(A)-enriched RNA-sequencing transcriptomic analyses, they found that there was decreased neuronal activity in regions needed for visual processing, and that there was dysregulation of neural-related gene networks and metabolic and translational pathways.

      We thank the reviewer for this detailed and accurate summary of our study and for recognising the convergent evidence linking Rlig1 loss to altered neural activity and visually guided behaviour in developing zebrafish.

      Major comments 1) My main major comment is that, because there is so much inherent variability in behavior and even development across different clutches, this study relies on comparing (cousin-matched) WT and maternal-zygotic rlig1 mutant animals. In most reliable peer-reviewed papers, this is not a fair comparison. While I appreciate that authors stated that they used parents that were siblings (so, offspring would be cousin-matched), I do not consider this scientifically rigorous enough for the claims presented. a. I do not consider it a reasonable request to ignore the massive amount of work that went into this paper using WT and MZrlig1 comparisons. However, at minimum, authors should consider performing essential behavior and RNA-seq (see point b) experiments with heterozygous incrosses of single-pair matings, and genotyping the animals post-hoc. Including this critical data in a main figure, as the basis for using MZ animals for the rest of the paper, would induce some confidence that the phenotypes and claims presented are not a result of inherent variability. If the authors already have adult heterozygous animals of mating age, I estimate that these experiments may be completed very reasonably within 3-4 weeks; if new animals need to be generated, this request would take ~4 months. Typically, these kinds of experiments would not be considered a financial burden to perform.

      Our central genetic condition was maternal-zygotic loss of rlig1, motivated by the strong maternal deposition of rlig1 mRNA during cleavage stages. A heterozygous incross would produce zygotic mutants that still receive maternal rlig1 transcript and protein, and would therefore test a related but biologically distinct condition. For the maternal–zygotic experiments, we used cousin-matched WT controls derived from the same parental family to minimise genetic-background differences, and we performed the behavioural assays with substantial numbers of larvae across independent experiments.

      We nevertheless repeated the behavioural analysis as suggested using zygotic rlig1 mutants and WT sibling controls obtained from heterozygous incrosses. This analysis revealed a qualitatively similar, although less pronounced, reduction in visually guided behaviour in zygotic mutants (new Supplementary Figure 4). We speculate that the reduced effect size is consistent with partial compensation by maternally supplied rlig1 transcript or protein in zygotic mutants.

      b. For transcriptomic analyses, I have two main points: i) again, it is difficult to statistically rigorously compare transcriptomes of nonsibling-matched animals with such low numbers of single 5 dpf brains. In line with point a, it would be essential to pool at least a few WT and rlig1 mutant siblings for at least 3 biological replicates per samples and compare those analyses with the results from MZ animals. ii) Typically this would not be a major concern, however given the nature of the gene of interest and published in vitro findings, I do consider that the rlig1 enzyme catalyzes 5'-3' RNA ligation, has been shown to be implicated in rRNA integrity and tRNA targeting, and is broadly essential for repair, splicing, and editing of RNAs. Thus, while the poly(A)-enriched RNA sequencing can provide context about gene networks that are affected (either primarily or secondarily), sequencing that enriches for tRNAs, polysome profiling or ribosome profiling, or some more targeted sequencing approach would be more appropriate to more rigorously support the claims in the paper. Depending on readiness of mating-age animals, this experiment and analyses may reasonably take up to 3 months; this approach may be considered a financial burden. Alternatively, with the current mRNA sequencing, the authors could delve into whether they can identify altered splicing or RNA editing dynamics in different RNA modules. I estimate that this alternative analysis approach may take up to one month to develop and interpret.

      We would like to clarify that the poly(A)-enriched RNA-seq was not performed on single 5 dpf brains, but on independent pools of 8–10 age- and genotype-matched whole embryos or larvae collected across six developmental stages. We have also validated eight selected 5 dpf RNA-seq candidates by RT-qPCR using sibling-matched zygotic rlig1 mutants and WT larvae generated by heterozygous incrosses. For each genotype, we analysed three independent biological replicates, each comprising a pool of four larvae. Six of the eight tested genes showed changes in the same direction as in the original MZrlig1 RNA-seq dataset, including cyp2p9, itln3, fabp7b, hamp, sult3st4, and rlig1 (new Supplementary Figure 7). Although zygotic mutants are not equivalent to maternal–zygotic mutants because they retain maternally supplied rlig1 transcript and protein, these results provide independent support for a substantial subset of the transcriptional changes identified in the MZrlig1 dataset. We have revised the Methods, Results, and Discussion to describe the breeding schemes and this limitation more explicitly.

      We also agree that poly(A)-enriched RNA-seq alone cannot identify direct Rlig1 substrates or adequately assess non-polyadenylated RNA classes. We therefore added targeted analyses of tRNA and rRNA abundance from total RNA isolated from 5 dpf WT and MZrlig1 larvae. The tRNA analysis identified seven tRNAs with increased and ten with decreased abundance in MZrlig1 larvae, including tRNA-Lys-CTT, previously found among RNAs enriched in human Rlig1 immunoprecipitates, and tRNA-Thr-CGT, which was reported to be increased in female rlig1 knockout mouse brains (Figure 5i; Supplementary Tables 8–9). In parallel, the rRNA analysis identified altered abundance of 122 5S rRNA species, with 86 increased and 36 decreased in MZrlig1 larvae (Figure 5h; Supplementary Tables 10–11).

      These new data provide additional evidence that loss of Rlig1 is associated with altered tRNA and rRNA homeostasis. At the same time, we explicitly state that neither the mRNA-, tRNA-, nor rRNA-seq datasets establish direct enzymatic substrates of Rlig1 or demonstrate altered tRNA splicing, RNA editing, or translation. Direct substrate mapping and analyses such as ribosome profiling will be important directions for future work. The revised manuscript frames the transcriptomic analyses accordingly.

      o The experiments as documented are adequately replicated and statistical analyses adequate (minus the nonsibling-matched point 1). I note that labels should more clearly state or denote individual (n) or experimental (N) numbers, some of which I provide in Minor comments below.

      We agree and have revised the figure legends accordingly. We now distinguish N for independent experiments or biological replicates from n for individual embryos, larvae, imaging planes, segmented cells or trials. Where pooled samples were used, the legends and Methods now state the number of embryos or larvae per pool and the number of independent pools or experiments.

      Minor comments Comments on figures or figure legends: 1) Figure 1e, align the "#" labels better, they look diagonal.

      Thank you. We corrected the alignment of the labels in Figure 1e.

      2) For 1f, consider labeling independent replicates directly on the graph instead of just the label, otherwise not very clear to the reader.

      We have revised Figure 1f to make the independent replicates more transparent. The figure now clearly indicates the number of independent replicates used for quantification. Every replicate has a different colour now, and N = 3 is indicated in the figure.

      3) Figure 2a, consider adding the reference gene (eef1a) in the legend.

      We have added eef1a to the Figure 2a legend and clarified that relative rlig1 mRNA levels were calculated using eef1a as the reference gene.

      4) Figure 2a - if I understand the experiment correctly, the current label n=3 (which would mean 3 individual embryos/larvae) should read N=3 (three independent experiments of x number of embryos/larvae per run)

      Thank you very much for this suggestion. We have corrected the sample-size notation in Figure 2a. The label now uses N for independent experiments and specifies the number of embryos or larvae used per experiment where appropriate.

      5) Supplementary Figure 1 was very unconvincing comparing WT to MZ mutants, I'm sorry to say I really could not tell much difference. When compared to Figure 3c, they look quite different. The DRAQ7 labeling also appeared uneven in Supplementary Figure 1. Consider optimizing the imaging strategy and providing more interpretably images. A separate, aesthetic comment - magenta was very difficult for me to see against a black background, consider switching the rlig1 channel to grayscale or flip the colors so that rlig1 mRNA is cyan, for example.

      We thank the reviewer for this comment and apologise that the purpose of Supplementary Figure 1 was not sufficiently clear. This figure shows no-probe control samples imaged in the rlig1 detection channel to document stage-dependent background and autofluorescence. Because no rlig1 probe was applied, no genotype-dependent difference between WT and MZrlig1 samples is expected in these images. The variable signal, including the yolk-associated fluorescence, therefore represents background rather than specific rlig1 mRNA detection.

      In contrast, Figure 3c shows samples processed with the rlig1 HCR probe set. The marked reduction of punctate signal in MZrlig1 larvae in this experiment is therefore attributable to the absence of rlig1 transcripts, consistent with the RNA-seq and RT-qPCR data. We have clarified this distinction in the revised text and figure legends.

      The apparently uneven DRAQ7 signal in some no-probe control images reflects differences in embryo orientation and imaging planes rather than genotype-specific staining differences. To improve the visibility and interpretability of the HCR data, we have additionally included a new Supplementary Figure 2 showing the rlig1 channel in greyscale, with matched contrast settings within comparable developmental-stage panels.

      6) Calcium imaging - related to Major comments above, consider performing this experiment in sibling-matched animals, especially with only one copy of the transgene. If WT vs. sibling mutant results look similar to the WT vs MZ mutant results, this would be more convincing.

      We agree that calcium imaging in sibling-matched zygotic mutants would provide a valuable complementary dataset. However, zygotic mutants retain maternally supplied rlig1 transcript and protein and therefore represent a biologically distinct condition from the maternal–zygotic mutants examined in our principal imaging experiments. Consistent with this distinction, the behavioural phenotype in sibling-matched zygotic mutants was qualitatively similar but less pronounced than in maternal–zygotic mutants.

      A sufficiently powered brain-wide calcium-imaging analysis in sibling-matched animals would require generation, imaging, and analysis of a substantial additional cohort, while the expected smaller effect size would limit its ability to directly test the maternal–zygotic phenotype reported here. We therefore believe that this experiment extends beyond the scope of the present study.

      **Referees cross-commenting**

      I agree with Reviewer #1 that at least the raw code is uploaded to GitHub or Zenodo, and raw data to be uploaded to Zenodo.

      We agree and thank the reviewer for this important suggestion. To ensure that the study can be reproduced without the need to contact the authors, we have made the underlying data and custom analysis code publicly accessible. The RNA-seq data have been deposited in the GEO repository under accession number GSE308510 and are available at https://www.ncbi.nlm.nih.gov/geo/query/acc.cgi?acc=GSE308510.

      In addition, the raw imaging data, behavioural and calcium-imaging datasets, processed data, and custom scripts used for the behavioural, calcium-imaging, as well as the tRNA and rRNA sequencing data have been deposited on KonDATA (DOI: 10.48606/vpwgm69277srrgaj) – together more than 190 GB – and can be accessed using this link: https://kondata.uni-konstanz.de/radar/en/dataset/vpwgm69277srrgaj?token=gLEaYEENHjmHBhjhHUHK.

      We have revised the Data and code availability statement in the manuscript accordingly (also see the response to Reviewer #1).

      I agree with Reviewer #1 that brain size can and should also be assessed, presumably using the same images already collected. For example, in Figure 5b, number of neural cells (even when normalized) could be lower if brain size is small. Reasonable control analysis.

      As suggested, we have quantified tectum width, tectum length, and hindbrain width from the existing calcium-imaging datasets in a blinded manner. Although MZrlig1 larvae showed modest reductions in tectum width and length, hindbrain width did not differ between genotypes. Thus, the reduced number of motion-responsive hindbrain cells is unlikely to be explained by a gross difference in hindbrain size. These control analyses are presented in the new Supplementary Figure 6 (also see the response to Reviewer #1).

      I agree with Reviewer #2 that addressing, either by writing or experimentally, a bit more about direct targets of the ligase (including tRNAs and rRNAs) will strengthen the manuscript significantly.

      We thank the reviewer for this helpful suggestion. To address this point, we have added new analyses of rRNA and tRNA abundance in 5 dpf WT and MZrlig1 larvae, together with an expanded discussion of their interpretation. These data provide additional evidence that loss of Rlig1 is associated with altered RNA homeostasis, while we distinguish such effects from the direct RNA substrates of the ligase, which remain to be identified (also see the response to Reviewer #2).

      I agree with Reviewer #1 first comment (last sentence) that, if RNA-seq (or other appropriate sequencing) of sibling-matched samples is financially prohibitive, then at least qPCR of some top genes would be acceptable.

      We have performed RT-qPCR validation of selected top differentially expressed genes using sibling-matched WT and zygotic rlig1 mutant larvae generated by heterozygous incrosses. These data provide independent support for the altered expression of several genes identified in the maternal–zygotic rlig1 RNA-seq dataset and are presented in new Supplementary Figure 9 (also see the response to Reviewer #1).

      I agree with the additional comment from Reviewer #1 - the manuscript details cousin-matched samples in lines 666-667, but I'd like to add a suggestion that the authors include details about "single-pair" versus "group-mating". For behavior and all analyses in these kinds of zebrafish experiments, it is very important that multiple replicates of single-pair (one female crossed to one male), sibling-matched groups are used.

      We appreciate the reviewer’s helpful suggestion. We agree that further detail on the breeding schemes is important. We have therefore expanded the Methods to specify, for each experiment, whether embryos or larvae were obtained from single-pair or group matings, the number of independent crosses or clutches, and whether mutant and control animals were sibling- or cousin-matched.

      Reviewer #3 (Significance (Required)):

      This study provides a good increase in our knowledge about a newly described RNA ligase enzyme - rlig1 - in vivo. The authors integrate their results across organismal behavior, brain cell activity, and transcriptomes using a newly generated stable genetic mutant to uncover a new link between neuronal RNA processing, development, and sensory-motor computation. Given that the human orthologue of this gene has been associated with neurological and cognitive conditions, including neurodevelopmental and neuroinflammatory disorders and Alzheimer's disease, the generation and characterization of this stable mutant line proves valuable. There are important technical limitations, specifically related to the comparison of wild type and maternal-zygotic mutant animals, that may not faithfully represent statistical differences compared to sibling-matched animals. Basic biological audiences, including in neurodevelopment, genetics, and RNA biology, would be interested in this research.

      We thank the reviewer for recognising the value of the stable rlig1 mutant line and for highlighting the importance of the breeding design. We agree that comparisons between cousin-matched WT and maternal–zygotic (MZ) mutant larvae require careful interpretation. However, a fully sibling-matched WT versus MZrlig1 comparison is not genetically possible. Maternal–zygotic mutants must be produced by homozygous mutant mothers, whereas WT siblings can only be obtained from a different maternal genotype. Thus, the maternal genotype and, critically, the presence or absence of maternally deposited rlig1 RNA and protein – necessarily differs between these conditions. This is not merely a technical limitation of the experimental design, but an intrinsic feature of testing maternal–zygotic gene function. A heterozygous incross instead produces sibling-matched zygotic mutants, which retain maternal rlig1 products and therefore represent a biologically distinct genetic condition rather than a direct replacement for the MZ comparison.

      For the MZ experiments, we minimised genetic-background differences by using cousin-matched controls derived from the same parental family and by analysing independent experimental replicates. Importantly, the principal behavioural finding was independently supported in sibling-matched zygotic mutants generated by heterozygous incrosses. These larvae showed a qualitatively similar reduction in visually guided behaviour, although with a smaller effect size (new Supplementary Figure 4). We also validated selected transcriptional changes in sibling-matched zygotic mutants by RT-qPCR (new Supplementary Figure 9). The weaker phenotype in zygotic mutants is consistent with partial buffering by maternal rlig1 transcript or protein. Future studies will be valuable to further separate how maternal and zygotic Rlig1 affects gene expression and visually guided behaviour.

      Insufficient expertise to evaluate: While I understand the first part of Figure 1, I do not have expertise in these sorts of assays. The rest of the experiments I do have sufficient expertise to evaluate. And thank you to the authors for providing direct DOI links to references.

      We are grateful for the reviewers’ detailed comments, which substantially improved the manuscript. We hope that the revised text and additional analyses address the central concerns and make the study more transparent and useful to the field.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary

      This paper provides good evidence that a newly described enzyme that catalyzes 5'-3' RNA ligation - rlig1 - plays some role in early vertebrate neurodevelopment. Using embryonic and larval zebrafish as a model, they found that, while rlig1 mRNA is highly maternally deposited and ubiquitously expressed early on, expression later in development localizes to the brain and eyes. They generated a stable CRISPR/Cas9 large deletion mutant spanning from upstream the 5'UTR past the start codon. By comparing wild type and maternal-zygotic (MZ) rlig1 mutants, the authors found that animals developed overtly normally but did show reduced behavioral responsiveness to a visual stimulus experimental paradigm. By combining calcium imaging and poly(A)-enriched RNA-sequencing transcriptomic analyses, they found that there was decreased neuronal activity in regions needed for visual processing, and that there was dysregulation of neural-related gene networks and metabolic and translational pathways.

      Major comments

      1) My main major comment is that, because there is so much inherent variability in behavior and even development across different clutches, this study relies on comparing (cousin-matched) WT and maternal-zygotic rlig1 mutant animals. In most reliable peer-reviewed papers, this is not a fair comparison. While I appreciate that authors stated that they used parents that were siblings (so, offspring would be cousin-matched), I do not consider this scientifically rigorous enough for the claims presented.

      a. I do not consider it a reasonable request to ignore the massive amount of work that went into this paper using WT and MZrlig1 comparisons. However, at minimum, authors should consider performing essential behavior and RNA-seq (see point b) experiments with heterozygous incrosses of single-pair matings, and genotyping the animals post-hoc. Including this critical data in a main figure, as the basis for using MZ animals for the rest of the paper, would induce some confidence that the phenotypes and claims presented are not a result of inherent variability. If the authors already have adult heterozygous animals of mating age, I estimate that these experiments may be completed very reasonably within 3-4 weeks; if new animals need to be generated, this request would take ~4 months. Typically, these kinds of experiments would not be considered a financial burden to perform.

      b. For transcriptomic analyses, I have two main points: i) again, it is difficult to statistically rigorously compare transcriptomes of nonsibling-matched animals with such low numbers of single 5 dpf brains. In line with point a, it would be essential to pool at least a few WT and rlig1 mutant siblings for at least 3 biological replicates per samples and compare those analyses with the results from MZ animals. ii) Typically this would not be a major concern, however given the nature of the gene of interest and published in vitro findings, I do consider that the rlig1 enzyme catalyzes 5'-3' RNA ligation, has been shown to be implicated in rRNA integrity and tRNA targeting, and is broadly essential for repair, splicing, and editing of RNAs. Thus, while the poly(A)-enriched RNA sequencing can provide context about gene networks that are affected (either primarily or secondarily), sequencing that enriches for tRNAs, polysome profiling or ribosome profiling, or some more targeted sequencing approach would be more appropriate to more rigorously support the claims in the paper. Depending on readiness of mating-age animals, this experiment and analyses may reasonably take up to 3 months; this approach may be considered a financial burden. Alternatively, with the current mRNA sequencing, the authors could delve into whether they can identify altered splicing or RNA editing dynamics in different RNA modules. I estimate that this alternative analysis approach may take up to one month to develop and interpret.

      The experiments as documented are adequately replicated and statistical analyses adequate (minus the nonsibling-matched point 1). I note that labels should more clearly state or denote individual (n) or experimental (N) numbers, some of which I provide in Minor comments below.

      Minor comments

      Comments on figures or figure legends:

      1. Figure 1e, align the "#" labels better, they look diagonal.
      2. For 1f, consider labeling independent replicates directly on the graph instead of just the label, otherwise not very clear to the reader.
      3. Figure 2a, consider adding the reference gene (eef1a) in the legend.
      4. Figure 2a - if I understand the experiment correctly, the current label n=3 (which would mean 3 individual embryos/larvae) should read N=3 (three independent experiments of x number of embryos/larvae per run)
      5. Supplementary Figure 1 was very unconvincing comparing WT to MZ mutants, I'm sorry to say I really could not tell much difference. When compared to Figure 3c, they look quite different. The DRAQ7 labeling also appeared uneven in Supplementary Figure 1. Consider optimizing the imaging strategy and providing more interpretably images. A separate, aesthetic comment - magenta was very difficult for me to see against a black background, consider switching the rlig1 channel to grayscale or flip the colors so that rlig1 mRNA is cyan, for example.
      6. Calcium imaging - related to Major comments above, consider performing this experiment in sibling-matched animals, especially with only one copy of the transgene. If WT vs. sibling mutant results look similar to the WT vs MZ mutant results, this would be more convincing.

      Referees cross-commenting

      I agree with Reviewer #1 that at least the raw code is uploaded to GitHub or Zenodo, and raw data to be uploaded to Zenodo.

      I agree with Reviewer #1 that brain size can and should also be assessed, presumably using the same images already collected. For example, in Figure 5b, number of neural cells (even when normalized) could be lower if brain size is small. Reasonable control analysis.

      I agree with Reviewer #2 that addressing, either by writing or experimentally, a bit more about direct targets of the ligase (including tRNAs and rRNAs) will strengthen the manuscript significantly.

      I agree with Reviewer #1 first comment (last sentence) that, if RNA-seq (or other appropriate sequencing) of sibling-matched samples is financially prohibitive, then at least qPCR of some top genes would be acceptable.

      I agree with the additional comment from Reviewer #1 - the manuscript details cousin-matched samples in lines 666-667, but I'd like to add a suggestion that the authors include details about "single-pair" versus "group-mating". For behavior and all analyses in these kinds of zebrafish experiments, it is very important that multiple replicates of single-pair (one female crossed to one male), sibling-matched groups are used.

      Significance

      This study provides a good increase in our knowledge about a newly described RNA ligase enzyme - rlig1 - in vivo. The authors integrate their results across organismal behavior, brain cell activity, and transcriptomes using a newly generated stable genetic mutant to uncover a new link between neuronal RNA processing, development, and sensory-motor computation. Given that the human orthologue of this gene has been associated with neurological and cognitive conditions, including neurodevelopmental and neuroinflammatory disorders and Alzheimer's disease, the generation and characterization of this stable mutant line proves valuable. There are important technical limitations, specifically related to the comparison of wild type and maternal-zygotic mutant animals, that may not faithfully represent statistical differences compared to sibling-matched animals. Basic biological audiences, including in neurodevelopment, genetics, and RNA biology, would be interested in this research.

      Insufficient expertise to evaluate: While I understand the first part of Figure 1, I do not have expertise in these sorts of assays. The rest of the experiments I do have sufficient expertise to evaluate. And thank you to the authors for providing direct DOI links to references.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      Klusman et al have investigated the function of the RNA ligase rlig1 in zebrafish. They first document expression of the gene, by quantitative RT-PCR and HCR-fluorescent in situ hybridization. They then test ligase activity of the Rlig1 protein in vitro. They next generate a null mutant and test function of the visual system using behaviour as well as calcium imaging. The data indicate that rlig1 is broadly expressed and capable of ligating RNA; loss of rlig1 has mild effects on overall development and pronounced effects on behavioural and neuronal response to visual stimuli. Finally, the authors use bulk transcriptome analysis to identify changes in gene expression in the mutants.

      Referees cross-commenting

      I agree that more details are required about the crosses would be useful.

      Significance

      Overall, the conclusions that rlig1 is required for normal development of the embryo, especially of a fully functioning visual system, are well supported. The optomotor response experiments have high power and, together with functional imaging, show a clear difference between mutant and wildtype.

      One limitation of this manuscript is in the characterization of gene expression. The gene expression database in Zfin contains one image of rlig1 (https://zfin.org/ZDB-IMAGE-060710-1925#image), which shows broad expression in cells of the embryo and larvae and no expression in the yolk. The images here, with the exception of the mutant in Figure 3C, show expression in the yolk. This would suggest that the yolk signal is not autofluorescence, which is inconsistent with the Thisses' data. Additonally, Figure S1 indicates a variable level of non-specific signal, especially in panel g. Thus, the distribution of rlig1 mRNA is unclear.

      The transcriptome analysis identified changes in gene expression in the mutant. This establishes a role for rlig1 in development, and identifies several processes that are disrupted by loss of rlig1. However, the molecular analysis sheds little light on direct targets of the ligase. Given the established effects on tRNA, for example, it is unclear why RNA was analysed only by short reads on poly(A) RNA. The reader is left wondering whether zebrafish tRNA contains introns that require Rlig1 for processing. In this context, it would be useful for the authors to provide more background on tRNA splicing in vertebrates, including a mention of tricRNA, and potentially the role of TSEN complex in brain development.

      To summarize, this manuscript extends work in the mouse and in cell lines that demonstrate a requirement for rlig1. It does not shed light on direct targets of Rlig1, but provides a strong foundation for future work on the role of RNA ligation in vertebrate development and brain function.

      This paper is expected to be of interest to a specialised audience.

      Minor points:

      The images showing gene expression in Figure 2 are not easy to see, due to the LUT used and low intensity of the signal. To aid the reader, the HCR channel should be shown in grayscale, possibly with the contrast enhanced (to the same extent in all images).

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      Provide a short summary of the findings and key conclusions (including methodology and model system(s) where appropriate).

      This study characterizes the function of RNA ligase 1 (Rlig1) in the vertebrate model zebrafish. Rlig1 is one of only two known RNA ligases in vertebrates, and its biological roles remain poorly understood. The authors combine gene expression analysis, loss-of-function approaches, transcriptomic profiling, calcium imaging, and behavioral assays to investigate its function during development. They show that loss of rlig1 (including maternal-zygotic loss) has no major effects on development or morphology, but that it leads to impairments in visually-guided behavior and altered neuronal activity in response to visual stimuli. Transcriptomic analyses reveal widespread dysregulation across multiple developmental stages, nominating genes that may underly the observed neural phenotypes. Together, the findings support a role for Rlig1 in neural development and function in vertebrates.

      Major comments:

      • Are the key conclusions convincing?

      The key conclusion of this study is that Rlig1 plays an important role in the development and function of vertebrate neural circuits. Overall, this overarching conclusion, as well as the individual conclusions from each set of experiments, are well supported by the data presented. The combination of tissue-specific expression of rlig1, robust behavioral phenotypes in mutants, transcriptomic changes across multiple developmental stages, and circuit differences observed through calcium imaging provides a coherent, multi-faceted argument for the importance of this enzyme in brain development and function. While the precise RNA substrates of Rlig1 and the mechanistic link between transcriptomic changes and neural phenotypes remain to be defined, the authors clearly acknowledge these next steps and limitations. This study is a critical foundation for those future experiments. - Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether?

      The claims in the manuscript are generally well-supported. The authors clearly acknowledge limitations and future experiments to further dissect mechanism in the Discussion section. - Would additional experiments be essential to support the claims of the paper? Request additional experiments only where necessary for the paper as it is, and do not ask authors to open new lines of experimentation.

      No major additional experiments appear essential for supporting the current claims. - Are the suggested experiments realistic in terms of time and resources? It would help if you could add an estimated cost and time investment for substantial experiments.

      No experiments are required for the current claims of the manuscript. - Are the data and the methods presented in such a way that they can be reproduced?

      The methods are generally well described. I would suggest that the "raw images, data, and source code for custom scripts used in this work" be made accessible without having to request from the authors. Zenodo provides up to 50 GB of storage, which is likely sufficient for the data presented in this manuscript. In particular, I think it is important to share the behavior analysis, calcium imaging pipeline, and transcriptomics analysis. Even if all the data is too large, a sample dataset and analysis scripts should be publicly available. - Are the experiments adequately replicated and statistical analysis adequate?

      The experiments appear adequately replicated, and statistical analyses are appropriate for the types of data presented.

      Minor comments:

      • Specific experimental issues that are easily addressable.
      • Are prior studies referenced appropriately?
      • Are the text and figures clear and accurate?
      • Do you have suggestions that would help the authors improve the presentation of their data and conclusions?
      • Throughout the manuscript: use the prime symbol for 5/3 DNA/RNA instead of an apostrophe. The prime symbol is present in a small number of sentences, but mostly the apostrophe is used.
      • Line 227: "Next, we compared the total number of neurons". The elavl3 driver labels brain cells in addition to neurons.
      • The authors compared to the total number of brain cells, but can they make any comments on the size of the brain across the various areas? I imagine this data is also accessible by analyzing the imaging already collected.
      • Given that there is already a mouse mutant for this gene and transcriptomics, can the authors do a more thorough job comparing the transcriptomics from that study with their own?
      • A clearer statement on the similarities and differences of Rlig1 and RtcB would be helpful. Is it possible RtcB is compensating at all?
      • I examined the DEG tables, and I did not notice an obvious substantial enrichment of genes on chromosome 25 (White et al., 2022, https://doi.org/10.7554/eLife.72825). Were the different samples from different clutches or the same clutch? I may have missed it. Regardless, I would carefully check the DEGs that are important for conclusions and check that they are not on the same chromosome as rlig1. It is likely worth rerunning all of the GO/GSEA with genes on chromosome 25 excluded.

      Referees cross-commenting

      I missed the point about the RNA-seq samples being cousin-matched. While I am optimistic that the results won't change, I agree with Reviewer #3 that some confirmation is necessary. It was unclear to me whether the samples were from the same or different clutches - if they are from different clutches and share overlapping genes, that would also add support to the results. I think that detail was missing from the methods, and I had pointed it out. Either additional RNA-seq or even qPCR of some top genes from a heterozygous incross is a reasonable request.

      Significance

      • Describe the nature and significance of the advance (e.g. conceptual, technical, clinical) for the field.

      This study provides a conceptual and biological advance by identifying a role for a vertebrate RNA ligase in brain development, behavior, and transcriptional regulation. - Place the work in the context of the existing literature (provide references, where appropriate).

      Although RNA ligases from single-cell organisms and phage are well-characterized, the roles of RNA ligases in vertebrates are relatively understudied. There are only two, including the one the one that is the focus of this manuscript. This study demonstrates an in vivo function for Rlig1, linking molecular changes to neural development and function. The Rlig1 enzyme was only very recently discovered (2023), making this work timely and an important addition to an area with relatively few studies.

      A major strength of the study is its multi-level approach, integrating diverse techniques to coherently link this gene to organism-level phenotypes. This work provides a strong conceptual and functional advance by demonstrating a role for Rlig1 in vertebrate neural circuit function and behavior. A remaining mechanistic gap is that the direct RNA substrates of Rlig1 are not identified, and the observed transcriptomic changes in mRNA are likely downstream consequences of its loss. However, these points are clearly acknowledged in the discussion, making the study a well-balanced contribution. Given the existence of a mouse knockout model, further discussion comparing the zebrafish transcriptomic results and phenotypes to those observed in mouse would help place this work in the context of prior studies. Overall, the main conclusions are well supported, and the limitations do not undermine them. This study represents an important contribution that establishes a foundation for future mechanistic work linking Rlig1 substrates to the observed phenotypes. - State what audience might be interested in and influenced by the reported findings.

      Zebrafish basic science researchers, particuarly those studying how genes lead to altered neural circuits and behavior, are the most direct target audience. However, the work is of more broad interest to those in the fields of neurodevelopment, gene regulation, and RNA biology / processing. - Define your field of expertise with a few keywords to help the authors contextualize your point of view. Indicate if there are any parts of the paper that you do not have sufficient expertise to evaluate.

      I am comfortable evaluating zebrafish mutants, transcriptomics, and behavioral assay design. I have more limited experiment in neural circuit anaysis and interpretation of calcium imaging data, though this part of the manuscript was also clearly presented and understandable.

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      Reply to the reviewers

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.

      We thank the reviewer for this comment. The figure legends have been updated to include more details of all the statistical tests used.

      1. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.

      We agree with the reviewer and indeed, in previous studies on HIV-1 infection of human macrophages performed in the lab, we observed via immunofluorescence that the proportion of infected cells ranged from 20 to 40 %. At the time of submission, we did not have the possibility to label the native SNAT7 protein by immunofluorescence, as the commercial antibody used only works for western blotting.

      In the meantime, we have been validating a new antibody (Proteintech) targeting SNAT7 for immunofluorescence. If this is confirmed, we will be able to detect and quantify HIV-1 p24 by immunofluorescence in SNAT7-depleted human macrophages and control cells, thus confirming our results in single-cell analysis.

      Flow cytometry analyses are difficult to perform on primary human macrophages because these cells are highly adherent and must be detached first. The process induces significant cell death and damage. This is why we would prefer to carry out these analyses using immunofluorescence and microscopy on adhered cells. This option will be undoubtedly pursued.

      1. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.

      We apologize for this omission. The figures showing the increase in SNAT7 protein expression following HIV-1 infection at MOIs ranging from 0.05 to 0.5 were added to the new version of the manuscript (Supp. Fig. 1 C-F).

      1. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3

      We thank the reviewer for this comment. Circulating T lymphocytes isolated from the blood of healthy donors are now referred to resting lymphocytes in the new version of the manuscript, as opposed to activated T lymphocytes stimulated with IL2 and PHA-P for several days (Fig. 1 A-C).

      The expression levels of SNAT7, both at the gene and protein levels, are lower in resting or IL2/PHA-P-activated T cells than in macrophages from the same donors. As suggested, we will perform a kinetic of T-cell activation upon HIV-1 infection to investigate how SNAT7 expression varies in these conditions.

      1. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).

      We thank the reviewer for this comment. Fig. 2B indeed shows one of the different donors analyzed. However, protein quantification across six different donors shows that SNAT7 is more depleted with siRNA #2 (Fig. 2C), and that Gag Pr55 protein levels are consequently more reduced, than with siRNA #1 (Fig. 2D).

      We use GraphPad Prism software to perform statistical analysis. Depending on the test used, the software automatically plots the comparison bar and displays the p-value above it. We changed the representation of statistics as suggested.

      Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.

      The reviewer is right in pointing that we observed a stronger effect during the later stages of the viral cycle, from transcription of viral RNAs (Fig. 2I and Supp. Fig. 2G) to the production of viral particles in the supernatant (Fig. 2D-G), than during the earlier stage of reverse transcription (Fig. 3F, G). Also, it is also possible that we might have missed the peak in ERT/LRT production, which is transient.

      It should be noted that SAMHD1 exhibits both dNTPase (Goldstone et al., 2011) and nuclease (Beloglazova et al., 2013) activities. The ability of SAMHD1 to restrict the virus, through dephosphorylation at T592, is mediated by its RNase activity (Ryoo et al., 2014), and not by the dNTPase activity (Welbourn et al., 2013; White et al., 2013).This could explain why SNAT7 exhibit a stronger impact on viral transcription than on reverse transcription.

      Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF?

      We thank the reviewer for this suggestion. As mentioned under comment #2, flow cytometry analyses are difficult to perform on strongly adherent primary human macrophages.

      With regard to immunofluorescence, there is a technical limitation based on the species in which the antibodies are produced. The antibody that targets the native SNAT7 protein, which is currently being validated in our laboratory, is produced in rabbits. An anti-CAp24 antibody produced in goats can be used. It will then be necessary to co-label the cells with anti SAMHD1 and phospho-SAMHD1produced in mouse. We will try to find options to co-label the cells.

      The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.

      We respectfully disagree with the reviewer.

      Figure 4D shows a representative blot of the six donors analysed. As mentioned, the depletion of SNAT7 in the absence of SAMHD1 reduces the production of the viral proteins GagPr55 and CAp24 (see Fig. 4D). This is illustrated by the quantifications (Fig. 4G–I). Following treatment with Vpx, GagPr55 protein expression in SNAT7 KD macrophages is reduced by a factor of 2.6 for siRNA #1 (mean = 1.48, light grey bar) and by a factor of 1.83 for siRNA #2 (mean = 2.13, orange bar), compared to the control (mean = 3.9, pink bar) (Fig. 4G). Similarly, CAp24 protein expression was reduced by a factor of 2.2 for siRNA #1 (mean = 2.05, light grey bar) and by a factor of 1.36 for siRNA #2 (mean = 3.34, orange bar), compared to the control (mean = 4.52, pink bar) (Fig. 4H).

      These differences are therefore consistent between the Western blot and the quantifications. However, they are not significantly different to those observed in cells treated with Vpx and depleted with control siRNA, suggesting that the viral restriction observed in SNAT7 KD cells is primarily due to SAMHD1.

      Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.

      We thank the reviewer for this comment, we will perform the suggested experiment.

      1. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions.

      We thank the reviewer for this comment. The discussion will be modified further accordingly.

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics. We respectfully disagree with the reviewer.

      The cells used here imply greater variability than a cell line, but are also more relevant.

      Indeed, the effects observed in the late stages of HIV-1 production are:

      • ~80 % decrease in viral transcription compared to the control (Fig. 2I),

      • ~85 % decrease in CAp24 protein expression compared to the control, as quantified by western blot (Fig. 2E), or ~90 % by ELISA measurement (Fig. 2F),

      • a reduction of more than 90 % in the release of infectious particles (Fig. 2G).

      These results were all significant across donors, while SNAT7 depletion was always partial (Fig. 2C, between 31 to 62 % of depletion compared to the control in infected cells).

      Therefore, the data were obtained from a mixture of depleted and non-depleted macrophages. This means that the results may be underestimated.

      Together, our results show that SNAT7 is necessary for HIV-1 production.

      However, reading the comments, we realized that our conclusions regarding reverse transcription were too strong. SNAT7 depletion does not affect viral fusion and reverse transcription. The manuscript was modified accordingly.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future.

      For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes? We thank the reviewer for these questions.

      To address the role of accessory viral proteins, we have already performed one experiment infecting hMDM with HIV-1 strains deleted for genes such as Nef, Vpr, Vpu and Vif, and have found no clear effect on SNAT7 protein expression compared to WT strains. As an alternative experiment, we could overexpress individual viral genes, such as Nef or Vpr, in HeLa cells and analyze their impact on SNAT7 expression by Western blot.

      It is also possible that SNAT7 expression and recycling of lysosomal glutamine are modulated by the macrophage intrinsic immunity in response to HIV-1 infection.

      The Thr592 motif of the SAMHD1 protein is phosphorylated by Cyclin A2/CDK1 and type 1 IFN in non-cycling cells, such as MDMs (Cribier et al., 2013). For now, the relationship between SNAT7 and SAMHD1 remains unclear. However, (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This has been added to the discussion to explain the relationship between the 3 partners.

      **Referees cross-commenting** I think the comments from the other referees are reasonable and consistent with my assessment

      Reviewer #1 (Significance (Required)):

      Strength and limitations see above;

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.

      We thank the reviewer for this comment. Indeed, there is a modest, but statistically significant increase in SNAT7 protein expression upon HIV-1 infection over time (Fig. 1G, H), without any modulation of SNAT7 gene expression (Fig. 1E). This indicates that the regulation of SNAT7 expression in this context is only at the translation level (i.e. increase of translation or stabilization of the SNAT7 protein).

      As mentioned, Fig. 1H aggregates between 3 to 7 independent experiments on different donors depending on the infection time point. SNAT7 protein expression is increased already at 1 day post-infection and until 8 days. The statistical test used here, i.e. 2 way-ANOVA, compared Mock-infected and HIV-1-infected condition for each time point with the same number of donors. In this figure, the comparison is statistically different only at day 6 of the time course (7 donors). We agree that increasing the number of donors of the other time points could help to improve the statistical difference between control and infection condition.

      We thank the reviewer for the suggestion mentioning the use of replication inhibitors in this experiment. We plan to use inhibitors of reverse transcription (Nevirapin) and integration (Dolutegravir).

      The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.

      We respectfully disagree with the reviewer for this question. Indeed, to evaluate the effects of SNAT7 on HIV-1 replication, we measured Gag Pr55 and Cap24 using a Western blot approach (Fig. 2B, D and E), but also assessed the quantity of Cap24 in the supernatants and lysates using an ELISA measurement, the quantity of infectious particles using TZM reporter cells, and total viral transcription or more specifically Gag Pr55 transcription using qPCR (Fig. 2F, G and I and Supp. Fig. 2G).

      Regarding the quantification of CAp24 at the cell single level, please refer to comment #2 under Reviewer #1.

      Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).

      We thank the reviewer for this comment. Our samples are indeed a mixture of SNAT7-depleted and non-depleted macrophages and RNA interference in these cells often leads to a decrease of 50 % of the protein expression.

      To determine whether SNAT7 is involved in the release of particles, we quantified Cap24 in cell lysates and in the cell culture medium separately, and normalized the results to the total protein content. The absence of SNAT7 reduced the amount of Cap24 measured by ELISA in both samples to the same extent, showing that there is no storage of Cap24-positive viral particles inside the infected macrophages. These data were initially pooled in one graph (Fig. 2F), but separate graphs are now provided in new Supp. Fig. 2 E, F.

      Regarding the western blot shown in Fig. 2B, please refer to comment #5 under Reviewer #1.

      In the new version of the manuscript, we arranged the figures and placed the later stages of the viral cycle in Fig. 2 and the earlier stages, such as fusion, reverse transcription and transcription, in Fig. 3.

      Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.

      We thank the reviewer for this suggestion to include inhibitors of viral replication as controls. In our experiments, cells were Mock-infected in parallel as a negative control of viral detection. We provide the results in the new version of the manuscript to show that (i) there is no detection of viral or Gag RNA in the absence of the virus, (ii) the expression of viral genes measured in HIV-1-infected SNAT7-depleted cells is not different from Mock-infected cells, indicating almost complete inhibition of viral transcription (Fig. 3H and Supp. Fig. 3B), also confirmed at the protein level (Fig. 2B, D-F).

      Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.

      We thank the reviewer for this comment. LRT concentrations are very low in human macrophages and more challenging to detect than ERT concentrations. This might explain why the differences observed between the SNAT7-depleted and control conditions appear less pronounced for LRT than for ERT.

      Furthermore, we cannot rule out the possibility that SNAT7 has a cumulative effect throughout the viral cycle. While reverse transcription remains statistically unaltered, and despite the reduced levels of ERT and LRT in SNAT7-depleted macrophages (Fig. 3 F, G), there is a significant impact on the transcription of viral RNAs (Fig. 2I) and Gag (Supp. Fig. 2G). This step may also be altered by the ribonuclease activity of SAMHD1 (Beloglazova et al., 2013; Ryoo et al., 2014).

      Finally, with the help of Dr Baek Kim in Atlanta, we attempted to quantify dNTP concentrations in our human macrophages. Unfortunately, it was not possible to draw any conclusions, as the concentrations of dNTPs extracted from our cells were far too low.

      Furthermore, it should be noted that SAMHD1 viral restriction through its phosphorylation at T592 is not correlated with its dNTPase activity (Welbourn et al., 2013; White et al., 2013), but with its ribonuclease activity (Beloglazova et al., 2013; Ryoo et al., 2014). This is supporting why SNAT7, by modulating the ribonuclease activity of SAMHD1, could have a greater effect on viral transcription than on reverse transcription.

      There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.

      We thank the reviewer for this comment, but believe that Figure 2E rather than Figure 2G is to be mentioned regarding the quantification of CAp24 by Western blot and to be compared with Figure 4H.

      In Fig. 2E, we observed an average reduction of 85 % in CAp24 expression normalized to Clathrin HC expression across different donors for both siRNAs targeting SNAT7. For Fig. 4H, there was a 73 % reduction in CAp24 levels for siRNA #1 and a 56 % reduction for siRNA #2. In addition, it should be noted that the reduction in Gag levels is greater in Fig. 4G (between 77 % and 83 %) than in Fig. 2D (between 55 % and 72 %).

      Therefore, there is some variation in the results obtained with the different donors, which could be explained by variations in Gag cleavage among donors, but this does not impact the conclusions for both figures.

      SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.

      We thank the reviewer for this comment. As suggested, we will perform experiments to assess the impact of Vpx-mediated SAMHD1 degradation on viral transcription.

      Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      We thank the reviewer for this comment. We will perform the suggested experiments to assess the impact of glutamine supplementation on viral transcription.

      Reviewer #2 (Significance (Required)):

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn. Major Concerns: 1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.

      We thank the reviewer for this comment. It is worth noting that (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity using drugs decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This is now further discussed in the discussion section of the manuscript.

      The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.

      We thank the reviewer for this comment. Please, refer to comment #5 under Reviewer #2.

      Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.

      We thank the reviewer for this comment. The discussion has been modified accordingly.

      It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.

      We thank the reviewer for this suggestion but don’t really understand why this would strengthen our conclusions. Indeed, despite the known variability between donors and technical limitations to transduce cells, we chose human blood monocyte-derived macrophages as a relevant non-transformed model for HIV-1 infection of macrophages. They also represent to some extent the human diversity.

      The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      We thank the reviewer for this comment. The discussion points to some elements of potential translation and limitations of the study.

      Reviewer #3 (Significance (Required)):

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience:This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.

      We thank the reviewer for this comment. The figure legends have been updated to include more details of all the statistical tests used.

      1. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.

      We agree with the reviewer and indeed, in previous studies on HIV-1 infection of human macrophages performed in the lab, we observed via immunofluorescence that the proportion of infected cells ranged from 20 to 40 %. At the time of submission, we did not have the possibility to label the native SNAT7 protein by immunofluorescence, as the commercial antibody used only works for western blotting.

      In the meantime, we have been validating a new antibody (Proteintech) targeting SNAT7 for immunofluorescence. If this is confirmed, we will be able to detect and quantify HIV-1 p24 by immunofluorescence in SNAT7-depleted human macrophages and control cells, thus confirming our results in single-cell analysis.

      Flow cytometry analyses are difficult to perform on primary human macrophages because these cells are highly adherent and must be detached first. The process induces significant cell death and damage. This is why we would prefer to carry out these analyses using immunofluorescence and microscopy on adhered cells. This option will be undoubtedly pursued.

      1. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.

      We apologize for this omission. The figures showing the increase in SNAT7 protein expression following HIV-1 infection at MOIs ranging from 0.05 to 0.5 were added to the new version of the manuscript (Supp. Fig. 1 C-F).

      1. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3

      We thank the reviewer for this comment. Circulating T lymphocytes isolated from the blood of healthy donors are now referred to resting lymphocytes in the new version of the manuscript, as opposed to activated T lymphocytes stimulated with IL2 and PHA-P for several days (Fig. 1 A-C).

      The expression levels of SNAT7, both at the gene and protein levels, are lower in resting or IL2/PHA-P-activated T cells than in macrophages from the same donors. As suggested, we will perform a kinetic of T-cell activation upon HIV-1 infection to investigate how SNAT7 expression varies in these conditions.

      1. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).

      We thank the reviewer for this comment. Fig. 2B indeed shows one of the different donors analyzed. However, protein quantification across six different donors shows that SNAT7 is more depleted with siRNA #2 (Fig. 2C), and that Gag Pr55 protein levels are consequently more reduced, than with siRNA #1 (Fig. 2D).

      We use GraphPad Prism software to perform statistical analysis. Depending on the test used, the software automatically plots the comparison bar and displays the p-value above it. We changed the representation of statistics as suggested.

      Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.

      The reviewer is right in pointing that we observed a stronger effect during the later stages of the viral cycle, from transcription of viral RNAs (Fig. 2I and Supp. Fig. 2G) to the production of viral particles in the supernatant (Fig. 2D-G), than during the earlier stage of reverse transcription (Fig. 3F, G). Also, it is also possible that we might have missed the peak in ERT/LRT production, which is transient.

      It should be noted that SAMHD1 exhibits both dNTPase (Goldstone et al., 2011) and nuclease (Beloglazova et al., 2013) activities. The ability of SAMHD1 to restrict the virus, through dephosphorylation at T592, is mediated by its RNase activity (Ryoo et al., 2014), and not by the dNTPase activity (Welbourn et al., 2013; White et al., 2013).This could explain why SNAT7 exhibit a stronger impact on viral transcription than on reverse transcription.

      Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF?

      We thank the reviewer for this suggestion. As mentioned under comment #2, flow cytometry analyses are difficult to perform on strongly adherent primary human macrophages.

      With regard to immunofluorescence, there is a technical limitation based on the species in which the antibodies are produced. The antibody that targets the native SNAT7 protein, which is currently being validated in our laboratory, is produced in rabbits. An anti-CAp24 antibody produced in goats can be used. It will then be necessary to co-label the cells with anti SAMHD1 and phospho-SAMHD1produced in mouse. We will try to find options to co-label the cells.

      The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.

      We respectfully disagree with the reviewer.

      Figure 4D shows a representative blot of the six donors analysed. As mentioned, the depletion of SNAT7 in the absence of SAMHD1 reduces the production of the viral proteins GagPr55 and CAp24 (see Fig. 4D). This is illustrated by the quantifications (Fig. 4G–I). Following treatment with Vpx, GagPr55 protein expression in SNAT7 KD macrophages is reduced by a factor of 2.6 for siRNA #1 (mean = 1.48, light grey bar) and by a factor of 1.83 for siRNA #2 (mean = 2.13, orange bar), compared to the control (mean = 3.9, pink bar) (Fig. 4G). Similarly, CAp24 protein expression was reduced by a factor of 2.2 for siRNA #1 (mean = 2.05, light grey bar) and by a factor of 1.36 for siRNA #2 (mean = 3.34, orange bar), compared to the control (mean = 4.52, pink bar) (Fig. 4H).

      These differences are therefore consistent between the Western blot and the quantifications. However, they are not significantly different to those observed in cells treated with Vpx and depleted with control siRNA, suggesting that the viral restriction observed in SNAT7 KD cells is primarily due to SAMHD1.

      Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.

      We thank the reviewer for this comment, we will perform the suggested experiment.

      1. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions.

      We thank the reviewer for this comment. The discussion will be modified further accordingly.

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics. We respectfully disagree with the reviewer.

      The cells used here imply greater variability than a cell line, but are also more relevant.

      Indeed, the effects observed in the late stages of HIV-1 production are:

      • ~80 % decrease in viral transcription compared to the control (Fig. 2I),

      • ~85 % decrease in CAp24 protein expression compared to the control, as quantified by western blot (Fig. 2E), or ~90 % by ELISA measurement (Fig. 2F),

      • a reduction of more than 90 % in the release of infectious particles (Fig. 2G).

      These results were all significant across donors, while SNAT7 depletion was always partial (Fig. 2C, between 31 to 62 % of depletion compared to the control in infected cells).

      Therefore, the data were obtained from a mixture of depleted and non-depleted macrophages. This means that the results may be underestimated.

      Together, our results show that SNAT7 is necessary for HIV-1 production.

      However, reading the comments, we realized that our conclusions regarding reverse transcription were too strong. SNAT7 depletion does not affect viral fusion and reverse transcription. The manuscript was modified accordingly.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future.

      For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes? We thank the reviewer for these questions.

      To address the role of accessory viral proteins, we have already performed one experiment infecting hMDM with HIV-1 strains deleted for genes such as Nef, Vpr, Vpu and Vif, and have found no clear effect on SNAT7 protein expression compared to WT strains. As an alternative experiment, we could overexpress individual viral genes, such as Nef or Vpr, in HeLa cells and analyze their impact on SNAT7 expression by Western blot.

      It is also possible that SNAT7 expression and recycling of lysosomal glutamine are modulated by the macrophage intrinsic immunity in response to HIV-1 infection.

      The Thr592 motif of the SAMHD1 protein is phosphorylated by Cyclin A2/CDK1 and type 1 IFN in non-cycling cells, such as MDMs (Cribier et al., 2013). For now, the relationship between SNAT7 and SAMHD1 remains unclear. However, (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This has been added to the discussion to explain the relationship between the 3 partners.

      **Referees cross-commenting** I think the comments from the other referees are reasonable and consistent with my assessment

      Reviewer #1 (Significance (Required)):

      Strength and limitations see above;

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.

      We thank the reviewer for this comment. Indeed, there is a modest, but statistically significant increase in SNAT7 protein expression upon HIV-1 infection over time (Fig. 1G, H), without any modulation of SNAT7 gene expression (Fig. 1E). This indicates that the regulation of SNAT7 expression in this context is only at the translation level (i.e. increase of translation or stabilization of the SNAT7 protein).

      As mentioned, Fig. 1H aggregates between 3 to 7 independent experiments on different donors depending on the infection time point. SNAT7 protein expression is increased already at 1 day post-infection and until 8 days. The statistical test used here, i.e. 2 way-ANOVA, compared Mock-infected and HIV-1-infected condition for each time point with the same number of donors. In this figure, the comparison is statistically different only at day 6 of the time course (7 donors). We agree that increasing the number of donors of the other time points could help to improve the statistical difference between control and infection condition.

      We thank the reviewer for the suggestion mentioning the use of replication inhibitors in this experiment. We plan to use inhibitors of reverse transcription (Nevirapin) and integration (Dolutegravir).

      The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.

      We respectfully disagree with the reviewer for this question. Indeed, to evaluate the effects of SNAT7 on HIV-1 replication, we measured Gag Pr55 and Cap24 using a Western blot approach (Fig. 2B, D and E), but also assessed the quantity of Cap24 in the supernatants and lysates using an ELISA measurement, the quantity of infectious particles using TZM reporter cells, and total viral transcription or more specifically Gag Pr55 transcription using qPCR (Fig. 2F, G and I and Supp. Fig. 2G).

      Regarding the quantification of CAp24 at the cell single level, please refer to comment #2 under Reviewer #1.

      Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).

      We thank the reviewer for this comment. Our samples are indeed a mixture of SNAT7-depleted and non-depleted macrophages and RNA interference in these cells often leads to a decrease of 50 % of the protein expression.

      To determine whether SNAT7 is involved in the release of particles, we quantified Cap24 in cell lysates and in the cell culture medium separately, and normalized the results to the total protein content. The absence of SNAT7 reduced the amount of Cap24 measured by ELISA in both samples to the same extent, showing that there is no storage of Cap24-positive viral particles inside the infected macrophages. These data were initially pooled in one graph (Fig. 2F), but separate graphs are now provided in new Supp. Fig. 2 E, F.

      Regarding the western blot shown in Fig. 2B, please refer to comment #5 under Reviewer #1.

      In the new version of the manuscript, we arranged the figures and placed the later stages of the viral cycle in Fig. 2 and the earlier stages, such as fusion, reverse transcription and transcription, in Fig. 3.

      Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.

      We thank the reviewer for this suggestion to include inhibitors of viral replication as controls. In our experiments, cells were Mock-infected in parallel as a negative control of viral detection. We provide the results in the new version of the manuscript to show that (i) there is no detection of viral or Gag RNA in the absence of the virus, (ii) the expression of viral genes measured in HIV-1-infected SNAT7-depleted cells is not different from Mock-infected cells, indicating almost complete inhibition of viral transcription (Fig. 3H and Supp. Fig. 3B), also confirmed at the protein level (Fig. 2B, D-F).

      Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.

      We thank the reviewer for this comment. LRT concentrations are very low in human macrophages and more challenging to detect than ERT concentrations. This might explain why the differences observed between the SNAT7-depleted and control conditions appear less pronounced for LRT than for ERT.

      Furthermore, we cannot rule out the possibility that SNAT7 has a cumulative effect throughout the viral cycle. While reverse transcription remains statistically unaltered, and despite the reduced levels of ERT and LRT in SNAT7-depleted macrophages (Fig. 3 F, G), there is a significant impact on the transcription of viral RNAs (Fig. 2I) and Gag (Supp. Fig. 2G). This step may also be altered by the ribonuclease activity of SAMHD1 (Beloglazova et al., 2013; Ryoo et al., 2014).

      Finally, with the help of Dr Baek Kim in Atlanta, we attempted to quantify dNTP concentrations in our human macrophages. Unfortunately, it was not possible to draw any conclusions, as the concentrations of dNTPs extracted from our cells were far too low.

      Furthermore, it should be noted that SAMHD1 viral restriction through its phosphorylation at T592 is not correlated with its dNTPase activity (Welbourn et al., 2013; White et al., 2013), but with its ribonuclease activity (Beloglazova et al., 2013; Ryoo et al., 2014). This is supporting why SNAT7, by modulating the ribonuclease activity of SAMHD1, could have a greater effect on viral transcription than on reverse transcription.

      There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.

      We thank the reviewer for this comment, but believe that Figure 2E rather than Figure 2G is to be mentioned regarding the quantification of CAp24 by Western blot and to be compared with Figure 4H.

      In Fig. 2E, we observed an average reduction of 85 % in CAp24 expression normalized to Clathrin HC expression across different donors for both siRNAs targeting SNAT7. For Fig. 4H, there was a 73 % reduction in CAp24 levels for siRNA #1 and a 56 % reduction for siRNA #2. In addition, it should be noted that the reduction in Gag levels is greater in Fig. 4G (between 77 % and 83 %) than in Fig. 2D (between 55 % and 72 %).

      Therefore, there is some variation in the results obtained with the different donors, which could be explained by variations in Gag cleavage among donors, but this does not impact the conclusions for both figures.

      SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.

      We thank the reviewer for this comment. As suggested, we will perform experiments to assess the impact of Vpx-mediated SAMHD1 degradation on viral transcription.

      Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      We thank the reviewer for this comment. We will perform the suggested experiments to assess the impact of glutamine supplementation on viral transcription.

      Reviewer #2 (Significance (Required)):

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn. Major Concerns: 1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.

      We thank the reviewer for this comment. It is worth noting that (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity using drugs decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This is now further discussed in the discussion section of the manuscript.

      The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.

      We thank the reviewer for this comment. Please, refer to comment #5 under Reviewer #2.

      Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.

      We thank the reviewer for this comment. The discussion has been modified accordingly.

      It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.

      We thank the reviewer for this suggestion but don’t really understand why this would strengthen our conclusions. Indeed, despite the known variability between donors and technical limitations to transduce cells, we chose human blood monocyte-derived macrophages as a relevant non-transformed model for HIV-1 infection of macrophages. They also represent to some extent the human diversity.

      The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      We thank the reviewer for this comment. The discussion points to some elements of potential translation and limitations of the study.

      Reviewer #3 (Significance (Required)):

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience:This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.

      We thank the reviewer for this comment. The figure legends have been updated to include more details of all the statistical tests used.

      1. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.

      We agree with the reviewer and indeed, in previous studies on HIV-1 infection of human macrophages performed in the lab, we observed via immunofluorescence that the proportion of infected cells ranged from 20 to 40 %. At the time of submission, we did not have the possibility to label the native SNAT7 protein by immunofluorescence, as the commercial antibody used only works for western blotting.

      In the meantime, we have been validating a new antibody (Proteintech) targeting SNAT7 for immunofluorescence. If this is confirmed, we will be able to detect and quantify HIV-1 p24 by immunofluorescence in SNAT7-depleted human macrophages and control cells, thus confirming our results in single-cell analysis.

      Flow cytometry analyses are difficult to perform on primary human macrophages because these cells are highly adherent and must be detached first. The process induces significant cell death and damage. This is why we would prefer to carry out these analyses using immunofluorescence and microscopy on adhered cells. This option will be undoubtedly pursued.

      1. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.

      We apologize for this omission. The figures showing the increase in SNAT7 protein expression following HIV-1 infection at MOIs ranging from 0.05 to 0.5 were added to the new version of the manuscript (Supp. Fig. 1 C-F).

      1. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3

      We thank the reviewer for this comment. Circulating T lymphocytes isolated from the blood of healthy donors are now referred to resting lymphocytes in the new version of the manuscript, as opposed to activated T lymphocytes stimulated with IL2 and PHA-P for several days (Fig. 1 A-C).

      The expression levels of SNAT7, both at the gene and protein levels, are lower in resting or IL2/PHA-P-activated T cells than in macrophages from the same donors. As suggested, we will perform a kinetic of T-cell activation upon HIV-1 infection to investigate how SNAT7 expression varies in these conditions.

      1. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).

      We thank the reviewer for this comment. Fig. 2B indeed shows one of the different donors analyzed. However, protein quantification across six different donors shows that SNAT7 is more depleted with siRNA #2 (Fig. 2C), and that Gag Pr55 protein levels are consequently more reduced, than with siRNA #1 (Fig. 2D).

      We use GraphPad Prism software to perform statistical analysis. Depending on the test used, the software automatically plots the comparison bar and displays the p-value above it. We changed the representation of statistics as suggested.

      Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.

      The reviewer is right in pointing that we observed a stronger effect during the later stages of the viral cycle, from transcription of viral RNAs (Fig. 2I and Supp. Fig. 2G) to the production of viral particles in the supernatant (Fig. 2D-G), than during the earlier stage of reverse transcription (Fig. 3F, G). Also, it is also possible that we might have missed the peak in ERT/LRT production, which is transient.

      It should be noted that SAMHD1 exhibits both dNTPase (Goldstone et al., 2011) and nuclease (Beloglazova et al., 2013) activities. The ability of SAMHD1 to restrict the virus, through dephosphorylation at T592, is mediated by its RNase activity (Ryoo et al., 2014), and not by the dNTPase activity (Welbourn et al., 2013; White et al., 2013).This could explain why SNAT7 exhibit a stronger impact on viral transcription than on reverse transcription.

      Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF?

      We thank the reviewer for this suggestion. As mentioned under comment #2, flow cytometry analyses are difficult to perform on strongly adherent primary human macrophages.

      With regard to immunofluorescence, there is a technical limitation based on the species in which the antibodies are produced. The antibody that targets the native SNAT7 protein, which is currently being validated in our laboratory, is produced in rabbits. An anti-CAp24 antibody produced in goats can be used. It will then be necessary to co-label the cells with anti SAMHD1 and phospho-SAMHD1produced in mouse. We will try to find options to co-label the cells.

      The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.

      We respectfully disagree with the reviewer.

      Figure 4D shows a representative blot of the six donors analysed. As mentioned, the depletion of SNAT7 in the absence of SAMHD1 reduces the production of the viral proteins GagPr55 and CAp24 (see Fig. 4D). This is illustrated by the quantifications (Fig. 4G–I). Following treatment with Vpx, GagPr55 protein expression in SNAT7 KD macrophages is reduced by a factor of 2.6 for siRNA #1 (mean = 1.48, light grey bar) and by a factor of 1.83 for siRNA #2 (mean = 2.13, orange bar), compared to the control (mean = 3.9, pink bar) (Fig. 4G). Similarly, CAp24 protein expression was reduced by a factor of 2.2 for siRNA #1 (mean = 2.05, light grey bar) and by a factor of 1.36 for siRNA #2 (mean = 3.34, orange bar), compared to the control (mean = 4.52, pink bar) (Fig. 4H).

      These differences are therefore consistent between the Western blot and the quantifications. However, they are not significantly different to those observed in cells treated with Vpx and depleted with control siRNA, suggesting that the viral restriction observed in SNAT7 KD cells is primarily due to SAMHD1.

      Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.

      We thank the reviewer for this comment, we will perform the suggested experiment.

      1. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions.

      We thank the reviewer for this comment. The discussion will be modified further accordingly.

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics. We respectfully disagree with the reviewer.

      The cells used here imply greater variability than a cell line, but are also more relevant.

      Indeed, the effects observed in the late stages of HIV-1 production are:

      • ~80 % decrease in viral transcription compared to the control (Fig. 2I),

      • ~85 % decrease in CAp24 protein expression compared to the control, as quantified by western blot (Fig. 2E), or ~90 % by ELISA measurement (Fig. 2F),

      • a reduction of more than 90 % in the release of infectious particles (Fig. 2G).

      These results were all significant across donors, while SNAT7 depletion was always partial (Fig. 2C, between 31 to 62 % of depletion compared to the control in infected cells).

      Therefore, the data were obtained from a mixture of depleted and non-depleted macrophages. This means that the results may be underestimated.

      Together, our results show that SNAT7 is necessary for HIV-1 production.

      However, reading the comments, we realized that our conclusions regarding reverse transcription were too strong. SNAT7 depletion does not affect viral fusion and reverse transcription. The manuscript was modified accordingly.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future.

      For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes? We thank the reviewer for these questions.

      To address the role of accessory viral proteins, we have already performed one experiment infecting hMDM with HIV-1 strains deleted for genes such as Nef, Vpr, Vpu and Vif, and have found no clear effect on SNAT7 protein expression compared to WT strains. As an alternative experiment, we could overexpress individual viral genes, such as Nef or Vpr, in HeLa cells and analyze their impact on SNAT7 expression by Western blot.

      It is also possible that SNAT7 expression and recycling of lysosomal glutamine are modulated by the macrophage intrinsic immunity in response to HIV-1 infection.

      The Thr592 motif of the SAMHD1 protein is phosphorylated by Cyclin A2/CDK1 and type 1 IFN in non-cycling cells, such as MDMs (Cribier et al., 2013). For now, the relationship between SNAT7 and SAMHD1 remains unclear. However, (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This has been added to the discussion to explain the relationship between the 3 partners.

      **Referees cross-commenting** I think the comments from the other referees are reasonable and consistent with my assessment

      Reviewer #1 (Significance (Required)):

      Strength and limitations see above;

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.

      We thank the reviewer for this comment. Indeed, there is a modest, but statistically significant increase in SNAT7 protein expression upon HIV-1 infection over time (Fig. 1G, H), without any modulation of SNAT7 gene expression (Fig. 1E). This indicates that the regulation of SNAT7 expression in this context is only at the translation level (i.e. increase of translation or stabilization of the SNAT7 protein).

      As mentioned, Fig. 1H aggregates between 3 to 7 independent experiments on different donors depending on the infection time point. SNAT7 protein expression is increased already at 1 day post-infection and until 8 days. The statistical test used here, i.e. 2 way-ANOVA, compared Mock-infected and HIV-1-infected condition for each time point with the same number of donors. In this figure, the comparison is statistically different only at day 6 of the time course (7 donors). We agree that increasing the number of donors of the other time points could help to improve the statistical difference between control and infection condition.

      We thank the reviewer for the suggestion mentioning the use of replication inhibitors in this experiment. We plan to use inhibitors of reverse transcription (Nevirapin) and integration (Dolutegravir).

      The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.

      We respectfully disagree with the reviewer for this question. Indeed, to evaluate the effects of SNAT7 on HIV-1 replication, we measured Gag Pr55 and Cap24 using a Western blot approach (Fig. 2B, D and E), but also assessed the quantity of Cap24 in the supernatants and lysates using an ELISA measurement, the quantity of infectious particles using TZM reporter cells, and total viral transcription or more specifically Gag Pr55 transcription using qPCR (Fig. 2F, G and I and Supp. Fig. 2G).

      Regarding the quantification of CAp24 at the cell single level, please refer to comment #2 under Reviewer #1.

      Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).

      We thank the reviewer for this comment. Our samples are indeed a mixture of SNAT7-depleted and non-depleted macrophages and RNA interference in these cells often leads to a decrease of 50 % of the protein expression.

      To determine whether SNAT7 is involved in the release of particles, we quantified Cap24 in cell lysates and in the cell culture medium separately, and normalized the results to the total protein content. The absence of SNAT7 reduced the amount of Cap24 measured by ELISA in both samples to the same extent, showing that there is no storage of Cap24-positive viral particles inside the infected macrophages. These data were initially pooled in one graph (Fig. 2F), but separate graphs are now provided in new Supp. Fig. 2 E, F.

      Regarding the western blot shown in Fig. 2B, please refer to comment #5 under Reviewer #1.

      In the new version of the manuscript, we arranged the figures and placed the later stages of the viral cycle in Fig. 2 and the earlier stages, such as fusion, reverse transcription and transcription, in Fig. 3.

      Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.

      We thank the reviewer for this suggestion to include inhibitors of viral replication as controls. In our experiments, cells were Mock-infected in parallel as a negative control of viral detection. We provide the results in the new version of the manuscript to show that (i) there is no detection of viral or Gag RNA in the absence of the virus, (ii) the expression of viral genes measured in HIV-1-infected SNAT7-depleted cells is not different from Mock-infected cells, indicating almost complete inhibition of viral transcription (Fig. 3H and Supp. Fig. 3B), also confirmed at the protein level (Fig. 2B, D-F).

      Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.

      We thank the reviewer for this comment. LRT concentrations are very low in human macrophages and more challenging to detect than ERT concentrations. This might explain why the differences observed between the SNAT7-depleted and control conditions appear less pronounced for LRT than for ERT.

      Furthermore, we cannot rule out the possibility that SNAT7 has a cumulative effect throughout the viral cycle. While reverse transcription remains statistically unaltered, and despite the reduced levels of ERT and LRT in SNAT7-depleted macrophages (Fig. 3 F, G), there is a significant impact on the transcription of viral RNAs (Fig. 2I) and Gag (Supp. Fig. 2G). This step may also be altered by the ribonuclease activity of SAMHD1 (Beloglazova et al., 2013; Ryoo et al., 2014).

      Finally, with the help of Dr Baek Kim in Atlanta, we attempted to quantify dNTP concentrations in our human macrophages. Unfortunately, it was not possible to draw any conclusions, as the concentrations of dNTPs extracted from our cells were far too low.

      Furthermore, it should be noted that SAMHD1 viral restriction through its phosphorylation at T592 is not correlated with its dNTPase activity (Welbourn et al., 2013; White et al., 2013), but with its ribonuclease activity (Beloglazova et al., 2013; Ryoo et al., 2014). This is supporting why SNAT7, by modulating the ribonuclease activity of SAMHD1, could have a greater effect on viral transcription than on reverse transcription.

      There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.

      We thank the reviewer for this comment, but believe that Figure 2E rather than Figure 2G is to be mentioned regarding the quantification of CAp24 by Western blot and to be compared with Figure 4H.

      In Fig. 2E, we observed an average reduction of 85 % in CAp24 expression normalized to Clathrin HC expression across different donors for both siRNAs targeting SNAT7. For Fig. 4H, there was a 73 % reduction in CAp24 levels for siRNA #1 and a 56 % reduction for siRNA #2. In addition, it should be noted that the reduction in Gag levels is greater in Fig. 4G (between 77 % and 83 %) than in Fig. 2D (between 55 % and 72 %).

      Therefore, there is some variation in the results obtained with the different donors, which could be explained by variations in Gag cleavage among donors, but this does not impact the conclusions for both figures.

      SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.

      We thank the reviewer for this comment. As suggested, we will perform experiments to assess the impact of Vpx-mediated SAMHD1 degradation on viral transcription.

      Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      We thank the reviewer for this comment. We will perform the suggested experiments to assess the impact of glutamine supplementation on viral transcription.

      Reviewer #2 (Significance (Required)):

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn. Major Concerns: 1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.

      We thank the reviewer for this comment. It is worth noting that (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity using drugs decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This is now further discussed in the discussion section of the manuscript.

      The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.

      We thank the reviewer for this comment. Please, refer to comment #5 under Reviewer #2.

      Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.

      We thank the reviewer for this comment. The discussion has been modified accordingly.

      It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.

      We thank the reviewer for this suggestion but don’t really understand why this would strengthen our conclusions. Indeed, despite the known variability between donors and technical limitations to transduce cells, we chose human blood monocyte-derived macrophages as a relevant non-transformed model for HIV-1 infection of macrophages. They also represent to some extent the human diversity.

      The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      We thank the reviewer for this comment. The discussion points to some elements of potential translation and limitations of the study.

      Reviewer #3 (Significance (Required)):

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience:This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.

      We thank the reviewer for this comment. The figure legends have been updated to include more details of all the statistical tests used.

      1. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.

      We agree with the reviewer and indeed, in previous studies on HIV-1 infection of human macrophages performed in the lab, we observed via immunofluorescence that the proportion of infected cells ranged from 20 to 40 %. At the time of submission, we did not have the possibility to label the native SNAT7 protein by immunofluorescence, as the commercial antibody used only works for western blotting.

      In the meantime, we have been validating a new antibody (Proteintech) targeting SNAT7 for immunofluorescence. If this is confirmed, we will be able to detect and quantify HIV-1 p24 by immunofluorescence in SNAT7-depleted human macrophages and control cells, thus confirming our results in single-cell analysis.

      Flow cytometry analyses are difficult to perform on primary human macrophages because these cells are highly adherent and must be detached first. The process induces significant cell death and damage. This is why we would prefer to carry out these analyses using immunofluorescence and microscopy on adhered cells. This option will be undoubtedly pursued.

      1. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.

      We apologize for this omission. The figures showing the increase in SNAT7 protein expression following HIV-1 infection at MOIs ranging from 0.05 to 0.5 were added to the new version of the manuscript (Supp. Fig. 1 C-F).

      1. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3

      We thank the reviewer for this comment. Circulating T lymphocytes isolated from the blood of healthy donors are now referred to resting lymphocytes in the new version of the manuscript, as opposed to activated T lymphocytes stimulated with IL2 and PHA-P for several days (Fig. 1 A-C).

      The expression levels of SNAT7, both at the gene and protein levels, are lower in resting or IL2/PHA-P-activated T cells than in macrophages from the same donors. As suggested, we will perform a kinetic of T-cell activation upon HIV-1 infection to investigate how SNAT7 expression varies in these conditions.

      1. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).

      We thank the reviewer for this comment. Fig. 2B indeed shows one of the different donors analyzed. However, protein quantification across six different donors shows that SNAT7 is more depleted with siRNA #2 (Fig. 2C), and that Gag Pr55 protein levels are consequently more reduced, than with siRNA #1 (Fig. 2D).

      We use GraphPad Prism software to perform statistical analysis. Depending on the test used, the software automatically plots the comparison bar and displays the p-value above it. We changed the representation of statistics as suggested.

      Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.

      The reviewer is right in pointing that we observed a stronger effect during the later stages of the viral cycle, from transcription of viral RNAs (Fig. 2I and Supp. Fig. 2G) to the production of viral particles in the supernatant (Fig. 2D-G), than during the earlier stage of reverse transcription (Fig. 3F, G). Also, it is also possible that we might have missed the peak in ERT/LRT production, which is transient.

      It should be noted that SAMHD1 exhibits both dNTPase (Goldstone et al., 2011) and nuclease (Beloglazova et al., 2013) activities. The ability of SAMHD1 to restrict the virus, through dephosphorylation at T592, is mediated by its RNase activity (Ryoo et al., 2014), and not by the dNTPase activity (Welbourn et al., 2013; White et al., 2013).This could explain why SNAT7 exhibit a stronger impact on viral transcription than on reverse transcription.

      Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF?

      We thank the reviewer for this suggestion. As mentioned under comment #2, flow cytometry analyses are difficult to perform on strongly adherent primary human macrophages.

      With regard to immunofluorescence, there is a technical limitation based on the species in which the antibodies are produced. The antibody that targets the native SNAT7 protein, which is currently being validated in our laboratory, is produced in rabbits. An anti-CAp24 antibody produced in goats can be used. It will then be necessary to co-label the cells with anti SAMHD1 and phospho-SAMHD1produced in mouse. We will try to find options to co-label the cells.

      The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.

      We respectfully disagree with the reviewer.

      Figure 4D shows a representative blot of the six donors analysed. As mentioned, the depletion of SNAT7 in the absence of SAMHD1 reduces the production of the viral proteins GagPr55 and CAp24 (see Fig. 4D). This is illustrated by the quantifications (Fig. 4G–I). Following treatment with Vpx, GagPr55 protein expression in SNAT7 KD macrophages is reduced by a factor of 2.6 for siRNA #1 (mean = 1.48, light grey bar) and by a factor of 1.83 for siRNA #2 (mean = 2.13, orange bar), compared to the control (mean = 3.9, pink bar) (Fig. 4G). Similarly, CAp24 protein expression was reduced by a factor of 2.2 for siRNA #1 (mean = 2.05, light grey bar) and by a factor of 1.36 for siRNA #2 (mean = 3.34, orange bar), compared to the control (mean = 4.52, pink bar) (Fig. 4H).

      These differences are therefore consistent between the Western blot and the quantifications. However, they are not significantly different to those observed in cells treated with Vpx and depleted with control siRNA, suggesting that the viral restriction observed in SNAT7 KD cells is primarily due to SAMHD1.

      Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.

      We thank the reviewer for this comment, we will perform the suggested experiment.

      1. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions.

      We thank the reviewer for this comment. The discussion will be modified further accordingly.

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics. We respectfully disagree with the reviewer.

      The cells used here imply greater variability than a cell line, but are also more relevant.

      Indeed, the effects observed in the late stages of HIV-1 production are:

      • ~80 % decrease in viral transcription compared to the control (Fig. 2I),

      • ~85 % decrease in CAp24 protein expression compared to the control, as quantified by western blot (Fig. 2E), or ~90 % by ELISA measurement (Fig. 2F),

      • a reduction of more than 90 % in the release of infectious particles (Fig. 2G).

      These results were all significant across donors, while SNAT7 depletion was always partial (Fig. 2C, between 31 to 62 % of depletion compared to the control in infected cells).

      Therefore, the data were obtained from a mixture of depleted and non-depleted macrophages. This means that the results may be underestimated.

      Together, our results show that SNAT7 is necessary for HIV-1 production.

      However, reading the comments, we realized that our conclusions regarding reverse transcription were too strong. SNAT7 depletion does not affect viral fusion and reverse transcription. The manuscript was modified accordingly.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future.

      For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes? We thank the reviewer for these questions.

      To address the role of accessory viral proteins, we have already performed one experiment infecting hMDM with HIV-1 strains deleted for genes such as Nef, Vpr, Vpu and Vif, and have found no clear effect on SNAT7 protein expression compared to WT strains. As an alternative experiment, we could overexpress individual viral genes, such as Nef or Vpr, in HeLa cells and analyze their impact on SNAT7 expression by Western blot.

      It is also possible that SNAT7 expression and recycling of lysosomal glutamine are modulated by the macrophage intrinsic immunity in response to HIV-1 infection.

      The Thr592 motif of the SAMHD1 protein is phosphorylated by Cyclin A2/CDK1 and type 1 IFN in non-cycling cells, such as MDMs (Cribier et al., 2013). For now, the relationship between SNAT7 and SAMHD1 remains unclear. However, (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This has been added to the discussion to explain the relationship between the 3 partners.

      **Referees cross-commenting** I think the comments from the other referees are reasonable and consistent with my assessment

      Reviewer #1 (Significance (Required)):

      Strength and limitations see above;

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.

      We thank the reviewer for this comment. Indeed, there is a modest, but statistically significant increase in SNAT7 protein expression upon HIV-1 infection over time (Fig. 1G, H), without any modulation of SNAT7 gene expression (Fig. 1E). This indicates that the regulation of SNAT7 expression in this context is only at the translation level (i.e. increase of translation or stabilization of the SNAT7 protein).

      As mentioned, Fig. 1H aggregates between 3 to 7 independent experiments on different donors depending on the infection time point. SNAT7 protein expression is increased already at 1 day post-infection and until 8 days. The statistical test used here, i.e. 2 way-ANOVA, compared Mock-infected and HIV-1-infected condition for each time point with the same number of donors. In this figure, the comparison is statistically different only at day 6 of the time course (7 donors). We agree that increasing the number of donors of the other time points could help to improve the statistical difference between control and infection condition.

      We thank the reviewer for the suggestion mentioning the use of replication inhibitors in this experiment. We plan to use inhibitors of reverse transcription (Nevirapin) and integration (Dolutegravir).

      The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.

      We respectfully disagree with the reviewer for this question. Indeed, to evaluate the effects of SNAT7 on HIV-1 replication, we measured Gag Pr55 and Cap24 using a Western blot approach (Fig. 2B, D and E), but also assessed the quantity of Cap24 in the supernatants and lysates using an ELISA measurement, the quantity of infectious particles using TZM reporter cells, and total viral transcription or more specifically Gag Pr55 transcription using qPCR (Fig. 2F, G and I and Supp. Fig. 2G).

      Regarding the quantification of CAp24 at the cell single level, please refer to comment #2 under Reviewer #1.

      Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).

      We thank the reviewer for this comment. Our samples are indeed a mixture of SNAT7-depleted and non-depleted macrophages and RNA interference in these cells often leads to a decrease of 50 % of the protein expression.

      To determine whether SNAT7 is involved in the release of particles, we quantified Cap24 in cell lysates and in the cell culture medium separately, and normalized the results to the total protein content. The absence of SNAT7 reduced the amount of Cap24 measured by ELISA in both samples to the same extent, showing that there is no storage of Cap24-positive viral particles inside the infected macrophages. These data were initially pooled in one graph (Fig. 2F), but separate graphs are now provided in new Supp. Fig. 2 E, F.

      Regarding the western blot shown in Fig. 2B, please refer to comment #5 under Reviewer #1.

      In the new version of the manuscript, we arranged the figures and placed the later stages of the viral cycle in Fig. 2 and the earlier stages, such as fusion, reverse transcription and transcription, in Fig. 3.

      Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.

      We thank the reviewer for this suggestion to include inhibitors of viral replication as controls. In our experiments, cells were Mock-infected in parallel as a negative control of viral detection. We provide the results in the new version of the manuscript to show that (i) there is no detection of viral or Gag RNA in the absence of the virus, (ii) the expression of viral genes measured in HIV-1-infected SNAT7-depleted cells is not different from Mock-infected cells, indicating almost complete inhibition of viral transcription (Fig. 3H and Supp. Fig. 3B), also confirmed at the protein level (Fig. 2B, D-F).

      Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.

      We thank the reviewer for this comment. LRT concentrations are very low in human macrophages and more challenging to detect than ERT concentrations. This might explain why the differences observed between the SNAT7-depleted and control conditions appear less pronounced for LRT than for ERT.

      Furthermore, we cannot rule out the possibility that SNAT7 has a cumulative effect throughout the viral cycle. While reverse transcription remains statistically unaltered, and despite the reduced levels of ERT and LRT in SNAT7-depleted macrophages (Fig. 3 F, G), there is a significant impact on the transcription of viral RNAs (Fig. 2I) and Gag (Supp. Fig. 2G). This step may also be altered by the ribonuclease activity of SAMHD1 (Beloglazova et al., 2013; Ryoo et al., 2014).

      Finally, with the help of Dr Baek Kim in Atlanta, we attempted to quantify dNTP concentrations in our human macrophages. Unfortunately, it was not possible to draw any conclusions, as the concentrations of dNTPs extracted from our cells were far too low.

      Furthermore, it should be noted that SAMHD1 viral restriction through its phosphorylation at T592 is not correlated with its dNTPase activity (Welbourn et al., 2013; White et al., 2013), but with its ribonuclease activity (Beloglazova et al., 2013; Ryoo et al., 2014). This is supporting why SNAT7, by modulating the ribonuclease activity of SAMHD1, could have a greater effect on viral transcription than on reverse transcription.

      There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.

      We thank the reviewer for this comment, but believe that Figure 2E rather than Figure 2G is to be mentioned regarding the quantification of CAp24 by Western blot and to be compared with Figure 4H.

      In Fig. 2E, we observed an average reduction of 85 % in CAp24 expression normalized to Clathrin HC expression across different donors for both siRNAs targeting SNAT7. For Fig. 4H, there was a 73 % reduction in CAp24 levels for siRNA #1 and a 56 % reduction for siRNA #2. In addition, it should be noted that the reduction in Gag levels is greater in Fig. 4G (between 77 % and 83 %) than in Fig. 2D (between 55 % and 72 %).

      Therefore, there is some variation in the results obtained with the different donors, which could be explained by variations in Gag cleavage among donors, but this does not impact the conclusions for both figures.

      SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.

      We thank the reviewer for this comment. As suggested, we will perform experiments to assess the impact of Vpx-mediated SAMHD1 degradation on viral transcription.

      Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      We thank the reviewer for this comment. We will perform the suggested experiments to assess the impact of glutamine supplementation on viral transcription.

      Reviewer #2 (Significance (Required)):

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn. Major Concerns: 1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.

      We thank the reviewer for this comment. It is worth noting that (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity using drugs decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This is now further discussed in the discussion section of the manuscript.

      The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.

      We thank the reviewer for this comment. Please, refer to comment #5 under Reviewer #2.

      Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.

      We thank the reviewer for this comment. The discussion has been modified accordingly.

      It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.

      We thank the reviewer for this suggestion but don’t really understand why this would strengthen our conclusions. Indeed, despite the known variability between donors and technical limitations to transduce cells, we chose human blood monocyte-derived macrophages as a relevant non-transformed model for HIV-1 infection of macrophages. They also represent to some extent the human diversity.

      The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      We thank the reviewer for this comment. The discussion points to some elements of potential translation and limitations of the study.

      Reviewer #3 (Significance (Required)):

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience:This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

      2.15.1.0 Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.

      We thank the reviewer for this comment. The figure legends have been updated to include more details of all the statistical tests used.

      1. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.

      We agree with the reviewer and indeed, in previous studies on HIV-1 infection of human macrophages performed in the lab, we observed via immunofluorescence that the proportion of infected cells ranged from 20 to 40 %. At the time of submission, we did not have the possibility to label the native SNAT7 protein by immunofluorescence, as the commercial antibody used only works for western blotting.

      In the meantime, we have been validating a new antibody (Proteintech) targeting SNAT7 for immunofluorescence. If this is confirmed, we will be able to detect and quantify HIV-1 p24 by immunofluorescence in SNAT7-depleted human macrophages and control cells, thus confirming our results in single-cell analysis.

      Flow cytometry analyses are difficult to perform on primary human macrophages because these cells are highly adherent and must be detached first. The process induces significant cell death and damage. This is why we would prefer to carry out these analyses using immunofluorescence and microscopy on adhered cells. This option will be undoubtedly pursued.

      1. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.

      We apologize for this omission. The figures showing the increase in SNAT7 protein expression following HIV-1 infection at MOIs ranging from 0.05 to 0.5 were added to the new version of the manuscript (Supp. Fig. 1 C-F).

      1. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3

      We thank the reviewer for this comment. Circulating T lymphocytes isolated from the blood of healthy donors are now referred to resting lymphocytes in the new version of the manuscript, as opposed to activated T lymphocytes stimulated with IL2 and PHA-P for several days (Fig. 1 A-C).

      The expression levels of SNAT7, both at the gene and protein levels, are lower in resting or IL2/PHA-P-activated T cells than in macrophages from the same donors. As suggested, we will perform a kinetic of T-cell activation upon HIV-1 infection to investigate how SNAT7 expression varies in these conditions.

      1. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).

      We thank the reviewer for this comment. Fig. 2B indeed shows one of the different donors analyzed. However, protein quantification across six different donors shows that SNAT7 is more depleted with siRNA #2 (Fig. 2C), and that Gag Pr55 protein levels are consequently more reduced, than with siRNA #1 (Fig. 2D).

      We use GraphPad Prism software to perform statistical analysis. Depending on the test used, the software automatically plots the comparison bar and displays the p-value above it. We changed the representation of statistics as suggested.

      Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.

      The reviewer is right in pointing that we observed a stronger effect during the later stages of the viral cycle, from transcription of viral RNAs (Fig. 2I and Supp. Fig. 2G) to the production of viral particles in the supernatant (Fig. 2D-G), than during the earlier stage of reverse transcription (Fig. 3F, G). Also, it is also possible that we might have missed the peak in ERT/LRT production, which is transient.

      It should be noted that SAMHD1 exhibits both dNTPase (Goldstone et al., 2011) and nuclease (Beloglazova et al., 2013) activities. The ability of SAMHD1 to restrict the virus, through dephosphorylation at T592, is mediated by its RNase activity (Ryoo et al., 2014), and not by the dNTPase activity (Welbourn et al., 2013; White et al., 2013).This could explain why SNAT7 exhibit a stronger impact on viral transcription than on reverse transcription.

      Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF?

      We thank the reviewer for this suggestion. As mentioned under comment #2, flow cytometry analyses are difficult to perform on strongly adherent primary human macrophages.

      With regard to immunofluorescence, there is a technical limitation based on the species in which the antibodies are produced. The antibody that targets the native SNAT7 protein, which is currently being validated in our laboratory, is produced in rabbits. An anti-CAp24 antibody produced in goats can be used. It will then be necessary to co-label the cells with anti SAMHD1 and phospho-SAMHD1produced in mouse. We will try to find options to co-label the cells.

      The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.

      We respectfully disagree with the reviewer.

      Figure 4D shows a representative blot of the six donors analysed. As mentioned, the depletion of SNAT7 in the absence of SAMHD1 reduces the production of the viral proteins GagPr55 and CAp24 (see Fig. 4D). This is illustrated by the quantifications (Fig. 4G–I). Following treatment with Vpx, GagPr55 protein expression in SNAT7 KD macrophages is reduced by a factor of 2.6 for siRNA #1 (mean = 1.48, light grey bar) and by a factor of 1.83 for siRNA #2 (mean = 2.13, orange bar), compared to the control (mean = 3.9, pink bar) (Fig. 4G). Similarly, CAp24 protein expression was reduced by a factor of 2.2 for siRNA #1 (mean = 2.05, light grey bar) and by a factor of 1.36 for siRNA #2 (mean = 3.34, orange bar), compared to the control (mean = 4.52, pink bar) (Fig. 4H).

      These differences are therefore consistent between the Western blot and the quantifications. However, they are not significantly different to those observed in cells treated with Vpx and depleted with control siRNA, suggesting that the viral restriction observed in SNAT7 KD cells is primarily due to SAMHD1.

      1. Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.

      We thank the reviewer for this comment, we will perform the suggested experiment.

      1. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions.

      We thank the reviewer for this comment. The discussion will be modified further accordingly.

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics. We respectfully disagree with the reviewer.

      The cells used here imply greater variability than a cell line, but are also more relevant.

      Indeed, the effects observed in the late stages of HIV-1 production are:

      • ~80 % decrease in viral transcription compared to the control (Fig. 2I),

      • ~85 % decrease in CAp24 protein expression compared to the control, as quantified by western blot (Fig. 2E), or ~90 % by ELISA measurement (Fig. 2F),

      • a reduction of more than 90 % in the release of infectious particles (Fig. 2G).

      These results were all significant across donors, while SNAT7 depletion was always partial (Fig. 2C, between 31 to 62 % of depletion compared to the control in infected cells).

      Therefore, the data were obtained from a mixture of depleted and non-depleted macrophages. This means that the results may be underestimated.

      Together, our results show that SNAT7 is necessary for HIV-1 production.

      However, reading the comments, we realized that our conclusions regarding reverse transcription were too strong. SNAT7 depletion does not affect viral fusion and reverse transcription. The manuscript was modified accordingly.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future.

      For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes? We thank the reviewer for these questions.

      To address the role of accessory viral proteins, we have already performed one experiment infecting hMDM with HIV-1 strains deleted for genes such as Nef, Vpr, Vpu and Vif, and have found no clear effect on SNAT7 protein expression compared to WT strains. As an alternative experiment, we could overexpress individual viral genes, such as Nef or Vpr, in HeLa cells and analyze their impact on SNAT7 expression by Western blot.

      It is also possible that SNAT7 expression and recycling of lysosomal glutamine are modulated by the macrophage intrinsic immunity in response to HIV-1 infection.

      The Thr592 motif of the SAMHD1 protein is phosphorylated by Cyclin A2/CDK1 and type 1 IFN in non-cycling cells, such as MDMs (Cribier et al., 2013). For now, the relationship between SNAT7 and SAMHD1 remains unclear. However, (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This has been added to the discussion to explain the relationship between the 3 partners.

      **Referees cross-commenting** I think the comments from the other referees are reasonable and consistent with my assessment

      Reviewer #1 (Significance (Required)):

      Strength and limitations see above;

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.

      We thank the reviewer for this comment. Indeed, there is a modest, but statistically significant increase in SNAT7 protein expression upon HIV-1 infection over time (Fig. 1G, H), without any modulation of SNAT7 gene expression (Fig. 1E). This indicates that the regulation of SNAT7 expression in this context is only at the translation level (i.e. increase of translation or stabilization of the SNAT7 protein).

      As mentioned, Fig. 1H aggregates between 3 to 7 independent experiments on different donors depending on the infection time point. SNAT7 protein expression is increased already at 1 day post-infection and until 8 days. The statistical test used here, i.e. 2 way-ANOVA, compared Mock-infected and HIV-1-infected condition for each time point with the same number of donors. In this figure, the comparison is statistically different only at day 6 of the time course (7 donors). We agree that increasing the number of donors of the other time points could help to improve the statistical difference between control and infection condition.

      We thank the reviewer for the suggestion mentioning the use of replication inhibitors in this experiment. We plan to use inhibitors of reverse transcription (Nevirapin) and integration (Dolutegravir).

      The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.

      We respectfully disagree with the reviewer for this question. Indeed, to evaluate the effects of SNAT7 on HIV-1 replication, we measured Gag Pr55 and Cap24 using a Western blot approach (Fig. 2B, D and E), but also assessed the quantity of Cap24 in the supernatants and lysates using an ELISA measurement, the quantity of infectious particles using TZM reporter cells, and total viral transcription or more specifically Gag Pr55 transcription using qPCR (Fig. 2F, G and I and Supp. Fig. 2G).

      Regarding the quantification of CAp24 at the cell single level, please refer to comment #2 under Reviewer #1.

      Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).

      We thank the reviewer for this comment. Our samples are indeed a mixture of SNAT7-depleted and non-depleted macrophages and RNA interference in these cells often leads to a decrease of 50 % of the protein expression.

      To determine whether SNAT7 is involved in the release of particles, we quantified Cap24 in cell lysates and in the cell culture medium separately, and normalized the results to the total protein content. The absence of SNAT7 reduced the amount of Cap24 measured by ELISA in both samples to the same extent, showing that there is no storage of Cap24-positive viral particles inside the infected macrophages. These data were initially pooled in one graph (Fig. 2F), but separate graphs are now provided in new Supp. Fig. 2 E, F.

      Regarding the western blot shown in Fig. 2B, please refer to comment #5 under Reviewer #1.

      In the new version of the manuscript, we arranged the figures and placed the later stages of the viral cycle in Fig. 2 and the earlier stages, such as fusion, reverse transcription and transcription, in Fig. 3.

      Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.

      We thank the reviewer for this suggestion to include inhibitors of viral replication as controls. In our experiments, cells were Mock-infected in parallel as a negative control of viral detection. We provide the results in the new version of the manuscript to show that (i) there is no detection of viral or Gag RNA in the absence of the virus, (ii) the expression of viral genes measured in HIV-1-infected SNAT7-depleted cells is not different from Mock-infected cells, indicating almost complete inhibition of viral transcription (Fig. 3H and Supp. Fig. 3B), also confirmed at the protein level (Fig. 2B, D-F).

      Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.

      We thank the reviewer for this comment. LRT concentrations are very low in human macrophages and more challenging to detect than ERT concentrations. This might explain why the differences observed between the SNAT7-depleted and control conditions appear less pronounced for LRT than for ERT.

      Furthermore, we cannot rule out the possibility that SNAT7 has a cumulative effect throughout the viral cycle. While reverse transcription remains statistically unaltered, and despite the reduced levels of ERT and LRT in SNAT7-depleted macrophages (Fig. 3 F, G), there is a significant impact on the transcription of viral RNAs (Fig. 2I) and Gag (Supp. Fig. 2G). This step may also be altered by the ribonuclease activity of SAMHD1 (Beloglazova et al., 2013; Ryoo et al., 2014).

      Finally, with the help of Dr Baek Kim in Atlanta, we attempted to quantify dNTP concentrations in our human macrophages. Unfortunately, it was not possible to draw any conclusions, as the concentrations of dNTPs extracted from our cells were far too low.

      Furthermore, it should be noted that SAMHD1 viral restriction through its phosphorylation at T592 is not correlated with its dNTPase activity (Welbourn et al., 2013; White et al., 2013), but with its ribonuclease activity (Beloglazova et al., 2013; Ryoo et al., 2014). This is supporting why SNAT7, by modulating the ribonuclease activity of SAMHD1, could have a greater effect on viral transcription than on reverse transcription.

      There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.

      We thank the reviewer for this comment, but believe that Figure 2E rather than Figure 2G is to be mentioned regarding the quantification of CAp24 by Western blot and to be compared with Figure 4H.

      In Fig. 2E, we observed an average reduction of 85 % in CAp24 expression normalized to Clathrin HC expression across different donors for both siRNAs targeting SNAT7. For Fig. 4H, there was a 73 % reduction in CAp24 levels for siRNA #1 and a 56 % reduction for siRNA #2. In addition, it should be noted that the reduction in Gag levels is greater in Fig. 4G (between 77 % and 83 %) than in Fig. 2D (between 55 % and 72 %).

      Therefore, there is some variation in the results obtained with the different donors, which could be explained by variations in Gag cleavage among donors, but this does not impact the conclusions for both figures.

      SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.

      We thank the reviewer for this comment. As suggested, we will perform experiments to assess the impact of Vpx-mediated SAMHD1 degradation on viral transcription.

      Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      We thank the reviewer for this comment. We will perform the suggested experiments to assess the impact of glutamine supplementation on viral transcription.

      Reviewer #2 (Significance (Required)):

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn. Major Concerns: 1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.

      We thank the reviewer for this comment. It is worth noting that (Meng et al., 2022) demonstrated that SNAT7 positively regulates mTORC1 activity at the lysosomal membrane through release of lysosomal glutamine, and (Dias et al., 2024) showed that inhibiting mTORC1 activity using drugs decreases SAMHD1 Thr592 phosphorylation in hMDM. Therefore, we could speculate that the absence of SNAT7 down-regulates mTORC1 activity, which then leads to decreased SAMHD1 phosphorylation. This is now further discussed in the discussion section of the manuscript.

      The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.

      We thank the reviewer for this comment. Please, refer to comment #5 under Reviewer #2.

      Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.

      We thank the reviewer for this comment. The discussion has been modified accordingly.

      It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.

      We thank the reviewer for this suggestion but don’t really understand why this would strengthen our conclusions. Indeed, despite the known variability between donors and technical limitations to transduce cells, we chose human blood monocyte-derived macrophages as a relevant non-transformed model for HIV-1 infection of macrophages. They also represent to some extent the human diversity.

      The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      We thank the reviewer for this comment. The discussion points to some elements of potential translation and limitations of the study.

      Reviewer #3 (Significance (Required)):

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience:This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

      2.15.1.0

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      Referee #3

      Evidence, reproducibility and clarity

      This study investigates the role of the lysosomal glutamine transporter SLC38A7/SNAT7 in HIV‑1 replication in primary human macrophages. The authors demonstrate that SNAT7 is highly expressed in macrophages and upregulated upon HIV‑1 infection. They show that SNAT7 depletion inhibits HIV‑1 production at the reverse transcription step without affecting viral fusion or global cellular translation/transcription. Mechanistically, SNAT7 knockdown reduces the inhibitory phosphorylation of SAMHD1 at T592, and degradation of SAMHD1 by Vpx fully rescues viral replication. Extracellular glutamine supplementation partially restores HIV‑1 production in SNAT7‑deficient cells. Overall, the authors report interesting observations; however, the mechanistic investigation remains preliminary, raising concerns about whether the data fully support all the conclusions drawn.

      Major Concerns

      1. The mechanistic depth is insufficient. The authors do not elucidate how glutamine regulates SAMHD1 T592 phosphorylation, whether through metabolite‑mediated control of kinases/phosphatases or via indirect effects.
      2. The authors do not measure intracellular dNTP levels upon SNAT7 knockdown, which is the key functional substrate of SAMHD1. They also do not directly demonstrate that glutamine supplementation restores dNTP pools.
      3. Extracellular glutamine only partially rescues viral production, implying the existence of transport‑independent functions of SNAT7 or additional pathways. This important observation is not discussed.
      4. It is suggested that the key findings be validated in immortalized THP‑1 cells differentiated into macrophage‑like cells by PMA.
      5. The Discussion section should be expanded to include the potential translational implications and limitations of the present study.

      Significance

      General assessment: This study identifies the lysosomal glutamine transporter SLC38A7/SNAT7 as a novel host dependency factor for HIV‑1 replication in primary human macrophages. The major strengths include the use of physiologically relevant primary macrophage models, a well-organized experimental pipeline from expression profiling to functional validation, and the establishment of a link between SNAT7, glutamine metabolism, and the HIV restriction factor SAMHD1.

      Advance: It extends current understanding of HIV‑1 host dependency factors and immunometabolism by revealing a compartment‑specific metabolic pathway that supports viral reverse transcription.

      Audience: This work will primarily interest specialized researchers in HIV‑1 biology, host-virus interactions, restriction factors, and antiviral innate immunity.

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      Referee #2

      Evidence, reproducibility and clarity

      In this report, Herit and colleagues describe the role of a HIV-1 dependency factor that promotes virus replication in macrophages. The authors suggest that the lysosomal membrane-associated SNAT7 glutamine transporter is a HIV dependency factor, that promotes virus replication by enhancing reverse transcription and Gag synthesis. The authors use transient knock-down approaches in primary macrophages to identify that SNAT7 depletion does not impact viral entry but inhibits early reverse transcription which was reversed by exogenous glutamine addition. While reverse transcription enhancement was likely due to selective increase in phosho-SAMHD1 expression, mechanisms by which SNAT7 enhanced viral gene expression were not clearly defined. These are well-controlled studies that pinpoint the role of SNAT7 in the early steps of viral life cycle and highlight the intricate interplay between macrophage metabolism and HIV-1 replication. While the question that is addressed is important, and the hypothesis overall sound, the data presented needs to be strengthened to support the conclusions. There are numerous weaknesses in data interpretation as well.

      1. Figure 1: SNAT7 expression was selectively enhanced upon differentiation of monocytes into macrophages but absent in CD4+ T cells. Though there is a claim of enhancement of SNAT7 expression upon HIV-1 infection of macrophages, RT-qPCR analysis shows the opposite trend (Fig 1E) and SNAT7 protein expression changes are modest. Statistical analysis in Fig. 1H needs to be revisited. The number of replicates vary for the lysates harvested at different day post infection, which might have an impact on the statistical test. To determine if SNAT7 expression enhancement is dependent on establishment of virus infection, as the authors imply, control lysates of virus infections in presence of replication inhibitors should be included.
      2. The authors rely exclusively on western blot analysis for HIV-1 Gag expression in cell lysates as a measure of effects of SNAT7 on virus replication. Single cell analysis such as intracellular p24gag analysis by FACS should be included; this will provide a better measure of effects of SNAT7 onHIV-1 infection establishment.
      3. Knockdown of SNAT7 in MDMs was partial at best; only 30-50% decrease in expression (Fig 2C), but the effects on viral gene expression (Fig. 2I), p24 release and infectious particle production is dramatic (Fig. 2F and G). This discrepancy is not addressed. Does SNAT7 knock-down negatively impact virus particle release? Please note that the representative WB in Fig 2B does not correlate with the quantification in Fig. 2D. There are no p55gag or p24gag bands in SNAT7#1 siRNA condition (Fig. 2B)? Data could also be rearranged to follow the logical sequence of virus replication cycle (viral RNa expression followed by Gag expression, and then release).
      4. Data interpretation would be greatly improved by including infection controls (RT or integrase inhibitors) to confirm that measurements of viral RNA and Gag are indeed modulated by SNAT7 expression.
      5. Figure 3: Decrease in SNAT7 expression in macrophages resulted in lower levels of early reverse transcripts. But surprisingly, LRT levels were not as affected by decreases in SNAT7 expression. The authors go on to suggest that decreases in early RT are due to loss of phospho-SAMHD1 and increases in catalytically active form of SAMHD1. Mechanistically this does not make sense: LRT should be similarly affected by increase in catalytically active SAMHD1. dNTP concentrations should be measured to determine if the rescue of RT is dependent on SAMHD1 dNTPase activity.
      6. There is lack of consistency in the data: p24 release upon SNAT7 depletion is highly variable. While there is a dramatic >90-95% decrease in p24 release (Fig. 2G), the effects are much more moderate in Fig. 4H (50-60% attenuation), even though siRNA-mediated depletion was similar across the data sets. The authors should comment on the variability in their findings.
      7. SNAT7 is postulated to affect 2 steps in the virus life cycle: reverse transcription and viral transcription. But Vpx-mediated SAMHD1 degradation reversed both. Its not clear to me as to how SAMHD1 degradation impacts the role of SNAT7 in viral transcription. No explanation is provided.
      8. Exogenous addition of glutamine only partially restored Gag synthesis and p24 release, which could be attributed to increased cytoplasmic levels and viral protein synthesis. What about effects on reverse transcription and viral gene expression?

      Significance

      This is a novel finding, as there are limited number of studies on amino acid transporters and HIV-1 replication enhancement in macrophages. Most of the previous work has focused on CD4 T cells. These studies on SNAT7 and HIV-1 infection establishment in macrophages might better inform the influences of macrophage metabolism on HIV-1 persistence and inflammatory responses.

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      Referee #1

      Evidence, reproducibility and clarity

      This study from the Niedergang lab establishes SNAT7 as a host-dependency factor in human macrophages that supports HIV-1 replication. They show a modest increase in SNAT7 levels HIV-1 infected macrophages and suggest that SNAT7 levels are transiently increased. Employing siRNA against SNAT7 they show reduction in HIV-1 protein levels and viral RNAs and claim that there is a block of reverse transcription in SNAT7 KD cells. Focusing on a known HIV-1 restriction factor in macrophages, SAMHD1, they interconnect the SNAT7 depletion with a reduction in phosphorylated, i.e. catalytical inactive SAMHD1 arguing that SNAT7 regulates the phosphorylation and thereby antiviral activity of SAMHD1. Since SNAT7 is a glutamine transporter that provides this AA from lysosomes, they lastly supplement glutamine and this somehow rescues the reduction of HIV-1 production in SNAT7 KD cells.

      Major comments:

      The strength of this manuscript is the clear focus on primary human macrophages that are HIV-1 infected and the interconnection of HIV-1 replication to the SNAT7 siRNA KD experiments in combination with SAMHD1 depletion and lastly glutamine supplementation. This establishes a stringent and coherent story line. The effects reported are modest; high variability is not a problem since using primary hMDM this is expected and can be addressed by testing several donors and applying stringent statistics.

      1. Having said so, I realize that while they give information on the statistical test used, i.e. one-way ANOVA they miss to explain the post-test used to assess significance (i.e. Bonferroni, Fishers LSD, whatsoever). Please add this information.
      2. Another issue that might underestimate the effects of HIV-1 infection on SNAT7 levels and vice versa of SNAT7 KD on HIV-1 replication is the non-single cell approach employed, i.e. WBlots. I assume that HIV-1 infection rates in macrophages are not super high, usually not exceeding 20-30%. So indeed the effects the authors observe could be much higher, when checking at the single cell level. I do not know about the SNAT7 ab, but all the other reagents should work via flow cytometry and could hence improve the readout a lot.
      3. Furthermore the authors never commented about a dose-response effect in terms of HIV-1 infection levels. There is a MOI dependency described for Suppl.Fig.1 C-F, unfortunately the data is missing in the manuscript.
      4. Figure1: specify circulating T lymphocytes. I would expect to see levels of SNAT7 in PHA or CD3/CD28 activated lymphocytes versus resting T cells and a time course of SNAT7 levels upon activation. I think even though SNAT7 levels in T cells might be low, they could also be increased by HIV-1 infection and it is essential that the authors test for this. If not, the result is a valid negative control. For this they should employ HIV-1 primary strains with a tropism for T cells, or at least lab-adapted HIV-1 NL4-3
      5. Figure 2 again single cell measurements could reveal much more pronounced effects; it is a bit counterintuitive that siRNA #2 is more efficient in SNAT7 KD but has higher levels of HIV-1 replication in terms of Gag levels. I assume when looking at the stats it is always a comparison to the Ctl treated cells (C-G), but this is not entirely clear. Unify labeling as compared to the stats in Fig.2 I (this also applies for all the other figs).
      6. Figure 3: It is a bit odd that they finally conclude on RT as essential step that is reduced in the absence of SNAT7 and then they fail to provide statistical significance for this (Fig.3 panels F and G). One would expect that RT is much more affected given the huge effects on HIV-1 capsid and particle production shown in Fig.2 F, G and I.
      7. Figure 4; again single cell flow measurements of SAMHD1, pSAMHD1 and p24 /SNAT7 might help to more clearly discriminate effects that are specifically induced upon infection or happen in virally infected cells. Maybe alternatively IF? The wblot shown in panel D does not really reflect the point the authors want to make by the quantification in panels G-I. Primary data (D) suggests that SNAT7 KD reduces HIV-1 production even in the absence of SAMHD1. The quantification rather indicates that SNAT7 KD does not affect HIV-1 production in the absence of SAMHD1. This needs clarification/corroboration by orthogonal approaches.
      8. Figure 5: show SAMHD1 and pSAMHD1 levels upon glutamine supplementation.
      9. I think the discussion is very thin, mainly summarizing the results; but fails to give broader context or critically discuss the limitations and further directions

      Looking at the data as a whole, I think the results support a modest functional importance of SNAT7 for HIV-1 production in macrophages. I acknowledge that the experiments in primary macrophages are prone to high variability in different donors and the authors transparently depicted their data. However clearly, I would advice the authors to tune down the extend in which they claim SNAT7-dependency given this huge variability and the sometimes-borderline statistics.

      On top, there are a lot of optional experiments I am sure the authors are aware of that should be done at least in the future. For instance, how does HIV-1 upregulate SNAT7, is a viral accessory protein involved? What is the mechanism of SNAT7 dependent SAMHD1 phosphorylation? Does SNAT7 (or glutamine) regulate the activity of the SAMHD1 associated kinase / phosphatase) If so, does this impact on other targets of these enzymes?

      Referees cross-commenting

      I think the comments from the other referees are reasonable and consistent with my assessment

      Significance

      Strength and limitations see above

      Significance: I think this work is of high interest for virologists working in the field of HIV-1 and infection of myeloid cells. In case SNAT7 (and hence glutamine) indeed regulates the phosphorylation of SAMHD1, there could potentially be broad relevance of this work. However unfortunately, this aspect remains underdeveloped and is also not discussed

      Field of expertise: HIV-1, immunology, cell biology

  2. Jul 2026
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      Reply to the reviewers

      1. General Statements We thank all Reviewers for their helpful input that allowed us to significantly improve our study. We acknowledge that the Reviewer's interpretation on the advance of our study was mixed. In our own view, the main advance of this study (relevant to a broader community of scientists interested in epithelial cell biology) is the identification of actin turnover as a spatial regulator of non-centrosomal microtubule organization in epithelial cells in vivo. This conclusion is based on the evidence that microtubules are specifically displaced from the apical cortex upon disruption of CAP-dependent actin turnover, associated with the mislocalization of the actin-microtubule coupling spectraplakin Shot, and partially restored by acute treatment with actin polymerization inhibitor Latrunculin A. While reviewers differed in their assessment of the conceptual advance, the reviews helped us strengthen both the experimental support and interpretation of the findings. In response, we have added new experiments, expanded quantification, and revised several conclusions to provide a more rigorous and balanced account of how CAP-dependent actin turnover contributes to epithelial cytoskeletal organization. Particularly important was the addition of acute Latrunculin A experiments demonstrating rapid and coordinated recovery of apical microtubules and Shot localization following partial disruption of the actin accumulation.

      In addition, our study includes advances relevant to a more specific group of scientists working on the regulation of the actin cytoskeleton. These include evidence for the role of CAP in local regulation of apical actin turnover in epithelial cells in vivo, which extends beyond the earlier reported findings of Baum and Perrimon (2001) (PMID: 11584269). Moreover, our study establishes the essential role of the CARP domain of CAP in epithelial actin turnover in animals in vivo, which complements the earlier studies conducted in vitro and in yeast (PMID: 29760438, PMID: 36912152). For more detailed arguments and description, please see below.

      1. Point-by-point description of the revisions

      Reviewer #1 (Evidence, reproducibility and clarity (Required)): In the manuscript by Babu et al, "Apical actin filament turnover mediated by cyclase-1 associated protein is required for organization of non-centrosomal microtubules in epithelium," the authors investigate how Cyclase-associated protein (CAP) regulates apical actin organization and how this impacts microtubule architecture and apical trafficking in the Drosophila follicular epithelium. CAP depletion leads to accumulation of a dense, Latrunculin-resistant apical F-actin network, accompanied by loss of apical microtubules, mislocalization of vesicular markers (e.g., Rab11, Cad99C, Dynein), defects in microvilli formation, and altered nuclear positioning. Domain-rescue experiments suggest that CAP's nucleotide exchange activity is required for proper actin organization. The study presents a rich set of phenotypic observations and highlights an important interplay between actin turnover, microtubule organization, and epithelial polarity. However, several key mechanistic conclusions are currently not fully supported by the data, and an important conceptual question regarding the spatial specificity of CAP function remains insufficiently addressed.

      Response: We thank the reviewer for this thoughtful assessment. We agree that the original version did not sufficiently support the mechanistic conclusions or address the spatial specificity of CAP function. In the revised manuscript, we strengthened quantification and refined our interpretation to distinguish between structural effects of actin accumulation and defects in actin-microtubule coupling, supported by new data regarding Shot redistribution and its dynamic recovery upon Latrunculin A treatment. We also addressed spatial specificity by comparing CAP depletion to Cofilin and Aip1 silencing, which cause global actin accumulation, whereas CAP loss produces a spatially restricted imbalance with apical accumulation and reduced basal actin. These revisions provide a more balanced and experimentally grounded interpretation of both the mechanism and spatial nature of CAP function.

      Major Comments 1. Is the CAP function truly apically specific? A central conclusion of the manuscript is that CAP regulates the apical actin cytoskeleton. However, the data do not yet clearly distinguish whether CAP acts in a spatially polarized manner or instead regulates global actin turnover, with apical accumulation emerging as a secondary consequence of epithelial geometry. As CAP appears largely cytoplasmic, it is plausible that its depletion affects actin dynamics throughout the cell. In this scenario, actin accumulation may become most apparent at the apical domain because this region is less occupied by organelles compared to the laterobasal cytoplasm. Thus, the observed phenotype could reflect global dysregulation of actin turnover, rather than a specifically apical mechanism. Importantly, this does not contradict the authors' model but represents an alternative that should be addressed. To clarify this point, the authors should consider: • Quantifying actin distribution across the full apico-basal axis • Testing whether forced relocalization of CAP (e.g., to the basal cortex) alters where actin accumulates • Assessing whether non-apical actin structures are also altered but less apparent Without addressing this, the claim of apical-specific regulation remains insufficiently supported and should be framed more cautiously.

      Response: Reviewer raised important conceptual question regarding whether the CAP phenotype reflects spatially specific regulation or a global defect in actin turnover. To directly address this, we performed comparative analyses with depletion of two well-established actin disassembly factors, Cofilin and Aip1. While depletion of either factor resulted in actin accumulation throughout the apico-basal axis (Fig. 1D-I), CAP depletion caused a strikingly confined accumulation at the apical cortex (Fig. 1J-O). To further quantify this distinction, we have now • quantified actin intensity along the apico-basal axis using line-scan analysis (Fig. 1F, I, L, O) • quantified basal actin levels independently (Fig. 1E', H', K', N') These analyses show that, unlike global turnover defects caused by Cofilin and Aip1 depletion, CAP depletion does not result in uniform actin accumulation, but instead produces a spatially restricted imbalance, with accumulation at the apical cortex and reduction elsewhere. These findings argue against a purely global turnover model influenced by epithelial geometry and instead support a model in which CAP loss generates a spatial imbalance in filament turnover, leading to preferential stabilization of apical actin. We agree that forced relocalization of CAP would provide an important additional test of spatial specificity. However, such experiments are technically challenging in this system and were not feasible within the current revision timeline.

      1. What is the primary molecular function of cap in this context? While the phenotypic consequences of CAP depletion are well described, the manuscript does not clearly resolve which step of actin turnover is affected. CAP is known to function in actin monomer recycling and cooperate with cofilin, but it remains unclear in this system whether the primary defect reflects: (i) Impaired actin depolymerization, (ii) Reduced monomer recycling or altered filament dynamics or nucleation balance Clarifying this point is important, as it would strengthen the mechanistic link between CAP activity and the observed cellular phenotypes. Even if not directly tested experimentally, this aspect should be more explicitly discussed and, where possible, supported by quantitative analysis of actin dynamics.

      Response: Reviewer requested for a clearer mechanistic interpretation of CAP function in this system. While directly isolating individual biochemical steps in vivo is not feasible, several independent lines of evidence consistently point toward a defect in actin filament turnover at the level of disassembly and recycling, rather than increased actin assembly: • The accumulated apical F-actin persists upon Latrunculin A treatment, consistent with reduced turnover (Fig. 6A, B) • The accumulated actin is enriched for Aip1 (Suppl. Fig. 1B), which is known to preferentially associate with Cofilin-decorated actin filaments • Basal actin levels are reduced (Fig. 1N'), consistent with depletion of polymerization-competent ATP-actin monomers Together, these observations support a model (PMID: 29760438, PMID: 36912152) in which actin accumulates because it fails to be efficiently disassembled and recycled, rather than because of increased polymerization. We acknowledge that direct quantitative measurements of actin dynamics (e.g., FRAP) would further strengthen this conclusion. Such experiments were beyond the scope of the current study. Our interpretation is instead based on the increased resistance of apical F-actin to Latrunculin A and the enrichment of Aip1 within the accumulated actin network, both of which are consistent with reduced actin turnover. We agree that interpretation of the CARP domain results requires careful consideration. Because this issue was raised by multiple reviewers, we address it in detail in response to Reviewer #3 (Comment 1). Briefly, we interpret the CARP mutant phenotype as reflecting the failure of the coordinated actin recycling cycle, rather than disruption of a single activity. We have substantially expanded the Discussion to clarify this mechanistic model.

      1. Insufficient quantification of actin stability. The conclusion that apical actin is stabilized in CAP mutants is based primarily on qualitative observations of Latrunculin A resistance. While convincing visually, this requires quantitative validation. Measurement of actin intensity under {plus minus} LatA conditions, across multiple samples with proper normalization and statistical analysis, is necessary to substantiate increased actin stability.

      Response: We have now performed quantitative analysis of actin intensity in control and Latrunculin A-treated samples across multiple egg chambers (Fig. 6B). These experiments confirm that actin structures in CAP mutant cells are significantly more resistant to depolymerization, supporting the conclusion that they are stabilized.

      1. Domain-rescue experiments lack quantification (Fig.2,S2). The conclusion that the CARP domain is required for rescue is based on qualitative comparisons. Given the importance of this experiment for mechanistic interpretation, quantitative analysis of rescue efficiency (e.g., actin intensity, percentage of rescued clones) is essential.

      Response: We agree that quantification is essential for interpreting these experiments. We have now quantified apical F-actin intensity across all rescue conditions, including CAP mutant clones, wild-type CAP rescue, and domain-specific mutants (HFD, PP, WH2, CARP) (Fig. 2F-I; Supl.Fig. 2B-E). These data confirm that disruption of the CARP domain specifically prevents rescue, strengthening our conclusion that this activity is critical for maintaining normal actin organization in vivo.

      1. Microtubule exclusion model is not directly demonstrated The authors propose that dense apical actin physically excludes microtubules. While the presented data are consistent with this model, they remain correlative. Alternative explanations include: (i) Altered microtubule stability, (ii) Defective nucleation or anchoring or (iii) changes in epithelial polarity affecting microtubule organization. To distinguish between these possibilities, the authors should: • Perform live imaging of microtubule plus ends (e.g., EB1) to assess whether microtubules fail to enter or instead destabilize at the apical region. • Examine whether microtubule polarity or nucleator localization is altered • Increase sample size and quantification for line-scan analyses (Fig. S3) The current interpretation should therefore be presented more cautiously as one of several possible mechanisms.

      Response: Reviewer pointed out that the current data do not directly demonstrate steric exclusion and that alternative mechanisms should be considered. In response, we have revised both the Results and Discussion to present a more balanced interpretation. Our data, with new quantitations show that: • Microtubules are reduced at the apical domain, now quantitated (Fig. 5A-C) • Microtubules reappear rapidly following partial actin disruption (Fig. 6A-C) • Microtubule minus-end anchoring is preserved (Patronin, Fig. 5D-F) • Microtubule polarity is maintained (Dynein, Fig. 7J-L) These findings indicate that microtubules are not globally lost, but instead are redistributed and fail to properly occupy the apical domain. In the revised manuscript, we no longer present microtubule exclusion as a single or dominant mechanism, but provide two non-exclusive mechanisms: structural effects, in which dense actin may limit microtubule access, and coupling defects, in which redistribution of Shot alters actin-microtubule interactions. We agree that direct analysis of microtubule growth dynamics would provide important complementary evidence, but such experiments were not feasible within the revision and are now stated as a limitation.

      1. Shot redistribution suggests an alternative mechanism (Fig.6). The redistribution of Shot beneath the actin accumulation is a key observation that is currently underexplored. Given that Shot mediates actin-microtubule crosslinking, this finding suggests that disrupted cytoskeletal coupling could underlie microtubule defects. This provides an alternative to the steric exclusion model and should be more fully integrated into the manuscript. The authors should: • Quantify Shot redistribution relative to the apical domain • test whether restoring Shot at the apical cortex rescues microtubule organization • compare effects of Shot versus Patronin manipulation to distinguish crosslinking versus anchoring roles

      Response: We agree that the redistribution of Shot is a key observation that was underdeveloped in the original submission. In particular, we agree with the reviewer that this finding raises an important alternative (or complementary) explanation to a purely steric exclusion model. In response, we have substantially expanded this part of the manuscript, both experimentally and conceptually, to directly address this concern. Experimentally, we have strengthened the analysis of Shot localization as follows: • We quantified Shot distribution relative to the apical domain (Fig. 5H), demonstrating a significant reduction at the cortex • We performed line-scan analyses (Fig. 5I), showing that Shot is consistently redistributed beneath the accumulated actin • We expanded the Discussion to compare Shot and Patronin phenotypes described in the literature with the CAP mutant phenotype Importantly, we also addressed whether Shot mislocalization is a consequence of altered actin organization. To this end, we performed Latrunculin A treatment, where partial disruption of the apical actin accumulation leads to re-entry of microtubules into the apical domain (Fig. 6A-C). Our new data shows that under the same conditions, Shot partially redistributes back toward the apical cortex (Fig. 6E-F) The rapid timescale of this response (30 min LatA treatment) indicates that Shot localization is dynamically dependent on the actin network and is not a secondary, long-term effect. Conceptually, we have revised our interpretation in direct response to the reviewer's suggestion. In the revised manuscript, we no longer present microtubule exclusion as a single or dominant mechanism. Instead, we explicitly distinguish between two non-exclusive mechanisms: • Structural effects - dense actin may limit microtubule access • Coupling defects - redistribution of Shot alters actin-microtubule interactions Under this model, microtubules are not simply blocked from entering the apical cortex, but may also fail to be properly captured, stabilized, or guided, due to loss of cortical coupling. We believe this revised interpretation directly addresses the reviewer's concern and integrates the Shot phenotype as a central mechanistic component, rather than a secondary observation. We agree that further experiments-such as targeted manipulation of Shot localization-would provide a more direct test of this model. However, these approaches require new genetic tools and therefore need to be performed in forthcoming studies.

      1. Nuclear positioning phenotype is not fully resolved (Fig.7). The explanation that the lack of rescue reflects late expression of the CAP construct is plausible but not experimentally demonstrated. This interpretation should be toned down or explicitly presented as speculative.

      Response: We agree that the original manuscript did not sufficiently explain why nuclear positioning is not rescued by CAP re-expression. To address this, we performed additional quantifications of CAP rescue construct expression and cytoskeletal organization during the developmental stages when nuclear positioning is established. We now show that: • CAP rescue constructs exhibit minimal expression during stages 6-7, when nuclear positioning is established (Fig. 4J-K). • During this same developmental window, CAP mutant cells and CAP rescue cells both display apical actin accumulation and altered microtubule organization (Fig. 4D-I). • By stage 10, when CAP expression increases, both the actin and microtubule phenotypes are efficiently rescued. Together, these data provide a plausible explanation for the lack of rescue of the nuclear positioning phenotype. Specifically, CAP activity appears to be required during early oogenesis, when nuclear positioning is established, whereas expression of the rescue construct occurs predominantly at later stages. Consistent with previous work showing that nuclear positioning depends on apically organized microtubules during stages 6-9 (PMID: 23077179), our findings suggest that early defects in actin and microtubule organization are sufficient to disrupt nuclear positioning even if cytoskeletal organization is restored later. We have revised the manuscript accordingly and now present the nuclear positioning phenotype as a consequence of early cytoskeletal defects, while noting that the precise mechanism linking CAP function to nuclear positioning remains to be determined.

      Minor comments: 1. Quantification and sample size Many claims rely on representative images and n and N are not reported in such cases. Include quantification and clearly report n and N for all analyses.

      Response: We have added quantitative analysis and clearly report n and N throughout all relevant figures.

      1. Vesicle exclusion and secretion defects remain indirect (Fig.3) Evidence for vesicle exclusion is based on loss of ER/Golgi markers and altered TEM structures. However, TEM identification of mutant (clones) cells is phenotype-based. The current data are consistent with altered apical trafficking but do not directly demonstrate vesicle exclusion from the actin-rich domain. More direct evidence would require visualization of vesicle dynamics to determine whether they fail to enter, stall at or are redirected from the apical actin accumulation. The current wording should be softened accordingly.

      Response: We have modified the wording accordingly. While direct visualization of vesicle dynamics is not provided, our data show consistent marked reduction of multiple markers: mCD8GFP (Fig. 3A-C), ER (Fig. 3E-G), Golgi (Gig.3H-J), Rab11 (Fig. 7G-I), and Dynein (Fig. 7J-L), from the actin-rich domain, supporting the interpretation indirectly.

      Reviewer #1 (Significance (Required)): The work provides a strong phenotypic characterization linking CAP depletion to accumulation of a dense, Latrunculin-resistant apical F-actin network, accompanied by defects in microtubule organization, vesicle localization, and epithelial morphology. A key strength is the integration of multiple readouts to connect actin turnover with broader aspects of epithelial organization. The study therefore offers potentially important insight into how actin dynamics can influence cytoskeletal crosstalk and tissue architecture. However, several central conclusions rely on largely qualitative or correlative evidence, and quantitative support is limited in key experiments. In addition, an important conceptual question remains unresolved: whether CAP regulates actin turnover in a spatially polarized (apical-specific) manner or more globally, with apical phenotypes emerging as a consequence of cellular organization. Addressing this distinction, along with strengthening quantification and moderating interpretation of the steric exclusion model, would substantially improve the manuscript. The main advance of the study is functional and conceptual, linking CAP-dependent actin turnover to microtubule organization and apical trafficking in a polarized epithelial context. While CAP is known to regulate actin dynamics, its role in coordinating cytoskeletal organization at the tissue level is less well defined, and this work extends current knowledge in that direction. At present, however, the mechanistic insight remains limited, particularly regarding the specific step in actin turnover affected and the causal relationship between actin, microtubules, and trafficking defects. The study will be of primary interest to a specialized audience in cytoskeleton, epithelial, and developmental biology, with broader relevance to researchers studying actin-microtubule crosstalk and cell polarity.

      Response: We thank the reviewer for this thoughtful assessment and recognizing the strengths of the manuscript. In the revised manuscript, we addressed the concerns regarding quantification by incorporating systematic analyses across key experiments and moderating interpretations where appropriate. We also directly addressed the question of spatial specificity by showing that the CAP phenotype differs from global actin turnover defects, supporting a model of spatially biased disruption rather than uniform regulation. Together, these revisions clarify the conceptual advance and provide a more balanced and experimentally supported interpretation of CAP function. We agree that resolving the individual biochemical steps of actin turnover is very challenging in our in vivo model. However, in the revised manuscript we clarify this by framing CAP function at the level of the actin turnover cycle and presenting the CARP phenotype as a defect in coordinated actin recycling, supported by Latrunculin A resistance, enrichment of disassembly-associated factors, and reduced basal actin levels. In addition, we have refined our interpretation of the relationship between actin, microtubules, and trafficking, explicitly considering both direct structural effects of altered actin organization and indirect consequences for cellular organization. Together, these revisions clarify the conceptual advance and provide a more balanced and experimentally supported interpretation of epithelial CAP function. Specifically, our study demonstrates that defects in actin turnover generate spatially restricted cytoskeletal changes that reorganize microtubule positioning and engagement in vivo.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)): Babu and colleagues report that clonal loss of Cyclase associated protein (CAP) function results in dramatic accumulation of F-actin in a large cytoplasmic domain below the apical surface of Drosophila egg chamber follicle cells. Rescue experiments confirm the overall role of CAP and show that its function in converting actin-GDP to actin-GTP is critical for preventing the F-actin accumulation. Numerous components of the cell are probed in the mutant clones and are shown to have altered distributions. Microtubules and intracellular membranes are generally excluded from the abnormal F-actin domains, and Latrunculin A treatment partially reversed the microtubule exclusion. Abnormalities in apical microvilli, apicolateral nuclear positioning, and actin binding protein distributions are also reported. In general, the microscopy is quite striking, and the manuscript is clearly written, but the overall advance seems fairly limited and several revisions are needed.

      Response: We thank the reviewer for their positive assessment of the microscopy and clarity of the manuscript. We acknowledge that the overall advance should be more clearly articulated. While apical actin accumulation in CAP mutants has been previously described (PMID: 11584269), our study shows that defects in actin turnover can generate spatially restricted cytoskeletal phenotypes, impair microtubule engagement with the apical cortex, and reorganize non-centrosomal microtubules in vivo. Importantly, we show that defects in actin turnover can both limit microtubule access to the apical cortex and alter actin-microtubule coupling through redistribution of the crosslinker Shot, providing a conceptual framework linking local actin dynamics to microtubule organization and epithelial function. Moreover, we show that CARP-domain-dependent actin recycling is required for spatial turnover of actin in an epithelium. We have revised the manuscript to better emphasize these advances and to distinguish our findings from prior work.

      Major comments: 1. The authors conclude that the abnormal F-actin accumulations of CAP mutant cells coincide with microtubule cytoskeleton alterations and say that this "suggests that spatially regulated actin filament turnover is important for microtubule organization". Although the conclusion and suggestion are formally true, they don't consider the directness of the relationship. In my view, two possibilities of indirect effects should be included: (1) the general disruption of subcellular organization by the large F-actin accumulation suggests that many indirect effects are possible, and (2) the very high level of F-actin accumulation, and of actin binding protein co-accumulations, without apparent losses from other parts of the cell suggest that the mutant cells have undergone major gene expression changes which could have a range of effects.

      Response: The Reviewer raises a concern regarding the extent to which the observed microtubule defects reflect direct consequences of altered actin organization versus indirect effects arising from broader disruption of cellular organization or changes in gene expression. Our study is based on genetic in vivo experiments and due the duration of these experiments, distinguishing between immediate and long-term cellular changes is challenging, as the Reviewer correctly points out. However, we would like to emphasize that our phenotypes show that microtubules are not globally disrupted but instead redistributed locally relative to the actin-rich domain (Fig. 5A-C), while polarity and anchoring remain intact (Fig. 5D-F; Fig. 7J-L). This distinguishes the observed phenotype from general cellular collapse and supports a conclusion of specific reorganization of microtubule-cortex interactions. To further address the Reviewer's concern, we have performed acute (~30 min) Latrunculin A (LatA) treatment experiments to test, how microtubule organization and the localization of actin-microtubule crosslinker Shot corresponds to LatA-mediated changes in actin cytoskeleton. We observed that LatA partially mitigated the accumulation of apical actin in CAP mutant cells (Fig. 6A, B). Concomitantly, microtubules reappeared to the apical domain (Fig. 6A, C) as well as the apical localization of Shot was increased (Fig. 6E, F). Considering the timescale of this experiment, we conclude that it is unlikely to reflect indirect effects, such as reprogramming of gene expression (typically occurring in the scale of hours). In our view, the most parsimonious conclusion is that these acute phenotypic changes reflect a direct structural effect of actin organization on local microtubule formation. Despite these arguments, we cannot fully rule out that long-term cellular adaptations, such as altered organelle distribution or changes in gene expression, are reflected to some of the CAP mutant phenotypes. We have now explicitly acknowledged both possibilities in the revised manuscript.

      1. The authors state that the CARP domain of CAP is known to bind ADP-actin monomers and promote ADP-ATP exchange, "thereby recharging actin monomers for polymerization". Of many mutations expected to affect individual domains of CAP, only mutations disrupting the nucleotide exchange activity of the CARP domain failed to rescue the abnormal F-actin accumulations of CAP mutant cells. It was unclear how extreme actin polymerization occurs in cells in which the CAP protein expressed only lacks the ability to recharge actin monomers for polymerization. Minimally, the results of the domain analyses should be addressed in the Discussion section. More analyses/constructs may be needed to confirm whether the mutations listed in Table 1 had their intended effects on CAP domain activities (especially on the activity of the HFD domain implicated in actin depolymerization).

      Response: The reviewer raises a concern regarding the apparent contradiction between impaired nucleotide exchange and the observed accumulation of F-actin. We agree that this observation is counterintuitive and requires better clarification. Firstly, we would like to emphasize that our interpretation is not that CAP loss increases actin polymerization. Instead, our interpretation of the experimental finding is that the phenotype likely arises from a defect in actin filament turnover, leading to progressive accumulation of aged, stabilized filaments. This interpretation is based on the following observations: • Accumulated apical actin shows increased resistance to Latrunculin A, indicating reduced filament dynamics (Fig. 6B) • The actin-rich structures are enriched in Aip1 that associate with cofilin-decorated filaments (Supl. Fig. 1B) • Basal actin levels are reduced (Fig. 1N'), consistent with depletion of polymerization-competent ATP-actin Together, these findings argue against excess polymerization and instead support a model in which filaments accumulate because they fail to be efficiently disassembled and recycled. This conclusion supported by existing studies in yeast (PMID: 29760438) and in vitro (PMID: 36912152). Based on the findings reported in Kotila et al., 2019 (PMID: 29760438) the CARP domain mutation used in this study is expected to disrupt both ADP-actin binding and nucleotide exchange. These functions are part of a coordinated and sequential actin turnover cycle. Disruption of this cycle is expected to 1) impair Cofilin release, 2) prevent efficient processing of disassembly products, and 3) block regeneration of ATP-actin. As a consequence, actin becomes trapped in a non-productive ADP-bound state, leading to accumulation of aged filaments and overall impairment of the turnover cycle. We acknowledge that direct biochemical validation of each mutant construct would have further strengthened the conclusions on the mutants lacking a clear phenotype. While these analyses were beyond the scope of the current study, we now discuss this caveat in the manuscript and clarify the mechanistic interpretation of the domain-rescue results in the Discussion.

      Minor comments: 1. It is stated that "In follicular epithelial cells, Lat A treatment resulted in the disappearance of apical and basal actin, whereas cortical actin remained largely unaffected in both stage 8 and 10 egg chambers (Fig. 1B)". However, the disappearance of basal actin was not clear because it is at low levels in the control making the comparison with the treatment difficult to interpret. Also, "lateral" would be a better term than "cortical".

      Response: We agree that the originally presented images did not adequately illustrate the effect of Latrunculin A treatment on basal actin, particularly given its relatively low baseline intensity. To address this, we have: • Added images of lateral and basal cross-sections (Fig. 1B) • Included quantitative measurements of basal actin intensity under control (DMSO) and Latrunculin A conditions (Fig. 1C) These additions allow for a more direct and reliable comparison and clarify that basal actin is indeed sensitive to Latrunculin A treatment. We have also replaced the term "cortical" with "lateral" throughout the manuscript, as suggested, to improve precision and clarity.

      1. The authors state "Interestingly, the width of the perivitelline space, apically to CAP mutant cells was decreased compared to the neighboring cells (Figure 3 E)." However, it was unclear where to look in the figure panel to see this effect. A degree of quantification is also warranted.

      Response: To improve the clarity in the original figure presentation we have now clearly marked the perivitelline space in the TEM images. We agree that direct quantification would strengthen this observation. However, because the width of the perivitelline space is closely related to the length of apical microvilli, we refer the reader to our quantitative measurements of microvillar length (Fig. 7B-C), which provides a biologically relevant quantitative measure associated with this phenotype. We now explicitly state this relationship in main text to ensure clarity.

      1. In Figure 4, I recommend expanding the explanations of the X axes of the graphs, and adding explanations of why data from the same experiment are graphed in multiple ways (or simplifying the presentation if it still allows the same conclusions).

      Response: We have revised the figure presentation (Fig. 5C', I' and 7F', I',L') to improve clarity in several ways: • Axis definition: We now provide a detailed explanation of the X-axis in the figure legends. In control cells, the zero point corresponds to the apical cortex. In CAP mutant cells, the position of the actin accumulation varies between cells. Therefore, we normalized the X-axis such that the zero point corresponds to the boundary between the actin-rich domain and the basal cytoplasm. • Rationale for normalization: We explicitly explain that this normalization allows for more meaningful averaging across cells and better reflects the spatial relationship between markers and the actin accumulation. • Simplification of presentation: To reduce complexity and improve readability, we have removed individual cell line scans and now present averaged profiles of the apical intensity from multiple cells, which better represent the overall trend. These revisions substantially improve the interpretability of the data while preserving the conclusions.

      1. Typo on page 6, line 244: "(Fig. 4C, E-F)"?

      Response: The figure reference has been corrected in the revised manuscript.

      1. More detail is needed to clarify this interpretation: "Furthermore, the localization of membrane-bound mCD8-GFP was partially restored in the apical region of CAP mutant cells after Latrunculin A treatment (Fig. 5E, F)." With respect to the local mCD8 protein levels, the DMSO control and LatA treatment seem similar.

      Response: Following this comment, we repeated the experiment and performed quantitative analysis of mCD8-GFP localization. Our results show no significant difference between DMSO and Latrunculin A-treated conditions (Fig. 6D). Therefore, we agree that the original interpretation was not sufficiently supported. We have now removed the corresponding statement from the manuscript and revised the text. We thank the reviewer for prompting this clarification.

      1. Grammar issue on page 2, line 50: "comprising of contractile actin"

      Response: We have corrected the grammatical error ("comprising of contractile actin") in the revised manuscript.

      1. Unclear sentence on page 3, line 100: "Our study demonstrates that actin disassembly protein, Cyclase associated protein-mediated apical actin turnover is required for..."

      Response: We have rewritten the sentence for clarity.

      1. On page 4, after describing an increased expression of profilin localized mainly away from the site of F-actin accumulation, the authors conclude that "This indicates that an excess of actin filament assembly is unlikely to occur at the apical side of CAP mutant cells." I suggest toning down this conclusion.

      Response: We have revised the text and removed this interpretation.

      Reviewer #2 (Significance (Required)): The advance made by the paper seems somewhat limited. In part, this is due to the two major comments above. Addressing these concerns experimentally could increase the significance of the paper. Additionally, the authors reference Baum and Perrimon (2001), a paper which showed excessive, apical F-actin accumulations in follicle cells mutant for CAP in Drosophila egg chambers. Other studies referenced in the manuscript provide evidence of local F-actin accumulations affecting the distributions of other components of a cell. Thus, the main conclusions of the manuscript seem similar to those made by previously published papers. Nonetheless, a strength of the paper is its reporting of altered distributions of a wide range of cell components in relation to an excessive accumulation of apical F-actin in an epithelial cell lacking CAP.

      Response: We realize that in the original manuscript, we did not fully succeed in communicating the advance made by this study. The Reviewer correctly points out, that the apical actin accumulation has been reported previously by Baum and Perrimon (2001) (PMID: 11584269). In our view, the main advance of our study relevant for broader audience interested in epithelial cell biology is that the disturbance of apical actin turnover in epithelial cells in vivo locally disturbs non-centrosomal microtubule organization. We show that while microtubule polarity is preserved (dynein localization) and apical Patronin localization is retained, the microtubules are markedly reduced from the apical site of actin accumulation. In the revised manuscript we further show that this phenotype can be partially reversed by a 30 min latrunculin A treatment, which also partially reduces the actin accumulation. We also show that the apical actin accumulation leads to mislocalization of the actin-microtubule crosslinker Shot. Notably, this mislocalization is also partially rescued by the 30 min LatA treatment, further supporting that these changes reflect direct impact on actin-microtubule coupling. In addition, more specific advance relevant to scientists studying regulation of actin cytoskeleton are following 1. Evidence for the role of CAP in local regulation of apical actin turnover in epithelial cells in vivo. We show that while the apical actin pool is rapidly (5 min) lost in LatA-treated control cells, reflecting high turnover, it becomes significantly more resistant to LatA in CAP mutant cells, supporting the conclusion that CAP controls apical actin turnover. This conclusion is further supported by the findings of Aip1 enrichment in the sites of CAP-dependent actin accumulation. Aip1 associates with cofilin-decorated filaments undergoing disassembly. 2. Establishing the essential role of the CARP domain of CAP in epithelial actin turnover in animals in vivo. Through domain-specific rescue experiments, we demonstrate that CARP-domain function is uniquely required to prevent apical actin accumulation, whereas mutations affecting other described CAP activities retain substantial rescue capacity. These data identify actin monomer recycling as a critical determinant of epithelial actin turnover and provide the first in vivo functional dissection of CAP domain requirements in a polarized epithelial tissue.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)): Summary: Cyclase-Associated Protein (CAP) is a multifunctional regulator of actin turnover that stabilises pointed end of actin filaments and facilitates ADP-ATP exchange on G-actin. In the manuscript by Babu et al. re-visit a previously described phenotype of CAP mutants in Drosophila follicle epithelial cells. Depletion of CAP in the follicular epithelium leads to an accumulation of dense actin aggregates in the apical region of the cells. This ectopic apical actin structure disrupts the organization of the non-centrosomal microtubule (MT) network, Dynein-based apical cargo trafficking, the formation of apical microvilli and nuclear positioning.

      1) The most interesting part of the manuscript in my opinion is the rescue of the CAP mutant phenotype by various CAP transgenes. The authors show that the formation of the actin aggregates can be rescued by the overexpression of CAP defective in pointed end depolymerisation activity, but not by a transgene with the for CARP domain, which is involved in actin monomer ADP-ATP exchange. This leads to the conclusion that the formation of actin aggregates is not caused by the stabilisation of the pointed ends of actin filaments, but rather by deficient G-actin ADP-ATP exchange. However, the overexpression of profilin does not rescue the CAP phenotype. It seems counterintuitive that depletion of G-actin-ATP induces the formation of an ectopic actin structure, suggesting an excess of actin polymerisation. Thus, the molecular basis for the phenotype remains unexplained.

      Response: We thank the reviewer for carefully considering the mechanistic implications of our domain-rescue experiments and for highlighting the apparent contradiction between impaired G-actin nucleotide exchange and accumulation of filamentous actin. We agree that this observation is initially counterintuitive. Our interpretation, however, is that CAP mutant cells do not exhibit increased actin assembly but instead accumulate actin filaments due to a failure of the turnover and recycling cycle. Several lines of evidence support this interpretation: • The accumulated apical actin is resistant to Latrunculin A (Fig. 6B), compared to apical actin in control cells (Fig. 1B, C), indicating that CAP reduced turnover rather than active assembly • The actin structures are enriched in Aip1 which associate with cofilin-decorated filaments undergoing disassembly (Suppl. Fig. 1B) • Basal actin levels are reduced (Fig. 1N'), consistent with depletion of ATP-actin monomers Together, these observations indicate that actin filaments accumulate because they become trapped in a non-productive state, rather than because polymerization is increased. In this context, the CARP domain plays a central role in coordinating ADP-actin processing, cofilin release, and nucleotide exchange. Disruption of this domain is expected to stall multiple steps of the recycling cycle simultaneously. This results in accumulation of ADP-bound actin and failure to sustain dynamic turnover. Thus, the phenotype likely reflects an impairment of the actin recycling system as described in previous studies (PMID: 29760438, PMID: 36912152), rather than a shift in polymerization dynamics. We have expanded the Discussion to explicitly address this point and clarify the interpretation of the underlying mechanism.

      2) I suggest that the authors go further to pinpoint the in vivo function of CAP in epithelia. According to Kotila et al., 2018, the CARP mutant that the authors used for their rescue experiments disrupts both G-actin-ADP binding and ADP-ATP exchange. The authors could test less severe CARP mutants for their ability to rescue the phenotype, such as the ∆4C mutant, which disrupts nucleotide exchange but still binds ADP-G actin, and K347A Y351A Y353A (yeast numbering), which disrupts ADP G-actin binding, but keeps ADP-ATP nucleotide exchange activity intact.

      Response: We agree that analysis of additional CARP mutants would provide valuable mechanistic insight. However, we were not able to perform these experiments within the scope of the current study: • The specific mutants separating ADP-actin binding and nucleotide exchange functions have not yet been generated in our system • We attempted to generate transgenic lines expressing the Δ4C mutant; however, these lines were unstable, poorly expressed, or non-viable These observations suggest that disruption of CAP function at this level may have strong dominant-negative or toxic effects in vivo. This is consistent with previous findings in yeast, where Δ4C behaves similarly to a CAP loss-of-function mutant by sequestering ADP-actin and stalling the turnover cycle (Kotila et al., 2019, PMID: 29760438). Such a dominant-negative effect could explain the poor viability and instability of transgenic lines. While we regret that we cannot provide these additional data, we believe that our current results already support a model in which CAP function cannot be reduced to a single biochemical activity but instead reflects coordinated regulation of multiple steps in actin turnover. We now state this limitation explicitly in the manuscript.

      3)The authors claim that noncentrosomal microtubules are disorganised in CAP mutant cells. However, the density of MTs below the apical actin barrier is normal and Patronin, a well-characterised marker of MT minus ends, still localises apically. This suggests that even though MT cannot penetrate the ectopic actin structure, they efficiently go round it. Since the authors have concluded that MT apical-basal polarity is preserved in CAP mutant cells, they should explain and demonstrate more clearly what is specifically wrong with the MT organisation and how this links to nuclear mispositioning.

      Response: The reviewer points out that our original description of the microtubule phenotype as "disorganized" was imprecise. We have revised this interpretation to more accurately reflect our observations. Specifically, we find that: • Microtubules are detectable beneath the actin accumulation (Fig. 5A-C) • Minus-end anchoring at the apical cortex is preserved (Patronin, Fig. 5D-F) • Microtubule polarity remains intact (Dynein, Fig. 7J-L) Thus, the microtubule array is not globally disrupted but is instead spatially redistributed relative to the apical cortex. We agree with the reviewer that microtubules may "go around" the actin-rich region, and this observation may be related to Shot mislocalization and changes in actin-microtubule coupling. However, such redistribution is itself likely to have functional consequences, particularly for processes that depend on proper microtubule positioning and engagement at the apical cortex. Importantly, we now incorporate Shot mislocalization into this interpretation (Fig. 5G-I). Because Shot mediates actin-microtubule coupling, its displacement suggests that microtubules may fail to be properly captured or guided at the cortex, in addition to being displaced. Consistent with the known role of apically organized microtubules in follicle cell nuclear positioning (PMID: 23077179), we propose that disruption of actin-microtubule coupling together with reduced microtubule access from the apical cortex may impair the spatial organization of microtubule-generated pushing forces required for nuclear positioning. We have revised the manuscript to emphasize spatial redistribution and impaired functional engagement, rather than disorganization.

      4)It would be very helpful if the authors could provide a clearer explanation why the expression of CAP rescue constructs enhances the nuclear mispositioning phenotype. I do not understand how the "better survival" (line 346) of cells connects with nuclear positioning. It is also not clear why the nuclear mispositioning phenotype cannot be rescued by expressing CAP transgenes at stages 8 to 10.

      Response: The reviewer highlights the need for a clearer and more consistent interpretation of the nuclear positioning phenotype. We agree that the original manuscript did not adequately explain the relationship between rescue construct expression and nuclear positioning, and we have removed unsupported statements regarding "better survival." Our revised analysis now provides a plausible explanation for why nuclear positioning is not restored by CAP re-expression. Specifically, we show that: • Nuclear mispositioning is present in CAP mutant cells (Fig. 4A-C). • CAP rescue constructs exhibit minimal expression during stages 6-7, when nuclear positioning is established (Fig. 4J-K). • During this same developmental window, actin accumulation and microtubule defects persist in CAP rescue cells (Fig. 4D-I). • At later stages, when CAP expression increases, both the actin and microtubule phenotypes are efficiently rescued. Together, these findings indicate that expression of the rescue construct occurs largely after the developmental period during which nuclear positioning is established. Thus, the inability of the transgene to rescue nuclear positioning is consistent with the temporal requirements of this process rather than a failure to rescue CAP function per se. Based on these observations, we propose that the nuclear positioning phenotype arises as a consequence of early cytoskeletal defects. Given that nuclear positioning in follicle cells depends on coordinated actin and microtubule organization during stages 6-9 (PMID: 23077179), persistent cytoskeletal defects during this period provide a plausible explanation for the observed phenotype. We have revised the manuscript accordingly and now clearly state that, while the data support a temporal explanation, the precise mechanism linking CAP function to nuclear positioning remains to be determined.

      Minor points: 1) Line 523 "For rescue experiments clones were generated up to 9 days prior to dissections, in order to ensure the disappearance of endogenous CAP." It takes less than 2 days for an egg chamber to mature from stage 1 to stage 10. Thus, waiting longer after clone induction should have no effect on the perdurance of CAP.

      Response: We agree that the timing of egg chamber development suggests that prolonged clone induction is unlikely to significantly affect the perdurance of endogenous CAP. We have revised this statement in the Methods section to avoid implying that extended induction time ensures CAP depletion. Instead, we now describe the experimental timing more accurately and avoid overinterpreting its effect.

      2)I could not find what media was used for incubating egg chambers with Latrunculin A.

      Response: We have now added a detailed description of the incubation conditions used for Latrunculin A treatment, including the culture medium and treatment parameters, to the Methods section to ensure reproducibility.

      Reviewer #3 (Significance (Required)): Although the data are sound, this report does not explain why CAP mutants cause an apical accumulation of F-actin in epithelial cells. Instead, their data seem to rule out the most likely explanation, namely that a loss of CAP leads to a failure to disassemble actin filaments, because mutation of the HDF domain, which enhances filament disassembly has no effect on the rescue by CAP transgenes. Since the CARP domain, which binds to G-actin to catalyse ADP to ATP exchange, is required for rescue, we are left with the counterintuitive conclusion that reducing the levels of assembly-competent ATP G-actin increases F-actin polymerisation. The main part of the manuscript describes the CAP mutant phenotype in detail. This reveals that the large apical blob of actin excludes other cellular structures. However, this does not advance our understanding of actin/ microtubule crosstalk as the authors claim, not does it explain why the nucleus is mispositioned even in rescued CAP mutant clones

      Response: As discussed above, we agree that the accumulation of F-actin upon disruption of a recycling function appears initially counterintuitive. However, our evidence that the apical actin pool is rapidly (5 min) lost in LatA-treated control cells but becomes significantly more resistant to LatA in CAP mutant cells, supports the conclusion that CAP indeed promotes apical actin turnover. This conclusion is further supported by the findings of Aip1 enrichment in the sites of CAP-dependent actin accumulation. Aip1 preferentially associate with aged, Cofilin-decorated filaments undergoing disassembly. As explained above, the failure of rescue of the mutant phenotype by the CARP domain mutant may reflect failure in the actin recycling, a conclusion supported by recent studies (PMID: 29760438, PMID: 36912152). Therefore, the conclusions of the role of CAP in epithelial actin turnover (disassembly vs. polymerization), cannot in our view be solely based on the single line of evidence from the CARP domain mutant rescue.

      While we appreciate the Reviewer's perspective, we believe our findings advance understanding of actin-microtubule crosstalk by identifying a role for local actin turnover in regulating the positioning and cortical engagement of non-centrosomal microtubules in vivo. Our data shows that while microtubule polarity is preserved (dynein localization) and apical Patronin localization is retained, the microtubules are markedly reduced from the apical site of actin accumulation. In the revised manuscript we further show that this phenotype can be partially reversed by a 30 min latrunculin A treatment, which also partially reduces the actin accumulation. We also show that the apical actin accumulation leads to mislocalization of the actin-microtubule crosslinker Shot. Notably, this mislocalization is also partially rescued by the 30 min LatA treatment. Collectively, these data support the conclusion that CAP-mediated apical actin turnover directly impacts actin-microtubule coupling in epithelial cells in vivo. In conclusion, our own interpretation of the advance aligns with that of Reviewer 1 that "the main advance of the study is functional and conceptual, linking CAP-dependent actin turnover to microtubule organization and apical trafficking in a polarized epithelial context."

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      Referee #3

      Evidence, reproducibility and clarity

      Summary: Cyclase-Associated Protein (CAP) is a multifunctional regulator of actin turnover that stabilises pointed end of actin filaments and also facilitates ADP-ATP exchange on G-actin. In the manuscript by Babu et al. re-visit a previously described phenotype of CAP mutants in Drosophila follicle epithelial cells. Depletion of CAP in the follicular epithelium leads to an accumulation of dense actin aggregates in the apical region of the cells. This ectopic apical actin structure disrupts the organization of the non-centrosomal microtubule (MT) network, Dynein-based apical cargo trafficking, the formation of apical microvilli and nuclear positioning.

      1) The most interesting part of the manuscript in my opinion is the rescue of the CAP mutant phenotype by various CAP transgenes. The authors show that the formation of the actin aggregates can be rescued by the overexpression of CAP defective in pointed end depolymerisation activity, but not by a transgene with the for CARP domain, which is involved in actin monomer ADP-ATP exchange. This leads to the conclusion that the formation of actin aggregates is not caused by the stabilisation of the pointed ends of actin filaments, but rather by deficient G-actin ADP-ATP exchange. However, the overexpression of profilin does not rescue the CAP phenotype. It seems counterintuitive that depletion of G-actin-ATP induces the formation of an ectopic actin structure, suggesting an excess of actin polymerisation. Thus, the molecular basis for the phenotype remains unexplained.

      2) I suggest that the authors go further to pinpoint the in vivo function of CAP in epithelia. According to Kotila et al., 2018, the CARP mutant that the authors used for their rescue experiments disrupts both G-actin-ADP binding and ADP-ATP exchange. The authors could test less severe CARP mutants for their ability to rescue the phenotype, such as the ∆4C mutant, which disrupts nucleotide exchange but still binds ADP-G actin, and K347A Y351A Y353A (yeast numbering), which disrupts ADP G-actin binding, but keeps ADP-ATP nucleotide exchange activity intact.

      3)The authors claim that noncentrosomal microtubules are disorganised in CAP mutant cells. However, the density of MTs below the apical actin barrier is normal and Patronin, a well-characterised marker of MT minus ends, still localises apically. This suggests that even though MT cannot penetrate the ectopic actin structure, they efficiently go round it. Since the authors have concluded that MT apical-basal polarity is preserved in CAP mutant cells, they should explain and demonstrate more clearly what is specifically wrong with the MT organisation and how this links to nuclear mispositioning.

      4)It would be very helpful if the authors could provide a clearer explanation why the expression of CAP rescue constructs enhances the nuclear mispositioning phenotype. I do not understand how the "better survival" (line 346) of cells connects with nuclear positioning. It is also not clear why the nuclear mispositioning phenotype cannot be rescued by expressing CAP transgenes at stages 8 to 10.

      Minor points:

      1) Line 523 "For rescue experiments clones were generated up to 9 days prior to dissections, in order to ensure the disappearance of endogenous CAP." It takes less than 2 days for an egg chamber to mature from stage 1 to stage 10. Thus, waiting longer after clone induction should have no effect on the perdurance of CAP.

      2)I could not find what media was used for incubating egg chambers with Latrunculin A.

      Significance

      Although the data are sound, this report does not explain why CAP mutants cause an apical accumulation of F-actin in epithelial cells. Instead, their data seem to rule out the most likely explanation, namely that a loss of CAP leads to a failure to disassemble actin filaments, because mutation of the HDF domain, which enhances filament disassembly has no effect on the rescue by CAP transgenes. Since the CARP domain, which binds to G-actin to catalyse ADP to ATP exchange, is required for rescue, we are left with the counterintuitive conclusion that reducing the levels of assembly-competent ATP G-actin increases F-actin polymerisation.

      The main part of the manuscript describes the CAP mutant phenotype in detail. This reveals that the large apical blob of actin excludes other cellular structures. However, this does not advance our understanding of actin/ microtubule crosstalk as the authors claim, not does it explain why the nucleus is mispositioned even in rescued CAP mutant clones

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      Referee #2

      Evidence, reproducibility and clarity

      Babu and colleagues report that clonal loss of Cyclase associated protein (CAP) function results in dramatic accumulation of F-actin in a large cytoplasmic domain below the apical surface of Drosophila egg chamber follicle cells. Rescue experiments confirm the overall role of CAP and show that its function in converting actin-GDP to actin-GTP is critical for preventing the F-actin accumulation. Numerous components of the cell are probed in the mutant clones, and are shown to have altered distributions. Microtubules and intracellular membranes are generally excluded from the abnormal F-actin domains, and Latrunculin A treatment partially reversed the microtubule exclusion. Abnormalities in apical microvilli, apicolateral nuclear positioning, and actin binding protein distributions are also reported. In general, the microscopy is quite striking and the manuscript is clearly written, but the overall advance seems fairly limited and several revisions are needed.

      Major comments:

      1. The authors conclude that the abnormal F-actin accumulations of CAP mutant cells coincide with microtubule cytoskeleton alterations, and say that this "suggests that spatially regulated actin filament turnover is important for microtubule organization". Although the conclusion and suggestion are formally true, they don't consider the directness of the relationship. In my view, two possibilities of indirect effects should be included: (1) the general disruption of subcellular organization by the large F-actin accumulation suggests that many indirect effects are possible, and (2) the very high level of F-actin accumulation, and of actin binding protein co-accumulations, without apparent losses from other parts of the cell suggest that the mutant cells have undergone major gene expression changes which could have a range of effects.
      2. The authors state that the CARP domain of CAP is known to bind ADP-actin monomers and promote ADP-ATP exchange, "thereby recharging actin monomers for polymerization". Of many mutations expected to affect individual domains of CAP, only mutations disrupting the nucleotide exchange activity of the CARP domain failed to rescue the abnormal F-actin accumulations of CAP mutant cells. It was unclear how extreme actin polymerization occurs in cells in which the CAP protein expressed only lacks the ability to recharge actin monomers for polymerization. Minimally, the results of the domain analyses should be addressed in the Discussion section. More analyses/constructs may be needed to confirm whether the mutations listed in Table 1 had their intended effects on CAP domain activities (especially on the activity of the HFD domain implicated in actin depolymerization).

      Minor comments:

      1. It is stated that "In follicular epithelial cells, Lat A treatment resulted in the disappearance of apical and basal actin, whereas cortical actin remained largely unaffected in both stage 8 and 10 egg chambers (Figure 1B)". However, the disappearance of basal actin was not clear because it is at low levels in the control making the comparison with the treatment difficult to interpret. Also, "lateral" would be a better term than "cortical".
      2. The authors state "Interestingly, the width of the perivitelline space, apically to CAP mutant cells was decreased compared to the neighboring cells (Figure 3 E)." However, it was unclear where to look in the figure panel to see this effect. A degree of quantification is also warranted.
      3. In Figure 4, I recommend expanding the explanations of the X axes of the graphs, and adding explanations of why data from the same experiment are graphed in multiple ways (or simplifying the presentation if it still allows the same conclusions).
      4. Typo on page 6, line 244: "(Figure 4 C, E-F)"?
      5. More detail is needed to clarify this interpretation: "Furthermore, the localization of membrane-bound mCD8-GFP was partially restored in the apical region of CAP mutant cells after Latrunculin A treatment (Figure 5 E, F)." With respect to the local mCD8 protein levels, the DMSO control and LatA treatment seem similar.
      6. Grammar issue on page 2, line 50: "comprising of contractile actin"
      7. Unclear sentence on page 3, line 100: "Our study demonstrates that actin disassembly protein, Cyclase associated protein-mediated apical actin turnover is required for..."
      8. On page 4, after describing an increased expression of profilin localized mainly away from the site of F-actin accumulation, the authors conclude that "This indicates that an excess of actin filament assembly is unlikely to occur at the apical side of CAP mutant cells." I suggest toning down this conclusion.

      Significance

      The advance made by the paper seems somewhat limited. In part, this is due to the two major comments above. Addressing these concerns experimentally could increase the significance of the paper. Additionally, the authors reference Baum and Perrimon (2001), a paper which showed excessive, apical F-actin accumulations in follicle cells mutant for CAP in Drosophila egg chambers. Other studies referenced in the manuscript provide evidence of local F-actin accumulations affecting the distributions of other components of a cell. Thus, the main conclusions of the manuscript seem similar to those made by previously published papers. Nonetheless, a strength of the paper is its reporting of altered distributions of a wide range of cell components in relation to an excessive accumulation of apical F-actin in an epithelial cell lacking CAP.

    4. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #1

      Evidence, reproducibility and clarity

      In the manuscript by Babu et al, "Apical actin filament turnover mediated by cyclase-1 associated protein is required for organization of non-centrosomal microtubules in epithelium," the authors investigate how Cyclase-associated protein (CAP) regulates apical actin organization and how this impacts microtubule architecture and apical trafficking in the Drosophila follicular epithelium. CAP depletion leads to accumulation of a dense, Latrunculin-resistant apical F-actin network, accompanied by loss of apical microtubules, mislocalization of vesicular markers (e.g., Rab11, Cad99C, Dynein), defects in microvilli formation, and altered nuclear positioning. Domain-rescue experiments suggest that CAP's nucleotide exchange activity is required for proper actin organization.

      The study presents a rich set of phenotypic observations and highlights an important interplay between actin turnover, microtubule organization, and epithelial polarity. However, several key mechanistic conclusions are currently not fully supported by the data, and an important conceptual question regarding the spatial specificity of CAP function remains insufficiently addressed.

      Major Comments

      1. Is the CAP function truly apically specific? A central conclusion of the manuscript is that CAP regulates the apical actin cytoskeleton. However, the data do not yet clearly distinguish whether CAP acts in a spatially polarized manner or instead regulates global actin turnover, with apical accumulation emerging as a secondary consequence of epithelial geometry. As CAP appears largely cytoplasmic, it is plausible that its depletion affects actin dynamics throughout the cell. In this scenario, actin accumulation may become most apparent at the apical domain because this region is less occupied by organelles compared to the laterobasal cytoplasm. Thus, the observed phenotype could reflect global dysregulation of actin turnover, rather than a specifically apical mechanism. Importantly, this does not contradict the authors' model but represents an alternative that should be addressed. To clarify this point, the authors should consider:
        • Quantifying actin distribution across the full apico-basal axis
        • Testing whether forced relocalization of CAP (e.g., to the basal cortex) alters where actin accumulates
        • Assessing whether non-apical actin structures are also altered but less apparent Without addressing this, the claim of apical-specific regulation remains insufficiently supported and should be framed more cautiously.
      2. what is the primary molecular function of cap in this context? While the phenotypic consequences of CAP depletion are well described, the manuscript does not clearly resolve which step of actin turnover is affected. CAP is known to function in actin monomer recycling and cooperate with cofilin, but it remains unclear in this system whether the primary defect reflects: (i) Impaired actin depolymerization, (ii) Reduced monomer recycling or altered filament dynamics or nucleation balance Clarifying this point is important, as it would strengthen the mechanistic link between CAP activity and the observed cellular phenotypes. Even if not directly tested experimentally, this aspect should be more explicitly discussed and, where possible, supported by quantitative analysis of actin dynamics.
      3. insufficient quantification of actin stability. The conclusion that apical actin is stabilized in CAP mutants is based primarily on qualitative observations of Latrunculin A resistance. While convincing visually, this requires quantitative validation. Measurement of actin intensity under {plus minus}LatA conditions, across multiple samples with proper normalization and statistical analysis, is necessary to substantiate increased actin stability.
      4. Domain-rescue experiments lack quantification (Fig.2,S2). The conclusion that the CARP domain is required for rescue is based on qualitative comparisons. Given the importance of this experiment for mechanistic interpretation, quantitative analysis of rescue efficiency (e.g., actin intensity, percentage of rescued clones) is essential.
      5. Microtubule exclusion model is not directly demonstrated The authors propose that dense apical actin physically excludes microtubules. While the presented data are consistent with this model, they remain correlative. Alternative explanations include: (i) Altered microtubule stability, (ii) Defective nucleation or anchoring or (iii) changes in epithelial polarity affecting microtubule organization. To distinguish between these possibilities, the authors should:
        • Perform live imaging of microtubule plus ends (e.g., EB1) to assess whether microtubules fail to enter or instead destabilize at the apical region
        • Examine whether microtubule polarity or nucleator localization is altered
        • Increase sample size and quantification for line-scan analyses (Fig. S3) The current interpretation should therefore be presented more cautiously as one of several possible mechanisms.
      6. Shot redistribution suggests an alternative mechanism (Fig.6). The redistribution of Shot beneath the actin accumulation is a key observation that is currently underexplored. Given that Shot mediates actin-microtubule crosslinking, this finding suggests that disrupted cytoskeletal coupling could underlie microtubule defects. This provides an alternative to the steric exclusion model and should be more fully integrated into the manuscript. The authors should:
        • Quantify Shot redistribution relative to the apical domain
        • test whether restoring Shot at the apical cortex rescues microtubule organization
        • compare effects of Shot versus Patronin manipulation to distinguish crosslinking versus anchoring roles
      7. Nuclear positioning phenotype is not fully resolved (Fig.7). The explanation that the lack of rescue reflects late expression of the CAP construct is plausible but not experimentally demonstrated. This interpretation should be toned down or explicitly presented as speculative.

      Minor comments:

      1. Quantification and sample size Many claims rely on representative images and n and N are not reported in such cases. Include quantification and clearly report n and N for all analyses.
      2. Vesicle exclusion and secretion defects remain indirect (Fig.3) Evidence for vesicle exclusion is based on loss of ER/Golgi markers and altered TEM structures. However, TEM identification of mutant (clones) cells is phenotype-based. The current data are consistent with altered apical trafficking but do not directly demonstrate vesicle exclusion from the actin-rich domain. More direct evidence would require visualization of vesicle dynamics to determine whether they fail to enter, stall at or are redirected from the apical actin accumulation. The current wording should be softened accordingly.

      Significance

      The work provides a strong phenotypic characterization linking CAP depletion to accumulation of a dense, Latrunculin-resistant apical F-actin network, accompanied by defects in microtubule organization, vesicle localization, and epithelial morphology. A key strength is the integration of multiple readouts to connect actin turnover with broader aspects of epithelial organization. The study therefore offers potentially important insight into how actin dynamics can influence cytoskeletal crosstalk and tissue architecture. However, several central conclusions rely on largely qualitative or correlative evidence, and quantitative support is limited in key experiments. In addition, an important conceptual question remains unresolved: whether CAP regulates actin turnover in a spatially polarized (apical-specific) manner or more globally, with apical phenotypes emerging as a consequence of cellular organization. Addressing this distinction, along with strengthening quantification and moderating interpretation of the steric exclusion model, would substantially improve the manuscript.

      The main advance of the study is functional and conceptual, linking CAP-dependent actin turnover to microtubule organization and apical trafficking in a polarized epithelial context. While CAP is known to regulate actin dynamics, its role in coordinating cytoskeletal organization at the tissue level is less well defined, and this work extends current knowledge in that direction. At present, however, the mechanistic insight remains limited, particularly regarding the specific step in actin turnover affected and the causal relationship between actin, microtubules, and trafficking defects. The study will be of primary interest to a specialized audience in cytoskeleton, epithelial, and developmental biology, with broader relevance to researchers studying actin-microtubule crosstalk and cell polarity.

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      Referee #3

      Evidence, reproducibility and clarity

      Cancer is associated with profound changes in metabolism and a deprivation of nutrients, including an overall reduction in amino acids. This research group has previously demonstrated that amino acid deprivation leads to ECM uptake that drives breast cancer cell migration and growth, but the mechanisms that drive this ECM scavenging are unknown. Here, the demonstrate that the collagen receptor integrin a2 is upregulated in cells following AA starvation in cells cultured in 2D and 3D. This upregulation is promoted by Ras/MEK signalling and was required for collagen uptake by cells. Furthermore, amino acid starvation was shown to promote cell adhesion to collagen-I and cell migration, highlighting the functional importance of this pathway.

      The data presented and approaches used are clear and well executed with appropriate conclusions made from the data. I have a few questions and suggestions that would help clarify the findings of the study and potentially increase the impact of the study:

      1. A clear change in a2 expression levels are shown following amino acid starvation, but does this correspond to changes in surface levels of this integrin?
      2. In the attachment assays, you mention that integrin a5 levels are not altered and suggest fibronectin as a possible ECM where no change in adhesion would be observed. Have you done the experiment with fibronectin?
      3. The conclusions are written appropriately for the data presented, but it would be interesting to determine whether the a2 internalisation and collagen-I uptake are required for the changes in proliferation observed following starvation rather than signalling downstream of a2 engagement with ligand.
      4. Similarly, the conclusion that amino acid starvation promotes attachment and migration on collagen is appropriate, but is this dependent on a2? You could use you inhibitor or knockdown to assess this.
      5. Does a2 localise to adhesion complexes in your assays? This is particularly relevant to your proliferation and migration assays where you use complete media over a longer period of time, ECM protein in the serum and generated by cells over this time may alter the integrins being utilised by the cells.

      I think addressing all of these points is optional as they will help strengthen the study but will not alter the conclusions drastically.

      The text and figures are very clear and work in the field is cited appropriately.

      Significance

      The findings from this study are significant to a variety of cancer types where changes in metabolism and nutrient availability are prevalent. The findings suggest that targeting a2 integrin may be a valid treatment option in pancreatic and breast tumours, particularly in relation to those with KRAS mutations which increases the significance of this study significantly and paves the way for future research that will presumably use patient-derived cells to assess some of the pathways identified.

      This study will be of interest to people working in basic research, cancer research and potentially translational research.

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      Referee #2

      Evidence, reproducibility and clarity

      This well-prepared manuscript describes the results of a study interrogating the mechanisms regulating amino acid-starvation-driven ECM uptake via alpha-2-integrin. The experiments are carefully carried out and analysed, and my comments mainly concern some analyses that are in my view lacking to fully enable the conclusions drawn.

      Specific comments

      Fig. 1. Maybe I am just missing something, but I do not understand the collagen-I labeling procedure: pH-rodo is pH sensitive, with increasing fluorescence at acidic pH values. It can therefore be used to assess endo-lysosomal pH values - but how do you distinguish in your collagen-I uptake index between more collagen taken up, vs localization in more acidic compartments? It seems this could introduce confounding effects. Please comment, and consider validating with a non-pH sensitive fluorophore.

      Fig. 2. There is a very dramatic difference between the increase in ITGA2 mRNA levels (up to 200-fold) and protein levels (max 2-fold) in starvation conditions. Would protein levels increase more substantially upon longer treatments? This deserves at least commenting, ideally testing.

      Fig. 3. It is very nice that the authors emply a matrigel 3D culture, but this is still a very artificial scenario, and matrigel does not really mimic the tumor ECM. To what extent is the same mechanism required for cancer cell survival in a more realistic tumor environment - i.e. with more complex ECM and/or additional (stromal) cell types present - which would alter the nutrient landscape? It would be very valuable to conduct experiments addressing this, but at least it should be discussed in more detail.

      Fig. 4. The authors convincingly show that the GCN2 pathway is not responsible for the ITGA2 regulation. This is a very nice opportunity to gain insight into the relative importance of ITGA2 for cancer cell survival under nutrient starvation - how much is growth affected by the GCN2 inhibition relative to by interfering with ITGA2?

      Perhaps I missed it, but can you comment on the possible relation and/or relative importance of the mTOR-inhibition-driven and RAS-driven pathways of ITGA2 regulation? If RAS signaling is important for the starvation-driven increase in ITGA2, does that imply that starvation further activates RAS signaling in cells which already harbor an oncogenic RAS mutation and thus presumably have constitutively increased RAS/MEK/MAPK signaling? Should ITGA2 not be consitutively upregulated in these cells if it was driven by RAS? Or is RAS just necessary, not the driver? Can the effect of starvation on ITGA2 be mimicked by introducing a constitutively active RAS in cells not harboring such mutations?

      Fig. 6. It would be very helpful to show whether this increased migration and spreading is dependent on the RAS-dependent increase in ITGA2 (use a RAS inhibitor) and/or can be mimicked by overexpression of ITGA2? And a suggestion: the quantified difference in F is very small (about 0.4 vs 0.45), whereas the image indicates that the gap is essentially closed in the AA condition. I would replace this with a more representative example.

      Fig. 7. Similar to my concern above, can you distinguish between effects of the MEKi on endo-lysosomal pH vs on collagen uptake?

      Minor

      P 1, a5b1 intergin -> integrin

      Significance

      Maybe not a huge advance but a carefully performed and clearly relevant study which contributes new information and is clearly deserving of publication.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      In this study, Yanes et al. used several cell lines from pancreatic and breast cancer to show that amino-acid starvation induces ECM uptake via RAS-MEK signaling pathway-dependent increase of integrin α2 expression at the RNA and the protein level, using RAS and MEK inhibitors. They also showed that this pathway enhances cell adhesion and that AA starvation promotes migration on collagen. Patient data analysis indicated a correlation between high integrin α2 expression and poor prognosis in pancreatic cancer.

      Major comments:

      While the key conclusions are mostly convincing, some require additional experiments to be fully supported, and some additional discussion would help to clarify some points, as explained in the comments bellow. The data are clearly presented and properly analyzed and replicated with the adequate statistical analysis. The methods are clear enough to ensure reproducibility.

      1) When observing collagen uptake, it would be useful to have a staining of endosomal markers to show that collagen is internalized in endosomes. Otherwise, the observed structures can only be named "vesicles" and not "endosomes".

      2) In figure 1D, the proliferation is tested only by counting cells after 4 days. We cannot exclude that the difference in cell numbers is due to a difference in cell viability or to a difference of the number of cells which initially attached (as it is shown in figure 6C). Testing proliferation with a proliferation assay such as Brdu incorporation assay or at least testing the cell viability would ensure that AA starvation improves proliferation on collagen.

      3) Only one siRNA has been used to knockdown integrin α2. A second siRNA should be used to ensure that the observed effects of the knockdown are not due to off-target effects.

      4) In figure 2B-F, it seems that the integrin α2 levels differ between the cell lines, both at the baseline level and after starvation. Do these differences correlate with different capacities of each cell line to internalize collagen in response to AA starvation? This should be discussed.

      5) In conclusion of figure 2, it is said that "a3, a5, and a6 integrin were not affected" by AA deprivation, and this is written again in the discussion. However, Figure S1K shows that integrin α5 expression also increases in this condition in SW1990 cells, as written in the text when describing this figure. The conclusion should be changed to include this result, and it would be nice to discuss it. Would fibronectin internalization in response to starvation also happen in this cell line?

      5) In figure 3 it seems from the images that integrin α2 is increased only in cell-cell adhesions but not on the edge of the spheroids in contact with the matrix. Is this something consistent and could this be quantified? If the increase is only happening inside the spheroids, it seems unlikely that it would have a role in matrix uptake in 3D. Moreover, as figure 6D does not show any difference of cell adhesion to Matrigel in complete media vs under AA starvation, doing the 3D experiments in collagen rather than Matrigel would give a better insight in the significance of the uptake mechanism in 3D. Even if the observation of integrin α2 expression changes in 3D is suggesting a similar mechanism in 3D than in 2D, observing collagen uptake in 3D would ensure that the role of this pathway is the same than in 2D. This could be done either by staining for collagen in Matrigel or by embedding the cells inside fluorescent collagen. Finally concerning the 3D data, in Figure 3 the size of the spheroids is quantified but no conclusion is drawn from the observed difference. Quantifying the number of cells would give a better readout of the differences in proliferation.

      6) Figure S3 shows that the MRTX1133 KRASG12D inhibitor decreases expression of integrin α2 in SW1990 cells but not in PANC1 cells, and it is speculated that this difference is due to the heterozygous status of PANC1 cells for KRAS. Using a pan-RAS inhibitor would be useful in PANC1 cells to confirm this hypothesis.

      7) The finding in Figure 6D that AA starvation does not impact adhesion on Matrigel is surprising, as we would expect Matrigel to contain collagen. This should be further discussed. As SW1990 also express higher levels of integrin α5 in response to starvation, looking at adhesion on fibronectin should be done to interrogate if this mechanism is specific to collagen binding only.

      8) The functional experiments of Figure 6 show nicely that AA starvation improves cell adhesion on collagen and migration under a collagen overlay. However, this does not show if the uptake of collagen itself is involved there. Blocking endocytosis would show if collagen uptake is necessary for the observed phenotype, or if it is only due to the higher expression of integrin α2 which by itself enhances cell adhesion and migration. Using in the migration experiment RAS and MEK inhibitors is also necessary to show that the same pathway is involved in migration to exclude that AA starvation would impact these via a different pathway, as it has been done for adhesion in Figure 7A. As the migration is emphasized in the title, I would also expect to see this experiment on other cell lines.

      9) While most experiments are performed on SW1990 cells, the collagen uptake experiment under MEK inhibition of Figure 7B was done only on MCF10A cells. This should be done on the SW1990 cells as well for consistency.

      10) If possible, showing correlation between KRAS mutation status and integrin α2 expression in patient data would reinforce the conclusions on the clinical significance of the mechanism. As the study includes breast cancer cell lines, showing the correlation between integrin α2 expression and survival in breast cancer patients would also provide better insights on the relevance of the mechanism in different cancer types.

      Minor comments:

      1) A reference is missing to cite the origin of the BTT-3033 inhibitor. I would suggest to cite Nissinen et al. Journal of Biochemistry 2012 (DOI: 10.1074/jbc.M111.309450).

      2) In figure 2L-M the 37kDa mark is not placed at the same height for all the GAPDH bands. I suppose it is an issue of the figure design rather than an issue on the blot itself and this should be corrected. Without the uncropped blots showing the ladder it is however not possible to assess if the bands are really at the indicated size, these should be provided.

      3) In Figure 6F, the graph should indicate individual values.

      Significance

      This study follows previous findings by the same group and others who showed that ECM uptake promotes tumors cells survival and proliferation in a low-nutrient availability context, and that the integrin α2β1 allows collagen uptake. The new findings here link these two observations as AA starvation is shown to upregulate integrin α2, leading to pro-oncogenic phenotypes. The study provides a mechanism for this, as they show the involvement of the RAS-MAPK pathway. The point made in the discussion that depending on the ERK inhibitor used or the duration of the inhibition might lead to different effects on integrin α2 levels, added to the discrepancies between cell lines, suggests that the described mechanism might not be universal or is relevant only in specific conditions.

      This is still an interesting and important conceptual and mechanistic advance, which will be of interest for researchers in the fields of cancer (here pancreas and breast cancer), cell adhesion and signaling, mostly for basic research but potential clinical implications might be of interest for a broader audiance.<br /> My expertise relevant to this study is in cancer cell biology, cell adhesion, migration and signaling.

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      Reply to the reviewers

      General Statements

      We thank the reviewers for thoroughly reading our manuscript and their constructive feedback. We have considered each comment carefully and came up with a revision plan that can be found below.

      1. Description of the planned revisions

      Response to Reviewer #1, #2 and #3 concerning alternative assays to measure the effects of ER stress on ribosome translation:

      Reviewer 1: 4. The modest reduction in the translation upon ER stress induction could be supported by alternative biochemical assays such as polysome profiling and amino acid incorporation.

      Reviewer 2: Is there a difference in the number polysomes in the non-stressed vs stressed yeast cells? A functional assay, such as polysome profiling combined with nascent-chain labeling might help to support the observation that an increased level of hibernating ribosomes exist in DTT or Tm-treated cells. Has this been considered? Perhaps there is evidence available in the literature?

      Reviewer 3: 5. The study mainly provides structural snapshots and population distributions of ribosomal states, without direct functional measurements of translation activity. Could the authors provide orthogonal biochemical or functional evidence supporting reduced translation under these exact stress conditions?

      We thank the reviewers for this suggestion. Other studies have shown a decrease in protein synthesis rate (Geronimo RAC et al., 2025 (PMID: 40959222), Pincus et al., 2014 (PMID: 25275008)) under similar conditions which matches our findings. However, we agree that confirming a reduction in translation for our specific conditions will strengthen our findings.

      In our lab we have previously performed polysome profiling for mammalian cells, we will adopt this protocol to yeast cells and use this to measure changes in monosome abundance and changes in the polysome to monosome ratio. We will perform this experiment for our main strain (Ire1cGFP) upon 0 hr, 45 min. and 4 hr. DTT treatment. Given the increase in hibernating ribosomes upon prolonged ER stress, we hypothesize that polysome profiles will reveal an increase in monosome subunits, assuming that the technique is sensitive enough to pick up moderate changes in translational activity. In case polysome profiling is not sensitive enough to pick up the moderate change in hibernation, we also aim to quantify the decrease in protein synthesis using C-35 labeling as we have done earlier in collaboration (Fedry et al, Mol. Cell 2024 (PMID: 38340715)).

      Reviewer #1 continued:

      1. For identification of hibernating ribosomes, the authors rely mainly on the presence of empty ribosomes along with eEF2, eEF5A, and eEF3. Whether these particles indeed possess known dormancy factors or they are different subclass of empty ribosomes is unclear. Similar analysis in the absence of dormancy factors would strengthen the authors claims.

      While empty 80S ribosomes (lacking tRNAs, elongation or hibernation factors) have been described in purified ribosome samples, those seem to be an in vitro re-association artifact as they are never observed in cells (bacteria: Xue et al. Nature 2022 (PMID: 36171285), yeast: Cheng et al. 2025 (PMID: 39789210), mammals: Xing et al. 2023 (PMID: 37410833), Fedry et al. 2024 (PMID: 38340715), etc.).

      Instead, in cells ribosomes are found in three possible states:

      1. individual subunits (40S and 60S in eukaryotes),
      2. translating 80S ribosomes; featuring a tRNA in the P-site
      3. hibernating 80S ribosomes; lacking a tRNA in the P-site and hence non translating. Those ribosomes are typically bound by eEF2 interacting with the dormancy factor bound in the mRNA channel, as well as possible additional factors (eIF5A, Dap1, SNOR, etc.). Our Hib class is seen in cells without tRNA in the P-site and bound by eEF2; we can therefore unambiguously assign this class as hibernating ribosomes.

      While doing a similar analysis on the translation landscape under ER stress in the absence of hibernating factors may yield some interesting insights, it would also alter the overall stress response and therefore may not help with the interpretation of our current structures. It would require us to repeat our complete workflow with new yeast strains (with Stm1 and/or Lso2 knocked out) and in our opinion the amount of time that these experiments would require do not justify the additional confidence that would be gained from the results. We have therefore decided that these experiments will be beyond the scope of this study. We will add a supplementary figure showing the presence of a density in the mRNA channel further supporting the presence of a dormancy factor interacting with eEF2.

      1. The authors suggest that ER induces modest level of increase in hibernating ribosomes. Adding controls such as glucose deprivation and nitrogen starvation would have provided more strength in relative comparison of these ribosomal sub populations.

      To our knowledge, no cryo-ET study has been done to study the effect of glucose deprivation and nitrogen starvation on the abundance of different translational states, making it an interesting and relevant experiment to do. However, it is unknown what change(s) in translational state abundance(s) these low-nutrient conditions might cause, so we are unsure if they could serve as control conditions. Collecting data on yeast under different stresses would require extensive resources, and would not directly address the translational response to ER stress. Therefore, we consider these suggested experiments beyond the scope of this work. We think this is an interesting future research direction and will comment on this in our discussion.

      We will include the suggested conditions in our polysome profiling experiments (proposed above in the first part of our revision plan) and analyse their monosome to polysome ratios. These can serve as positive controls for strong translation shutdown. We are grateful for the reviewers suggestion.

      1. The authors show the retention of dormant ribosomes on the ER surface. As usual notion of ribosome association with ER membrane to be dependent on nascent translation, retention of dormant ribosomes on ER membrane is interesting and puzzling. Analysis using strains deleted for dormancy factors may provide more insights on this mechanism.

      We agree with the reviewer that the presence of hibernating ribosomes on the ER surface is an interesting observation, but we do not consider it surprising. For yeast and mammals, idle ribosomes bound to Sec61 are well established in vitro (e.g., Becker et al (PMID: 19933108)), indicating that the interaction between these two components is not dependent on active translation. Furthermore, an average of an ER-bound hibernating ribosomes have been found on microsomes derived from human cells, and they become the prevalent form upon DDT-treatment, which strongly suggests that hibernating ribosomes can stay bound to the ER (Gemmer et al., 2023 (PMID: 36697828)). To clarify this point we will refer to these previous findings in our revised manuscript. As our observation is consistent with current knowledge in the field, we do not believe that additional analysis is necessary on this point.

      Reviewer #2 continued:

      The new Dec3 state might be clarified a bit further by zooming in to the corresponding areas in the Dec1 and Dec2 structures. This is a point of novelty in the paper and should be emphasized for future reference. Does an additional classification algorithm, such as cryo-DRGN-ET, verify the various states, especially the new Dec3 state? The structures should of course be uploaded to EMDB or another suitable server.

      We will provide an additional supplemental figure, zooming in on the eIF5a area in Dec1/2/3. Dec3 was found in 3 separate classification runs and we will therefore not perform classification with an alternative algorithm. We will upload the novel structures (Dec3, Hib and the ER-bound ribosome) to EMDB, which will be released upon publication of this manuscript

      There is generally a lack of supporting quantification, which will bother a number of readers. For example, a "high confidence rigid body fit" shows additional density in the hibernating state, but what is the confidence? Even the resolution measures of 7-8 Angstrom are simply stated. Presumably they come from a WARP report. There should be some specification for the evaluation. How many lamellae were used, and how many tomograms? Were they taken from different biological experiments, or all collected from the same grid, for each condition?

      We agree with the reviewer that this additional information is required to properly judge our conclusions. We will provide a confidence score for the eEF3 fit. We will provide FSC curves as supplemental data, specifying where the FSC curve was obtained from. Local resolution estimates are derived from Relion. Table 4 indicates the number of tomograms collected per sample and we will add the number of lamella/grids used.

      Reviewer #3 continued:

      Major comments:

      1. For the analysis of ER-bound ribosomes, the authors applied an ellipsoidal mask during subtomogram averaging. However, this masking strategy may not be sufficient because the relative orientation of ribosomes with respect to the ER membrane can be variable, and membrane density may influence particle alignment. The authors may consider including an additional masking step to exclude membrane density and minimize potential alignment bias.

      We thank the reviewer for pointing out this confusing point in our manuscript. The ellipsoid mask was only used in the image classification step aiming at separating ER-bound ribosomes from soluble ribosomes. The ER-bound ribosomes were subsequently aligned with a mask comprising the large ribosomal subunit and the membrane. This was crucial for the alignment not to go astray. We will clarify this in the text:

      “Alignment and averaging of these particles using a mask comprising the ribosomal large subunit and the membrane region yielded a ribosome with a clear membrane bilayer and an additional density at the exit tunnel”

      The signal coming from the ribosomal RNA is very strong (unlike single particles studies of smaller membrane proteins) and typically much stronger than the signal coming from the ER membrane. This strategy is well established in the field (Pfeffer et al. 2014 (PMID: 24407213), 2015 (PMID: 26411746), Braunger et al. 2018 (PMID: 29519914), Gemmer et al. 2023 (PMID: 36697828)).

      1. Supplementary Figures 1B and 1C appear to suggest that the Ire1i-GFP and Ire1i-NG strains exhibit stronger HAC1 splicing upon DTT treatment. Given this apparent increase in UPR activation, it would be interesting to analyze these strains as well to determine whether they display more pronounced changes in translational states.

      We thank the reviewer for raising this interesting point. All strains display ~25% of hibernating ribosomes under ER stress. The corresponding analysis can be found in Sup Figures 4 and 5. We will clarify this point by adding a sentence about this and the reference to the corresponding Sup figures: “First, we observed an increase in the relative abundance of hibernating ribosomes (from 3 to 25%) at the expense of some of the major elongating states, like Dec2 and Pre (from 22% to 16% and from 38% to 17%, (Fig. 3E-F, Supp. Fig. 4D-e). A similar effect was observed in the Ire1i-GFP and Ire1i-NG (Sup. Fig. 4, 5). This increase in inactive 80S complexes is indicative of a reduced translation activity in the cell, that is typically caused by the inhibition of translation initiation.”

      There is a difference in the magnitude of HAC1 splicing, but all have sufficiently high HAC1 splicing levels to robustly activate ER stress. This can explain why they all show a similar abundance in hibernating ribosomes.

      Minor comments:

      1. "FOV" should be defined as "Field of View" upon first use

      We will correct the corresponding sentence to: “Cells were then imaged with cryo-ET at an intermediate magnification (6.32-7.09 Å/pix, Field of View (FOV): ~9 µm2), allowing us to laterally capture near-complete cellular ultrastructure in each tomogram (Figure 1B-D)“

      1. In Supplementary Figure 7A, the image quality appears insufficient to clearly resolve structures within the autophagic bodies. As a result, it is difficult to determine whether ER-derived membranes are present within these structures. If ER-like membranes are observed, this could suggest induction of ER-phagy under ER stress conditions, consistent with previous reports (e.g., Mizuno et al., PLoS Genetics, 2020).

      The tomogram in supplemental Figure 7A does not contain obvious ER-derived membranes. We have observed membranes in other tomograms but our cryo-ET approach does not allow us to identify their origin (ER or other organelles). Therefore, we refrain from making any claims about ER-phagy in our manuscript and limit our discussion to the more general autophagy.

      1. In the sentence "Using this approach, we identified 7 distinct ribosome states," the authors should clearly specify which strains and treatment conditions were analyzed. Similarly, statements such as "A similar increase in Dec3 was seen for the other conditions" and "Overall, we observed a consistent, stress-independent increase of the Dec3 state at the ER for all Ire1c-GFP conditions" should explicitly define the corresponding conditions in the text.

      We agree that these statements are too vague and we will specify the corresponding conditions in each of these sentences in the revised manuscript.

      1. In the sentence "Finally, like for cytosolic ribosome states, we observed that upon ER stress the abundance of hibernating states at the ER increased over time at the expense of other translating states (Dec2 and Pre)," the authors should explicitly reference the corresponding figures.

      Agreed, we will refer to the Figure 4D for explicit comparison.

      1. In the References section, "Elife" should be corrected to "eLife" for the citation of van Anken et al.

      Agreed, we will correct this citation.

      1. The enrichment of eEF3 on inactive ribosomes leads the authors to propose a possible role for eEF3 in yeast ribosome hibernation improvement or keep. However, this interpretation currently appears speculative because the map resolution for the external density is relatively limited (~9-15 Å). Could the authors strengthen this claim by performing focused refinement/classification of the eEF3 density, testing eEF3 mutants or depletion strains or examining whether eEF3 occupancy changes quantitatively during stress progression?

      Based on the abundance and function of eEF3 we deemed eEF3 the most likely candidate to fit this external density. However, we agree that currently the strength of the claim does not match the strength of the evidence. We will try to improve the local resolution by performing a focused refinement on the eEF3 density. Though, eEF3 is a small density for cryo-ET. In this resolution range we are uncertain whether it will improve the quality of the map in this region. We will quantify the quality of the fit.

      Regarding the mutant/depletion strains, eEF3 is essential in yeast and it is also required for translation elongation. Hence depletion strains or interaction mutants will also perturb the role of eEF3 in translation. This strongly limits the possibilities to specifically investigate the functional importance of eEF3 for ribosome hibernation.

      1. The current study only examines translational states during ongoing stress exposure and does not investigate whether these changes are reversible after stress resolution.

      We thank the reviewer for this interesting point. We hypothesize that the modest translation decrease we observe upon ER stress is most likely reversible. We will check this by including a recovery condition in our polysome profiling experiment.

      2. Description of the revisions that have already been incorporated in the transferred manuscript

      No revisions have been carried out yet.

      3. Description of analyses that authors prefer not to carry out

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      1. The authors mainly focus on 80S particles in their analysis for suggesting the different states of ribosomes. However, there is a possibility of free subunits being stored under specific condition. Can the authors comment on free 40S and 60S subunits?

      The reviewer is correct and several factors binding free ribosomal subunits have been proposed to play a role in translation inhibition and ribosomal subunit hibernation (Saba et al. EMBO J 2024 (PMID: 39533057)). While we appreciate this interesting perspective, we believe that it is beyond the scope of the present work and that incorporating it would distract from the central focus of the manuscript, namely the effect of ER stress on translation elongation dynamics.

      However, if the polysome profiling experiments, now planned based on the suggestions of the reviewers, highlight a significant change in 40S and/or 60s subunit abundance relative to 80S we will try to re-analyze our data, focusing on 40S and 60S subunits.

      1. A previous study has reported the storage of dormant ribosomes on the mitochondrial surfaces. Analysis of mitochondria associated dormant ribosomes in S. cerevisiae would shed more light on this phenomenon.

      We thank the reviewer for raising this interesting point. Because of our focus on ER stress, our data collection was targeted at the ER, hence only a few of our tomograms contain mitochondria. On the few mitochondria that we did image, we do not observe lattice-like tethering of ribosomes, as described upon glucose starvation in S. Pombe (Gemin and Gluc et al. 2024 (PMID: 39379376)). This tethering is a novel observation, and its function still needs to be explored. Indeed, earlier experiments also indicated that glucose deprivation can induce ribosome binding to mitochondria in S. cerevisiae spheroplasts (Kellems et al., 1975 (PMID: 1092698)). However, initial experiments should first confirm whether this phenomenon also without conversion to spheroplasts before moving on to ER stress.

      The structural analysis of mitochondria-associated ribosomes upon ER stress would require new sample preparation of lamellae of control and DTT-treated yeast cells and data collection targeted at mitochondria. It is unlikely to be very different from the modest effect we describe in the cytosol and at the ER membrane. Finally it would distract from the main message of our manuscript centered on the impact of ER stress on translation dynamics. Hence, we consider these experiment beyond the scope of our current work.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Were the cryo-FM lamellae maps shown in Fig. S1F-I used to target the tomogram acquisitions? A correlation between the FM and the EM could provide hints about where the Ire1p clusters are located. The puncta are curious somehow, although established in the literature. I'm wondering if they appear somewhere in the tomograms. I would not insist on new experiments to find them, but it would make sense to show if they are already present in the data. Fig S1D does not show a lamella, and it is hard to conclude that the puncta are really absent there. As a general/historical comment, is it clear that the GFP does not affect the protein condensation?

      We thank the reviewer for this highly relevant and interesting question. Indeed, the cryo-FM data was used to collect tomograms targeted at Ire1p oligomers. However, none of the conditions (the 3 different cell lines, different timing and different type of stressors) showed detectable clusters in the tomograms.

      The absence of clusters can be explained by at least three possible reasons. First, as pointed out by the reviewer, it is possible that the fusion of a fluorescent protein (GFP or NeonGreen) affects the assembly of Ire1p clusters. We think that this is unlikely as these clusters could be visualized by cryoCLEM using a similar fusion constructs in mammalian cells (Tran et al. Science 2021 (PMID: 34591618)). The second possible explanation is a technical limitation. To detect enough fluorescent signal, our cryo-FM data was collected on ~400 nm thick lamellae prior to polishing the lamellae down to Since it is very challenging to convincingly determine which explanation is correct, and it still remains largely speculative to us, we decided to not elaborate on this part of the research effort.*

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      1. For the description of ER volume changes under ER stress, the manuscript currently presents only tomograms from Ire1c-GFP cells treated with DTT. To strengthen this observation, it would be helpful to also include representative tomograms and corresponding segmentations from additional treatments and strains in the supplementary figures.

      Indeed we have only collected these low magnification tomograms on a single strain. Similar to HAC1 splicing, ER expansion in response to ER stress is a widely accepted phenomenon (Bernales et al. 2006 (PMID: 17132049), Schuck et al. 2009 (PMID: 19948500)). There is likely only limited potential for new insights from reproducing these data, and we do not feel the resource investment required is justified.

      1. While cryo-ET enables structural analysis of small cellular volumes at high resolution, volume EM approaches such as FIB-SEM can provide complementary large-scale ultrastructural information. In particular, samples prepared by high-pressure freezing and freeze substitution generally preserve membrane morphology well and closely resemble native membrane architecture. Incorporating such approaches could further support and complement the cryo-ET observations.

      We think that additional volume EM experiments cannot be justified here as the enlargement of ER volume upon ER stress has already been well established through various volume EM approaches (eg; Sriburi et al. 2004 (PMID: 15466483), Bernales et al. 2006 (PMID: 17132049), Schuck et al. 2009 (PMID: 19948500), Heinz et al. 2025 (PMID: 40795978)). Here we only collected additional low magnification tomogram and quantified the ER volume on these to confirm that our experimental conditions lead to a similar ER stress response as previously described. We will add additional references related to this volume EM work to the text to clarify this.

      Minor Comments

      1. Figure 1: the number of biological replicates (N = 3) is relatively small, particularly considering that yeast samples are generally not difficult to prepare.

      The sample size here was not limited by yeast preparation but by cryo-ET data collection time. Because ER expansion upon ER stress is well established in the literature, we only collected a few low magnification tomograms to confirm this effect in our samples, and dedicated most of our microscope time to the collection of high magnification tomograms for the analysis of translation elongation dynamics.

      1. In addition to ER volume expansion, were there any detectable changes in nuclear size or nuclear envelope morphology? Since the nuclear envelope is continuous with the ER network, this could provide additional insight into the cellular response to ER stress.

      Only a few of our low magnification tomograms contained parts of the nucleus. The few nuclei that we observed may show an increased distance between the nuclear membranes, but we collected too few examples to reliably quantify this effect. Hence we refrained from discussing this in our manuscript, focused on translation elongation.

      1. The discussion of alternative pathways remains underdeveloped. Specifically, the authors briefly mention Gcn2p and PKA signaling as potential contributors. Yet no experiments directly test whether the observed ribosome hibernation depends on these pathways. Could the authors clarify: whether eIF2α phosphorylation was induced under their stress conditions, whether Gcn2-deficient strains alter the hibernation phenotype and how much of the observed effect is truly UPR-specific rather than a generic integrated stress response?

      We touched upon alternative pathways in the discussion to explain that the observed hibernation was plausible. Since the PERK pathway does not exist in yeast, we expect that some readers might be surprised by our findings. We will adjust this paragraph to improve its readability.

      The suggested experiments would show which pathways are activated, however the activation of these pathways has already been described in the literature (Pincus et al., 2014 (PMID: 25275008) ; Patil et al., 2004 (PMID: 15314660)). To really explain which factors directly trigger hibernation, various additional biochemical experiments will have to be performed. This is definitely interesting for future research, but beyond the scope of this cryo-ET focused paper.

      We agree that we cannot directly attribute the observed changes to the UPR, that is why we focus on ER stress instead of the UPR. We will double check that this is done consistently throughout the paper.

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      Referee #3

      Evidence, reproducibility and clarity

      This study combines cryo-FIB milling, cryo-electron tomography, and subtomogram averaging to investigate how ER stress affects the translational machinery in S. cerevisiae. The work provides interesting structural insights into ER morphology, autophagy, and ribosome states under stress conditions. The manuscript is generally well written, and the data are of potential interest to the field. However, several aspects of the analysis and presentation would benefit from further clarification and additional supporting data, as outlined below.

      Major Comments

      1. For the description of ER volume changes under ER stress, the manuscript currently presents only tomograms from Ire1c-GFP cells treated with DTT. To strengthen this observation, it would be helpful to also include representative tomograms and corresponding segmentations from additional treatments and strains in the supplementary figures.
      2. While cryo-ET enables structural analysis of small cellular volumes at high resolution, volume EM approaches such as FIB-SEM can provide complementary large-scale ultrastructural information. In particular, samples prepared by high-pressure freezing and freeze substitution generally preserve membrane morphology well and closely resemble native membrane architecture. Incorporating such approaches could further support and complement the cryo-ET observations.
      3. For the analysis of ER-bound ribosomes, the authors applied an ellipsoidal mask during subtomogram averaging. However, this masking strategy may not be sufficient because the relative orientation of ribosomes with respect to the ER membrane can be variable, and membrane density may influence particle alignment. The authors may consider including an additional masking step to exclude membrane density and minimize potential alignment bias.
      4. Supplementary Figures 1B and 1C appear to suggest that the Ire1i-GFP and Ire1i-NG strains exhibit stronger HAC1 splicing upon DTT treatment. Given this apparent increase in UPR activation, it would be interesting to analyze these strains as well to determine whether they display more pronounced changes in translational states.
      5. The study mainly provides structural snapshots and population distributions of ribosomal states, without direct functional measurements of translation activity. Could the authors provide orthogonal biochemical or functional evidence supporting reduced translation under these exact stress conditions?

      Minor Comments

      1. Figure 1: the number of biological replicates (N = 3) is relatively small, particularly considering that yeast samples are generally not difficult to prepare.
      2. "FOV" should be defined as "Field of View" upon first use.
      3. In addition to ER volume expansion, were there any detectable changes in nuclear size or nuclear envelope morphology? Since the nuclear envelope is continuous with the ER network, this could provide additional insight into the cellular response to ER stress.
      4. In Supplementary Figure 7A, the image quality appears insufficient to clearly resolve structures within the autophagic bodies. As a result, it is difficult to determine whether ER-derived membranes are present within these structures. If ER-like membranes are observed, this could suggest induction of ER-phagy under ER stress conditions, consistent with previous reports (e.g., Mizuno et al., PLoS Genetics, 2020).
      5. In the sentence "Using this approach, we identified 7 distinct ribosome states," the authors should clearly specify which strains and treatment conditions were analyzed. Similarly, statements such as "A similar increase in Dec3 was seen for the other conditions" and "Overall, we observed a consistent, stress-independent increase of the Dec3 state at the ER for all Ire1c-GFP conditions" should explicitly define the corresponding conditions in the text.
      6. In the sentence "Finally, like for cytosolic ribosome states, we observed that upon ER stress the abundance of hibernating states at the ER increased over time at the expense of other translating states (Dec2 and Pre)," the authors should explicitly reference the corresponding figures.
      7. In the References section, "Elife" should be corrected to "eLife" for the citation of van Anken et al.
      8. The enrichment of eEF3 on inactive ribosomes leads the authors to propose a possible role for eEF3 in yeast ribosome hibernation improvement or keep. However, this interpretation currently appears speculative because the map resolution for the external density is relatively limited (~9-15 Å). Could the authors strengthen this claim by performing focused refinement/classification of the eEF3 density, testing eEF3 mutants or depletion strains or examining whether eEF3 occupancy changes quantitatively during stress progression?
      9. The discussion of alternative pathways remains underdeveloped. Specifically, the authors briefly mention Gcn2p and PKA signaling as potential contributors. Yet no experiments directly test whether the observed ribosome hibernation depends on these pathways. Could the authors clarify: whether eIF2α phosphorylation was induced under their stress conditions, whether Gcn2-deficient strains alter the hibernation phenotype and how much of the observed effect is truly UPR-specific rather than a generic integrated stress response?
      10. The current study only examines translational states during ongoing stress exposure and does not investigate whether these changes are reversible after stress resolution.

      Significance

      General Assessment

      This study combines cryo-FIB milling, cryo-electron tomography, and subtomogram averaging to investigate how ER stress affects translational regulation in S. cerevisiae. The work provides valuable in situ structural insights into ER remodeling, autophagy, and stress-associated ribosome states. A major strength of the study is the direct visualization of inactive ribosome populations within native cellular environments. The manuscript is technically strong and generally well presented. However, several conclusions would benefit from additional validation across strains and conditions, clearer description of analyzed datasets, and further methodological clarification regarding ER-bound ribosome analysis.

      Advance

      The study extends current understanding of the yeast ER stress response by providing structural evidence that ER stress promotes accumulation of inactive ribosome states both in the cytosol and at the ER. Since translational attenuation in S. cerevisiae remains less well characterized compared with metazoan UPR pathways, these findings provide useful mechanistic insight into how yeast cells may reduce translational load during ER stress. The work also highlights the power of cryo-ET for studying translational states directly in situ.

      Audience

      This work will mainly interest researchers in structural biology, cryo-ET, ribosome biology, ER stress/UPR research, and membrane cell biology. The study is primarily relevant to the basic research community but may also be of broader interest to scientists studying cellular stress responses and proteostasis.

      Field of Expertise

      Cryo-electron tomography, in situ structural biology, membrane biology.

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      Referee #2

      Evidence, reproducibility and clarity

      de Jager et al investigate the unfolded protein response (UPR) in yeast using an approach of in situ structural biology. As explained in the introduction, metazoans react to ER stress by a number of means, and in particular by reducing the protein folding load by mRNA translation inhibition. (To the non-specialist, this would seem to be simply a non-specific reduction in protein expression at the level of translation. Is that the intent?) Yeast lack key components in the identified DIDD/PERK mechanism of translational control, so the question arises how the inhibition occurs in its absence. The underlying hypothesis proposed here is that ribosome structure may provide an explanation. Indeed, the core of the study was a sub-tomogram analysis of a large number of ribosomes in both non-stressed and stressed conditions. Ribosomes were classified into 7 classes corresponding to stages in the elongation cycle, and a significant increase was found in the fraction of hibernating ribosomes. Under longer stress where autophagy was observed, the ribosomes present in vesicles showed a majority in the hibernating state as might be expected. One might have expected that ER-associated ribosomes would be more strongly inhibited than cytoplasmic ones; this was not observed. The overall fraction of translation-inhibited ribosomes was much lower than observed previously by the same group in human cells, however. It was not clear from the manuscript whether this corresponds to a less-complete shutdown of protein expression in yeast UPR, or whether there must be another mechanism yet to be discovered. This would be an important point for structural biologists less familiar with the specific system. Overall, the work is impressive and should definitely be published.

      Major points:

      Were the cryo-FM lamellae maps shown in Fig. S1F-I used to target the tomogram acquisitions? A correlation between the FM and the EM could provide hints about where the Ire1p clusters are located. The puncta are curious somehow, although established in the literature. I'm wondering if they appear somewhere in the tomograms. I would not insist on new experiments to find them, but it would make sense to show if they are already present in the data. Fig S1D does not show a lamella, and it is hard to conclude that the puncta are really absent there. As a general/historical comment, is it clear that the GFP does not affect the protein condensation?

      Is there a difference in the number polysomes in the non-stressed vs stressed yeast cells? A functional assay, such as polysome profiling combined with nascent-chain labeling might help to support the observation that an increased level of hibernating ribosomes exist in DTT or Tm-treated cells. Has this been considered? Perhaps there is evidence available in the literature?

      Minor points:

      The new Dec3 state might be clarified a bit further by zooming in to the corresponding areas in the Dec1 and Dec2 structures. This is a point of novelty in the paper and should be emphasized for future reference. Does an additional classification algorithm, such as cryo-DRGN-ET, verify the various states, especially the new Dec3 state? The structures should of course be uploaded to EMDB or another suitable server.

      There is generally a lack of supporting quantification, which will bother a number of readers. For example, a "high confidence rigid body fit" shows additional density in the hibrenating state, but what is the confidence? Even the resolution measures of 7-8 Angstrom are simply stated. Presumably they come from a WARP report. There should be some specification for the evaluation. How many lamellae were used, and how many tomograms? Were they taken from different biological experiments, or all collected from the same grid, for each condition?

      Significance

      The manuscript extends a previous work of the group on UFP in human cells to yeast, where the most relevant biochemical pathway is missing. It follows a very nice publication by the group on human cells. Here, the result is less striking but no less a discovery. Therefore I think it will make a very nice publication, and it is likely to inspire further work to identify further mechanisms involved in stress-dependent translation inhibition.

      The approach taken is that of structural biology, where the work defines a state of the art. The conclusions have strongest implications for cell biology, to my taste. Since my own expertise is on the side of cryo-ET I would defer to cell biologists regarding the latter.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      The Jager et al., investigated the effect of DTT and Tunicamycin induced ER stress on translation status. They used the cryo-FIB milling and cryo-ET to identify different states of ribosomes and found increased dormant ribosomes occupied with eEF5A, eEF2, and eEF3. The study suggests that ER stress also leads to suppression of translation by increasing the levels of dormant ribosomes in both cytosol and ER membranes.

      Major Comments:

      1. For identification of hibernating ribosomes, the authors rely mainly on the presence of empty ribosomes along with eEF2, eEF5A, and eEF3. Whether these particles indeed possess known dormancy factors or they are different subclass of empty ribosomes is unclear. Similar analysis in the absence of dormancy factors would strengthen the authors claims.
      2. The authors suggest that ER induces modest level of increase in hibernating ribosomes. Adding controls such as glucose deprivation and nitrogen starvation would have provided more strength in relative comparison of these ribosomal sub populations.
      3. The authors mainly focus on 80S particles in their analysis for suggesting the different states of ribosomes. However, there is a possibility of free subunits being stored under specific condition. Can the authors comment on free 40S and 60S subunits?
      4. The modest reduction in the translation upon ER stress induction could be supported by alternative biochemical assays such as polysome profiling and amino acid incorporation.
      5. The authors show the retention of dormant ribosomes on the ER surface. As usual notion of ribosome association with ER membrane to be dependent on nascent translation, retention of dormant ribosomes on ER membrane is interesting and puzzling. Analysis using strains deleted for dormancy factors may provide more insights on this mechanism.
      6. A previous study has reported the storage of dormant ribosomes on the mitochondrial surfaces. Analysis of mitochondria associated dormant ribosomes in S. cerevisiae would shed more light on this phenomenon.

      Significance

      General assessment: The study provides further insights into the regulation of translation under ER stress in yeast in the structural perspective. It provides more insights onto the proportion of different ribosomal populations under normal and ER stress conditions.

      Advance: This study provides very useful technical advancement for understanding the proportion of dormant ribosomes to the 80S monosomes which is difficult to segregate using classical biochemical approaches.

      Audience: This study will be interesting for the broad readership of structural biology and regulation of protein synthesis and ribosomes.

      Field of expertise: Molecular biology, regulation of protein synthesis, mTOR signaling

  3. Jun 2026
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      Reply to the reviewers

      • *

      Review Commons: RC-2026-03417

      We thank all three reviewers for their thoughtful and constructive evaluations of our manuscript. We are encouraged that the reviewers recognize the significance of identifying a role for the TRAPPIII-Rab1 module in Wingless (Wg) trafficking and secretion. We also appreciate the insightful comments that have helped us identify areas where our interpretations, experimental support, and presentation can be strengthened.

      Below, we provide a detailed point-by-point response to all comments and concerns raised by the reviewers.

      Reviewer #1

      __Evidence, reproducibility and clarity __

      Summary

      In this manuscript, the authors investigate the role of Transport Protein Particle (TRAPP) complexes in the secretion of Wingless (Wg) in Drosophila. Two TRAPP complexes are known to exist: TRAPPII and TRAPPIII. Through the systematic analysis of individual subunits, the authors identify the requirement of the TRAPPIII subunit TRAPPC8 for Wg trafficking.

      They demonstrate that the absence of TRAPPC8 disrupts the retrograde trafficking of both Wg and its carrier Evi, resulting in their intracellular accumulation within Wg- producing cells. Further analyses suggest that TRAPPC8 controls the post-apical internalisation and endosomal trafficking of Wg and Evi. Consistent with the established function of TRAPPIII as a Rab1-specific GEF, they demonstrate that inhibiting Rab1 produces similar effects as depleting TRAPPC8, while constitutively active Rab1 reverses the trafficking defects. Furthermore, depletion of either TRAPPC8 or Rab1 increases the levels of Wg-unbound Evi, suggesting that they act downstream of Evi-Wg dissociation. Taken together, these findings suggest that TRAPPIII and its effector Rab1 are essential regulators of retrograde Wg trafficking, which is necessary for efficient secretion.

      Overall, the work is carefully performed and the results are presented clearly. The controls are appropriate and the study expands the functional scope of Rab1-dependent trafficking beyond early secretory pathways. The identification of a previously unrecognised function of TRAPPC8 in Wg trafficking is a valuable contribution.

      Major Points

      1. It is not entirely clear whether the RNAi lines used in the initial screen were validated for knockdown efficiency. Notably, some core TRAPPIII subunits (e.g., TRAPPC3 and TRAPPC5) do not show a phenotype. This could indicate that the complex retains partial function upon their depletion, or alternatively that the RNAi lines are ineffective. While this point may not critically affect the main conclusion regarding TRAPPC8, it is important for drawing conclusions about the specificity of TRAPPIII versus TRAPPII involvement. For instance, TRAPPC10 (a TRAPPII-specific subunit) was analysed using a single RNAi line, yet no evidence of knockdown efficiency was provided. Validation of these RNAi reagents would strengthen the conclusions regarding complex specificity.

      Response: *We thank the reviewer for highlighting this shortcoming in the manuscript. We agree that testing the knockdown efficiency of the TRAPPII complex subunits will strengthen our conclusion on the specificity of TRAPPC8/TRAPPIII towards Wg trafficking. While testing the protein levels would be ideal for checking knockdown efficiency, specific antibodies to these subunits are not commercially available. Therefore, as an alternative approach, we will perform RT-PCR to assess the efficiency of RNAi-mediated depletion of the TRAPPII-specific subunits (TRAPPC9 and TRAPPC10). *

      Furthermore, we would also like to highlight that previous studies have reported variable phenotypic outcomes upon loss of TRAPP complex subunits, ranging from no apparent defects to early lethality (Sun and Sui 2023; Riedel et al. 2018). For example, complete deletion of the C9 gene and a frameshift mutation in the C10 gene were found to be homozygously viable, whereas C8 and C11 homozygous mutants showed early larval lethality (Riedel et al., 2018).

      *To better contextualize our findings, we will include a more detailed discussion comparing our results with the phenotypes reported for these published mutants, in addition to the RT-PCR analysis of RNAi efficiency. *

      Minor Points

      In Figure 2C, the clone appears restricted to the apical region, and I do not clearly observe GFP loss in the basolateral domain. Larger clones or additional sections would help clarify the spatial distribution and strengthen the interpretation.

      Response - *We thank the reviewer for pointing this out. This issue arises from the pseudostratified nature of the wing epithelium. For smaller clones, such as those observed in the TRAPPC8 mutant, cross-sections can occasionally pass through the tissue at an oblique angle, making it difficult to capture the entire clone within a single section. *

      We have repeated the experiment and now provide better images where the apical and basolateral distribution of the mutant clone is visible, and accumulation of exWg can be observed (see updated Figure 2A-C).

      The authors should discuss why TRAPPC8 depletion results primarily in apical Wg enrichment, whereas Rab1 inhibition leads to Wg accumulation at both apical and basolateral membranes. This difference may provide insight into whether Rab1 has additional TRAPPIII-independent functions or whether TRAPPC8 affects a more spatially restricted trafficking step.

      __ ____Response__: We agree that, while inhibition of either TRAPPC8 or Rab1 led to a strong intracellular accumulation of Wg, subtle differences were observed in the localization of the accumulated Wg. In agreement with your comment and as suggested by previous studies, C8 may direct the Rab1-GEF activity of the core TRAPP complex towards a specific location, while Rab1DN will affect all downstream functions, possibly also including TRAPPIII-independent effects (Riedel et al. 2018; Gyurkovska et al. 2026)*. We will modify the text to incorporate these points more clearly. *

      __ ____Significance__

      This study broadens our understanding of Rab1-dependent membrane trafficking by identifying a previously unrecognized role for the TRAPPIII complex in retrograde transport during Wingless secretion. ____While the study convincingly establishes the involvement of the TRAPPIII-Rab1 module in Wg trafficking, it does not define the specific retrograde trafficking step that is regulated by this machinery. In addition, the functional relationship between TRAPPIII-Rab1 and established retrograde regulators, such as the retromer complex, is not addressed.

      ____Response: We thank the reviewer for this comment. This issue was also raised by Reviewer 3. We agree that the precise retrograde trafficking step regulated by the TRAPPC8-Rab1 module remained unclear in the study. To address this, we will perform additional experiments to investigate the functional interactions between TRAPPC8-Rab1 and components of the retrograde trafficking machinery, including the retromer complex, and will incorporate these findings into the revised manuscript. These analyses should help clarify the specific trafficking step controlled by the TRAPPC8-Rab1 module.

      Further molecular and mechanistic analyses will be required to position TRAPPIII within the broader retrograde trafficking network and to fully elucidate how Rab1 activity is coordinated with other pathways involved in Wnt secretion. These unresolved issues represent the main limitation of the current study.

      __ ____Response__: Wg secretion in polarized epithelial cells involves multiple transport routes and regulatory mechanisms, including exosome-mediated transport, cytonemes, and association with carrier molecules. A systematic analysis of the contribution of TRAPPC8-Rab1 to each of these pathways would require substantial additional investigation and falls outside the scope of the present study.

      In this work, we focused on a key, relatively underexplored aspect of Wg transport: the retrograde pathway that mediates the separation and recycling of Wg and Evi/Wls. Our findings identify TRAPPC8-Rab1 as an important component of this process and provide a basis for future studies to define its broader mechanistic integration into intracellular trafficking pathways.

      Reviewer #2

      __Evidence, reproducibility and clarity __

      __Summary Sharma, Sabnis et al. show in this report that TRAPPC8 and Rab1 are important for Wingless (Wg) secretion in developing Drosophila wing discs. - Loss of TRAPPC8 (either knockdown or mutant clones) lead to higher levels of apical Wg in Wg-producing cells (total and extracellular staining). - The levels of the intracellular Wg transporter Evi/Wls are also increased, in particular in its 'unbound' form. - A similar phenotype is observed upon overexpression of Rab1 dominant negative. - Overexpression of constitutively active Rab1 has no effect in otherwise wild type discs but does rescue the effect of TRAPPC8 loss of function.

      Major concerns 1) The author's key message is that TRAPPC8 is essential for retrograde transport of Wg and Evi. However, in apparent contradiction, TRAPPC8 loss does not appear to affect the basolateral distribution of exWg (or total Evi) (Fig2B', FigS3). Therefore, while Wg transport may be less efficient in the absence of TRAPPC8, the conclusion that TRAPPC8 is essential should be toned down. It is warranted to suggest that transport of unbound Evi is disrupted in the absence of TRAPPC8, as unbound Evi increases apically and is lost basally (Fig 4A-B).__

      Response:

      *Thank you for these comments, which prompted us to retest the extracellular Wg levels in these experiments. We repeated the experiments and reanalyzed the basolateral distribution of extracellular Wg in TRAPPC8-depleted cells. While we consistently observed an increase in apical extracellular Wg, the effects on basolateral Wg were more variable. In several samples, basolateral Wg appeared largely unaffected, whereas in others we observed some reduction. We speculate that this variability may arise from differences in RNAi efficiency, with stronger depletion of TRAPPC8 potentially required to reveal basolateral defects. Furthermore, these defects are completely rescued by the expression of Rab1CA, indicating Rab1-dependent effects of TRAPPC8 loss. *

      *We apologize for this oversight in our analysis in the original manuscript and would like to correct our conclusions regarding the basolateral Wg. We have included both results in the partially revised manuscript, indicating the variability observed in the basolateral Wg, albeit with consistent apical accumulation of extracellular Wg. *

      Furthermore, we have modified the statement (line 235, page 8) "These results suggest that TRAPPC8 functions after the dissociation of the Evi-Wg complex, likely promoting proper sorting of Evi and Wg within maturing endosomes" to "These results suggest that TRAPPC8 functions after the dissociation of the Evi-Wg complex, likely affecting proper retrograde trafficking of unbound-Evi."

      Pending revision: *We will further update our discussion section to include these points after completing all additional experiments suggested by the reviewers. *

      2) The relative roles of Rab1 and TRAPPC8 are not equally considered. As the authors show, unlike TRAPPC8 loss of function, Rab1 DN causes a decrease in basal exWg. Doesn't this suggest that Rab1 is more important for Wg trafficking than TRAPPC8?

      Response: This issue is addressed in the previous comment.

      a) Rab1 DN causes also accumulation of total basal Wg. Does this mean that Wg can be trafficked basally but fails to be secreted at the basal surface?

      Response: Yes, we agree with this interpretation. In Rab1DN-expressing cells, total Wg accumulates throughout the cell, including at the basal side, while basolateral extracellular Wg is reduced. This suggests that Wg-containing vesicles can reach the basolateral region but are inefficiently secreted at the basal surface. One possibility is that Rab1 function is required for the apical-to-basolateral transcytosis and/or the final delivery of Wg-containing vesicles to sites of basolateral secretion.

      b) A similar assay (total basal Wg) is lacking in condition of TRAPPC8 loss (clones or RNAi); only exWg is shown.__

      Response: We will also include the basolateral sections of total Wg in TRAPPC8 depletion conditions (mutant clones and RNAi) in the revised manuscript.

      c) Also needed is an assessment of total and exWg at the basal surface in the Rab1 CA experiment. Based on the cross-section image shown in Fig6B, it seems that the distribution of Wg might be more confined to the apical plane of the cells compared to other conditions (Fig6F for example), but there is little difference in this regard between the anterior and posterior compartments.__

      Response: *We thank the reviewer for this important point, and we will reanalyze both total and extracellular Wg levels in Rab1CA samples, specifically the apical and basolateral distributions and provide images in the revised manuscript. *

      3) A significant claim of the paper is "TRAPPC8 regulates retrograde Wg trafficking post-apical internalization". a. The increase in apical extracellular Wg (FigS3), which seems to remain associated with the membrane of Wg-producing cells (i.e. no onward spread) would suggest that apical internalization may be affected, but this is not considered by the authors.

      Response: *We agree that the increased apical extracellular Wg observed in Fig. S3 (now Fig 2D-F and S3) could also suggest alterations in apical uptake dynamics. However, based on our internalization assay, we believe that the major defect is likely in the post-endocytic sorting/trafficking of Wg after apical internalization rather than a complete block in internalization itself. In these internalization assays, following the internalization pulse, the tissue was subjected to a brief acid wash to remove extracellular and surface-bound antibody. At the same time, the internalized antibody-antigen complexes remain protected. Therefore, the Wg signal detected after the acid wash represents internalized apical Wg, demonstrating that apical internalization does occur in the TRAPPC8 loss condition. *

      4) From the antibody chase experiment, it is not clear if the effect of TRAPPC8 loss affects endocytosis and/or trafficking in general or whether it is specific to Wg and Evi. A fluorescent Dextran control should be included as in Witte et al., 2020 (https://doi.org/10.1242/dev.186833 ). Also, can the authors be sure that they are visualising internalised Wg and not just internalised Wg antibody? Can the author show a field of view where Wg is not expressed?

      __ Response: __Thank you for this important suggestion. We would first like to clarify that the Wg internalization assay, using the highly specific monoclonal anti-Wg antibody, is an established approach that has been used in multiple previous studies to monitor Wg internalization and trafficking (Hemalatha et al. 2016; Sharma and Chaudhary 2024)*. Furthermore, as shown in Figure S4C-C′ (now moved to Fig 3D), the internalized Wg signal is detected specifically in cells close to the DV boundary, while more distal receiving cells do not show comparable staining. This spatially restricted pattern strongly supports the specificity of the assay for Wg-producing cells and a limited number of nearby receiving cells that may internalize secreted Wg, rather than nonspecific internalization of the antibody alone. We will revise the text to clarify this point in the revised manuscript. *

      To address whether TRAPPC8 loss affects general endocytosis, we will perform a fluorescent Dextran uptake assay, as suggested by the reviewer and similar to the approach described by (Witte et al. 2020)*. *

      5) The authors suggest that TRAPPC8 loss leads to increased Rab7 levels. This is taken as evidence for a role of acidification in driving Wg dissociation from Evi, with TRAPPC8 acting downstream to sort Wg from mature endosomes. ____Neither of these claims are supported because in Fig.S3G loss of TRAPPC8 results in an increase in Rab7 everywhere except at the DV boundary where the Wg-producing cells are. This should be acknowledged in text, and these data should appear in the main Fig4.

      Response: To address this concern, we have repeated the experiment and reanalyzed the RAb7 and lysotracker levels specifically in cells at the DV boundary. The data is now moved to the updated main Figure 5E-F and 5G-H. A significant increase in both lysotracker and Rab7 can be observed, suggesting that loss of TRAPPC8 affected late endosomal maturation.

      a) The increase in lysotracker also does not support the above claims as it could be due to an increase in unbound Evi that cannot be trafficked back to the ER (and hence targeted for degradation in lysosomes).

      Response: We respectfully disagree with this interpretation. If TRAPPC8 loss primarily caused increased lysosomal degradation of unbound Evi, we would expect a reduction in total Evi levels, as observed upon loss of retromer function, in which Evi is diverted to lysosomes and specifically depleted in Wg-producing cells (Port et al. 2008). In contrast, we observe an accumulation of both total and unbound Evi in TRAPPC8-depleted cells (Figures 4A-D and 5A-D), arguing against enhanced lysosomal degradation as the primary defect.

      b) In fig S3G, the purported Rab7 increase in the posterior compartment is not readily apparent (and not quantified), in contrast to the authors' description of the effect of TRAPPC8 depletion. This suggest that the model proposed by the authors needs to be revised (Fig6G) and the relevant paragraphs from Results and Discussion section must be significantly edited or removed.

      Response: We apologize for the lack of clarity in our previous images. As noted above, we now observe a significant increase in Rab7 and Lysotracker signals in Wg-producing cells, indicating an expansion of Rab7-positive acidic late endosomal compartments upon TRAPPC8 depletion. Furthermore, our interpretation is consistent with our previous findings showing that the Evi-Wg complex dissociates within maturing endosomes.

      Minor concerns 1) The way data in Fig 2, S3 and S4 is presented and referred to in text could be rearranged slightly to make it easier to follow: first talk about the work using clones (Fig2, FigS4 becomes FigS3), then mention similar results with the knockdown (FigS3 becomes FigS4). This arrangement would link naturally to the effect on Evi.

      Response: Thanks for your suggestion, we have revised the supplementary figure order by changing FigS3 (now Fig S4) to FigS4 (now Fig S5) and FigS4 (now Fig S5) to FigS3 (now Fig S4), and the corresponding figure references in the main text have been updated accordingly. We have also moved some of the RNAi data from Fig S3 to main figures (Fig 2D-F and Fig 3D-F) to increase the clarity and make the results easier to follow.

      2) How do the authors explain that the knockdown of some core TRAPP subunits does not have a phenotype? Some sort of rationalisation (or experimental follow up) is desirable.

      *__Response: __The lack of a detectable phenotype following knockdown of some core TRAPP subunits may reflect several possibilities. Previous studies have suggested that certain core subunits, including TRAPPC2, TRAPPC2L, TRAPPC6A and TRAPPC6B, are not universally required for mammalian cell viability, indicating potential functional redundancy or their context-dependent requirements within the TRAPP core complex (Lipatova and Segev, 2019; Sun and Sui, 2023). It is also possible that residual protein levels after RNAi-mediated depletion are sufficient to support partial TRAPP function. Testing the RNAi-mediated protein depletion of these subunits is beyond the scope of the current study. *

      *We would like to highlight that the focus of the study is TRAPPC8, a TRAPPIII-specific subunit, which was validated with a genomic mutation. However, to strengthen our conclusions regarding the TRAPPIII-specific effect, we will validate the known efficiency of the TRAPPII complex subunits with RT-PCR, also addressing the comment from Reviewer 1. *

      3) The authors should give more detail about how they quantified normalised intensity profiles and clarify if the profiles correspond to just the representative image shown or the average of multiple discs (possible for the compartment experiments, but presumably impossible for the clone experiments as they would need to normalise by the size of the clone too).

      Response: *Thank you. We have updated the figure legend to clearly indicate the representative images corresponding to each plot profile. The plot profiles were generated from representative images only and do not represent averages from multiple discs. The intensity values were normalized by dividing each value by the mean intensity across the quantified region. We have also added this information in the Materials and Methods section (line 447, page 16). *

      __ ____Significance__

      This report is a valuable report for the Wg secretion subfield, and useful for the Wnt community. It makes some interesting observations and brings the importance of Rab1 back into the conversation after Ching et al., 2008. However, the insight remain limited and the mechanism/trafficking defects remain unclear. There is convincing evidence that TRAPPC8 and Rab1 affect Wg and Evi, but the claims that TRAPPC8 is essential and acts downstream of acidic endosomes is inadequate.

      __ ____Response:__ * Please refer to the responses for Reviewer 3. We have addressed these concerns in the next section.*

      Reviewer #2 (Significance (Required)):

      __This report is a valuable report for the Wg secretion subfield, and useful for the Wnt community. It makes some interesting observations and brings the importance of Rab1 back into the conversation after Ching et al., 2008. However, the insight remain limited and the mechanism/trafficking defects remain unclear. There is convincing evidence that TRAPPC8 and Rab1 affect Wg and Evi, but the claims that TRAPPC8 is essential and acts downstream of acidic endosomes) is inadequate. ____ __

      __Reviewer #3 __

      This manuscript uncovers a direct or indirect role of RAB1/TRAPPIII in regulating the intracellular fate of Wng in the columnar epithelial cells of the wing imaginal disc of the fruit fly. This observation is interesting, although it should come as no surprise that, given the fact that Wnts are secreted morphogens and considering the involvement of TRAPPIII in the early stages of the secretory pathway, the key TRAPPIII subunit, TRS85/TRAPPC8, is crucial for their normal trafficking. The main finding of this work is that cells deficient in TRAPPIII/RAB1 accumulate the morphogen and its receptor in the apical region of morphogen-producing cells, which is interpreted as a block in the retrograde trafficking of the morphogen.


      1) While it is unclear to me what the authors consider as retrograde trafficking of Wng (see below), the arguments fall short of being convincing, in part because the intracellular trafficking of Wng is rather intricate, but also because the physiological role of TRAPPIII is insufficiently understood. It is well established that Wng transits through endosomes to reach multivesicular bodies, where it is incorporated into the inwardly budding vesicles that are secreted as exosomes (Gross et al, cited). Do the authors consider this a retrograde pathway? The authors do not delineate further the location at which Wng accumulates, for example using co-localization studies.

      Response: *We would like to clarify that, in our manuscript, we use the term "retrograde trafficking" specifically to describe the trafficking route followed by apically internalized Wg/Evi complexes through the endosomal system before their re-secretion from Wg-producing cells. *

      *Wg trafficking after internalization is highly complex and can involve multiple intracellular routes. Importantly, besides trafficking of internalized Wg to multivesicular bodies (MVBs) for exosomal secretion, other pathways downstream of apical internalization have also been reported, including Rab4-dependent apical recycling, apical-to-basolateral transcytosis involving HSPGs, and secretion of Wg on lipoprotein particles. Testing the effect of TRAPPC8 in multiple trafficking routes is currently beyond the scope of this study. *

      *Our current study does not attempt to distinguish between these individual downstream secretory routes. Rather, our data support a requirement for TRAPPC8/Rab1 in trafficking steps occurring after apical internalization of Wg/Evi and before their redistribution and/or re-secretion. The detailed characterization of the precise endosomal compartments and carrier-specific secretion mechanisms affected by TRAPPC8/Rab1 will require significant additional lines of experiments, which are beyond the scope of the current work. *

      __2) They have also not provided a rationalization of their observations with current knowledge of retrograde trafficking between the endosomes and the Golgi. It would have been interesting to address the effects of Trs85 depletion in mutant backgrounds deficient in the master regulator of retrograde pathways, RAB6, its effector, the GARP complex, or RAB7 and the retromer; it would have been important to study TRAPPIII depletion under conditions in which endocytic internalization is blocked, or the biogenesis of multivesicular bodies is prevented. __

      __ ____Response: __We agree that understanding the functional relationship between TRAPPIII and other retrograde trafficking regulators would provide important mechanistic insight into Wg/Evi trafficking.

      *Among the known regulators of retrograde trafficking, we are particularly interested in testing the functional interaction between TRAPPC8 and the retromer complex, as retromer is one of the best-characterized regulators of Evi recycling in the Drosophila Wg pathway (Port et al., 2008; Franch-Marro et al., 2008; Belenkaya et al., 2008). Therefore, we will analyze the functional interactions between TRAPPC8 and retromer components and provide results in the revised manuscript. *

      However, the roles of other retrograde trafficking regulators, such as GARP and Rab6, in retrograde Wg trafficking in Drosophila are not yet well established and would first require independent characterization before meaningful epistasis analyses with TRAPPIII can be performed.

      *Regarding the suggestion to block endocytic internalization, our antibody internalization experiments indicate that early Wg internalization, including uptake of Wg in neighboring receiving (non-secreting) cells, is not detectably affected upon TRAPPC8 or Rab1 depletion. These observations suggest that TRAPPC8 and Rab1 are unlikely to play a general role in endocytic uptake. *

      We therefore focused our analyses on post-internalization trafficking events affecting Wg and Evi. Furthermore, blocking endocytosis globally would likely introduce strong secondary effects on both Evi-Wg complex internalization in secreting cells and uptake of extracellular Wg in receiving cells, making it difficult to distinguish direct effects on retrograde trafficking from broader defects in Wg trafficking dynamics.

      __Specific comments __

      3) There are no page or line numbers, which makes very cumbersome to comment on specific sections of the manuscript.

      *__Response: __We apologize for this inconvenience and have now added page and line numbers. *

      __4) The introduction contains a factual mistake. TRAPPC11, 12, and 13 are not metazoan specific. They are present in fungi but have been lost in Saccharomyces cerevisiae. Pinar M, Arias-Palomo E, de Los Ríos V, Arst HN Jr, Peñalva MA. Characterization of Aspergillus nidulans TRAPPs uncovers unprecedented similarities between fungi and metazoans and reveals the modular assembly of TRAPPII. PLoS Genet. 2019 Dec 23;15(12):e1008557. doi: 10.1371/journal.pgen.1008557. This reference should have been cited. __

      Response: *We thank the reviewer for pointing this out and apologize for missing this reference. We have now updated the text and added the reference (see line 83 on page 3). *

      __5) Materials and methods are very incomplete, particularly in the section that deals with the antibodies, which are essential tools for understanding the experiments. __

      __Is the Wnt antibody a monoclonal antibody? __

      __Are there different antibodies specific for extracellular and intracellular Wnt? __

      __What is the molecular basis for this differential detection? __

      __The transgene expressing GFP under the engrailed driver is not described anywhere. __

      __ ____Response:__ We apologize for the lack of sufficient detail in the Materials and Methods section. We have now revised this section to include the missing methodological details and clarifications requested by the reviewer.* *

      For all Wg-related stainings, including total, extracellular, and internalization assays, we used the mouse monoclonal anti-Wg antibody obtained from DSHB. Antibody details and working dilutions are provided in the revised Materials and Methods section.

      The differential detection of extracellular versus total Wg does not arise from the use of different antibodies, but rather from differences in the staining protocol. Total Wg staining was performed after permeabilization of wing imaginal discs using 0.2% Triton X-100 in 1X PBS, allowing detection of both intracellular and extracellular Wg pools. In contrast, extracellular Wg staining was performed without tissue permeabilization, thereby restricting antibody access to extracellular or cell surface-associated Wg. Similarly, the Wg internalization assay was performed using established protocols already described in the manuscript. We have now updated the Materials and Methods section to include additional details for the extracellular Wg staining procedure (line 409, page 14).

      • *The GFP expression used in our study is driven by the Gal4-UAS system, where engrailed-Gal4 (en-Gal) drives UAS-GFP expression. We have provided the details for these two fly lines in the Drosophila stocks section in Materials and Methods. For our experiments, we generated a recombinant fly stock having both en-Gal and UAS-GFP on the second chromosome using Drosophila genetics, and this genotype, along with different combinations of genes, is listed in our Supplementary Information.
      • *__6) The labeling of the figures and the figure legends themselves are excessively simple and appear to be accessible for fly experts only. __

      Response: We thank the reviewer for this suggestion. We have revised the details for labeling the figure in the legends and expanded the figure legends to improve clarity and accessibility for a broader audience. In particular, we added more detailed descriptions of the specific images with reference to their corresponding quantified graphs (as also suggested by Reviewer 2). We also incorporated additional minor explanatory details (for example, GFP-negative clones mean the homozygous mutant) wherever necessary to help non-fly experts to better understand the figures.

      __7) The authors have not considered the possibility that ablating TRAPPC8 of TRAPPIII can have off-target effects in TRAPPII. It would have been very interesting to address the phenotype of down-regulating TRAPPII and of down-regulating one of the core subunits of TRAPPs. __

      __ ____ Response: __*If the reviewer is suggesting the off-target effects of TRAPPC8 RNAi on TRAPPII complex member, we would like point out that the observations from the RNAi were validated by the TRAPPC8 mutant. However, if the concern is whether TRAPPC8 loss functionally affected TRAPPII complex besides TRAPPIII, then it we have not directly tested this. However, several past studies have shown that TRAPPC8 is a TRAPPIII-specific subunit and not part of TRAPPII complex. Furthermore, and more importantly, we have rescued the RNAi phenotype with the expression of Rab1CA, indicating the effects TRAPPIII-specific are unlikely to be via the TRAPPII-Rab11 pathway. *

      __8) Figure 1, Panel 1i: What is the basis at this point that justifies "likely by altering intra-cellular trafficking"? __

      Response: Since loss of TRAPPC8 resulted in increased levels of total Wg, we wanted to determine whether this increase could be due to transcriptional upregulation of wg. To address this, we examined the established wg-LacZ reporter and found that its expression was not altered upon loss of TRAPPC8 (Fig 1i).

      Therefore, the increased Wg levels are unlikely to arise from increased wg transcription. In addition, previous studies have shown that loss of Evi/Wls leads to intracellular accumulation of Wg as a consequence of trafficking defects rather than transcriptional regulation. Based on these observations, we concluded that the accumulation of Wg upon TRAPPC8 depletion is more likely due to altered intracellular trafficking.

      __9) Several figures: where are the boundaries of the cells in orthogonal views? If GFP labels whole cells, why is there an area at the top of the cross-sections that hasn't got GFP staining? __

      __ ____Response:__ In all orthogonal views of the GFP-negative mutant clones, we have used dotted lines to indicate the clone boundaries. The wing disc epithelium consists of two distinct epithelial layers: a squamous epithelium (the peripodial membrane) and a pseudostratified columnar epithelium. Although GFP-negative clones are generated in both layers, our analysis focuses specifically on the columnar epithelium, where Wg is expressed. Therefore, the signal observed from the peripodial membrane can vary in the orthogonal views and does not affect our interpretation of Wg localization in the columnar cells.

      __10) I can follow the point that accumulation in the apical side means that retrograde trafficking is impaired. I miss the connection between the observation and the conclusion. __

      Response: We apologize for the lack of clarity in explaining the retrograde trafficking defects and would like to clarify this point for Wg.

      In our experiments, we performed both total Wg staining (predominantly intracellular) and extracellular Wg staining. The apical accumulation observed in total Wg staining upon TRAPPC8/Rab1 depletion, by itself, does not directly demonstrate impaired retrograde trafficking. However, the increase in extracellular Wg indicates that Wg can still reach the plasma membrane, suggesting that the anterograde delivery pathway remains functional.

      Our conclusion regarding defective retrograde trafficking is primarily based on the antibody internalization assays. In these experiments, internalized Wg and Evi accumulate intracellularly upon loss of TRAPPC8/Rab1, consistent with a defect in post-endocytic trafficking and recycling. Since both Wg and Evi normally undergo endocytic recycling through retrograde pathways, the accumulation of internalized Evi and Wg supports the interpretation that retrograde trafficking is impaired in TRAPPC8/Rab1-depleted cells.

      __11) VPS34 is an effector of RAB5 and therefore its down-regulation impairs the maturation of early endosomes because their membranes cannot acquire the key component phosphatidylinositol-3-phosphate, which is recognized by the ESCRT machinery to proceed with multivesicular body biogenesis. __

      __ ____Response: __We agree with the reviewer that VPS34 acts as an effector of Rab5 and plays an important role in early endosome maturation. However, more recent studies have shown that VPS34 functions within two related but functionally distinct complexes, VPS34 complex I and VPS34 complex II. VPS34 complex II, which contains UVRAG, functions predominantly in the endolysosomal system and is associated with Rab5. In contrast, VPS34 complex I, which contains Atg14, functions in autophagy and has been shown to interact with Rab1. Importantly, Rab1 and Rab5 bind VPS34 in a mutually exclusive manner at overlapping interaction sites (Scott and Burke 2026; Cook et al. 2025; Špokaitė et al. 2026; Tremel et al. 2021)*. *

      • *Therefore, while the reviewer's interpretation regarding Rab5-dependent VPS34 function in endosomal maturation is fully valid, these studies also support the possibility that Rab1 can regulate VPS34-dependent trafficking pathways through a distinct VPS34 complex.

      __12) The Q70L mutation, widely used as a constitutive activator of RABs, is borrowed from studies in RAS and it might not lead to constitutive activation of RAB1 (Langemeyer, L., Nunes Bastos, R., Cai, Y., Itzen, A., Reinisch, K.M., and Barr, F.A. (2014). Diversity and plasticity in Rab GTPase nucleotide release mechanism has consequences for Rab activation and inactivation. eLife 3, e01623). __

      Response: We thank the reviewer for raising this important point. We admit that we have not performed an independent analysis of the GTP-locked status of the Rab1Q70L mutant in flies. Our rationale for using Rab1Q70L as a GTP-locked or functionally hyperactive Rab1 variant is based on its extensive prior use in the field (Tisdale et al. 1992; Levin et al. 2016; Russo et al. 2016; van Vliet et al. 2026). Importantly, a past study in Drosophila has shown functional hyperactivity of the Rab1Q70L compared with WT Rab1 (Sechi et al. 2017)*. ** *

      References (response to reviewers):

      Cook, Annan S. I., Minghao Chen, Thanh N. Nguyen, et al. 2025. "Structural Pathway for PI3-Kinase Regulation by VPS15 in Autophagy." Science (New York, N.Y.) 388 (6743): eadl3787.

      Gyurkovska, Valeriya, Rakhilya Murtazina, Sarah F. Zhao, Christopher B. Huppenbauer, Vadim Gaponenko, and Nava Segev. 2026. "Distinct TRAPP Complexes Activate Ypt/Rab GTPases in Secretion and Autophagy." The Journal of Cell Biology 225 (5). https://doi.org/10.1083/jcb.202507166.

      Hemalatha, Anupama, Chaitra Prabhakara, and Satyajit Mayor. 2016. "Endocytosis of Wingless via a Dynamin-Independent Pathway Is Necessary for Signaling in Drosophila Wing Discs." Proceedings of the National Academy of Sciences of the United States of America 113 (45): E6993-E7002.

      Levin, Rebecca S., Nicholas T. Hertz, Alma L. Burlingame, Kevan M. Shokat, and Shaeri Mukherjee. 2016. "Innate Immunity Kinase TAK1 Phosphorylates Rab1 on a Hotspot for Posttranslational Modifications by Host and Pathogen." Proceedings of the National Academy of Sciences of the United States of America 113 (33): E4776-83.

      Nakajima, Yu-Ichiro. 2021. "Analysis of Epithelial Architecture and Planar Spindle Orientation in the Drosophila Wing Disc." Methods in Molecular Biology (Clifton, N.J.) (New York, NY), Methods in molecular biology (Clifton, N.J.), vol. 2346: 51-62.

      Port, Fillip, Marco Kuster, Patrick Herr, et al. 2008. "Wingless Secretion Promotes and Requires Retromer-Dependent Cycling of Wntless." Nature Cell Biology 10 (2): 178-185.

      Riedel, Falko, Antonio Galindo, Nadine Muschalik, and Sean Munro. 2018. "The Two TRAPP Complexes of Metazoans Have Distinct Roles and Act on Different Rab GTPases." The Journal of Cell Biology 217 (2): 601-617.

      Russo, Ashley J., Alyssa J. Mathiowetz, Steven Hong, Matthew D. Welch, and Kenneth G. Campellone. 2016. "Rab1 Recruits WHAMM during Membrane Remodeling but Limits Actin Nucleation." Molecular Biology of the Cell 27 (6): 967-978.

      Scott, Mackenzie K., and John E. Burke. 2026. "Two Binding Sites Are Better than One." eLife 15 (e110917). https://doi.org/10.7554/eLife.110917.

      Sechi, Stefano, Anna Frappaolo, Roberta Fraschini, et al. 2017. "Rab1 Interacts with GOLPH3 and Controls Golgi Structure and Contractile Ring Constriction during Cytokinesis in Drosophila Melanogaster." Open Biology 7 (1): 160257.

      Sharma, Satyam, and Varun Chaudhary. 2024. "Dissociation of Drosophila Evi-Wg Complex Occurs Post Apical Internalization in the Maturing Acidic Endosomes." Traffic (Copenhagen, Denmark) 25 (9): e12955.

      Špokaitė, Saulė, Yohei Ohashi, Maxime Bourguet, Antoine N. Dessus, and Roger L. Williams. 2026. "A Novel RAB5 Binding Site in Human VPS34-CII That Is Likely the Primordial Site in Eukaryotic Evolution." In eLife. ELife, March 31. https://doi.org/10.7554/elife.110040.

      Sun, Shan, and Sen-Fang Sui. 2023. "Structural Insights into Assembly of TRAPPII and Its Activation of Rab11/Ypt32." Current Opinion in Structural Biology 80 (102596): 102596.

      Tisdale, E. J., J. R. Bourne, R. Khosravi-Far, C. J. Der, and W. E. Balch. 1992. "GTP-Binding Mutants of rab1 and rab2 Are Potent Inhibitors of Vesicular Transport from the Endoplasmic Reticulum to the Golgi Complex." The Journal of Cell Biology 119 (4): 749-761.

      Tremel, Shirley, Yohei Ohashi, Dustin R. Morado, et al. 2021. "Structural Basis for VPS34 Kinase Activation by Rab1 and Rab5 on Membranes." Nature Communications 12 (1): 1564.

      Vliet, Alexander R. van, Alison K. Gillingham, Tomos E. Morgan, et al. 2026. "A Rab1 Interactome Illuminates a Dual Role in Autophagy and Membrane Trafficking." The Journal of Cell Biology 225 (3): e202507084.

      Witte, Leonie, Karen Linnemannstöns, Kevin Schmidt, et al. 2020. "The Kinesin Motor Klp98A Mediates Apical to Basal Wg Transport." Development 147 (15). https://doi.org/10.1242/dev.186833.

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      Referee #3

      Evidence, reproducibility and clarity

      This manuscript uncovers a direct or indirect role of RAB1/TRAPPIII in regulating the intracellular fate of Wng in the columnar epithelial cells of the wing imaginal disc of the fruit fly. This observation is interesting, although it should come as no surprise that, given the fact that Wnts are secreted morphogens and considering the involvement of TRAPPIII in the early stages of the secretory pathway, the key TRAPPIII subunit, TRS85/TRAPPC8, is crucial for their normal trafficking. The main finding of this work is that cells deficient in TRAPPIII/RAB1 accumulate the morphogen and its receptor in the apical region of morphogen-producing cells, which is interpreted as a block in the retrograde trafficking of the morphogen. While it is unclear to me what the authors consider as retrograde trafficking of Wng (see below), the arguments fall short of being convincing, in part because the intracellular trafficking of Wng is rather intricate, but also because the physiological role of TRAPPIII is insufficiently understood. It is well established that Wng transits through endosomes to reach multivesicular bodies, where it is incorporated into the inwardly budding vesicles that are secreted as exosomes (Gross et al, cited). Do the authors consider this a retrograde pathway? The authors do not delineate further the location at which Wng accumulates, for example using co-localization studies. They have also not provided a rationalization of their observations with current knowledge of retrograde trafficking between the endosomes and the Golgi. It would have been interesting to address the effects of Trs85 depletion in mutant backgrounds deficient in the master regulator of retrograde pathways, RAB6, its effector, the GARP complex, or RAB7 and the retromer; it would have been important to study TRAPPIII depletion under conditions in which endocytic internalization is blocked, or the biogenesis of multivesicular bodies is prevented.

      Specific comments

      There are no page or line numbers, which makes very cumbersome to comment on specific sections of the manuscript.

      The introduction contains a factual mistake. TRAPPC11, 12, and 13 are not metazoan specific. They are present in fungi but have been lost in Saccharomyces cerevisiae. Pinar M, Arias-Palomo E, de Los Ríos V, Arst HN Jr, Peñalva MA. Characterization of Aspergillus nidulans TRAPPs uncovers unprecedented similarities between fungi and metazoans and reveals the modular assembly of TRAPPII. PLoS Genet. 2019 Dec 23;15(12):e1008557. doi: 10.1371/journal.pgen.1008557. This reference should have been cited.

      Materials and methods are very incomplete, particularly in the section that deals with the antibodies, which are essential tools for understanding the experiments. Is the Wnt antibody a monoclonal antibody? Are there different antibodies specific for extracellular and intracellular Wnt? What is the molecular basis for this differential detection? The transgene expressing GFP under the engrailed driver is not described anywhere.

      The labeling of the figures and the figure legends themselves are excessively simple and appear to be accessible for fly experts only.

      The authors have not considered the possibility that ablating TRAPPC8 of TRAPPIII can have off-target effects in TRAPPII. It would have been very interesting to address the phenotype of down-regulating TRAPPII and of down-regulating one of the core subunits of TRAPPs.

      Figure 1, Panel 1i: What is the basis at this point that justifies "likely by altering intra-cellular trafficking"?

      Several figures: where are the boundaries of the cells in orthogonal views? If GFP labels whole cells, why is there an area at the top of the cross-sections that hasn't got GFP staining?

      I can follow the point that accumulation in the apical side means that retrograde trafficking is impaired. I miss the connection between the observation and the conclusion.

      VPS34 is an effector of RAB5 and therefore its down-regulation impairs the maturation of early endosomes because their membranes cannot acquire the key component phosphatidylinositol-3-phosphate, which is recognized by the ESCRT machinery to proceed with multivesicular body biogenesis.

      The Q70L mutation, widely used as a constitutive activator of RABs, is borrowed from studies in RAS and it might not lead to constitutive activation of RAB1 (Langemeyer, L., Nunes Bastos, R., Cai, Y., Itzen, A., Reinisch, K.M., and Barr, F.A. (2014). Diversity and plasticity in Rab GTPase nucleotide release mechanism has consequences for Rab activation and inactivation. eLife 3, e01623).

      Referee cross-commenting

      I also feel that six months is a more realistic estimation

      Significance

      In summary an interesting observation that deserves a more detailed follow-up to unveil the actual role of TRAPPIII in the Wng pathway.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      Sharma, Sabnis et al. show in this report that TRAPPC8 and Rab1 are important for Wingless (Wg) secretion in developing Drosophila wing discs.

      • Loss of TRAPPC8 (either knockdown or mutant clones) lead to higher levels of apical Wg in Wg-producing cells (total and extracellular staining).
      • The levels of the intracellular Wg transporter Evi/Wls are also increased, in particular in its 'unbound' form.
      • A similar phenotype is observed upon overexpression of Rab1 dominant negative.
      • Overexpression of constitutively active Rab1 has no effect in otherwise wild type discs but does rescue the effect of TRAPPC8 loss of function.

      Major concerns

      1) The authors key message is that TRAPPC8 is essential for retrograde transport of Wg and Evi. However, in apparent contradiction, TRAPPC8 loss does not appear to affect the basolateral distribution of exWg (or total Evi) (Fig2B', FigS3). Therefore, while Wg transport may be less efficient in the absence of TRAPPC8, the conclusion that TRAPPC8 is essential should be toned down. It is warranted to suggest that transport of unbound Evi is disrupted in the absence of TRAPPC8, as unbound Evi increases apically and is lost basally (Fig4A-B).

      2) The relative roles of Rab1 and TRAPPC8 are not equally considered. As the authors show, unlike TRAPPC8 loss of function, Rab1 DN causes a decrease in basal exWg. Doesn't this suggest that Rab1 is more important for Wg trafficking than TRAPPC8? a. Rab1 DN causes also accumulation of total basal Wg. Does this mean that Wg can be trafficked basally but fails to be secreted at the basal surface? b. A similar assay (total basal Wg) is lacking in condition of TRAPPC8 loss (clones or RNAi); only exWg is shown. c. Also needed is an assessment of total and exWg at the basal surface in the Rab1 CA experiment. Based on the cross-section image shown in Fig6B, it seems that the distribution of Wg might be more confined to the apical plane of the cells compared to other conditions (Fig6F for example), but there is little difference in this regard between the anterior and posterior compartments.

      3) A significant claim of the paper is "TRAPPC8 regulates retrograde Wg trafficking post-apical internalization". a. The increase in apical extracellular Wg (FigS3), which seems to remain associated with the membrane of Wg-producing cells (i.e. no onward spread) would suggest that apical internalization may be affected, but this is not considered by the authors. b. From the antibody chase experiment, it is not clear if the effect of TRAPPC8 loss affects endocytosis and/or trafficking in general or whether it is specific to Wg and Evi. A fluorescent Dextran control should be included as in Witte et al., 2020 (https://doi.org/10.1242/dev.186833 ). Also, can the authors be sure that they are visualising internalised Wg and not just internalised Wg antibody? Can the author show a field of view where Wg is not expressed?

      4) The authors suggest that TRAPPC8 loss leads to increased Rab7 levels. This is taken as evidence for a role of acidification in driving Wg dissociation from Evi, with TRAPPC8 acting downstream to sort Wg from mature endosomes. a. Neither of these claims are supported because in Fig.S3G loss of TRAPPC8 results in an increase in Rab7 everywhere except at the DV boundary where the Wg-producing cells are. This should be acknowledged in text, and these data should appear in the main Fig4. b. The increase in lysotracker also does not support the above claims as it could be due to an increase in unbound Evi that cannot be trafficked back to the ER (and hence targeted for degradation in lysosomes). c. In fig S3G, the purported Rab7 increase in the posterior compartment is not readily apparent (and not quantified), in contrast to the authors' description of the effect of TRAPPC8 depletion. This suggest that the model proposed by the authors needs to be revised (Fig6G) and the relevant paragraphs from Results and Discussion section must be significantly edited or removed.

      Minor concerns

      1) The way data in Fig 2, S3 and S4 is presented and referred to in text could be rearranged slightly to make it easier to follow: first talk about the work using clones (Fig2, FigS4 becomes FigS3), then mention similar results with the knockdown (FigS3 becomes FigS4). This arrangement would link naturally to the effect on Evi.

      2) How do the authors explain that the knockdown of some core TRAPP subunits does not have a phenotype? Some sort of rationalisation (or experimental follow up) is desirable.

      3) The authors should give more detail about how they quantified normalised intensity profiles and clarify if the profiles correspond to just the representative image shown or the average of multiple discs (possible for the compartment experiments, but presumably impossible for the clone experiments as they would need to normalise by the size of the clone too).

      Referee cross-commenting

      Reviewer 3 was thorough and makes some good points that I had not considered because of coming from a different research field (e.g. the fact that losing TRAPPC8 can have off-target effects in TRAPPII, or that the figures may not be clear to non-fly people). In my review I identified the lack of testing of other TRAPP subunits as a minor point, but having read R3's comments I would probably increase this to a major issue. Reviewer 1 and I agree on multiple points as well (e.g. the lack of testing of other TRAPP subunits, the difference between the TRAPPC8 and Rab1 phenotypes). I believe that 1 - 3 months to complete revisions is optimistic. 6 months is a more realistic, with the caveat that the results from some of the requested experiments could upend the conclusions of this study.

      Significance

      This report is a valuable report for the Wg secretion subfield, and useful for the Wnt community. It makes some interesting observations and brings the importance of Rab1 back into the conversation after Ching et al., 2008. However, the insight remain limited and the mechanism/trafficking defects remain unclear. There is convincing evidence that TRAPPC8 and Rab1 affect Wg and Evi, but the claims that TRAPPC8 is essential and acts downstream of acidic endosomes) is inadequate.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      In this manuscript, the authors investigate the role of Transport Protein Particle (TRAPP) complexes in the secretion of Wingless (Wg) in Drosophila. Two TRAPP complexes are known to exist: TRAPPII and TRAPPIII. Through the systematic analysis of individual subunits, the authors identify the requirement of the TRAPPIII subunit TRAPPC8 for Wg trafficking. They demonstrate that the absence of TRAPPC8 disrupts the retrograde trafficking of both Wg and its carrier Evi, resulting in their intracellular accumulation within Wg-producing cells. Further analyses suggest that TRAPPC8 controls the post-apical internalisation and endosomal trafficking of Wg and Evi. Consistent with the established function of TRAPPIII as a Rab1-specific GEF, they demonstrate that inhibiting Rab1 produces similar effects as depleting TRAPPC8, while constitutively active Rab1 reverses the trafficking defects. Furthermore, depletion of either TRAPPC8 or Rab1 increases the levels of Wg-unbound Evi, suggesting that they act downstream of Evi-Wg dissociation. Taken together, these findings suggest that TRAPPIII and its effector Rab1 are essential regulators of retrograde Wg trafficking, which is necessary for efficient secretion. Overall, the work is carefully performed and the results are presented clearly. The controls are appropriate and the study expands the functional scope of Rab1-dependent trafficking beyond early secretory pathways. The identification of a previously unrecognised function of TRAPPC8 in Wg trafficking is a valuable contribution.

      Major Points

      It is not entirely clear whether the RNAi lines used in the initial screen were validated for knockdown efficiency. Notably, some core TRAPPIII subunits (e.g., TRAPPC3 and TRAPPC5) do not show a phenotype. This could indicate that the complex retains partial function upon their depletion, or alternatively that the RNAi lines are ineffective. While this point may not critically affect the main conclusion regarding TRAPPC8, it is important for drawing conclusions about the specificity of TRAPPIII versus TRAPPII involvement. For instance, TRAPPC10 (a TRAPPII-specific subunit) was analysed using a single RNAi line, yet no evidence of knockdown efficiency was provided. Validation of these RNAi reagents would strengthen the conclusions regarding complex specificity.

      Minor Points

      • In Figure 2C, the clone appears restricted to the apical region, and I do not clearly observe GFP loss in the basolateral domain. Larger clones or additional sections would help clarify the spatial distribution and strengthen the interpretation.
      • The authors should discuss why TRAPPC8 depletion results primarily in apical Wg enrichment, whereas Rab1 inhibition leads to Wg accumulation at both apical and basolateral membranes. This difference may provide insight into whether Rab1 has additional TRAPPIII-independent functions or whether TRAPPC8 affects a more spatially restricted trafficking step.

      Significance

      This study broadens our understanding of Rab1-dependent membrane trafficking by identifying a previously unrecognized role for the TRAPPIII complex in retrograde transport during Wingless secretion. While the study convincingly establishes the involvement of the TRAPPIII-Rab1 module in Wg trafficking, it does not define the specific retrograde trafficking step that is regulated by this machinery. In addition, the functional relationship between TRAPPIII-Rab1 and established retrograde regulators, such as the retromer complex, is not addressed. Further molecular and mechanistic analyses will be required to position TRAPPIII within the broader retrograde trafficking network and to fully elucidate how Rab1 activity is coordinated with other pathways involved in Wnt secretion. These unresolved issues represent the main limitation of the current study. This work will be of particular interest to researchers in the fields of cell signaling, membrane trafficking, and intercellular communication.

      My expertise lies in cell communication and the regulation of cellular proliferation.

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      Reply to the reviewers

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This work focuses on zebrafish notochord morphogenesis during axial elongation. In particular it dissects the role of YAP signalling on regulating the balance between caudal cell addition with the cell enlargement occurring rostrally through vacuolation.

      The article is timely to the field and includes several important experiments. The overall presentation and written style are good, citations are adequate and there is a clear effort to integrate experiments and mathematical modelling from the outset. The logic behind experiments is sound and the conclusion coherent (even if not totally unexpected given the literature): YAP affects progenitor addition which in turn changes packing, vacuolation and axis length. I just have a few points that could make the article clearer and more persuasive.

      We thank the reviewer for these positive comments about our manuscript. We would like to reiterate the two main unexpected findings based on our results:

      • While YAP mutants display a defective notochord (Kimelman et al., 2017; eLife) it has not been clear what specific role that YAP signalling is playing during notochord development. Therefore, the finding that Yap signalling plays a role in controlling the rate to notochord progenitor addition and represents a novel discovery.
      • The observation that the notochord can buffer its elongation rate against an increased influx of progenitors is novel and counter intuitive. Our current understanding of tissue elongation depends on the central idea that the addition of progenitors directly impacts elongation rate. Here we show for the first time that this has minimal impact at the tissue level using the notochord as an example. Major points

      - Last section of results is difficult and confusing. After analysing vgll4b loss-of-function line, effectively over-activating YAP, the focus is on YAP inhibition using Verteporfin.

      o Concerns on Verteporfin: the molecule has been widely used to module YAP, but there are also plenty of studies suggesting it is non-specific (also degrades YAP, has 14-4-3σ dependency and induces stress). I would consider an alternative: truncated TEAD, LATS over-expression or gain-of-function phosphomimetic versions of YAP.

      o Presentation: regardless of point above, Verteporfin's role on YAP should be verified in the system. As such it is crucial to include: images of 4xGTIIC, noto and YAP stains after treatment. Only then inspect the effects on vacuolation and different treatments.

      As suggested by the reviewer, we have added a supplementary figure validating the verteporfin treatment, including quantification of GFP reduction across the three tissues and quantification of notochord staining. We did not include Yap1 immunostaining data because the signal quality was insufficient for reliable analysis.

      A simple over-expression experiment will not allow the spatial and temporal control required to test our hypothesis. Yap has a known function in gastrulation, so we need experiments that allow us to perturb Yap activity only at posterior body elongation stages. This has been achieved with the vgl4b experiments shown in the manuscript, as this gene is specifically expressed in the tailbud at these stages. In addition to the full verification of verteporfin's impact on YAP activity, we feel this is sufficient evidence to support our conclusions.

      - In Fig 3F, noto HCR staining is taken as evidence for progenitor exhaustion/ faster depletion. Other scenarios would be possible without more direct demonstration. Evidence (either experimental or literature) that YAP is not involved in self-renewal or induction of these progenitors at these stages should be discussed.

      We have concluded that the smaller volume of noto expressing cells is consistent with the faster depletion of the progenitor pool based on the direct observation of increased progenitor addition rate from photo-labelling experiments (Figure 3A,B). As suggested by the reviewer, we have now quantified cell divisions within the midline progenitor population and found no significant differences between mutant and control embryos. These data have now been included in Supplementary figure 3.

      - Individual datapoints in Fig 3C and 4D should be shown.

      These data have now been added to the figures

      Additional justification is needed as to why spinal cord is the best to benchmark displacement. Additionally looking at this with respect to mesoderm migration could capture another set of progenitors and behaviour/ displacements.

      Photolabels within the pre-somitic mesoderm are difficult to interpret as the high amount of cell rearrangement in this tissue leads to a spreading out of the labelled clone in a manner that then makes it difficult to assess tissue displacement (see Figure 2D,E; Thomson et al., (2021) Cells and Development). In contrast, aprevious paper has shown that notochord-spinal cord displacements can be mapped in a reliable manner across the anterior-posterior axis which motivated our choice here (McLaren and Steventon (2021) Development).

      - Plotting vacuole area in Fig.4I vs A-P position (similar to plots 1H, 2F-H) could further strengthen the point of gradual (linear) vacuolation.

      As suggested by the reviewer, we have plotted vacuole area as a function of position for the verteporfin treatment experiments, and these data have now been included in Figure 5.


      Minor points:

      - Scheme of Fig1A could benefit from having the info of zebrafish timeline (hpf)

      The scheme has been modified indicating zebrafish timeline

      - Figure 3B, what was time 0?

      Timepoints have now been included in the text and figure legend

      - The authors should address whether Verteporfin-treated mutants are rescued or whether the compound overwhelms the genetic effect.

      Given that verteporfin will impact Yap signalling in a global manner, whereas the vgl4b have a localised over-activation of Yap signalling, we think this experiment would be difficult to interpret and would likely be non-informative.

      - Cell density is an elegant measure but quite abstract. A plot of cells detected at each AP position would be quite valuable to reinforce more cells are being added to a relatively constant area.

      As suggested by the reviewer, we have now plotted these data for mutant and controls and also for verteporfin treatments. These data have now been included in supplementary figures 3 and 7.

      Reviewer #1 (Significance (Required)):

      Significance included above.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary

      Camacho-Macorra et al. investigate the mechanisms of axis extension in zebrafish embryos, focusing on the notochord and its two key elongation processes: progenitor addition (occurring early and posteriorly) and vacuolization (occurring later and in an anterior to posterior sequence). The authors first develop a mathematical model to predict notochord elongation dynamics by integrating these processes. They demonstrate that the YAP signaling pathway is active in both the notochord and its progenitors during axial extension. Their analysis reveals that vgll4b, an inhibitor of YAP, is expressed in the same regions. Knockdown of vgll4b results in YAP hyperactivation in the notochord and posterior progenitor regions, leading to increased progenitor recruitment into the notochord and a reduction in the progenitor pool. The effects of this mutation on extension are most pronounced during the late phase, which is dominated by vacuolization. The authors observe smaller vacuoles in mutants during this phase. However, early (but not late) YAP inhibition decreases notochord cell density and increases vacuole size, suggesting that YAP primarily regulates notochord progenitor uptake, which indirectly affect vacuolization.

      Major Comments

      The authors propose that YAP activity mediates a long-range feedback mechanism linking posterior progenitor addition to anterior vacuolization. Two lines of evidence are presented to support this idea. First, there appears to be compensation for tissue length during Phase 2, when both progenitor addition and vacuolization occur. Second, temporal YAP inhibition experiments show that early, but not late, YAP inactivation affects both cell addition and vacuolization. While these observations are intriguing, they do not conclusively demonstrate spatial long-range coordination. Instead, the global decrease of vacuole size could be a simple delayed consequence of cell density increase or cell disorganization at the posterior end without involving a long-range feedback along AP axis. Claiming that such long-range feedback is taking place would require a more precise characterization and/or the identification of its nature (chemical, mechanical).

      We would like to thank this reviewer for this point, that we feel requires further clarification. As they suggest, the increased additional rate of posterior progenitors leads to a later impact on vacuolation, once these cells have reached more anterior parts of the body axis- creating an effective long-range feedback mechanism to link the two processes. However, this is not a direct propagation of a signal (mechanical or otherwise) across the length of the notochord, as may have been interpreted to be based on the previous framing of our conclusions. We have modified the title of our manuscript to place less emphasis on the 'long-range feedback', and included an additional discussion paragraph to make this point clearer.

      Furthermore, there are several caveats with the interpretations of the claims cited above. The authors do not show quantification of vacuole area using notochord cell segmentation as described in Fig 1C in vgll4b mutants at stages when progenitor addition is increased.

      This is an important point highlighted by the reviewer. We have now included analysis at 24 hpf, where we do see a significant reduction in vacuole area within the anterior part of the notochord during the buffering phase in vgl4b mutants- consistent with our model that reduced anterior vacuolation compensates for increased progenitor addition rate during this phase of notochord elongation (Figure 4E).

      The slope of internuclear distances in Supplementary Figure 4A at 27 hours post-fertilization suggests that vacuolization is initially normal (similar to wt context in Fig 1H), arguing against an early defect in vacuolation dynamics along the Anterior to Posterior axis that could compensate for extra addition of progenitors.

      We have revised Supplementary Figure 4 to present a direct comparison between mutant and control embryos at each time point analyzed. This analysis shows that within the mid-trunk region of the notochord, differences in cell size first emerge at the developmental stage when vacuolation becomes the primary driver of axis elongation. In addition, we observe a progressive decoupling of the scaling relationship in mutant embryos over time. As mentioned above- there is a significant difference in vacuole size within more anterior regions at 22.5 hpf that is consistent with the model that this is buffering against increase posterior addition.

      Finally, the timing of the analysis of the effect of Verteporfin treatments is unclear. According to the legend of Figure 4F, analyses for Treatment A (16-27 hpf) and Treatment B (27-38 hpf) were done at 24 hpf and 30 hpf, respectively. If this is the case, the 3-hour window for Treatment B may not allow sufficient time to reveal effects on vacuolization.

      We agree that the information regarding the verteporfin experiments was not clearly presented in the original figure, and we have therefore revised the schematic accordingly.

      To strengthen the claim of long-range coupling, the authors could:

      Provide direct measurements of vacuolization A-P dynamics/area during Phase 2, before the effect on notochord length in the mutant, to see if there is indeed a compensatory effect on notochord length for the additional accretion of notochord progenitors in the Vgll4b mutant.

      As suggested by the reviewer, we have added an earlier time point to the A-P area dynamics plot in phase 2, corresponding to a stage at which the effect on notochord length in the mutant is not yet detectable. At this stage, we observed no difference in vacuole area between mutants and controls. We have also included an earlier time point analysis in the anterior region of the axis, which shows a similar cell size difference to that observed later in a more posterior region (Figure 4F; see above response).

      Clarify the analysis timing of Treatment B to confirm that YAP inhibition during the vacuolization phase truly has no effect.

      This has now been clarified.

      Additionally, as a non-specialist, I found the distinction between the two modeling hypotheses difficult to follow. Specifically, it is unclear why the first hypothesis assumes YAP affects vacuolation rate, while the second assumes it affects vacuolation front speed. It is also not intuitive how front speed can be independent of vacuolation rate, as one would expect that if cells form vacuoles more slowly, the front should progress more slowly as well. Therefore, it could be good to clarify these aspects of the modeling part.

      We thank the reviewer for this comment and apologise for the lack of clarity in our description of the model. In our framework, the cell size profile along the AP axis of the notochord is governed by two distinct processes: (i) the addition of progenitors at the posterior tip, and (ii) vacuolation, which increases cell size and proceeds from anterior to posterior. We model the latter as a propagating wave with velocity vf​, such that cells begin to vacuolate when the wave front reaches their position.

      Importantly, in the model these two aspects of vacuolation are decoupled: the front velocity vf​ determines when a given cell starts vacuolating, whereas the vacuolation rate J determines how fast the cell increases in size once the process has started. Biologically, this corresponds to distinguishing between the propagation of a trigger or competence signal along the tissue, and the execution of vacuole growth within each cell. Our reasoning was that they need not be strictly proportional: a signalling wave could propagate at a given speed even if the downstream cellular response is slower or faster.

      This is why we considered two alternative hypotheses: either YAP modulates the propagation of the vacuolation front (affecting vf​), or it modulates the growth dynamics within each cell (affecting J). Our quantitative comparison with the experimental data supports the former scenario. This has now been clarified in the main text.

      Minor Comments

      While the study is technically sound, a few areas could benefit from improved clarity or additional data.

      An intriguing but puzzling finding is the reduction in the noto-expressing progenitor domain in vgll4b mutants, despite elevated YAP activity in progenitors. Intuitively, if YAP promotes progenitor maintenance or expansion, one might expect the noto+ domain to increase, not shrink. This paradox suggests that YAP may not only simply maintain progenitors but instead accelerates their differentiation or migration into the notochord (as stated in the manuscript and graphical abstract). Alternatively, YAP could only deplete the noto+ pool by driving premature entry into the notochord, though the lack of clear YAP upregulation in this domain would imply a non-cell autonomous role of YAP for this interpretation. The authors should discuss these possibilities more explicitly in the Discussion section and could consider including additional markers, such as proliferation assays or apoptosis markers, to clarify whether YAP affects progenitor proliferation, differentiation, or migration.

      As also suggested by the reviewer, we have included a cell proliferation analysis in Supplementary Figure 3 and have revised the Discussion section accordingly.

      In Figure 2B, the YAP activity reporter signal in the posterior floor plate is not immediately obvious. The authors should consider providing higher-magnification insets.

      As suggested by the reviewer, we have included higher-magnification insets in Figure 2

      In Figure 2C, the differences in tail shape between wild-type and mutant embryos are visually striking. If these differences have not been quantified or discussed, a brief comment in the text would be helpful.

      We did not see a consistent impact on the morphology of the posterior body, this has now been clarified in the main text.

      Supplementary Figure 6 describes embryo length differences in mutants but does not include a representative image. Adding one would strengthen the phenotypic description.

      As suggested by the reviewer, we have modified Supplementary Figure 6

      Figure 1C is not cited in the text as not associated with a result, but just a description of the approach that is used later in Fig 4I

      We have modified the text to include the appropriate figure reference.

      Finally, the authors might consider citing Michaud & Pourquié (2025) when presenting the role of hydrostatic pressure in axis elongation in the Introduction.

      We have now modified the text to include this citation which we agree is relevant to this work.

      Reviewer #2 (Significance (Required)):

      This study by Camacho-Macorra et al. presents a fascinating exploration of how YAP signaling and its inhibition by vgll4b coordinate progenitor addition and vacuolization during zebrafish notochord elongation. The work is well executed, with clear results and integration of mathematical modeling and experimental data. The findings shed new light on the molecular and mechanical regulation of axis extension, a fundamental process in vertebrate development. However, while the study is innovative and rigorously conducted, the central claim of "long-range coupling" between progenitor addition and vacuolization requires further substantiation. Addressing the points discussed below will make the study more convincing and accessible to developmental biologists and mechanobiologists alike.

      reviewer expertise: developmental biologist specialised in morphogenesis

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      In the studies conducted by Camacho-Macorra et al., the authors examine the extension of the body axis is zebrafish, focusing on the notochord. They specifically compare timepoints where progenitor addition to the notochord and vacuolization are important to drive axis extension. They generate a simple mathematical model of notochord extension and show that it recapitulates observations in vivo where progenitor addition and vacuolation drive tissue elongation. They further perturb the system by showing that YAP activity is localized to the midline progenitors of the notochord where when the competitive inhibitor of YAP vgll4b is perturbed it increases YAP signaling and results in increase progenitor addition to the notochord. They further describe a possible indirect-feedback mechanism linking YAP driven progenitor addition to the notochord with anterior vacuolation which when perturbed (i.e. increased YAP) results in reduced notochord elongation.

      Major Comments:

      NA

      Minor comments:

      1.Figure 1B - please put the model equation in the figure or at least point out what variables of the equation refer to each part of the schematic.

      As suggested by the reviewer, we have modified the scheme in Figure 1

      2.Figure 1F - smooth line is misleading, please include individual embryo measurement points. This comment could be applied to several figures

      We agree with the reviewer that the graphs in the original manuscript could be improved, and we have therefore modified all figures to better represent data dispersion within each group.

      3.Figure 2C/D - To make this manuscript more accessible to individuals who are not familiar with the anatomy of zebrafish tail, please include zoom in panels of the region of interest where arrows are pointing out increased YAP signaling in the floor plate and hypochord.

      As suggested by the reviewer, we have included higher-magnification insets in Figure 2

      4.In discussion - "In vgll4b mutants, increased progenitor incorporation initially does not alter overall notochord length due to a buffering mechanism for natural variation in progenitor addition" - this is not directly tested in terms of buffering for variation and is an assumption. Please either cite a paper or reword

      This point has been clarified in the revised discussion.

      Reviewer #3 (Significance (Required)):

      Overall, the logic and experiments conducted in these studies are well defined. However, the significance of the work is minimal and makes only a small contribution to the advancement of the field of developmental biology. Regardless, the studies are well done and worth publication.

      Strengths:

      -The study does a good job of incorporating and testing a computational model in a way that proves/disproves their hypothesis

      -The manuscript is well written and follows a logical order, making it easy for readers to understand the main findings

      -The study uses multiple routes of YAP inhibition (genetic and drug) to show effect on progenitor addition to the notochord and shortened body axis

      -The discussion does aa very good job of giving the context of the study's results.

      Weaknesses:

      -The study is minimal and fails to illuminate the mechanism that connects progenitor addition to vacuolization, claiming only an indirect relationship with YAP signaling. However, this is admitted by the authors and not overstated

      The study provides a minimal advancement to the field by investigating an unexplored area of zebrafish notochord extension. It provides a small step toward connecting mechanical/morphogenic mechanisms with signalling in zebrafish body axis extension.

      The audience of this work is a specialized basic research group of developmental biology scientists. The research is of particular relevance to individuals studying zebrafish or axis elongation. While the authors make comparisons to other systems, due to the unique nature of the zebrafish body extension, this generates a narrow field of focus for the manuscript.

      We have previously discussed the uniqueness of zebrafish posterior body elongation in light of critical differences in the degree to which posterior growth from self-renewing tailbud progenitor populations contribute to the mechanisms of axis elongation (Sambasivan and Steventon (2021) Frontiers in cell and dev. Biol; Steventon and Martinez Arias (2017) Developmental Biology). Here too, we think zebrafish provide an important system to explore differences in the mechanisms that drive notochord elongation, and we envisage that this study will provoke a similar cross species comparison that takes into account differences in the relative timing of progenitor addition and anterior notochord expansion (that occurs much later in amniotes, for example). It is only by considering these species-specific differences across experimental organisms that we can arrive at the fundamental principles that drive developmental processes, and how evolution has acted upon these to drive change in adult body plans. We therefore respectfully disagree with the review about the scope and importance of this work for these reasons.

      In addition, we feel that the principles by which dynamic processes are coupled across an organ are broadly applicable and will illuminate further research into understanding organ growth control.

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      Referee #3

      Evidence, reproducibility and clarity

      In the studies conducted by Camacho-Macorra et al., the authors examine the extension of the body axis is zebrafish, focusing on the notochord. They specifically compare timepoints where progenitor addition to the notochord and vacuolization are important to drive axis extension. They generate a simple mathematical model of notochord extension and show that it recapitulates observations in vivo where progenitor addition and vacuolation drive tissue elongation. They further perturb the system by showing that YAP activity is localized to the midline progenitors of the notochord where when the competitive inhibitor of YAP vgll4b is perturbed it increases YAP signaling and results in increase progenitor addition to the notochord. They further describe a possible indirect-feedback mechanism linking YAP driven progenitor addition to the notochord with anterior vacuolation which when perturbed (i.e. increased YAP) results in reduced notochord elongation.

      Major Comments: NA

      Minor comments: 1.Figure 1B - please put the model equation in the figure or at least point out what variables of the equation refer to each part of the schematic.

      2.Figure 1F - smooth line is misleading, please include individual embryo measurement points. This comment could be applied to several figures

      3.Figure 2C/D - To make this manuscript more accessible to individuals who are not familiar with the anatomy of zebrafish tail, please include zoom in panels of the region of interest where arrows are pointing out increased YAP signaling in the floor plate and hypochord.

      4.In discussion - "In vgll4b mutants, increased progenitor incorporation initially does not alter overall notochord length due to a buffering mechanism for natural variation in progenitor addition" - this is not directly tested in terms of buffering for variation and is an assumption. Please either cite a paper or reword

      Significance

      Overall, the logic and experiments conducted in these studies are well defined. However, the significance of the work is minimal and makes only a small contribution to the advancement of the field of developmental biology. Regardless, the studies are well done and worth publication.

      Strengths:

      • The study does a good job of incorporating and testing a computational model in a way that proves/disproves their hypothesis
      • The manuscript is well written and follows a logical order, making it easy for readers to understand the main findings
      • The study uses multiple routes of YAP inhibition (genetic and drug) to show effect on progenitor addition to the notochord and shortened body axis
      • The discussion does aa very good job of giving the context of the study's results.

      Weaknesses:

      • The study is minimal and fails to illuminate the mechanism that connects progenitor addition to vacuolization, claiming only an indirect relationship with YAP signaling. However, this is admitted by the authors and not overstated

      The study provides a minimal advancement to the field by investigating an unexplored area of zebrafish notochord extension. It provides a small step toward connecting mechanical/morphogenic mechanisms with signalling in zebrafish body axis extension.

      The audience of this work is a specialized basic research group of developmental biology scientists. The research is of particular relevance to individuals studying zebrafish or axis elongation. While the authors make comparisons to other systems, due to the unique nature of the zebrafish body extension, this generates a narrow field of focus for the manuscript.

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      Camacho-Macorra et al. investigate the mechanisms of axis extension in zebrafish embryos, focusing on the notochord and its two key elongation processes: progenitor addition (occurring early and posteriorly) and vacuolization (occurring later and in an anterior to posterior sequence). The authors first develop a mathematical model to predict notochord elongation dynamics by integrating these processes. They demonstrate that the YAP signaling pathway is active in both the notochord and its progenitors during axial extension. Their analysis reveals that vgll4b, an inhibitor of YAP, is expressed in the same regions. Knockdown of vgll4b results in YAP hyperactivation in the notochord and posterior progenitor regions, leading to increased progenitor recruitment into the notochord and a reduction in the progenitor pool. The effects of this mutation on extension are most pronounced during the late phase, which is dominated by vacuolization. The authors observe smaller vacuoles in mutants during this phase. However, early (but not late) YAP inhibition decreases notochord cell density and increases vacuole size, suggesting that YAP primarily regulates notochord progenitor uptake, which indirectly affect vacuolization.

      Major Comments

      The authors propose that YAP activity mediates a long-range feedback mechanism linking posterior progenitor addition to anterior vacuolization. Two lines of evidence are presented to support this idea. First, there appears to be compensation for tissue length during Phase 2, when both progenitor addition and vacuolization occur. Second, temporal YAP inhibition experiments show that early, but not late, YAP inactivation affects both cell addition and vacuolization. While these observations are intriguing, they do not conclusively demonstrate spatial long-range coordination. Instead, the global decrease of vacuole size could be a simple delayed consequence of cell density increase or cell disorganization at the posterior end without involving a long-range feedback along AP axis. Claiming that such long-range feedback is taking place would require a more precise characterization and/or the identification of its nature (chemical, mechanical). Furthermore, there are several caveats with the interpretations of the claims cited above. The authors do not show quantification of vacuole area using notochord cell segmentation as described in Fig 1C in vgll4b mutants at stages when progenitor addition is increased. The slope of internuclear distances in Supplementary Figure 4A at 27 hours post-fertilization suggests that vacuolization is initially normal (similar to wt context in Fig 1H), arguing against an early defect in vacuolation dynamics along the Anterior to Posterior axis that could compensate for extra addition of progenitors. Finally, the timing of the analysis of the effect of Verteporfin treatments is unclear. According to the legend of Figure 4F, analyses for Treatment A (16-27 hpf) and Treatment B (27-38 hpf) were done at 24 hpf and 30 hpf, respectively. If this is the case, the 3-hour window for Treatment B may not allow sufficient time to reveal effects on vacuolization. To strengthen the claim of long-range coupling, the authors could: Provide direct measurements of vacuolization A-P dynamics/area during Phase 2, before the effect on notochord length in the mutant, to see if there is indeed a compensatory effect on notochord length for the additional accretion of notochord progenitors in the Vgll4b mutant. Clarify the analysis timing of Treatment B to confirm that YAP inhibition during the vacuolization phase truly has no effect. Additionally, as a non-specialist, I found the distinction between the two modeling hypotheses difficult to follow. Specifically, it is unclear why the first hypothesis assumes YAP affects vacuolation rate, while the second assumes it affects vacuolation front speed. It is also not intuitive how front speed can be independent of vacuolation rate, as one would expect that if cells form vacuoles more slowly, the front should progress more slowly as well. Therefore, it could be good to clarify these aspects of the modeling part.

      Minor Comments

      While the study is technically sound, a few areas could benefit from improved clarity or additional data. An intriguing but puzzling finding is the reduction in the noto-expressing progenitor domain in vgll4b mutants, despite elevated YAP activity in progenitors. Intuitively, if YAP promotes progenitor maintenance or expansion, one might expect the noto+ domain to increase, not shrink. This paradox suggests that YAP may not only simply maintain progenitors but instead accelerates their differentiation or migration into the notochord (as stated in the manuscript and graphical abstract). Alternatively, YAP could only deplete the noto+ pool by driving premature entry into the notochord, though the lack of clear YAP upregulation in this domain would imply a non-cell autonomous role of YAP for this interpretation. The authors should discuss these possibilities more explicitly in the Discussion section and could consider including additional markers, such as proliferation assays or apoptosis markers, to clarify whether YAP affects progenitor proliferation, differentiation, or migration. In Figure 2B, the YAP activity reporter signal in the posterior floor plate is not immediately obvious. The authors should consider providing higher-magnification insets. In Figure 2C, the differences in tail shape between wild-type and mutant embryos are visually striking. If these differences have not been quantified or discussed, a brief comment in the text would be helpful. Supplementary Figure 6 describes embryo length differences in mutants but does not include a representative image. Adding one would strengthen the phenotypic description. Figure 1C is not cited in the text as not associated with a result, but just a description of the approach that is used later in Fig 4I Finally, the authors might consider citing Michaud & Pourquié (2025) when presenting the role of hydrostatic pressure in axis elongation in the Introduction.

      Significance

      This study by Camacho-Macorra et al. presents a fascinating exploration of how YAP signaling and its inhibition by vgll4b coordinate progenitor addition and vacuolization during zebrafish notochord elongation. The work is well executed, with clear results and integration of mathematical modeling and experimental data. The findings shed new light on the molecular and mechanical regulation of axis extension, a fundamental process in vertebrate development. However, while the study is innovative and rigorously conducted, the central claim of "long-range coupling" between progenitor addition and vacuolization requires further substantiation. Addressing the points discussed below will make the study more convincing and accessible to developmental biologists and mechanobiologists alike.

      reviewer expertise: developmental biologist specialised in morphogenesis

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      Referee #1

      Evidence, reproducibility and clarity

      This work focuses on zebrafish notochord morphogenesis during axial elongation. In particular it dissects the role of YAP signalling on regulating the balance between caudal cell addition with the cell enlargement occurring rostrally through vacuolation.

      The article is timely to the field and includes several important experiments. The overall presentation and written style are good, citations are adequate and there is a clear effort to integrate experiments and mathematical modelling from the outset. The logic behind experiments is sound and the conclusion coherent (even if not totally unexpected given the literature): YAP affects progenitor addition which in turn changes packing, vacuolation and axis length. I just have a few points that could make the article clearer and more persuasive.

      Major points

      • Last section of results is difficult and confusing. After analysing vgll4b loss-of-function line, effectively over-activating YAP, the focus is on YAP inhibition using Verteporfin.
        • Concerns on Verteporfin: the molecule has been widely used to module YAP, but there are also plenty of studies suggesting it is non-specific (also degrades YAP, has 14-4-3σ dependency and induces stress). I would consider an alternative: truncated TEAD, LATS over-expression or gain-of-function phosphomimetic versions of YAP.
        • Presentation: regardless of point above, Verteporfin's role on YAP should be verified in the system. As such it is crucial to include: images of 4xGTIIC, noto and YAP stains after treatment. Only then inspect the effects on vacuolation and different treatments.
      • In Fig 3F, noto HCR staining is taken as evidence for progenitor exhaustion/ faster depletion. Other scenarios would be possible without more direct demonstration. Evidence (either experimental or literature) that YAP is not involved in self-renewal or induction of these progenitors at these stages should be discussed.
      • Individual datapoints in Fig 3C and 4D should be shown. Additional justification is needed as to why spinal cord is the best to benchmark displacement. Additionally looking at this with respect to mesoderm migration could capture another set of progenitors and behaviour/ displacements.
      • Plotting vacuole area in Fig.4I vs A-P position (similar to plots 1H, 2F-H) could further strengthen the point of gradual (linear) vacuolation.

      Minor points:

      • Scheme of Fig1A could benefit from having the info of zebrafish timeline (hpf)
      • Figure 3B, what was time 0?
      • The authors should address whether Verteporfin-treated mutants are rescued or whether the compound overwhelms the genetic effect.
      • Cell density is an elegant measure but quite abstract. A plot of cells detected at each AP position would be quite valuable to reinforce more cells are being added to a relatively constant area.

      Significance

      Significance included above.

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      Reply to the reviewers

      Reviewer #1

      Evidence, reproducibility and clarity:

      In this paper, Tomasek and colleagues describe a series of experiments illuminating the effects of OM-89, a bacterial lysate taken orally for prevention of recurrent UTI, on intracellular dynamics of UPEC, using cell culture and organoid models. Suggestions for improvement and for clarification of the authors' conclusions and relevance to human UTI (and OM-89 use) are offered below.

      Major points:

      1. The data indicate that OM-89 exposure in the organoids enhances lysosomal degradation pathways and (in mBOs) autophagic flux, and the authors conclude this is a mechanism by which UPEC regrowth after antibiotic treatment (modeling rUTI) is inhibited by OM-89. They also show enhanced cellular uptake of fluorescently labeled antibiotics (ampicillin) in organoids - this leads them to conclude (and state in the paper's title) that increased intracellular antibiotic concentration effects increased killing of UPEC and decreased regrowth. These are two separate proposed mechanisms, and especially with regard to the antibiotics, they have not shown that increased intracellular antibiotic concentration actually kills intracellular UPEC in their model - only that regrowth as measured microscopically is less. In total, a mechanistic connection between the observed lysosomal effect and the intracellular antibiotic uptake, and which one is more important for UPEC control in this model, is incomplete. The precise wording of the paper's title should be reconsidered accordingly.

      We agree with the reviewer that our study does not establish a direct mechanistic connection between OM-89-induced lysosomal remodeling and enhanced intracellular antibiotic accumulation, nor does it definitively determine the relative contribution of each process to intracellular UPEC control. Further studies dissecting the molecular pathways underlying these phenotypes will be required to determine whether they are mechanistically linked or represent parallel epithelial defense responses induced by OM-89.

      Importantly, additional CFU experiments performed during revision (as suggested in point number 4) revealed that OM-89 already reduces intracellular bacterial burden following a classical gentamicin protection assay, prior to prolonged ampicillin exposure. These findings suggest that enhanced intracellular bacterial control cannot be explained solely by increased intracellular antibiotic accumulation and support a direct contribution of epithelial antimicrobial mechanisms, including lysosomal activation, to the observed phenotype. Nevertheless, the relative contribution of lysosomal remodeling and enhanced antibiotic uptake to bacterial clearance remains unresolved and will require further investigation.

      Accordingly, we changed the title to "Targeted lysosomal activation in bladder epithelium enhances clearance of intracellular uropathogenic Escherichia coli." This revised title avoids implying a direct causal link between increased intracellular antibiotic accumulation and bacterial clearance while reflecting the central biological process identified in our study.

      OM-89 is taken orally for rUTI prevention, and some "components" reach the urinary tract (line 81). But it isn't explained how applying OM-89 directly to organoids models how its components may reach the bladder epithelium (from the basolateral side, if the OM-89 is applied outside the organoids) in the whole animal or human. At the least, this limitation should be stated in the Discussion.

      We thank the reviewer for pointing out this limitation. Although advanced in vitro models help to better mimic the in vivo situation, they still do not fully recapitulate all aspects of drug exposure and delivery observed in vivo. We included the following statement of limitation now in the discussion in lines 493-503: “One limitation of our study is that OM-89 was applied directly to epithelial cultures and organoids, whereas in clinical use it is administered orally. Although pharmacokinetic studies have demonstrated systemic distribution and urinary accumulation of OM-89-derived components following oral administration (van Dijk, 1982), our experimental setup does not recapitulate the exact route, kinetics or concentration profiles encountered in vivo. Rather, our models were designed to determine whether bladder epithelial cells are capable of responding directly to OM-89-mediated signals and to identify the intracellular pathways involved. Given the documented systemic exposure following oral administration, direct effects on the urothelium are biologically plausible. However, future studies will be required to determine how the epithelial responses identified here integrate with the complex systemic and immune-mediated effects of OM-89 under physiological administration conditions.”

      In the lysosome studies starting on line 319, the cultured cells are all infected (and either treated with OM-89 or not). What observations regarding number and size of vesicles, etc (all the measures in Fig 6) are evident when cells are treated with OM-89 only? These data should be presented (at least as a supplemental figure) to enable optimal interpretation of the OM-89+UPEC data in Fig 6. As the authors themselves indicate, OM-89 may be having a generalized effect on endocytic and/or autophagic flux by bladder epithelial cells, independent of infection.

      We thank the reviewer for this helpful suggestion and agree that assessing OM-89 treatment in the absence of infection provides important context for interpreting the infection-associated phenotypes as shown in Figure 6.

      Accordingly, we have included additional supplementary data examining the effects of OM-89 alone in both murine and human bladder epithelial cells. Specifically, we added analyses of Lamp1-positive lysosomal vesicles, lysosomal acidification (LysoSensor), and Cathepsin L activity under uninfected conditions (Supplementary Figures 4A, 4G and 7D-F). We comment on these additional findings in the Result section in lines 242-246 and lines 366-370, and in the Discussion section in lines 469-483.

      These experiments, together with the transcriptional data in SI Figure 3D, demonstrate that key features of lysosome-centered remodeling and activation are already induced by OM-89 in the absence of infection, indicating that OM-89 directly modulates epithelial lysosomal pathways rather than merely amplifying infection-driven responses. Inclusion of these data provides additional context for interpreting the infection-associated phenotypes shown in the main figures and further supports the concept of OM-89 as a direct modulator of epithelial antimicrobial function.

      With the organoids, beyond the microscopic quantification of UPEC, can CFUs be measured?

      We appreciate the reviewer’s interest in obtaining orthogonal measurements of bacterial burden. Performing CFU quantification directly from microinjected organoids is technically challenging, as it requires highly reproducible injections into identical numbers of organoids while avoiding bacterial leakage into the surrounding extracellular matrix. Even minor variations or accidental release of bacteria into the Matrigel can substantially affect CFU recovery and compromise interpretation.

      To address the reviewer’s underlying question while avoiding these limitations, we performed intracellular CFU assays using differentiated mouse bladder epithelial monolayers. Following a classical gentamicin protection assay for 1 hour, OM-89-treated cells displayed significantly reduced intracellular bacterial burden compared with PBS controls (new Figure 2C). Addition of ampicillin for 3 hours after the gentamicin protection phase resulted in a similar trend but did not further significantly reduce the bacterial burden (new Figure 2D). We commented on these findings in the Results section in lines 169-182, and in the Discussion section in lines 463-469 and lines 474-483. We also updated the Methods section in lines 637-652 with the intracellular bacterial burden assay description.

      These experiments provide an orthogonal readout of intracellular bacterial burden and are consistent with enhanced epithelial control of intracellular UPEC. In addition, we would like to clarify that the higher-throughput microscopy approach used throughout the organoid experiments does not allow strict discrimination between luminal, intracellular and tissue-associated bacteria. We therefore revised the terminology throughout the manuscript and now consistently refer to the measured signal as “intra-organoid bacterial burden”. To clarify this point, we added the following statement to the Results section (line 115): “Hence, the microscopy data represent the total “intra-organoid” bacterial burden at each experimental stage, without distinguishing the exact localization of the bacteria – which can be luminal, intracellular or tissue-associated.”. Consistent with this clarification, we have replaced the term “antibiotic-mediated killing” throughout the manuscript with the more cautious wording “antibiotic-mediated clearance” or “reduced bacterial burden”, where appropriate.

      Minor points:

      1. In Fig 1A, the "co-application" horizontal line is under the 7-10 hour window, but the text suggests that the application of antibiotics and OM-89 in this experiment is between 4-7 hours.

      We thank the reviewer for pointing this out. Indeed, in the co-application regime, OM-89 is added at the same timepoint as the antibiotic – meaning straight after monitoring the growth phase at 4h post-infection (pi). We now adapted the horizontal line for the “co-application” treatment in Figure 1A accordingly to represent the time-point of OM-89 addition better. Additionally, we added a line for the antibiotic-treatment in order to further facilitate readability.

      How are antibiotics and OM-89 "removed" at the 7-hour mark? This was not detailed in the Methods.

      Although we had specified this in the methods section (now line 682: “For every media exchange (e.g. antibiotic treatment or withdrawal), each well was washed with 9 ml of the respective media before leaving 1 ml in the well.”), we realized the positioning was not optimal as we had mentioned this part under the point “Bacterial injection” in “Injection experiments”. We therefore now separated this part, together with the lid preparation, from the “Bacterial injection” part and created the new subsection “Lid preparation for media changes” (line 668 onwards).

      What time point was used for the transcriptomic profiling of organoids? This is not clear from the relevant Methods or Results sections.

      As stated in the methods section, RNA for transcriptomic profiling from mBOs was extracted at 4h post-infection (pi) (now line 892).

      In showing that OM-89 "attenuated" the magnitude of inflammatory responses (Fig 2C and S3B), it would be helpful to add a panel showing the comparison of OM89+UPEC to PBS alone - this would be expected to convey activity (red) in the infection-related pathways, but to a lower magnitude than seen in UPEC vs PBS.

      Please see our combined response at point 5.

      Similarly, in the results outlined starting on line 196, it would be helpful to add a panel showing OM89+UPEC vs OM89 alone.

      We thank the reviewer for these suggestions. We performed the requested additional analyses and generated Gene Ontology Biological Process (GOBP) enrichment plots comparing (i) PBS+UPEC versus PBS, (ii) OM-89+UPEC versus PBS and (iii) OM-89+UPEC versus OM-89.

      As anticipated by the reviewer, these analyses show that infection-associated pathways remain induced in OM-89-treated infected organoids but with a reduced magnitude compared with infected PBS controls. Specifically, pathways that are strongly enriched in the PBS+UPEC versus PBS comparison display lower enrichment significance and effect size in the OM-89+UPEC versus PBS comparison. Furthermore, many of these pathways are no longer significantly enriched in the direct OM-89+UPEC versus OM-89 comparison, indicating that OM-89 attenuates the transcriptional inflammatory response induced by UPEC infection. These observations are consistent with our original interpretation, concluded from Figure 3C, that OM-89 dampens excessive infection-associated inflammatory signaling while preserving epithelial antimicrobial activity.

      Importantly, we found that the direct comparison between PBS+UPEC and OM-89+UPEC, presented in the original Figure 3C, remains the most informative representation of the OM-89 effect because it controls for infection status while specifically highlighting the transcriptional changes induced by OM-89. By contrast, comparisons against PBS or OM-89 alone involve simultaneous changes in both infection and treatment status, making biological interpretation less straightforward.

      Nevertheless, because the additional analyses directly address the reviewer's request and provide complementary context for interpreting Figure 3C, we have included them in Supplementary Figure 3B.

      In line 236, what is meant by lysosomal "activation"? A more specific term should be chosen here.

      We thank the reviewer for this question and aim to increase readability of this section. With lysosomal activation in the first sentence of the mentioned paragraph, we referred to the observed effect of upregulated lysosomal pathways and enhanced lysosomal function (measured by alterations in lysosomal vesicles) in the previous paragraph. However, to make the connection to the previous paragraph better, and given the comment number two of reviewer number two, we changed the whole first paragraph of this section. Therefore, the first sentence of this paragraph (line 252 onwards) reads now: “To test whether the observed effects on lysosomal pathways could mechanistically, at least in parts, explain OM-89-mediated protection, we first used Genebridge analysis (Li et al, 2019) to examine how the lysosomal gene signature identified in our RNA-seq data relates to host defense programs in the human bladder.”

      In the Abstract (line 25), the phrase "Using bladder organoids..." is a dangling modifier.

      We thank the reviewer for pointing this out and changed the sentence accordingly to “OM-89 promotes lysosomal acidification and increases lysosomal protease activity in bladder organoids and differentiated epithelial monolayers, thereby directing intracellular UPEC toward degradative compartments.” (now line 24)

      Typographical and copyediting:

      We thank the reviewer for identifying typographical errors and have corrected them throughout the manuscript.

      1. Line 74 should read "For instance..."

      2. Line 76 should read "when combined with antibiotic therapy..."

      As this sentence is to emphasize the already observed protective effects of OM-89, and the two studies mentioned were either performed without or in combination with antibiotics, we changed the sentence to “For instance, rodent infection studies have demonstrated protective effects of OM-89 alone (Bosch et al, 1988; Lee et al, 2006) and in combination with antibiotic therapy (Canton et al, 2025; Bessler et al, 2010), although this observed in vivo protection could not be linked to any major quantitative changes in bladder immune cell infiltration (Canton et al, 2025), leaving the underlying molecular mechanism not fully resolved.” for better readability. (now line 71)

      Line 122 should read "...regrowth following antibiotic treatment" or "regrowth post-antibiotic treatment"

      Line 138 should use "regimen" not "regime"

      Line 196 delete comma after "Although"

      Line 244 fully hyphenate "OM-89-mediated"

      Line 374 should read "...significantly enhance antibiotic-mediated killing"

      Significance:

      The paper is very well written and though a lot of data are included, the presentation is excellent and helps the reader to follow the story. The paper makes a strong contribution to the UTI pathogenesis field, and the use of mouse and human bladder organoids is innovative in studying intracellular UPEC. My scientific expertise as a reviewer is in UPEC pathogenesis, directly relevant to the content of this paper.

      Reviewer #2

      Evidence, reproducibility and clarity:

      This study examined the effect of OM-89 on UPEC infection, antibiotic clearance, and resurgence in mouse and human organoid models. The goal of the study was to understand the molecular mechanisms by which OM-89 is effective at preventing rUTI in patients.

      Major comments:

      The manuscript is well-written and the figures are well presented. Adequate background information is provided to give the study context and sufficient experimental details are provided to allow replication by other groups. Experiments contain appropriate controls and sufficient replicates to allow appropriate statistical analyses. The authors are careful to acknowledge the differences they observed between the mouse and human system and provide satisfactory potential explanations for these differences. The conclusions they draw are well supported by their data and none of their claims from their data are overstatements. Below are some, which I believe if addressed could improve the paper.

      1. I think the authors overstate the novelty of the concept that the urothelium is an active targetable determinant of infection and treatment outcomes. This is not an entirely new concept since previous studies have examined antimicrobial peptides and other factors from the urothelium.

      We thank the reviewer for this important point and agree that the urothelium has long been recognized as an active participant in host defense through mechanisms such as antimicrobial peptide production, pathogen sensing and regulation of inflammatory responses. We have therefore revised the manuscript to avoid implying that urothelial involvement in infection outcome is itself a novel concept. Instead, we now emphasize the specific advance of our study: the identification of lysosome-centered epithelial activation as a therapeutically targetable mechanism that enhances intracellular bacterial clearance and potentiates antibiotic efficacy.

      In the abstract we changed: “Our findings position the bladder epithelium from a passive barrier to an active, targetable determinant of treatment outcome and suggest host-directed modulation of epithelial antimicrobial pathways as a promising strategy to enhance intracellular bacterial clearance.” to “Our findings demonstrate that bladder epithelial antimicrobial pathways can be pharmacologically reinforced to influence treatment outcomes by enhancing intracellular bacterial clearance.” in line 29.

      In the introduction we changed: “Together with increased intracellular accumulation of antibiotics across different classes, this leads to improved intracellular killing and reduced bacterial regrowth across diverse UPEC strains.” to “Together with increased intracellular accumulation of antibiotics across different classes, these changes are associated with improved intracellular clearance and reduced bacterial regrowth across diverse UPEC strains.” in line 90 and “Together, these findings reveal a previously unrecognized epithelial lysosome-centered mechanism by which OM-89 enhances intracellular antibiotic performance and repositions the bladder epithelium from a passive reservoir of infection reactivation to an actively transformable antimicrobial compartment influencing treatment outcomes.” to “Together, these findings reveal a previously unrecognized lysosome-centered epithelial mechanism by which OM-89 strengthens bladder epithelial antimicrobial defenses and enhances intracellular bacterial clearance, identifying enhanced lysosomal function as a therapeutically targetable component of host defense.” in line 95.

      In the discussion we changed: “Together, these findings provide a mechanistic framework for the long-observed clinical efficacy of OM-89. Our findings reveal that the urothelium itself can be therapeutically targeted to reduce pathogen regrowth by transforming the epithelial barrier from a passive refuge for UPEC into an active defense site.” to “Together, these findings provide a mechanistic framework for the long-observed clinical efficacy of OM-89 and identify epithelial lysosomal pathways as a therapeutically targetable component of host defense that can be used to improve intracellular bacterial clearance.” in line 421 and “In the face of rising antimicrobial resistance (2024), strengthening epithelial antimicrobial function offers a complementary route to shift the bladder mucosa from a passive niche of bacterial survival and infection reactivation toward an active site of accelerated pathogen clearance.” to “In the face of rising antimicrobial resistance (2024), our findings provide a mechanistic rationale for the clinical use of OM-89 and support epithelial lysosomal pathways as a promising target for host-directed therapeutic strategies that enhance intracellular bacterial clearance and improve the efficacy of existing antibiotics.” in line 513.

      Depending on the target audience, the Module-Module association analysis could need more introduction. I am not a computational biologist and it was not obviously apparent how Figure 4A is generated and what it actually showing. How specifically does this analysis demonstrate a functional link between lysosomal activity and immune defense pathways? Without further explanation, it is my opinion that this figure panel is an unnecessary distraction that is not required for any of the conclusions that the group can already draw from the rest of their data.

      We thank the reviewer for this constructive critique. We agree that the rationale and interpretation of this analysis were not sufficiently explained in the original manuscript. We have therefore expanded the description of the MMAS approach and clarified how these data support the translational relevance of the lysosomal pathways identified in our experimental models.

      Specifically, we now explain that the Module-Module Association Score (MMAS) analysis evaluates transcriptional correlations between the lysosomal gene network and functional biological pathways across eight independent human bladder transcriptomic datasets comprising more than 1,400 clinical samples. We further highlight the strong positive associations observed with host defense modules, including “response to molecule of bacterial origin”, “cell activation involved in immune response”, and “innate immune response”. These additions clarify both the methodology and the rationale for including Figure 5A as a translational bridge between our experimental findings and human bladder biology.

      The revised text (starting at line 251) now reads: “To test whether the observed effects on lysosomal pathways could mechanistically, at least in parts, explain OM-89-mediated protection, we first used Genebridge analysis (Li et al, 2019) to examine how the lysosomal gene signature identified in our RNA-seq data relates to host defense programs in the human bladder. To evaluate the translational relevance of our experimental findings, we used a computational Module-Module Association Score (MMAS) analysis across eight independent human bladder transcriptomic datasets comprising over 1,400 clinical samples. This network-based approach evaluates the transcriptional correlation between the lysosomal gene network and functional biological pathways across diverse human cohorts. Module-Module association analysis performed on these human bladder datasets indicated that the lysosome module has strong positive associations with specific host defense modules, including "response to molecule of bacterial origin", "cell activation involved in immune response", and "innate immune response" (Figure 5A), highlighting a conserved functional link between lysosomal activity and immune defense pathways in the bladder epithelium. Altogether, these positive correlations suggest that enhanced lysosomal function represents a conserved pathway integrated within mucosal immunity across species, rather than an isolated cellular response unique to our experimental models.”

      Significance:

      General assessment: Solid experimental design with appropriate controls. Appropriate statistical rigor. Conclusions justified by the data. Limitations acknowledged. Differences in results between mice and humans acknowledged.

      Advance: Moderate technical advance building on prior organoid models. Significant mechanistic advance because OM-89 has been widely used for a long time without detailed understanding of why it works. Moderate conceptual advance that urothelial cells are a targetable determinant of treatment outcomes.

      Audience: I am a basic science researcher in the field of female urogenital tract microbiome and infections. Other researchers studying UTI will certainly be interested in this study. It also may be of interest to people studying other bladder conditions that involve the urothelium (bladder cancer).

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      Referee #2

      Evidence, reproducibility and clarity

      This study examined the effect of OM-89 on UPEC infection, antibiotic clearance, and resurgence in mouse and human organoid models. The goal of the study was to understand the molecular mechanisms by which OM-89 is effective at preventing rUTI in patients.

      Major comments:

      The manuscript is well-written and the figures are well presented. Adequate background information is provided to give the study context and sufficient experimental details are provided to allow replication by other groups. Experiments contain appropriate controls and sufficient replicates to allow appropriate statistical analyses. The authors are careful to acknowledge the differences they observed between the mouse and human system and provide satisfactory potential explanations for these differences. The conclusions they draw are well supported by their data and none of their claims from their data are overstatements. Below are some, which I believe if addressed could improve the paper.

      1. I think the authors overstate the novelty of the concept that the urothelium is an active targetable determinant of infection and treatment outcomes. This is not an entirely new concept since previous studies have examined antimicrobial peptides and other factors from the urothelium.
      2. Depending on the target audience, the Module-Module association analysis could need more introduction. I am not a computational biologist and it was not obviously apparent how Figure 4A is generated and what it actually showing. How specifically does this analysis demonstrate a functional link between lysosomal activity adn immune defense pathways? Without further explanation, it is my opinion that this figure panel is an unnecessary distraction that is not required for any of the conclusions that the group can already draw from the rest of their data.

      Significance

      General assessment: The manuscript has several methodological strengths. These include the use of both mouse and human urothelial models, inclusion of appropriate controls, and sufficient replicates to ensure reproducibility. The statistical methods employed were appropriate. No major methodological weaknesses were identified. The descriptions of methods provide sufficient experimental details to allow the experiments to be reproduced by other labs. The authors did a nice job interpreting their data in light of previous literature. They did not overstate the magnitude or significance of their findings and were careful to acknowledge the limitations in their study design.

      Advance: Moderate technical advance building on prior organoid models. Significant mechanistic advance because OM-89 has been widely used for a long time without detailed understanding of why it works. Moderate conceptual advance that urothelial cells are a targetable determinant of treatment outcomes.

      Audience: I am a basic science researcher in the field of female urogenital tract microbiome and infections. Other researchers studying UTI will certainly be interested in this study. It also may be of interest to people studying other bladder conditions that involve the urothelium (bladder cancer).

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #1

      Evidence, reproducibility and clarity

      In this paper, Tomasek and colleagues describe a series of experiments illuminating the effects of OM-89, a bacterial lysate taken orally for prevention of recurrent UTI, on intracellular dynamics of UPEC, using cell culture and organoid models. Suggestions for improvement and for clarification of the authors' conclusions and relevance to human UTI (and OM-89 use) are offered below.

      Major points:

      1. The data indicate that OM-89 exposure in the organoids enhances lysosomal degradation pathways and (in mBOs) autophagic flux, and the authors conclude this is a mechanism by which UPEC regrowth after antibiotic treatment (modeling rUTI) is inhibited by OM-89. They also show enhanced cellular uptake of fluorescently labeled antibiotics (ampicillin) in organoids - this leads them to conclude (and state in the paper's title) that increased intracellular antibiotic concentration effects increased killing of UPEC and decreased regrowth. These are two separate proposed mechanisms, and especially with regard to the antibiotics, they have not shown that increased intracellular antibiotic concentration actually kills intracellular UPEC in their model - only that regrowth as measured microscopically is less. In total, a mechanistic connection between the observed lysosomal effect and the intracellular antibiotic uptake, and which one is more important for UPEC control in this model, is incomplete. The precise wording of the paper's title should be reconsidered accordingly.
      2. OM-89 is taken orally for rUTI prevention, and some "components" reach the urinary tract (line 81). But it isn't explained how applying OM-89 directly to organoids models how its components may reach the bladder epithelium (from the basolateral side, if the OM-89 is applied outside the organoids) in the whole animal or human. At the least, this limitation should be stated in the Discussion.
      3. In the lysosome studies starting on line 319, the cultured cells are all infected (and either treated with OM-89 or not). What observations regarding number and size of vesicles, etc (all the measures in Fig 6) are evident when cells are treated with OM-89 only? These data should be presented (at least as a supplemental figure) to enable optimal interpretation of the OM-89+UPEC data in Fig 6. As the authors themselves indicate, OM-89 may be having a generalized effect on endocytic and/or autophagic flux by bladder epithelial cells, independent of infection.
      4. With the organoids, beyond the microscopic quantification of UPEC, can CFUs be measured?

      Minor points:

      1. In Fig 1A, the "co-application" horizontal line is under the 7-10 hour window, but the text suggests that the application of antibiotics and OM-89 in this experiment is between 4-7 hours.
      2. How are antibiotics and OM-89 "removed" at the 7-hour mark? This was not detailed in the Methods.
      3. What time point was used for the transcriptomic profiling of organoids? This is not clear from the relevant Methods or Results sections.
      4. In showing that OM-89 "attenuated" the magnitude of inflammatory responses (Fig 2C and S3B), it would be helpful to add a panel showing the comparison of OM89+UPEC to PBS alone - this would be expected to convey activity (red) in the infection-related pathways, but to a lower magnitude than seen in UPEC vs PBS.
      5. Similarly, in the results outlined starting on line 196, it would be helpful to add a panel showing OM89+UPEC vs OM89 alone.
      6. In line 236, what is meant by lysosomal "activation"? A more specific term should be chosen here.
      7. In the Abstract (line 25), the phrase "Using bladder organoids..." is a dangling modifier.

      Typographical and copyediting:

      1. Line 74 should read "For instance..."
      2. Line 76 should read "when combined with antibiotic therapy..."
      3. Line 122 should read "...regrowth following antibiotic treatment" or "regrowth post-antibiotic treatment"
      4. Line 138 should use "regimen" not "regime"
      5. Line 196 delete comma after "Although"
      6. Line 244 fully hyphenate "OM-89-mediated"
      7. Line 374 should read "...significantly enhance antibiotic-mediated killing"

      Significance

      The paper is very well written and though a lot of data are included, the presentation is excellent and helps the reader to follow the story. The paper makes a strong contribution to the UTI pathogenesis field, and the use of mouse and human bladder organoids is innovative in studying intracellular UPEC. My scientific expertise as a reviewer is in UPEC pathogenesis, directly relevant to the content of this paper.

    4. Note: This response was posted by the corresponding author to Review Commons. The content has not been altered except for formatting.

      Learn more at Review Commons


      Reply to the reviewers

      Reviewer #1

      Evidence, reproducibility and clarity:

      In this paper, Tomasek and colleagues describe a series of experiments illuminating the effects of OM-89, a bacterial lysate taken orally for prevention of recurrent UTI, on intracellular dynamics of UPEC, using cell culture and organoid models. Suggestions for improvement and for clarification of the authors' conclusions and relevance to human UTI (and OM-89 use) are offered below.

      Major points:

      1. The data indicate that OM-89 exposure in the organoids enhances lysosomal degradation pathways and (in mBOs) autophagic flux, and the authors conclude this is a mechanism by which UPEC regrowth after antibiotic treatment (modeling rUTI) is inhibited by OM-89. They also show enhanced cellular uptake of fluorescently labeled antibiotics (ampicillin) in organoids - this leads them to conclude (and state in the paper's title) that increased intracellular antibiotic concentration effects increased killing of UPEC and decreased regrowth. These are two separate proposed mechanisms, and especially with regard to the antibiotics, they have not shown that increased intracellular antibiotic concentration actually kills intracellular UPEC in their model - only that regrowth as measured microscopically is less. In total, a mechanistic connection between the observed lysosomal effect and the intracellular antibiotic uptake, and which one is more important for UPEC control in this model, is incomplete. The precise wording of the paper's title should be reconsidered accordingly.

      We agree with the point raised by the reviewer that we did not show a mechanistic connection between the observed lysosomal effect and the intracellular antibiotic uptake. Further experiments dissecting the exact involved mechanistic pathways driving both - either in conjunction or separately - would improve our understanding on how OM-89 leads to its positive effects. In future studies we will focus on dissecting the underlying pathways and determining whether a mechanistic connection exists to explain the observed positive effects of OM-89 between lysosomal degradation and enhanced intracellular antibiotic accumulation.

      Accordingly, we changed the title to "Targeted lysosomal activation in bladder epithelium enhances clearance of intracellular uropathogenic ____Escherichia coli". This revised title avoids implying a direct causal link between increased intracellular antibiotic accumulation and bacterial clearance, while still reflecting the central biological process identified in our study.

      Additionally, we incorporated changes in the introduction, as highlighted in our reply to point number one raised by reviewer number two.

      OM-89 is taken orally for rUTI prevention, and some "components" reach the urinary tract (line 81). But it isn't explained how applying OM-89 directly to organoids models how its components may reach the bladder epithelium (from the basolateral side, if the OM-89 is applied outside the organoids) in the whole animal or human. At the least, this limitation should be stated in the Discussion.

      We thank the reviewer for pointing out this limitation. Although advanced in vitro models help to better mimic the in vivo situation, they still do not fully recapitulate all aspects of drug exposure and delivery observed in vivo. We included the following statement of limitation now in the discussion in line 449-459: "One limitation of our study is that OM-89 was applied directly to epithelial cultures and organoids, whereas in clinical use it is administered orally. Although pharmacokinetic studies have demonstrated systemic distribution and urinary accumulation of OM-89-derived components following oral administration (van Dijk, 1982), our experimental setup does not recapitulate the exact route, kinetics or concentration profiles encountered ____in vivo. Rather, our models were designed to determine whether bladder epithelial cells are capable of responding directly to OM-89-mediated signals and to identify the intracellular pathways involved. Given the documented systemic exposure following oral administration, direct effects on the urothelium are biologically plausible. However, future studies will be required to determine how the epithelial responses identified here integrate with the complex systemic and immune-mediated effects of OM-89 under physiological administration conditions."

      In the lysosome studies starting on line 319, the cultured cells are all infected (and either treated with OM-89 or not). What observations regarding number and size of vesicles, etc (all the measures in Fig 6) are evident when cells are treated with OM-89 only? These data should be presented (at least as a supplemental figure) to enable optimal interpretation of the OM-89+UPEC data in Fig 6. As the authors themselves indicate, OM-89 may be having a generalized effect on endocytic and/or autophagic flux by bladder epithelial cells, independent of infection.

      We thank the reviewer for this suggestion and agree that evaluating OM-89 treatment in the absence of infection provides important context for interpreting the infection-associated phenotypes shown in Figure 6. Our original intention was to focus the main manuscript on the effects of OM-89 during UPEC infection, and we therefore did not include the corresponding uninfected conditions.

      As part of the planned revision, we will include additional supplementary data examining the effects of OM-89 alone in both murine and human bladder epithelial cells. Specifically, we will present analyses of Lamp1-positive lysosomal vesicles, lysosomal acidification (LysoSensor), and Cathepsin L activity under uninfected conditions. These experiments will allow readers to assess the extent to which OM-89 activates epithelial lysosomal pathways independently of infection and will provide important context for interpreting the infection-associated responses presented in the main figures.

      We agree with the reviewer that OM-89 may exert broader effects on epithelial lysosomal pathways beyond the setting of infection, and inclusion of these data will strengthen the interpretation of OM-89 as a direct modulator of epithelial antimicrobial function.

      With the organoids, beyond the microscopic quantification of UPEC, can CFUs be measured?

      We understand the wish of the reviewer to see CFU measurements performed on organoids. However, this imposes strong technical limitations, mainly due to the tedious and technically challenging microinjections, e.g. the exact same amount of organoids would need to be infected by microinjections in both conditions (OM-89 and control) and injections would need to be performed extremely precise with no bacteria spreading into the surrounding extracellular matrix (frequently, organoids would get penetrated with the microneedle all the way, leading to bacteria being not injected into the lumen but rather into the wall of the organoid or even be released on the other side of the organoid) as otherwise also bacteria escaping into the extracellular matrix would be collected upon recovering the organoids from the extracellular matrix domes, strongly affecting the CFU measurements.

      However, using differentiated monolayers of mouse bladder epithelial cells and performing a classic gentamicin protection assay would add an additional layer of information on the purely intracellular bacterial population, whilst overcoming the previously mentioned technical challenges. Therefore, we aim to perform CFU measurements on monolayers with and without OM-89 treatment to support our microscopic quantification and specifically be able to make a statement on reduced intracellular bacterial burden with OM-89 treatment. The CFUs will therefore provide an orthogonal measure of intracellular bacterial burden and complement the microscopy-based quantification during the infection and antibiotic-treatment phases.

      Adding to this point of the reviewer, we wanted to clarify that with the higher-throughput microscopic quantification used in our approach (Thunder widefield microscope at 25x magnification), we cannot distinguish between strictly intracellular or tissue-associated bacteria, hence we used the wording "intra-organoid" in our methods section. We now added this information also into the results section for clarification (line 116): "Hence, the microscopy data represent the total "intra-organoid" bacterial burden at each experimental stage, without distinguishing the exact localization of the bacteria - which can be luminal, intracellular or tissue-associated.". To further reflect this, we stepped back from referring to antibiotic-mediated "killing", but changed the wording to antibiotic-mediated "clearance" or referred to reduced bacterial burden throughout the manuscript.

      __Minor points:____ __

      1. In Fig 1A, the "co-application" horizontal line is under the 7-10 hour window, but the text suggests that the application of antibiotics and OM-89 in this experiment is between 4-7 hours.

      We thank the reviewer for pointing this out. Indeed, in the co-application regime, OM-89 is added at the same timepoint as the antibiotic - meaning straight after monitoring the growth phase at 4h post-infection (pi). We now adapted the horizontal line for the "co-application" treatment in Figure 1A accordingly to represent the time-point of OM-89 addition better. Additionally, we added a line for the antibiotic-treatment in order to further facilitate readability.

      How are antibiotics and OM-89 "removed" at the 7-hour mark? This was not detailed in the Methods.

      Although we had specified this in the methods section at line 603 "For every media exchange (e.g. antibiotic treatment or withdrawal), each well was washed with 9 ml of the respective media before leaving 1 ml in the well.", we realized the positioning was not optimal as we had mentioned this part under the point "Bacterial injection" in "Injection experiments". We therefore now separated this part, together with the lid preparation, from the "Bacterial injection" part and created the new subsection "Lid preparation for media changes" (line 613 onwards).

      What time point was used for the transcriptomic profiling of organoids? This is not clear from the relevant Methods or Results sections.

      As stated in the methods section, RNA for transcriptomic profiling from mBOs was extracted at 4h post-infection (pi) (line 842).

      In showing that OM-89 "attenuated" the magnitude of inflammatory responses (Fig 2C and S3B), it would be helpful to add a panel showing the comparison of OM89+UPEC to PBS alone - this would be expected to convey activity (red) in the infection-related pathways, but to a lower magnitude than seen in UPEC vs PBS.

      We thank the reviewer for this suggestion, as well as comment number 5 below. We comment more on both suggestions below.

      Similarly, in the results outlined starting on line 196, it would be helpful to add a panel showing OM89+UPEC vs OM89 alone.

      We performed the requested, combined GOBP analyses and they confirm that infection-associated pathways remain strongly activated in OM89-treated infected organoids relative to baseline (PBS) controls and relative to OM89-treated uninfected organoids. These results confirm the reviewer's hypotheses and further confirm the results presented in Figure 2C. In fact, induction of genes involved in detrimental effects of UPEC infections are induced at a lower extent when organoids are exposed to OM-89 only.

      However, because the direct comparison between OM89+UPEC and PBS+UPEC already highlights the effect of OM-89 while controlling for the infection status, we believe our original analysis presented in Figure 2C remains the most informative representation of attenuation. Therefore, we will include the new comparison in the supplementary section of the manuscript.

      In line 236, what is meant by lysosomal "activation"? A more specific term should be chosen here.

      We thank the reviewer for this question and aim to increase readability of this section. With lysosomal activation in the first sentence of the mentioned paragraph, we referred to the observed effect of upregulated lysosomal pathways and altered lysosomal vesicles in the previous paragraph. However, to make the connection to the previous paragraph better, and given the comment number two of reviewer number two, we changed the whole first paragraph of this section. Therefore, the first sentence of this paragraph (line 235 onwards) reads now: "To test whether the observed effects on lysosomal pathways could mechanistically, at least in parts, explain OM-89-mediated protection, we first used Genebridge analysis (Li et al, 2019) to examine how the lysosomal gene signature identified in our RNA-seq data relates to host defense programs in the human bladder."

      In the Abstract (line 25), the phrase "Using bladder organoids..." is a dangling modifier.

      We thank the reviewer for pointing this out and changed the sentence accordingly to "In bladder organoids and differentiated epithelial monolayers, OM-89 promotes lysosomal acidification and increases lysosomal protease activity, driving intracellular UPEC toward degradative compartments."

      Typographical and copyediting:

      We thank the reviewer for pointing out the typographical errors below and we corrected them all.

      1. Line 74 should read "For instance..."

      2. Line 76 should read "when combined with antibiotic therapy..."

      As this sentence is to emphasize the already observed protective effects of OM-89, and the two studies mentioned were either performed without or in combination with antibiotics, we changed the sentence to "For instance, rodent infection studies have demonstrated protective effects of OM-89 alone (Bosch et al, 1988; Lee et al, 2006) and in combination with antibiotic therapy (Canton et al, 2025; Bessler et al, 2010), although this observed in vivo protection could not be linked to any major quantitative changes in bladder immune cell infiltration (Canton et al, 2025), leaving the underlying molecular mechanism not fully resolved." for better readability.

      Line 122 should read "...regrowth following antibiotic treatment" or "regrowth post-antibiotic treatment"

      Line 138 should use "regimen" not "regime"

      Line 196 delete comma after "Although"

      Line 244 fully hyphenate "OM-89-mediated"

      Line 374 should read "...significantly enhance antibiotic-mediated killing"

      • *

      __Significance:____ __

      The paper is very well written and though a lot of data are included, the presentation is excellent and helps the reader to follow the story. The paper makes a strong contribution to the UTI pathogenesis field, and the use of mouse and human bladder organoids is innovative in studying intracellular UPEC. My scientific expertise as a reviewer is in UPEC pathogenesis, directly relevant to the content of this paper.


      Reviewer #2


      Evidence, reproducibility and clarity:

      This study examined the effect of OM-89 on UPEC infection, antibiotic clearance, and resurgence in mouse and human organoid models. The goal of the study was to understand the molecular mechanisms by which OM-89 is effective at preventing rUTI in patients.

      Major comments:

      The manuscript is well-written and the figures are well presented. Adequate background information is provided to give the study context and sufficient experimental details are provided to allow replication by other groups. Experiments contain appropriate controls and sufficient replicates to allow appropriate statistical analyses. The authors are careful to acknowledge the differences they observed between the mouse and human system and provide satisfactory potential explanations for these differences. The conclusions they draw are well supported by their data and none of their claims from their data are overstatements. Below are some, which I believe if addressed could improve the paper.

      1. I think the authors overstate the novelty of the concept that the urothelium is an active targetable determinant of infection and treatment outcomes. This is not an entirely new concept since previous studies have examined antimicrobial peptides and other factors from the urothelium.

      We thank the reviewer for this important point and agree that the urothelium has long been recognized as an active participant in host defense through mechanisms such as antimicrobial peptide production, pathogen sensing and regulation of inflammatory responses. We have therefore revised the manuscript to avoid implying that urothelial involvement in infection outcome is itself a novel concept. Instead, we now emphasize the specific advance of our study: the identification of lysosome-centered epithelial activation as a therapeutically targetable mechanism that enhances intracellular bacterial clearance and potentiates antibiotic efficacy.

      In the abstract we changed: "Our findings position the bladder epithelium from a passive barrier to an active, targetable determinant of treatment outcome and suggest host-directed modulation of epithelial antimicrobial pathways as a promising strategy to enhance intracellular bacterial clearance." to "Our findings demonstrate that bladder epithelial antimicrobial pathways can be pharmacologically reinforced to influence treatment outcomes by enhancing intracellular bacterial clearance." in line 30.

      In the introduction we changed: "Together with increased intracellular accumulation of antibiotics across different classes, this leads to improved intracellular killing and reduced bacterial regrowth across diverse UPEC strains." to "Together with increased intracellular accumulation of antibiotics across different classes, this leads to improved intracellular clearance and reduced bacterial regrowth across diverse UPEC strains." in line 91 and "Together, these findings reveal a previously unrecognized epithelial lysosome-centered mechanism by which OM-89 enhances intracellular antibiotic performance and repositions the bladder epithelium from a passive reservoir of infection reactivation to an actively transformable antimicrobial compartment influencing treatment outcomes." to "Together, these findings reveal a previously unrecognized epithelial-centered mechanism by which OM-89 enhances intracellular antibiotic performance and establishes lysosomal activation as a therapeutically targetable component of epithelial host defense against intracellular UPEC." in line 96.

      In the discussion we changed: "Together, these findings provide a mechanistic framework for the long-observed clinical efficacy of OM-89. Our findings reveal that the urothelium itself can be therapeutically targeted to reduce pathogen regrowth by transforming the epithelial barrier from a passive refuge for UPEC into an active defense site." to "Together, these findings provide a mechanistic framework for the long-observed clinical efficacy of OM-89 and identify epithelial lysosomal pathways as a therapeutically targetable component of host defense that can be used to improve intracellular bacterial clearance." in line 398 and "In the face of rising antimicrobial resistance (2024), strengthening epithelial antimicrobial function offers a complementary route to shift the bladder mucosa from a passive niche of bacterial survival and infection reactivation toward an active site of accelerated pathogen clearance." to "In the face of rising antimicrobial resistance (2024), our findings provide a mechanistic rationale for the clinical use of OM-89 and support epithelial lysosomal pathways as a promising target for host-directed therapeutic strategies that enhance intracellular bacterial clearance and improve the efficacy of existing antibiotics." in line 469.

      Depending on the target audience, the Module-Module association analysis could need more introduction. I am not a computational biologist and it was not obviously apparent how Figure 4A is generated and what it actually showing. How specifically does this analysis demonstrate a functional link between lysosomal activity and immune defense pathways? Without further explanation, it is my opinion that this figure panel is an unnecessary distraction that is not required for any of the conclusions that the group can already draw from the rest of their data.

      We thank the reviewer for this constructive critique. We agree that the rationale and interpretation of this analysis were not sufficiently explained in the original manuscript. We have therefore expanded the description of the MMAS approach and clarified how these data support the translational relevance of the lysosomal pathways identified in our experimental models. We also agree that for a broader biological audience, the computational framework and the strategic necessity of Figure 4A required a clearer introduction and stronger justification.

      To address the reviewer's concerns, we have thoroughly revised the text (lines 235-250) to clarify the methodology and emphasize the essential translational value this analysis adds to our study:

      • How the figure is generated and what it shows: We have added explicit language clarifying that we used a computational Module-Module Association Score (MMAS) to evaluate the transcriptional correlation between the lysosomal gene network and functional biological pathways. Rather than relying on a single experimental dataset, this analysis compiles data across eight independent human bladder transcriptomic datasets encompassing over 1,400 clinical samples.
      • Demonstrating the link to immune pathways: We have explicitly named the specific host defense modules highlighted in Figure 4A, namely "Response to molecule of bacterial origin", "cell activation involved in immune response", and "innate immune response" to guide the reader directly to the strong positive correlations shown in the panel.
      • Justifying its inclusion (mouse-to-human translational bridge): While the rest of our data characterizes the cellular mechanics of OM-89 in murine organoids and cell culture, Figure 4A demonstrates that the link between lysosomal activity and bacterial defense is a conserved feature of bladder tissue biology across species. This cross-species alignment (our mouse-data at this stage of the manuscript compared to human-derived data) provides critical clinical justification for targeting epithelial lysosomal pathways as a therapeutic strategy in human patients. The new paragraph reads as follows: "To test whether the observed effects on lysosomal pathways could mechanistically, at least in parts, explain OM-89-mediated protection, we first used Genebridge analysis (Li et al., 2019) to examine how the lysosomal gene signature identified in our RNA-seq data relates to host defense programs in the human bladder. To evaluate the translational relevance of our experimental findings, we used a computational Module-Module Association Score (MMAS) analysis across eight independent human bladder transcriptomic datasets comprising over 1,400 clinical samples. This network-based approach evaluates the transcriptional correlation between the lysosomal gene network and functional biological pathways across diverse human cohorts. Module-Module association analysis performed on these human bladder datasets indicated that the lysosome module has strong positive associations with specific host defense modules, including "response to molecule of bacterial origin", "cell activation involved in immune response", and "innate immune response" (Figure 4A), highlighting a conserved functional link between lysosomal activity and immune defense pathways in the bladder epithelium. Altogether, these positive correlations suggest that lysosomal activation represents a conserved pathway integrated within mucosal immunity across species, rather than an isolated cellular response unique to our experimental models."

      __Significance:____ __

      General assessment: Solid experimental design with appropriate controls. Appropriate statistical rigor. Conclusions justified by the data. Limitations acknowledged. Differences in results between mice and humans acknowledged.

      Advance: Moderate technical advance building on prior organoid models. Significant mechanistic advance because OM-89 has been widely used for a long time without detailed understanding of why it works. Moderate conceptual advance that urothelial cells are a targetable determinant of treatment outcomes.

      Audience: I am a basic science researcher in the field of female urogenital tract microbiome and infections. Other researchers studying UTI will certainly be interested in this study. It also may be of interest to people studying other bladder conditions that involve the urothelium (bladder cancer).

    5. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      This study examined the effect of OM-89 on UPEC infection, antibiotic clearance, and resurgence in mouse and human organoid models. The goal of the study was to understand the molecular mechanisms by which OM-89 is effective at preventing rUTI in patients.

      Major comments:

      The manuscript is well-written and the figures are well presented. Adequate background information is provided to give the study context and sufficient experimental details are provided to allow replication by other groups. Experiments contain appropriate controls and sufficient replicates to allow appropriate statistical analyses. The authors are careful to acknowledge the differences they observed between the mouse and human system and provide satisfactory potential explanations for these differences. The conclusions they draw are well supported by their data and none of their claims from their data are overstatements. Below are some, which I believe if addressed could improve the paper.

      1. I think the authors overstate the novelty of the concept that the urothelium is an active targetable determinant of infection and treatment outcomes. This is not an entirely new concept since previous studies have examined antimicrobial peptides and other factors from the urothelium.
      2. Depending on the target audience, the Module-Module association analysis could need more introduction. I am not a computational biologist and it was not obviously apparent how Figure 4A is generated and what it actually showing. How specifically does this analysis demonstrate a functional link between lysosomal activity adn immune defense pathways? Without further explanation, it is my opinion that this figure panel is an unnecessary distraction that is not required for any of the conclusions that the group can already draw from the rest of their data.

      Significance

      General assessment: The manuscript has several methodological strengths. These include the use of both mouse and human urothelial models, inclusion of appropriate controls, and sufficient replicates to ensure reproducibility. The statistical methods employed were appropriate. No major methodological weaknesses were identified. The descriptions of methods provide sufficient experimental details to allow the experiments to be reproduced by other labs. The authors did a nice job interpreting their data in light of previous literature. They did not overstate the magnitude or significance of their findings and were careful to acknowledge the limitations in their study design.

      Advance: Moderate technical advance building on prior organoid models. Significant mechanistic advance because OM-89 has been widely used for a long time without detailed understanding of why it works. Moderate conceptual advance that urothelial cells are a targetable determinant of treatment outcomes.

      Audience: I am a basic science researcher in the field of female urogenital tract microbiome and infections. Other researchers studying UTI will certainly be interested in this study. It also may be of interest to people studying other bladder conditions that involve the urothelium (bladder cancer).

    6. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #1

      Evidence, reproducibility and clarity

      In this paper, Tomasek and colleagues describe a series of experiments illuminating the effects of OM-89, a bacterial lysate taken orally for prevention of recurrent UTI, on intracellular dynamics of UPEC, using cell culture and organoid models. Suggestions for improvement and for clarification of the authors' conclusions and relevance to human UTI (and OM-89 use) are offered below.

      Major points:

      1. The data indicate that OM-89 exposure in the organoids enhances lysosomal degradation pathways and (in mBOs) autophagic flux, and the authors conclude this is a mechanism by which UPEC regrowth after antibiotic treatment (modeling rUTI) is inhibited by OM-89. They also show enhanced cellular uptake of fluorescently labeled antibiotics (ampicillin) in organoids - this leads them to conclude (and state in the paper's title) that increased intracellular antibiotic concentration effects increased killing of UPEC and decreased regrowth. These are two separate proposed mechanisms, and especially with regard to the antibiotics, they have not shown that increased intracellular antibiotic concentration actually kills intracellular UPEC in their model - only that regrowth as measured microscopically is less. In total, a mechanistic connection between the observed lysosomal effect and the intracellular antibiotic uptake, and which one is more important for UPEC control in this model, is incomplete. The precise wording of the paper's title should be reconsidered accordingly.
      2. OM-89 is taken orally for rUTI prevention, and some "components" reach the urinary tract (line 81). But it isn't explained how applying OM-89 directly to organoids models how its components may reach the bladder epithelium (from the basolateral side, if the OM-89 is applied outside the organoids) in the whole animal or human. At the least, this limitation should be stated in the Discussion.
      3. In the lysosome studies starting on line 319, the cultured cells are all infected (and either treated with OM-89 or not). What observations regarding number and size of vesicles, etc (all the measures in Fig 6) are evident when cells are treated with OM-89 only? These data should be presented (at least as a supplemental figure) to enable optimal interpretation of the OM-89+UPEC data in Fig 6. As the authors themselves indicate, OM-89 may be having a generalized effect on endocytic and/or autophagic flux by bladder epithelial cells, independent of infection.
      4. With the organoids, beyond the microscopic quantification of UPEC, can CFUs be measured?

      Minor points:

      1. In Fig 1A, the "co-application" horizontal line is under the 7-10 hour window, but the text suggests that the application of antibiotics and OM-89 in this experiment is between 4-7 hours.
      2. How are antibiotics and OM-89 "removed" at the 7-hour mark? This was not detailed in the Methods.
      3. What time point was used for the transcriptomic profiling of organoids? This is not clear from the relevant Methods or Results sections.
      4. In showing that OM-89 "attenuated" the magnitude of inflammatory responses (Fig 2C and S3B), it would be helpful to add a panel showing the comparison of OM89+UPEC to PBS alone - this would be expected to convey activity (red) in the infection-related pathways, but to a lower magnitude than seen in UPEC vs PBS.
      5. Similarly, in the results outlined starting on line 196, it would be helpful to add a panel showing OM89+UPEC vs OM89 alone.
      6. In line 236, what is meant by lysosomal "activation"? A more specific term should be chosen here.
      7. In the Abstract (line 25), the phrase "Using bladder organoids..." is a dangling modifier.

      Typographical and copyediting:

      1. Line 74 should read "For instance..."
      2. Line 76 should read "when combined with antibiotic therapy..."
      3. Line 122 should read "...regrowth following antibiotic treatment" or "regrowth post-antibiotic treatment"
      4. Line 138 should use "regimen" not "regime"
      5. Line 196 delete comma after "Although"
      6. Line 244 fully hyphenate "OM-89-mediated"
      7. Line 374 should read "...significantly enhance antibiotic-mediated killing"

      Significance

      The paper is very well written and though a lot of data are included, the presentation is excellent and helps the reader to follow the story. The paper makes a strong contribution to the UTI pathogenesis field, and the use of mouse and human bladder organoids is innovative in studying intracellular UPEC. My scientific expertise as a reviewer is in UPEC pathogenesis, directly relevant to the content of this paper.

    1. Note: This response was posted by the corresponding author to Review Commons. The content has not been altered except for formatting.

      Learn more at Review Commons


      Reply to the reviewers

      Point-by-point response to the reviewers (____blue____)

      Dear Editor,

      Thank you for taking care of our manuscript. We are pleased to see that the reviewers are positive about our manuscript. We have amended our manuscript to address nearly all the reviewer’s comments. See below our point by points answer Although we cannot fully establish the exact function of the serine protease homolog Skanda in the Drosophila immune response, our study that combines both biochemistry and genetic provides important insight on the Toll-PO cascade and its complexity

      With best regards,

      Bruno Lemaitre on the behalf of the authors


      __Review____er #1 (Evidence, reproducibility and clarity (Required)): __

      In the manuscript entitled "The serine protease homolog Skanda modulates Toll-phenoloxidase-mediated immunity in Drosophila," Vasanth et al characterize in detail a previously unstudied component of the insect immune response using first biochemical and then in vivo methods. Using proteins overexpressed and purified from insect cells, the authors provide evidence that Skanda could be a negative regulator of the SP cascade, impacting cleavage of proHayan and proPsh, and consequently Toll pathway and PPO1 activation. This work reaches further by transposing these findings into the D. melanogaster in vivo model. Here, however, the picture becomes more confusing as Skanda at native levels does not appear to regulate either the Toll pathway or the melanization cascade. Only one strong phenotype was identified in that decreased expression of Skanda increased susceptibility to S. aureus infection while increased expression decreased susceptibility. The mechanism for this remains unclear. To their credit, the authors carry out an in-depth analysis to rule out all the obvious possibilities. In the discussion, the authors explore the basis of discrepancies between their biochemical and genetic findings. We would suggest that an additional one to consider is differing roles or behaviors of Skanda in the microenvironments of the local site of injury (where S. aureus may be contained when it is tolerated) and the hemolymph. In summary, this is a valuable analysis of the innate immune component Skanda whose role has become somewhat clearer through these studies, but still remains obscure.

      We thank the reviewer for this general assessment of our article. We agree with his idea that discrepancies between the biochemical and genetic findings arise from differing roles or behaviors of Skanda in the microenvironments of the local site of injury and the hemolymph’. We added the following sentence in the discussion: ‘The presence of Skanda in the hemolymph (Rommelaere et al. 2025) suggests a role in the systemic immune response; however, we cannot exclude that it may be particularly important within the local microenvironments at sites of injury’.

      __Major Comments __ - To assess bimodal distribution of bacterial ds within single flies in Fig 6E, authors should either: increase the sample size to allow for proper statistical assessment of different distributions among genotypes, specifically between w1118 and skanda_d107; or, provide a modelling framework for statistical testing. Otherwise, the present results seem insufficient to conclude that Skanda is playing a role in resistance to S. aureus. We agree with the reviewer that our bacterial count was not enough developed. In the revised version we add a new Figure 6E with two time points 13h and 16h that were chosen before flies start to die from S. aureus. We observe at 13h a significantly higher bacterial count in the Skanda mutants but not at the 16 hours although there is higher proportion of wild-type flies that have clear the bacteria. These observations suggest a role of Skanda to resist, but also tolerate S. aureus. The fast killing induced by systemic injury with a low dose S. aureus made difficult to find a condition that would allow to see a clear load difference. So we have amended our text to highlight that Skanda could also play a role in tolerance.

      We agree with the reviewer but measuring the BLUD with S. aureus is rather challenging as flies die quickly to this bacterium. As mentioned above and following revised figure 6E, we discuss in the revised version that Skanda could be involved in both resistance and tolerance.

      • The error bars on qRT-PCR datasets are large, the data points are not shown so we do not know how many replicates were included in the graphs (Fig 5 B and C, Fig 6C, Fig 7 A and B, and Fig 8B). Bar plots are not the most faithful reproduction of biological datasets, as they can hinder significant information regarding datapoints distribution and variation (Beyond Bar and Line Graphs: Time for a New Data Presentation Paradigm | PLOS Biology). We advise that, particularly in the case of datasets such as qRT-PCR, the final values of fold change are represented with individual dots, with the mean value clearly represented, whether with or without the additional bar graph. Furthermore, no statistical tests were applied to determine significance. Data points should be shown and appropriate statistical tests should be applied. The number of biological replicates should be included in the analysis and the statistical test applied should be noted in the figure legends.

      We have changed the figures related to qRT-PCR to show the individual points and we have added statistics in the revised version.

      • Although there are claims of Skanda conferring resistance to S. aureus infection, only Drs levels are tested. These conclusions could be strengthened by assessing expression levels of additional AMPs.

      In the revised manuscript, we report the expression of BomS1 in wild-type, skanda, and spz mutants following S. aureus infection. As previously observed for Drosomycin, Skanda does not markedly affect BomS1 expression (new Supplementary Figure S3E).

      __Minor Comments __ - Parag. 1: (data not shown) should be removed and if possible AlphaFold prediction of skanda conformation added. Alternatively, remove sentence.

      We have removed (data not shown) and indicated that the information derived from Alphafold.

      • Parg. 3: 1000 mL? why not 1L?

      Corrected.

      • Parag. 5: , in last sentence that should be .

      Corrected.

      • Parag. 6: "a role at the same position..." does not convey the correct messageWe have improved the sentence for ‘Our results indicate that Grass processes Skanda in the Toll–PO SP cascade, consistent with Skanda acting at the same level of the proteolytic cascade as Hayan and Psh’.

      • Figure axes (5D, 5E, 6D, etc...) of melanization assays are wrongly named "% melanisation", with "s"

      We have corrected for “Melanization”.

      • Parag. 21: compound mutants (if correctly interpreted as dataset presented in Fig. 8B) were tested at 6h, 24h and 48h, and not 32h, as written in the text

      Indeed, in figure 8B, we monitored expression at 6, 24 and 32h and not 48h. This has been corrected.

      • Results section "skanda is not mandatory for the activation of the Toll pathway" adopts a literal translation which would probably be better phrased as "is not essential"

      We have corrected accordingly.

      • Discussion parag. 2: "Skanda exhibits..."

      • Discussion last parag: "..., but also underlies..."

      • It has been evidenced that

      This has been corrected.

      Additional comments: - The sentence on page 2 beginning with "Upon binding, these PRRs..." is very long and difficult to follow. This should be rewritten.

      We have split this sentence in two shorter ones for clarity.

      • In many places in the manuscript bacterial "dose" is used in place of bacterial burden. The dose is the amount of a substance or bacterium given to the animal.

      We have changed ‘bacterial dose’ for ‘bacterial burden’ when relevant, and we have kept the term “dose” when we mentioned the OD used to infect flies.

      Page 11: Skanda is described as a placeholder when I think a (competitive) inhibitor would be more appropriate.

      We agree that Skanda functionally resembles a competitive inhibitor, but several key differences set it apart from classical small-molecule inhibitors. First, Skanda is comparable in size and structure to Persephone and Hayan, natural substrates of Grass. Second, Skanda-like SPHs, which have close SP paralogs (e.g., Psh), are common in insects (Cao and Jiang, 2019), indicating that they may constitute a distinct class of negative regulators that warrants its own terminology. Moreover, because amplification in protease cascades typically occurs at the terminal step. Negative regulation by Skanda in an intermediate step could be more stochiometric than the freely reversible inhibition expected for a typical competitive inhibitor. As Skanda’s mechanism remains unclear. the neutral term “placeholder” seems more appropriate than “competitive inhibitor”.

      **Referee cross-commenting**

      I agree with the comments of the other reviewers.

      Reviewer #1 (Significance (Required)):

      Strengths: The authors take a multi-disciplinary biochemical and in vivo approach to understand the molecular interactions among SPs and SPHs and thereby uncover the role of the protein Skanda that might otherwise not have been appreciated. They have made extensive use of novel transgenic fly lines, generated in the context of this study, and have thoroughly tested their specificity and cis-acting potential. These will provide a resource to the field. In addition to the new description of Skanda, these findings strengthen previous knowledge regarding systemic infections with different bacteria (M. luteus, S. aureus) and reproduce the known redundancies of Psh and Hayan modes of action. Moreover, this research is relevant for the expansion of basic knowledge on innate immunity, particularly in the field of insect-pathogen interactions, making use of S. frugiperda cell lines and D. melanogaster adults and larvae. Although not at the focus of this work, the evolutionary conserved nature of these aspects of innate immunity across these two distant species enhance the importance of these findings.

      Weaknesses: Some assays do not include enough biological replicates and others do not have enough information on how many biological replicates were performed. Therefore, the conclusions drawn are difficult to assess. Lack of statistical analysis on the qPCR experiments complicates the interpretation of results.

      We thank the reviewer for his assessment. We have added the number of replicates in the revised version and make visible the variability of our data.

      __Review____er #2 (Evidence, reproducibility and clarity (Required)): __

      Summary In this work the authors identify the SPH skanda as an important player in Drosophila resistance to S. aureus infections independent of Toll and classical melanization. The authors conducted rigorous in vitro assays using recombinant proteins of various SPs in the Drosophila Toll-PO cascade to show that skanda negatively regulates activation cleavage of SPs at the level of and downstream of Psh and hayan, two key SPs that converge on Toll pathway activation with the latter playing a central role in cuticular melanization. In parallel, genetic analysis using mutant flies showed that skanda does not negatively regulate Toll pathway nor melanization. Only skanda over expression in vivo led to a reduction in S. aureus melanization which, in my opinion, is most likely due to the artificial increase in the in vivo concentration of the protein rather than an indication of a potential true function. Altogether this an interesting work as it shows the discrepancies between the biochemical and genetic approaches when it comes to dissecting the insect SP cascades regulating melanization and Toll as highlighted by the authors themselves in the discussion section. All experimental work is well controlled, methodology is robust and results are adequately discussed. I have some comments concerning few experiments and interpretations that in my opinion warrant further discussion.

      We thank the reviewer for the analysis and agree that the result showing than Skanda negatively regulates melanization could be due to over-expression.

      __Major comments: __ 1- It seems that SP48 and Grass can redundantly cleave Skanda although the later cleaves more strongly. (Fig 3B) Can other downstream SPs cleave skanda? Can ModSp alone cleave skanda? (ModSP + skanda lane was absent for Fig 3B). It is important to test these possibilities as the in vitro system may be quite relaxed as to the specificity of these cleavage events and may not reflect what happens in vivo. In fact it has been shown in Anopheles gambiae that SPH can be redundantly cleaved by multiple SP in the protease cascade. Although these are cascades with certain hierarchy, information can still flow in more than one direction along the different branches of these cascades.

      We tested whether ModSP could cleave pro-Skanda and found that it did not (data not shown). This result is consistent with our expectations, as ModSP has a chymoelastase-like specificity and preferentially cleavage after Leu. In contrast, Skanda is cleaved by Grass and cSP48, both of which are trypsin-like proteases.

      At present, there is no straightforward way to assess whether downstream SPs activate pro-Skanda. Obtaining an active downstream SP would require sequential activation of all its upstream enzymes, and it is nearly impossible to completely remove these activating proteases afterward. As a result, it is difficult to distinguish the activity of a downstream SP from that of cSP48 and Grass. We are currently developing a new approach to overcome this limitation.

      2- In Fig 4B and 4C the bands of active forms should be quantified from at least 3 immunoblots for robust results especially in Fig 4C where the differences are minimal.

      As suggested by the reviewer, we quantified the band intensities from four independent blots and presented the data in Fig. 4B and 4C (lower panels).

      3- It is not clear to me why skanda should have a specific role in resisting S. aureus infections despite that S. aureus is not a natural pathogen of Drosophila? Has other Gram-positive and Gram-negative bacteria been tested?

      It is true that S. aureus is unlikely to be a natural pathogen of Drosophila. However, this bacterium has been used in several studies (notably Dudzic 2019) to uncover a specific activity associated with melanization modules that is distinct from cuticular blackening. For this reason, we believe that S. aureus provides a sensitive assay to monitor this particular immune mechanism. We further hypothesize that other bacteria related to S. aureus—possibly members of the Staphylococcus family—may infect Drosophila and could be controlled by Skanda. We chose not to elaborate on this point to avoid overextending the scope of the article.

      4- In Fig 6E more points should be collected for statistical power. It is also better to show these data that are not normally distributed in violin charts or boxes and whiskers which give a better indication as to which quartile the bulk of the data belongs.

      We have addressed this point (see answer to Reviewer 1).

      Minor comments: 5- In Figures 3 and 4, It would be easier to follow the cleavage events if a schematic drawing is provided showing the sequence of activation cleavage events of the tested SPs

      Because the order of the two cleavage events is unclear, we felt it was simpler to include the putative cleavage sites in Fig. 2B and refer interested readers to Fig. S1, Table S1, and Fig. 3 legend.

      6- The fact that PPO1/PPO2 depleted flies exhibit increased Drs expression could be due to increased bacterial proliferation in this mutant background that trigger increased Toll stimulation, rather than a negative feedback mechanism. This increased proliferation is shown in Fig 6E.

      This is a good point. The higher expression of Drs in PO1/PPO2 depleted flies could be associated to higher bacterial load in the mutant, or to negative feedback of the melanization reaction. This higher Toll pathway activation has been further characterized in Liu et al., (Plos pathogen 2025) where it was suggested that it relate to a negative feedback loop between the Toll and the melanization cascade.

      7- In Fig 6E more points should be collected for statistical power. It is also better to show these data that are not normally distributed in violin charts or boxes and whiskers which give a better indication as to which quartile the bulk of the data belongs.

      We have addressed this point. See answer to reviewer 1 for discussion.

      8- A phenotype for skanda in melanization was observed only in over-expression assays which may artificially alter molecular interactions in the cascade.

      We agree with this statement and we have added a comment in the discussion of the revised manuscript about the potential artifactual results due to over-expression.

      9- Page 10 last paragraph "peak expression at 32 hrs or 48 hrs as shown on the figure?"

      This is 32h and has been corrected.

      10- The differences in Drs expression levels in Hayan-pshDef and psh-skandaDef double mutant flies infected with M. luteus and S. aureus is surprising. I wonder whether the observed differences are due to biochemical differences in the microbial surfaces to which these cascades are recruited.

      Drs expression is markedly higher following systemic infection with M. luteus than with S. aureus, consistent with the different bacterial doses used. We deliberately employed a low dose of S. aureus because this condition reveals a pronounced susceptibility in skanda flies. Consequently, direct comparison between these two infection regimes remains challenging.

      11- There are several typos in the manuscript

      We have carefully re-read the manuscript and corrected several typos.

      Reviewer #2 (Significance (Required)):

      The main strength of this work is that it combines biochemistry and genetics in a strong genetic model to characterize the biochemical interactions between SPH and Sp in clip cascades and relate the relevant interactions observed in vitro with potential in vivo functions. This is the first time that such a rigorous combined approach was adopted to the study of these cascades. The results obtained also show the advantages and limitations of each approach. As such i believe this study will be of interest to a broad audience in the field of insect immunity.

      __Review____er #3 (Evidence, reproducibility and clarity (Required)): __

      __Summary: __

      Serine protease cascades are central for activation of immune responses in insects. In Drosophila melanogaster, Toll signaling pathway has been quite extensively studied, and several serine proteases, serpins and serine protease homologs (SPH) with functions in Toll activation have been identified. In this work, the authors characterize a new component of this system, a SPH which they name Skanda. Skanda seems to have multiple roles/points of action, on one hand participating in the regulation of Toll together with the established serine protease in the Toll activation, Psh, and on the other hand controlling the response to a systemic S. aureus infection, via not yet fully specified mechanism.

      __Major comments: __

      Key conclusions made in this work are convincing, and backed up by the data presented. The data and methods are presented in a way that allows reproduction of the experiment. The number of individuals used especially in the infection experiment (20 male flies per a replicate) is on the lower side, but the experiments are adequately replicated and the effects seen are clear.

      While this work contributes to our understanding of the regulatory mechanisms governing Toll signaling, at times the authors' reasoning is difficult to follow. I recognize that this is a complex topic, with multiple upstream branches activating Toll signaling, and the authors do consider various mechanisms that could explain their findings. However, the manuscript would benefit from additional clarification, perhaps through a schematic model illustrating the proposed effects of Skanda, to help readers position Skanda within the broader context of Toll signaling. We have done our best to explain the Toll serine protease and added a figure at the beginning of the manuscript. Since we cannot position Skanda in the Toll-Po cascade yet, we prefer to avoid drawing a model. We believe that this study highlights our ignorance of the complexity of serine protease cascades acting upstream of Spätzle and Melanization.

      Statistical analyses for the Drs expression experiments are lacking.

      The statistical analysis for Drs expression has been added in the revised version.

      __Minor comments: __

      The authors could explain what type of cells the sf9 cells are and why they decided to use them.

      Sf9 cells are an insect ovarian cell line derived from Spodoptera frugiperda and are widely used for baculovirus-mediated expression of eukaryotic proteins. They support proper protein folding, disulfide bond formation, and post-translational processing. This information is now mentioned in the Result section in addition to methods.

      Band intensities could be measured and plotted for the immunoblots. The immunoblot methods should be fully described in the Materials and methods section.

      Thanks for the suggestion. We have done this accordingly and included the results in Fig. 4B and Fig. 4C (lower panels). Brief descriptions of densitometric analyses have been added to the figure legends.

      Protein levels of Skanda in the Skanda mutant could be shown as the mRNA levels remain relatively high (Sup. Fig 3B). If this is not possible, could the authors comment on the remaining expression of Skanda in the Skanda mutants?

      We have added a comment on this point: The skanda mutation is a frameshift mutation that affects the coding sequence. There are still transcripts although not functional. The decreased expression of Skanda in SkandaD107 is probably due to non-sense-mediated RNA decay caused by the frameshift.

      Under the heading "Loss of skanda does not further enhance the cuticular melanization defects caused by the loss of Hayan or psh" the text should refer to figure 5D not 5B.

      We have corrected this mistake in the revised version.

      Figure 6C shows that Drs expression is higher in the Skanda mutant than in controls at 32 h post S. aureus infection (although this has not been statistically tested). The authors don't mention this result in the manuscript, but to me it fits with the idea of Skanda acting as a negative regulator (the effect of which is accumulating and seen only late after infection). Could the authors comment on this? We do not think that the higher expression of Drs in Skanda mutant upon S. aureus systemic infection is due a negative regulation the Toll pathway but rather to higher S. aureus burden. We conclude this because Drs is not higher than the wild-type upon injection of M. luteus and proteases. At this stage, we cannot exclude that there are differences between M. luteus and S. aureus.

      Under the heading "Psh and skanda redundantly regulate Toll signaling", the comparison should likely be between Figures 7A-7B and 5B-C (rather than 5A). When examining the effects of single versus double mutants on Drs expression, the Psh-Skanda double mutant clearly reduces Drs more than the Psh single mutant. However, in the context of microbial proteases, the pattern appears different: there is virtually no difference at 6 hours, while at 48 hours there may be a slight decrease in Drs expression in the double mutant compared to the Psh single mutant, although this difference would likely not reach statistical significance if tested. I don't know what this could mean, but I'd like to hear the authors' take on this. The reviewer is correct and we have revised our manuscript to mention the appropriate figure. Figures 7A-7B and 5B-C.

      The reviewer raised a good point; we believe that the additional effect of Skanda in absence of Psh is less marked upon microbial proteases because Psh already has a strong effect by itself in sensing proteases. In contrast there is higher redundancy between Psh and Hayan upon M. luteus and consequently the double mutant psh, Skanda have a stronger effect.

      __**Referee cross-commenting** __

      I also agree with the comments and points raised by the other reviewers.

      __Review____er #3 (Significance (Required)): __

      Research on the Drosophila immune response has significantly advanced our understanding of (innate) immune responses, both generally and in an evolutionary context. Despite over three decades of study, this work demonstrates that there are aspects of Toll signaling that remain unresolved. The authors identify a novel regulator of the Toll pathway and begin to elucidate its functions. Equally important, their findings underscore the complexity and context-dependency of the regulatory events that shape immune responses.

      We fully agree with the assessment of the reviewer. Our study highlights the complexity (and our ignorance) of this important facet of Drosophila immunity, as mentioned in the last sentence of the discussion.

      My fields of expertise are Drosophila melanogaster, innate immunity, cell-mediated immunity.

      __Review____er #4 (Evidence, reproducibility and clarity (Required)): __

      __Summary __

      In this study, the authors investigate the function of Skanda, a serine protease homolog (SPH) in Drosophila innate immunity using both biochemical and genetical approaches. The reason to focus on this SPH is that it lies at the same locus as two key proteases of Drosophila immune defenses, Hayan and Persephone, all of which are induced by an immune challenge. After having modeled this SPH and shown that the three amino-acid of the serine protease catalytic triad are either mutated or poorly oriented, they report that Skanda may limit the cleavage of proteases downstream of Grass, a key event for their biochemical activation. The study of an isogenized, putatively null, mutant line failed to reveal any impact of skanda on Toll pathway activation nor on melanization, albeit a strong but not moderate overexpression somewhat inhibits the formation of a melanization scab only after "clean" but not septic injury. These results are not in keeping with the biochemical analysis: the mutant would have been expected to display an enhanced immune response. Unexpectedly, skanda mutants are as highly susceptible to a low amount of Staphylococcus aureus injection as flies deleted for the adult-expressed phenoloxidases PPO1 and PPO2, melanization playing a key role in host defense in this infection paradigm. No strong impact on the bacterial load was detected at the sole investigated time point, 24h. Because the analysis of the single skanda mutant did not unambiguously reveal its role in host defense, the authors then studied double or triple mutants of the three protease genes and found a redundant role for Skanda with Persephone for Toll pathway activation after a challenge with a nonpathogenic Gram-positive bacterium or a bacterial protease. In the case of S. aureus infection, a strong induction of the Drosomycin gene, is observed at 48h of infection in the compound mutants, which was not observed with the nonpathogenic challenges. Evidence, reproducibility and clarity

      __Major comments __

      The authors state that "These results are consistent with a role of Skanda in resistance to S. aureus". This conclusion rests on a very fragile experiment that measured the bacterial burden 24h after challenge with a low dose of S. aureus: whereas wild-type control flies exhibit a dual low and high distribution of bacterial loads, skanda flies exhibit only the higher values. However, the bacterial load in skanda appears to be as high in persephone mutant flies that are much less sensitive to S. aureus than skanda flies. This makes it highly unlikely that the high susceptibility of skanda to S. aureus is due solely to resistance. The problem is compounded by the poor description of the experiment: it is not stated anywhere how many times the experiment has been performed, whether pooled data are shown, what each data point represents, pooled or single flies. A fine-grained time course with more biological samples would definitely be needed to convince the reader of a (limited) role in resistance. The authors do not consider the alternative, but not exclusive, possibility that skanda plays also a role in disease tolerance. The determination of the bacterial load upon death of single flies may provide some clues about this alternative function (Duneau et al., eLife, 2017). Another approach might be to determine whether the bacterial supernatant is toxic and whether skanda might protect from this toxicity. As Bomanins play a role in the host defense against S. aureus (this study, but see also Hanson et al., eLife 2019 in which the 55C deficiency susceptibility phenotype was stronger) and given the role of Bomanins in host defense against Gram-positive bacteria or fungal infections both in resistance and disease tolerance (e.g., Clemmons et al. PLoS Pathogens 2015, Lindsay et al., J. Innate Immun, 2018, Xu et al., EMBO Reports 2023, Lou et al., BioRxiv, 2025) and that BomS1 has an optimal Dorsal-related Immune Factor Binding site (Busse et al. EMBO J. , 2007), it may be useful to monitor the expression of several Bom genes in complement to that of the expression of Drosomycin, especially after S. aureus challenge. Furthermore, BomT1 is the only peptide that appears to play a role in resistance against Gram-positive bacteria, namely against E. faecalis. This series of qPCR experiments is rapid to make, provided the authors have kept the cDNAs of their samples.

      To address the reviewer’s comment, we extended the bacterial load analysis of S. aureus in skanda mutants (new figure 6E). Our results support a role for Skanda in both resistance and disease tolerance. This point is now briefly discussed in the Results section, and we have added references highlighting a role of the Toll pathway in disease tolerance. We did not elaborate further, as accurately monitoring S. aureus burden following low-dose infection remains technically challenging given the high pathogenicity of this bacterium.

      In the Discussion, the authors speculate "that Skanda acts at the level of Persephone-Hayan to allow Hayan to activate the Toll pathway. Skanda would skew the activity of the Persephone-Hayan platform to induce Toll signaling and resistance to S. aureus rather than cuticular melanization". This model does not fit with the fact that SPE is only moderately susceptible to S. aureus (Dudzic et al., 2019) and that spätzle mutant flies are either not sensitive at all (Dudzic et al., 2019) or moderately sensitive to it (Hanson et al., eLife, 2019) (see also below). Whether it may apply to host defense against other pathogens remains to be determined. To better understand the function of skanda, considering only S. aureus may be limiting as this bacterium is fundamentally not susceptible to the canonical Toll intracellular signaling cascade (e.g., Bischoff et al, Nat Immunol, 2004, Dudzic et al, Cell Reports, 2019) and to the final part of the Toll-activation proteolytic cascade as discussed above with SPE and Spätzle. The authors appear to have chosen not to display the results they have gained with Enterococcus faecalis (but forgot to remove their mention at two places in the Material and Methods): it would definitely be interesting to know what the outcome of these experiments was and also to investigate the susceptibility and microbial burden of skanda mutants to representative yeast and filamentous fungal pathogens, Aspergillus fumigatus being of special interest since its proliferation is limited through melanization whereas the Toll pathway protects against secreted virulence factors (Xu et al., EMBO Reports, 2023). This series of experiments would likely take some three months and might give additional insights into Skanda function(s).

      We agree with the reviewer that examining the role of Skanda in response to additional bacterial species could further help elucidate its function. However, the most robust phenotype we identified is a strong acute susceptibility to S. aureus, which is dependent on the Psh–Hayan–Skanda axis but independent of the SPE–Spätzle pathway. Because the bacterial strains suggested by the reviewers are primarily controlled by the SPE–Spätzle–Toll pathway, we did not pursue this direction further. However, in the revised version we have added survival analysis with Skanda to Candida albicans and Enterococcus faecalis (new supplement Figure 3F and G). Notably, we also observed an intermediate susceptibility to both Candida albicans and E. faecalis (see below). This indicates that Skanda is not a classical regulator of the Toll-PO cascade such as Grass, ModSP, SPE or Hayan/SPE.

      In general, figure legends are not highly informative and fail to provide key information such as the number of independent experiments, whether the data are representative or pooled, which statistical test was used, e.g., qPCR experiments (the descriptions are available for the analysis of survival and melanization experiments at the end of the Mat. and Meth section). As noted above, critical information is lacking to understand microbial load graphs. It is also difficult to check statements such as: ", while psh[sk1] flies showed a reduced Toll pathway reponse". Indeed, no statistical analysis has been performed to analyze any RTqPCR data. Given the low number of experimental data points, each data point ought to be displayed and not bar graphs, for which in addition the error bars are not defined. The Material and Methods section is incomplete. It does not include a description of all the in vitro synthesized proteins used in this study nor indicate the different tags. The primary and secondary antibodies used for Western blot analysis are not reported, e.g., those that detect cleaved spätzle. This would need to be included in the Table at the beginning of this section.

      In the revised version, we have addressed these points by adding statistical tests to the RT–qPCR analyses, displaying all data points, and improving the microbial load measurement. As discussed in the Material and Methods section, Table S2 provides information for all in vitro synthesized proteins used in this study, including affinity tags and the primary and secondary antibodies. On a more personal note, we first identified the striking susceptibility of Skanda/CG15046 flies more than 10 years ago, and the skanda project subsequently experienced a long period of discontinuation before we decided to reassemble and consolidate the most important findings. Unfortunately, this study did not result in a straightforward narrative with a “happy ending.” Nevertheless, we still consider this work an important step toward a better characterization of this aspect of fly immunity.

      __Minor points __ Introduction: 1. The authors may want to cite Stein, Cho&Stevens, FLY, 2013 when referring to the proteolytic cascade regulating the establishment of dorso-ventral patterning.

      This reference has been added

      The statement "The Toll-PO SP cascade can be DIRECTLY activated at the level of Psh-Hayan, through direct cleavage of the Psh protease bait region by microbial proteases" may be slightly misleading as only subtilisin is able to do this, the other tested proteases producing an inactive cleaved Psh that needed to be secondarily activated by a couple of specific cathepsins (Issa et al., Molecular Cell, 2018).

      Good point. This point has been corrected with the Issa reference added.

      Results 3. The reasoning of the second paragraph is difficult to follow as the reader does not understand how the cleavage sites can be computed. It would be important to state that the recombinant proteins are tagged. It would actually be very helpful to provide a scheme of the various recombinant proteins used in the study as had been done in the Shan et al., Science Advances article.

      We followed the reviewer’s good suggestions, modified the text accordingly, and added Table S2.

      With respect to Western blots, many of the bands are faint, e.g., SPE after the addition of Skanda cannot be detected on a printed version of the figure. It is also difficult to determine whether the reduction in band amount is reproducible as no indications are given in this respect. It is important that the images be quantified in several independent blots so that the observed reduction can be statistically assessed. With respect to PPO1 cleavage, it would be important to also check its cleavage in vivo, which would yield higher confidence on the relevance of in vitro study to the in vivo situation.

      In response to the reviewer’s suggestions, we repeated SDS-PAGE and immunoblot analysis, quantified band intensities, and performed statistical analyses for the samples shown in Fig. 3B and 3C (lower panels). The total number of blots for each representative is 3 to 4. For practical reasons, we are unable to assess PPO1 cleavage in vivo.

      First sentence of the paragraph "skanda mutants are highly susceptible": the authors might also want to cite Hanson et al, eLife 2019.

      We have added the Hanson reference and Ryckebusch et al 2025, which is more appropriate.

      In Dudzic et al., Cell Reports, 2019, the authors did not observe any susceptibility to S. aureus with Hayan[sk3] whereas here they find an intermediate sensitivity phenotype with Hayan[sk6]. Was the former not a null allele of Hayan? With respect to the 55C Bomanin deficiency, Hanson et al., 2019 had reported a stronger phenotype than that shown in Fig. 8A, with some 75% of flies dead within three days. Which study should we trust or does this reflect variations between experiments (hence the question about the representation of survival data: are these pooled data from thre independent experiments; how much variation was there between independent experiments?).

      Both Hayan mutant flies were null. We observed differences along the years with different experimenters; although the main results stand. We also tend to observe a stronger impact of psh than initially reported in response to M. luteus (Figure 5B), although this is consistent with its role in the PRR-Grass-SPE pathway. Considering all the parameters that influence survival experiments (temperature, humidity, time to form the bacterial pellet and sometimes bacterial strains) and possible cryptic infections (Nora infection), we consider these variations as expectable.

      It would be interesting to measure the S. aureus bacterial load upon skanda overexpression to confirm a putative role in resistance.

      This is an interesting suggestion but we did not do it because of the technical challenge that monitoring S. aureus burden represents. We have preferred to focus our attention on monitoring S. aureus in Skanda loss-of-function mutants.

      UAS-skanda: besides Fig. 6B, the authors should also refer the reader to Fig. S4A.

      The link to Fig S4A has been added.

      Genetic dissection of the skanda-psh-hayan gene cluster: the last sentence of the paragraph does not reflect what Fig. S7B is showing: one of the double mutants and the triple mutant displayed a significant intermediate susceptibility to S. aureus.

      This is in fact Ecc15 that we discussed. The reviewer is correct as the triple mutants and hayan,psh double have increased susceptibility to Ecc15.

      Paragraphs Compound mutants are EXTREMELY susceptible to S. aureus. The wording is likely too ...extreme: they do not seem to die much faster than skanda simple mutants, which were HIGHLY susceptible to S. aureus, like PPO1-PPO2 double mutants.

      The reviewer is correct and we have avoided to use the term ‘extremely’ in the revised version (replaced by ‘highly’ or removed).

      Last paragraph: psh mutants should be compared side-by-side with psh-skanda double mutants in the same RTqPCR experiment: it is difficult to judge whether the statement of equivalent Drosomycin expression after S. aureus challenge is true given the low resolution of the figures (Fig. 6C vs. Fig. 7B). Last sentence: it would be more appropriate to mention "host defense" rather than "resistance" since the authors did not check the bacterial burdens of the compound mutants.

      Experiments were done simultaneously on single and double/triple mutant but this represents kinetic with 4 times in 10 different backgrounds! We have preferred to separate the data to simplify the reading. We believe that the reader can compare the data despite display in two different panels. We have changed in all the manuscript host defense instead of resistance as following bacterial counting, we suspect that Skanda may play both in resistance and disease tolerance.

      Fig. 1: the scheme is not up to date and oversimplified. It should take into account the complexity revealed in the Shan et al. Science Advances article.

      We disagree on this point. This schema reflect inference done by genetics. An up-to-date figure is shown in Westlake, Hanson Lemaitre Handbook but would require a broad introduction. In the revised version, we have highlighted that this is simplified model based on genetics.

      Fig. S1: numbering the amino-acids in the sequence would help follow the text from Document S1. What are the residues written in light blue? It may be worth highlighting residue E194. Of note, there is a difference between the sequence for peptide 4 as found in the sequence displayed on Fig. S1: KTDRD YV and the sequence of peptide 4 in Table S1: KTDRE YV; the presence of a potential SNP should be indicated, even though it is not making a major change in terms of charge of the peptide.

      We included an asterisk at every tenth position and a numerical indicator near the end of each line to facilitate counting. Residues highlighted in cyan may represent cleavage sites of cSP48, Grass, or a trypsin-like protease released by Sf9 cells. The peptide (E194R212) appears to undergo cleavage to generate P204LNLPLQP__R212__, which is detected in the secondary MS. The reviewer is correct on peptide 4 that we attribute to a potential SNP. This is now indicated in the legend of Figure S1.

      Document S1: trypsin digestion (just before second call to Fig. S1); should it not be purified proteases instead? The text should be somewhat reworded as it is currently slightly misleading.

      "In lane 8, peptide-1 through -19 were nearly undetectable". Table S1 shows that even though peptides 1, 2, 6, , 7 , and 11 are not expressed to strong enough a level to be displayed Fig. S1 lane 8 given the chosen scale, peptides 1, 2, 6, and 7 are expressed in the same range for slices 8B and 8C, whereas peptide 1 is found with just a two-fold difference in slices 8A and 8C.

      Points taken. To better illustrate the differences in band intensities in the top right panel of Fig. S1, we kept the same scale for bands A and B in line 8 (as well as for bands A-C in the top left and middle panels) and used the second y-axis for band C.

      Fig. S2: the effect of skanda on SP7 cleavage is not detectable when Hayan isoforms are co-incubated. The main text should be modified to take this into account. How do the authors explain that pro-MP1 levels are not different upon co-incubation with Psh or Hayan-PB with or without adding Skanda, even though the active MP1 form is detected only in the absence of Skanda? In contrast, the pro-MP1 band can be detected upon co-incubation with Skanda and Hayan-PA.

      Thanks for the comments. We repeated the experiments and obtained four independent blots for each. After scanning, integrated band densities for all paired bands (i.e., with and with Skanda) were quantified using ImageJ (Fig. S2 and data not shown). In the representative blots, Skanda had little effect on SP7 activation by Hayan-PA (507/527; 96%) or Hayan-PB (15,763/15,828; ~100%), in contrast to Psh (937/7,917; 12%). However, when ratios from all blots were considered, the mean reductions were 56 ± 14% for Psh, 49 ± 19% for Hayan-PA, and 65 ± 18% for Hayan-PB. For MP1, comparison of precursor bands is less reliable because small decreases in precursor intensity are difficult to quantify; therefore, we focused on the MP1 product. MP1 levels were reduced to 58 ± 8% (Psh), 44 ± 3% (Hayan-PA), and 90 ± 30% (Hayan-PB). SPE intensity was reduced to 38 ± 12% (Psh), 43 ± 5% (Hayan-PA), and 23 ± 4% (Hayan-PB). Ser7 intensity was reduced to 9 ± 4% (Psh), 35 ± 1% (Hayan-PA), and 27 ± 13% (Hayan-PB). In general, Skanda suppressed the activation of SP7, SPE, MP1, and Ser7 by Psh, Hayan-PA, or Hayan-PB. We included the information in Fig. S2 legend.

      Fig. S3B, S7A: the three genes of the locus are inducible upon immune challenge. Have any NF-kappaB binding sites been detected at the locus. It might be relevant to repeat the experiment shown in S3B and especially S7A after a challenge with M. luteus. These experiments are definitely not essential.

      We did not look to the presence of NF-kB sites in their promoters but they have been shown to be induced and regulated by the Toll pathway (De Gregorio 2002). We did not extend our manuscript in this direction.

      The mention 'Data not shown" is used twice. Not allReview Commons-affiliated journals accept it.

      These mentions have been removed.

      Reviewer #4 (Significance (Required)): A strength of this work is the dual biochemical and genetic characterization of a SPH, an endeavor that is important to understand further the function of this class of protease-like family of secreted proteins that have been so far imperfectly studied from both perspectives (Kambris et al., CB, 2006, but see Westlake Reproducibility study on BioRxiv, Jin et al. Frontiers Immunol. 2023). Unfortunately, the two approaches fail to provide an integrated view of Skanda's function(s). A weakness is that this study does not unambiguously reveal at this stage what are the functions of Skanda in the host defense against S. aureus, let alone against other pathogens controlled to some extent by the Toll pathway or melanization. The authors have not considered a possible role in disease tolerance to S. aureus. These limitations decrease the conceptual advance of this article.

      In the revised version, we have considered a role of Skanda in resilience. This article will be of interest to investigators working on the innate immunity of insects. This reviewer is an expert in the Drosophila innate immunity field.

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      Referee #4

      Evidence, reproducibility and clarity

      Summary

      In this study, the authors investigate the function of Skanda, a serine protease homolog (SPH) in Drosophila innate immunity using both biochemical and genetical approaches. The reason to focus on this SPH is that it lies at the same locus as two key proteases of Drosophila immune defenses, Hayan and Persephone, all of which are induced by an immune challenge. After having modeled this SPH and shown that the three amino-acid of the serine protease catalytic triad are either mutated or poorly oriented, they report that Skanda may limit the cleavage of proteases downstream of Grass, a key event for their biochemical activation. The study of an isogenized, putatively null, mutant line failed to reveal any impact of skanda on Toll pathway activation nor on melanization, albeit a strong but not moderate overexpression somewhat inhibits the formation of a melanization scab only after "clean" but not septic injury. These results are not in keeping with the biochemical analysis: the mutant would have been expected to display an enhanced immune response. Unexpectedly, skanda mutants are as highly susceptible to a low amount of Staphylococcus aureus injection as flies deleted for the adult-expressed phenoloxidases PPO1 and PPO2, melanization playing a key role in host defense in this infection paradigm. No strong impact on the bacterial load was detected at the sole investigated time point, 24h. Because the analysis of the single skanda mutant did not unambiguously reveal its role in host defense, the authors then studied double or triple mutants of the three protease genes and found a redundant role for Skanda with Persephone for Toll pathway activation after a challenge with a nonpathogenic Gram-positive bacterium or a bacterial protease. In the case of S. aureus infection, a strong induction of the Drosomycin gene, is observed at 48h of infection in the compound mutants, which was not observed with the nonpathogenic challenges. Evidence, reproducibility and clarity

      Major comments

      The authors state that "These results are consistent with a role of Skanda in resistance to S. aureus". This conclusion rests on a very fragile experiment that measured the bacterial burden 24h after challenge with a low dose of S. aureus: whereas wild-type control flies exhibit a dual low and high distribution of bacterial loads, skanda flies exhibit only the higher values. However, the bacterial load in skanda appears to be as high in persephone mutant flies that are much less sensitive to S. aureus than skanda flies. This makes it highly unlikely that the high susceptibility of skanda to S. aureus is due solely to resistance. The problem is compounded by the poor description of the experiment: it is not stated anywhere how many times the experiment has been performed, whether pooled data are shown, what each data point represents, pooled or single flies. A fine-grained time course with more biological samples would definitely be needed to convince the reader of a (limited) role in resistance. The authors do not consider the alternative, but not exclusive, possibility that skanda plays also a role in disease tolerance. The determination of the bacterial load upon death of single flies may provide some clues about this alternative function (Duneau et al., eLife, 2017). Another approach might be to determine whether the bacterial supernatant is toxic and whether skanda might protect from this toxicity. As Bomanins play a role in the host defense against S. aureus (this study, but see also Hanson et al., eLife 2019 in which the 55C deficiency susceptibility phenotype was stronger) and given the role of Bomanins in host defense against Gram-positive bacteria or fungal infections both in resistance and disease tolerance (e.g., Clemmons et al. PLoS Pathogens 2015, Lindsay et al., J. Innate Immun, 2018, Xu et al., EMBO Reports 2023, Lou et al., BioRxiv, 2025) and that BomS1 has an optimal Dorsal-related Immune Factor Binding site (Busse et al. EMBO J. , 2007), it may be useful to monitor the expression of several Bom genes in complement to that of the expression of Drosomycin, especially after S. aureus challenge. Furthermore, BomT1 is the only peptide that appears to play a role in resistance against Gram-positive bacteria, namely against E. faecalis. This series of qPCR experiments is rapid to make, provided the authors have kept the cDNAs of their samples. In the Discussion, the authors speculate "that Skanda acts at the level of Persephone-Hayan to allow Hayan to activate the Toll pathway. Skanda would skew the activity of the Persephone-Hayan platform to induce Toll signaling and resistance to S. aureus rather than cuticular melanization". This model does not fit with the fact that SPE is only moderately susceptible to S. aureus (Dudzic et al., 2019) and that spätzle mutant flies are either not sensitive at all (Dudzic et al., 2019) or moderately sensitive to it (Hanson et al., eLife, 2019) (see also below). Whether it may apply to host defense against other pathogens remains to be determined. To better understand the function of skanda, considering only S. aureus may be limiting as this bacterium is fundamentally not susceptible to the canonical Toll intracellular signaling cascade (e.g., Bischoff et al, Nat Immunol, 2004, Dudzic et al, Cell Reports, 2019) and to the final part of the Toll-activation proteolytic cascade as discussed above with SPE and Spätzle. The authors appear to have chosen not to display the results they have gained with Enterococcus faecalis (but forgot to remove their mention at two places in the Material and Methods): it would definitely be interesting to know what the outcome of these experiments was and also to investigate the susceptibility and microbial burden of skanda mutants to representative yeast and filamentous fungal pathogens, Aspergillus fumigatus being of special interest since its proliferation is limited through melanization whereas the Toll pathway protects against secreted virulence factors (Xu et al., EMBO Reports, 2023). This series of experiments would likely take some three months and might give additional insights into Skanda function(s). In general, figure legends are not highly informative and fail to provide key information such as the number of independent experiments, whether the data are representative or pooled, which statistical test was used, e.g., qPCR experiments (the descriptions are available for the analysis of survival and melanization experiments at the end of the Mat. and Meth section). As noted above, critical information is lacking to understand microbial load graphs. It is also difficult to check statements such as: ", while psh[sk1] flies showed a reduced Toll pathway reponse". Indeed, no statistical analysis has been performed to analyze any RTqPCR data. Given the low number of experimental data points, each data point ought to be displayed and not bar graphs, for which in addition the error bars are not defined. The Material and Methods section is incomplete. It does not include a description of all the in vitro synthesized proteins used in this study nor indicate the different tags. The primary and secondary antibodies used for Western blot analysis are not reported, e.g., those that detect cleaved spätzle. This would need to be included in the Table at the beginning of this section.

      Minor points

      Introduction:

      1. The authors may want to cite Stein, Cho&Stevens, FLY, 2013 when referring to the proteolytic cascade regulating the establishment of dorso-ventral patterning.
      2. The statement "The Toll-PO SP cascade can be DIRECTLY activated at the level of Psh-Hayan, through direct cleavage of the Psh protease bait region by microbial proteases" may be slightly misleading as only subtilisin is able to do this, the other tested proteases producing an inactive cleaved Psh that needed to be secondarily activated by a couple of specific cathepsins (Issa et al., Molecular Cell, 2018). Results
      3. The reasoning of the second paragraph is difficult to follow as the reader does not understand how the cleavage sites can be computed. It would be important to state that the recombinant proteins are tagged. It would actually be very helpful to provide a scheme of the various recombinant proteins used in the study as had been done in the Shan et al., Science Advances article.
      4. With respect to Western blots, many of the bands are faint, e.g., SPE after the addition of Skanda cannot be detected on a printed version of the figure. It is also difficult to determine whether the reduction in band amount is reproducible as no indications are given in this respect. It is important that the images be quantified in several independent blots so that the observed reduction can be statistically assessed. With respect to PPO1 cleavage, it would be important to also check its cleavage in vivo, which would yield higher confidence on the relevance of in vitro study to the in vivo situation.
      5. First sentence of the paragraph "skanda mutants are highly susceptible": the authors might also want to cite Hanson et al, eLife 2019.
      6. In Dudzic et al., Cell Reports, 2019, the authors did not observe any susceptibility to S. aureus with Hayan[sk3] whereas here they find an intermediate sensitivity phenotype with Hayan[sk6]. Was the former not a null allele of Hayan? With respect to the 55C Bomanin deficiency, Hanson et al., 2019 had reported a stronger phenotype than that shown in Fig. 8A, with some 75% of flies dead within three days. Which study should we trust or does this reflect variations between experiments (hence the question about the representation of survival data: are these pooled data from thre independent experiments; how much variation was there between independent experiments?).
      7. It would be interesting to measure the S. aureus bacterial load upon skanda overexpression to confirm a putative role in resistance.
      8. UAS-skanda: besides Fig. 6B, the authors should also refer the reader to Fig. S4A.
      9. Genetic dissection of the skanda-psh-hayan gene cluster: the last sentence of the paragraph does not reflect what Fig. S7B is showing: one of the double mutants and the triple mutant displayed a significant intermediate susceptibility to S. aureus.
      10. Paragraphs Compound mutants are EXTREMELY susceptible to S. aureus. The wording is likely too ...extreme: they do not seem to die much faster than skanda simple mutants, which were HIGHLY susceptible to S. aureus, like PPO1-PPO2 double mutants.
      11. Last paragraph: psh mutants should be compared side-by-side with psh-skanda double mutants in the same RTqPCR experiment: it is difficult to judge whether the statement of equivalent Drosomycin expression after S. aureus challenge is true given the low resolution of the figures (Fig. 6C vs. Fig. 7B). Last sentence: it would be more appropriate to mention "host defense" rather than "resistance" since the authors did not check the bacterial burdens of the compound mutants.
      12. Fig. 1: the scheme is not up to date and oversimplified. It should take into account the complexity revealed in the Shan et al. Science Advances article.
      13. Fig. S1: numbering the amino-acids in the sequence would help follow the text from Document S1. What are the residues written in light blue? It may be worth highlighting residue E 194. Of note, there is a difference between the sequence for peptide 4 as found in the sequence displayed on Fig. S1: KTDRD YV and the sequence of peptide 4 in Table S1: KTDRE YV; the presence of a potential SNP should be indicated, even though it is not making a major change in terms of charge of the peptide.
      14. Document S1: trypsin digestion (just before second call to Fig. S1); should it not be purified proteases instead? The text should be somewhat reworded as it is currently slightly misleading " In lane 8, peptide-1 through -19 were nearly undetectable". Table S1 shows that even though peptides 1, 2, 6, , 7 , and 11 are not expressed to strong enough a level to be displayed Fig. S1 lane 8 given the chosen scale, peptides 1, 2, 6, and 7 are expressed in the same range for slices 8B and 8C, whereas peptide 1 is found with just a two-fold difference in slices 8A and 8C.
      15. Fig. S2: the effect of skanda on SP7 cleavage is not detectable when Hayan isoforms are co-incubated. The main text should be modified to take this into account. How do the authors explain that pro-MP1 levels are not different upon co-incubation with Psh or Hayan-PB with or without adding Skanda, even though the active MP1 form is detected only in the absence of Skanda? In contrast, the pro-MP1 band can be detected upon co-incubation with Skanda and Hayan-PA.
      16. Fig. S3B, S7A: the three genes of the locus are inducible upon immune challenge. Have any NF-kappaB binding sites been detected at the locus. It might be relevant to repeat the experiment shown in S3B and especially S7A after a challenge with M. luteus. These experiments are definitely not essential.
      17. The mention 'Data not shown" is used twice. Not all Review Commons-affiliated journals accept it.

      Significance

      A strength of this work is the dual biochemical and genetic characterization of a SPH, an endeavor that is important to understand further the function of this class of protease-like family of secreted proteins that have been so far imperfectly studied from both perspectives (Kambris et al., CB, 2006, but see Westlake Reproducibility study on BioRxiv, Jin et al. Frontiers Immunol. 2023). Unfortunately, the two approaches fail to provide an integrated view of Skanda's function(s). A weakness is that this study does not unambiguously reveal at this stage what are the functions of Skanda in the host defense against S. aureus, let alone against other pathogens controlled to some extent by the Toll pathway or melanization. The authors have not considered a possible role in disease tolerance to S. aureus. These limitations decrease the conceptual advance of this article.

      This article will be of interest to investigators working on the innate immunity of insects. This reviewer is an expert in the Drosophila innate immunity field.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      Serine protease cascades are central for activation of immune responses in insects. In Drosophila melanogaster, Toll signaling pathway has been quite extensively studied, and several serine proteases, serpins and serine protease homologs (SPH) with functions in Toll activation have been identified. In this work, the authors characterize a new component of this system, a SPH which they name Skanda. Skanda seems to have multiple roles/points of action, on one hand participating in the regulation of Toll together with the established serine protease in the Toll activation, Psh, and on the other hand controlling the response to a systemic S. aureus infection, via not yet fully specified mechanism.

      Major comments:

      Key conclusions made in this work are convincing, and backed up by the data presented. The data and methods are presented in a way that allows reproduction of the experiment. The number of individuals used especially in the infection experiment (20 male flies per a replicate) is on the lower side, but the experiments are adequately replicated and the effects seen are clear.

      While this work contributes to our understanding of the regulatory mechanisms governing Toll signaling, at times the authors' reasoning is difficult to follow. I recognize that this is a complex topic, with multiple upstream branches activating Toll signaling, and the authors do consider various mechanisms that could explain their findings. However, the manuscript would benefit from additional clarification, perhaps through a schematic model illustrating the proposed effects of Skanda, to help readers position Skanda within the broader context of Toll signaling.

      Statistical analyses for the Drs expression experiments are lacking.

      Minor comments:

      The authors could explain what type of cells the sf9 cells are and why they decided to use them.

      Band intensities could be measured and plotted for the immunoblots. The immunoblot methods should be fully described in the Materials and methods section.

      Protein levels of Skanda in the Skanda mutant could be shown as the mRNA levels remain relatively high (Sup. Fig 3B). If this is not possible, could the authors comment on the remaining expression of Skanda in the Skanda mutants?

      Under the heading "Loss of skanda does not further enhance the cuticular melanization defects caused by the loss of Hayan or psh" the text should refer to figure 5D not 5B.

      Figure 6C shows that Drs expression is higher in the Skanda mutant than in controls at 32 h post S. aureus infection (although this has not been statistically tested). The authors don't mention this result in the manuscript, but to me it fits with the idea of Skanda acting as a negative regulator (the effect of which is accumulating and seen only late after infection). Could the authors comment on this?

      Under the heading "Psh and skanda redundantly regulate Toll signaling", the comparison should likely be between Figures 7A-7B and 5B-C (rather than 5A). When examining the effects of single versus double mutants on Drs expression, the Psh-Skanda double mutant clearly reduces Drs more than the Psh single mutant. However, in the context of microbial proteases, the pattern appears different: there is virtually no difference at 6 hours, while at 48 hours there may be a slight decrease in Drs expression in the double mutant compared to the Psh single mutant, although this difference would likely not reach statistical significance if tested. I don't know what this could mean, but I'd like to hear the authors' take on this.

      Referee cross-commenting

      I also agree with the comments and points raised by the other reviewers.

      Significance

      Research on the Drosophila immune response has significantly advanced our understanding of (innate) immune responses, both generally and in an evolutionary context. Despite over three decades of study, this work demonstrates that there are aspects of Toll signaling that remain unresolved. The authors identify a novel regulator of the Toll pathway and begin to elucidate its functions. Equally important, their findings underscore the complexity and context-dependency of the regulatory events that shape immune responses.

      My fields of expertise are Drosophila melanogaster, innate immunity, cell-mediated immunity.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      In this work the authors identify the SPH skanda as an important player in Drosophila resistance to S. aureus infections independent of Toll and classical melanization. The authors conducted rigorous in vitro assays using recombinant proteins of various SPs in the Drosophila Toll-PO cascade to show that skanda negatively regulates activation cleavage of SPs at the level of and downstream of Psh and hayan, two key SPs that converge on Toll pathway activation with the latter playing a central role in cuticular melanization. In parallel, genetic analysis using mutant flies showed that skanda does not negatively regulate Toll pathway nor melanization. Only skanda over expression in vivo led to a reduction in S. aureus melanization which, in my opinion, is most likely due to the artificial increase in the in vivo concentration of the protein rather than an indication of a potential true function. Altogether this an interesting work as it shows the discrepancies between the biochemical and genetic approaches when it comes to dissecting the insect SP cascades regulating melanization and Toll as highlighted by the authors themselves in the discussion section. All experimental work is well controlled, methodology is robust and results are adequately discussed. I have some comments concerning few experiments and interpretations that in my opinion warrant further discussion.

      Major comments:

      1. It seems that SP48 and Grass can redundantly cleave Skanda although the later cleaves more strongly. (Fig 3B) Can other downstream SPs cleave skanda? Can ModSp alone cleave skanda? (ModSP + skanda lane was absent for Fig 3B). It is important to test these possibilities as the in vitro system may be quite relaxed as to the specificity of these cleavage events and may not reflect what happens in vivo. In fact it has been shown in Anopheles gambiae that SPH can be redundantly cleaved by multiple SP in the protease cascade. Although these are cascades with certain hierarchy, information can still flow in more than one direction along the different branches of these cascades.
      2. In Fig 4B and 4C the bands of active forms should be quantified from at least 3 immunoblots for robust results especially in Fig 4C where the differences are minimal.
      3. It is not clear to me why skanda should have a specific role in resisting S. aureus infections despite that S. aureus is not a natural pathogen of Drosophila? Has other Gram-positive and Gram-negative bacteria been tested?
      4. In Fig 6E more points should be collected for statistical power. It is also better to show these data that are not normally distributed in violin charts or boxes and whiskers which give a better indication as to which quartile the bulk of the data belongs.

      Minor comments:

      1. In Figures 3 and 4, It would be easier to follow the cleavage events if a schematic drawing is provided showing the sequence of activation cleavage events of the tested SPs
      2. The fact that PPO1/PPO2 depleted flies exhibit increased Drs expression could be due to increased bacterial proliferation in this mutant background that trigger increased Toll stimulation, rather than a negative feedback mechanism. This increased proliferation is shown in Fig 6E.
      3. In Fig 6E more points should be collected for statistical power. It is also better to show these data that are not normally distributed in violin charts or boxes and whiskers which give a better indication as to which quartile the bulk of the data belongs.
      4. A phenotype for skanda in melanization was observed only in over-expression assays which may artificially alter molecular interactions in the cascade.
      5. Page 10 last paragraph "peak expression at 32 hrs or 48 hrs as shown on the figure?"
      6. The differences in Drs expression levels in Hayan-pshDef and psh-skandaDef double mutant flies infected with M. luteus and S. aureus is surprising. I wonder whether the observed differences are due to biochemical differences in the microbial surfaces to which these cascades are recruited.
      7. There are several typos in the manuscript

      Significance

      The main strength of this work is that it combines biochemistry and genetics in a strong genetic model to characterize the biochemical interactions between SPH and Sp in clip cascades and relate the relevant interactions observed in vitro with potential in vivo functions. This is the first time that such a rigorous combined approach was adopted to the study of these cascades. The results obtained also show the advantages and limitations of each approach. As such i believe this study will be of interest to a broad audience in the field of insect immunity.

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      Referee #1

      Evidence, reproducibility and clarity

      In the manuscript entitled "The serine protease homolog Skanda modulates Toll-phenoloxidase-mediated immunity in Drosophila," Vasanth et al characterize in detail a previously unstudied component of the insect immune response using first biochemical and then in vivo methods. Using proteins overexpressed and purified from insect cells, the authors provide evidence that Skanda could be a negative regulator of the SP cascade, impacting cleavage of proHayan and proPsh, and consequently Toll pathway and PPO1 activation. This work reaches further by transposing these findings into the D. melanogaster in vivo model. Here, however, the picture becomes more confusing as Skanda at native levels does not appear to regulate either the Toll pathway or the melanization cascade. Only one strong phenotype was identified in that decreased expression of Skanda increased susceptibility to S. aureus infection while increased expression decreased susceptibility. The mechanism for this remains unclear. To their credit, the authors carry out an in-depth analysis to rule out all the obvious possibilities. In the discussion, the authors explore the basis of discrepancies between their biochemical and genetic findings. We would suggest that an additional one to consider is differing roles or behaviors of Skanda in the microenvironments of the local site of injury (where S. aureus may be contained when it is tolerated) and the hemolymph. In summary, this is a valuable analysis of the innate immune component Skanda whose role has become somewhat clearer through these studies, but still remains obscure.

      Major Comments

      • To assess bimodal distribution of bacterial loads within single flies in Fig 6E, authors should either: increase the sample size to allow for proper statistical assessment of different distributions among genotypes, specifically between w1118 and skanda_d107; or, provide a modelling framework for statistical testing. Otherwise, the present results seem insufficient to conclude that Skanda is playing a role in resistance to S. aureus.
      • Another way to assess a role for tolerance in the Skanda mutant would be to measure BLUDs (https://doi.org/10.7554/eLife.28298 ) and/or transcription of CrebA (https://doi.org/10.1371/journal.ppat.1006847).
      • The error bars on qRT-PCR datasets are large, the data points are not shown so we do not know how many replicates were included in the graphs (Fig 5 B and C, Fig 6C, Fig 7 A and B, and Fig 8B). Bar plots are not the most faithful reproduction of biological datasets, as they can hinder significant information regarding datapoints distribution and variation (Beyond Bar and Line Graphs: Time for a New Data Presentation Paradigm | PLOS Biology). We advise that, particularly in the case of datasets such as qRT-PCR, the final values of fold change are represented with individual dots, with the mean value clearly represented, whether with or without the additional bar graph. Furthermore, no statistical tests were applied to determine significance. Data points should be shown and appropriate statistical tests should be applied. The number of biological replicates should be included in the analysis and the statistical test applied should be noted in the figure legends.
      • Although there are claims of Skanda conferring resistance to S. aureus infection, only Drs levels are tested. These conclusions could be strengthened by assessing expression levels of additional AMPs.

      Minor Comments

      • Parag. 1: (data not shown) should be removed and if possible AlphaFold prediction of skanda conformation added. Alternatively, remove sentence.
      • Parg. 3: 1000 mL? why not 1L?
      • Parag. 5: , in last sentence that should be .
      • Parag. 6: "a role at the same position..." does not convey the correct message< replace with equivalent?
      • Figure axes (5D, 5E, 6D, etc...) of melanization assays are wrongly named "% melanisation", with "s"
      • Parag. 21: compound mutants (if correctly interpreted as dataset presented in Fig. 8B) were tested at 6h, 24h and 48h, and not 32h, as written in the text
      • Results section "skanda is not mandatory for the activation of the Toll pathway" adopts a literal translation which would probably be better phrased as "is not essential"
      • Discussion parag. 2: "Skanda exhibits..."
      • Discussion last parag: "..., but also underlies..."
      • It has been evidenced that

      Additional comments:

      • The sentence on page 2 beginning with "Upon binding, these PRRs..." is very long and difficult to follow. This should be rewritten.
      • In many places in the manuscript bacterial "dose" is used in place of bacterial burden. The dose is the amount of a substance or bacterium given to the animal.
      • Page 11: Skanda is described as a placeholder when I think a (competitive) inhibitor would be more appropriate.

      Referee cross-commenting

      I agree with the comments of the other reviewers.

      Significance

      Strengths: The authors take a multi-disciplinary biochemical and in vivo approach to understand the molecular interactions among SPs and SPHs and thereby uncover the role of the protein Skanda that might otherwise not have been appreciated. They have made extensive use of novel transgenic fly lines, generated in the context of this study, and have thoroughly tested their specificity and cis-acting potential. These will provide a resource to the field. In addition to the new description of Skanda, these findings strengthen previous knowledge regarding systemic infections with different bacteria (M. luteus, S. aureus) and reproduce the known redundancies of Psh and Hayan modes of action. Moreover, this research is relevant for the expansion of basic knowledge on innate immunity, particularly in the field of insect-pathogen interactions, making use of S. frugiperda cell lines and D. melanogaster adults and larvae. Although not at the focus of this work, the evolutionary conserved nature of these aspects of innate immunity across these two distant species enhance the importance of these findings.

      Weaknesses: Some assays do not include enough biological replicates and others do not have enough information on how many biological replicates were performed. Therefore, the conclusions drawn are difficult to assess. Lack of statistical analysis on the qPCR experiments complicates the interpretation of results.

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      Reply to the reviewers

      We thank the reviewers for their insightful comments.Please find below a point-by-point response.

      • As the authors acknowledge in the section at the end of the discussion (Limitations of this study) it is not established that LIN-15A has a cell-autonomous function in Y-to-PDA transdifferentiation. Given that LIN-15A has a cell non-autonomous function in vulval development (Herman and Hedgecock, 1990) it is possible that its function here could also be. The authors have used an egl-5 promoter to rescue lin-15A through expression in rectal cells; however, all these cells are in a neighborhood. The lack of a promoter that is specfic for Y has impeded answering this question (a standard genetic mosaic analysis would be problematic because of the incomplete penetrance of the mutation). Although this issue is addressed in the section at the end of the Discussion, I think most readers would like to see this acknowledged earlier in the presentation, perhaps after describing the egl-5 rescue experiment.

      We thank the reviewer for this comment and agree that our data do not formally demonstrate a Y-cell autonomous role for LIN-15A during Y-to-PDA transdifferentiation, as we discussed in the manuscript. As suggested, we have modified the Results section immediately after the egl-5 rescue experiment to explicitly acknowledge this limitation early-on (see p8, l168-170) and retained the discussion in the "Limitations of the study" section.

      • The experiment shown in Figure S1B is unconvincing. To show that they are detecting a LIN-15A-LIN-56 heterodimer, the authors need to show that antibody tags to both proteins detect the band. Mass spectrometry or biochemical purifications would also be helpful. As it is, they show the protein(s) detected depend genetically on lin-56 and lin-15A. It was also unclear what the other bands were in the mutant backgrounds

      We agree that the experiment shown in Figure S1B does not provide sufficient evidence to conclusively demonstrate the existence of a LIN-15A-LIN-56 heterodimer. While the detected species depend genetically on both lin-15A and lin-56, we agree that additional controls, such as detection through reciprocal tagging, biochemical purification, or mass spectrometry, would be required to firmly establish the molecular nature of the complex and to interpret the additional bands observed in the mutant backgrounds. As this experiment is not essential to the conclusions of the manuscript, we have removed Figure S1B and the associated statements from the revised version.

      • Lines 207-212. The authors are making an argument that LIN-15A and LIN-56 function as "Licensers" not "Drivers" because they are not strictly required but appear to facilitate the process. Could it be that LIN-15A and LIN-56 function as "Drivers" but that in their absence the fidelity of the process is compromise? There are many ways that genetic redundancy can be manifested at biochemical levels and the concern is that there are other interpretations of the data. In this regard, the authors should consider rewriting the Abstract to focus on the genetic results underpinning the work. The current version or the Abstract focuses on an interpretation of the data, not the data itself.

      We thank the reviewer for this thoughtful comment. We agree that the Driver/Licenser terminology represents an interpretation of the genetic data and that additional activities acting alongside LIN-15A may exist: lin-15A alleles used in this study correspond to null alleles - that is total loss of lin-15A activity - and approximately half of the animals still successfully undergo Y-to-PDA transdifferentiation in these null mutants. Thus, lin-15A activity is either not strictly required to facilitate the initiation of the process (e.g., threshold model). Or this may point to other factors (than lin-56) able to somewhat compensate for lin-15A absence and that remain to be identified. In line with this interpretation, while we retrieved several alleles for some of the genes identified in our forward genetic screen (in which lin-15A was identified), that screen may not have been saturated. Note that both these hypotheses are compatible with a role for LIN-15A as a licenser of the initiation of the process.

      Importantly, our distinction between "Drivers" and "Licensers" is not solely based on the incomplete penetrance of lin-15A and lin-56 null mutants. First, the distinction reflects the different biological roles inferred from our genetic analyses. The previously characterized factors CEH-6, SOX-2, SEM-4, EGL-27, EGL-5 and HLH-16 are conserved plasticity factors that promote the initiation of transdifferentiation. Their loss results in a complete, or near-complete, failure of Y-to-PDA initiation, and they act within a common plasticity-promoting network. By contrast, LIN-15A and LIN-56 define a genetically distinct pathway. They are neither upstream nor downstream of the Driver cassette, and display additive interactions with partial Driver mutants. Second, loss of LIN-15A does not affect the fidelity or outcome of transdifferentiation. In all defective animals examined, the Y cell retains its normal position, morphology and rectal markers, indicating a failure to initiate the process rather than the production of an aberrant cell type. Third, the fact that a core Driver set is involved in different transdifferentiation events (ie Y-to-PDA and K-to-DVB) but not lin-15A or lin-56 further argues against LIN-15A acting as a Driver. And finally, and most importantly, lin-15A and lin-56 antagonize SynMuvB chromatin regulators known to safeguard differentiated cell identities, while the Drivers do not. In fact, the transdifferentiation process is mostly restored in some lin-15A; SynMuvB double null mutants, suggesting that LIN-15A main function is to block these genes activities. We therefore favor a model in which the Drivers cassette triggers transdifferentiation, whereas LIN-15A and LIN-56 facilitate the process by alleviating inhibitory constraints imposed by identity-safeguarding mechanisms. We have reformulated this in the manuscript in order to make it clearer and also clarified how we define Drivers and Licencers activitities (see p10, l211-217; p13, l283-289 and p14 l312-315). We have further reformulated the abstract to integrate the reviewer's comments.

      Minor Points

      __ 1. Line 279. The authors state that "LIN-15A becomes dispensable when member of the SynMuvB factors are absent." This statement is not completely accurate as the suppression is incomplete.__

      • Addressed, the statement has been reworded in the revised version (see p13, l285-286)

      2. Line 294. The number in Tagble S1 is 58.8% not 65%

      • Addressed, thank you for spotting this, Table S1 was correct, and the typo in the Results section was corrected (see p15, l319).

      3__. Lines 300-301. I couldn't find the data for lin-40. __

      __- __The data can be found in Fig. 3Bii (which we have more clearly indicated in the text) and SI table 1.

      __. Line 363. Should be "represses cell cycle genes." __

      - Addressed

      __5. Line 862. AJM-1 is not a tight junction component. AJM-1 is best described as a component of apical junctions. __

      __- __Absolutely ! Addressed

      Reviewer 2

      • The conclusions derived from the presented data are generally comprehensible but should be phrased more carefully to grant full legitimacy. The reason is that the central mechanistic claim that LIN-15A licenses Td by antagonizing most of the SynMuvBs chromatin factors, including DREAM, rests on whole-animal ChIP-seq that cannot resolve the Y cell. The authors acknowledge that "it was not technically feasible to purify sufficient Y cells for analysis" and therefore use synchronized unstarved L1 whole-animal lysates. This is certainly legitimate, but demands more tact when using such a conclusion as the headline claim.

      We thank the reviewer for this important comment and agree that the mechanistic conclusions drawn from the ChIP-seq data should be presented more cautiously. As noted by the referee and in the manuscript, it was not technically feasible to isolate sufficient Y cells for chromatin profiling and therefore all ChIP-seq experiments were performed on synchronized whole-animal L1 populations. We agree that these experiments cannot directly establish the mechanism operating in the Y cell. Rather, our genetic analyses demonstrate that LIN-15A antagonizes identity-safeguarding SynMuvB factors during Y-to-PDA transdifferentiation. The ChIP-seq data provide an additional and independent line of evidence suggesting that this antagonism may involve modulation of DREAM chromatin occupancy. We have rephrased to state this more clearly. We thus have revised the Abstract (see p2, l7), Introduction (p6, L110-112), Results (see p18-19, l405-420) and Discussion (see p23-24, l523-542 and p25 l566-575) to more clearly separate the conclusions supported by the genetic analyses from the mechanistic interpretation suggested by the ChIP-seq data. We further clarify that the relevance of this mechanism to the Y cell remains a hypothesis consistent with, but not directly demonstrated by, the available data.

      • Also, in the context of the ChIP-Seq experiments, it is understandable that it could not be conducted in a cell-specific manner, but two duplicates in some ChIP-Seq experiments (as stated in the material and methods) is below standard.

      We thank the reviewer for this comment and agree that two biological replicates represent the lower end of what is generally desirable for ChIP-seq analyses. To clarify, more biological samples were initially generated than are represented in the final analysis. In total, five independent biological preparations were performed for each genotype. However, the experimental design imposed substantial technical constraints. Because the experiments required tightly synchronized fed L1 populations (ie, not using a starvation step), standard synchronization procedures could not be used and animals instead had to be collected through successive hatch pulses, resulting in considerably lower yields. Combined with the mutant backgrounds analyzed, this led to variable ChIP-seq quality across preparations. To ensure robustness, we restricted the final analyses to datasets that passed all predefined quality-control criteria. As a result, some conditions were ultimately represented by only two high-quality biological replicates. We agree that this limitation should be made more explicit and have added this information in the Materials and Methods section (p35 l774-779). Despite the reduced number of replicates retained for some conditions, the genome-wide binding patterns observed for LIN-15B and LIN-35 in wild-type animals closely recapitulated those reported previously by the Ahringer laboratory (Gal et al., 2022; SI table 2), supporting the overall robustness and biological validity of the datasets used in this study. More generally, we have also tempered the interpretation of the ChIP-seq experiments throughout the manuscript. We view these data as supportive evidence consistent with a chromatin-level mechanism, rather than as definitive mechanistic proof, and have revised the text to reflect this more clearly.

      • Regarding the genetic interactions with met-2: as MET-2 works in concert with other SET domain proteins, such as SET-25, and also HPL-2, is there a possibility they may be implicated?

      We also considered the possibility that the interaction observed with MET-2 could reflect a broader involvement of the H3K9 methylation machinery, given the well-established functional relationships between MET-2 and other SET domain proteins. To address this possibility, we tested whether SET-25 and SET-32 losses suppressed the lin-15A phenotype. In contrast to met-2 loss-of-function, neither set-25 nor set-32 mutations modified the transdifferentiation defects observed in lin-15A mutants. These observations suggest that the interaction is not a general property of all MET-2-associated SET domain proteins and may instead reflect a more specific role for MET-2 in this context, although we have not tested triple mutant combinations, such as met-2; set-25; lin-15A or met-2; set-32; lin-15A, and therefore cannot exclude additional contributions from these factors. However, based on the available genetic evidence, our data support a model in which the phenotype is more closely linked to the SynMuvB-centered identity-safeguarding machinery than to the canonical MET-2/SET pathways. We now mention these negative results p14, l290-295 and in the discussion (p22, l510-511) of the revised manuscript. HPL-2 itself was tested alongside the other SynMuvBs, as previously reported to be a SynMuvB (Fig. 4Ci). Loss of HPL-2 had the same effect than loss of the other SynMuvBs. Together these data further suggest that the canonical SynMuvB machinery is at play, including MET-2, but not a generic requirement for all H3K9 methyltransferases, and instead points toward a more specific role of MET-2 within the SynMuvB.

      • The fact that Y-to-PDA in males (which involves a cell division) shows the same lin-15A dependence as in hermaphrodites is informative and a bit underplayed. Since this argues against a cell-cycle-coupled mechanism (an important aspect of the reprogramming field) for LIN-15A, it is worth elaborating on this in the discussion.

      We thank the reviewer for this insightful comment and agree that this result deserves further discussion. One of our initial hypotheses was indeed that LIN-15A might be specifically required in transdifferentiation events that occur without a cell division. Cell division and DNA replication have long been proposed to facilitate cellular reprogramming by promoting the dilution or resetting of identity-safeguarding mechanisms. In this context, it was conceivable that LIN-15A and LIN-56 might compensate for the absence of such a process during hermaphrodite Y-to-PDA transdifferentiation. However, our data do not support this model. We found that LIN-15A and LIN-56 are similarly required for Y-to-PDA transdifferentiation in males, despite the fact that this event occurs through a cell division. Conversely, neither factor is required for the K-to-DVB transdifferentiation, which also occurs in the rectum at a similar developmental stage and likewise involves a cell division. Together, these observations argue that the requirement for LIN-15A is not determined by the presence or absence of cell division. Rather, they suggest that the Licensers activity is context-dependent and linked to specific cellular identities. We agree that this point also strengthens the notion that Licensers are distinct from Driver factors, which function in both Y-to-PDA and K-to-DVB transdifferentiation. We have therefore modified the discussion (see p20 l441-443 and l455-480).

      Minor: __ - in the legend of Figure 1 and other places, it should be "Fisher's exact" instead of "Fisher exact" - line 31; exhibits instead of exhibit - line 85: results instead of result - line 228: involvement instead of involvment - line 293: "of missing" in loss of lin-36 had no effect while loss ... lin-53 further - lines 297 - 299: check sentence; reads not correct - line 395: "with an increase" - line 484: "with regard"__

      • All points were all addressed in the revised version.

        Reviewer 3

      Based on the observation that LIN-15A does not affect SynMuvB expression in Y (figure S4), the authors conclude that antagonism of the SynMuvBs by LIN-15A is not likely mediated by a negative control of their expression, but rather by impacting their activity. However, as suggested by the authors, antagonistic functions on the same targe genes is also a possibility. The classical approach to test this would be through expression profiling. I understand that RNA-seq on single Y cells cannot be carried out for technical reasons and that bulk RNA-seq would not be informative. Importantly, the same reasoning applies to the ChIP-seq data that is presented in support for common regulatory functions of a subset of synMuvs and LIN-15A (Figure 6 and S6), which was obtained from whole animals. The relevance of these results to the Y to PDA Td process is therefore extremely limited, as the claim that LIN-15A restricts lin-35/DREAM binding on a subset of target genes is based on a reported decrease in DREAM binding in lin-15 mutants in bulk chromatin. This is especially true as both DREAM and LIN-15A are widely expressed proteins.

      We agree with the general limitation highlighted here. As the reviewer notes, neither expression profiling nor chromatin profiling can currently be performed specifically in the Y cell due to the extremely small number of cells involved and the lack of suitable purification strategies. Consequently, the ChIP-seq experiments were performed on synchronized - and fed - whole-animal L1 populations. These data do not directly establish the mechanism operating during Y-to-PDA transdifferentiation. Rather, our conclusions are based on two distinct observations. First, the genetic analyses demonstrate an antagonistic relationship between LIN-15A and multiple SynMuvB factors during transdifferentiation. Second, the ChIP-seq experiments provide independent evidence that LIN-15A can influence DREAM chromatin occupancy at the organismal level. We interpreted these observations together as supporting a model in which the genetic antagonism may involve modulation of SynMuvB/DREAM chromatin activity. We agree, however, that the ChIP-seq data do not demonstrate that these chromatin changes occur in the Y cell itself, nor do they identify the relevant target genes involved in Y-to-PDA transdifferentiation. We have therefore revised the manuscript to more clearly distinguish between the conclusions supported directly by the genetic analyses and the mechanistic interpretation suggested by the ChIP-seq experiments. Throughout the revised version, and in the discussion in particular, we present the chromatin-level model as a hypothesis consistent with the available data rather than as a demonstrated mechanism operating in Y (see p2, l7 ; p6, l110-112 ; p18-19, l405-420 ; p23-24, l523-542 and p25 l566-575).

      In addition there are specific issues with Figure 6, which is mislabeled: upregulated and downregulated applies to gene expression, while the numbers refer to binding peaks. Why are some numbers in red (not mentioned in the legend). An example of the corresponding genome browser tracks should be shown in supplementary. Was a spike-in used to normalize data?

      We thank the reviewer for these helpful suggestions. We agree that the terminology "upregulated" and "downregulated" is potentially confusing in the context of ChIP-seq peaks. In the revised manuscript, we have replaced these terms with "up-bound" and "down-bound" in Figure 6. Regarding the red numbers, these were originally highlighted to emphasise the relatively small number of peaks showing decreased occupancy in lin-15A mutants compared to the other genotypes analyzed. However, as this information was not explained in the legend and may be confusing to readers, we have removed the color coding in the revised figure. Following the reviewer's suggestion, we have also added representative genome browser tracks in the Figure S6E to illustrate the binding changes described in Figure 6. No exogenous spike-in controls were used in these experiments. The ChIP-seq workflow was intentionally designed to closely follow that used by Gal et al. (2022), to allow direct comparison with the published LIN-15B and LIN-35 datasets. However, several observations suggest that the patterns reported here are unlikely to result from normalization artifacts alone. First, the genome-wide binding profiles obtained for LIN-15B and LIN-35 in wild-type animals closely recapitulate those reported previously, providing an independent validation of the overall quality of the datasets. In addition, the different mutant backgrounds exhibit distinct peak gain/loss profiles rather than a common directional shift that would be expected from a systematic technical bias. Nevertheless, we acknowledge the absence of spike-in controls as a limitation of the dataset and have clarified this point in the revised manuscript in the Material and Methods section (see p36 l84-805).

      Overall the discussion is highly speculative and could be shortened and refocused on the actual findings reported. For example, the fact that GO terms associated LIN-15B targets are associated with membrane processes (mentioned above) is not sufficient to speculate that LIN-15A could increase the delaminating capacities of Y by alleviating SynMuvB repression of membrane process genes.

      Our intention was to discuss possible mechanisms that could connect the observed genetic interactions to the cellular events underlying Y-to-PDA transdifferentiation. We fully agree that some of these interpretations, such as the impact of the DREAM/LIN-15A antagonisms on membrane remodeling, are purely speculative in nature. We have removed the following sentence : "In brief, the role of the Licensers would be to provide a favorable chromatin context for cellular processes that favor/install a plastic state, possibly through the modulation of membrane processes as suggested by our ChIP-seq analyses (Fig. S6). » and changed it to "In this framework, Td Licensers would facilitate transdifferentiation by alleviating identity-safeguarding chromatin states, thereby creating a permissive context for the Drivers to execute the Td program. », and have removed the paragraph describing Y delamination. More generally, we have substantially shortened and refocused the Discussion section to answer the referee's comment.

      The classical definition of a licensing factor is a protein (or complex) that allows the start of DNA replication from a replication origin. In the field of reprogramming, the term "licenser" has been applied to pioneer factors which 'license' transcriptional reprogramming by accessing chromatin to initiate a series of events, including binding of additional, non-pioneer transcription factors and additional chromatin regulators. Here the authors apply the term 'Licensers' to LIN-15A and LIN-56 as factors that facilitate the Td process. This may lead to confusion (and implications) as to what these factors are actually doing.

      We thank the reviewer for raising this point. We agree that the term "licensing" has been used in several biological contexts, including DNA replication and, more recently, cellular reprogramming, where it is often associated with pioneer factors that initiate chromatin remodeling and transcriptional changes. However, our use of the term "Licenser" is intended to describe a distinct functional concept emerging from the genetic analyses presented here. We introduced this terminology to distinguish a class of factors that facilitate transdifferentiation by alleviating identity-safeguarding mechanisms from the previously identified "Driver" factors that actively promote the cell-fate transition itself. In this framework, LIN-15A and LIN-56 are not proposed to act as pioneer factors or direct initiators of transcriptional reprogramming. Rather, the genetic data support a role in creating a permissive context for transdifferentiation by antagonizing mechanisms that oppose cell-fate change. We agree, however, that this distinction was not sufficiently defined in the original manuscript and may lead to confusion. We have therefore revised the Results and Discussion to explicitly frame it in the context of transdifferentiation ("Td Licenser"), define what we mean, and to clearly distinguish this usage from previous applications of the term in DNA replication and reprogramming studies (for instance, see p10, l211-217; p13, l283-289 and p14 l312-315).

      __Minor comments: __

      __ Abstract: why are Drivers and Licensers in capitals? How is Driver defined? __

      __- __We use capital letters to signal that these represent two conceptual categories. However, this could be changed if that impairs reading. Drivers are defined in this study as plasticity factors whose loss completely prevents Td initiation (see p10, l211-217 and p14 l312-315).

      __Figure Aii: no PDE, ajm-1::GFP positive Y cells. It is not clear how the Y cell is identified-isn't ajm-1 supposed to surround the cell? The difference between the top and bottom ajm-1:egl-5 panels is not clear to a non expert. LIN-26 panel is missing. __

      • The Y cell is identified by its location at the ventral-most position on the anterior side of the rectal slit. AJM-1 is a component of the apical junctions, hence it is expressed at the apical domain of the Y cell. The LIN-26 typo has been corrected, the marker used in this experiment is the rectal-specific gene egl-5 which labels the nucleus of the Y cell.

      2F color scheme : licensers are not in yellow but pink

      • Addressed : they now are yellow in the revised version

      Fig S1: need to provide more details about experimental conditions for WB-stage, conditions (reducing agents?), nature of Q2015 antibody. In the absence of this information hard to substantiate claim of a LIN-15/LIN-56 heterodimer in the text -

      See answer to reviewer #1 : we agree that this experiment is dispensable for the results presented in this manuscript and adds more questions than useful information, and it has been removed from the revised version.

      __Line 130. What is the nature of the LIN-56 protein? This would be useful information __

      • Addressed. We have indicated this early on in the introduction (p5, l95-96) and in the Results section (p7, l132-134). Note that little is known about LIN-56 except its association with LIN-15A in VPC specification and that is equally possesses a THAP-like C2CH motif.

      __ Line 38 yielding__

      • Addressed

      __Line 48 identities suggested by Blau and Baltimore (1991). __

      • Addressed
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      Referee #3

      Evidence, reproducibility and clarity

      Through classical genetic analysis and the use of markers for different cell fates the authors identify the THAP domain protein LIN-15A as a novel factor in rectal-to-neuronal Y-to-PDA transdifferentiation (Td) in Caenorhabditis elegans. They show that lin-15A is not a core plasticity factor per se, but acts specifically in the Y cell to initiate Td by antagonizing a subset of chromatin-modifying complexes of the synmuvB class. Based on their data, the authors propose that lin-15A acts as a "licenser", as opposed to their previously described "drivers", to facilitate transdifferentiation.

      Most of the key conclusions are convincing, and experiments overall well executed and controlled.

      The lab previously showed that NODE-like complex components SEM-4/SALL4, CEH-6/OCT, EGL-27/MTA1 act together with the HOX TF EGL-5, SOX-2/SOX2 and HLH-16 to drive transdifferentiation of Y to PDA: in their absence Td does not initiate. The genetic evidence they provide here supports a model in which LIN-15A (together with another factor LIN-56) contributes (but is not essential) to the Td process: its loss results in a 50% decrease in Td (Figure 1A).

      Genetic rescue experiments are consistent with lin-15A acting specifically in rectal cells (Figure 1D), and genetic interaction studies support a role in parallel to "driver" genes (Figure 2). The genetic experiments showing that lin-15A does not act in a second natural transdifferentiation process (K-to-DVB), and actually restricts plasticity in blastomeres, are also well executed and support a specific role for LIN-15A in the rectal Y cell.

      The genetic data in Fig 4 is consistent with SynMuvB genes and LIN-15A acting antagonistically in the same pathway or on the same targets (figure 5). This is interesting, since in vulval cell fate specification lin-15A and synMuvB genes are redundant.

      Major comments:

      Based on the observation that LIN-15A does not affect SynMuvB expression in Y (figure S4), the authors conclude that antagonism of the SynMuvBs by LIN-15A is not likely mediated by a negative control of their expression, but rather by impacting their activity.

      However, as suggested by the authors, antagonistic functions on the same targe genes is also a possibility. The classical approach to test this would be through expression profiling. I understand that RNA-seq on single Y cells cannot be carried out for technical reasons and that bulk RNA-seq would not be informative. Importantly, the same reasoning applies to the ChIP-seq data that is presented in support for common regulatory functions of a subset of synMuvs and LIN-15A (Figure 6 and S6), which was obtained from whole animals. The relevance of these results to the Y to PDA Td process is therefore extremely limited, as the claim that LIN-15A restricts lin-35/DREAM binding on a subset of target genes is based on a reported decrease in DREAM binding in lin-15 mutants in bulk chromatin. This is especially true as both DREAM and LIN-15A are widely expressed proteins.

      In addition there are specific issues with Figure 6, which is mislabeled: upregulated and downregulated applies to gene expression, while the numbers refer to binding peaks. Why are some numbers in red (not mentioned in the legend). An example of the corresponding genome browser tracks should be shown in supplementary. Was a spike-in used to normalize data?

      Overall conclusions based on ChIP-seq data should be significantly toned down throughout - eg line 445 in the discussion: a role in the modulation of membrane processes based on ChIP-seq would require some type of validation using available cell membrane markers. The GO term analysis (Figure S1) identifies many very broad classes.

      Overall the discussion is highly speculative and could be shortened and refocused on the actual findings reported. For example, the fact that GO terms associated LIN-15B targets are associated with membrane processes (mentioned above) is not sufficient to speculate that LIN-15A could increase the delaminating capacities of Y by alleviating SynMuvB repression of membrane process genes.

      A general comment: The classical definition of a licensing factor is a protein (or complex) that allows the start of DNA replication from a replication origin. In the field of reprogramming, the term "licenser" has been applied to pioneer factors which 'license' transcriptional reprogramming by accessing chromatin to initiate a series of events, including binding of additional, non-pioneer transcription factors and additional chromatin regulators. Here the authors apply the term 'Licensers' to LIN-15A and LIN-56 as factors that facilitate the Td process. This may lead to confusion (and implications) as to what these factors are actually doing.

      Minor comments:

      Abstract: why are Drivers and Licensers in capitals? How is Driver defined?

      Figure Aii: no PDE, ajm-1::GFP positive Y cells. It is not clear how the Y cell is identified-isn't ajm-1 supposed to surround the cell? The difference between the top and bottom ajm-1:egl-5 panels is not clear to a non expert. LIN-26 panel is missing.

      2F color scheme : licensers are not in yellow but pink

      Fig S1: need to provide more details about experimental conditions for WB-stage, conditions (reducing agents?), nature of Q2015 antibody. In the absence of this information hard to substantiate claim of a LIN-15/LIN-56 heterodimer in the text

      Line 130. What is the nature of the LIN-56 protein? This would be useful information

      Line 38 yielding

      Line 48 identities suggested by Blau and Baltimore (1991).

      Significance

      The present work builds upon previous work from the lab identifying drivers of the Y to PDA transdifferentiation process and additional players. This is the only group working on this specific Td process. The main limitation of this study is that it relies almost exclusively on classical genetic analysis and reporter gene expression. LIN-15A and SynMuvB proteins are broadly expressed chromatin associated factors and no LIN-15A homolog has been identified outside nematodes; technical difficulties have hindered the implementation of single cell expression data or chromatin binding profiles of the individual cells studied, which would constitute a major brekthrough. In addition the notion of chromatin factors as reprogramming barriers is already well documented. The novelty here lies in the study of natural developmentally regulated transdifferentiation process.

      The work may nonetheless be of broad interest in the reprogramming field by providing an example of the complexity of interaction driving a natural transdifferentiation process, highlighting the activity of parallel pathways and the central role of chromatin associated proteins.

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      Referee #2

      Evidence, reproducibility and clarity

      The study describes the implication of LIN-15A, which is a THAP zinc-finger-like protein, in the Y-to-PDA conversion. This cell fate conversion is an intriguing type of direct reprogramming, as it is a developmentally programmed transdifferentiation process in the nematode C. elegans and offers a unique model for investigating cell fate conversion in vivo. The Jarriault research group has demonstrated in the past how powerful this cell-fate conversion model is for identifying novel players in transdifferentiation. This is a well-executed genetic study that establishes lin-15A as a new player in the Y-to-PDA transdifferentiation phenomenon and introduces a useful conceptual distinction between Driver and Licenser factors. The genetic interactions with class B SynMuvs are clean and informative. LIN-15A is proposed to act as a Licenser in a context-dependent manner because it is also expressed in other cell types; mechanistic insights are indispensable for understanding the nature of this context dependence. Overall, I support the publication of this study, but have some comments prior to its acceptance.

      Main comments:

      The conclusions derived from the presented data are generally comprehensible but should be phrased more carefully to grant full legitimacy. The reason is that the central mechanistic claim that LIN-15A licenses Td by antagonizing most of the SynMuvBs chromatin factors, including DREAM, rests on whole-animal ChIP-seq that cannot resolve the Y cell. The authors acknowledge that "it was not technically feasible to purify sufficient Y cells for analysis" and therefore use synchronized unstarved L1 whole-animal lysates. This is certainly legitimate, but demands more tact when using such a conclusion as the headline claim.

      Also, in the context of the ChIP-Seq experiments, it is understandable that it could not be conducted in a cell-specific manner, but two duplicates in some ChIP-Seq experiments (as stated in the material and methods) is below standard.

      Regarding the genetic interactions with met-2: as MET-2 works in concert with other SET domain proteins, such as SET-25, and also HPL-2, is there a possibility they may be implicated?

      The fact that Y-to-PDA in males (which involves a cell division) shows the same lin-15A dependence as in hermaphrodites is informative and a bit underplayed. Since this argues against a cell-cycle-coupled mechanism (an important aspect of the reprogramming field) for LIN-15A, it is worth elaborating on this in the discussion.

      Minor:

      • in the legend of Figure 1 and other places, it should be "Fisher's exact" instead of "Fisher exact"
      • line 31; exhibits instead of exhibit
      • line 85: results instead of result
      • line 228: involvement instead of involvment
      • line 293: "of missing" in loss of lin-36 had no effect while loss ... lin-53 further
      • lines 297 - 299: check sentence; reads not correct
      • line 395: "with an increase"
      • line 484: "with regard"

      Significance

      This is a well-executed genetic study that establishes lin-15A as a new player in Y-to-PDA transdifferentiation and introduces a useful conceptual distinction between Driver and Licenser factors. The genetic interactions are clean and informative.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      This manuscript from Sophie Jarriault's lab investigates the genetic mechanisms underpinning Y-to-PDA transdifferentiation in the nematode Caenorhabditis elegans. Transdifferentiation is the process by which one differentiated cell type converts to a different differentiated cell type without passing through a pluripotent stem cell stage. Understanding the biology and molecular mechanisms of transdifferentiation in an in vivo context will ultimately aid in engineering transdifferentiation for regenerative medical applications.

      Through a forward genetic screen the authors isolated a mutant allele of the lin-15A gene, which encodes a THAP domain chromatin factor. lin-15A has been well-studied for its role in redundant chromatin pathways that repress the expression of LIN-3/EGF during vulval development. Hence it is referred to as a SynMuvA gene. The authors show that lin-15A null mutants exhibit an incompletely penetrant defect in Y-to-PDA transdifferentiation, with approximately 50% of the animals exhibiting the defect. They show that lin-15A functions in rectal cells, a group of cells in the vicinity of Y and they provide evidence that LIN-15A functions in the initiation of transdifferentiation. Genetic evidence supports a model in which LIN-15A functions in parallel to "Drivers" of transdifferentiation, which include the transcriptional regulators, CEH-6, SOX-2, EGL-5, SEM-4, EGL-27, and SEM-4. An interesting genetic result is that LIN-15A, together another synMuvA gene LIN-56, functions antagonistically to synMuvB genes. Through an analysis of ChIP-seq data, they suggest a model in which LIN-15A antagonizes SynMuvB function in the transdifferentiation decision.

      Critique

      This is a well-written manuscript on an interesting topic. The work provides genetic insights that will be useful for setting "boundary conditions" and predictions for subsequent molecular studies. The authors should consider the following points.

      Major Points

      1. As the authors acknowledge in the section at the end of the discussion (Limitations of this study) it is not established that LIN-15A has a cell-autonomous function in Y-to-PDA transdifferentiation. Given that LIN-15A has a cell non-autonomous function in vulval development (Herman and Hedgecock, 1990) it is possible that its function here could also be. The authors have used an egl-5 promoter to rescue lin-15A through expression in rectal cells; however, all these cells are in a neighborhood. The lack of a promoter that is specfic for Y has impeded answering this question (a standard genetic mosaic analysis would be problematic because of the incomplete penetrance of the mutation). Although this issue is addressed in the section at the end of the Discussion, I think most readers would like to see this acknowledged earlier in the presentation, perhaps after describing the egl-5 rescue experiment.
      2. The experiment shown in Figure S1B is unconvincing. To show that they are detecting a LIN-15A-LIN-56 heterodimer, the authors need to show that antibody tags to both proteins detect the band. Mass spectrometry or biochemical purifications would also be helpful. As it is, they show the protein(s) detected depend genetically on lin-56 and lin-15A. It was also unclear what the other bands were in the mutant backgrounds
      3. Lines 207-212. The authors are making an argument that LIN-15A and LIN-56 function as "Licensers" not "Drivers" because they are not strictly required but appear to facilitate the process. Could it be that LIN-15A and LIN-56 function as "Drivers" but that in their absence the fidelity of the process is compromise? There are many ways that genetic redundancy can be manifested at biochemical levels and the concern is that there are other interpretations of the data. In this regard, the authors should consider rewriting the Abstract to focus on the genetic results underpinning the work. The current version or the Abstract focuses on an interpretation of the data, not the data itself.

      Minor Points

      1. Line 279. The authors state that "LIN-15A becomes dispensable when member of the SynMuvB factors are absent." This statement is not completely accurate as the suppression is incomplete.
      2. Line 294. The number in Tagble S1 is 58.8% not 65%
      3. Lines 300-301. I couldn't find the data for lin-40.
      4. Line 363. Should be "represses cell cycle genes."
      5. Line 862. AJM-1 is not a tight junction component. AJM-1 is best described as a component of apical junctions.

      David Greenstein

      Significance

      General Assessment

      This is well-written genetic study on an interesting topic-a natural case of transdifferentiation. The experiments are well conducted and properly analyzed. The identification of LIN-15A as a player in Y-to-PDA transdifferentiation will enable experimental tests of the authors' model. The limitations of the study are that for technical reasons the authors acknowledge, it is not established whether the function of LIN-15A is cell autonomous to Y. The authors have undertaken the beginnings of molecular work to get at mechanism, but the downstream targets of the apparent chromatin regulation are not yet apparent.

      Advance

      The identification of LIN-15A as a regulator of Y-to-PDA transdifferentation and the suppression by mutations in synMuvB genes are of interest to the field.

      Audience

      This manuscript will be of keen interest to developmental geneticists focusing on chromatin regulation in genetic model systems as well as developmental biologists studying transdifferentiation processes.

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      Reply to the reviewers

      We have uploaded our response to the reviewers as a separate file as it contained figures that could not be included in this format.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary: In this manuscript, Veldsink et al. use affinity-purification mass spectrometry combined with metabolic labeling, as well as microscopy to characterize a previously published nanobody targeting the inner ring nucleoporin Nic96 of yeast nuclear pore complexes. The authors find that this nanobody cannot label pre-existing NPCs, as its epitope on Nic96 is occluded after Nic96's incorporation into NPCs, but instead it can be co-incorporated along with newly synthesized Nic96 subcomplexes into newly formed NPCs. The authors use this tool to measure NPC assembly kinetics in haploid and diploid cells and to characterize nuclear-vacuole-junction proximal lipid droplets as a putative Nup storage location. Overall, this is an interesting and thorough study that warrants publication after some key control experiments are performed.

      Major comments:

      Figure 1D:

      I am confused about the interpretation of the KARMA results. At 90 minutes only ~37.5% of Nic96 and even less of its CNT interaction partners that co-purified with VHH[Nic96] are metabolically labeled with heavy lysine, suggesting that the majority of bound Nic96 (~62.5%) and CNT are non-labeled (i.e. contain light lysine). Could the authors please comment on whether they think the light lysine labeled population represents NPC-incorporated Nups or soluble Nup subcomplex pools that pre-existed prior to the heavy lysine labeling pulse?

      Isn't it unlikely that nanobodies IP the entire preformed NPC, but rather that they preferentially bind much smaller unassembled subcomplexes and that such soluble Nup pools are therefore also preferentially enriched? Please comment if this could introduce bias in the analysis.

      The VHH[Nup84] nanobody control does not seem like an intuitive choice, since Nic96 and CNT Nups that copurify via Nup84 (as part of the Y-complex) must have likely assembled into NPCs already. Wouldn't IPs via this nanobody monitor a later stage in NPC assembly (where Nic96-CNT-Y-complex interactions have formed)? What is the fractional labeling of Nup84 and other Y-complex members in the VHH[Nup84] versus VHH[Nic96] IPs? Would this simply be a mirror image?

      Figure 3:

      In order to show that VHH[Nic96] expression doesn't interfere with NPC function, could the authors please assess the localization of endogenous Nic96 in the absence or presence of VHH[Nic96] expression? They could for example co-express VHH[Nic96]-mNG in the Nic96-Halo cell line to co-localize both and show that there are no mislocalization artefacts of endogenous Nic96 upon nanobody expression. Would you observe the same number and intensity of Nic96-Halo positive non-NPC/lipid-droplet co-localized foci -/+ VHH[Nic96] expression? A nanobody that is not targeting a Nup could be expressed as comparison.

      Figure 6:

      The phenotype of acute degradation of Brl1 on VHH[Nic96]-mNG staining (Fig. 2E) are convincing and suggest that indeed this nanobody doesn't stain pre-existing NPCs but instead gets co-incorporated into newly assembling NPCs. However, the lower staining intensity of VHH[Nic96]-mNG compared to endogenous Nic96-mNG (Fig. 4D), as well as the Nup155 steric clash experiments (Fig. 2G) demonstrate that at least some Nic96-VHH[Nic96] complexes are prevented from assembling into NPCs, since removing the steric clash increases nuclear rim staining intensity with VHH[Nic96]. This makes me wonder if some of the atypical non-NPC foci observed with VHH[Nic96]-mNG, i.e. the foci co-localizing with lipid droplets, are simply a result of failed NPC incorporation of a subset nanobody-bound Nic96 subcomplexes. Could the authors visualize starvation- or NPC assembly defect-induced lipid droplet localization of the Nic96 subcomplex in the Nic96-Halo cell line directly (i.e. without the nanobody?). This would support their model.

      The word foci is used confusingly throughout the manuscript to describe VHH[Nic96] signal accumulations in the cytosol, near lipid droplets and at the nuclear envelope (at NPCs). For example, in Figure 5C are the foci moving between mother and daughter cells associated with NPC inheritance or are these lipid droplet-associated Nic96 foci?

      To support the authors hypothesis that Nic96 subcomplexes might get stored near/on lipid droplets during starvation or NPC assembly stress it would be useful to quantify VHH[Nic96]-mNG foci co-localization with lipid droplets (AutoDOT staining) in unstarved vs N-starved cells, and in WT vs Nup170ΔC, WT vs Nup53Δ and Brl1-AID Ethanol vs Auxin treatment.

      Minor comments:

      Introduction: A more thorough discussion of prior work that addressed the same challenge of selectively visualizing newly formed NPCs is missing. For example, Sola et al. 2024 EMBO J. (PMID: 38649536) developed a large toolbox of anti-human and anti-frog nucleoporin nanobodies to track interphase assembly of frog NPCs into human nuclear envelopes.

      Fig. 3B: Hardly any NPC / nuclear rim labelling with VHH[Nic96]-mNG is visible after 6h induction. This is likely due to the absence of a glucose chase period which would otherwise degrade excess cytosolic nanobody. Maybe the authors could highlight this difference in the figure legend or text, a comparison to Fig. 2B ton=overnight but with 5 hour chase would otherwise be confusing.

      Fig. 6A: The triangles do not work well for pointing at things in images, since it is not clear which corner is supposed to point. Please convert them into asymmetric arrows. The top arrow doesn't seem to point at anything in the mNG channel.

      Fig. 6B: The authors could explain that Vph1 represents a vacuolar marker protein in the figure legend.

      Line 22: difficult  difficulty

      Line 49-51: Incomplete sentence ending in 'amongst which Saccharomyces cerevisiae Nup84 (Nup107 in human NPCs).'

      Line 111: change from 'to this subcomplex' to 'into this subcomplex'

      Line 114: change young to nascent or newly synthesized

      Significance

      I think this is a solid contribution to the NPC assembly field and will generate interest in a few groups that study yeast NPC assembly in particular and could thus use the characterized nanobody tool after more careful controls as outlined above have been performed. The finding that NPC assembly rates differ between haploid and diploid cells seems interesting and could generate questions for mechanistic follow-up to explore this difference. It seems that the Nup localization to lipid droplets had been described before and its physiological role and relevance to NPC homeostasis remains enigmatic even with the current study.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      This study presents VHH[Nic96], a nanobody-based live-cell probe as a tool to monitor nuclear pore assembly process in budding yeast. Based on their data, the authors concluded that VHH[Nic96] specifically labels newly forming NPCs and becomes incorporated during their assembly in live cells. Using this tool, they found that unassembled Nic96 accumulates at lipid droplets, particularly near the nuclear-vacuolar junction (NVJ). Under stress conditions, such as nitrogen starvation, or when NPC assembly is impaired, more Nic96 is redirected to lipid droplets. The authors propose that cells maintain a balance between NPC assembly and temporary storage of nucleoporins on lipid droplets, enabling them to adapt NPC biogenesis to changing physiological conditions. Overall, if VHH[Nic96] really labels only newly assembling NPCs, it could become a valuable tool for studying NPC assembly in live yeast cells. However, the current evidence that VHH[Nic96] distinguishes assembling from mature NPCs is limited. Moreover, even if this specificity is correct, the authors do not convincingly demonstrate how this tool provides new insights into NPC assembly. Some conclusions appear overstated, and several datasets lack sufficient analysis or quantification. Detailed comments are provided below.

      Major comment 1: Limited evidence that VHH[Nic96] specifically labels assembling NPCs The data presented in Figures 1-5 do not provide sufficient evidence that VHH[Nic96] marks newly forming NPCs. An equally plausible interpretation is that the nanobody binds mature NPCs, albeit at very low efficiency. Stronger experimental support is needed before concluding that VHH[Nic96] specifically labels NPC assembly intermediates. For example, as illustrated in Figure 1A (right panel), VHH[Nic96] is expected to associate with NPC assembly intermediates (i.e., INM herniations). Demonstrating this directly, e.g., using immuno-electron microscopy with VHH[Nic96]-GFP combined with an anti-GFP antibody, would convincingly validate the tool's specificity and strengthen its value for studying where, when, and how NPC assembly occurs.

      Major comment 2: Whether VHH[Nic96] provides new biological insights First of all, the claim that VHH[Nic96] accumulates at lipid droplets near the NVJ is not well supported because the data lack quantification. On Line 276 the authors state "VHH[Nic96] foci were located near the NVJ (Fig. 6A)", but no quantitative analysis is provided. From the images in Fig. 6A, this proximity could simply occur by chance. The authors should quantify this observation, e.g., by measuring how often VHH[Nic96] foci occur near versus away from the NVJ. A similar issue arises on Line 282, where the authors state "VHH[Nic96] foci...were often overlapped with or in close proximity to lipid droplets...", without quantification. In the CLEM data, the authors write on Line 280 that "VHH[Nic96]-mNG signal at the NVJ-localized foci...," but in the images the signal appears slightly displaced from the NVJ. If the authors wish to argue that VHH[Nic96] is located at the NVJ, they should measure these distances and clearly define what they consider as "overlap." On Line 284, the authors state that "...Ldo16 and Pdr16...mark a specific NVJ-localized lipid droplet (Fig. 6D)". However, in the images neither the vacuole nor the nuclear envelope is labeled, so this conclusion cannot be drawn from the data as presented. On Line 294, they state "VHH[Nic96] noticeably changed its localization...(Fig. 6F)...leading to an increase in the cytoplasmic VHH pool". This is difficult to judge from the images provided, and quantification would strengthen the claim. Finally, on Line 301, they state that stress results in "an increased number of cytosolic VHH[Nic96] foci and bright accumulations in the NE (Fig. 6HI)". Yet the nuclear envelope is not labeled, making it unclear whether this is accurate. Moreover, the shift of VHH[Nic96] foci to the cytosol is not quantified. Since the degree of effect seems to vary depending on stress condition (e.g., nitrogen starvation vs. NPC assembly defects), proper quantification is essential.

      A second concern is whether VHH[Nic96] is truly required to obtain the insights presented in Fig. 6. The observations shown could also be made using short-pulse overexpression of Nic96-mNG, Nup192-mNG, Nup57-mNG, or Kap121-GFP, which label newly forming NPCs (Fig. 5E-G). The authors should therefore demonstrate more convincingly why VHH[Nic96] provides unique or superior advantages for studying NPC assembly.

      Minor points:

      Line 215: This should refer to Fig. 4C, not Fig. 4D.

      Line 233: This should refer to Fig. 4F, not Fig. 4G.

      The data in Fig. 4F are not convincing because they are based on sparse sampling (Fig. S4). In diploid cells, sampling every 1 hour shows a clear pattern: the number of foci increases until 2 hours and then decreases to zero by 4 hours (Fig. S4B). However, in haploid cells, sampling was mainly at 1, 3, and 6 hours (Fig. S4C), making it uncertain whether the apparent peak at 3 hours is real and whether the decline at 6 hours is reliable. Including critical intermediate time points (e.g., 2, 4, and 8 hours) would make this case more convincing.

      Significance

      In its current form, the significance of this study is limited. Demonstrating that VHH[Nic96] truly labels NPC assembly intermediates would greatly strengthen its value as a tool for studying where, when, and how NPC assembly occurs. Regarding the biological insights, the claim that unassembled Nic96 accumulates at lipid droplets near the NVJ, and that under stress conditions (e.g., nitrogen starvation or impaired NPC assembly) more Nic96 is redirected to lipid droplets, is intriguing but not fully convincing. If the authors could provide quantitative evidence for this redistribution, it would enhance the impact of the work by linking NPC assembly to metabolic state and stress response, and by clarifying how cells adjust NPC assembly under different conditions.

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      Referee #1

      Evidence, reproducibility and clarity

      Annemiek C V. et al. reported a nanobody-based method in budding yeast, where they combined pulsed expression with fluorescence microscopy to study how nucleoporins are assembled into the nuclear pore complex. Using this approach, they also found that nucleoporins localize to lipid droplets before assembly.

      Major comments

      1. In Abstract the authors claim 'Our nanobody-based pulsed-labelling strategy opens new avenues for dissecting the spatiotemporal regulation of NPC assembly'. The authors utilized a Nic96 nanobody to study the assembly process, since in fully assembled NPC, Nic96 is buried inside inner ring complex hence the binding sites of this nanobody is shielded, which makes this 'nanobody-based pulsed-labelling' approach possible. Yet, NPC is comprised by ~30 different kinds of nups, a lot of them are exposed to surrounding environment, such as Nup159 complex, Y complexes, FG-nups etc (for instance, please see Fig 1. from Matteo A. et al.,), if one should use nanobody toward those nups, would this 'nanobody-based pulsed labelling' strategy also work? In the study the authors showed nanobody against Nup84, a component of Y complex, in Fig 1, to be compared with respect to Nic96, and clearly this nanobody targeted both fully assembled NPC, and newly synthesized nup84, so that if one would like to use the strategy of 'nanobody-based pulsed-labelling' targeting nup84 using this nanobody, one should fail. Which is against authors' claim at the end of Abstract: 'Our nanobody-based pulsed-labelling strategy opens new avenues for dissecting the spatiotemporal regulation of NPC assembly, with implications for understanding aging and diseases linked to NPC dysfunction.' Personally, I would suggest the authors to either change their claim, or add another nanobody against another nup, ideally one sits on outer ring, to show this approach is not limited to just one nup. In addition to that, the authors should also add in additional discussion regarding the concern, to make it clear how should one chose the nanobody, and whether there's other nanobody/antibody available and suitable to conduct such strategy. Or, the results on how newly synthesized nups cluster on lipid droplets itself is already exciting, maybe the authors could address more on that issue, to shift the scope from this approach to a more interesting biological story?
      2. There have been several literatures studying NPC assembly process, for instance Ref. 15, their approach could also reveal the sequence of nups being incorporated on to NPC. At least in discussion section, the authors should also comment on those studies, addressing on what has been improved in this study, to give a more comprehensive view for the readers.
      3. Indeed, dysfunction on several nups are considered to be related to disease, but most studies focus on nups from metazoans, for instance, please see the review from Charlotte M. F. et al., (doi: 10.1080/19491034.2024.2314297), since authors used yeast model throughout the study, and haven't show any nups from metazoans, the last sentence from Abstract 'Our nanobody-based pulsed-labelling strategy opens new avenues for dissecting the spatiotemporal regulation of NPC assembly, with implications for understanding aging and diseases linked to NPC dysfunction' seem to be an over-claim, please change the statement here. Or, if the authors could elaborate more in the discussion section.
      4. Line 23 the authors say '...pulsed-labelling mass spectrometry...', whereas in line 89 the authors say '...affinity purification - mass spectrometry (MS) experiments to study its interactome'. I understand the approach is to pulse the expression, then purify, then run MS analysis, the term 'pulsed-labelling MS' seems to be misleading, since there's purification step in between pulse expression and MS, please be precise about the terms.
      5. For the florescence image showed in Fig 2B, the author's explanation to this is '...VHH[Nic96]-mNG localized at the NE, although likely sub-stoichiometrically to Nic96 as its total fluorescence was lower than endogenously expressed Nic96-mNG.' Whereas in the images of VHH-[Nic96]-mNG, you could still see lots of signals located in cytoplasm, especially for cells in the middle and on upper right, the NE localization is not clear, the signal strength is even comparable to cytoplasm. Seems to me these images do not support the conclusion that VHH[Nic96] eventually incorporated into NPCs, at least not in the time scale of ~24 hrs. Could the authors elaborate more on the cytoplasm localization of these Nic96 signals?
      6. In Fig. 6B, it seems the CLEM image are taken from cells, if so, please also provide the CLEM image of the thin sections, to make the positioning clearer.
      7. Relate to previous comment, the three positions showed in Fig. 6B have different scale, covering different field of view, also the scale bar itself have different sizes, this should not be tolerated, please change!

      Minor comments

      1. Line 159, '...Nic96 and its co-translationally assembled binding partners, and that it is incorporated into nascent NPCs along with newly synthesized Nic96', is there any evidence showing that Nic96 will go to nascent NPCs, or if there's a reference to this statement? If not, please delete the word 'nascent'.
      2. The title of Fig. 1, 'VHH[Nic96] binds newly synthesized Nic96 and subcomplex members' is quite confusing, I guess here the authors meant 'CNT subcomplexes'? Since different nups form several different subcomplexes, please be specific here.
      3. Personally, I find the arrangement of Nups within NPC is confusing for readers outside of the field, thus for Fig 2F, I think it's vital to add another figure viewing the model from another angle, for instance, 90-degree rotated view, to help readers to understand the geometry.
      4. Line 269, '...of NPC assembly paving the way for detailed studying addressing where and...', shouldn't it be '...detailed study addressing...'?

      Significance

      As a highly organized molecular machine, the NPC has been a hotspot for many researches, yet its complicated nature has made it challenging to study its structure and function, the authors provided a nanobody-based approach to study the process of incorporation of nups into NPCs, based on this approach, the authors studied Nic96 assembly and found nups cluster on lipid droplets. I think it is an interesting approach and the assembly process showed in the literature is also interesting to people who work in NPC assembly, particularly. However, based on the comparison between nanobody to Nic96 and Nup84, it is a bit concerning whether this approach could also be applied to outer ring nups or even other partner of the inner ring nups. Other than that, there're several mistakes in the main figure, and some panel could be refined, without these information, some of the statements made in the manuscript seem to be over claimed. Hence, I would suggest to consider this manuscript to be published after major revisions, also refinement on literatures have been done.

      My experties are limited to NPC structure, cryo-EM including single particle analysis as well as cryo-ET

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      Referee #2

      Evidence, reproducibility and clarity

      In their manuscript entitled " Single-molecule behavior and cell-growth regulation in human RTKs" Abe et al. demonstrate automated single-particle tracking of 52 receptor tyrosine kinases (RTKs) in both resting state and upon stimulation with the respective ligands. The approach is based on transient transfection of cells with each RTK tagged with a Halo-tag, allowing for subsequent dye labeling and live cell video recording using TIRF microscopy. Subsequently, a seemingly commercial analysis software is used to then obtain particle trajectories from single molecule localizations and analyze their properties using a hidden Markov model. The authors have previously demonstrated pioneering work in the field of single-particle tracking with respect to automation (Yasui et al, 2018) and analysis (Yanagawa et al, 2021), and in this work they scale their approach up to characterize a broad set of RTKs. The resulting observations are a powerful demonstration of the benefits of SPT in general and significantly advance our understanding of the dynamics of RTKs as a class, beyond the most prominently studied candidate EGFR, as well as promising evolutionary insights.

      Comments and questions:

      1. The authors picked 52 out 58 human RTKs. Why not all?
      2. In contrast to the above mentioned previous publications, here a seemingly commercial software package was used (AAS by Zido). The methods part is very short on the specific parameters that were used to i) localize particles (e.g. net gradient threshold) or ii) connect localizations into trajectories (step size, allowed dark frames, min. trajectory length). Similarly a clearer explanation of the HMM calculus would significantly help to better follow the analysis approach and parameter choice. Perhaps this reviewer has missed it, but why did the authors e.g. choose 3 states for HMM?
      3. The replicate experiment in Fig. S2 is appreciated, but what condition was repeated here? Also experimental details are missing: was it two repeats of: i) seeding cells in a dish, transfection, labeling, imaging? An image from cells from those repeats would be important to show, also to which degree the density of particles F varies, i.e. to which degree this is an unprecise experimental parameter itself as compared to biologically meaningful. This is especially as Fig. S2 does not contain any density comparison at all, whereas in the main figures it is indeed an experimental observable used.
      4. The density raises another issue. Some of the movies show extremely dense signal. Here the authors should explain how they deal with particles whose trajectories cross. This could lead to artificial dynamics and a supplementary figure showing that their analysis is robust toward varying densities (again suggesting to include a simulation) could be helpful
      5. Fig. 2C is a bit hard to understand since here localizations are colored based on their state but not from which trajectory they come. Do e.g. individual trajectories show various dynamic behaviors or are the trajectories not long enough to observe this?
      6. The evolutionary aspects could use further and simpler explanations to make this passage easier to grasp

      Significance

      The manuscript by Abe et al. represents a significant advancement in the field of single-particle tracking (SPT) by scaling up recording 52 human receptor tyrosine kinases (RTKs), offering comprehensive insights into their dynamics beyond the traditionally studied EGFR. While the study demonstrates cutting edge single-particle tracking and provides promising evolutionary insights, it currently lacks certain methodological details that are essential for reproducibility, such as specific parameters used in particle localization and trajectory analysis. The exclusion of 6 out of 58 human RTKs without discussion also requires further explanation, but overall, the study fills a knowledge gap by providing a broad overview of RTK dynamics and their diffusion behavior. Overall, this work should have broad appeal to fields such as cell signaling as well as methods development int the area of single-particle tracking.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary: "Single-molecule behavior and cell-growth regulation in human RTKs" studies 52 of the 58 human receptor tyrosine kinases (RTKs) on the surface of live HEK293A cells using a Total Internal Reflection Fluoresence Microscope (TIRFM) system previously described in Watanabe et al. Single molecule tracking is conducted automated commercial Auto Analysis System (AAS; Zido) software followed by analysis in Python via scikit-learn. The analysis includes use of a Variational Bayesian-Hidden Markov Model (VB-HMM) described previously (Hiroshima, 2018). The VB-HMM analysis was used to characterize movement of RTKs with the authors concluding that the movement could be explained by the receptors transitioning between three states: immobile, slow, and fast. Single molecular transport parameters are then extracted from the analysis and averaged results are reported. How these parameters change after stimulation are then evaluated and compared. To relate the diffusion "behaviors" with biological function, the authors retrieve cell growth data from loss-of-function data in the DepMap project (Arafeh, 2025). By correlating selected parameters with the functional data, the authors find that behaviors in the resting and response states partially "explained their function". The authors then relate specific parameters through correlation to growth-inhibitory or growth-supporting signaling, amino acid sequence characteristics ("structural"), and evolutionary parameters. Additionally, the authors build a regression model to evaluate how their behavior parameters may predict RTK functional characteristics.

      Major Comments: 1. The primary findings from this article are the extraction of parameters of a 3-state hidden Markov model from the analyzed single molecule trajectories of 52 RTKs. It is difficult to evaluate these primary findings since the raw data, the analysis software, the intermediate results, the hidden Markov model, and the Python analysis scripts are not readily available to the public or this reviewer. Thus the evaluation of the underlying software, applicability of the software to the problem, or reproducibility of the results from the data are not possible to evaluate. I encourage the authors to provide as much data and software available as possible even if under restricted licenses. a. The availability of raw single molecule movies from this study are not generally available and thus it is difficult possible to evaluate the efficacy of the Zido AAS software or compare to the tracks generated to other single molecule tracking software. While it is appreciated that a mosaic of the movies is made available as Supplemental Movies 1A through 1D, these are not in a form analyzable by other tracking software. Ideally, all the raw experimental data would be made available, but it might suffice if a single raw movie and its analysis were made available for direct evaluation. b. The trajectory information of single particles from the Zido AAS are not available. While the raw movies may be voluminous in nature, the extracted trajectories would also be valuable. As multiple hidden Markov models are available to evaluate diffusive behaviors, it would be useful to have the trajectory information available for a comparison between distinct models to be conducted by reviewers. c. The Variational Bayesian-Hidden Markov Model (Hiroshima et al. 2018) that is used at the core of this paper is not readily available.

      1. While it is appreciated that the authors combine their extracted VB-HMM parameters of RTKs to other bioinformatic data sets, the relationship to functional and structural-sequence information is only correlative. There is no attempt in this article to validate the correlative findings.

      2. Many statistical comparisons are made in this article across cell lines, RTKs, and parameters, but it is not clear if multiple comparison corrections are applied to compensate for the false discovery rate. The authors should provide a detailed Statistical Analysis section in the methods section.

      Minor comments: 1. The authors insufficiently cite the Broad Institute's Dependency Map project from which their functional analysis is derived. The following is quoted from https://depmap.org/portal/data_page/?tab=overview#how-to-cite . For DepMap Release data, including CRISPR Screens, PRISM Drug Screens, Copy Number, Mutation, Expression, and Fusions: DepMap, Broad (2025). DepMap Public 25Q3. Dataset. depmap.org Please note, you may need to update the release quarter depending on which version of the data you are using. We ask that you also cite the DepMap program: Arafeh, R., Shibue, T., Dempster, J.M. et al. The present and future of the Cancer Dependency Map. Nat Rev Cancer 25, 59-73 (2025). https://doi.org/10.1038/s41568-024-00763-x

      Significance

      General assessment: The main significance of this paper comes from a broad and data-rich study of 52 of 58 human receptor tyrosine kinases. If this data, the intermediate analysis results such as the trajectories, or executable software used to conduct the analysis were made available, the value to the field would be high. However, the article lacks any statements regarding open availability of the data or the software. While correlating their "behavioral" parameters to other bioinformatic datasets creates context and suggests further studies, the lack of any validation of the correlative findings limits the significance of the results.

      Advance: While the authors share large final outputs of their parameter datasets, the unavailability of the raw data or intermediate results makes it difficult to compare their analysis and models to other readily available analysis pipelines or models. In particularly, it would be useful to the field if their analysis could be directly compared to the software packages in the following citations:

      1. Monnier, N., Barry, Z., Park, H. et al. Inferring transient particle transport dynamics in live cells. Nat Methods 12, 838-840 (2015). https://doi.org/10.1038/nmeth.3483
      2. Vega et al., Biophys. J. 2018. Multistep Track Segmentation and Motion Classification for Transient Mobility Analysis. https://pubmed.ncbi.nlm.nih.gov/29539390/.

      Audience: The potential audience is the field of receptor tyrosine kinases and more generally cell surface receptors. The lack of validation of their correlative results or comparison of their analysis pipeline to other analysis pipelines limits the value of the findings to the field. There is also a potential audience for other authors of computational trajectory analysis software if the raw data or intermediate analysis results were available. The effective audience is thus limited to biophysicists or quantitative biologists capable of replicating the VB-HMM model for validation of the correlative results in falsifiable experiments.

      Reviewer's Field of Expertise: I have a field of expertise in advanced microscopy, image analysis, single particle tracking, receptor tyrosine kinases, membrane biophysics, hidden Markov models, Bayesian analysis, and software engineering.

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      Reply to the reviewers

      General Statements

      Thank you for providing an assessment of our manuscript. Below, we outline our revision plan. The revisions address four main areas: the relationship between the identified molecular signatures and fibrosis severity or disease etiology; the criteria used to identify disease-associated fibroblasts; the interpretation of the genes and biological processes highlighted by our analyses; and the broader biological insights supported by the study.

      As part of the revisions implemented, we have:

      Associated organ-specific fibrotic molecular signatures and fibrosis severity scores available in the clinical metadata, helping to relate the identified transcriptional patterns to biologically meaningful aspects of fibrosis. Extended supplementary figures that more clearly present the decision-making process used to identify fibroblast subpopulations associated with fibrosis. Revised the methods, figures, legends, and captions in response to the reviewers' suggestions to improve clarity. Expanded the discussion of the results by incorporating the literature suggested by the reviewers, thereby providing additional context for the identified fibrotic signatures. Extended our spatial analysis using a more robust identification of fibrotic regions.

      We plan to:

      Extend our cell-cell communication and spatial analysis using deconvolution methods Provide comparisons between our unsupervised multicellular factor analysis of multiple studies with our supervised fibrotic signatures to ensure coherence between analyses. Perform additional comparisons between specific pairs of organs and additional cell types, instead of focusing solely on the comparison of all organs simultaneously. Expand the results and discussion to clarify the relevance and limitations of our study. We believe these revisions will strengthen our resource manuscript and will help us to provide a robust and reliable description of fibrotic processes across organs.

      Description of the planned revisions

      Reviewer #1

      Reviewer #1, major comment 1: The group has been developing cutting edge bioinformatic tools for the community. The authors also provided scripts and the processed data for reproducibility. I have no doubt in their implementation of the methodology. I also understand the reasons of the objective tone throughout the manuscript. However, the authors made very little claims with biological significance. The conclusion of the study is vague with almost nothing mentioned in the abstract. What are the cross-organ effects in fibrosis identified in this study? I believe some additional claims would facilitate the reader with less technical knowledge to grasp the study better.

      We understand the concern of the reviewer regarding the lack of an explicit discussion of the biological significance in the abstract and other parts of the manuscript, as most of the manuscript is focused on the comparison of studies at different levels. Our study defines which fibrosis-associated transcriptional patterns are reproducibly detectable across the currently available public single-cell datasets, while also identifying where cross-organ interpretation remains limited. We observed that some disease-associated transcriptional patterns recur across organs and studies, particularly in mesenchymal and endothelial compartments. In contrast, other compartments, including myeloid cells, showed weaker cross-organ agreement, which may reflect either greater tissue-context dependence or stronger sensitivity to differences in disease stage, sampling, and annotation. Finally, we observed a convergence of fibrotic signals in a subset of mesenchymal cells and show which genes are specifically expressed in actively scarring regions across organs, with TIMP1 being consistently identified as highly expressed in fibrotic regions by disease associated fibroblasts across tissues and modalities.

      Our results should be interpreted as robust and reproducible cross-dataset fibrosis signatures rather than definitive evidence for a specific pathophysiological mechanism. Therefore, we believe that the primary contribution of this study lies not in assigning causal roles to individual genes or pathways, but in providing a systematic framework for identifying fibrosis-associated programs that are reproducibly observed across studies, organs, and disease etiologies. As our analysis is entirely computational, we intentionally avoid making strong mechanistic claims without experimental validation. Instead, we envision this resource as a means to prioritize candidates and generate hypotheses for future functional studies.

      To address the reviewer's concern, we will make more explicit claims of our observations within our abstract and throughout the text to make our intentions and conclusions clearer. We will be more explicit about what information we are providing with our resource and how it can best be leveraged. We will further include our conclusions about cross-organ agreements described above, as well as specific observations from our analyses that help the reader to get a better grasp of the study.

      Reviewer #1, major comment 3: The authors performed multicellular factor modeling in each organ and identified factors that are distinct in fibrotic and reference tissue in Fig. 2B, e.g., factors 1 and 2 in heart. Are these factors driven by specific biological pathways? Could these factors also be used to identify common biological functions in fibrotic tissue across organs?

      We agree that, in principle, the latent factors identified by the multicellular factor models could be interrogated for their biological interpretation. Each factor is associated with a gene-weight vector per cell type, which can be analyzed similarly to a differential expression signature to identify enriched pathways and biological processes.

      However, we chose not to pursue a systematic factor-level interpretation for three reasons. First, as shown in Suppl. Figure 3, the contribution of individual factors to the separation between fibrotic and reference samples varies substantially across organs. In some organs, the distinction is largely captured by a single factor, whereas in others it is distributed across multiple factors. Second, because the models were trained independently for each organ, there is no direct correspondence between factor identities across organs, making cross-organ comparisons of individual factors difficult to interpret. Finally, we were not able to capture a fibrosis-related transcriptomic program from all organs.

      We therefore used the multicellular factor analysis primarily as an unsupervised approach to assess whether common fibrosis-associated variation could be detected across datasets. The observation that fibrotic and reference samples consistently separated along latent factors suggested the presence of shared disease-associated signals. For the subsequent biological interpretation, however, we opted for a supervised analysis framework based on differential expression and downstream functional enrichment, which allowed more direct and robust comparisons across organs and disease contexts.

      We will revise the manuscript to make this rationale more transparent to the reader. In addition, we will include an analysis demonstrating that the gene weights associated with the disease-relevant latent factors closely resemble the corresponding organ effect sizes in heart, kidney, and lung, illustrating that biological interpretation at the factor level yields conclusions that are highly consistent with those obtained from the supervised differential expression analysis. This further supports our decision to base the downstream functional analyses on the organ effect sizes, which provide a more straightforward framework for cross-organ comparison.

      Reviewer #1, major comment 4: Although strong organ-specific effects, the author detected similar transcriptional changes in endothelial and mesenchymal cells in heart and lung at Fig. 3B. The analysis on disease-associated fibroblasts also showed much higher overlapped between heart and lung compared to, e.g., liver and kidney in Fig. 4C. Are there additional shared fibrosis features or functions in mesenchymal cells or disease-associated fibroblasts in heart and lung?

      Reviewer #1, major comment 5: There seems to be certain degree of similarities among the epithelial cells in kidney and lung in Fig. 4B.

      Shared response for comments 4 and 5:

      Given the high number of combinations of comparisons, we decided to focus on the most shared signals (mesenchymal and endothelial) in our manuscript. However, as the reviewer notes, there are other comparisons, such as the one between epithelial cells from kidney and lung, or in endothelial cells between heart and lung, that may be important to report. We plan to revise the text in section "Fibrotic disease programs within tissues" to explicitly discuss the observed similarity and plan to additionally show the shared genes driving these similarities in a supplementary Figure in the manuscript.

      Reviewer #1, major comment 8: TNC appears in the lower bottom of the list in Fig. 6C. It is unclear why TNC was chosen as a board therapeutic target in the end.

      We agree that the original wording may have implied that TNC was selected because it was the top-ranked candidate in Figure 6C. This was not our intention. Rather, we chose TNC as an illustrative example because it emerged from our analysis without prior manual prioritization, has already been linked to fibrosis in specific disease contexts, and has been explored experimentally as a therapeutic target. At the same time, its role has not been investigated broadly across fibrotic diseases, making it a useful example of how the presented framework can identify candidates that may have relevance beyond the settings in which they were originally studied.

      We will revise the text to clarify that TNC is presented as one representative example from the set of prioritized candidates rather than as the single most highly ranked therapeutic target.

      Reviewer #1, minor comment 1: Is there additional measure that account for the datasets with lower RNA counts shown in Fig. S1?

      We thank the reviewer for highlighting this potential source of technical variation. We did not apply an additional correction specifically to account for datasets with lower RNA counts. Instead, to minimize the impact of differences in sequencing depth and cell-level sparsity across datasets, the majority of our analyses were performed on pseudobulk profiles rather than individual cells. Pseudobulk aggregation substantially reduces the influence of variation in RNA counts between cells and datasets, providing more robust estimates of gene expression. We therefore believe that differences in RNA counts had a limited impact on the main conclusions of the study. To illustrate this point, we plan on showing additional quality control summary plots for our pseudobulked data.

      Reviewer #2

      Reviewer #2, major comment 3: Fig. 4B-C: the full list of organ-specific and overlapping genes should be given in a supplemental table.

      We thank the reviewer for this suggestion. We agree that providing the complete lists of organ-specific and overlapping genes improves the transparency and utility of the analysis. We will provide the full gene lists underlying Figures 4B-C as supplementary tables in the revised manuscript. These tables will provide the complete set of genes used for the reported overlap analyses and allow readers to further explore the identified organ-specific and shared fibrotic programs.

      Reviewer #2, major comment 6: Cell-cell communications analysis: It would be informative to add a circosplot highlighting the best cell-cell communication candidates in each organ. The authors should also provide the full list of predicted interactions in a supplementary table, including scores for each organ for each interaction. Additionally, it would be important to focus specifically on ligand-receptor pairs associated with growth factors and cytokines. While incorporating Visium data is very interesting and challenging, it may reduce sensitivity due to its relatively poor capture efficiency. This could particularly overemphasize the importance of collagens and other ECM-related factors, which are highly expressed.

      We agree that additional visualization and data availability would improve the presentation of the cell-cell communication analysis. Therefore, we will add additional organ-specific visualizations highlighting the highest-confidence cell-cell communication candidates within each organ, providing a more intuitive overview of the predicted interactions. Second, we plan to include the complete list of predicted ligand-receptor interactions as supplementary tables, including the corresponding scores for each organ and gene annotations (i.e. cytokine, growth factor, etc.), allowing readers to explore the full set of predictions underlying the analyses.

      We also agree that highly expressed extracellular matrix components, such as collagens and proteoglycans, can dominate CCC analyses, especially when investigating fibrotic diseases. Indeed, this consideration motivated our final therapeutic target prioritization strategy (Figure 6). In this analysis, we specifically excluded collagens and proteoglycans, thereby enriching for extracellular signaling molecules that are more likely to represent biologically informative and therapeutically actionable cell-cell communication events. We will modify the results section to clarify our rationale for this analysis.

      Reviewer #2, major comment 8: Visium Dataset Analysis: It would be interesting to compare fibrotic areas across different organs by performing niche or topic analyses using supervised deconvolution approaches (such as RCTD). This would allow for a better estimation of cell composition and functional annotations of fibrotic and inflammatory areas.

      We agree that a cell type deconvolution would provide an informative framework for characterizing the cellular composition of fibrotic niches and its association with the fibrotic signatures we derived from single-cell data. We plan to address the reviewer's suggestion by running a cell type deconvolution analysis of the Visium datasets to estimate the enrichment of major cell populations within scar regions and compare them across organs. We hope that these additional analyses will provide complementary information on the cellular composition of these areas.

      Reviewer #2, minor comment 1: p11: the authors conclude that "cell proportions differed not only between patients and organs, but also that there was no uniform abundance change in disease". This result may reflect technical variability, particularly due to dissociation biases from very different organs or the use of different platforms. This limitation should be discussed.

      We agree that differences in cell type proportions may not only reflect biological variation but can also be influenced by technical factors, including organ-specific dissociation biases, differences in tissue processing, and the use of distinct sequencing platforms. We will expand the text to explicitly acknowledge these potential confounding factors and to emphasize that the observed differences in cell abundances should be interpreted with appropriate caution.

      Reviewer #2, minor comment 3: Panel E in Fig. 5 is difficult to read and needs to be improved.

      To improve the readability of the figure, will include fewer ligand-receptor pairs and additionally add grey boxes in the background to help the reader to better distinguish the ligand-receptor pairs from each other.

      Reviewer #3

      Reviewer #3, minor comment 1: P5: Some context regarding expected differences between single cell and single nuclei datasets here would be good (especially if some differences are potentially important).

      We agree that adding context regarding the expected differences between single cell and single nuclei datasets would add value to the manuscript. These differences have been investigated in the past and were shown to have an impact on the RNA-sequencing results and their interpretations (Van Melkebeke et al. 2024; Lake et al. 2023; Feng et al. 2026; Denisenko et al. 2020; Litviňuková et al. 2020; Koenitzer et al. 2020). We therefore plan to include more background information, including the distinct capture biases and transcriptomic characteristics, to highlight that these differences should be considered when comparing datasets generated using different protocols.

      Reviewer #3, minor comment 6: *P12: Please clarify whether the multicellular factor model is fit jointly across all datasets within an organ, or separately per dataset followed by comparison. If fit jointly, how are batch/study effects handled? If fit separately, how are factors aligned across invocations? *

      Is it possible to say how much of this consistency across datasets is due to non-fibrotic or non-disease state regulation? Are the disease-associated factors driven by coordinated changes across multiple cell types, or primarily by one dominant cell type? And if the latter, is this related to expression magnitude, or cell type abundance?

      We agree that the description of the multicellular factor model in the original manuscript did not provide sufficient methodological detail.

      The multicellular factor model was fitted jointly across all datasets within each organ, resulting in one model per organ (four models in total). Following the strategy proposed in the MOFA+ framework (Argelaguet et al. 2020), individual studies were treated as groups within the model, allowing the integration of multiple datasets while accounting for study-specific effects. Because the model uses cell type-specific pseudobulk profiles as separate views, the inferred factors reflect coordinated transcriptional changes across cell types rather than differences in single-cell abundance. Pseudobulk aggregation substantially reduces the influence of cell number variation, and we applied quality control thresholds to ensure that only samples with sufficient counts for each cell type were included.

      To further clarify the relationship between latent factors and fibrosis, we plan to add an additional analysis showing the proportion of variance explained (R²) by each factor across studies and cell types. The R² can be used as a proxy of the importance of a cell-type in defining the latent factor. Whereas many latent factors capture sources of biological or technical variation unrelated to disease, only a subset consistently separates fibrotic from reference samples. These disease-associated factors therefore represent fibrosis-specific variation rather than general transcriptional structure and are the factors we highlighted in the manuscript text to support that different studies had a consistent disease signal.

      We will incorporate these clarifications into the manuscript to make the modeling framework and its interpretation more transparent and add additional analyses showing the variance explained as extra insights into the models.

      Reviewer #3, minor comment 12: *P23: What conclusions should be drawn from the broad cell-type communication comparisons between organs in Fig. 5A? The text reports which broad cell-type pairs account for many upregulated ligand-receptor interactions, but it is not clear whether these comparisons identify fibrosis-specific communication or mainly reflect broad tissue architecture, cell-type abundance, etc. *

      If the broad categories were chosen because finer cell-state annotations are not consistently available across studies, it would be helpful to state this limitation explicitly.

      We agree that the rationale and interpretation of the broad cell-cell communication analysis should be described more clearly in the manuscript.

      The analysis shown in Figure 5A is based on the organ-specific mixed-effects differential expression models and therefore reflects disease-associated changes in ligand and receptor expression between fibrotic and reference samples, rather than absolute expression levels. Therefore, Figure 5A shows which cell type pairs increase their communication in fibrosis, based on the amount of ligand-receptor pairs that are differentially expressed above a threshold. As the mixed-effects models run per cell type separately, it is unlikely that an increase in cell type proportion causes more upregulated communication events to another cell type with this type of analysis. Overall, we do not see a correlation between increase in cell type proportion in the tissue (Figure 2A) and number of upregulated genes with the mixed effect models (Figure 4A). Therefore, we do not think that cell type proportions have a high effect on this particular analysis.

      We also agree that the use of broad cell type categories warrants clarification. These categories were chosen because they can be robustly harmonized across the diverse datasets included in this meta-analysis, whereas finer cell-state annotations are not consistently available or comparable across studies and organs. We plan to revise the manuscript to clarify both the interpretation of Figure 5A and the rationale for using broad cell type categories in this analysis.

      Reviewer #3, minor comment 14: P31: The therapeutic suggestions should come with some discussion that this is association rather than causation, as it's not established that these are causal drivers. MOXD1 seems compelling, especially if this has been observed to have a potential therapeutic effect in other fibrotic diseases, and this is an excellent outcome that justifies the meta-analysis approach. TNC is somewhat more speculative in this regard, so if there is any mechanistic or other motivations, it would be good to include them here.

      We agree that the therapeutic implications of our findings should be interpreted with appropriate caution, as our analyses identify associations rather than causal drivers of fibrosis.

      These candidates were selected based on the combination of our computational prioritization results and the existing literature, rather than a causal role that has been established by our analysis. Our intention was to provide representative examples of how the presented framework can recover biologically plausible candidates with existing experimental support while simultaneously suggesting their potential relevance across a broader range of fibrotic diseases. We plan to revise the discussion to more clearly emphasize that the proposed therapeutic candidates represent hypothesis-generating observations that require experimental validation.

      Reviewer #3, minor comment 16: P31: It would be nice to have what you think the issues are with the lack of patient metadata, and how these issues might manifest in the analyses (this links with the previous comment regarding disease stage).

      The lack of detailed clinical and histological metadata substantially limits the range of biological and clinical questions that can be addressed, thereby reducing the value that can be extracted from the considerable effort and cost associated with large-scale tissue sequencing studies. In the current study, we are mostly restricted to comparing fibrotic and reference samples because information such as disease stage, fibrosis severity, time since diagnosis, medication, treatment history, tissue sampling location, and other clinical covariates is largely unavailable or inconsistently reported across studies. If these metadata were available, they could be explicitly incorporated into the statistical models, allowing analyses that relate transcriptional changes to clinically relevant variables such as fibrosis severity or disease progression rather than simply disease status.

      Furthermore, additional patient metadata would allow potential confounding factors to be accounted for or controlled in the analysis. For example, treatment effects or other clinical characteristics could be modeled directly or specific patient groups could be excluded where appropriate, leading to a clearer separation of disease-associated biology from technical or clinical confounders.

      We will expand the Discussion to more explicitly describe these limitations and their potential impact on the interpretation of our results.

      Description of the revisions that have already been incorporated in the transferred manuscript

      To facilitate review of the revised manuscript, we have grouped our responses into two categories. First, we address comments that resulted in substantial new analyses, figures, or modifications to the interpretation of the results. Second, we address minor and editorial comments, which have already been directly incorporated into the revised manuscript.

      3.1 Comments requiring additional analyses or substantial revisions

      Reviewer #1

      Reviewer #1, major comment 2: The authors have pooled the data from at least five different disease per organ to identify the pan-fibrosis signature across diseases. Some of the diseases, e.g., pneumonitis, ICM, MI, MCD, ALD) may present more acute remodeling compared to the rest, which might exhibit distinct features that mask the analysis. The extent of fibrosis also varies very significantly. A correlation with histological data is required.

      We agree that fibrotic diseases differ substantially with respect to disease etiology, disease stage, extent of remodeling, and the degree of fibrosis present in the tissue. We had highlighted this as a key limitation of the study in the discussion:

      "Second, the limited availability of patient metadata leaves many aspects unresolved, including the exact diagnosis, disease severity, tissue sampling location, and the extent of fibrosis. If these aspects were better documented, they could be accounted for in the analysis and could allow a clearer distinction of physiological from pathophysiological fibrotic processes. Third, we treated all disease etiologies collectively under the term "fibrosis". However, the degree of fibrotic remodeling likely varies between conditions, and the dataset remains imbalanced in terms of sample representation across organs."

      While comprehensive histological and disease severity information was not consistently available across the published datasets included in our meta-analysis, we were able to further investigate this question in the subset of studies for which fibrosis-related metadata were available. Specifically, we derived organ-specific fibrosis signatures, scored these signatures across patients, and performed a per-study normalization. In these datasets, our derived organ fibrosis scores correlated with available fibrosis severity measurements, supporting the biological relevance of the identified programs (Figure S5A-D).

      In addition, these analyses indicate that fibrosis signature scores vary across disease etiologies, consistent with the reviewer's suggestion that different diseases may exhibit distinct degrees of fibrotic remodeling (Figure S5E). However, given that most of the etiologies are covered by a single study, it is not possible to disentangle these results from the type of controls used by each study and technical variability.

      Nevertheless, because detailed histological and clinical metadata are available only for a limited subset of studies, we believe that a comprehensive analysis of fibrosis severity, disease chronicity, and etiology-specific remodeling is not possible with the currently available data. Future studies with more uniformly annotated patient cohorts will be well-positioned to address these questions in greater depth. Our findings should therefore be interpreted as identifying molecular programs consistently associated with fibrotic disease across diverse conditions, rather than as a direct measure of fibrosis severity itself. We have included these observations in the results section "Identification of shared gene programs per tissue":

      "As multiple disease etiologies and disease stages were integrated in each organ, we asked whether the extracted organ-consensus genes were associated with fibrosis severity. However, fibrosis severity measurements were unavailable for the majority of studies, preventing a systematic assessment of severity across the integrated dataset. To nevertheless evaluate whether the identified programs captured biologically meaningful aspects of fibrosis, we derived organ-specific fibrosis signatures, scored these signatures across patients, and performed a per-study normalization. In datasets containing fibrosis severity measurements, our derived fibrosis signature scores correlated with fibrosis severity, supporting the biological relevance of the identified programs (Figure S5A-D). Furthermore, we observed differences in signature scores across disease etiologies (Figure S5E). However, because disease etiologies were unevenly distributed across studies, it remains difficult to distinguish true biological differences from study-specific technical effects. Overall, these results suggest that there is a part of the fibrotic program that appears to be shared within most tissues, primarily found in endothelial, mesenchymal, and epithelial cells. Furthermore, our findings indicate that the identified organ-consensus programs capture biologically meaningful aspects of fibrosis."

      To explain our methodology, we further added this section to our methods:

      "Fibrosis severity scoring

      To associate the organ-consensus gene signature with fibrosis severity, we first extracted an organ-consensus gene set per organ from the organ-specific gene ranking. Specifically, for each cell type and organ, genes were ranked based on the random-effects meta-analysis estimate obtained from differential expression analyses across studies. Only genes detected in at least three studies were considered for downstream analyses. Positively associated genes were required to have a non-negative upper confidence interval bound and were ranked by decreasing effect size, whereas negatively associated genes were required to have a non-positive upper confidence interval bound and were ranked by increasing effect size. The top 200 positively associated genes and the top 100 negatively associated genes were retained for each cell type-organ combination.

      To give each sample a fibrosis score, pseudobulk profiles were generated for each study by aggregating raw counts across all annotated cells per sample, excluding samples with fewer than three annotated cell types. Pseudobulk count matrices were normalized to 10,000 counts per sample, followed by log-transformation. Gene set activities were inferred per sample using decoupler's (124) (v1.9.0) univariate linear model (ULM) with curated organ-consensus gene sets, yielding enrichment scores for each sample.

      Finally, these enrichment scores were normalized per study: For each study, the mean and standard deviation of enrichment scores were calculated for all control samples. Sample-level scores were then centered against the corresponding study-specific control mean and additionally converted to standardized scores by dividing by the control standard deviation."

      Reviewer #1, major comment 7: The graphs in Fig. S6A do not clearly present how the disease-associated fibroblasts are identified. The true identities of disease should also be plotted in these UMAPs. The results indicating these cells expressed myofibroblast signature should also be shown confirming that these cells are not other mesenchymal cells, e.g., pericytes or smooth muscle cells.

      We agree that the original supplementary figures did not sufficiently illustrate how disease-associated fibroblast populations were identified and distinguished from other mesenchymal cell types. To improve transparency, we have substantially expanded the original Figures S6A-C with four organ-specific supplementary figures (Figures S6-S9). For each organ, we now provide:

      Cluster-level compositional analyses showing changes in abundance between healthy and fibrotic samples. (A) Percentage of mesenchymal cell labels as disease-associated fibroblast (blue) and "rest" per study. (B) Expression of canonical marker genes for myofibroblasts, pericytes, and smooth muscle cells across clusters. (C) The top marker genes for the cluster(s) selected as disease-associated fibroblasts. (C) UMAP visualizations colored by disease etiology and disease condition (fibrosis vs. control), the study, and the original author-provided cell state annotations, including myofibroblast/activated fibroblast annotations where available. (D - G) UMAP visualizations colored by the final annotations used in the subsequent analysis. (H) These additions make the selection procedure substantially more transparent and provide multiple independent lines of evidence supporting the identification of disease-associated fibroblast populations.

      The rationale for the selected clusters is now evident from the revised supplementary figures. In the lung, the selected cluster 3 exhibits a clear increase in abundance in fibrotic samples, expresses canonical myofibroblast markers, and corresponds closely to activated fibroblast/myofibroblast annotations provided in the original studies. In the heart, the selected cluster 1 was the only population showing a robust disease-associated expansion together with strong myofibroblast marker expression and agreement with published annotations. Although another small cluster (cluster 4) displayed partial myofibroblast characteristics, its very low abundance would have a negligible impact on our pseudobulk-based analyses. In the liver, the selected cluster showed consistent expansion across studies and expressed canonical myofibroblast markers, although author-provided annotations were not available for direct comparison. Finally, the kidney datasets presented the greatest integration challenges, likely due to differences between single-cell and single-nucleus protocols. Here, we selected two clusters (cluster 0 and cluster 4) that increased in fibrosis and expressed fibroblast-associated markers, while excluding another expanding cluster (cluster 2) that showed a pericyte-like expression profile. Overall, our final annotations were broadly consistent with the original study annotations wherever such information was available.

      Changes in the manuscript:

      "We integrated the mesenchymal cell population per organ and identified a disease-associated cluster by compositional analysis (Figure 4A, Figures S7-Figure S10)."

      Furthermore, we added the following section to our methods to clarify our methodology:

      "Candidate clusters were required to show consistent enrichment in fibrotic samples and a transcriptional profile characteristic of activated fibroblasts/myofibroblasts. In cases where multiple candidate populations were present, clusters with low abundance or expression profiles inconsistent with myofibroblast identity (e.g., pericyte-like populations) were excluded. Final cluster assignments were validated against the original study annotations whenever available."

      Reviewer #2

      Reviewer #2, major comment 1: Fig.4A: Fibroblast Population Analysis. The authors integrated the fibroblast populations per organ to identify a disease-associated cluster by compositional analysis. In some models, more than one pathological clusters are revealed by the analysis. Shouldn't they be included as pathological, or at least excluded, from the reference population used as a control for differential expression?

      We thank the reviewer for this important comment. We agree that, in some organs, more than one cluster shows features associated with disease and that the selection of disease-associated fibroblast populations should therefore be carefully justified. To improve transparency, we have substantially expanded the supplementary analyses and replaced the original Figures S6A-C with four organ-specific supplementary figures (Figures S7-S10), as described in our answer to Reviewer #1, major comment 7.

      Regarding the reviewer's suggestion to exclude additional potentially pathological clusters from the reference population, we chose not to do so. In many cases, the identity of these secondary clusters is less clear, and excluding them would introduce an additional layer of subjective decision-making that may not necessarily improve robustness. Instead, we used a conservative strategy in which only well-supported disease-associated fibroblast populations were explicitly selected. Furthermore, all downstream analyses of disease-associated fibroblasts were performed using pseudobulk profiles. Because pseudobulk aggregation emphasizes broad transcriptional trends, we expect the resulting signatures to be relatively robust to the inclusion or exclusion of small, ambiguously annotated subpopulations. For these reasons, we believe that retaining the remaining mesenchymal populations in the reference group provides the most objective and reproducible framework for the differential expression analysis.

      For changes in the manuscript associated to this comment, please see our answer to Reviewer #1, major comment 7.

      Reviewer #2, major comment 7: Scar-specific cell-cell communication: Using only COL1A1 as a marker may not be the best option, as this gene is also expressed in normal areas. Suggestion: Use a score combining the best fibrosis-associated genes across the four organs to define fibrotic areas more accurately?

      We thank the reviewer for this suggestion. We agree that COL1A1 is not exclusively expressed in fibrotic regions and can also be detected in normal tissue. To make the analysis more robust, we revised our approach and no longer rely on a single marker gene. Instead, we now compute an enrichment score based on a broader set of established extracellular matrix components, including all collagens and proteoglycans collected by Naba et al. (2012), thereby identifying regions characterized by active matrix deposition rather than expression of COL1A1 alone.

      We then assess the spatial colocalization of candidate ligands and receptors with these ECM-enriched regions across the entire tissue section and focus on the strongest colocalization signals. Importantly, this spatial analysis is subsequently integrated with the disease-associated fibroblast analysis, allowing us to prioritize genes that are both enriched in disease-associated fibroblasts and localized to ECM-rich regions.

      We acknowledge that ECM-rich regions are not necessarily equivalent to fibrotic scar tissue and that some physiologically matrix-producing regions may also be captured by this approach. However, because the analysis is performed across entire tissue sections and multiple independent samples, we expect such regions to contribute primarily as background signal for fibrotic slides. By focusing on the strongest and most consistently colocalizing ligands and receptors across samples, the analysis is designed to identify signals robustly associated with ECM-rich regions rather than being driven by isolated areas of physiological matrix expression.

      We considered the reviewer's suggestion of defining fibrotic regions using fibrosis-associated genes derived from our single-cell analyses. However, we chose not to pursue this strategy because it would introduce a degree of circularity into the analysis. Specifically, the same fibrosis-associated genes would first be used to define fibrotic regions and evaluate for spatial association with candidate ligands and receptors. They would naturally be used again in the gene expression ranking of disease-associated fibroblasts. However, we would like to compare those genes we have found in our meta-analysis with an independent data-modality. Therefore, by instead using an independent ECM-based definition of scar regions, we avoid this potential bias and maintain a clearer separation between the identification of fibrotic regions and the prioritization of disease-associated signaling molecules.

      We compared the results from before (COL1A1-to-gene colocalization) to our results now (ECM enrichment-to-gene colocalization) and found high correlation values between both results for each organ (Review Plan Figure 1). To further show that we expect the pathophysiological ECM signature to largely overshadow physiological ECM expression, we quantified their scores per slide (Figure 6B). We think that our new analysis method is more robust than before, as we now combine several genes into one score.

      We have updated Figure 6 and its text with these new results in our manuscript:

      "To refine these insights, we next focused on identifying ligands and receptors that are specifically expressed in actively scarring regions. We prioritized these molecules because, as extracellular signaling factors and cell-surface proteins, they are directly accessible to therapeutic intervention and therefore represent particularly attractive candidate targets. Structural extracellular matrix molecules were excluded as candidate genes in this analysis and were used instead for the identification of fibrotic scar regions.

      Accordingly, we calculated an ECM enrichment score for each spatial spot, based on a broad set of established structural extracellular matrix components, consisting of all collagens and proteoglycans collected by Naba et al.(Naba et al. 2012). We then computed the spatial colocalization of all remaining ligands and receptors with the identified scarring regions (see methods). Finally, we compared the scar-localization of each gene per organ to the organ-consensus scores of disease fibroblasts (Figure 6A). ECM enrichment scores were significantly elevated in fibrotic compared with control samples across all four organs (Wilcoxon rank-sum test: heart p = 0.005; lung p = 0.002; liver p = 0.014; kidney p = 4e-6, Figure 6B), indicating that pathological extracellular matrix production substantially exceeds physiological ECM turnover. We overall observed a low correlation between scar localization of ligands and receptors and organ effect size in each organ (R in heart = 0.32, liver = 0.38, lung = 0.09, kidney = 0.11), suggesting several cell types and states to be involved in scar-tissue gene expression or a fibrotic gene expression change that goes beyond the scar area (Figure 6C). When comparing the overlap between top ranked genes per organ (upper 20th percentile in gene regulation and colocalization), we observed 8 genes that were identified in 3 out of 4 organs (VIM, TIMP1, FSTL1, CCN2, ANXA2, FBN1, FN1, THBS2), and 2 genes (TIMP2, MRC2) that were identified in all four organs (Figure 6D)."

      Furthermore, we updated Supplementary Figure 12 to include ECM enrichment scores instead of COL1A1 expression.

      Finally, we updated the methods section:

      "To identify actively scarring regions, we performed an enrichment analysis of the geneset consisting of Collagens and Proteoglycans using decoupler's (124) (v1.9.0) univariate linear model (ULM). The spatial colocalization of scarring regions and targets of interest was estimated with the bivariate Moran's R metric implemented in LIANA+ (130) v1.5.0 per target and Visium slide."

      Reviewer #3

      Reviewer #3, minor comment 13: P30: The staging or severity of each of the diseases seems like quite a strong confounder, especially if there is a bias for sampling tissues that are late stage. It would be nice to see this addressed more explicitly in the results, perhaps with some comparisons between those that are identified as earlier and later stage in the respective fibrotic diseases (if these annotations exist).

      We thank the reviewer for raising this important point. We agree that disease stage and severity are potential confounding factors in any meta-analysis of fibrotic diseases and that a bias toward sampling late-stage disease could influence the molecular programs identified.

      Unfortunately, disease staging and fibrosis severity annotations were not consistently available across the published datasets included in our analysis. As a result, we were unable to systematically stratify samples into early- and late-stage disease groups across all organs and disease etiologies. We have therefore highlighted this limitation in the discussion:

      "Second, the limited availability of patient metadata leaves many aspects unresolved, including the exact diagnosis, disease severity, tissue sampling location, and the extent of fibrosis. If these aspects were better documented, they could be accounted for in the analysis and could allow a clearer distinction of physiological from pathophysiological fibrotic processes."

      Nevertheless, we sought to address this concern in the subset of studies for which fibrosis-related severity measurements were available. Specifically, we derived organ-specific fibrosis signatures, scored these signatures across patients, and performed per-study normalization. In these datasets, fibrosis signature scores correlated with available fibrosis severity measurements, supporting the biological relevance of the identified programs (Figure S5A-D). In addition, these analyses indicate that fibrosis signature scores vary across disease etiologies, consistent with the reviewer's suggestion that different diseases may exhibit distinct degrees of fibrotic remodeling (Figure S5E).

      Nevertheless, because detailed histological and clinical metadata are available only for a limited subset of studies, we believe that a comprehensive analysis of fibrosis severity, disease chronicity, and etiology-specific remodeling is beyond the scope of the currently available data and that the currently available metadata are insufficient to robustly compare early- and late-stage disease across the full collection of datasets. We agree that a systematic investigation of stage-specific fibrotic programs would be highly valuable and represents an important direction for future studies using more comprehensively annotated patient cohorts.

      For changes in the manuscript associated to this comment, please see our answer to Reviewer #1, major comment 2.

      3.2 Editorial corrections or clarity improvements

      Reviewer #1

      Reviewer #1, major comment 6: The authors focused on the common functions between mesenchymal and endothelial cells among organs in Fig. 3H and I. Are there cell type specific effects here but shared across organs?

      We thank the reviewer for this question. The results shown in Figures 3H and 3I already represent cell type-specific functional enrichments, as the analyses were performed independently for each cell type before identifying pathways that are consistently altered across organs. Thus, the reported enrichments correspond to cell type-specific effects that are shared across fibrotic diseases in different tissues.

      At the same time, we agree with the reviewer that an interesting observation emerging from these analyses is the overlap in the enriched biological processes identified across different cell types. This suggests that, despite clear cell type-specific transcriptional responses, multiple cell populations converge on a common set of fibrosis-associated pathways. To avoid potential confusion, we have revised the text to clarify that Figures 3H and 3I display cell type-specific enrichments and that the overlap between cell types reflects convergence on shared biological processes rather than identical gene-level responses. Furthermore, we pointed out one difference shown in the plots: the enrichment of neuronal development and axonogenesis pathways in mesenchymal cells.

      "This association with development was further supported by the functional characterization of upregulated genes per organ and cell type."

      [...] "In addition, enrichment of neuronal development and axonogenesis pathways points to activation of projection-related programs, which were not present in the endothelial cell population (Figure 3I). "

      Reviewer #1, major comment 9: It is unclear why only known ligands and receptors are included in the therapeutic target identification analysis in Fig. 6B.

      Our intention was to focus the therapeutic target identification analysis on known ligands and receptors, while excluding major extracellular matrix (ECM) components, because ligands and receptors are generally more amenable to therapeutic intervention and therefore represent particularly attractive candidate targets. To clarify this rationale, we have revised the manuscript text to explicitly describe the criteria used for target selection and the motivation for restricting the analysis to this subset of genes. The corresponding clarification has been added to the results section "Scar-specific cell-cell communication":

      "To refine these insights, we next focused on identifying ligands and receptors that are specifically expressed in actively scarring regions. We prioritized these molecules because, as extracellular signaling factors and cell-surface proteins, they are directly accessible to therapeutic intervention and therefore represent particularly attractive candidate targets. Structural extracellular matrix molecules were excluded as candidate genes in this analysis and were used instead for the identification of fibrotic scar regions."

      Reviewer #1, minor comment 2: The description or legend for the colors is missing in Fig. 3A

      We thank the reviewer for this comment. The color legend was included in the original version of Figure 3A; however, we agree that its placement did not make it sufficiently prominent and may have reduced its visibility. To improve clarity, we have revised the figure layout and repositioned the legend of Figure 3A above the plot so that the color annotation is more readily identifiable.

      Reviewer #1, minor comment 3: FAP appears to be the top gene with robust upregulation in fibrotic heart, lung, liver, and kidney in Fig. 3E, which is also a well-establish surrogate of fibroblast activity and tissue fibrosis in clinical settings (for instance, PMID: 38279381) but not mentioned anywhere in the text.

      We thank the reviewer for highlighting the upregulation of FAP across fibrotic organs. We agree that FAP is a well-established marker of activated fibroblasts and tissue fibrosis and therefore deserves explicit mention at this stage of the analysis. We have revised the text accompanying Figure 3E to highlight FAP as one of the most consistently upregulated genes across organs and to note its established relevance in fibrotic disease:

      "One of the most robustly upregulated genes across organs was prolyl endopeptidase FAP (FAP), a well-established marker gene of activated fibroblasts that has been shown to be functionally relevant in fibrotic diseases in several clinical settings."

      Reviewer #1, minor comment 4: Although it is clear that this study was performed at a much larger scale, the additional gain compared to the previous attempt on identification of shared feature in fibrotic heart, lung, liver, and kidney should be mentioned (PMID: 41752153).

      We thank the reviewer for pointing out this relevant study (PMID: 41752153). We agree that it represents an important previous effort to identify shared features across fibrotic diseases and should be discussed. We have therefore revised the Introduction to acknowledge this work and clarify how the present study extends beyond it. Specifically, while the previous study compared fibrotic heart, lung, liver, and kidney tissues, it was based on a limited number of studies and disease contexts per organ. In contrast, our analysis integrates a substantially larger collection of datasets spanning multiple disease etiologies within each organ, enabling a more systematic assessment of conserved and tissue-specific fibrotic programs across diverse fibrotic diseases.

      • "Recent studies have sought to define shared molecular features across fibrotic diseases affecting the heart, lung, liver, and kidney (15). However, these analyses were based on one study and limited disease contexts per organ, restricting their ability to systematically assess the robustness and generalizability of shared fibrotic programs across diverse disease etiologies."*

      Reviewer #2

      Reviewer #2, major comment 4: Fig.4D: Among this top list, DNM3OS has been indeed characterized as a regulator of the TGF-β pathway in lung fibrosis and should be cited (PMID: 30964696). Interestingly, this lncRNA encodes a cluster of miRNA, including miR-199a-5p, that has been found deregulated in various fibrotic models including lung, kidney and liver (PMID: 23459460).

      We thank the reviewer for highlighting the functional relevance of DNM3OS in fibrosis to improve the manuscript. We checked the literature and agree that its role as a regulator of TGF-β signaling and the involvement of its associated miRNA cluster, including miR-199a-5p, provide important context for interpreting our findings.

      We have therefore expanded the discussion of Fig. 4D and DNM3OS in the manuscript and added the suggested references. Specifically, we now note that DNM3OS was consistently upregulated across organs and that both DNM3OS and its associated miRNA miR-199a-5p have been implicated as downstream effectors of TGF-β signaling involved in myofibroblast activation in lung fibrosis, as well as in experimental models of liver and kidney fibrosis.

      "Furthermore, long noncoding RNA dynamin 3 opposite strand (DNM3OS) was consistently upregulated across organs. DNM3OS and its associated miRNA, miR-199a-5p, have been identified as downstream effectors of TGF-β signaling and implicated in myofibroblast activation in lung fibrosis (76), as well as in experimental mouse models of liver and kidney fibrosis (77)."

      Reviewer #2, major comment 5: Fig. 3F-I and Fig. 4E: the list of the predicted downstream genes for each TF should be provided in a supplemental table

      The transcription factor target gene sets used in these analyses were not generated as part of this study but were obtained from previously published and publicly available regulatory network resources. Because these target gene lists are extensive and already available through the original resource, we did not include them as supplementary tables. To improve transparency and reproducibility, we have revised the manuscript to clearly state the source of these regulatory networks and provide the corresponding reference(s) and access information, allowing readers to retrieve the complete target gene sets used in our analyses. Therefore, in the section "Common aspects of fibrosis across tissues in endothelial and mesenchymal cells", we now state that the collection is publicly available and refer to the methods section:

      "From organ effect sizes, we also inferred transcription factor (TF) activities per organ using CollectTRI (54), a curated publicly available collection of TF-targets, and identified the most commonly upregulated TFs based on the up- or downregulation of the genes they regulate across organs (see methods)."

      In addition, we specifically state in the methods section how the regulons can be accessed:

      "CollecTRI regulons are publicly accessible as described in the original publication (64), for instance at https://zenodo.org/records/8192729?preview_file=CollecTRI_regulons.csv."

      Reviewer #2, minor comment 2: Several panels (Fig.3F-I, Fig.4E-F) need to be improved, in particular the dot plots. with the same order for organs than for the other panels and another range for the size of the dots (-log10 pvalue) to reduce the max size of the dot as well as the enrichment score to expand the value of the z-score.

      We thank the reviewer for these suggestions regarding figure presentation. To improve the readability and consistency of the dot plots, we have made several changes to the figures. We believe these changes substantially improve the interpretability of the figures while preserving the underlying biological signal.

      First, we reordered the organs in Figures 3F-I and 4E-F (see above, in answer to Reviewer #1, minor comment 2 and below, respectively) to match the ordering used throughout the remainder of the manuscript. Second, we expanded the displayed enrichment score range from −2 to 2 to −4 to 4. While many values remain relatively homogeneous, this reflects the fact that these panels were specifically designed to highlight the most consistently shared and strongly regulated signals across organs. Third, we adjusted the dot size scaling for the adjusted p-values. To further improve the visualization of statistical significance, we now explicitly indicate significance using circle outlines: features with an adjusted p-value

      Reviewer #2, minor comment 4: The study is meticulously designed and clearly presented, employing a robust combination of computational approaches. To the reviewer's knowledge, this is the first systematic, cross-organ meta-analysis of fibrosis, offering a comprehensive characterization of both organ-specific and shared gene programs associated with fibrotic processes. A particularly commendable aspect of this work is the provision of a rich and accessible dataset through an interactive data browser, which will serve as a valuable resource for the scientific community at large. The impact of this study is broad and multidisciplinary, benefiting not only computational biologists but also experimental biologists and clinicians working in the field of fibrosis.

      We appreciate the positive assessment of our work and would like to thank the reviewer for recognizing the value of the systematic cross-organ analysis and the interactive data browser. We are pleased that the reviewer considers the study to be a useful resource for the fibrosis research community and appreciates its potential relevance to computational and experimental researchers, as well as clinicians.

      Reviewer #3

      Reviewer #3, minor comment 2: P6: 43 {plus minus} 9 % - this looks a little strange as a percentage, leaving it as a count would probably be clearer as its quite a small number. Please clarify here what 'feature count' here refers to.

      We agree that the notation "43 {plus minus} 9%" may be less intuitive. However, we chose to retain the percentage because it summarizes the proportion of female samples across datasets rather than the total number of samples, which varies substantially between studies. To improve clarity, we removed the variability term and now report only the percentage of samples in the section Data curation for a cross-organ comparison of fibrotic diseases (p.6):

      "In studies with available gender information (16/22 datasets), 43 % of samples were female on average (Figure 1D)."

      In addition, we clarified the meaning of "feature count" by replacing this term with "gene count" throughout the text and in Suppl. Figure 1B.

      Reviewer #3, minor comment 3: P8: Caption: Could you expand a bit upon this 'molecular change severity' in the text?

      We thank the reviewer for pointing this out. We agree that at this point in the manuscript, the concept of "molecular change severity" is not clear yet. It is described later in the manuscript at the beginning of the section "Fibrotic disease programs within tissues" and refers to our analysis with scDist.To make this clearer at its first mention, we have revised the caption to explicitly direct readers to the relevant section and figures. The caption now states:

      "Studies displayed in grey were excluded after an initial assessment of molecular change severity between patient groups, as discussed in the section 'Fibrotic disease programs within tissues' (Figure S2A-D & methods)."

      We believe this addition improves clarity while avoiding duplication of the more detailed explanation provided later in the manuscript.

      Reviewer #3, minor comment 4: Do the author annotated cell types correspond reasonably well with your cell type labels, in those datasets where its present?

      We would like to clarify that we did not perform de novo cell type annotation in the studies except for two. Instead, we used the cell type annotations provided by the original study authors and harmonized them into broader cell type categories based on their names to enable comparisons across studies and organs. The mapping between the original study annotations and these harmonized categories is already provided in Supplementary Table 1. To make this more explicit, the text now states:

      "To enable a comparison across tissues, we grouped cells into five broad categories based on the author's annotations: endothelial-, epithelial-, mesenchymal-, lymphoid-, and myeloid cells (mappings available in Suppl. Table 1)."

      Furthermore, the consistency of these annotations was assessed by examining the expression of cell type marker genes, as shown in Figure 1F, which supports the validity of the harmonized cell type labels used throughout the study.

      Reviewer #3, minor comment 5: P11: A little more information on scDist and what the distances are calculated based on would be good here.

      We thank the reviewer for this suggestion. We agree that the original description did not sufficiently explain how ScDist quantifies molecular differences between conditions. We have therefore expanded the text to clarify that ScDist is a mixed-effects modeling framework and that larger distances correspond to stronger disease-associated transcriptional perturbations:

      "To do so, we applied ScDist (36), a mixed-effects modeling framework that quantifies transcriptomic differences between conditions while accounting for donor-to-donor variability (see methods). For each cell type, ScDist estimates a distance in gene expression space between healthy and fibrotic cells, with larger values indicating stronger disease-associated transcriptional changes."

      Furthermore, we added to the methods:

      "To assess disease-associated transcriptional shifts within each cell type, we applied scDist (v1.1.2) (117) to estimate transcriptional distances between fibrotic and control samples. ScDist assesses disease-associated transcriptional shifts within each cell type by using a linear mixed-effects model that separates condition-associated transcriptional changes from inter-individual variability by including the disease condition as a fixed effect and donor-specific variation as a random effect."

      Reviewer #3, minor comment 7: P14: Are these genes known to be implicated in fibrotic diseases? I know that this is discussed further later, but a few words here would be good.

      We added some context to some of the mentioned genes into the text:

      ** "Notably, several of the highest-ranked genes by our analysis are well-established stress-response and fibrosis markers, such as POSTN38,39, SPP140, VCAN41,42, COL15A121, C343,44, FABP445, and VWF46,47, providing confidence that the identified signatures capture true disease processes instead of study-specific occurrences."

      Reviewer #3, minor comment 8: P17: Fig 3H: enrichment -> enrichment score? (same elsewhere)

      We thank the reviewer for noting this ambiguity. We agree that the term "enrichment" was imprecise in this context. To improve clarity and consistency, we have revised the figure legends of Fig 3 F-I and Fig 4 E-F to explicitly refer to the reported metric as the enrichment score rather than simply enrichment. The updated figure 3 can be found in our answer to Reviewer #1, minor comment 2, the updates to Figure 4 in our answer to Reviewer #2, minor comment 2.

      Reviewer #3, minor comment 9: P19: ULM is used a few times in the captions, but only ever defined in the methods.

      We agree that the abbreviation ULM was not sufficiently defined in the main text and figure legends. To improve readability, we now define the term ULM as univariate linear model at its first occurrence in the figure legends (Figure 3I, page 18).

      The figure caption now reads:

      "For F-I: Dots show the enrichment score (positive: upregulated in fibrosis), while sizes show the -log10 of the adjusted p-values of univariate linear model (ULM) enrichments."

      Reviewer #3, minor comment 10: P20: 'disease relevant cell states' - this might need rewording to better reflect the compositional analysis, and not imply that this identifies cell states rather than clusters of cells.

      We agree that compositional analysis formally identifies cell clusters enriched in disease rather than directly establishing biological cell states. We have revised the text to refer to disease-associated mesenchymal populations/clusters identified through compositional analysis rather than "disease-relevant cell states":

      "To identify disease-associated mesenchymal subpopulations in our datasets, we integrated the mesenchymal cell population per organ and identified a disease-associated cluster by compositional analysis"

      "We also explored disease-associated mesenchymal subpopulation-specific gene expression and the spatial localization of ligands and receptors."

      Reviewer #3, minor comment 11: P22: Fig 4D: This could do with more dynamic range on the colour axis, as most things are near or above the scale.

      We thank the reviewer for this suggestion & agree that the original color scale provided limited visual separation between highly concordant features. We note that this is, in part, a consequence of the panel's design, as Figure 4D specifically highlights genes that are consistently and strongly regulated across organs and therefore exhibit relatively similar effect sizes. Nevertheless, to improve visual discrimination, we have adjusted the color scale of Figure 4D (and similarly, Figure 3 D and E) to provide greater dynamic range and enhance the visibility of differences between genes while preserving the underlying data. We believe this modification improves the interpretability of the figures. The new figures 3 and 4 can be found in our answers to Reviewer #1, minor comment 2 and Reviewer #3, minor comment 8, respectively.

      Reviewer #3, minor comment 15: It would be nice to keep the gene naming schemes consistent (i.e., MOXD1 and TNC), especially within the same discussion.

      We thank the reviewer for this suggestion and agree that consistent gene nomenclature improves readability. We have therefore revised the discussion text to use a consistent naming.

      Reviewer #3, minor comment 17: 'some studies have highlighted the disease-relevance of specific cell states' -> please cite

      To support this statement, we have added the appropriate references describing disease-relevant cell states in fibrotic tissues:

      "Lastly, with exception to the mesenchymal cell population, our analysis primarily focused on broad cell type categories, even though some studies have highlighted the disease-relevance of specific cell states (22, 73,74,7,75,33)".

      Reviewer #3, minor comment 18: Code availability: I think the 'fi' digraph in the link for https://github.com/saezlab/organfibrosis breaks it, but after correcting it manually I can access the repository.

      We thank the reviewer for noting this issue. The hyperlink functions correctly in the submitted manuscript PDF, but we are not sure in which format the reviewer received the manuscript. We will work with the editorial team during the publishing process to ensure that the repository link will be displayed correctly and remains fully accessible in the published version.

      Description of analyses that authors prefer not to carry out

      Reviewer #1

      -

      Reviewer #2

      Reviewer #2, major comment 2: Myeloid Cell Analysis: given the importance of myeloid cells in fibrotic processes, particularly the origin of pathological cells (often monocyte-derived macrophages), it would be highly informative to adopt a similar approach to determine whether myeloid subpopulations differ depending on the affected organ.**

      We thank the reviewer for this suggestion and agree that myeloid cells play a critical role in fibrosis. A systematic comparison of disease-associated myeloid states across organs would therefore be highly valuable. In the present study, however, we chose to focus our state-level analysis on mesenchymal cells because they represent the principal effector population responsible for extracellular matrix deposition and scar formation across fibrotic diseases and because they showed a promising overlap between tissues at the broad cell type level. In contrast, our cross-organ analyses indicate weaker transcriptional conservation among myeloid cells (highest cross-organ disease score prediction AUROC mesenchymal: 0.88; myeloid: 0.72), suggesting that organ-specific immune responses may contribute more strongly than shared fibrosis-associated programs.

      Moreover, our integrated dataset combines both single-cell and single-nucleus sequencing studies, which are known to differ in transcript capture and cell type recovery, especially in immune cells (Feng et al. 2026; Van Melkebeke et al. 2024b; Denisenko et al. 2020). These technical differences already complicated the robust comparison of mesenchymal populations, and we expect they would present an even greater challenge for the identification and comparison of fine-grained myeloid cell states across studies and organs. We therefore chose to focus our detailed state-level analysis on mesenchymal populations, where the biological question was most directly aligned with the central objective of identifying conserved fibrogenic programs across organs.

      Therefore, extending the same analysis to myeloid populations would require a comprehensive integration, annotation, and validation effort that would substantially expand the scope of the current study. We therefore chose to focus our in-depth state-level analysis on the mesenchymal compartment, which is most directly aligned with the central objective of identifying conserved fibrogenic programs across organs.

      Reviewer #3

      -

      References

      Argelaguet, Ricard, Damien Arnol, Danila Bredikhin, et al. 2020. "MOFA+: A Statistical Framework for Comprehensive Integration of Multi-Modal Single-Cell Data." Genome Biology 21 (1): 111. https://doi.org/10.1186/s13059-020-02015-1.

      Denisenko, Elena, Belinda B. Guo, Matthew Jones, et al. 2020. "Systematic Assessment of Tissue Dissociation and Storage Biases in Single-Cell and Single-Nucleus RNA-Seq Workflows." Genome Biology 21 (1): 130. https://doi.org/10.1186/s13059-020-02048-6.

      Feng, Xue, Yu Feng, Sayed Haidar Abbas Raza, Yun Ma, and Hongyu Deng. 2026. "Single Cell and Single Nucleus RNA Sequencing in Liver Tissues: Applications and Prospects in Model and Non-Model Organisms." Frontiers in Genetics 17 (April): 1781941. https://doi.org/10.3389/fgene.2026.1781941.

      Koenitzer, Jeffrey R., Haojia Wu, Jeffrey J. Atkinson, Steven L. Brody, and Benjamin D. Humphreys. 2020. "Single-Nucleus RNA-Sequencing Profiling of Mouse Lung. Reduced Dissociation Bias and Improved Rare Cell-Type Detection Compared with Single-Cell RNA Sequencing." American Journal of Respiratory Cell and Molecular Biology 63 (6): 739-47. https://doi.org/10.1165/rcmb.2020-0095MA.

      Lake, Blue B., Rajasree Menon, Seth Winfree, et al. 2023. "An Atlas of Healthy and Injured Cell States and Niches in the Human Kidney." Nature 619 (7970): 585-94. https://doi.org/10.1038/s41586-023-05769-3.

      Litviňuková, Monika, Carlos Talavera-López, Henrike Maatz, et al. 2020. "Cells of the Adult Human Heart." Nature 588 (7838): 466-72. https://doi.org/10.1038/s41586-020-2797-4.

      Naba, Alexandra, Karl R. Clauser, Sebastian Hoersch, Hui Liu, Steven A. Carr, and Richard O. Hynes. 2012. "The Matrisome: In Silico Definition and In Vivo Characterization by Proteomics of Normal and Tumor Extracellular Matrices*." Molecular & Cellular Proteomics 11 (4): M111.014647. https://doi.org/10.1074/mcp.M111.014647.

      Van Melkebeke, Lukas, Jef Verbeek, Dora Bihary, et al. 2024a. "Comparison of the Single-Cell and Single-Nucleus Hepatic Myeloid Landscape within Decompensated Cirrhosis Patients." Frontiers in Immunology 15 (February). https://doi.org/10.3389/fimmu.2024.1346520.

      Van Melkebeke, Lukas, Jef Verbeek, Dora Bihary, et al. 2024b. "Comparison of the Single-Cell and Single-Nucleus Hepatic Myeloid Landscape within Decompensated Cirrhosis Patients." Frontiers in Immunology 15 (February). https://doi.org/10.3389/fimmu.2024.1346520.

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      Referee #3

      Evidence, reproducibility and clarity

      This paper describes an integrated analysis of several single cell and spatial RNA sequencing datasets to uncover common programs within fibrotic diseases. Many of the signals observed in the scRNA-seq analysis are related to the ECM, and therefore the authors specifically use spatial sequencing data from each of the tissues to investigate local cell-cell communication with fibrotic scar regions. Using this analysis, the authors propose several potential therapeutic targets, and provide an interactive web app to view the results of their analyses.

      I would like to congratulate the authors on a well written and interesting manuscript. I have no major concerns regarding the paper as a whole, but I think several points would benefit from clarification, particularly around interpretation of disease heterogeneity and the therapeutic implications.

      Results

      p5:

      Some context regarding expected differences between single cell and single nuclei datasets here would be good (especially if some differences are potentially important).

      p6:

      43 {plus minus} 9 % - this looks a little strange as a percentage, leaving it as a count would probably be clearer as its quite a small number.

      Please clarify here what 'feature count' here refers to.

      p8:

      Caption: Could you expand a bit upon this 'molecular change severity' in the text?

      Do the author annotated cell types correspond reasonably well with your cell type labels, in those datasets where its present?

      p11:

      A little more information on scDist and what the distances are calculated based on would be good here.

      p12:

      Please clarify whether the multicellular factor model is fit jointly across all datasets within an organ, or separately per dataset followed by comparison. If fit jointly, how are batch/study effects handled? If fit separately, how are factors aligned across invocations?

      Is it possible to say how much of this consistency across datasets is due to non-fibrotic or non-disease state regulation? Are the disease-associated factors driven by coordinated changes across multiple cell types, or primarily by one dominant cell type? And if the latter, is this related to expression magnitude, or cell type abundance?

      p14:

      Are these genes known to be implicated in fibrotic diseases? I know that this is discussed further later, but a few words here would be good.

      p17:

      Fig 3H: enrichment -> enrichment score? (same elsewhere)

      p19:

      ULM is used a few times in the captions, but only ever defined in the methods.

      p20:

      'disease relevant cell states' - this might need rewording to better reflect the compositional analysis, and not imply that this identifies cell states rather than clusters of cells.

      p22:

      Fig 4D: This could do with more dynamic range on the colour axis, as most things are near or above the scale.

      p23:

      What conclusions should be drawn from the broad cell-type communication comparisons between organs in Fig. 5A? The text reports which broad cell-type pairs account for many upregulated ligand-receptor interactions, but it is not clear whether these comparisons identify fibrosis-specific communication or mainly reflect broad tissue architecture, cell-type abundance, etc.

      If the broad categories were chosen because finer cell-state annotations are not consistently available across studies, it would be helpful to state this limitation explicitly.

      p30:

      The staging or severity of each of the diseases seems like quite a strong confounder, especially if there is a bias for sampling tissues that are late stage. It would be nice to see this addressed more explicitly in the results, perhaps with some comparisons between those that are identified as earlier and later stage in the respective fibrotic diseases (if these annotations exist).

      p31:

      The therapeutic suggestions should come with some discussion that this is association rather than causation, as it's not established that these are causal drivers. MOXD1 seems compelling, especially if this has been observed to have a potential therapeutic effect in other fibrotic diseases, and this is an excellent outcome that justifies the meta-analysis approach. TNC is somewhat more speculative in this regard, so if there is any mechanistic or other motivations, it would be good to include them here.

      It would be nice to keep the gene naming schemes consistent (i.e., MOXD1 and TNC), especially within the same discussion.

      p31:

      It would be nice to have what you think the issues are with the lack of patient metadata, and how these issues might manifest in the analyses (this links with the previous comment regarding disease stage).

      'some studies have highlighted the disease-relevance of specific cell states' -> please cite

      Code availability: I think the 'fi' digraph in the link for https://github.com/saezlab/organfibrosis breaks it, but after correcting it manually I can access the repository.

      Significance

      This is a well-presented analysis of single-cell, single-nucleus, and spatial transcriptomics data derived from patients with a range of fibrotic diseases, with the aim of developing an integrated description of fibrosis-associated programs across organs. This integrated analysis is used to nominate potential therapeutic targets, many of which are compatible with current understanding of fibrosis and therefore provide validity for the approach. The results are also made available through a web application that can be queried easily.

      The main limitations of the study arise from the nature and heterogeneity of the available data. In particular, limitations in dataset composition and clinical annotation mean that important aspects such as disease progression, severity, sampling location, and fibrosis stage cannot be systematically studied.

      The novelty of the study lies in its cross-organ, gene-centric integration of fibrotic disease datasets across a sizeable patient cohort, including analyses of inferred interactions between broad cell-type compartments. This provides a useful precursor to deeper mechanistic studies of fibrotic regulation, and a resource for researchers interested in fibrosis-associated signatures and candidate mechanisms. More generally, it is a good example of how public datasets can be integrated within systems biomedicine.

      My background is in computational biology and biophysics.

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      Referee #2

      Evidence, reproducibility and clarity

      The article by Küchenhoff et al. presents a comprehensive meta-analysis of single-cell transcriptomic data from healthy and fibrotic human tissues encompassing 20 studies and 25 disease etiologies across the heart, liver, kidney, and lung. They identified organ-specific as well as cross-organ fibrosis-associated gene expression profiles in major cell types including fibroblasts, epithelial, endothelial and immune cells. Additionally, they also conduct a focused analysis on transcription factors and intercellular communication patterns in fibrotic regions, supported by both scRNA-seq and spatial transcriptomics data.

      The study is well-designed and clearly presented, with a robust combination of computational approaches that enhance the characterization of both organ-specific and shared gene programs in fibrosis. The authors also provide a rich and accessible dataset through an interactive data browser, which will be highly useful for the scientific community. While most of the data are convincing, some clarifications and improvements are needed, as detailed below.

      Major comments:

      • Fig.4A: Fibroblast Population Analysis. The authors integrated the fibroblast populations per organ to identify a disease-associated cluster by compositional analysis. In some models, more than one pathological clusters are revealed by the analysis. Shouldn't they be included as pathological, or at least excluded, from the reference population used as a control for differential expression?
      • Myeloid Cell Analysis: given the importance of myeloid cells in fibrotic processes, particularly the origin of pathological cells (often monocyte-derived macrophages), it would be highly informative to adopt a similar approach to determine whether myeloid subpopulations differ depending on the affected organ.
      • Fig. 4B-C: the full list of organ-specific and overlapping genes should be given in a supplemental table.
      • Fig.4D: Among this top list, DNM3OS has been indeed characterized as a regulator of the TGF-β pathway in lung fibrosis and should be cited (PMID: 30964696). Interestingly, this lncRNA encodes a cluster of miRNA, including miR-199a-5p, that has been found deregulated in various fibrotic models including lung, kidney and liver (PMID: 23459460).
      • Fig. 3F-I and Fig. 4E: the list of the predicted downstream genes for each TF should be provided in a supplemental table
      • Cell-cell communications analysis: It would be informative to add a circosplot highlighting the best cell-cell communication candidates in each organ. The authors should also provide the full list of predicted interactions in a supplementary table, including scores for each organ for each interaction. Additionally, it would be important to focus specifically on ligand-receptor pairs associated with growth factors and cytokines. While incorporating Visium data is very interesting and challenging, it may reduce sensitivity due to its relatively poor capture efficiency. This could particularly overemphasize the importance of collagens and other ECM-related factors, which are highly expressed.
      • Scar-specific cell-cell communication: Using only COL1A1 as a marker may not be the best option, as this gene is also expressed in normal areas. Suggestion: Use a score combining the best fibrosis-associated genes across the four organs to define fibrotic areas more accurately?
      • Visium Dataset Analysis: It would be interesting to compare fibrotic areas across different organs by performing niche or topic analyses using supervised deconvolution approaches (such as RCTD). This would allow for a better estimation of cell composition and functional annotations of fibrotic and inflammatory areas.

      Minor comments:

      • p11: the authors conclude that "cell proportions differed not only between patients and organs, but also that there was no uniform abundance change in disease". This result may reflect technical variability, particularly due to dissociation biases from very different organs or the use of different platforms. This limitation should be discussed.
      • Several panels (Fig.3F-I, Fig.4E-F) need to be improved, in particular the dot plots. with the same order for organs than for the other panels and another range for the size of the dots (-log10 pvalue) to reduce the max size of the dot as well as the enrichment score to expand the value of the z-score.
      • Panel E in Fig. 5 is difficult to read and needs to be improved.
      • Figure Improvements: Fig. 3F-I and Fig. 4E-F: The dot plots could be improved by i) using the same order for organs as in other panels for consistency; ii) adjusting the dot size scale (-log10 p-value) to reduce the maximum dot size and expand the range of enrichment scores (z-score). Fig. 5E: This panel is difficult to read and needs improvement for clarity.

      Referees cross-commenting

      I agree with the comments made by the other reviewers, who effectively highlight the merits and value of this study and point out a few issues for improvement or clarification.

      Significance

      The study is meticulously designed and clearly presented, employing a robust combination of computational approaches. To the reviewer's knowledge, this is the first systematic, cross-organ meta-analysis of fibrosis, offering a comprehensive characterization of both organ-specific and shared gene programs associated with fibrotic processes.

      A particularly commendable aspect of this work is the provision of a rich and accessible dataset through an interactive data browser, which will serve as a valuable resource for the scientific community at large. The impact of this study is broad and multidisciplinary, benefiting not only computational biologists but also experimental biologists and clinicians working in the field of fibrosis.

      Reviewer's expertise: The reviewer has extensive experience in functional genomics and fibrosis research, including single-cell-based approaches, but is not specialized in bioinformatics.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      Küchenhoff and co-authors aimed to explore the shared and organ-specific gene expression profiles in tissue fibrosis by integrative analysis on 20 publicly available scRNA-Seq datasets obtain from human heart, liver, lung, and kidney. Despite strong organ-specific effects, they identified consensus fibrosing gene signature across different disease etiologies within and among organs. Shared gene expression profiles across organs were enriched in endothelial and mesenchymal cells. Analysis focused on a subset of fibrosis-enriched fibroblasts revealed consistent upregulation of collagen-related pathways and dysregulation of developmental-related transcription factors across organs. Cell-cell communication analysis detected robust upregulations ECM-integrin interactions between mesenchymal and endothelial cells in multiple organs. The authors further proposed several targets based on spatial co-expression with COL1A1 in Visium datasets and previous analysis based on scRNA-Seq. They also made their results publicly available and easily accessible through a web dashboard.

      Major comments:

      1. The group has been developing cutting edge bioinformatic tools for the community. The authors also provided scripts and the processed for reproducibility. I have no doubt in their implementation of the methodology. I also understand the reasons of the objective tone throughout the manuscript. However, the authors made very little claims with biological significance. The conclusion of the study is vague with almost nothing mentioned in the abstract. What are the cross-organ effects in fibrosis identified in this study? I believe some additional claims would facilitate the reader with less technical knowledge to grasp the study better.
      2. The authors have pooled the data from at least five different disease per organ to identify the pan-fibrosis signature across diseases. Some of the diseases, e.g., pneumonitis, ICM, MI, MCD, ALD) may present more acute remodeling compared to the rest, which might exhibit distinct features that mask the analysis. The extent of fibrosis also varies very significantly. A correlation with histological data is required.
      3. The authors performed multicellular factor modeling in each organ and identified factors that are distinct in fibrotic and reference tissue in Fig. 2B, e.g., factors 1 and 2 in heart. Are these factors driven by specific biological pathways? Could these factors also be used to identify common biological functions in fibrotic tissue across organs?
      4. Although strong organ-specific effects, the author detected similar transcriptional changes in endothelial and mesenchymal cells in heart and lung at Fig. 3B. The analysis on disease-associated fibroblasts also showed much higher overlapped between heart and lung compared to, e.g., liver and kidney in Fig. 4C. Are there additional shared fibrosis features or functions in mesenchymal cells or disease-associated fibroblasts in heart and lung?
      5. There seems to be certain degree of similarities among the epithelial cells in kidney and lung in Fig. 4B.
      6. The authors focused on the common functions between mesenchymal and endothelial cells among organs in Fig. 3H and I. Are there cell type specific effects here but shared across organs?
      7. The graphs in Fig. S6A do not clearly present how the disease-associated fibroblasts are identified. The true identities of disease should also be plotted in these UMAPs. The results indicating these cells expressed myofibroblast signature should also be shown confirming that these cells are not other mesenchymal cells, e.g., pericytes or smooth muscle cells.
      8. TNC appears in the lower bottom of the list in Fig. 6C. It is unclear why TNC was chosen as a board therapeutic target in the end.
      9. It is unclear why only known ligands and receptors are included in the therapeutic target identification analysis in Fig. 6B.

      Minor comments:

      1. Is there additional measure that account for the datasets with lower RNA counts shown in Fig. S1?
      2. The description or legend for the colors is missing in Fig. 3A
      3. FAP appears to be the top gene with robust upregulation in fibrotic heart, lung, liver, and kidney in Fig. 3E, which is also a well-establish surrogate of fibroblast activity and tissue fibrosis in clinical settings (for instance, PMID: 38279381) but not mentioned anywhere in the text.
      4. Although it is clear that this study was performed at a much larger scale, the additional gain compared to the previous attempt on identification of shared feature in fibrotic heart, lung, liver, and kidney should be mentioned (PMID: 41752153).

      Significance

      This is the first study reporting the transcriptomic changes in tissue fibrosis in heart, lung, liver, and kidney at large scale across different diseases in a cell type specific manner. This study implemented state-of-the-art bioinformatics that not only focus on shared feature among organs, but also the similarities across organs. The manuscript highlights the similar molecular changes within endothelial and mesenchymal cells, especially from heart and lung. The authors performed spatial co-expression with COL1A1, further increase the robustness of target identification for fibrotic core. The authors further made their results public available, which would benefit fibrosis research community and facilitate the development of therapeutics against tissue fibrosis.

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      Referee #3

      Evidence, reproducibility and clarity

      The work describes an optofluidic automation setup to optically inhibit and enrich selected bacterial populations in confined microchannels through negative selection using light stimulation. The work is well described and the manuscript is well constructed.

      major comment: The authors reported that methylene blue with 2uM incubation has superior performance than UV light. But it's also noted on line 152 there is an inhibition effect from the chemical affecting ~40% of the growth rate. It will be noteworthy what is the growth curve or at least the MIC of methylene blue used on the MG1655 E. coli by the authors.

      Minor:

      Figure 3A has examined the off-target growth rate effects. Statistics were made as shown in the subfigure. However, the details of the statistical inference seems to be missed in the materials and methods. Figure 4D highlights the novelty of the work to enrich mCherry E.coli population by selectively inhibiting GFP populations. However, this figure is lacking error bars which should be available given the population data. I would applaud the authors to describe the optical setup in good detail. However, since the throughput of the mother machine microfluidic device and the FOV throughput were discussed in the discussion. From Fig.S1 the mother machine device seems of special design. A more detailed description of the trench dimension, depth, and number of trenches on each device is warranted.

      Significance

      The optics part of the work is well described, however the materials and methods details of the biological and microfluidic part can be extended. Overall the system demonstrated the practical use of combining microfluidics for enrichment of microbial population as an novel alternative method, despite that the efficiency is currently subpar to conventional methods.

      But combining further with deep learning phenotype or growth rate monitoring, the technology represents a new path for phenotypic selection which is also novel that conventional methods cannot offer. The work will benefit readers in applied science seeking for new target enrichment based on optofluidics.

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      Referee #2

      Evidence, reproducibility and clarity

      In this manuscript, the authors reported Microscopic PhotoSelection (MiPS), a closed-loop automated robotic platform designed to link time-resolved imaging with physical sample recovery in mother machine microfluidic devices. By pairing a standard mother machine layout with a custom DMD optical path, an LED array, and an optimized DeLTA deep-learning model, the system tracks dynamic single-cell phenotypes and isolates specific cells via automated, targeted phototoxicity, i.e. selection by elimination. This is a novel technical development that addresses a clear limitation of snapshot sorting methods like FACS or MACS when screening for time-resolved, lineage-dependent traits. However, several methodological limitations and presentation errors must be addressed before publication.

      Major Comments

      1. Definition of 'Optimal' Dose (Figure 2D): The authors identify 8.0 W*cm-2 UV light for 300s as the optimal condition. However, this data point lies at the absolute boundary of the tested parameter space. In classical dose-response characterization, an optimum is defined by a local peak or a plateau followed by a decline in performance (typically due to rising off-target toxicity or scatter). Because the performance curve has not rolled over, this represents a boundary condition rather than a demonstrated mathematical optimum. The authors should either extend the parameter sweep to locate the true peak or soften their language to reflect that this is simply the highest performing condition tested.
      2. UV Exposure Time Gap: The exposure time sweep skips directly from 60s to 300s. While the closely spaced early timepoints are appropriate for capturing initial cell-death kinetics, the large gap to 300s leaves a significant engineering blind spot. Figure 3D demonstrates that off-target scattering damage scales linearly with cumulative light energy. If complete target cell arrest can be achieved at an intermediate exposure (e.g., 120s, 180s or 240s), operating the system at 300s unnecessarily subjects neighboring "surviving" cells to secondary global UV stress via device-wide scattering. An intermediate temporal sweep is recommended to optimize the selection window and properly balance target lethality with background library viability.
      3. Baseline Chemical Toxicity of Methylene Blue (MB): The photosensitizer workflow shows a clear improvement in contrast at lower power densities and exposure times. However, lines 151-153 note that the addition of 2 uM MB alone, even without light activation, stunts the baseline bacterial growth rate by ~40%. This is a major biological confounder. For applications like directed evolution or dynamic physiological screening, introducing a chemical stressor that nearly halves fitness imposes an unintended selective pressure. This baseline stress may activate pathways that mask or alter the phenotypes of interest. The authors must expand their discussion on how this baseline toxicity impacts multi-round iterative selections, and should ideally evaluate lower concentrations (e.g., 0.5uM or 1uM) or alternative photosensitizers to identify a more viable operational window.
      4. Negative Selection Framework and Search Space Scale: The MiPS platform relies entirely on negative selection by destroying unwanted variants. While effective for the demonstrated 1:1 binary proof-of-concept mixture, negative selection scales poorly when screening for rare variants within large libraries. For instance, isolating a single high-performer from a library of 105 cells requires the system to successfully target and kill 99,999 individual cells; any statistical leak or failure in killing efficiency directly leads to heavy contamination of the recovered sample. The Discussion section requires a quantitative evaluation of these search space constraints, outlining how they limit the system's utility compared to positive selection mechanisms (such as optical tweezers or droplet sorters) when scaling to rare mutations (<1 in 104).

      Minor and Typographical Comments

      1. Missing Figure 2F: On page 6, line 150, the text explicitly cites Figure 2F to justify the 5-fold reduction in exposure duration for the MB photosensitizer workflow. However, Figure 2 ends at panel E. The authors must either supply the missing panel or correct the text reference.
      2. Textual Corrections:

      a. Line 224: "At reach round of the simulation..." should read "At each round..."

      b. Line 285: "By observing cells over longer durations and averaging the measurements, resulting in a readout closer to the "true" selected phenotype." This is a grammatically incomplete sentence fragment. Please revise for proper syntax.

      c. Line 302: "...these advantages highight MiPS as an enabler..." Typo in "highight"; change to "highlight."

      Significance

      This study presents a significant methodological advance in single-cell analysis and microfluidics by integrating long-term live-cell imaging, automated image analysis, and phenotype-guided cell recovery into a closed-loop platform. Existing approaches such as FACS and MACS are largely limited to endpoint or snapshot measurements, whereas MiPS enables selection based on dynamic and lineage-dependent cellular behaviors, thereby addressing an important gap in current single-cell screening technologies.

      A key strength is the effective integration of mother machine microfluidics, custom optics, and deep-learning-based tracking into an automated and functional system. While the individual components are established, their combination into a phenotype-driven selection platform is innovative and expands the utility of live-cell microscopy from passive observation to active cell selection. The advance is therefore primarily methodological and technological, with potential to enable future conceptual discoveries in cellular heterogeneity and lineage dynamics.

      However, limitations remain regarding scalability, robustness, selection accuracy, and generalizability across biological systems. Additional benchmarking and validation would strengthen the work further.

      Overall, the study will be of interest to researchers in microfluidics, single-cell biology, microbial systems biology, bioengineering, quantitative imaging, and synthetic biology.

      My expertise is in microfluidics, cell sorting and disease mechanobiology.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      The authors present MiPS, a platform combining DMD-based patterned illumination, automated microscopy, retrained DeLTA segmentation, and mother-machine microfluidics to selectively inhibit or eliminate cells based on dynamic phenotypes. The system enables targeted UV or red-light illumination in real time using segmentation-informed projection masks, allowing selective enrichment directly within mother-machine devices. The manuscript demonstrates proof-of-concept enrichment of mCherry cells from mixed GFP/mCherry populations, characterizes off-target effects, and performs computational simulations of iterative enrichment rounds. Overall, the engineering and systems integration are impressive, and the platform has strong potential for applications in directed evolution, biosensor optimization, and dynamic phenotype-based selection workflows.

      Overall, I believe the work is suitable for publication after minor revisions and clarification of several aspects of the manuscript. In particular, the paper would benefit from additional context in the Introduction and Methods sections, clearer positioning relative to existing platforms, improved figure readability/captions, and a more careful revision of the English throughout the manuscript.

      Major comments:

      1. The manuscript should better position MiPS relative to recent microscopy-based and DMD-enabled selection/control systems, particularly Lugagne et al., Nature Communications (2024), DOI: 10.1038/s41467-024-46361-1. That work also combines mother-machine microfluidics, DeLTA-based real-time image analysis, and DMD projection. The key distinction here appears to be physical selection/enrichment through targeted killing rather than optogenetic control, and this difference should be stated more explicitly.
      2. The manuscript currently compares MiPS mostly to FACS/MACS. However, the more relevant comparison may be recent image-based and microfluidic photoselection systems. A dedicated comparison table discussing throughput, temporal phenotyping, iterative selection, dynamic phenotype tracking, and enrichment capabilities would strengthen the paper.
      3. The enrichment experiment in Figure 4 represents a relatively simple classification problem (GFP vs mCherry). Since the proposed applications involve subtle continuous phenotypes, it would considerably strengthen the manuscript to include at least one experiment selecting for high vs. low expressors within a single fluorescent reporter population.
      4. The strongest enrichment result (~170-fold enrichment in Figure 5) is entirely simulation-based. Since the manuscript already states that ~45 min is sufficient between rounds for growth evaluation, a real 2-3-round enrichment experiment seems feasible and would substantially strengthen the platform's practical relevance. This experiment appears realistic within a relatively short time investment.
      5. The bimodal distributions in Figure 2 suggest that a fraction of cells may be stress-resistant rather than simply surviving randomly. It would be useful to discuss whether repeated rounds could progressively enrich UV-resistant subpopulations.
      6. The manuscript repeatedly uses the term "killed," although the data shown in Figures 2 and 4 mostly demonstrate strong growth arrest/inhibition. Please clarify how the cutoff of division rate <0.4 h⁻¹ was selected and whether an independent viability assay was performed.
      7. The off-target analysis in Figure 3 is one of the strongest parts of the paper and should probably be emphasized more. The conclusion that the dominant effects are global rather than local is interesting, but additional discussion about optical scattering, ROS diffusion, or device-wide coupling effects would strengthen the interpretation.
      8. UV exposure is inherently mutagenic in E. coli, and untargeted cells still receive a substantial fraction of the UV dose at high targeting fractions. Please discuss whether the MB/red-light modality may be preferable in applications where preserving genotype integrity is important.
      9. The manuscript discusses that methylene blue (MB) improves the on:off target ratio, but MB also appears to reduce baseline growth by ~40% even without red-light exposure. This is potentially important for iterative selection workflows. Please discuss whether this effect is reversible after washout and how rapidly cells recover.
      10. The manuscript states that the retrained DeLTA model used ~3,000 annotated fluorescence images, but no train/validation/test split or segmentation performance metrics are reported. Since segmentation directly impacts phenotype classification and projection targeting, these details are important for reproducibility.
      11. The manuscript would benefit from a stronger Methods description regarding DMD calibration, alignment procedures, projection accuracy validation, and computational timing requirements for the real-time analysis pipeline.

      Minor comments:

      1. In Figure 1, it would help to better distinguish the imaging optical path from the photoselection/UV projection path.
      2. The manuscript claims submicron projection precision (<0.5 µm), but it would help to relate this more directly to trench dimensions and actual biological targeting accuracy.
      3. In Figure 3, please include trench spacing and trench geometry information, since these parameters are important for interpreting local leakage and off-target illumination effects.
      4. The fitted off-target scaling factor (m = 0.26) becomes central to the simulation framework later in the paper, but no uncertainty or confidence interval is reported for this fit.
      5. In Figure 4, please clarify more explicitly how mixed or unidentified trenches were handled computationally before projection.
      6. The enrichment shift from 1:1 to 3.8:1 in Figure 4D is promising, but the number of biological replicates should be stated. If this were a single experiment, additional replicates with error bars would increase confidence in the enrichment result.
      7. Several figure captions would benefit from additional context and clearer definitions of technical terms and abbreviations. In multiple cases, interpreting the figure panels was difficult without returning to the main text.
      8. Please define all abbreviations directly in the figure captions, even if they are introduced earlier in the manuscript.
      9. In several figures, the color coding is not fully explained in the captions. Please make sure all colors, dashed lines, highlighted regions, and overlays are explicitly defined.
      10. The captions should more clearly describe what readers are expected to conclude from each figure, not only what is shown.
      11. Figure 2 caption issue: the manuscript references "Figure 2F," but Figure 2 only contains panels A-E.
      12. The manuscript does not currently clarify whether the software, DMD calibration routines, or retrained DeLTA weights will be publicly released. Clarifying code and software availability would improve reproducibility.
      13. There are several grammatical and readability issues throughout the manuscript. The technical ideas are strong, but some sentences are difficult to follow and would benefit from careful proofreading and language editing.

      Significance

      General assessment:

      This is a creative and technically impressive study that combines mother-machine microfluidics, automated microscopy, real-time image analysis, and DMD-based photoselection into a unified platform for dynamic, phenotype-based enrichment. The strongest aspects of the work are the systems integration, the quantitative characterization of off-target effects, and the conceptual demonstration that dynamic microscopy-derived phenotypes can be linked to physical enrichment workflows.

      The main limitations are that the biological validation remains largely proof-of-concept and the most compelling enrichment results are currently simulation-based rather than experimentally demonstrated across multiple rounds. In addition, the manuscript would benefit from stronger positioning relative to recent image-based and DMD-enabled microfluidic control systems.

      Advance:

      The study extends the field of single-cell microfluidics and image-based selection by introducing a platform that links longitudinal microscopy measurements directly to physical enrichment decisions within mother-machine devices. To my knowledge, the combination of iterative feedback-driven selection, DMD-based targeted elimination, and dynamic phenotype tracking in this context is novel.

      The closest related systems appear to be recent DMD-enabled mother-machine platforms for real-time optogenetic control, particularly those reported by Lugagne et al. (Nature Communications 2024, DOI: 10.1038/s41467-024-46361-1). However, MiPS introduces a distinct conceptual advance by using patterned illumination for selective enrichment/elimination rather than gene-expression modulation alone.

      The advance is primarily technical and conceptual, with potential downstream applications in directed evolution, synthetic biology, biosensor engineering, and dynamic phenotype screening workflows that are difficult or impossible to implement using FACS alone.

      Audience:

      The work will likely be of strongest interest to researchers working in synthetic biology, microfluidics, single-cell analysis, systems biology, bioengineering, and automated microscopy. It may also be of broader interest to communities developing dynamic phenotype screening technologies, closed-loop biological control systems, and next-generation directed evolution platforms.

      The audience is likely specialized but multidisciplinary, spanning both engineering-oriented and biology-oriented researchers. The methods and conceptual framework may also influence future development of automated selection systems beyond the specific mother-machine context.

      Expertise - My expertise includes:

      • Microfluidics
      • Synthetic biology
      • Single-cell systems
      • Automated microscopy
      • Real-time image analysis
      • Bioengineering platforms
      • Dynamic phenotype characterization
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      Reply to the reviewers

      Note: This preprint has been reviewed by subject experts for Review Commons. COntent has not been altered except for formatting.

      Reply to the Reviewers

      1. General Statements

      We thank the reviewers for their careful evaluation of our manuscript and for the many constructive suggestions. Overall, the reviewers found the identification of Msc1 as a glucose starvation-responsive NVJ-associated factor to be novel and potentially important, while also raising several important concerns regarding the mechanistic interpretation of our findings and the topology/localization of Msc1. We particularly appreciate the reviewers' comments regarding potential overinterpretation of several conclusions. In the revised manuscript we will substantially revise the wording throughout the text to more carefully distinguish correlation from causation and to avoid unsupported mechanistic conclusions. In addition, we plan to address the reviewers' concerns through a combination of additional experiments, revised data presentation, clarification of methodological details, and expanded discussion of alternative interpretations.

      1. Description of the planned revisions

      In the point-by-point response below, the reviewers' comments are presented in italics, and our responses are provided below each comment.

      Reviewer #1

      Comment:

      *This is a nice, smallish study of Msc1, a fungal protein of unknown function. The authors show it localises to the NVJ when that expands in late-log/stationary phase, at which stage its transcription is increased 80-fold - an induction one whole order of magnitude greater than shown by Nvj1 itself. This indicates that Msc1 may be a previously unappreciated master regulator of the NVJ. There are some interesting phenotypes of deleting Msc1, including some cell death and loss of Nvj1, mostly through destabilisation since the transcriptional effect is marginal. *

      *While no mechanism for Msc1 is discovered, that might be too much to ask for in this first paper. However, there are ways to begin to address this that the authors should look into. *

      *My major issue with the paper is that it makes no link to the previously studied homologues of Msc1 in S pombe (Ish1/Les1 - see Asakawa et all 2022). Admittedly, S. pombe has no Nvj1 homolog, but there is a physical relationship between nucleus and vacuole (Chadwick et al (2020) 10.1088/1478-3975/aba510). Also, the paper on Ish1/Les1 developed a phenotype to test Ish1 (toxicity of over expression) that might be useful for studies of Msc1. *

      *The current MS should link to work on Ish1/ Les1 in S. pombe, relating to several features: *

      *Topology. Given the high similarity between Msc1 and Ish1/Les1, they are (a priori) likely to share considerable form and function. If Msc1 is a soluble protein in the ER lumen, then the previous report that Ish1/Les1 have TMDs is wrong. The report here should make that link and carefully explain how the Pombe paper is wrong. Also explain how is it possible for Msc1 (and Ish1/Les1) to stay restricted to the nuclear envelope? (in many images it is diffuse throughout the NE). The only mechanism I can think of is binding an integral protein that sorts to the inner-NE by known mechanisms (or possibly binding to an outer-NE protein that binds to an inner-NE one, like SUN/KASH). I cannot think of any other example of a soluble proteins restricted to the NE - so this is quite a claim. An alternative view that could be investigated and should definitely be discussed is that Msc1 (and by implication Ish1 and Les1) has a TMD even though it is extracted by carbonate. Something similar has been reported for some single TMD proteins in mitochondria (Kim et al (2015) 10.1002/pro.2817). Investigations would include proteomics showing whether the protein is normally full length (as coded by the open reading frame) or clipped (indicating the signal sequence is removed for a soluble protein). Such data may already be available in published mass spec datasets. *

      We agree that the relationship between Msc1 and the previously characterized S. pombe homologs Ish1/Les1 should be discussed more carefully, particularly with respect to membrane topology. In the revised manuscript, we will cite and discuss the Ish1/Les1 studies and further investigate the topology and localization of Msc1 through several additional experiments. First, as suggested by the reviewer, we will examine whether the N-terminal region of Msc1, which is predicted to function as a signal sequence and as a weak transmembrane domain, undergoes proteolytic processing. To address this, we plan to perform mass spectrometry-based analyses and examine whether the N-terminus is retained in the mature protein. As an alternative approach in case the N-terminal peptide cannot be reliably detected by mass spectrometry, we will generate an Msc1 mutant lacking the predicted N-terminal 22-amino-acid signal sequence and compare its migration on SDS-PAGE with that of the full-length protein. This analysis should provide an additional assessment of whether the predicted signal sequence is removed during Msc1 maturation.

      In addition, following comments from multiple reviewers, we will repeat the alkaline carbonate extraction experiments using additional ER membrane protein controls to more carefully evaluate the membrane association properties of Msc1.

      Furthermore, we plan to perform additional split-GFP localization analyses to test whether Msc1 localizes within the perinuclear ER lumen. Specifically, we will express GFP1-10 either within the ER lumen or within the nucleoplasm and examine in which compartment co-expression of Msc1-GFP11 results in GFP fluorescence.

      Finally, as suggested by the reviewer, we agree that interactions with integral membrane proteins may explain the restricted localization of Msc1 within the nuclear envelope/NVJ region. In our preliminary experiments, we obtained results suggesting a physical interaction between Msc1 and Nvj2. Therefore, we plan to further investigate the interaction of Msc1 with Nvj2, as well as with other known NVJ-associated proteins, to better understand the mechanism underlying its localization and enrichment at the NVJ.

      *Minor Issues *

      *The Abstract switches from response to lack of glucose to terminology about 'stress-response'. This could appear to be an effort to appear more interesting. If the idea is to remain, it needs some support with the introduction of the idea that yeast experiences stress (as opposed to "normal" transcription driven programmatic changes in relation to changing levels of glucose in normal cultures. *

      To avoid overstating our findings, we will revise the Abstract and related text to use more precise terminology and to more clearly describe the observed responses.

      Introduction para 1 seems to be dedicated to the idea that a set of intracellular structures (here MCS) are 'dynamically and coordinately remodeled in response to metabolic and stress conditions'. This conclusion applies widely and may not be noteworthy. The paragraph needs a bit of rethinking.

      While nutrient-dependent changes in the NVJ itself have long been recognized, we believe that dynamic remodeling of multiple MCSs in response to environmental and metabolic conditions has only more recently become appreciated more broadly in the field. We therefore think that discussing the emerging concept that diverse MCSs undergo dynamic reorganization under different physiological conditions provides important context for the present study. Nevertheless, we will revise the Introduction to explain this point more clearly and concisely.

      Figure 2D: I could not find Nsg1 result described in the text.

      We will repeat the experiment independently and quantify the immunoblot results shown in Figure 2D. The resulting quantitative data will be added to Figure 2D, and the Results section will be revised accordingly to describe these findings, including the Nsg1 phenotype.

      P6: "Strikingly, GS-dependent transcriptional activation of NVJ1 was significantly suppressed in msc1∆ cells (Fig. 4B)." This overstates the strength of the result. Instead state that the induction diminishes from 6-fold to 4-fold, and give the p value.

      We will revise the text to provide a more quantitative description of the result, including the corresponding p value.

      *Language: Avoid use of rhetorical wording (e.g. dramatic): just state the results (e.g. 80-fold induction) and let the results be dramatic/striking etc. all by themselves.

      *

      We will also revise the text to avoid rhetorical wording and instead describe the results in a more direct and quantitative manner.

      Reviewer #2 * The study describes the finding of the nuclear envelope protein Msc1 as a new component of the membrane contact site nucleus vacuole junction (NVJ) under the conditions of glucose starvation. Msc1 has previously only been known as a nuclear envelope protein, presumably localizing to the nuclear lumen, and its role in DNA damage repair. The main finding of this study is the glucose starvation-induced upregulation and NVJ-localization of Msc1 (Figure 1). The second main finding is that the loss of Msc1 results in an impaired induction of the expression of Nvj1 (the main component of the NVJ, responsible for the formation of NVJ via direct interaction with Vac8) upon glucose starvation (Fig. 3 A). The effect of Msc1-loss on the Nvj1 expression levels is transcriptional (Fig. 4 B). The glucose starvation-mediated expression induction of some other previously identified NVJ components, Nsg1 and Nsg2 is also impaired in the msc1D mutant, while the expression of Ypf1 is affected to a lesser degree. The data supporting these two main findings are solid (Figure 1; Figure 3 A; Figure 4 A, B).

      The study further shows that the loss of Msc1 results in a loss of NVJ-localization of NVJ components Tsc13, Ypf1 and to a lesser degree Hmg2. The microscopy data looks solid, however the interpretation of this finding is not clear. In my view, the most likely explanation is that the effect of Msc1 loss on the localization of NVJ components to the NVJ is due to the impaired glucose starvation-induced Nvj1 expression in the msc1D mutant.

      MAJOR COMMENTS:

      Here are suggested experiments that would strengthen the study: - It is difficult to imagine how a NE protein could affect expression levels of other NVj proteins - this key finding would be supported by a complementation experiment where MSC1 is expressed from a vector - to test whether this rescues the phenotype (to make sure that the observed phenotype is not due to an off-target effect of msc1D deletion) *

      As suggested by the reviewer, we plan to perform complementation experiments by expressing Msc1 from a plasmid in msc1∆ cells to confirm that the observed phenotypes are specifically caused by loss of MSC1.

      *- If technically feasible under the glucose starvation conditions, this hypothesis could be tested by overexpressing Nvj1 from an inducible or some other promoter. *

      We agree that this is an important point. As suggested by the reviewer, we plan to overexpress Nvj1 using a constitutive promoter and examine whether this suppresses the phenotypes observed in msc1∆ cells.

      *- The effect of msc1D deletion on Tsc13 proteins levels (preferentially using the same Tsc13-GFP strain as used in microscopy - anti Tsc13 or anti-GFP antibodies could be used) *

      We will examine Tsc13 protein levels in msc1∆ cells using the same Tsc13-GFP strain used for microscopy.

      *- The results concerning the localization of Msc1-GFP in elo3D mutant have been interpreted as "accelerated localization", "expansion of the the size of Msc1-NVJ domain" etc. However, the levels of Msc1-GFP in the elo3D mutant are higher compared to WT (Figure 2 D). Considering this, it is very likely that the larger surface area measured in the elo3D mutant is a consequence of this. This could be potentially checked by comparing images set of WT and elo3D that are set to a similar fluorescence intensity. In any case, this possibility should be definitely addressed in the interpretation of the result. *

      We agree that the increased Msc1-GFP signal in elo3∆ cells could contribute to the apparent increase in NVJ area. However, in our previous study (Fujimoto and Tamura, 2026, J. Cell Biol.), we observed accelerated NVJ expansion under glucose starvation and in elo3∆ cells using Ypf1, whose expression levels are largely unchanged under these conditions. We therefore think that the observed phenotype is unlikely to be explained solely by increased Msc1 expression. Nevertheless, because Msc1 protein levels are clearly elevated in elo3∆ cells, we will revise the text to describe these results more carefully and fairly, while citing our previous findings.

      *- There is an impression that the data has been overinterpreted, and the conclusions should be written much more carefully. Examples: o "Here, we show that Msc1 is a GS-responsive NVJ factor that plays an important role in functional NVJ remodeling." - based on data shown, the effect of Msc1 could be indirect. The statement above should be re-written or argumented much better. o "we find that GS-dependent induction of NVJ1 transcription is attenuated in msc1Δ cells, suggesting that proper NVJ remodeling contributes to the execution of stress-responsive transcriptional programs" - this is unclear; which data support this? o "Together, these findings position Msc1 as an upstream regulator linking GS signaling to functional maturation of the NVJ and associated cellular adaptation responses." - same comment as above o "...suggesting that Msc1 functions as a GS-responsive regulator of NVJ functions." o "...these findings suggest that Msc1 acts upstream of Ypf1 in orchestrating GS-induced NVJ functional maturation." o "Collectively, these results indicate that Snf1 acts upstream of Msc1 to drive GS-induced NVJ remodeling, whereas reduced Elo3 activity further accelerates this process and promotes Msc1 accumulation." - not sure if the available data support this. o "These results indicate that although Msc1 ...... it is required for efficient GS-dependent functional maturation of the NVJ domain." o "These observations suggest that loss of Msc1 does not cause a general defect in transcriptional activation but rather impairs the proper execution and dynamic range of GS-dependent transcriptional responses." - this is unclear o "Within this context, the robust induction of NVJ1 appears to be particularly sensitive to Msc1 deficiency." - this sentence would benefit from being re-written. o "Together, these results indicate that Msc1 contributes to transcriptional reprogramming associated with NVJ remodeling during GS." - this sounds overstated. o "the observation that loss of Msc1 attenuates GS-dependent induction of NVJ1 raises the possibility that NVJ remodeling influences stress-responsive gene expression programs." *

      We appreciate the reviewer's concern that several interpretations in the current manuscript may extend beyond what is directly supported by the available data. We will therefore revise these statements throughout the manuscript to provide more balanced interpretations and avoid overstating our conclusions. In addition, several planned experiments, including complementation analyses, Nvj1 overexpression experiments, additional localization analyses, quantitative protein analyses, and identification of NVJ-associated proteins that interact with Msc1, may further clarify the relationship between Msc1, NVJ remodeling, and glucose starvation responses. We will revise the text accordingly based on the results obtained from these additional experiments.

      *OTHER COMMENTS FIGURE BY FIGURE - SOME ARE MAJOR (overlapping to the above comments), SOME ARE MINOR: *

      *Figure 1: *

      *Figure 1 A and B shows that Msc1-GFP expression is upregulated in cells starved for glucose for 24h, but not in nitrogen-starved cells. *

      *o Size of the markers (protein ladder) would be helpful. * We will reprocess the immunoblot images from the original data and revise the figure layout to include molecular weight markers.

      *Figure 2: - Comment: It is not clear if these are the same strains as analyzed by microscopy (GFP-tagged Msc1). This should be specified in the Figure legend 2 D. *

      *- Comment: o Since the levels of Msc1-GFP in the elo3D mutant are higher compared to WT (Figure 2 D), the larger surface area measured in C may be a consequence of this. *

      *o It is not clear if Figure A and D analyze the same strains (western blot and microscopy - do both show GFP-tagged Msc1? - using anti-GFP?). This should be specified in the Figure legend 2 D. Since the increased area measured in Figure 2 C could be due to increased Msc1-GFP levels in this mutant strain, the WB should check the levels of Msc1-GFP in the same strain and under same conditions as analyzed in Figure 2 C.

      o Does Tim23 serve as a loading control in Figure 2 D? *

      We added "Tim23 was used as a loading control." In the legend of Figure 2D.* o Would be good to have protein ladder sized marked in Western blots o Since the increase in Msc1 levels in the elo3D mutant could be significant for the interpretation of the results, it would be helpful to have quantification of the protein levels in WB (normalized to a loading control). *

      We will clarify in the Figure 2 legend that Figure 2A shows GFP-tagged Msc1 expressed cells analyzed by fluorescence microscopy, whereas Figure 2D shows untagged strains analyzed by immunoblotting using an anti-Msc1 antibody. We will also clarify that Tim23 was used as a loading control and add molecular weight markers to the Western blots. We agree that the increased Msc1-GFP levels in elo3∆ cells could influence the apparent increase in NVJ area measured in Figure 2C. As noted above, our previous findings using Ypf1 suggest that accelerated NVJ expansion in elo3∆ cells is unlikely to be explained solely by increased Msc1 expression (Fujimoto and Tamura, J. Cell Biol., 2026). Nevertheless, we acknowledge that elevated Msc1-GFP levels could influence the apparent NVJ area measured in Figure 2C. We will therefore revise the text to more carefully describe these results and discuss them in the context of our previous findings.

      In addition, we will quantify the Western blot signals in Figure 2D normalized to the loading control and include these data in the revised manuscript.

      Figure 3 ** Together these data show that localization of other NVJ-proteins to the NVJ depends on the presence of Msc1. Comment: - From the available data it is possible that Msc1 recruits these components by direct interaction, or by modifying the structure of NVJ, or functions in an indirect manner - this should be discussed in the Discussion. Comment: - The signal of Tsc1-GFP in log-growing cells is very weak, therefore the quantification may be unreliable. I would remove this condition (log-grown cells) form the quantification in C) due to the low signal, since it is not crucial to the interpretation of the data. If the authors prefer to leave it, that is fine. - The title of the Figure 3 is "Msc1 supports stability and recruitment of NVJ-associated proteins" - I am not sure what "stability" is; the data don't address stability or recruitment in a direct manner - I suggest to change the figure title into a statement describing what is shown in the Figure, for example: "The loss of Msc1 results in decreased Nvj1 levels and a decreased localization of NVJ proteins to the NVJ). And have a comment that this data suggests that Msc1 supports recruitment of NVJ-associated proteins, likely in an indirect manner, based on the finding that the loss of Msc1 leads to a lower expression of Nvj1, in the main text (e.g. in the Discussion). - Is it possible that the loss of Msc1 on the loss of NVJ-localized Tsc13 is due to the downregulation of Tsc13 expression? Considering the effect of msc1D deletion on the expression of some NVJ proteins (Figure 3 A), Tsc13 expression levels would be good to be checked, considering the effect of msc1D on Tsc13-GFP localization. It would be optimal to do the WB with the same Tsc13-GFP-expressing strain and under the same growth conditions as was used in the microscopy in the Figure 3 B. - Expression levels of Ypf1 are lower in the msc1D strain, than in the WT (Fig. 3 A) - could this affect lower NVJ-area in his mutant? (Fig. 3 B)

      We agree that the current data do not distinguish whether Msc1 affects localization of NVJ-associated proteins directly, indirectly through changes in NVJ structure, or through other indirect mechanisms. We also agree that the term "stability" used in the current Figure 3 title is not sufficiently supported by the available data, as our experiments do not directly address protein stability. To address this issue, we plan to overexpress Nvj1 in msc1∆ cells and examine the expression and localization of NVJ-associated proteins including Nsg1 and Nsg2. Based on the results obtained from these additional experiments, we will revise the Figure 3 title and discuss these possibilities more carefully in the revised manuscript.

      Regarding the quantification of Tsc13-GFP localization in log-growing cells, although the NVJ signal is relatively small and weak under these conditions, we confirmed the signal carefully during quantification. In addition, we consider this dataset important because it suggests that the effect of Msc1 is relatively limited during logarithmic growth. Therefore, we currently prefer to retain these data in the revised manuscript.

      As suggested by the reviewer, we will revise the Figure 3 title to more directly describe the observed phenotypes.

      We will also examine Tsc13 protein levels in msc1∆ cells using the same Tsc13-GFP strain and growth conditions used for the microscopy analyses. In addition, we will quantitatively analyze expression levels of Ypf1 and other NVJ-associated proteins in msc1∆ cells and discuss how these changes may contribute to the observed localization phenotypes.

      *Figure 4. Figure 4 A shows mRNA levels in glucose starved cells compared to log-.growing cells for MSC1, NVJ1 and YPF1. - Comment: I would move Figure 4 A to Figure 1. Figure 4 B shows mRNA levels of proteins expressed in WT and msc1D mutant strain, in log-growing cells in under glucose starvation. The data show that the loss of Msc1 leads to a decrease in NVJ1 mRNA under the conditions of glucose starvation. Th expression of other NVJ proteins analyzed are not affected. - Comment: Would this Figure 4 A-B better fit together with the data showing Nvj1 levels in the msc1D mutant from a previous figure (3 A)? *

      *Figure 4 C shows PI staining of cells after 5 days of glucose starvation. The loss of Msc1 leads to a double increase in PI-positive cells (in contrast to the nvj1D mutant, which is similar to WT), indicating that the viability of cells after 5 days of glucose starvation is decreased in the absence of Msc1. - Comment: Since there is no phenotype of nvj1D, this is likely not due to the non-functional NVJ, but another function of Msc1 - the question is which. This could be discussed in the Discussion. - Comment: This is informative, however it is not sure why this data is placed together with the mRNA data within the Figure 4. *

      We appreciate these suggestions and agree that the figure organization could be improved. Following the reviewer's recommendations, and taking into account the results of the additional experiments described above, we will reorganize the figure layout to better align related datasets and improve the overall flow of the manuscript. We also agree that the increased PI staining observed in msc1∆ cells is unlikely to be explained solely by loss of NVJ function, since nvj1∆ cells do not show a comparable phenotype. We will therefore discuss this point more carefully in the revised Discussion and consider additional functions of Msc1 that may contribute to cell survival during glucose starvation.

      Figure S1. - Comment - as in Figure 2 - Msc1-GFP has a much stronger signal in elo3D mutant, than in WT, which could influence (or likely influences) the measured area. Perhaps one way to test this is to image WT cells with higher % of laser "a "longer exposition"), to get a stronger signal similar to that seen in the elo3D mutant, and then repeat the quantification.

      • Taken the result as it is presently, I suggest taking the Figure S1 out.

      As discussed above for Figure 2C, increased Msc1-GFP levels in elo3∆ cells could influence the apparent increase in NVJ area. We agree that this analysis is not central to the main conclusions of the current manuscript. Therefore, together with the additional experiments described above, we will re-evaluate the organization of the supplementary figures and revise the figure layout accordingly. Based on the revised dataset, we will determine whether Figure S1 should be removed, relocated, or incorporated into a more appropriate context in the revised manuscript.

      *Figure S3 . Validation of anti-Msc1 antibody - Could be moved as S1. *

      We will move the current Figure S3 to Figure S1 in the revised manuscript.

      Reviewer #3

      *Summary: In this study, the authors identify Msc1 as a factor associated with nucleus-vacuole junctions (NVJs) during glucose starvation. Using Saccharomyces cerevisiae as a model system, and combining immunoblotting and microscopy approaches, they report a functional connection between Msc1 and the NVJ component Nvj1.

      Major comments: - Are the key conclusions convincing? Overall, the main conclusions are largely convincing. However, several interpretations are overstated and should be phrased more cautiously (see specific comments below).

      • Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether? Yes. In several instances, the data support correlation rather than causation, and the authors should clearly indicate when conclusions are speculative.

      • Would additional experiments be essential to support the claims of the paper? Request additional experiments only where necessary for the paper as it is, and do not ask authors to open new lines of experimentation. For some conclusions, either:

      • the interpretation should be weakened, or
      • additional experiments are needed to fully support the claims

      • Are the suggested experiments realistic in terms of time and resources? It would help if you could add an estimated cost and time investment for substantial experiments. If Western blot membranes are available, additional controls could likely be addressed by reprobing, which would require minimal effort and a short timeframe. Suggested microscopy experiments would require strain construction and are therefore expected to take approximately 2-3 weeks.

      • Are the data and the methods presented in such a way that they can be reproduced? Some methodological details are insufficiently described and should be clarified to ensure reproducibility.

      • Are the experiments adequately replicated and statistical analysis adequate? The authors do not specify which tests for normality were performed. It is therefore difficult to assess whether the use of Student's t-test is appropriate. In at least one case (comparison of three groups), a t-test is not appropriate and should be replaced with a suitable multiple-comparison test.

      Minor comments: - Specific experimental issues that are easily addressable. See below

      • Are prior studies referenced appropriately? Yes, mostly/ The authors should provide a reference supporting NVJ expansion during nitrogen starvation.

      • Are the text and figures clear and accurate? Yes

      • Do you have suggestions that would help the authors improve the presentation of their data and conclusions? see below *

      We appreciate the reviewer's overall positive evaluation of our study and the recognition that the main conclusions are largely convincing. We also appreciate the reviewer's careful and constructive suggestions regarding interpretation, experimental support, and presentation of the data. As also pointed out by other reviewers, several interpretations in the current manuscript may extend beyond what is directly supported by the available data. We will therefore revise the manuscript throughout to more clearly distinguish between observations directly supported by the data and more speculative interpretations, and to avoid overstating our conclusions. In addition, we are currently performing several additional experiments, including complementation analyses, Nvj1 overexpression experiments, quantitative protein analyses, and additional localization studies, which may further strengthen some of the interpretations. We will also revise the Methods section to provide more detailed information regarding experimental procedures, statistical analyses, and reproducibility. In addition, we will reanalyze the data using appropriate statistical methods where necessary. In addition, we will revise and reorganize several figures and figure legends, and methodological details, and improve the overall presentation and clarity of the manuscript. We will also add references regarding NVJ expansion during nitrogen starvation as suggested by the reviewer.

      *Figures and data presentation • Figure 1A: The image is difficult to interpret. The authors should improve visibility, for example by: o using grayscale instead of magenta/green for single channels, or o applying an intensity LUT. This is particularly important as the Nvj1 signal is barely visible.

      *

      We will revise Figure 1A to improve visibility of the fluorescence signals, including the Nvj1 signal, by adjusting the image presentation methods as suggested by the reviewer.

        • Figure 1B: The use of Tim23 as a loading control is not appropriate. The authors should justify why a mitochondrial protein was used as a reference.* Although Tim23 is a mitochondrial protein, we previously confirmed that its abundance is not substantially affected by glucose starvation conditions and therefore serves as a suitable loading control in this experimental setting (Fujimoto and Tamura, J. Cell Biol., 2026). In the revised manuscript, we will clarify the rationale for using Tim23 as a loading control. We will also normalize immunoblot signals to Tim23 and explicitly state this in the text.
      • Figure 1C: The experimental design and interpretation are problematic: o Using an ER protein together with mitochondrial markers in the proteinase K protection assay is not appropriate for the stated conclusions. * Because ER and mitochondrial membranes are both present in the membrane fraction used for the proteinase K protection assay, we believe that mitochondrial marker proteins can still serve as controls for proteinase K accessibility. However, we agree that the integrity of the ER membrane itself was not directly assessed in the current experiment. We therefore plan to repeat the experiment using appropriate ER membrane protein controls.

      *o The claim that Msc1 is not an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used. *

      Similar concerns regarding the topology and membrane association of Msc1 were also raised by other reviewers. To address these issues, we are currently performing additional experiments, including detailed analyses of the N-terminal region of Msc1 and further localization studies (see also our response to the first comment from Reviewer #1). We also plan to examine the fission yeast Msc1 homolog Les1, whose localization has been analyzed in greater detail previously (Asakawa et al. Genes Cells. 2022, 27(11):643-656. doi: 10.1111/gtc.12981). In addition, we are currently investigating NVJ-associated proteins that interact with Msc1, which may provide further mechanistic insight into the localization and function of Msc1 at the NVJ.

      *o The authors should provide additional evidence for localization (or use alternative approaches). *

      As also mentioned in our response to Reviewer #1, we plan to perform additional localization analyses using a split-GFP approach. Specifically, we will express GFP1-10 either within the ER lumen or within the nucleoplasm and examine in which compartment co-expression of Msc1-GFP11 results in GFP fluorescence.

        • Figure 1D: o The authors conclude that deletion of NVJ1 and VAC8 reduces Msc1 colocalization. However, an alternative explanation is that NVJs are not formed under these conditions. o This conclusion should therefore be phrased more cautiously. Alternatively, a known NVJ marker should be included to demonstrate NVJ formation. *

      We agree that reduced Msc1 localization in nvj1 and vac8∆ cells could simply reflect impaired NVJ formation itself. To address this possibility, we plan to examine NVJ formation in these mutants using split-GFP-based NVJ probes that we previously developed (Tashiro et al., Front Cell Dev Biol. 2020, doi: 10.3389/fcell.2020.571388). If NVJ formation is indeed disrupted under these conditions, we will revise the interpretation more cautiously.

      *o The argument involving Ypf1 is weak, as the observed effect could be indirect and mediated via another factor. *

      The relationship between Msc1 and Ypf1 will be described more cautiously in the revised manuscript.

        • Figure 2B: The statistical analysis (Student's t-test) is not appropriate for the dataset presented.* The statistical analysis for Figure 2B will be revised using a more appropriate method.
        • Additional point: The authors again use a mitochondrial protein as a loading control in Figure 1D, which requires justification. As mentioned above, Tim23 used as a loading control was selected based on our previous study showing that its abundance remains unchanged during glucose starvation (Fujimoto and Tamura, J. Cell Biol.* 2026). This explanation will be added to the revised manuscript.

      *Conceptual interpretation • The link between transcriptional reprogramming and NVJ remodeling is not convincingly demonstrated. The data suggest a temporal correlation but do not establish causality. • The PI staining experiments show increased cell death in the absence of Msc1. However, a causal relationship to NVJ function is not demonstrated. An alternative explanation (e.g., an additional role of Msc1 in processes such as DNA repair) should be considered or discussed. *

      These points will be appropriately discussed in the revised manuscript, taking into account the results of additional experiments, including those examining the effects of Nvj1 expression in msc1∆ cells.

      • The claim that Msc1 localizes to the perinuclear space is not sufficiently supported: o Appropriate ER/nuclear envelope controls are missing. As noted above, we will perform additional split-GFP-based analyses to further investigate the localization of Msc1.

      we will perform additional experiments to further examine the membrane topology of Msc1, including controls using antibodies against ER proteins and alkaline extraction analysis of Les1, a fission yeast homolog of Msc1 with a characterized membrane topology. In addition, we will test whether Les1 can complement the msc1∆ mutant.

      *o As an alternative, structural predictions (e.g., transmembrane helix prediction) could strengthen this claim. *

      The N-terminal region of Msc1 is predicted to function as a weak transmembrane segment and a signal sequence. We will incorporate these predictions into the revised manuscript and perform additional experiments to examine the topology and potential processing of this region as mentioned above.

      *Literature and references • The authors should provide a reference supporting NVJ expansion during nitrogen starvation.

      *

      The appropriate reference will be cited in the revised manuscript.

      *Methods • The antibody section is incomplete; all antibodies used need to be specified. *

      The antibody information will be completed in the revised Methods section.

        • Cultivation conditions require more detail: o duration of growth o timing and conditions of glucose starvation shift

      * The cultivation conditions will be described in greater detail in the revised Methods section.

      2. Description of the revisions that have already been incorporated in the transferred manuscript

      Reviewer#1

      Previous reports of Msc1 in patches (page 3): the citation of Breker et al (LOQATE) seems wrong because that database shows Msc1 at the ER not at NVJ; Medina-Suarez et al is also not great: it shows NE w some patches - not high penetrance + some cER. So I suggest the authors simply rely on their own BioRxiv paper.* *

      We agree that the LOQATE database only weakly shows punctate localization of Msc1 and will therefore remove this citation. However, we believe that Medina-Suarez et al. still provides relevant support because Msc1 exhibits a localization pattern resembling the NVJ in a subset of cells, and therefore we plan to retain this reference.

      Table S1: needs Msc1-GFP adding to some lines.

      We revised Table S1 accordingly.

      *Avoid unnecessary abbreviations: GS creates a novel word that has no obvious meaning and makes the manuscript hard to read rapidly. It would be better to use "glucose starvation" in all cases, especially the abstract. *

      P7: "These results indicate that loss of Msc1 impairs NVJ function more severely than loss of Nvj1 alone." Here NVJ function might not be the target of Msc1 deletion, since nvj1-deletion does not show increased cell death. Also, in general very little is known about NVJ function as very few phenotypes can be pinned down to loss of the NVJ. Better here to say "cell function" (that may involve some aspect of Msc1's interactions at NVJs) instead.

      We revised the wording accordingly.

      Reviewer#2

      *- It is not certain what the term "stability of multiple NVJ proteins" means. Could another term be used, or this explained? *

      We agree that the term "stability" could imply a specific mechanism that is not directly demonstrated in our study. Therefore, we have revised the text to more accurately reflect our findings by referring to the abundance of NVJ proteins rather than their stability: "Together with these observations, our results suggest that Msc1 plays a central role in maintaining the abundance of multiple NVJ proteins, including Nvj1, Ypf1, Nsg1, and Nsg2, during glucose starvation."

      *o The title of the Figure 2 is: "Snf1 signaling and VLCFA metabolism modulate NVJ partitioning of Msc1" - what is "NVJ partitioning" - for me it would be clearer to write "Snf1 signaling and VLCFA metabolism modulate the localization of Msc1 to NVJ" *

      As suggested by the reviewer, we will revise the Figure 2 title from "Snf1 signaling and VLCFA metabolism modulate NVJ partitioning of Msc1" to "Snf1 signaling and VLCFA metabolism modulate the localization of Msc1 to the NVJ."

      *Figure 1 A and B shows that Msc1-GFP expression is upregulated in cells starved for glucose for 24h, but not in nitrogen-starved cells. - Comments: o Is Tim23 used as a loading control? If yes, it should be stated in the figure legends and/ or main text. *

      We have revised the figure legends to indicate that Tim23 was used as a loading control.*

      *

      • *

      *o Which antibody is used for Western in B? *

      We have revised the figure legend to specify that the immunoblots shown in Fig. B were probed with anti-Msc1, anti-Nvj1, anti-Ypf1, and anti-Tim23 antibodies.

      * - Comment: It would be helpful to explain the abbreviation "PK" in Figure 1C Figure legend. *

      We have revised the Figure 1C legend to define PK as proteinase K.

      * Figure 1 D: Msc1-GFP localization to the NVJ is dependent on Nvj1, Vac8, but not Nsg1 and 2 and Ypf1 - Comment: a typo: "(D) Fluorescence microscopy images of the indicates strains..." should be "indicated". - Comment: "Single focal planes were shown." Would be better in present tense "are shown". *

      We have corrected "indicates" to "indicated" and revised "Single focal planes were shown" to "Single focal planes are shown" in the Figure 1D legend.

      *Figure S2. - The list of genes analyzed and the conditions analyzed are different in the figure and in the legend. Probably the figure is correct. *

      We revised the Figure S2 legend.

      3. Description of analyses that authors prefer not to carry out

      Reviewer#1

      Comment:

      Function/structural form: the manuscript is light on describing what Msc1 is: it shares the same repeat structure that has been described in Ish1/Les1. The S pombe work described the repeats wrongly as motifs, when AlphaFold2 confidently predicts them as structurally characteristic domains with 2 parallel helices separated by a loop. It would be interesting to speculate a bit on how these might function in the NVJ. One major mystery of the NVJ is the extreme uniformity, shown especially well by cryo-ET (MIllen et al (2008) 10.1111/j.1600-0854.2008.00789.x). This suggests some long-range oligomerisation: is it possible that Msc1 provides that? Possible experiments include expressing Pombe Ish1/Les1 either whole or chimeras with Msc1 to see if they function and are extractable. If that is not to be done here it should at least be discussed.

      Regarding the suggested experiments using S. pombe Ish1/Les1 or chimeric constructs, we agree that these would be interesting approaches. However, because we plan to prioritize additional analyses of Msc1 topology, including detailed characterization of the N-terminal region and repeated alkaline carbonate extraction experiments using ER membrane protein controls, we do not currently plan to pursue extensive chimera-based functional analyses within the scope of the present revision.

      With respect to the possibility that Msc1 contributes to long-range oligomerization underlying the structural uniformity of the NVJ, we currently consider this possibility less likely. In density-gradient centrifugation analyses performed under mild detergent conditions, the apparent molecular size of Msc1 was not particularly large, and we therefore did not obtain evidence supporting formation of a stable large oligomeric complex by Msc1.

      Reviewer#2

      - The authors refer to a previous study showing that nvj1D deletion does not affect protein levels of several NVJ proteins, however, it would be nice to have this data shown here - i.e. the localization of Tsc13, Ypf1 (and Hmg2) in the nvj1D mutant, especially since the study cited has not been peer-reviewed yet: "Notably, our previous work showed that loss of Nvj1 or Ypf1 does not affect the protein levels of each other or those of other NVJ-associated factors such as Nsg1 and Nsg2 (Fujimoto and Tamura, 2025)."

      We believe this point may reflect two partially distinct issues: (i) whether loss of Nvj1 affects the protein levels of NVJ-associated factors, and (ii) whether loss of Nvj1 affects their NVJ localization. In our previous study, we showed that loss of Nvj1 does not affect the protein levels of Ypf1, Nsg1, or Nsg2, whereas their NVJ localization does require Nvj1 (Fujimoto and Tamura, 2026; J Cell Biol. 225. doi:10.1083/jcb.202506071, now published). In addition, a previous study demonstrated that Tsc13 localizes to the NVJ in an Nvj1-dependent manner (Kvam et al., 2005). We also showed that loss of Ypf1 prevents efficient accumulation of Hmg2 at the NVJ (Fujimoto and Tamura, J. Cell Biol. 2026). We therefore believe that these localization dependencies have already been sufficiently established in previous studies.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      In this study, the authors identify Msc1 as a factor associated with nucleus-vacuole junctions (NVJs) during glucose starvation. Using Saccharomyces cerevisiae as a model system, and combining immunoblotting and microscopy approaches, they report a functional connection between Msc1 and the NVJ component Nvj1.

      Major comments:

      • Are the key conclusions convincing?

      Overall, the main conclusions are largely convincing. However, several interpretations are overstated and should be phrased more cautiously (see specific comments below). - Should the authors qualify some of their claims as preliminary or speculative, or remove them altogether?

      Yes. In several instances, the data support correlation rather than causation, and the authors should clearly indicate when conclusions are speculative. - Would additional experiments be essential to support the claims of the paper? Request additional experiments only where necessary for the paper as it is, and do not ask authors to open new lines of experimentation.

      For some conclusions, either:

      • the interpretation should be weakened, or
      • additional experiments are needed to fully support the claims
      • Are the suggested experiments realistic in terms of time and resources? It would help if you could add an estimated cost and time investment for substantial experiments.

      If Western blot membranes are available, additional controls could likely be addressed by reprobing, which would require minimal effort and a short timeframe. Suggested microscopy experiments would require strain construction and are therefore expected to take approximately 2-3 weeks. - Are the data and the methods presented in such a way that they can be reproduced?

      Some methodological details are insufficiently described and should be clarified to ensure reproducibility. - Are the experiments adequately replicated and statistical analysis adequate?

      The authors do not specify which tests for normality were performed. It is therefore difficult to assess whether the use of Student's t-test is appropriate. In at least one case (comparison of three groups), a t-test is not appropriate and should be replaced with a suitable multiple-comparison test.

      Minor comments:

      • Specific experimental issues that are easily addressable.

      See below - Are prior studies referenced appropriately?

      Yes, mostly/ The authors should provide a reference supporting NVJ expansion during nitrogen starvation. - Are the text and figures clear and accurate?

      Yes - Do you have suggestions that would help the authors improve the presentation of their data and conclusions? see below

      Figures and data presentation

      • Figure 1A: The image is difficult to interpret. The authors should improve visibility, for example by:
      • using grayscale instead of magenta/green for single channels, or
      • applying an intensity LUT. This is particularly important as the Nvj1 signal is barely visible.

      • Figure 1B: The use of Tim23 as a loading control is not appropriate. The authors should justify why a mitochondrial protein was used as a reference.

      • Figure 1C: The experimental design and interpretation are problematic:

      • Using an ER protein together with mitochondrial markers in the proteinase K protection assay is not appropriate for the stated conclusions.
      • The claim that Msc1 is an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used.
      • The authors should provide additional evidence for localization (or use alternative approaches).

      • Figure 1D:

      • The authors conclude that deletion of NVJ1 and VAC8 reduces Msc1 colocalization. However, an alternative explanation is that NVJs are not formed under these conditions.
      • This conclusion should therefore be phrased more cautiously. Alternatively, a known NVJ marker should be included to demonstrate NVJ formation.
      • The argument involving Ypf1 is weak, as the observed effect could be indirect and mediated via another factor.

      • Figure 2B: The statistical analysis (Student's t-test) is not appropriate for the dataset presented.

      • Additional point: The authors again use a mitochondrial protein as a loading control in Figure 1D, which requires justification.

      Conceptual interpretation

      • The link between transcriptional reprogramming and NVJ remodeling is not convincingly demonstrated. The data suggest a temporal correlation but do not establish causality. The PI staining experiments show increased cell death in the absence of Msc1. However, a causal relationship to NVJ function is not demonstrated. An alternative explanation (e.g., an additional role of Msc1 in processes such as DNA repair) should be considered or discussed. The claim that Msc1 localizes to the perinuclear space is not sufficiently supported: Appropriate ER/nuclear envelope controls are missing. As an alternative, structural predictions (e.g., transmembrane helix prediction) could strengthen this claim.

      Literature and references

      The authors should provide a reference supporting NVJ expansion during nitrogen starvation.
      

      Methods

      • The antibody section is incomplete; all antibodies used need to be specified.
      • Cultivation conditions require more detail:
      • duration of growth
      • timing and conditions of glucose starvation shift

      Referee cross-commenting

      Rev#1:

      I generally agree with the other reviewers. I found an error (?typo) in one thing Reviewer 3 says about Fig 1C: "The claim that Msc1 is an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I think they mean: "The claim that Msc1 is NOT an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I see that my own review has lots of typos - I will write separately to the editor about those.

      Rev#2:

      I agree with the Reviewer 3 that the link between transcriptional reprogramming and NVJ remodeling is not convincingly demonstrated.

      I agree with the Reviewer 3 that the localization of Msc1 to the perinuclear space is not sufficiently supported. The authors may re-write the conclusion to include this uncertainty, or add experimental data.

      I am not sure if I agree with the Reviewer 1 in that the loss of Msc1 leads to the downregulation of Nvj1 "mostly through destabilisation since the transcriptional effect is marginal". Available data does not include the quantification of the Nvj1 protein levels in the msc1- mutant compared to WT, therefore, it is presently unclear how large the downregulation at the protein level is.

      I agree with the Reviewer 3 that the Methods section needs a more detailed description, especially of the growth conditions and glucose starvation protocol (at which OD600 were cells diluted to, were cells washed prior to media change, etc.).

      Rev#3:

      I find Reviewer 2's suggestion of a complementation experiment compelling; this assay would require minimal additional effort and would help exclude off-target effects of the msc1Δ phenotype.

      I agree with Reviewer 1 that the use of "GS" is unnecessary and hinders readability; "glucose starvation" should be used throughout.

      I agree with Reviewer 1 that a more thorough comparison with homologous proteins in S. pombe (Ish1/Les1), including topology and functional parallels, would substantially strengthen the manuscript.

      I thank Reviewer 1 for identifying the misleading phrasing regarding integral versus associated membrane proteins. However, I maintain that the assay in Figure 1C still requires stronger support.

      Significance

      Nature and significance of the advance

      The manuscript describes Msc1 as a novel factor associated with NVJs, contributing to the growing body of work characterizing these membrane contact sites. While this represents a potentially interesting addition, the mechanistic insight provided is currently limited.

      Context within the literature

      The study fits into a series of recent publications that systematically characterize NVJs. Compared to these, the present work adds a new component but does not substantially advance mechanistic understanding.

      Audience

      The primary audience will be researchers interested in:

      • membrane contact sites
      • NVJ biology
      • yeast cell biology The manuscript could reach a broader audience interested in cellular metabolism if the authors more strongly connect their findings to metabolic states and regulatory pathways.

      Reviewer expertise

      The reviewer has expertise in:

      • membrane contact sites (MCS)
      • nucleus-vacuole junctions (NVJs)
      • yeast as a model system
      • microscopy-based analysis
      • intracellular communication
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      Referee #2

      Evidence, reproducibility and clarity

      The study describes the finding of the nuclear envelope protein Msc1 as a new component of the membrane contact site nucleus vacuole junction (NVJ) under the conditions of glucose starvation. Msc1 has previously only been known as a nuclear envelope protein, presumably localizing to the nuclear lumen, and its role in DNA damage repair. The main finding of this study is the glucose starvation-induced upregulation and NVJ-localization of Msc1 (Figure 1). The second main finding is that the loss of Msc1 results in an impaired induction of the expression of Nvj1 (the main component of the NVJ, responsible for the formation of NVJ via direct interaction with Vac8) upon glucose starvation (Fig. 3 A). The effect of Msc1-loss on the Nvj1 expression levels is transcriptional (Fig. 4 B). The glucose starvation-mediated expression induction of some other previously identified NVJ components, Nsg1 and Nsg2 is also impaired in the msc1D mutant, while the expression of Ypf1 is affected to a lesser degree. The data supporting these two main findings are solid (Figure 1; Figure 3 A; Figure 4 A, B).

      The study further shows that the loss of Msc1 results in a loss of NVJ-localization of NVJ components Tsc13, Ypf1 and to a lesser degree Hmg2. The microscopy data looks solid, however the interpretation of this finding is not clear. In my view, the most likely explanation is that the effect of Msc1 loss on the localization of NVJ components to the NVJ is due to the impaired glucose starvation-induced Nvj1 expression in the msc1D mutant.

      Major comments:

      Here are suggested experiments that would strengthen the study:

      • It is difficult to imagine how a NE protein could affect expression levels of other NVj proteins - this key finding would be supported by a complementation experiment where MSC1 is expressed from a vector - to test whether this rescues the phenotype (to make sure that the observed phenotype is not due to an off-target effect of msc1D deletion)
      • If technically feasible under the glucose starvation conditions, this hypothesis could be tested by overexpressing Nvj1 from an inducible or some other promoter.
      • The authors refer to a previous study showing that nvj1D deletion does not affect protein levels of several NVJ proteins, however, it would be nice to have this data shown here - i.e. the localization of Tsc13, Ypf1 (and Hmg2) in the nvj1D mutant, especially since the study cited has not been peer-reviewed yet: "Notably, our previous work showed that loss of Nvj1 or Ypf1 does not affect the protein levels of each other or those of other NVJ-associated factors such as Nsg1 and Nsg2 (Fujimoto and Tamura, 2025)."
      • The effect of msc1D deletion on Tsc13 proteins levels (preferentially using the same Tsc13-GFP strain as used in microscopy - anti Tsc13 or anti-GFP antibodies could be used)

      Other Major comments:

      • The results concerning the localization of Msc1-GFP in elo3D mutant have been interpreted as "accelerated localization", "expansion of the the size of Msc1-NVJ domain" etc. However, the levels of Msc1-GFP in the elo3D mutant are higher compared to WT (Figure 2 D). Considering this, it is very likely that the larger surface area measured in the elo3D mutant is a consequence of this. This could be potentially checked by comparing images set of WT and elo3D that are set to a similar fluorescence intensity. In any case, this possibility should be definitely addressed in the interpretation of the result.
      • There is an impression that the data has been overinterpreted, and the conclusions should be written much more carefully. Examples:
        • "Here, we show that Msc1 is a GS-responsive NVJ factor that plays an important role in functional NVJ remodeling." - based on data shown, the effect of Msc1 could be indirect. The statement above should be re-written or argumented much better.
        • "we find that GS-dependent induction of NVJ1 transcription is attenuated in msc1Δ cells, suggesting that proper NVJ remodeling contributes to the execution of stress-responsive transcriptional programs" - this is unclear; which data support this?
        • "Together, these findings position Msc1 as an upstream regulator linking GS signaling to functional maturation of the NVJ and associated cellular adaptation responses." - same comment as above
        • "...suggesting that Msc1 functions as a GS-responsive regulator of NVJ functions."
        • "...these findings suggest that Msc1 acts upstream of Ypf1 in orchestrating GS-induced NVJ functional maturation."
        • "Collectively, these results indicate that Snf1 acts upstream of Msc1 to drive GS-induced NVJ remodeling, whereas reduced Elo3 activity further accelerates this process and promotes Msc1 accumulation." - not sure if the available data support this.
        • "These results indicate that although Msc1 ...... it is required for efficient GS-dependent functional maturation of the NVJ domain."
        • "These observations suggest that loss of Msc1 does not cause a general defect in transcriptional activation but rather impairs the proper execution and dynamic range of GS-dependent transcriptional responses." - this is unclear
        • "Within this context, the robust induction of NVJ1 appears to be particularly sensitive to Msc1 deficiency." - this sentence would benefit from being re-written.
        • "Together, these results indicate that Msc1 contributes to transcriptional reprogramming associated with NVJ remodeling during GS." - this sounds overstated.
        • "the observation that loss of Msc1 attenuates GS-dependent induction of NVJ1 raises the possibility that NVJ remodeling influences stress-responsive gene expression programs."
      • It is not certain what the term "stability of multiple NVJ proteins" means. Could another term be used, or this explained?

      OTHER COMMENTS FIGURE BY FIGURE - SOME ARE MAJOR (overlapping to the above comments), SOME ARE MINOR:

      Figure 1: Figure 1 A and B shows that Msc1-GFP expression is upregulated in cells starved for glucose for 24h, but not in nitrogen-starved cells. - Comments: o Is Tim23 used as a loading control? If yes, it should be stated in the figure legends and/ or main text. o Size of the markers (protein ladder) would be helpful. o Which antibody is used for Western in B? - Comment: It would be helpful to explain the abbreviation "PK" in Figure 1C Figure legend. Figure 1 D: Msc1-GFP localization to the NVJ is dependent on Nvj1, Vac8, but not Nsg1 and 2 and Ypf1 - Comment: a typo: "(D) Fluorescence microscopy images of the indicates strains..." should be "indicated". - Comment: "Single focal planes were shown." Would be better in present tense "are shown".

      Figure 2: - Comment: It is not clear if these are the same strains as analyzed by microscopy (GFP-tagged Msc1). This should be specified in the Figure legend 2 D. - Comment: o Since the levels of Msc1-GFP in the elo3D mutant are higher compared to WT (Figure 2 D), the larger surface area measured in C may be a consequence of this. o It is not clear if Figure A and D analyze the same strains (western blot and microscopy - do both show GFP-tagged Msc1? - using anti-GFP?). This should be specified in the Figure legend 2 D. Since the increased area measured in Figure 2 C could be due to increased Msc1-GFP levels in this mutant strain, the WB should check the levels of Msc1-GFP in the same strain and under same conditions as analyzed in Figure 2 C. o The title of the Figure 2 is: "Snf1 signaling and VLCFA metabolism modulate NVJ partitioning of Msc1" - what is "NVJ partitioning" - for me it would be clearer to write "Snf1 signaling and VLCFA metabolism modulate the localization of Msc1 to NVJ" o Does Tim23 serve as a loading control in Figure 2 D? o Would be good to have protein ladder sized marked in Western blots o Since the increase in Msc1 levels in the elo3D mutant could be significant for the interpretation of the results, it would be helpful to have quantification of the protein levels in WB (normalized to a loading control).

      Figure 3 Together these data show that localization of other NVJ-proteins to the NVJ depends on the presence of Msc1. Comment: - From the available data it is possible that Msc1 recruits these components by direct interaction, or by modifying the structure of NVJ, or functions in an indirect manner - this should be discussed in the Discussion. Comment: - The signal of Tsc1-GFP in log-growing cells is very weak, therefore the quantification may be unreliable. I would remove this condition (log-grown cells) form the quantification in C) due to the low signal, since it is not crucial to the interpretation of the data. If the authors prefer to leave it, that is fine. - The title of the Figure 3 is "Msc1 supports stability and recruitment of NVJ-associated proteins" - I am not sure what "stability" is; the data don't address stability or recruitment in a direct manner - I suggest to change the figure title into a statement describing what is shown in the Figure, for example: "The loss of Msc1 results in decreased Nvj1 levels and a decreased localization of NVJ proteins to the NVJ). And have a comment that this data suggests that Msc1 supports recruitment of NVJ-associated proteins, likely in an indirect manner, based on the finding that the loss of Msc1 leads to a lower expression of Nvj1, in the main text (e.g. in the Discussion). - Is it possible that the loss of Msc1 on the loss of NVJ-localized Tsc13 is due to the downregulation of Tsc13 expression? Considering the effect of msc1D deletion on the expression of some NVJ proteins (Figure 3 A), Tsc13 expression levels would be good to be checked, considering the effect of msc1D on Tsc13-GFP localization. It would be optimal to do the WB with the same Tsc13-GFP-expressing strain and under the same growth conditions as was used in the microscopy in the Figure 3 B. - Expression levels of Ypf1 are lower in the msc1D strain, than in the WT (Fig. 3 A) - could this affect lower NVJ-area in his mutant? (Fig. 3 B)

      Figure 4. Figure 4 A shows mRNA levels in glucose starved cells compared to log-.growing cells for MSC1, NVJ1 and YPF1. - Comment: I would move Figure 4 A to Figure 1. Figure 4 B shows mRNA levels of proteins expressed in WT and msc1D mutant strain, in log-growing cells in under glucose starvation. The data show that the loss of Msc1 leads to a decrease in NVJ1 mRNA under the conditions of glucose starvation. Th expression of other NVJ proteins analyzed are not affected. - Comment: Would this Figure 4 A-B better fit together with the data showing Nvj1 levels in the msc1D mutant from a previous figure (3 A)? Figure 4 C shows PI staining of cells after 5 days of glucose starvation. The loss of Msc1 leads to a double increase in PI-positive cells (in contrast to the nvj1D mutant, which is similar to WT), indicating that the viability of cells after 5 days of glucose starvation is decreased in the absence of Msc1. - Comment: Since there is no phenotype of nvj1D, this is likely not due to the non-functional NVJ, but another function of Msc1 - the question is which. This could be discussed in the Discussion. - Comment: This is informative, however it is not sure why this data is placed together with the mRNA data within the Figure 4.

      Figure S1. - Comment - as in Figure 2 - Msc1-GFP has a much stronger signal in elo3D mutant, than in WT, which could influence (or likely influences) the measured area. Perhaps one way to test this is to image WT cells with higher % of laser "a "longer exposition"), to get a stronger signal similar to that seen in the elo3D mutant, and then repeat the quantification. - Taken the result as it is presently, I suggest taking the Figure S1 out. Figure S2. - The list of genes analyzed and the conditions analyzed are different in the figure and in the legend. Probably the figure is correct. Figure S3 . Validation of anti-Msc1 antibody - Could be moved as S1.

      *Referee cross-commenting

      Rev#1:

      I generally agree with the other reviewers. I found an error (?typo) in one thing Reviewer 3 says about Fig 1C: "The claim that Msc1 is an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I think they mean: "The claim that Msc1 is NOT an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I see that my own review has lots of typos - I will write separately to the editor about those.

      Rev#2:

      I agree with the Reviewer 3 that the link between transcriptional reprogramming and NVJ remodeling is not convincingly demonstrated.

      I agree with the Reviewer 3 that the localization of Msc1 to the perinuclear space is not sufficiently supported. The authors may re-write the conclusion to include this uncertainty, or add experimental data.

      I am not sure if I agree with the Reviewer 1 in that the loss of Msc1 leads to the downregulation of Nvj1 "mostly through destabilisation since the transcriptional effect is marginal". Available data does not include the quantification of the Nvj1 protein levels in the msc1- mutant compared to WT, therefore, it is presently unclear how large the downregulation at the protein level is.

      I agree with the Reviewer 3 that the Methods section needs a more detailed description, especially of the growth conditions and glucose starvation protocol (at which OD600 were cells diluted to, were cells washed prior to media change, etc.).

      Rev#3:

      I find Reviewer 2's suggestion of a complementation experiment compelling; this assay would require minimal additional effort and would help exclude off-target effects of the msc1Δ phenotype.

      I agree with Reviewer 1 that the use of "GS" is unnecessary and hinders readability; "glucose starvation" should be used throughout.

      I agree with Reviewer 1 that a more thorough comparison with homologous proteins in S. pombe (Ish1/Les1), including topology and functional parallels, would substantially strengthen the manuscript.

      I thank Reviewer 1 for identifying the misleading phrasing regarding integral versus associated membrane proteins. However, I maintain that the assay in Figure 1C still requires stronger support.

      Significance

      General assessment - strenghts and limitations:

      The identification of Msc1 as a new glucose starvation-induced protein that localizes to the NVJ is supported by strong data and represents a novel and a strong point of the paper. Furthermore, the finding that the loss of Msc1 results in the impaired expression of several other NVJ-localized proteins under glucose starvation is convincing, although the solidity of this latter data requires some more experimental controls (detailed above). The weak point is the interpretation of the Msc1 loss on the localization of other NVJ proteins - the present conclusions need to be modified, or supported by the additional experimental data.

      Advance - compare the study to existing knowledge - does it fill the gap?

      The study identifies protein Msc1, which was previously known as a nuclear envelope protein involved in DNA damage repair, as a new component of the membrane contact site nucleus vacuole junction (NVJ), whose expression and the localization to the NVJ is induced by glucose starvation. What kind of advance does it make - conceptual; incremental...? The finding that a nuclear lumen protein, which is required for DNA damage repair, under certain circumstances (glucose starvation) changes localization and potentially has new roles, has a potential of a conceptual advance, however, for that, more experimental data would be needed, specifically to determine the mechanistic role of Msc1 in glucose starvation, and compare it to it role in DNA damage response. The available data supports mainly an incremental advance in our understanding of the structure and regulation of the NVJ.

      Audience - broad; specialized; basic research...? The audience of this paper will be interested in the basic research. Especially interested may be scientists working with yeast.

      Describe your expertise: My expertise is in yeast genetics, in the field of degradation-mediated protein quality control.

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      Referee #1

      Evidence, reproducibility and clarity

      This is a nice, smallish study of Msc1, a fungal protein of unknown function. The authors show it localises to the NVJ when that expands in late-log/stationary phase, at which stage its transcription is increased 80-fold - an induction one whole order of magnitude greater than shown by Nvj1 itself. This indicates that Msc1 may be a previously unappreciated master regulator of the NVJ. There are some interesting phenotypes of deleting Msc1, including some cell death and loss of Nvj1, mostly through destabilisation since the transcriptional effect is marginal.

      While no mechanism for Msc1 is discovered, that might be too much to ask for in this first paper. However, there are ways to begin to address this that the authors should look into.

      My major issue with the paper is that it makes no link to the previously studied homologues of Msc1 in S pombe (Ish1/Les1 - see Asakawa et all 2022). Admittedly, S. pombe has no Nvj1 homolog, but there is a physical relationship between nucleus and vacuole (Chadwick et al (2020) 10.1088/1478-3975/aba510). Also, the paper on Ish1/Les1 developed a phenotype to test Ish1 (toxicity of over expression) that might be useful for studies of Msc1. The current MS should link to work on Ish1/ Les1 in S. pombe, relating to several features:

      Topology.

      Given the high similarity between Msc1 and Ish1/Les1, they are (a priori) likely to share considerable form and function. If Msc1 is a soluble protein in the ER lumen, then the previous report that Ish1/Les1 have TMDs is wrong. The report here should make that link and carefully explain how the Pombe paper is wrong. Also explain how is it possible for Msc1 (and Ish1/Les1) to stay restricted to the nuclear envelope? (in many images it is diffuse throughout the NE). The only mechanism I can think of is binding an integral protein that sorts to the inner-NE by known mechanisms (or possibly binding to an outer-NE protein that binds to an inner-NE one, like SUN/KASH). I cannot think of any other example of a soluble proteins restricted to the NE - so this is quite a claim.

      An alternative view that could be investigated and should definitely be discussed is that Msc1 (and by implication Ish1 and Les1) has a TMD even though it is extracted by carbonate. Something similar has been reported for some single TMD proteins in mitochondria (Kim et al (2015) 10.1002/pro.2817). Investigations would include proteomics showing whether the protein is normally full length (as coded by the open reading frame) or clipped (indicating the signal sequence is removed for a soluble protein). Such data may already be available in published mass spec datasets.

      Function/structural form:

      the manuscript is light on describing what Msc1 is: it shares the same repeat structure that has been described in Ish1/Les1. The S pombe work described the repeats wrongly as motifs, when AlphaFold2 confidently predicts them as structurally characteristic domains with 2 parallel helices separated by a loop. It would be interesting to speculate a bit on how these might function in the NVJ. One major mystery of the NVJ is the extreme uniformity, shown especially well by cryo-ET (MIllen et al (2008) 10.1111/j.1600-0854.2008.00789.x). This suggests some long-range oligomerisation: is it possible that Msc1 provides that?

      Possible experiments include expressing Pombe Ish1/Les1 either whole or chimeras with Msc1 to see if they function and are extractable. If that is not to be done here it should at least be discussed.

      Minor Issues

      The Abstract switches from response to lack of glucose to terminology about 'stress-response'. This could appear to be an effort to appear more interesting. If the idea is to remain, it needs some support with the introduction of the idea that yeast experiences stress (as opposed to "normal" transcription driven programmatic changes in relation to changing levels of glucose in normal cultures.

      Introduction para 1 seems to be dedicated to the idea that a set of intracellular structures (here MCS) are 'dynamically and coordinately remodeled in response to metabolic and stress conditions'. This conclusion applies widely and may not be noteworthy. The paragraph needs a bit of rethinking.

      Previous reports of Msc1 in patches (page 3): the citation of Breker et al (LOQATE) seems wrong because that database shows Msc1 at the ER not at NVJ; Medina-Suarez et al is also not great: it shows NE w some patches - not high penetrance + some cER. So I suggest the authors simply rely on their own BioRxiv paper.

      Figure 2D: I could not find Nsg1 result described in the text.

      P6: "Strikingly, GS-dependent transcriptional activation of NVJ1 was significantly suppressed in msc1∆ cells (Fig. 4B)." This overstates the strength of the result. Instead state that the induction diminishes from 6-fold to 4-fold, and give the p value.

      P7: "These results indicate that loss of Msc1 impairs NVJ function more severely than loss of Nvj1 alone." Here NVJ function might not be the target of Msc1 deletion, since nvj1-deletion does not show increased cell death. Also, in general very little is known about NVJ function as very few phenotypes can be pinned down to loss of the NVJ. Better here to say "cell function" (that may involve some aspect of Msc1's interactions at NVJs) instead.

      Table S1: needs Msc1-GFP adding to some lines

      Language:

      Avoid unnecessary abbreviations: GS creates a novel word that has no obvious meaning and makes the manuscript hard to read rapidly. It would be better to use "glucose starvation" in all cases, especially the abstract. Avoid use of rhetorical wording (e.g. dramatic): just state the results (e.g. 80-fold induction) and let the results be dramatic/striking etc. all by themselves.

      Referee cross-commenting

      Rev#1:

      I generally agree with the other reviewers. I found an error (?typo) in one thing Reviewer 3 says about Fig 1C: "The claim that Msc1 is an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I think they mean: "The claim that Msc1 is NOT an integral membrane protein is not sufficiently supported, particularly if a polyclonal antibody was used." I see that my own review has lots of typos - I will write separately to the editor about those.

      Rev#2:

      I agree with the Reviewer 3 that the link between transcriptional reprogramming and NVJ remodeling is not convincingly demonstrated.

      I agree with the Reviewer 3 that the localization of Msc1 to the perinuclear space is not sufficiently supported. The authors may re-write the conclusion to include this uncertainty, or add experimental data.

      I am not sure if I agree with the Reviewer 1 in that the loss of Msc1 leads to the downregulation of Nvj1 "mostly through destabilisation since the transcriptional effect is marginal". Available data does not include the quantification of the Nvj1 protein levels in the msc1- mutant compared to WT, therefore, it is presently unclear how large the downregulation at the protein level is.

      I agree with the Reviewer 3 that the Methods section needs a more detailed description, especially of the growth conditions and glucose starvation protocol (at which OD600 were cells diluted to, were cells washed prior to media change, etc.).

      Rev#3:

      I find Reviewer 2's suggestion of a complementation experiment compelling; this assay would require minimal additional effort and would help exclude off-target effects of the msc1Δ phenotype.

      I agree with Reviewer 1 that the use of "GS" is unnecessary and hinders readability; "glucose starvation" should be used throughout.

      I agree with Reviewer 1 that a more thorough comparison with homologous proteins in S. pombe (Ish1/Les1), including topology and functional parallels, would substantially strengthen the manuscript.

      I thank Reviewer 1 for identifying the misleading phrasing regarding integral versus associated membrane proteins. However, I maintain that the assay in Figure 1C still requires stronger support.

      Significance

      This is a nice, smallish study of Msc1, a fungal protein of unknown function. The authors show it localises to the NVJ when that expands in late-log/stationary phase, at which stage its transcription is increased 80-fold - an induction one whole order of magnitude greater than shown by Nvj1 itself. This indicates that Msc1 may be a previously unappreciated master regulator of the NVJ. There are some interesting phenotypes of deleting Msc1, including some cell death and loss of Nvj1, mostly through destabilisation since the transcriptional effect is marginal.

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      Referee #2

      Evidence, reproducibility and clarity

      In the submitted manuscript by Lassota et al., there are some interesting observations on the alternative splicing patterns of Dscam in Drosophila and honeybees. Using reporter systems, the authors present findings suggesting spatial regulation of Dscam alternative exons, and different trends depending on tissue and exon 4 /exon9 clusters.

      At this point, the manuscript unfortunately is more of a data dump than a coherent story. Effort should be made to improve the narrative, presentation of figures, etc. A finalized manuscript for journal submission needs to take more of a direction. This likely requires more removing of data than adding. There are several pieces of data included that seem superfluous to the rest of the paper (e.g. Fig. 7).

      The major problem with the paper, however, is not the lack of focused narrative. The major problem is lack of quantification of the imaging data. In several cases, one can only take the author's word that the representative image presented reflects what was observed accurately. This is particularly a problem for figures 4 and 5. When quantification is presented in figure 6, there are no error bars or data points presented and the P values reported as significant do not make sense to me. e.g. Line 237: P values seem very large (0.333, 0.559), yet are claimed to be significant. The data in figure 6 could be very interesting- that odor exposure leads to alternative splicing of dscam. But the rigor in data analysis and statistics is not adequate. Finally, one must be careful in interpretation. For example, the conclusions drawn here are premature (line 223: "...findings indicate that inclusion of Dscam variables changes during aging, resulting in various inclusion patterns across individuals".).

      A more focused manuscript with improved data quantification would be a better option for submitting to a peer reviewed journal.

      Significance

      There is potential in this work for high significance, but more rigorous data analysis and experimentation is required on several key areas.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      The Drosophila DSCAM gene is remarkable in its use of alternative splicing to generate enormous molecular diversity via three large arrays of mutually exclusive variant exons. DSCAM is important during neurodevelopment, faciliting recognition of self from non-self between neighbouring axons, as well as in the immune system where it allows response to pathogens. These two functions appear to place conflicting demands on DSCAM; neuronal wiring would be compatible with stochastic selection of individual exon variants to provide unique combinations of isoforms in individual cells, but immune response would require specificity of variant exon selection according to the pathogen encountered.

      The manuscript from Lassota, Dix and Soller addresses the nature of DSCAM variant exon selection using in vivo DSCAM splicing dependent reporter vectors in Drosophila to look at exon selection during development of the brain and nervous system. RNA FISH for specific exon variants in honeybee is used to look for changes in specific variant exon usage during aging, and after sensory experience.

      Both approaches provide evidence for both stochastic-like exon choice in some settings, but also specific preferential spatially and temporally controlled exon choice in other circumstances. These provide important high-level insights, even without the underpinning molecular explanations. In addition to these main insights, the reporter systems produced variable signals between cells and anatomical locations, even from positive control vectors that were expected to provide robust uniform signals. This is discussed in vague terms as reflecting non-productive splicing/stochastic variation in general splicing. A final experiment even builds upon this, by looking at the effects of transient knockdown of all DSCAM transcripts upon neuromuscular junctions. To my mind, the variable signal from the positive control vectors needs to be characterized at the molecular level to show if and how the loss of reporter signal is associated with variant exon splicing. In the absence of this characterization speculation about the biological significance of proposed non-productive splicing is premature. Nevertheless, the headline findings of combined stochastic and deterministic selection stand.

      Major points

      1. Throughout the manuscript more attention needs to be given to precise use of language; to me the manuscript read as if it were using "lab jargon" i.e. using a shorthand that is fully understood within the research group, but using terms that might be ambiguous to others. DSCAM is an exceptionally complex experimental system, so clear unambiguous text is essential. As one example "variables" is used in the text to refer to "variant exons", leading to ambiguity. In the abstract: "overlapping dendritic fields through selection of different variables in neighbouring cells"... "expression in optic lobes and variable expression across identical cells in salivary glands and photoreceptor fields". This sounds like a minor point, but I found the text to be a much tougher read than it needed to be.
      2. The single exon splicing reporters are an elegant design. However, at no point in the manuscript is there independent validation that variation in fluorescent protein signal actually results from the expected variation in splicing. This is mainly of concern where the positive control exon 9 and 4 vectors do not show the expected widespread expression. This is vaguely interpreted as "suppression or absence of exon 9 splicing" "at the level of splicing being productive" "stochastic variation in general splicing". This calls into question the general validity of the reporter model. If the authors wish to build upon this observation and propose that regulated splicing also results in quantitative effects upon DSCAM expression (which is the assumption underpinning Figure 7), some sort of analysis is needed to characterize the molecular output of the reporter under these conditions. What is the nature of the reporter RNA when there is no fluorescent readout? Does this reflect similar processes with endogenous DSCAM? If some of this validation was already reported in earlier papers it should be referred to explicitly.
      3. It is assumed that the single nucleotide deletions/insertions into variant exons have no effect upon their splicing. Has this been validated? Many exons have embedded exon splicing enhancers and/or silencers.
      4. RNA FISH Fig 4. How was it determined that the signal from RNA-FISH probes derived exclusively from spliced RNA rather than from pre-mRNA? A probe residing fully within an exon would hybridize equally well to mRNA and pre-mRNA. Would a probe crossing the spliced junction from specific exon 4 variants to one of the adjacent constitutive exons be a better design, specific for spliced DSCAM mRNA? A negative control probe for the RNA FISH would be useful.
      5. Lines 235- "we observed increased inclusion of variable exon 4.5". The p-values associated with this statement are 0.333, 0.559, 0.149 and 0.069. Which, if any, of these are considered to be significant?

      Minor

      1. Line 61. "Selection of alternative exons follows a preference for proximity,". Is this a general statement about splice site selection or a specific statement about previous experiments with Dscam? Clarify and provide a reference.
      2. Line 67, 68 "In the case of the splicing regulator Srrm234, inclusion of exon 9 variables diversifies," This reads rather cryptically. Not clear what experiment was carried out with Srrm234.
      3. Lines 76, 77. The term "isoforms" appears to be used interchangeably to refer to i) individual variant exons, and ii) different full length mRNA isoforms (characterized by specific variant exons in each of the three clusters).
      4. Line 82 - perhaps use "inclusion of specific exon 4 and exon 9 variants"?
      5. Line 84-85. "In salivary glands, we observed unequal exon 9 inclusion across nuclei, indicating that splicing efficiency varies at the single cell level". Unclear what is meant by this sentence, particularly what is implied by "splicing efficiency".
      6. Line 112 "positive control in which inclusion of all variables results in tdTomato expression". As written could be understood as inclusion of all variant exons within a single transcript. Suggest using: "positive control in which inclusion of any individual e9 variant results in..."
      7. Line 118-119. "and appeared to be stochastic". Since the concept of stochastic exon selection is important, I think the observations need more precise description to highlight what indicates stochastic behaviour. Do the green spots in Supp Fig 2A and Fig 1 correspond to individual nuclei or clusters of cells? The DAPI staining appears more diffuse than the fluoresence images so this is not clear.
      8. Line 135-136 "an in-frame GAL4 transcriptional activator, which is engineered into the endogenous locus." Clarify: which endogenous locus? DSCAM?
      9. Lines 141-142 "in the positive control, where all variables can be included". Misleading as written. Perhaps "where inclusion of any variant exon produces fluorescent signal".
      10. Some annotation of the microscopy images would be useful for readers who are not familiar with Drosophila neuroanatomy. For example lines 148-149 refer to developing mushroom bodies - but there is no annotation to indicate this in Supp Fig 4Q-S). In Fig 3, some annotation is needed to support the statement in the text (lines 192-193) that "we found repeated inclusion in the same photoreceptor cell across multiple ommatidia". I found it difficult to relate the schematic in panel A with the images in panels E-S.
      11. Line 255 "used an inducible elav-GAL4 (elav-GSG)". More explanation needed.

      Referees cross-commenting

      I agree with Reviewer 2's assessment. Substantial modifications are needed before a manuscript could be considered by a peer reviewed journal.

      Significance

      DSCAM alternative splicing is fascinating both from molecular mechanistic and biological perspectives. From the molecular perspective how is such a complex splicing system controlled? From the biological perspective, how is the generated molecular diversity harnessed? This manuscript addresses high level mechanistic questions concerning the degree to which variant exon selection is stochastic vs deterministic. This provides the necessary conceptual framework for subsequent more detailed mechanistic investigations. By providing this framework, the manuscript will be of interest to those interested in molecular mechanisms of gene expression. The molecular diversity enabled by DSCAM splicing is important in development of the nervous system, so the manuscript will be of interest to neurobiologists, especially those using Drosophila as a model system.

      My expertise lies more towards molecular mechanisms of gene expression/splicing. A lot of the approaches were therefore not familiar to me. I would have found the manuscript more accessible with additional annotation of many of the fluoresence microscopy images to indicate different anatomical features etc

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      Reply to the reviewers

      The authors adapt MemPrep, a protocol they originally developed to purify organelle membranes from yeast, for use in human cell lines. To this end, they established immuno-isolation strategies based on tagged versions of the ER sheet protein SEC61β and the ER tubular protein REEP5 in HEK293T cells. Their purification strategy allowed them to generate highly pure ER sheet- and tubule-enriched fractions, which were then subjected to quantitative lipidomic and proteomic analyses.

      Overall, this manuscript is well written and presents a careful interpretation of the data. It introduces MemPrep in mammalian cells as a method that will be useful for studying the membrane lipid and protein composition of organelles, with a particular focus on the ER. As such, the manuscript provides sufficient information and controls to assess the experiments in terms of reproducibility and clarity.

      We thank the reviewer for a positive, thorough assessment and for raising important points that helped us to improve the manuscript.

      Major comments:

      1. Based on the immunofluorescence images in Figure 1, it is not clear that the tagged and slightly overexpressed versions of SEC61β and REEP5 localize specifically to ER sheets and tubules, respectively, or that these proteins are enriched in these distinct ER subdomains. Perhaps reducing the fixation time, for example to a maximum of 2 minutes, or using PFA fixation, could help to better preserve ER sheet and tubular domains.

      To address the localization of the bait proteins in the ER membrane network, we added new co-localization microscopy data and quantifications to the revised manuscript (new Figure 1E,F; new Supplementary Figure S1C,D). Despite its low level of overexpression (new Figure 1C; new Suppl. Fig. S1A), SEC61β localizes to the entire ER membrane network including ER tubules and the nuclear envelope (new Fig. 1E,F).

      Considering the new data, we have carefully rephrased all sections regarding the subcellular localization of bait-SEC61β. In the revised manuscript, we use SEC61β as a general ER marker.

      Intriguingly, quantitative proteomics of the SEC61β MemPrep isolate demonstrates a selective enrichment of ER sheet-associated proteins compared to the REEP5 MemPrep, which selectively enriches proteins associated with ER tubules (Fig. 5). While we do not claim to 'isolate' ER subdomains, we enrich ER subdomains.

      We have performed additional microscopy experiments and adjusted our fixation protocol as suggested by the reviewer (Revision Fig. 1). Shortening the fixation time has no apparent impact on the ER structure, while any PFA fixation seems to largely disrupt the ER.

      Does expression of tagged SEC61β or REEP5 influence the ER sheet:tubule ratio? In addition, does expression of these constructs affect the lipidome or proteome of the cells?

      The reviewer raises an important point, which is experimentally not easy to address. Our imaging modality is not sufficient to make a firm statement about the sheet:tubule ratio in HEK293T cells. We are not aware of any study that firmly quantifies the relative content of sheets and tubules in HEK293T cells. Imaging the ER in HEK293T cells is challenging and most studies on the ER membrane networks use other cell types to study the impact of ER-shaping protein on the ER membrane network.

      In the revised manuscript we state: 'We found no evidence that the expression of the bait constructs disrupts the tubule-to-sheet ratio or other aspects of the ER architecture, but distinguishing ER sheets and ER tubules is challenging in HEK293T cells.'

      Furthermore, we have studied if the expression of the bait constructs affects the cellular proteome (new Suppl. Fig. S1A,B) and lipidome (new Suppl. Fig. S4A-H (previously Suppl. Fig. S3)). The expression of the bait constructs has no substantial impact of the cellular proteome. Most importantly, we find no evidence that proteins characteristic for ER sheets or ER tubules (other than the bait proteins) change their expression level (new Suppl. Fig. S1A,B). In the revised manuscript we state:

      ' We decided to go one step further and compared the proteomes of wildtype HEK293T cells with the two cell lines using TMT multiplexed, untargeted protein mass spectrometry (Suppl. Fig. S1A, B). This experiment revealed that bait proteins have only a minimal, neglectable impact on the cellular proteome (Suppl. Fig. S1A, B). We did not find evidence for a systematic deregulation of proteins known to localize exclusively to ER tubules or other ER subdomains. Furthermore, quantitative proteomics validated the results from immunoblotting (Fig. 1B, C): Expression of bait-SEC61β has barely any impact on the total cellular level of SEC61β (Suppl. Fig. S1A) while the expression of the REEP5-bait results in a 1.8-fold overabundance of REEP5 (Suppl. Fig. S1B).'

      Likewise, the expression of the bait constructs has little to no effect on the cellular lipidome as shown in Suppl. Fig. S4A-J. In the revised manuscript we state:

      'As a control, we also tested the impact of the bait constructs on the HEK293T whole cell lipidome (Suppl. Fig. 4A-J). Overall, the lipid composition of the virally transduced cells was indistinguishable from HEK293T cells with only minor impact on the level of CL and lysolipids (Suppl. Fig. 4A-J).'

      Apart from hypotonic swelling and douncing, could the authors use alternative methods for cell disruption to exclude the possibility that mechanical stress confounds the interpretation of the data?

      Thanks to the reviewer's comment, we became aware of a mistake. Our cell lysis buffer is hypertonic and not hypotonic (15% sucrose w/v, 10 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid)(HEPES) pH 7.4, 300 mM NaCl, 1 mM EDTA freshly supplemented with protease inhibitor cocktail from Roche). We have corrected all relevant sections in the revised manuscript.

      The reviewer is right that different means of mechanical lysis, and/or the incubation of the cells in hypo/hypertonic buffer are likely to have impact on the structure of the ER and to affect the isolation procedure. Changing such critical parameters will likely affect the purity of the preparation. Performing additional MemPrep isolations using different means of cell disruptions goes beyond the scope of this manuscript.

      Upon establishing the MemPrep protocol, we have explored various mechanical cell disruptions: Different cannula, Dounce homogenizers, and a ball-bearing device. We experimented with both hypo- and hypertonic buffers. Given the costs and work associated with lipidomic and proteomic analyses, we have tried to find a suitable conditions for cell disruption without performing a full analysis each time. Therefore, we performed differential centrifugations as exemplary shown in Fig. 2B of the manuscript. Critical factors for our decision whether to further persue a certain condition was 1) the depletion of the mitochondrial TOM22 marker, 2) the enrichment of the ER markers, and 3) the total protein yield in the P100,000 fraction.

      In the revised manuscript we state: 'Compared to the MemPrep procedure in yeast, we tested various means of cell disruption and optimized the differential centrifugation protocol.'

      and

      'Mild cell disruption by Dounce homogenization in a hypertonic buffer is crucial for cracking cells open, but these procedures can disrupt normal ER architecture and might facilitate the undesired mixing of previously well-defined ER subdomains. Despite these limitations, our data underscore the purity of our ER membrane preparations, demonstrate a differential enrichment of ER subdomains (Fig. 5), and establish the lipid composition of the ER membrane (Fig. 6)'.

      What is the total amount of lipids and proteins isolated with REEP5- or SEC61β-based MemPrep? Are there differences in the total lipid:protein ratio between these isolates, and could this reflect differences in the ER sheet:tubule ratio?

      In response to the reviewers' question, we have included a new Supplementary table 1 to the manuscript outlining the yield of total protein and total lipid of MemPrep.

      The mammlian MemPrep protocol is not yet optimized for determining the lipid:protein ratio in the membrane. At this moment, we do not want to make a statement about the protein-to-lipid ratio in the ER or its subdomains. The isolates still contain material originating from the ER lumen.

      The combined analysis of lipid and protein composition demonstrates the capacity of the method. To test that MemPrep can capture changes in ER membrane architecture, it would be useful to compare ER protein and lipid composition across different cellular states, such as stressed versus unstressed cells, or growing versus resting cells.

      We agree with the reviewer that a comparison of the ER under different conditions would be extremely interesting. Currently, we see it beyond the scope of this study.

      Minor comment:

      1. In line 335, the authors state: "To address this possibility, we performed a new round of REEP5 and SEC61β MemPreps for a direct comparison of the isolates (Fig. 5A, B)." It is unclear whether the MemPrep protocol was altered or whether this refers simply to an additional round of purification. Please clarify.

      Thank you. This point was also raised by reviewer 2 and 3. We have clarified our statements. In the revised manuscript we state:

      'Hence, we performed a new round of REEP5 and SEC61β MemPreps in triplicates for a direct comparison of the isolates (Fig. 5A, B) rather than comparing the changes in abundance relative to the respective cell lysates as performed in Figure 3. Knowing that non-ER proteins are less efficiently enriched by the MemPrep procedure than ER proteins (Fig. 3C, D) and that the sensitivity and comprehensiveness of mass spectrometry-based proteomics experiments are reduced with increasing sample complexity (Ting et al, 2011; Beck et al, 2011) , we were hoping to gain a better insight into the distribution of low abundant and challenging to quantify proteins in the two MemPrep isolates'.

      Reviewer #1 (Significance (Required)):

      General assessment:

      The manuscript establishes MemPrep for mammalian cells as an important discovery tool to investigate how cells coordinate membrane lipid composition with membrane protein composition, and vice versa. This is a rapidly growing research field, which attracts a lot of interest.

      MemPrep is based on an immuno-isolation strategy using tagged versions of the ER sheet protein SEC61β and the ER tubular protein REEP5 in HEK293T cells. The purification strategy allowed to generate highly pure ER sheet- and tubule-enriched fractions, which were then subjected to quantitative lipidomic and proteomic analyses.

      The results show that the protein composition differs between the SEC61β- and REEP5-enriched fractions. Yet the lipid composition of ER sheets and tubules is largely indistinguishable. Both fractions are dominated by PC alongside other monounsaturated GPL, and hydroxylated ceramides. These physicochemical properties of the ER lipid bilayer are matched by ER-resident membrane proteins.

      Thorough bioinformatic analysis of a subset of ER membrane proteins further revealed that their transmembrane domains have reduced hydrophobicity and increased polarity compared with those of plasma membrane proteins, matching the ER lipidome.

      Hence the combined analysis of lipid and protein composition demonstrates the capacity of the method. Many variations of this approach will be possible in the future to understand on the molecular level how cells assemble and control their membranes.

      Advance: Other immuno-isolation methods, or "organelle immunoprecipitation" approaches, have been established for lysosomes, the Golgi apparatus, and other organelles.

      MemPrep is an important and complementary addition to the technical toolbox for organelle isolation, with a particular focus on the analysis of membrane lipid and protein content.

      Audience: The manuscript will be of broad interest to researchers in basic biology as well as clinical and translational research.

      Reviewer's field of expertise:

      Molecular membrane biology.

      __Reviewer #2 __

      Jain and colleagues develop a biochemical fractionation procedure in which ER microsomes are enriched through small epitope tags. The manuscript is pitched around the concept that there are ER sheets and tubules and ER proteins differentially localise to them. The authors use REEP5 as a 'tubule' bait and SEC61beta as a 'sheet' bait. These baits are immuoisolated after a sensible membrane fractionation and ER membraned purified. There is a convincing ER proteome as a result, and this is used to compare the TMD properties of the organelles resident membrane proteins. The authors make the interesting observation that the transmembrane domains are more polar in the ER. They then compare the two sheet and tubule preparations and see a different in the proteome, before comparing the lipidome. There is no difference observed between the lipidome of the sheet and tubule preps, however they see a difference in the whole cell lysate and use that to compare the ER lipidome against the whole cell.

      Overall the manuscript has an interesting premise and the data is well presented, the experiments well performed and the interpretations appropriate. I think there are some issues with the mechanistic insight and novelty, and essentially although the premise is with regards to sheets and tubules there is limited progress in that direction in terms of results. I am reluctant to be to critical overall as there are certainly interesting observations that may be insightful for future studies in the field. I have some more specific comments below:

      We thank the reviewer for a thorough, constructive assessment and for highlighting important points that helped us improve the manuscript.

      1) The authors cite nixon-abell, but they do not mention the major point of that manuscript which is that the 'sheets' in the cellular periphery are instead dense tubular networks. I think this is quite an omission for the introduction, as it points to the premise not being as clear as stated.

      In the revised manuscript we refer to the Nixon-Abell study and two additional studies from the Jokitalo lab. Notably, the Nixon-Abell study does not rule out the existence of ER sheets.

      In the revised manuscript we state: ' [...] dense tubular networks in the cell periphery can appear like ER sheets in diffraction-limited microscopy (Nixon-Abell et al, 2016). Furthermore, the edges of ER sheets are populated by curvature-stabilizing proteins also found in ER tubules (Shibata et al, 2010; Shemesh et al, 2014), and ER sheets show different degrees of fenestration dependent on the cell type and the cell cycle phase (Puhka et al, 2007, 2012; Nixon-Abell et al, 2016). Consistent with our microscopic data (Fig. 1E, F) and because ER sheets may be biochemically inseparable from ER tubules, we use SEC61β as a general ER marker.'

      We performed additional co-localization studies of the bait proteins with RTN4 and CLIMP63 (new Fig. 1E,F) suggesting that SEC61B can localize across many ER subdomains including ER tubules and the nuclear envelope.

      We have carefully revised our manuscript accordingly and shifting the focus of our discussion away from a molecular description of discrete ER subdomains.

      2) The first section when the protocol is discussed essentially relies on looking at other papers to understand. As the manuscript is centrally about this protocol, I think a brief but clear description is more appropriate.

      We agree with the reviewer. We added a short section to the results section providing an overview over the MemPrep procedure. We now state:

      'To this end, we adapted the MemPrep procedure originally developed for the isolation of organelle membranes from Saccaromyces cerevisiae (S. cerevisiae) (Reinhard et al, 2023, 2024). Mammalian MemPrep relies on a gentle, detergent-free, mechanical lysis of the cells in a hypertonic buffer followed by differential centrifugation to separate ER-derived microsomes from mitochondria-derived membranes. Next, larger organelle fragments are disrupted by brief pulses of sonication, and the resulting vesicles are subjected to affinity purification using magnetic dynabead-coupled antibodies directed against the cleavable tag of the bait protein. Specifically bound, ER-derived membrane vesicles are washed with harsh, urea-containing buffers and selectively released by proteolytically cleaving the bait tag.'

      3) In figure 1C the two markers are supposed to localise to sheets and tubules differentially. To me they look very similar. This, of course, is a major concern. Have the authors co-expressed them (at the same levels in these lines) and seen that indeed they do differentially localise?

      The reviewer raises an important point regarding the localzation of the bait proteins. While we have not co-expressed the bait proteins in cells, we have performed additional co-localization experiments with RTN4 and CLIMP63 as markers for ER tubules and ER sheets, respectively (new Figure 1E,F; new Suppl. Fig. S1C,D). The implications of these data are discussed in the manuscript.

      In light of these new data, we do not refer to SEC61β as an ER sheet marker any longer, instead we refer to SEC61β as a general ER marker. We carefully revised our discussion of the data throughout the manuscript along the line suggested by the reviewer in point 8.

      4) I found the TMD polarity section very interesting, but it was not clear to me why they needed their proteomics for this? Could this not be done with annotated ER membrane proteins?

      The reviewer is correct. The same type of analysis could have been performed with an even bigger dataset of all ER annotated proteins. One of the co-authors, Joseph Lorent, has performed such analysis at this larger scale (PMID: 40326394). The study by Lorent et al. addressed TMH length and side chain bulkiness (PMID: 40326394) in the ER, Golgi apparatus, and the PM. This work is referenced in the manuscript.

      We focused our analysis on the smaller dataset of 83 single-pass proteins found in our proteomics experiments, because we initially planned to perform a comparative analysis of ER proteins in either of the two isolates.

      In line of the reviewers' suggestion, we validate our new finding on the TMH hydrophobicity in the ER using a larger dataset covering all single pass TMHs of ER proteins (215 instead of 83), Golgi apparatus proteins (260), and plasma membrane proteins (1322) (Suppl. Fig. S3D).

      5) It was not clear to me based on the results section text the difference between the figure 5 proteomics and the previous runs.

      This point was also raised by reviewer 1 and 3. We clarified our statement in the revised manuscript:

      'Hence, we performed a new round of REEP5 and SEC61β MemPreps in triplicates for a direct comparison of the isolates (Fig. 5A, B) rather than comparing the changes in abundance relative to the respective cell lysates as performed in Figure 3. Knowing that non-ER proteins are less efficiently enriched by the MemPrep procedure than ER proteins (Fig. 3C, D) and that the sensitivity and comprehensiveness of mass spectrometry-based proteomics experiments are reduced with increasing sample complexity (Ting et al, 2011; Beck et al, 2011) , we were hoping to gain a better insight into the distribution of low abundant and challenging to quantify proteins in the two MemPrep isolates.'

      6) Again in figure 5- are the authors sure that the difference was not due to the over-expression (albeit mild) of their protein.

      After performing an important control experiment, we are sure that the mild over-expression of the bait proteins has no impact.

      We have compared HEK293T WT cells with the bait protein expressing cell lines by quantitative proteomics (new Suppl. Fig. S1A,B). The bait proteins have no impact of the cellular proteome and do not affect the abundance of proteins known to be enriched in ER sheets or ER tubules. Hence, the enrichment of these proteins in our MemPrep isolates as shown in Fig. 5 suggests that some of the identity of ER sheets and ER tubules is maintained in our preparations even though they are not resolved by our microscopy experiments (Fig. 1). In the revised manuscript, we carefully discuss the implications of these findings.

      7) There were no differences in the ER lipidome between the two baits. This may be because there is no difference between the lipid profile of sheets and tubules, but it is very hard to conclude that.

      The reviewer has a point. Even though our findings suggest that we can differentially enrich for ER subdomains (the proteomics data in Fig. 5 on MemPrep isolates can be regarded as a golded standard for this statement), we do not have any knowledge about their biochemical purity. Hence, we have carefully toned down our statements on the basis of new imaging data (Fig. 1E,F; Suppl. Fig. S1C,D) and new proteomics data (Suppl. Fig. S1A,B).

      Along the reasoning of the reviewer, we also rephrased our statements on the difference/similarity of ER subdomains.

      8) I do not see it as my job as a reviewer to propose reorganisations and rewrites, so I encourage the authors to feel free to ignore this comment. To me the lipidome and TMD polar observations are the key manuscript findings, and there is very limited insight into the tubules and sheets line of inquiry. I wonder if it would be worth changing the focus of the manuscript overall to rather be about the ER, and not the tubules and sheets.

      Again, the reviewer raises an important point that we did not want 'to ignore'. We have carefully revised the manuscript and toned down our interpretations. In the revised manuscript we put more emphasis on the ER lipidome and less so on the composition of specific ER subdomains.

      __Reviewer #2 (Significance (Required)): __

      Overall the manuscript has an interesting premise and the data is well presented, the experiments well performed and the interpretations appropriate. I think there are some issues with the mechanistic insight and novelty, and essentially although the premise is with regards to sheets and tubules there is limited progress in that direction in terms of results. I am reluctant to be to critical overall as there are certainly interesting observations that may be insightful for future studies in the field.

      Reviewer #3

      Summary: Jain et al., provide a clear and thorough manuscript that extends their prior biochemical analysis of the yeast ER-lipidome (MEMPREP) to mammalian cells. They use detergent free lysis and differential speed centrifugation from 293T cells bearing reporters with affinity handles targeted to sheet-like or tubular-like subdomains of the ER and enrich membranes and membrane-embedded proteins from these sites. The lipidomics reveals a distinct ER-lipidome, heavily enriched in PC and PI, contains predominantly mono-unsaturated phospholipids and is surprisingly invariant across sheet-like and tubule-like domains. Additional hydrophobicity analysis suggests that ER-localised TMDs are more polar and shorter than PM-resident TMDs, and the authors speculate about co-evolution of the lipidome and proteome to ensure targeting.

      Major comments:

      I think the data are solid, clear and convincing. The similarity of the lipidomes from sheet and tubule regions of the ER give good indication of the robustness of the technique. Whilst the yield is low, the authors go to good lengths to demonstrate purity of ER capture and de-enrichment of other cellular membranes. There is good discussion of the limitations of the technique and good comparison to recent data from other labs, most notably, a recent preprint and I think the manuscripts support eachother well. There's a fair amount of speculation in the manuscript, e.g., about lipid headgroup charge density being inferred by the charge distribution on the -1 position, but the speculation is clearly acknowledged.

      1. I think that blotting for SEC61B would really help. A clear comparison to endogenous SEC61B would be helpful. I appreciate that the authors lacked an antibody here, but there are several on CiteAb that seem to detect endogenous protein.

      Following the reviewers' advice, we added new data using a commercial antibody directed against SEC61β (new Fig. 1C). We also added proteomics data comparing HEK293T WT cells with the bait expressing cell lines (new Suppl. Fig. S1A,B).

      We also characterized the commercial Proteintech (15087-1-AP) antibody to make sure it recognizes the same epitopes in the tagged and untagged variant of SEC61β.

      It's not brilliantly easy to see the 'sharp decline' in relative frequency of hydrophobic amino acids at 21 aa for ER and Golgi; whilst the individual amino acid information is interesting (and some comment could be made about the favouring of Leucines in ER and Golgi TMDs), would this be clearer if the relative frequencies were binned into hydrophobic/aromatic, polar, positive, negative?

      The reviewer is right. We have removed our statement regarding a 'sharp decline'. In fact, the decline is rather gradual for ER and Golgi TMHs, but more clear for PM TMHs. This is also reflected in the data shown in Suppl. Fig. S3D and discussed in the revised manuscript.

      We state: Confirming our expectations based on the predicted TMH length (Suppl. Fig. S3A), we observed a gradual decline in the relative frequency of hydrophobic and aromatic resides at about 21 amino acids for ER (Fig. 4E) and Golgi-associated TMHs (Fig. 4F). Such decline was more clearly defined for plasma membrane TMHs but only after 24 aa or more (Fig. 4G).'

      We also state: 'We therefore challenged our finding and performed an additional analysis using this larger dataset of all annotated human single-pass TMHs (Fig. S3D) and compared the hydrophobicity profiles of TMHs from the ER (215), the Golgi apparatus (260), and the PM (1322) (Lorent et al, 2025). This analysis further substantiated our finding that the ER and the Golgi apparatus host less hydrophobic TMHs compared to the plasma membrane. Furthermore, we observed that the ER and Golgi profiles display a conical shape with hydrophobic maxima at the center of the membrane's hydrophobic core, while the PM TMH's possess higher hydrophobicity in the cytoplasmic part of the membrane, compared to the exoplasmic part (Fig. S3D).'

      We decided to keep the Fig. 4 with its single amino acid 'resolution' was it was in the original manuscript, because we feel that this representation still has its value. It helps connecting physicochemical parameters of an average TMH in an organelle (Fig. 4A-D; Suppl. Fig. S3A-D) with the preferred amino acid composition and distribution (Fig. 4E-G). Nevertheless, some 'noise' in inherent to the data and we hope that the adaptations to the text avoids any possible confusion of the reader.

      The frequency of leucine residues in TMHs from the PM (24.5%) is comparable to the frequency of TMHs from the ER (24.1%) and from the Golgi apparatus (26.3%). Our attempts to identify an organelle-selective usage of certain amino acids did not yield robust and significant results.

      Related to this point, it's hard to correlate the degree of polar amino acid incorporation in the TMDs of Golgi, ER, PM proteins (which don't appear to vary in 4E, 4F and 4G) with the variance described in 4C. Is there a better way of displaying this data, or are the polarity measurements calculated by some other metric in 4C?

      The reviewer is right. Figure 4A-D and Figure 4E-G are based on different metrics. Figure 4A-D considers different physicochemical parameters of the amino acid sidechains (Fig. 4C: Kyte-Dolittle scale). Figure 4E-G only represents the relative frequencies. We believe that both representations can be useful.

      Notably, the relative incorporation of polar and apolar amino acids is significantly different between TMHs from the ER and the Golgi versus the TMHs from the PM (Suppl. Fig. S3B,C).

      In the revised manuscript we state: 'Our new finding that the TMHs of ER proteins are more polar than the TMHs in the plasma membrane (Fig. 4C) is also reflected by the significantly different number of apolar and polar residues in the TMHs from ER-, Golgi apparatus-, and PM-derived proteins (Suppl. S3B, C)'.

      Indeed, the polarity in Fig. 4A and Fig. 4C is calculated via the Kyte-Dolittle scale, while only the normalized frequency of the amino acid is color-coded in Fig. 4E-G.

      Minor comments:

      1. Panel 2D isn't labelled on the figure

      We represented both MemPreps in a single Panel 2C because we aimed to label in the immunoblots only a single time to avoid redundancies. We are open to change our strategy of panel labeling if our current representation is confusing.

      There is limited co-enrichment of non-ER proteins in the ER-affinity preps, and the authors have done well to deal with misannotated GO terms. It might be worthwhile adding to the discussion that all TMD proteins that localise at steady-state to post-ER compartments must necessarily pass through the ER during biosynthesis. As such, detection of non-ER proteins in ER fractions is not inherently unexpected.

      This is of course correct. In the revised manuscript we state: 'Finding non-ER proteins in an ER proteome is not surprising, because a very large number of proteins are first delivered to the ER, before they are sent to other cellular destinations.'

      I didn't understand the line on L377 about the new round of extraction featureing inherently less complex proteomes.

      This point was also raised by reviewer 1 and 2. We clarified our statement in the revised manuscript:

      'Hence, we performed a new round of REEP5 and SEC61β MemPreps in triplicates for a direct comparison of the isolates (Fig. 5A, B) rather than comparing the changes in abundance relative to the respective cell lysates as performed in Figure 3. Knowing that non-ER proteins are less efficiently enriched by the MemPrep procedure than ER proteins (Fig. 3C, D) and that the sensitivity and comprehensiveness of mass spectrometry-based proteomics experiments are reduced with increasing sample complexity (Ting et al, 2011; Beck et al, 2011) , we were hoping to gain a better insight into the distribution of low abundant and challenging to quantify proteins in the two MemPrep isolates.'

      For line L390-391, in the speculation about progressively more unsaturation as you move ER-Golgi-postGolgi, is there any (published) data from ER-FLIPPR that could inform about the degree of membrane fluidity/packing as you traverse the secretory pathway?

      We agree that mentioning evidence on the biophysical changes along the secretory pathway is helpful in this section. In the revised manuscript we state:

      'These changes of the lipid acyl chains are associated with biophysical changes of the membrane properties along the secretory pathway as observed by molecular probes reporting on lipid packing and membrane tension (Goujon et al, 2019; López-Andarias et al, 2021, 2022; Wong & Budin, 2024).'

      Reviewer #3 (Significance (Required)):

      The strengths of the study are the conceptual novelty and information provided - I think this is the first comprehensive reporting of the ER lipidome. This is a major organelle and I think as the lipid biology field develops, resources like this are really important. Moreover, the MEMPREP protocol is applicable for protein extraction from these domains, which will help with functional characterisation of ER subdomains and is a strong technical advance.

      Weaknesses relate to the single cell type and overexpression (albeit mild) methodologies. I'm not hugely fussed about this as this manuscript describes an important 1st step.

      I'm a cell biologist studying the ER

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      Jain et al., provide a clear and thorough manuscript that extends their prior biochemical analysis of the yeast ER-lipidome (MEMPREP) to mammalian cells. They use detergent free lysis and differential speed centrifugation from 293T cells bearing reporters with affinity handles targeted to sheet-like or tubular-like subdomains of the ER and enrich membranes and membrane-embedded proteins from these sites. The lipidomics reveals a distinct ER-lipidome, heavily enriched in PC and PI, contains predominantly mono-unsaturated phospholipids and is surprisingly invariant across sheet-like and tubule-like domains. Additional hydrophobicity analysis suggests that ER-localised TMDs are more polar and shorter than PM-resident TMDs, and the authors speculate about co-evolution of the lipidome and proteome to ensure targeting.

      Major comments:

      I think the data are solid, clear and convincing. The similarity of the lipidomes from sheet and tubule regions of the ER give good indication of the robustness of the technique. Whilst the yield is low, the authors go to good lengths to demonstrate purity of ER capture and de-enrichment of other cellular membranes. There is good discussion of the limitations of the technique and good comparison to recent data from other labs, most notably, a recent preprint and I think the manuscripts support eachother well. There's a fair amount of speculation in the manuscript, e.g., about lipid headgroup charge density being inferred by the charge distribution on the -1 position, but the speculation is clearly acknowledged.

      1. I think that blotting for SEC61B would really help. A clear comparison to endogenous SEC61B would be helpful. I appreciate that the authors lacked an antibody here, but there are several on CiteAb that seem to detect endogenous protein.
      2. It's not brilliantly easy to see the 'sharp decline' in relative frequency of hydrophobic amino acids at 21 aa for ER and Golgi; whilst the individual amino acid information is interesting (and some comment could be made about the favouring of Leucines in ER and Golgi TMDs), would this be clearer if the relative frequencies were binned into hydrophobic/aromatic, polar, positive, negative?
      3. Related to this point, it's hard to correlate the degree of polar amino acid incorporation in the TMDs of Golgi, ER, PM proteins (which don't appear to vary in 4E, 4F and 4G) with the variance described in 4C. Is there a better way of displaying this data, or are the polarity measurements calculated by some other metric in 4C?

      Minor comments:

      1. Panel 2D isn't labelled on the figure
      2. There is limited co-enrichment of non-ER proteins in the ER-affinity preps, and the authors have done well to deal with misannotated GO terms. It might be worthwhile adding to the discussion that all TMD proteins that localise at steady-state to post-ER compartments must necessarily pass through the ER during biosynthesis. As such, detection of non-ER proteins in ER fractions is not inherently unexpected.
      3. I didn't understand the line on L377 about the new round of extraction featureing inherently less complex proteomes.
      4. For line L390-391, in the speculation about progressively more unsaturation as you move ER-Golgi-postGolgi, is there any (published) data from ER-FLIPPR that could inform about the degree of membrane fluidity/packing as you traverse the secretory pathway?

      Significance

      The strengths of the study are the conceptual novelty and information provided - I think this is the first comprehensive reporting of the ER lipidome. This is a major organelle and I think as the lipid biology field develops, resources like this are really important. Moreover, the MEMPREP protocol is applicable for protein extraction from these domains, which will help with functional characterisation of ER subdomains and is a strong technical advance.

      Weaknesses relate to the single cell type and overexpression (albeit mild) methodologies. I'm not hugely fussed about this as this manuscript describes an important 1st step.

      I'm a cell biologist studying the ER

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      Referee #2

      Evidence, reproducibility and clarity

      Jain and colleagues develop a biochemical fractionation procedure in which ER microsomes are enriched through small epitope tags. The manuscript is pitched around the concept that there are ER sheets and tubules and ER proteins differentially localise to them. The authors use REEP5 as a 'tubule' bait and SEC61beta as a 'sheet' bait. These baits are immuoisolated after a sensible membrane fractionation and ER membraned purified. There is a convincing ER proteome as a result, and this is used to compare the TMD properties of the organelles resident membrane proteins. The authors make the interesting observation that the transmembrane domains are more polar in the ER. They then compare the two sheet and tubule preparations and see a different in the proteome, before comparing the lipidome. There is no difference observed between the lipidome of the sheet and tubule preps, however they see a difference in the whole cell lysate and use that to compare the ER lipidome against the whole cell.

      Overall the manuscript has an interesting premise and the data is well presented, the experiments well performed and the interpretations appropriate. I think there are some issues with the mechanistic insight and novelty, and essentially although the premise is with regards to sheets and tubules there is limited progress in that direction in terms of results. I am reluctant to be to critical overall as there are certainly interesting observations that may be insightful for future studies in the field. I have some more specific comments below:

      1. The authors cite nixon-abell, but they do not mention the major point of that manuscript which is that the 'sheets' in the cellular periphery are instead dense tubular networks. I think this is quite an omission for the introduction, as it points to the premise not being as clear as stated.
      2. The first section when the protocol is discussed essentially relies on looking at other papers to understand. As the manuscript is centrally about this protocol, I think a brief but clear description is more appropriate.
      3. In figure 1C the two markers are supposed to localise to sheets and tubules differentially. To me they look very similar. This, of course, is a major concern. Have the authors co-expressed them (at the same levels in these lines) and seen that indeed they do differentially localise?
      4. I found the TMD polarity section very interesting, but it was not clear to me why they needed their proteomics for this? Could this not be done with annotated ER membrane proteins?
      5. It was not clear to me based on the results section text the difference between the figure 5 proteomics and the previous runs.
      6. Again in figure 5- are the authors sure that the difference was not due to the over-expression (albeit mild) of their protein.
      7. There were no differences in the ER lipidome between the two baits. This may be because there is no difference between the lipid profile of sheets and tubules, but it is very hard to conclude that.
      8. I do not see it as my job as a reviewer to propose reorganisations and rewrites, so I encourage the authors to feel free to ignore this comment. To me the lipidome and TMD polar observations are the key manuscript findings, and there is very limited insight into the tubules and sheets line of inquiry. I wonder if it would be worth changing the focus of the manuscript overall to rather be about the ER, and not the tubules and sheets.

      Significance

      Overall the manuscript has an interesting premise and the data is well presented, the experiments well performed and the interpretations appropriate. I think there are some issues with the mechanistic insight and novelty, and essentially although the premise is with regards to sheets and tubules there is limited progress in that direction in terms of results. I am reluctant to be to critical overall as there are certainly interesting observations that may be insightful for future studies in the field.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      The authors adapt MemPrep, a protocol they originally developed to purify organelle membranes from yeast, for use in human cell lines. To this end, they established immuno-isolation strategies based on tagged versions of the ER sheet protein SEC61β and the ER tubular protein REEP5 in HEK293T cells. Their purification strategy allowed them to generate highly pure ER sheet- and tubule-enriched fractions, which were then subjected to quantitative lipidomic and proteomic analyses.

      Overall, this manuscript is well written and presents a careful interpretation of the data. It introduces MemPrep in mammalian cells as a method that will be useful for studying the membrane lipid and protein composition of organelles, with a particular focus on the ER. As such, the manuscript provides sufficient information and controls to assess the experiments in terms of reproducibility and clarity.

      Major comments:

      1. Based on the immunofluorescence images in Figure 1, it is not clear that the tagged and slightly overexpressed versions of SEC61β and REEP5 localize specifically to ER sheets and tubules, respectively, or that these proteins are enriched in these distinct ER subdomains. Perhaps reducing the fixation time, for example to a maximum of 2 minutes, or using PFA fixation, could help to better preserve ER sheet and tubular domains.
      2. Does expression of tagged SEC61β or REEP5 influence the ER sheet:tubule ratio? In addition, does expression of these constructs affect the lipidome or proteome of the cells?
      3. Apart from hypotonic swelling and douncing, could the authors use alternative methods for cell disruption to exclude the possibility that mechanical stress confounds the interpretation of the data?
      4. What is the total amount of lipids and proteins isolated with REEP5- or SEC61β-based MemPrep? Are there differences in the total lipid:protein ratio between these isolates, and could this reflect differences in the ER sheet:tubule ratio?
      5. The combined analysis of lipid and protein composition demonstrates the capacity of the method. To test that MemPrep can capture changes in ER membrane architecture, it would be useful to compare ER protein and lipid composition across different cellular states, such as stressed versus unstressed cells, or growing versus resting cells.

      Minor comment:

      1. In line 335, the authors state: "To address this possibility, we performed a new round of REEP5 and SEC61β MemPreps for a direct comparison of the isolates (Fig. 5A, B)." It is unclear whether the MemPrep protocol was altered or whether this refers simply to an additional round of purification. Please clarify.

      Significance

      General assessment:

      The manuscript establishes MemPrep for mammalian cells as an important discovery tool to investigate how cells coordinate membrane lipid composition with membrane protein composition, and vice versa. This is a rapidly growing research field, which attracts a lot of interest.

      MemPrep is based on an immuno-isolation strategy using tagged versions of the ER sheet protein SEC61β and the ER tubular protein REEP5 in HEK293T cells. The purification strategy allowed to generate highly pure ER sheet- and tubule-enriched fractions, which were then subjected to quantitative lipidomic and proteomic analyses.

      The results show that the protein composition differs between the SEC61β- and REEP5-enriched fractions. Yet the lipid composition of ER sheets and tubules is largely indistinguishable. Both fractions are dominated by PC alongside other monounsaturated GPL, and hydroxylated ceramides. These physicochemical properties of the ER lipid bilayer are matched by ER-resident membrane proteins.

      Thorough bioinformatic analysis of a subset of ER membrane proteins further revealed that their transmembrane domains have reduced hydrophobicity and increased polarity compared with those of plasma membrane proteins, matching the ER lipidome.

      Hence the combined analysis of lipid and protein composition demonstrates the capacity of the method. Many variations of this approach will be possible in the future to understand on the molecular level how cells assemble and control their membranes.

      Advance: Other immuno-isolation methods, or "organelle immunoprecipitation" approaches, have been established for lysosomes, the Golgi apparatus, and other organelles.

      MemPrep is an important and complementary addition to the technical toolbox for organelle isolation, with a particular focus on the analysis of membrane lipid and protein content.

      Audience:

      The manuscript will be of broad interest to researchers in basic biology as well as clinical and translational research.

      Reviewer's field of expertise:

      Molecular membrane biology.

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      Reply to the reviewers

      Reviewer #1

      Evidence, reproducibility and clarity

      This paper addresses a very interesting problem of non-centrosomal microtubule organization in developing Drosophila oocytes. Using genetics and imaging experiments, the authors reveal an interplay between the activity of kinesin-1, together with its essential cofactor Ensconsin, and microtubule organization at the cell cortex by the spectraplakin Shot, minus-end binding protein Patronin and Ninein, a protein implicated in microtubule minus end anchoring. The authors demonstrate that the loss of Ensconsin affects the cortical accumulation non-centrosomal microtubule organizing center (ncMTOC) proteins, microtubule length and vesicle motility in the oocyte, and show that this phenotype can be rescued by constitutively active kinesin-1 mutant, but not by Ensconsin mutants deficient in microtubule or kinesin binding. The functional connection between Ensconsin, kinesin-1 and ncMTOCs is further supported by a rescue experiment with Shot overexpression. Genetics and imaging experiments further implicate Ninein in the same pathway. These data are a clear strength of the paper; they represent a very interesting and useful addition to the field.

      The weaknesses of the study are two-fold. First, the paper seems to lack a clear molecular model, uniting the observed phenomenology with the molecular functions of the studied proteins. Most importantly, it is not clear how kinesin-based plus-end directed transport contributes to cortical localization of ncMTOCs and regulation of microtubule length.

      Second, not all conclusions and interpretations in the paper are supported by the presented data.

      We thank the reviewer for recognizing the impact of this work. In response to the insightful suggestions, we performed extensive new experiments that establish a well-supported cellular and molecular model (Figure 7). The discussion has been restructured to directly link each conclusion to its corresponding experimental evidence, significantly strengthening the manuscript.

      Below is a list of specific comments, outlining the concerns, in the order of appearance in the paper/figures.

      Figure 1. The statement: "Ens loading on MTs in NCs and their subsequent transport by Dynein toward ring canals promotes the spatial enrichment of the Khc activator Ens in the oocyte" is not supported by data. The authors do not demonstrate that Ens is actually transported from the nurse cells to the oocyte while being attached to microtubules. They do show that the intensity of Ensconsin correlates with the intensity of microtubules, that the distribution of Ensconsin depends on its affinity to microtubules and that an Ensconsin pool locally photoactivated in a nurse cell can redistribute to the oocyte (and throughout the nurse cell) by what seems to be diffusion. The provided images suggest that Ensconsin passively diffuses into the oocyte and accumulates there because of higher microtubule density, which depends on dynein. To prove that Ensconsin is indeed transported by dynein in the microtubule-bound form, one would need to measure the residence time of Ensconsin on microtubules and demonstrate that it is longer than the time needed to transport microtubules by dynein into the oocyte; ideally, one would like to see movement of individual microtubules labelled with photoconverted Ensconsin from a nurse cell into the oocyte. Since microtubules are not enriched in the oocyte of the dynein mutant, analysis of Ensconsin intensity in this mutant is not informative and does not reveal the mechanism of Ensconsin accumulation.

      As noted by Reviewer 3, the directional movement of microtubules traveling at ~140 nm/s from nurse cells toward the oocyte through Ring Canals was previously reported using a tagged Ens-MT binding domain reporter line by Lu et al. (2022). We have therefore added the citation of this crucial work in the novel version of the manuscript (lane 155-157) and removed the photo-conversion panel.

      Critically, however, our study provides mechanistic insight that was missing from this earlier work: this mechanism is also crucial to enrich MAPs in the oocyte. The fact that Dynein mutants fail to enrich Ensconsin is a crucial piece of evidence: it supports a model of Ensconsin-loaded MT transport (Figure 1D-1F).

      Figure 2. According to the abstract, this figure shows that Ensconsin is "maintained at the oocyte cortex by Ninein". However, the figure doesn't seem to prove it - it shows that oocyte enrichment of Ensonsin is partially dependent on Ninein, but this applies to the whole cell and not just to the cell cortex. Furthermore, it is not clear whether Ninein mutation affects microtubule density, which in turn would affect Ensconsin enrichment, and therefore, it is not clear whether the effect of Ninein loss on Ensconsin distribution is direct or indirect.

      Ninein plays a critical role in Ensconsin enrichment and microtubule organization in the oocyte (new Figure 2, Figure 3, Figure S3). Quantification of total Tubulin signal shows no difference between control and Nin mutant oocytes (new Figure S3 panels A, B). We found decreased Ens enrichment in the oocyte, and Ens localization on MTs and to the cell cortex (Figure 2E, 2F, and Figure S3C and S3D).

      Novel quantitative analyses of microtubule orientation at the anterior cortex, where MTs are normally preferentially oriented toward the posterior pole (Parton et al. 2011), demonstrate that Nin mutants exhibit randomized MT orientation compared to wild-type oocytes (new Figure 3C-3E).These findings establish that Ninein (although not essential) favors Ensconsin localization on MTs, Ens enrichment in the oocyte, ncMTOC cortical localization, and more robust MT orientation toward the posterior cortex. It also suggests that Ens levels in the oocyte acts as a rheostat to control Khc activation.

      The observation that the aggregates formed by overexpressed Ninein accumulate other proteins, including Ensconsin, supports, though does not prove their interactions. Furthermore, there is absolutely no proof that Ninein aggregates are "ncMTOCs". Unless the authors demonstrate that these aggregates nucleate or anchor microtubules (for example, by detailed imaging of microtubules and EB1 comets), the text and labels in the figure would need to be altered.

      We have modified the manuscript, we now refer to an accumulation of these components in large puncta, rather than aggregates, consistent with previous observations (Rosen et al., 2000). We acknowledge in the revised version that these puncta recruit Shot, Patronin and Ens without mentioning direct interaction (lane 218).

      Importantly, we conducted a more detailed characterization of these Ninein/Shot/Patronin/Ens-containing puncta in a novel Figure S4. To rigorously assess their nucleation capacity, we analyzed Eb1-GFP-labeled MT comets, a robust readout of MT nucleation (Parton et al., 2011, Nashchekin et al., 2016). While few Eb1-positive comets occasionally emanate from these structures, confirming their identity as putative ncMTOCs, these puncta function as surprisingly weak nucleation centers (new Figure S4 E, Video S1) and, their presence does not alter overall MT architecture (new Figure S4 F). Moreover, these puncta disappear over time, are barely visible at stage 10B, they do not impair oocyte development or fertility (Figure S4 G and Table 1).

      Minor comment: Note that a "ratio" (Figure 2C) is just a ratio, and should not be expressed in arbitrary units.

      We have amended this point in all the figures.

      Figure 3B: immunoprecipitation results cannot be interpreted because the immunoprecipitated proteins (GFP, Ens-GFP, Shot-YFP) are not shown. It is also not clear that this biochemical experiment is useful. If the authors would like to suggest that Ensconsin directly binds to Patronin, the interaction would need to be properly mapped at the protein domain level.

      This is a good point: the GFP and Ens-GFP immunoprecipitated proteins are now much clearly identified on the blots and in the figure legend (new Figure 4G). Shot-YFP IP, was used as a positive control but is difficult to be detected by Western blot due to its large size (>106 Da) using conventional acrylamide gels (Nashchekin et al., 2016).

      We now explicitly state that immunoprecipitations were performed at 4{degree sign}C, where microtubules are fully depolymerized, thereby excluding undirect microtubule-mediated interactions. We agree with this reviewer: we cannot formally rule out interactions through bridging by other protein components. This is stated in the revised manuscript (lane 238-239).

      One of the major phenotypes observed by the authors in Ens mutant is the loss of long microtubules. The authors make strong conclusions about the independence of this phenotype from the parameters of microtubule plus-end growth, but in fact, the quality of their data does not allow to make such a conclusion, because they only measured the number of EB1 comets and their growth rate but not the catastrophe, rescue or pausing frequency."Note that kinesin-1 has been implicated in promoting microtubule damage and rescue (doi: 10.1016/j.devcel.2021).In the absence of such measurements, one cannot conclude whether short microtubules arise through defects in the minus-end, plus-end or microtubule shaft regulation pathways.

      We thank the reviewer for raising this important point. Our data demonstrate that microtubule (MT) nucleation and polymerization rates remain unaffected under Khc RNAi and ens mutant conditions, indicating that MT dynamics alterations must arise through alternative mechanisms.

      As the reviewer suggested, recent studies on Kinesin activity and MT network regulation are indeed highly relevant. Two key studies from the Verhey and Aumeier laboratories examined Kinesin-1 gain-of-function conditions and revealed that constitutively active Kinesin-1 induces MT lattice damage (Budaitis et al., 2022). While damaged MTs can undergo self-repair, Aumeier and colleagues demonstrated that GTP-tubulin incorporation generates "rescue shafts" that promote MT rescue events (Andreu-Carbo et al., 2022). Extrapolating from these findings, loss of Kinesin-1 activity could plausibly reduce rescue shaft formation, thereby decreasing MT rescue frequency and stability. Although this hypothesis is challenging to test directly in our system, it provides a mechanistic framework for the observed reduction in MT number and stability.

      Additionally, the reviewer highlighted the role of Khc in transporting the dynactin complex, an anti-catastrophe factor, to MT plus ends (Nieuwburg et al., 2017), which could further contribute to MT stabilization. This crucial reference is now incorporated into the revised Discussion.

      Importantly, our work also demonstrates the contribution of Ens/Khc to ncMTOC targeting to the cell cortex. Our new quantitative analyses of MT organization (new Figure 5 B) reveal a defective anteroposterior orientation of cortical MTs in mutant conditions, pointing to a critical role for cortical ncMTOCs in organizing the MT network.

      Taken together, we propose that the observed MT reduction and disorganization result from multiple interconnected mechanisms: (1) reduced rescue shaft formation affecting MT stability; (2) impaired transport of anti-catastrophe factors to MT plus ends; and (3) loss of cortical ncMTOCs, which are essential for minus-end MT stabilization and network organization. The Discussion has been revised to reflect this integrated model in a dedicated paragraph ("A possible regulation of MT dynamics in the oocyte at both plus end minus MT ends by Ens and Khc" lane 415-432).

      It is important to note in that a spectraplakin, like Shot, can potentially affect different pathways, particularly when overexpressed.

      We agree that Shot harbors multiple functional domains and acts as a key organizer of both actin and microtubule cytoskeletons. Overexpression of such a cytoskeletal cross-linker could indeed perturb both networks, making interpretation of Ens phenotype rescue challenging due to potential indirect effects.

      To address this concern, we selected an appropriate Shot isoform for our rescue experiments that displayed similar localization to "endogenous" Shot-YFP (a genomic construct harboring shot regulatory sequences) and importantly that was not overexpressed.

      Elevated expression of the Shot.L(A) isoform (see Western Blot Figure S8 A), considered as the wild-type form with two CH1 and CH2 actin-binding motifs (Lee and Kolodziej, 2002), showed abnormal localization such as strong binding to the microtubules in nurse cells and oocyte confirming the risk of gain-of-function artifacts and inappropriate conclusions (Figure S8 B, arrows).

      By contrast, our rescue experiments using the Shot.L(C) isoform (that only harbors the CH2 motif) provide strong evidence against such artifacts for three reasons. First, Shot-L(C) is expressed at slightly lower levels than a Shot-YFP genomic construct (not overexpressed), and at much lower levels than Shot-L(A), despite using the same driver (Figure S8 A). Second, Shot-L(C) localization in the oocyte is similar to that of endogenous Shot-YFP, concentrating at the cell cortex (Figure S8 B, compare lower and top panels). Taken together, these controls rather suggest our rescue with the Shot-L(C) is specific.

      Note that this Shot-L(C) isoform is sufficient to complement the absence of the shot gene in other cell contexts (Lee and Kolodziej, 2002).

      Unjustified conclusions should be removed: the authors do not provide sufficient data to conclude that "ens and Khc oocytes MT organizational defects are caused by decreased ncMTOC cortical anchoring", because the actual cortical microtubule anchoring was not measured.

      This is a valid point. We acknowledge that we did not directly measure microtubule anchoring in this study. In response, we have revised the discussion to more accurately reflect our observations. Throughout the manuscript, we now refer to "cortical microtubule organization" rather than "cortical microtubule anchoring," which better aligns with the data presented.

      Minor comment: Microtubule growth velocity must be expressed in units of length per time, to enable evaluating the quality of the data, and not as a normalized value.

      This is now amended in the revised version (modified Figure S7).

      A significant part of the Discussion is dedicated to the potential role of Ensconsin in cortical microtubule anchoring and potential transport of ncMTOCs by kinesin. It is obviously fine that the authors discuss different theories, but it would be very helpful if the authors would first state what has been directly measured and established by their data, and what are the putative, currently speculative explanations of these data.

      We have carefully considered the reviewer's constructive comments and are confident that this revised version fully addresses their concerns.

      First, we have substantially strengthened the connection between the Results and Discussion sections, ensuring that our interpretations are more directly anchored in the experimental data. This restructuring significantly improves the overall clarity and logical flow of the manuscript.

      Second, we have added a new comprehensive figure presenting a molecular-scale model of Kinesin-1 activation upon release of autoinhibition by Ensconsin (new Figure 7D). Critically, this figure also illustrates our proposed positive feedback loop mechanism: Khc-dependent cytoplasmic advection promotes cortical recruitment of additional ncMTOCs, which generates new cortical microtubules and further accelerates cytoplasmic transport (Figure 7 A-C). This self-amplifying cycle provides a mechanistic framework consistent with emerging evidence that cytoplasmic flows are essential for efficient intracellular transport in both insect and mammalian oocytes.

      Minor comment: The writing and particularly the grammar need to be significantly improved throughout, which should be very easy with current language tools. Examples: "ncMTOCs recruitment" should be "ncMTOC recruitment"; "Vesicles speed" should be "Vesicle speed", "Nin oocytes harbored a WT growth,"- unclear what this means, etc. Many paragraphs are very long and difficult to read. Making shorter paragraphs would make the authors' line of thought more accessible to the reader.

      We have amended and shortened the manuscript according to this reviewer feed-back. We have specifically built more focused paragraphs to facilitates the reading.

      Significance

      This paper represents significant advance in understanding non-centrosomal microtubule organization in general and in developing Drosophila oocytes in particular by connecting the microtubule minus-end regulation pathway to the Kinesin-1 and Ensconsin/MAP7-dependent transport. The genetics and imaging data are of good quality, are appropriately presented and quantified. These are clear strengths of the study which will make it interesting to researchers studying the cytoskeleton, microtubule-associated proteins and motors, and fly development.

      The weaknesses of this study are due to the lack of clarity of the overall molecular model, which would limit the impact of the study on the field. Some interpretations are not sufficiently supported by data, but this can be solved by more precise and careful writing, without extensive additional experimentation.

      We thank the reviewer for raising these important concerns regarding clarity and data interpretation. We have thoroughly revised the manuscript to address these issues on multiple fronts. First, we have substantially rewritten key sections to ensure that our conclusions are clearly articulated and directly supported by the data. Second, we have performed several new experiments that now allow us to propose a robust mechanistic model, presented in new figures. These additions significantly strengthen the manuscript and directly address the reviewer's concerns.

      My expertise is cell biology and biochemistry of the microtubule cytoskeleton, including both microtubule-associated proteins and microtubule motors.

      Reviewer #2

      Evidence, reproducibility and clarity

      In this manuscript, Berisha et al. investigate how microtubule (MT) organization is spatially regulated during Drosophila oogenesis. The authors identify a mechanism in which the Kinesin-1 activator Ensconsin/MAP7 is transported by dynein and anchored at the oocyte cortex via Ninein, enabling localized activation of Kinesin-1. Disruption of this pathway impairs ncMTOC recruitment and MT anchoring at the cortex. The authors combine genetic manipulation with high-resolution microscopy and use three key readouts to assess MT organization during mid-to-late oogenesis: cortical MT formation, localization of posterior determinants, and ooplasmic streaming. Notably, Kinesin-1, in concert with its activator Ens/MAP7, contributes to organizing the microtubule network it travels along. Overall, the study presents interesting findings, though we have several concerns we would like the authors to address. Ensconsin enrichment in the oocyte 1. Enrichment in the oocyte • Ensconsin is a MAP that binds MTs. Given that microtubule density in the oocyte significantly exceeds that in the nurse cells, its enrichment may passively reflect this difference. To assess whether the enrichment is specific, could the authors express a non-Drosophila MAP (e.g., mammalian MAP1B) to determine whether it also preferentially localizes to the oocyte?

      To address this point, we performed a new series of experiments analyzing the enrichment of other Drosophila and non-Drosophila MAPs, including Jupiter-GFP, Eb1-GFP, and bovine Tau-GFP, all widely used markers of the microtubule cytoskeleton in flies (see new Figure S2). Our results reveal that Jupiter-GFP, Eb1-GFP, and bovine Tau-GFP all exhibit significantly weaker enrichment in the oocyte compared to Ens-GFP. Khc-GFP also shows lower enrichment. These findings indicate that MAP enrichment in the oocyte is MAP-dependent, rather than solely reflecting microtubule density or organization. Of note, we cannot exclude that microtubule post-translational modifications contribute to differential MAP binding between nurse cells and the oocyte, but this remains a question for future investigation.

      The ability of ens-wt and ens-LowMT to induce tubulin polymerization according to the light scattering data (Fig. S1J) is minimal and does not reflect dramatic differences in localization. The authors should verify that, in all cases, the polymerization product in their in vitro assays is microtubules rather than other light-scattering aggregates. What is the control in these experiments? If it is just purified tubulin, it should not form polymers at physiological concentrations.

      The critical concentration Cr for microtubule self-assembly in classical BRB80 buffer found by us and others is around 20 µM (see Fig. 2c in Weiss et al., 2010). Here, microtubules were assembled at 40 µM tubulin concentration, i.e., largely above the Cr. As stated in the materials and methods section, we systematically induced cooling at 4{degree sign}C after assembly to assess the presence of aggregates, since those do not fall apart upon cooling. The decrease in optical density upon cooling is a direct control that the initial increase in DO is due to the formation of microtubules. Finally, aggregation and polymerization curves are widely different, the former displaying an exponential shape and the latter a sigmoid assembly phase (see Fig. 3A and 3B in Weiss et al., 2010).

      Photoconversion caveatsMAPs are known to dynamically associate and dissociate from microtubules. Therefore, interpretation of the Ens photoconversion data should be made with caution. The expanding red signal from the nurse cells to the oocyte may reflect a any combination of dynein-mediated MT transport and passive diffusion of unbound Ensconsin. Notably, photoconversion of a soluble protein in the nurse cells would also result in a gradual increase in red signal in the oocyte, independent of active transport. We encourage the authors to more thoroughly discuss these caveats. It may also help to present the green and red channels side by side rather than as merged images, to allow readers to assess signal movement and spatial patterns better.

      This is a valid point that mirrors the comment of Reviewers 1 and 3. The directional movement of microtubules traveling at ~140 nm/s from nurse cells toward the oocyte via the ring canals was previously reported by Lu et al. (2022) with excellent spatial resolution. Notably, this MT transport was measured using a fusion protein containing the Ens MT-binding domain. We now cite this relevant study in our revised manuscript and have removed this redundant panel in Figure 1.

      Reduction of Shot at the anterior cortex• Shot is known to bind strongly to F-actin, and in the Drosophila ovary, its localization typically correlates more closely with F-actin structures than with microtubules, despite being an MT-actin crosslinker. Therefore, the observed reduction of cortical Shot in ens, nin mutants, and Khc-RNAi oocytes is unexpected. It would be important to determine whether cortical F-actin is also disrupted in these conditions, which should be straightforward to assess via phalloidin staining.

      As requested by the reviewer, we performed actin staining experiments, which are now presented in a new Figure S5. These data demonstrate that the cortical actin network remains intact in all mutant backgrounds analyzed, ruling out any indirect effect of actin cytoskeleton disruption on the observed phenotypes.

      MTs are barely visible in Fig. 3A, which is meant to demonstrate Ens-GFP colocalization with tubulin. Higher-quality images are needed.

      The revised version now provides significantly improved images to show the different components examined. Our data show that Ens and Ninein localize at the cell cortex where they co-localize with Shot and Patronin (Figure 2 A-C). In addition, novel images show that Ens extends along microtubules (new Figure 4 A).

      MT gradient in stage 9 oocytesIn ens-/-, nin-/-, and Khc-RNAi oocytes, is there any global defect in the stage 9 microtubule gradient? This information would help clarify the extent to which cortical localization defects reflect broader disruptions in microtubule polarity.

      We now provide quantitative analysis of microtubule (MT) array organization in novel figures (Figure 3D and Figure 5B). Our data reveal that both Khc RNAi and ens mutant oocytes exhibit severe disruption of MT orientation toward the posterior (new Figure 5B). Importantly, this defect is significantly less pronounced in Nin-/- oocytes, which retain residual ncMTOCs at the cortex (new Figure 3D). This differential phenotype supports our model that cortical ncMTOCs are critical for maintaining proper MT orientation toward the posterior side of the oocyte.

      Role of Ninein in cortical anchoringThe requirement for Ninein in cortical anchorage is the least convincing aspect of the manuscript and somewhat disrupts the narrative flow. First, it is unclear whether Ninein exhibits the same oocyte-enriched localization pattern as Ensconsin. Is Ninein detectable in nurse cells? Second, the Ninein antibody signal appears concentrated in a small area of the anterior-lateral oocyte cortex (Fig. 2A), yet Ninein loss leads to reduced Shot signal along a much larger portion of the anterior cortex (Fig. 2F)-a spatial mismatch that weakens the proposed functional relationship. Third, Ninein overexpression results in cortical aggregates that co-localize with Shot, Patronin, and Ensconsin. Are these aggregates functional ncMTOCs? Do microtubules emanate from these foci?

      We now provide a more comprehensive analysis of Ninein localization. Similar to Ensconsin (Ens), endogenous Ninein is enriched in the oocyte during the early stages of oocyte development but is also detected in NCs (see modified Figure 2 A and Lasko et al., 2016). Improved imaging of Ninein further shows that the protein partially co-localizes with Ens, and ncMTOCs at the anterior cortex and with Ens-bound MTs (Figure 2B, 2C).

      Importantly, loss of Ninein (Nin) only partially reduces the enrichment of Ens in the oocyte (Figure 2E). Both Ens and Kinesin heavy chain (Khc) remain partially functional and continue to target non-centrosomal microtubule-organizing centers (ncMTOCs) to the cortex (Figure 3A). In Nin-/- mutants, a subset of long cortical microtubules (MTs) is present, thereby generating cytoplasmic streaming, although less efficiently than under wild-type (WT) conditions (Figure 3F and 3G). As a non-essential gene, we envisage Ninein as a facilitator of MT organization during oocyte development.

      Finally, our new analyses demonstrate that large puncta containing Ninein, Shot, Patronin, and despite their size, appear to be relatively weak nucleation centers (revised Figure S4 E and Video 1). In addition, their presence does not bias overall MT architecture (Figure S4 F) nor impair oocyte development and fertility (Figure S4 G and Table 1).

      Inconsistency of Khc^MutEns rescueThe Khc^MutEns variant partially rescues cortical MT formation and restores a slow but measurable cytoplasmic flow yet it fails to rescue Staufen localization (Fig. 5). This raises questions about the consistency and completeness of the rescue. Could the authors clarify this discrepancy or propose a mechanistic rationale?

      This is a good point. The cytoplasmic flows (the consequence of cargo transport by Khc on MTs) generated by a constitutively active KhcMutEns in an ens mutant condition, are less efficient than those driven by Khc activated by Ens in a control condition (Figure 6C). The rescued flow is probably not efficient enough to completely rescue the Staufen localization at stage 10.

      Additionally, this KhcMutEns variant rescues the viability of embryos from Khc27 mutant germline clones oocytes but not from ens mutants (Table1). One hypothesis is that Ens harbors additional functions beyond Khc activation.

      This incomplete rescue of Ens by an active Khc variant could also be the consequence of the "paradox of co-dependence": Kinesin-1 also transport the antagonizing motor Dynein that promotes cargo transport in opposite directions (Hancock et al., 2016). The phenotype of a gain of function variant is therefore complex to interpret. Consistent with this, both KhcMutEns-GFP and KhcDhinge2 two active Khc only rescues partially centrosome transport in ens mutant Neural Stem Cells (Figure S10).

      Minor points: 1. The pUbi-attB-Khc-GFP vector was used to generate the Khc^MutEns transgenic line, presumably under control of the ubiquitous ubi promoter. Could the authors specify which attP landing site was used? Additionally, are the transgenic flies viable and fertile, given that Kinesin-1 is hyperactive in this construct?

      All transgenic constructs were integrated at defined genomic landing sites to ensure controlled expression levels. Specifically, both GFP-tagged KhcWT and KhcMutEns were inserted at the VK05 (attP9A) site using PhiC31-mediated integration. Full details of the landing sites are provided in the Materials and Methods section. Both transgenic flies are homozygous lethal and the transgenes are maintained over TM6B balancers.

      On page 11 (Discussion, section titled "A dual Ensconsin oocyte enrichment mechanism achieves spatial relief of Khc inhibition"), the statement "many mutations in Kif5A are causal of human diseases" would benefit from a brief clarification. Since not all readers may be familiar with kinesin gene nomenclature, please indicate that KIF5A is one of the three human homologs of Kinesin heavy chain.

      We clarified this point in the revised version (lane 465-466).

      On page 16 (Materials and Methods, "Immunofluorescence in fly ovaries"), the sentence "Ovaries were mounted on a slide with ProlonGold medium with DAPI (Invitrogen)" should be corrected to "ProLong Gold."

      This is corrected.

      Significance

      This study shows that enrichment of MAP7/ensconsin in the oocyte is the mechanism of kinesin-1 activation there and is important for cytoplasmic streaming and localization non-centrosomal microtubule-organizing centers to the oocyte cortex

      We thank the reviewers for the accurate review of our manuscript and their positive feed-back.

      Reviewer #3

      Evidence, reproducibility and clarity

      The manuscript of Berisha et al., investigates the role of Ensconsin (Ens), Kinesin-1 and Ninein in organisation of microtubules (MT) in Drosophila oocyte. At stage 9 oocytes Kinesin-1 transports oskar mRNA, a posterior determinant, along MT that are organised by ncMTOCs. At stage 10b, Kinesin-1 induces cytoplasmic advection to mix the contents of the oocyte. Ensconsin/Map7 is a MT associated protein (MAP) that uses its MT-binding domain (MBD) and kinesin binding domain (KBD) to recruit Kinesin-1 to the microtubules and to stimulate the motility of MT-bound Kinesin-1. Using various new Ens transgenes, the authors demonstrate the requirement of Ens MBD and Ninein in Ens localisation to the oocyte where Ens activates Kinesin-1 using its KBD. The authors also claim that Ens, Kinesin-1 and Ninein are required for the accumulation of ncMTOCs at the oocyte cortex and argue that the detachment of the ncMTOCs from the cortex accounts for the reduced localisation of oskar mRNA at stage 9 and the lack of cytoplasmic streaming at stage 10b. Although the manuscript contains several interesting observations, the authors' conclusions are not sufficiently supported by their data. The structure function analysis of Ensconsin (Ens) is potentially publishable, but the conclusions on ncMTOC anchoring and cytoplasmic streaming not convincing.

      We are grateful that the regulation of Khc activity by MAP7 was well received by all reviewers. While our study focuses on Drosophila oogenesis, we believe this mechanism may have broader implications for understanding kinesin regulation across biological systems.

      For the novel function of the MAP7/Khc complex in organizing its own microtubule networks through ncMTOC recruitment, we have carefully considered the reviewers' constructive recommendations. We now provide additional experimental evidence supporting a model of flux self-amplification in which ncMTOC recruitment plays a key role. It is well established that cytoplasmic flows are essential for posterior localization of cell fate determinants at stage 10B. Slow flows have also been described at earlier oogenesis stages by the groups of Saxton and St Johnston. Building on these early publications and our new experiments, we propose that these flows are essential to promote a positive feedback loop that reinforces ncMTOC recruitment and MT organization (Figure 7).

      1) The main conclusion of the manuscript is that "MT advection failure in Khc and ens in late oogenesis stems from defective cortical ncMTOCs recruitment". This completely overlooks the abundant evidence that Kinesin-1 directly drives cytoplasmic streaming by transporting vesicles and microtubules along microtubules, which then move the cytoplasm by advection (Palacios et al., 2002; Serbus et al, 2005; Lu et al, 2016). Since Kinesin-1 generates the flows, one cannot conclude that the effect of khc and ens mutants on cortical ncMTOC positioning has any direct effect on these flows, which do not occur in these mutants.

      We regret the lack of clarity of the first version of the manuscript and some missing references. We propose a model in which the Kinesin-1- dependent slow flows (described by Serbus/Saxton and Palacios/StJohnston) play a central role in amplifying ncMTOC anchoring and cortical MT network formation (see model in the new Figure 7).

      2) The authors claim that streaming phenotypes of ens and khs mutants are due to a decrease in microtubule length caused by the defective localisation of ncMTOCs. In addition to the problem raised above, However, I am not convinced that they can make accurate measurements of microtubule length from confocal images like those shown in Figure 4. Firstly, they are measuring the length of bundles of microtubules and cannot resolve individual microtubules. This problem is compounded by the fact that the microtubules do not align into parallel bundles in the mutants. This will make the "microtubules" appear shorter in the mutants. In addition, the alignment of the microtubules in wild-type allows one to choose images in which the microtubule lie in the imaging plane, whereas the more disorganized arrangement of the microtubules in the mutants means that most microtubules will cross the imaging plane, which precludes accurate measurements of their length.

      As mentioned by Reviewer 4, we have been transparent with the methodology, and the limitations that were fully described in the material and methods section.

      Cortical microtubules in oocytes are highly dynamic and move rapidly, making it technically impossible to capture their entire length using standard Z-stack acquisitions. We therefore adopted a compromise approach: measuring microtubules within a single focal plane positioned just below the oocyte cortex. This strategy is consistent with established methods in the field, such as those used by Parton et al. (2011) to track microtubule plus-end directionality. To avoid overinterpretation, we explicitly refer to these measurements as "minimum detectable MT length," acknowledging that microtubules may extend beyond the focal plane, particularly at stage 10, where long, tortuous bundles frequently exit the plane of focus. These methodological considerations and potential biases are clearly described in the Materials and Methods section and the text now mentions the possible disorganization of the MT network in the mutant conditions (lane 272-273).

      In this revised version, we now provide complementary analyses of MT network organization.Beyond length measurements (and the mentioned limitations), we also quantified microtubule network orientation at stage 9, assessing whether cortical microtubules are preferentially oriented toward the posterior axis as observed in controls (revised Figure 3D and Figure 5B). While this analysis is also subject to the same technical limitations, it reveals a clear biological difference: microtubules exhibit posterior-biased orientation in control oocytes similar to a previous study (Parton et al., 2011) but adopt a randomized orientation in Nin-/-, ens, and Khc RNAi-depleted oocytes (revised Figure 3D and Figure 5B).

      Taken together, these complementary approaches, despite their technical constraints, provide convergent evidence for the role of the Khc/Ens complex in organizing cortical microtubule networks during oogenesis.

      3) "To investigate whether the presence of these short microtubules in ens and Khc RNAi oocytes is due to defects in microtubule anchoring or is also associated with a decrease in microtubule polymerization at their plus ends, we quantified the velocity and number of EB1comets, which label growing microtubule plus ends (Figure S3)." I do not understand how the anchoring or not of microtubule minus ends to the cortex determines how far their plus ends grow, and these measurements fall short of showing that plus end growth is unaffected. It has already been shown that the Kinesin-1-dependent transport of Dynactin to growing microtubule plus ends increases the length of microtubules in the oocyte because Dynactin acts as an anti-catastrophe factor at the plus ends. Thus, khc mutants should have shorter microtubules independently of any effects on ncMTOC anchoring. The measurements of EB1 comet speed and frequency in FigS2 will not detect this change and are not relevant for their claims about microtubule length. Furthermore, the authors measured EB1 comets at stage 9 (where they did not observe short MT) rather than at stage 10b. The authors' argument would be better supported if they performed the measurements at stage 10b.

      We thank the reviewer for raising this important point. The short microtubule (MT) length observed at stage 10B could indeed result from limited plus-end growth. Unfortunately, we were unable to test this hypothesis directly: strong endogenous yolk autofluorescence at this stage prevented reliable detection of Eb1-GFP comets, precluding velocity measurements.

      At least during stage 9, our data demonstrate that MT nucleation and polymerization rates are not reduced in both KhcRNAi and ens mutant conditions, indicating that the observed MT alterations must arise through alternative mechanisms.

      In the discussion, we propose the following interconnected explanations, supported by recent literature and the reviewers' suggestions:

      1- Reduced MT rescue events. Two seminal studies from the Verhey and Aumeier laboratories have shown that constitutively active Kinesin-1 induces MT lattice damage (Budaitis et al., 2022), which can be repaired through GTP-tubulin incorporation into "rescue shafts" that promote MT rescue (Andreu-Carbo et al., 2022). Extrapolating from these findings, loss of Kinesin-1 activity could plausibly reduce rescue shaft formation, thereby decreasing MT stability. While challenging to test directly in our system, this mechanism provides a plausible framework for the observed phenotype.

      2- Impaired transport of stabilizing factors. As that reviewer astutely points out, Khc transports the dynactin complex, an anti-catastrophe factor, to MT plus ends (Nieuwburg et al., 2017). Loss of this transport could further compromise MT plus end stability. We now discuss this important mechanism in the revised manuscript.

      3- Loss of cortical ncMTOCs. Critically, our new quantitative analyses (revised Figure 3 and Figure 5) also reveal defective anteroposterior orientation of cortical MTs in mutant conditions. These experiments suggest that Ens/Khc-mediated localization of ncMTOCs to the cortex is essential for proper MT network organization, and possibly minus-end stabilization as suggested in several studies (Feng et al., 2019, Goodwin and Vale, 2011, Nashchekin et al., 2016).

      Altogether, we now propose an integrated model in which MT reduction and disorganization may result from multiple complementary mechanisms operating downstream of Kinesin-1/Ensconsin loss. While some aspects remain difficult to test directly in our in vivo system, the convergence of our data with recent mechanistic studies provides an interesting conceptual framework. The Discussion has been revised to reflect this comprehensive view in a dedicated paragraph ("A possible regulation of MT dynamics in the oocyte at both plus end minus MT ends by Ens and Khc" lane 415-432).

      4) The Shot overexpression experiments presented in Fig.3 E-F, Fig.4D and TableS1 are very confusing. Originally , the authors used Shot-GFP overexpression at stage 9 to show that there is a decrease of ncMTOCs at the cortex in ens mutants (Fig.3 E-F) and speculated that this caused the defects in MT length and cytoplasmic advection at stage 10B. However the authors later state on page 8 that : "Shot overexpression (Shot OE) was sufficient to rescue the presence of long cortical MTs and ooplasmic advection in most ens oocytes (9/14), resembling the patterns observed in controls (Figures 4B right panel and 4D). Moreover, while ens females were fully sterile, overexpression of Shot was sufficient to restore that loss of fertility (Table S1)". Is this the same UAS Shot-GFP and VP16 Gal4 used in both experiments? If so, this contradictions puts the authors conclusions in question.

      This is an important point that requires clarification regarding our experimental design.

      The Shot-YFP construct is a genomic insertion on chromosome 3. The ens mutation is also located on chromosome 3 and we were unable to recombine this transgene with the ens mutant for live quantification of cortical Shot. To circumvent this technical limitation, we used a UAS-Shot.L(C)-GFP transgenic construct driven by a maternal driver, expressed in both wild-type (control) and ens mutant oocytes. We validated that the expression level and subcellular localization of UAS-Shot.L(C)-GFP were comparable to those of the genomic Shot-YFP (new Figure S8 A and B).

      From these experiments, we drew two key conclusions. First, cortical Shot.L(C)-GFP is less abundant in ens mutant oocytes compared to wild-type (the quantification has been removed from this version). Second, despite this reduced cortical accumulation, Shot.L(C)-GFP expression partially rescues ooplasmic flows and microtubule streaming in stage 10B ens mutant oocytes, and restores fertility to ens mutant females.

      5) The authors based they conclusions about the involvement of Ens, Kinesin-1 and Ninein in ncMTOC anchoring on the decrease in cortical fluorescence intensity of Shot-YFP and Patronin-YFP in the corresponding mutant backgrounds. However, there is a large variation in average Shot-YFP intensity between control oocytes in different experiments. In Fig. 2F-G the average level of Shot-YFP in the control sis 130 AU while in Fig.3 G-H it is only 55 AU. This makes me worry about reliability of such measurements and the conclusions drawn from them.

      To clarify this point, we have harmonized the method used to quantify the Shot-YFP signals in Figure 4E with the methodology used in Figure 3B, based on the original images. The levels are not strictly identical (Control Figure 2 B: 132.7+/-36.2 versus Control Figure 4 E: 164.0+/- 37.7). These differences are usual when experiments are performed at several-month intervals and by different users.

      6) The decrease in the intensity of Shot-YFP and Patronin-YFP cortical fluorescence in ens mutant oocytes could be because of problems with ncMTOC anchoring or with ncMTOCs formation. The authors should find a way to distinguish between these two possibilities. The authors could express Ens-Mut (described in Sung et al 2008), which localises at the oocyte posterior and test whether it recruits Shot/Patronin ncMTOCs to the posterior.

      We tried to obtain the fly stocks described in the 2008 paper by contacting former members of Pernille Rørth's laboratory. Unfortunately, we learned that the lab no longer exists and that all reagents, including the requested stocks, were either discarded or lost over time. To our knowledge, these materials are no longer available from any source. We regret that this limitation prevented us from performing the straightforward experiments suggested by the reviewer using these specific tools.

      7) According to the Materials and Methods, the Shot-GFP used in Fig.3 E-F and Fig.4 was the BDSC line 29042. This is Shot L(C), a full-length version of Shot missing the CH1 actin-binding domain that is crucial for Shot anchoring to the cortex. If the authors indeed used this version of Shot-GFP, the interpretation of the above experiments is very difficult.

      The Shot.L(C) isoform lacks the CH1 domain but retains the CH2 actin-binding motif. Truncated proteins with this domain and fused to GST retains a weak ability to bind actin in vitro. Importantly, the function of this isoform is context-dependent: it cannot rescue shot loss-of-function in neuron morphogenesis but fully restores Shot-dependent tracheal cell remodeling (Lee and Kolodziej, 2002).

      In our experiments, when the Shot.L(C) isoform was expressed under the control of a maternal driver, its localization to the oocyte cortex was comparable to that of the genomic Shot-YFP construct (new Figure S8). This demonstrates unambiguously that the CH1 domain is dispensable for Shot cortical localization in oocytes, and that CH2-mediated actin binding is sufficient for this localization. Of note, a recent study showed that actin network are not equivalent highlighting the need for specific Shot isoforms harboring specialized actin-binding domain (Nashchekin et al., 2024).

      We note that the expression level of Shot.L(C)-GFP in the oocyte appeared slightly lower than that of Shot-YFP (expressed under endogenous Shot regulatory sequences), as assessed by Western blot (Figure S8 A).

      Critically, Shot.L(C)-GFP expression was substantially lower than that of Shot.L(A)-GFP (that harbored both the CH1 and CH2 domain). Shot.L(A)-GFP was overexpressed (Figure 8 A) and ectopically localized on MTs in both nurse cells and the ooplasm (Figure S8 B middle panel and arrow). These observations are in agreement that the Shot.L(C)-GFP rescue experiment was performed at near-physiological expression levels, strengthening the validity of our conclusions.

      8) Page 6 "converted in NCs, in a region adjacent to the ring canals, Dendra-Ens-labeled MTs were found in the oocyte compartment indicating they are able to travel from NC toward the oocyte through ring canals". I have difficulty seeing the translocation of MT through the ring canals. Perhaps it would be more obvious with a movie/picture showing only one channel. Considering that f Dendra-Ens appears in the oocyte much faster than MT transport through ring canals (140nm/s, Lu et al 2022), the authors are most probably observing the translocation of free Ens rather than Ens bound to MT. The authors should also mention that Ens movement from the NC to the oocyte has been shown before with Ens MBD in Lu et al 2022 with better resolution.

      We fully agree on the caveat mentioned by this reviewer: we may observe the translocation of free Dendra-Ensconsin. The experiment, was removed and replaced by referring to the work of the Gelfand lab. The movement of MTs that travel at ~140 nm/s between nurse cells toward the oocyte through the Ring Canals was reported before by Lu et al. (2022) with a very good resolution. Notably, this directional directed movement of MTs was measured using a fusion protein encompassing Ens MT-binding domain. We decided to remove this inclusive experiment and rather refer to this relevant study.

      9) Page 6: The co-localization of Ninein with Ens and Shot at the oocyte cortex (Figure 2A). I have difficulty seeing this co-localisation. Perhaps it would be more obvious in merged images of only two channels and with higher resolution images

      10) "a pool of the Ens-GFP co-localized with Ch-Patronin at cortical ncMTOCs at the anterior cortex (Figure 3A)". I also have difficulty seeing this.

      We have performed new high-resolution acquisitions that provide clearer and more convincing evidence for the localization cortical distribution of these proteins (revised Figure 2A-2C and Figure 4A). These improved images demonstrate that Ens, Ninein, Shot, and Patronin partially colocalize at cortical ncMTOCs, as initially proposed. Importantly, the new data also reveal a spatial distinction: while Ens localizes along microtubules extending from these cortical sites, Ninein appears confined to small cytoplasmic puncta adjacent but also present on cortical microtubules.

      11) "Ninein co-localizes with Ens at the oocyte cortex and partially along cortical microtubules, contributing to the maintenance of high Ens protein levels in the oocyte and its proper cortical targeting". I could not find any data showing the involvement of Ninein in the cortical targeting of Ens.

      We found decreased Ens localization to MTs and to the cell cortex region (new Figure S3 A-B).

      12) "our MT network analyses reveal the presence of numerous short MTs cytoplasmic clustered in an anterior pattern." "This low cortical recruitment of ncMTOCs is consistent with poor MT anchoring and their cytoplasmic accumulation." I could not find any data showing that short cortical MT observed at stage 10b in ens mutant and Khc RNAi were cytoplasmic and poorly anchored.

      The sentence was removed from the revised manuscript.

      13) "The egg chamber consists of interconnected cells where Dynein and Khc activities are spatially separated. Dynein facilitates transport from NCs to the oocyte, while Khc mediates both transport and advection within the oocyte." Dynein is involved in various activities in the oocyte. It anchors the oocyte nucleus and transports bcd and grk mRNA to mention a few.

      The text was amended to reflect Dynein involvement in transport activities in the oocyte, with the appropriate references (lane 105-107).

      14) The cartoons in Fig.2H and 3I exaggerate the effect of Ninein and Ens on cortical ncMTOCs. According to the corresponding graphs, there is a 20 and 50% decrease in each case.

      New cartoons (now revised Figure 3E and 4F), are amended to reflect the ncMTOC values but also MT orientation (Figure 3E).

      Significance

      Given the important concerns raised, the significance of the findings is difficult to assess at this stage.

      We sincerely thank the reviewer for their thorough evaluation of our manuscript. We have carefully addressed their concerns through substantial new experiments and analyses. We hope that the revised manuscript, in its current form, now provides the clarifications and additional evidence requested, and that our responses demonstrate the significance of our findings.

      Reviewer #4 (Evidence, reproducibility and clarity (Required)):

      Summary: This manuscript presents an investigation into the molecular mechanisms governing spatial activation of Kinesin-1 motor protein during Drosophila oogenesis, revealing a regulatory network that controls microtubule organization and cytoplasmic transport. The authors demonstrate that Ensconsin, a MAP7 family protein and Kinesin-1 activator, is spatially enriched in the oocyte through a dual mechanism involving Dynein-mediated transport from nurse cells and cortical maintenance by Ninein. This spatial enrichment of Ens is crucial for locally relieving Kinesin-1 auto-inhibition. The Ens/Khc complex promotes cortical recruitment of non-centrosomal microtubule organizing centers (ncMTOCs), which are essential for anchoring microtubules at the cortex, enabling the formation of long, parallel microtubule streams or "twisters" that drive cytoplasmic advection during late oogenesis. This work establishes a paradigm where motor protein activation is spatially controlled through targeted localization of regulatory cofactors, with the activated motor then participating in building its own transport infrastructure through ncMTOC recruitment and microtubule network organization.

      There's a lot to like about this paper! The data are generally lovely and nicely presented. The authors also use a combination of experimental approaches, combining genetics, live and fixed imaging, and protein biochemistry.

      We thank the reviewer for this enthusiastic and supportive review, which helped us further strengthen the manuscript.

      Concerns: Page 6: "to assay if elevation of Ninein levels was able to mis-regulate Ens localization, we overexpressed a tagged Ninein-RFP protein in the oocyte. At stage 9 the overexpressed Ninein accumulated at the anterior cortex of the oocyte and also generated large cortical aggregates able to recruit high levels of Ens (Figures 2D and 2H)... The examination of Ninein/Ens cortical aggregates obtained after Ninein overexpression showed that these aggregates were also able to recruit high levels of Patronin and Shot (Figures 2E and 2H)." Firstly, I'm not crazy about the use of "overexpressed" here, since there isn't normally any Ninein-RFP in the oocyte. In these experiments it has been therefore expressed, not overexpressed. Secondly, I don't understand what the reader is supposed to make of these data. Expression of a protein carrying a large fluorescent tag leads to large aggregates (they don't look cortical to me) that include multiple proteins - in fact, all the proteins examined. I don't understand this to be evidence of anything in particular, except that Ninein-RFP causes the accumulation of big multi-protein aggregates. While I can understand what the authors were trying to do here, I think that these data are inconclusive and should be de-emphasized.

      We have revised the manuscript by replacing overexpressed with expressed (lanes 211 and 212). In addition, we now provide new localization data in both cortical (new Figure S4 A, top) and medial focal planes (new Figure S4 A, bottom), demonstrating that Ninein puncta (the word used in Rosen et al, 2019), rather than aggregates are located cortically. We also show that live IRP-labelled MTs do not colocalize with Ninein-RFP puncta. In light of the new experiments and the comments from the other reviewers, the corresponding text has been revised and de-emphasized accordingly.

      Page 7: "Co-immunoprecipitations experiments revealed that Patronin was associated with Shot-YFP, as shown previously (Nashchekin et al., 2016), but also with EnsWT-GFP, indicating that Ens, Shot and Patronin are present in the same complex (Figure 3B)." I do not agree that association between Ens-GFP and Patronin indicates that Ens is in the same complex as Shot and Patronin. It is also very possible that there are two (or more) distinct protein complexes. This conclusion could therefore be softened. Instead of "indicating" I suggest "suggesting the possibility."

      We have toned down this conclusion and indicated "suggesting the possibility" (lane 238-239).

      Page 7: "During stage 9, the average subcortical MT length, taken at one focal plane in live oocytes (see methods)..." I appreciate that the authors have been careful to describe how they measured MT length, as this is a major point for interpretation. I think the reader would benefit from an explanation of why they decided to measure in only one focal plane and how that decision could impact the results.

      We appreciate this helpful suggestion. Cortical microtubules are indeed highly dynamic and extend in multiple directions, including along the Z-axis. Moreover, their diameter is extremely small (approximately 25 nm), making it technically challenging to accurately measure their full length with high resolution using our Zeiss Airyscan confocal microscope (over several, microns): the acquisition of Z-stacks is relatively slow and therefore not well suited to capturing the rapid dynamics of these microtubules. Consequently, our length measurements represent a compromise and most likely underestimate the actual lengths of microtubules growing outside the focal plane. We note that other groups have encountered similar technical limitations (Parton et al., 2011).

      Page 7: "... the MTs exhibited an orthogonal orientation relative to the anterior cortex (Figures 4A left panels, 4C and 4E)." This phenotype might not be obvious to readers. Can it be quantified?

      We have now analyzed the orientation of microtubules (MTs) along the dorso-ventral axis. Our analysis shows that ens, Khc RNAi oocytes (new Figure 5B), and, to a lesser extent, Nin mutant oocytes (new Figure 3D), display a more random MT orientation compared to wild-type (WT) oocytes. In WT oocytes, MTs are predominantly oriented toward the posterior pole, consistent with previous findings (Parton et al., 2011).

      Page 8: "Altogether, the analyses of Ens and Khc defective oocytes suggested that MT organization defects during late oogenesis (stage 10B) were caused by an initial failure of ncMTOCs to reach the cell cortex. Therefore, we hypothesized that overexpression of the ncMTOC component Shot could restore certain aspects of microtubule cortical organization in ens-deficient oocytes. Indeed, Shot overexpression (Shot OE) was sufficient to rescue the presence of long cortical MTs and ooplasmic advection in most ens oocytes (9/14)..." The data are clear, but the explanation is not. Can the authors please explain why adding in more of an ncMTOC component (Shot) rescues a defect of ncMTOC cortical localization?

      We propose that cytoplasmic ncMTOCs can bind the cell cortex via the Shot subunit that is so far the only component that harbors actin-binding motifs. Therefore, we propose that elevating cytoplasmic Shot increase the possibility of Shot to encounter the cortex by diffusion when flows are absent. This is now explained lane 282-285.

      I'm grateful to the authors for their inclusion of helpful diagrams, as in Figures 1G and 2H. I think the manuscript might benefit from one more of these at the end, illustrating the ultimate model.

      We have carefully considered and followed the reviewer's suggestions. In response, we have included a new figure illustrating our proposed model: the recruitment of ncMTOCs to the cell cortex through low Khc-mediated flows at stage 9 enhances cortical microtubule density, which in turn promotes self-amplifying flows (new Figure 7, panels A to C). Note that this Figure also depicts activation of Khc by loss of auto-inhibition (Figure 7, panel D).

      I'm sorry to say that the language could use quite a bit of polishing. There are missing and extraneous commas. There is also regular confusion between the use of plural and singular nouns. Some early instances include:

      1. Page 3: thought instead of "thoughted."
      2. Page 5: "A previous studies have revealed"
      3. Page 5: "A significantly loss"
      4. Page 6: "troughs ring canals" should be "through ring canals"
      5. Page 7: lives stage 9 oocytes
      6. Page 7: As ens and Khc RNAi oocytes exhibits
      7. Page 7: we examined in details
      8. Page 7: This average MT length was similar in Khc RNAi and ens mutant oocyte..

      We apologize for errors. We made the appropriate corrections of the manuscript.

      Reviewer #4 (Significance (Required)):

      This work makes a nice conceptual advance by showing that motor activation controls its own transport infrastructure, a paradigm that could extend to other systems requiring spatially regulated transport.

      We thank the reviewers for their evaluation of the manuscript and helpful comments.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #4

      Evidence, reproducibility and clarity

      Summary: This manuscript presents an investigation into the molecular mechanisms governing spatial activation of Kinesin-1 motor protein during Drosophila oogenesis, revealing a regulatory network that controls microtubule organization and cytoplasmic transport. The authors demonstrate that Ensconsin, a MAP7 family protein and Kinesin-1 activator, is spatially enriched in the oocyte through a dual mechanism involving Dynein-mediated transport from nurse cells and cortical maintenance by Ninein. This spatial enrichment of Ens is crucial for locally relieving Kinesin-1 auto-inhibition. The Ens/Khc complex promotes cortical recruitment of non-centrosomal microtubule organizing centers (ncMTOCs), which are essential for anchoring microtubules at the cortex, enabling the formation of long, parallel microtubule streams or "twisters" that drive cytoplasmic advection during late oogenesis. This work establishes a paradigm where motor protein activation is spatially controlled through targeted localization of regulatory cofactors, with the activated motor then participating in building its own transport infrastructure through ncMTOC recruitment and microtubule network organization.

      There's a lot to like about this paper! The data are generally lovely and nicely presented. The authors also use a combination of experimental approaches, combining genetics, live and fixed imaging, and protein biochemistry.

      Concerns:

      Page 6: "to assay if elevation of Ninein levels was able to mis-regulate Ens localization, we overexpressed a tagged Ninein-RFP protein in the oocyte. At stage 9 the overexpressed Ninein accumulated at the anterior cortex of the oocyte and also generated large cortical aggregates able to recruit high levels of Ens (Figures 2D and 2H)... The examination of Ninein/Ens cortical aggregates obtained after Ninein overexpression showed that these aggregates were also able to recruit high levels of Patronin and Shot (Figures 2E and 2H)." Firstly, I'm not crazy about the use of "overexpressed" here, since there isn't normally any Ninein-RFP in the oocyte. In these experiments it has been therefore expressed, not overexpressed. Secondly, I don't understand what the reader is supposed to make of these data. Expression of a protein carrying a large fluorescent tag leads to large aggregates (they don't look cortical to me) that include multiple proteins - in fact, all the proteins examined. I don't understand this to be evidence of anything in particular, except that Ninein-RFP causes the accumulation of big multi-protein aggregates. While I can understand what the authors were trying to do here, I think that these data are inconclusive and should be de-emphasized.

      Page 7: "Co-immunoprecipitations experiments revealed that Patronin was associated with Shot-YFP, as shown previously (Nashchekin et al., 2016), but also with EnsWT-GFP, indicating that Ens, Shot and Patronin are present in the same complex (Figure 3B)." I do not agree that association between Ens-GFP and Patronin indicates that Ens is in the same complex as Shot and Patronin. It is also very possible that there are two (or more) distinct protein complexes. This conclusion could therefore be softened. Instead of "indicating" I suggest "suggesting the possibility."

      Page 7: "During stage 9, the average subcortical MT length, taken at one focal plane in live oocytes (see methods)..." I appreciate that the authors have been careful to describe how they measured MT length, as this is a major point for interpretation. I think the reader would benefit from an explanation of why they decided to measure in only one focal plane and how that decision could impact the results.

      Page 7: "... the MTs exhibited an orthogonal orientation relative to the anterior cortex (Figures 4A left panels, 4C and 4E)." This phenotype might not be obvious to readers. Can it be quantified?

      Page 8: "Altogether, the analyses of Ens and Khc defective oocytes suggested that MT organization defects during late oogenesis (stage 10B) were caused by an initial failure of ncMTOCs to reach the cell cortex. Therefore, we hypothesized that overexpression of the ncMTOC component Shot could restore certain aspects of microtubule cortical organization in ens-deficient oocytes. Indeed, Shot overexpression (Shot OE) was sufficient to rescue the presence of long cortical MTs and ooplasmic advection in most ens oocytes (9/14)..." The data are clear, but the explanation is not. Can the authors please explain why adding in more of an ncMTOC component (Shot) rescues a defect of ncMTOC cortical localization?

      I'm grateful to the authors for their inclusion of helpful diagrams, as in Figures 1G and 2H. I think the manuscript might benefit from one more of these at the end, illustrating the ultimate model.

      I'm sorry to say that the language could use quite a bit of polishing. There are missing and extraneous commas. There is also regular confusion between the use of plural and singular nouns. Some early instances include:

      1. Page 3: thought instead of "thoughted."
      2. Page 5: "A previous studies have revealed"
      3. Page 5: "A significantly loss"
      4. Page 6: "troughs ring canals" should be "through ring canals"
      5. Page 7: lives stage 9 oocytes
      6. Page 7: As ens and Khc RNAi oocytes exhibits
      7. Page 7: we examined in details
      8. Page 7: This average MT length was similar in Khc RNAi and ens mutant oocyte..

      Significance

      This work makes a nice conceptual advance by showing that motor activation controls its own transport infrastructure, a paradigm that could extend to other systems requiring spatially regulated transport.

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      Referee #3

      Evidence, reproducibility and clarity

      The manuscript of Berisha et al., investigates the role of Esconsin (Ens), Kinesin-1 and Ninein in organisation of microtubules (MT) in Drosophila oocyte. At stage 9 oocytes Kinesin-1 transports oskar mRNA, a posterior determinant, along MT that are organised by ncMTOCs. At stage 10b, Kinesin-1 induces cytoplasmic advection to mix the contents of the oocyte. Ensconsin/Map7 is a MT associated protein (MAP) that uses its MT-binding domain (MBD) and kinesin binding domain (KBD) to recruit Kinesin-1 to the microtubules and to stimulate the motility of MT-bound Kinesin-1. Using various new Ens transgenes, the authors demonstrate the requirement of Ens MBD and Ninein in Ens localisation to the oocyte where Ens activates Kinesin-1 using its KBD. The authors also claim that Ens, Kinesin-1 and Ninein are required for the accumulation of ncMTOCs at the oocyte cortex and argue that the detachment of the ncMTOCs from the cortex accounts for the reduced localisation of oskar mRNA at stage 9 and the lack of cytoplasmic streaming at stage 10b.

      Although the manuscript contains several interesting observations, the authors' conclusions are not sufficiently supported by their data. The structure function analysis of Ensconsin (Ens) is potentially publishable, but the conclusions on ncMTOC anchoring and cytoplasmic streaming not convincing

      1. The main conclusion of the manuscript is that "MT advection failure in Khc and ens in late oogenesis stems from defective cortical ncMTOCs recruitment". This completely overlooks the abundant evidence that Kinesin-1 directly drives cytoplasmic streaming by transporting vesicles and microtubules along microtubules, which then move the cytoplasm by advection (Palacios et al., 2002; Serbus et al, 2005; Lu et al, 2016). Since Kinesin-1 generates the flows, one cannot conclude that the effect of khc and ens mutants on cortical ncMTOC positioning has any direct effect on these flows, which do not occur in these mutants.
      2. The authors claim that streaming phenotypes of ens and khs mutants are due to a decrease in microtubule length caused by the defective localisation of ncMTOCs. In addition to the problem raised above, However, I am not convinced that they can make accurate measurements of microtubule length from confocal images like those shown in Figure 4. Firstly, they are measuring the length of bundles of microtubules and cannot resolve individual microtubules. This problem is compounded by the fact that the microtubules do not align into parallel bundles in the mutants. This will make the "microtubules" appear shorter in the mutants. In addition, the alignment of the microtubules in wild-type allows one to choose images in which the microtubule lie in the imaging plane, whereas the more disorganised arrangement of the microtubules in the mutants means that most microtubules will cross the imaging plane, which precludes accurate measurements of their length.
      3. "To investigate whether the presence of these short microtubules in ens and Khc RNAi oocytes is due to defects in microtubule anchoring or is also associated with a decrease in microtubule polymerization at their plus ends, we quantified the velocity and number of EB1comets, which label growing microtubule plus ends (Figure S3)." I do not understand how the anchoring or not of microtubule minus ends to the cortex determines how far their plus ends grow, and these measurements fall short of showing that plus end growth is unaffected. It has already been shown that the Kinesin-1-dependent transport of Dynactin to growing microtubule plus ends increases the length of microtubules in the oocyte because Dynactin acts as an anti-catastrophe factor at the plus ends. Thus, khc mutants should have shorter microtubules independently of any effects on ncMTOC anchoring. The measurements of EB1 comet speed and frequency in FigS2 will not detect this change and are not relevant for their claims about microtubule length. Furthermore, the authors measured EB1 comets at stage 9 (where they did not observe short MT) rather than at stage 10b. The authors' argument would be better supported if they performed the measurements at stage 10b.
      4. The Shot overexpression experiments presented in Fig.3 E-F, Fig.4D and TableS1 are very confusing. Originally , the authors used Shot-GFP overexpression at stage 9 to show that there is a decrease of ncMTOCs at the cortex in ens mutants (Fig.3 E-F) and speculated that this caused the defects in MT length and cytoplasmic advection at stage 10B. However the authors later state on page 8 that : "Shot overexpression (Shot OE) was sufficient to rescue the presence of long cortical MTs and ooplasmic advection in most ens oocytes (9/14), resembling the patterns observed in controls (Figures 4B right panel and 4D). Moreover, while ens females were fully sterile, overexpression of Shot was sufficient to restore that loss of fertility (Table S1)". Is this the same UAS Shot-GFP and VP16 Gal4 used in both experiments? If so, this contradictions puts the authors conclusions in question.
      5. The authors based they conclusions about the involvement of Ens, Kinesin-1 and Ninein in ncMTOC anchoring on the decrease in cortical fluorescence intensity of Shot-YFP and Patronin-YFP in the corresponding mutant backgrounds. However, there is a large variation in average Shot-YFP intensity between control oocytes in different experiments. In Fig. 2F-G the average level of Shot-YFP in the control sis 130 AU while in Fig.3 G-H it is only 55 AU. This makes me worry about reliability of such measurements and the conclusions drawn from them.
      6. The decrease in the intensity of Shot-YFP and Patronin-YFP cortical fluorescence in ens mutant oocytes could be because of problems with ncMTOC anchoring or with ncMTOCsformation. The authors should find a way to distinguish between these two possibilities. The authors could express Ens-Mut (described in Sung et al 2008), which localises at the oocyte posterior and test whether it recruits Shot/Patronin ncMTOCs to the posterior.
      7. According to the Materials and Methods, the Shot-GFP used in Fig.3 E-F and Fig.4 was the BDSC line 29042. This is Shot L(C), a full-length version of Shot missing the CH1 actin-binding domain that is crucial for Shot anchoring to the cortex. If the authors indeed used this version of Shot-GFP, the interpretation of the above experiments is very difficult.
      8. Page 6 "converted in NCs, in a region adjacent to the ring canals, Dendra-Ens-labeled MTs were found in the oocyte compartment indicating they are able to travel from NC toward the oocyte trough ring canals". I have difficulty seeing the translocation of MT through the ring canals. Perhaps it would be more obvious with a movie/picture showing only one channel. Considering that f Dendra-Ens appears in the oocyte much faster than MT transport through ring canals (140nm/s, Lu et al 2022) , the authors are most probably observing the translocation of free Ens rather than Ens bound to MT. The authors should also mention that Ens movement from the NC to the oocyte has been shown before with Ens MBD in Lu et al 2022 with better resolution.
      9. Page 6: The co-localization of Ninein with Ens and Shot at the oocyte cortex (Figure 2A). I have difficulty seeing this co-localisation. Perhaps it would be more obvious in merged images of only two channels and with higher resolution images
      10. "a pool of the Ens-GFP co-localized with Ch-Patronin at cortical ncMTOCs at the anterior cortex (Figure 3A)". I also have difficulty seeing this.
      11. "Ninein co-localizes with Ens at the oocyte cortex and partially along cortical microtubules, contributing to the maintenance of high Ens protein levels in the oocyte and its proper cortical targeting". I could not find any data showing the involvement of Ninein in the cortical targeting of Ens.
      12. "our MT network analyses reveal the presence of numerous short MTs cytoplasmic clustered in an anterior pattern." "This low cortical recruitment of ncMTOCs is consistent with poor MT anchoring and their cytoplasmic accumulation." I could not find any data showing that short cortical MT observed at stage 10b in ens mutant and Khc RNAi were cytoplasmic and poorly anchored.
      13. "The egg chamber consists of interconnected cells where Dynein and Khc activities are spatially separated. Dynein facilitates transport from NCs to the oocyte, while Khc mediates both transport and advection within the oocyte." Dynein is involved in various activities in the oocyte. It anchors the oocyte nucleus and transports bcd and grk mRNA to mention a few.
      14. The cartoons in Fig.2H and 3I exaggerate the effect of Ninein and Ens on cortical ncMTOCs. According to the corresponding graphs, there is a 20 and 50% decrease in each case.

      Significance

      Given the important concerns raised, the significance of the findings is difficult to assess at this stage.

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      Referee #2

      Evidence, reproducibility and clarity

      In this manuscript, Berisha et al. investigate how microtubule (MT) organization is spatially regulated during Drosophila oogenesis. The authors identify a mechanism in which the Kinesin-1 activator Ensconsin/MAP7 is transported by dynein and anchored at the oocyte cortex via Ninein, enabling localized activation of Kinesin-1. Disruption of this pathway impairs ncMTOC recruitment and MT anchoring at the cortex. The authors combine genetic manipulation with high-resolution microscopy and use three key readouts to assess MT organization during mid-to-late oogenesis: cortical MT formation, localization of posterior determinants, and ooplasmic streaming. Notably, Kinesin-1, in concert with its activator Ens/MAP7, contributes to organizing the microtubule network it travels along. Overall, the study presents interesting findings, though we have several concerns we would like the authors to address.

      Ensconsin enrichment in the oocyte

      1. Enrichment in the oocyte
        • Ensconsin is a MAP that binds MTs. Given that microtubule density in the oocyte significantly exceeds that in the nurse cells, its enrichment may passively reflect this difference. To assess whether the enrichment is specific, could the authors express a non-Drosophila MAP (e.g., mammalian MAP1B) to determine whether it also preferentially localizes to the oocyte?
        • The ability of ens-wt and ens-LowMT to induce tubulin polymerization according to the light scattering data (Fig. S1J) is minimal and does not reflect dramatic differences in localization. The authors should verify that, in all cases, the polymerization product in their in vitro assays is microtubules rather than other light-scattering aggregates. What is the control in these experiments? If it is just purified tubulin, it should not form polymers at physiological concentrations.
      2. Photoconversion caveats MAPs are known to dynamically associate and dissociate from microtubules. Therefore, interpretation of the Ens photoconversion data should be made with caution. The expanding red signal from the nurse cells to the oocyte may reflect a any combination of dynein-mediated MT transport and passive diffusion of unbound Ensconsin. Notably, photoconversion of a soluble protein in the nurse cells would also result in a gradual increase in red signal in the oocyte, independent of active transport. We encourage the authors to more thoroughly discuss these caveats. It may also help to present the green and red channels side by side rather than as merged images, to allow readers to assess signal movement and spatial patterns better.
      3. Reduction of Shot at the anterior cortex
        • Shot is known to bind strongly to F-actin, and in the Drosophila ovary, its localization typically correlates more closely with F-actin structures than with microtubules, despite being an MT-actin crosslinker. Therefore, the observed reduction of cortical Shot in ens, nin mutants, and Khc-RNAi oocytes is unexpected. It would be important to determine whether cortical F-actin is also disrupted in these conditions, which should be straightforward to assess via phalloidin staining.
        • MTs are barely visible in Fig. 3A, which is meant to demonstrate Ens-GFP colocalization with tubulin. Higher-quality images are needed.
      4. MT gradient in stage 9 oocytes In ens-/-, nin-/-, and Khc-RNAi oocytes, is there any global defect in the stage 9 microtubule gradient? This information would help clarify the extent to which cortical localization defects reflect broader disruptions in microtubule polarity.
      5. Role of Ninein in cortical anchoring The requirement for Ninein in cortical anchorage is the least convincing aspect of the manuscript and somewhat disrupts the narrative flow. First, it is unclear whether Ninein exhibits the same oocyte-enriched localization pattern as Ensconsin. Is Ninein detectable in nurse cells? Second, the Ninein antibody signal appears concentrated in a small area of the anterior-lateral oocyte cortex (Fig. 2A), yet Ninein loss leads to reduced Shot signal along a much larger portion of the anterior cortex (Fig. 2F)-a spatial mismatch that weakens the proposed functional relationship. Third, Ninein overexpression results in cortical aggregates that co-localize with Shot, Patronin, and Ensconsin. Are these aggregates functional ncMTOCs? Do microtubules emanate from these foci?
      6. Inconsistency of Khc^MutEns rescue The Khc^MutEns variant partially rescues cortical MT formation and restores a slow but measurable cytoplasmic flow yet it fails to rescue Staufen localization (Fig. 5). This raises questions about the consistency and completeness of the rescue. Could the authors clarify this discrepancy or propose a mechanistic rationale?

      Minor points:

      1. The pUbi-attB-Khc-GFP vector was used to generate the Khc^MutEns transgenic line, presumably under control of the ubiquitous ubi promoter. Could the authors specify which attP landing site was used? Additionally, are the transgenic flies viable and fertile, given that Kinesin-1 is hyperactive in this construct?
      2. On page 11 (Discussion, section titled "A dual Ensconsin oocyte enrichment mechanism achieves spatial relief of Khc inhibition"), the statement "many mutations in Kif5A are causal of human diseases" would benefit from a brief clarification. Since not all readers may be familiar with kinesin gene nomenclature, please indicate that KIF5A is one of the three human homologs of Kinesin heavy chain.
      3. On page 16 (Materials and Methods, "Immunofluorescence in fly ovaries"), the sentence "Ovaries were mounted on a slide with ProlonGold medium with DAPI (Invitrogen)" should be corrected to "ProLong Gold."

      Significance

      This study shows that enrichment of MAP7/ensconsin in the oocyte is the mechanism of kinesin-1 activation there and is important for cytoplasmic streaming and localization non-centrosomal microtubule-organizing centers to the oocyte cortex

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      Referee #1

      Evidence, reproducibility and clarity

      This paper addresses a very interesting problem of non-centrosomal microtubule organization in developing Drosophila oocytes. Using genetics and imaging experiments, the authors reveal an interplay between the activity of kinesin-1, together with its essential cofactor Ensconsin, and microtubule organization at the cell cortex by the spectraplakin Shot, minus-end binding protein Patronin and Ninein, a protein implicated in microtubule minus end anchoring. The authors demonstrate that the loss of Ensconsin affects the cortical accumulation non-centrosomal microtubule organizing center (ncMTOC) proteins, microtubule length and vesicle motility in the oocyte, and show that this phenotype can be rescued by constitutively active kinesin-1 mutant, but not by Ensconsin mutants deficient in microtubule or kinesin binding. The functional connection between Ensconsin, kinesin-1 and ncMTOCs is further supported by a rescue experiment with Shot overexpression. Genetics and imaging experiments further implicate Ninein in the same pathway. These data are a clear strength of the paper; they represent a very interesting and useful addition to the field.

      The weaknesses of the study are two-fold. First, the paper seems to lack a clear molecular model, uniting the observed phenomenology with the molecular functions of the studied proteins. Most importantly, it is not clear how kinesin-based plus-end directed transport contributes to cortical localization of ncMTOCs and regulation of microtubule length.

      Second, not all conclusions and interpretations in the paper are supported by the presented data. Below is a list of specific comments, outlining the concerns, in the order of appearance in the paper/figures.

      1. Figure 1. The statement: "Ens loading on MTs in NCs and their subsequent transport by Dynein toward ring canals promotes the spatial enrichment of the Khc activator Ens in the oocyte" is not supported by data. The authors do not demonstrate that Ens is actually transported from the nurse cells to the oocyte while being attached to microtubules. They do show that the intensity of Ensconsin correlates with the intensity of microtubules, that the distribution of Ensconsin depends on its affinity to microtubules and that an Ensconsin pool locally photoactivated in a nurse cell can redistribute to the oocyte (and throughout the nurse cell) by what seems to be diffusion. The provided images suggest that Ensconsin passively diffuses into the oocyte and accumulates there because of higher microtubule density, which depends on dynein. To prove that Ensconsin is indeed transported by dynein in the microtubule-bound form, one would need to measure the residence time of Ensconsin on microtubules and demonstrate that it is longer than the time needed to transport microtubules by dynein into the oocyte; ideally, one would like to see movement of individual microtubules labelled with photoconverted Ensconsin from a nurse cell into the oocyte. Since microtubules are not enriched in the oocyte of the dynein mutant, analysis of Ensconsin intensity in this mutant is not informative and does not reveal the mechanism of Ensconsin accumulation.
      2. Figure 2. According to the abstract, this figure shows that Ensconsin is "maintained at the oocyte cortex by Ninein". However, the figure doesn't seem to prove it - it shows that oocyte enrichment of Ensonsin is partially dependent on Ninein, but this applies to the whole cell and not just to the cell cortex. Furthermore, it is not clear whether Ninein mutation affects microtubule density, which in turn would affect Ensconsin enrichment, and therefore, it is not clear whether the effect of Ninein loss on Ensconsin distribution is direct or indirect. The observation that the aggregates formed by overexpressed Ninein accumulate other proteins, including Ensconsin, supports, though does not prove their interactions. Furthermore, there is absolutely no proof that Ninein aggregates are "ncMTOCs". Unless the authors demonstrate that these aggregates nucleate or anchor microtubules (for example, by detailed imaging of microtubules and EB1 comets), the text and labels in the figure would need to be altered.

      Minor comment: Note that a "ratio" (Figure 2C) is just a ratio, and should not be expressed in arbitrary units. 3. Figure 3B: immunoprecipitation results cannot be interpreted because the immunoprecipitated proteins (GFP, Ens-GFP, Shot-YFP) are not shown. It is also not clear that this biochemical experiment is useful. If the authors would like to suggest that Ensconsin directly binds to Patronin, the interaction would need to be properly mapped at the protein domain level. 4. One of the major phenotypes observed by the authors in Ens mutant is the loss of long microtubules. The authors make strong conclusions about the independence of this phenotype from the parameters of microtubule plus-end growth, but in fact, the quality of their data does not allow to make such a conclusion, because they only measured the number of EB1 comets and their growth rate but not the catastrophe, rescue or pausing frequency. Note that kinesin-1 has been implicated in promoting microtubule damage and rescue (doi: 10.1016/j.devcel.2021). In the absence of such measurements, one cannot conclude whether short microtubules arise through defects in the minus-end, plus-end or microtubule shaft regulation pathways. It is important to note in that a spectraplakin, like Shot, can potentially affect different pathways, particularly when overexpressed. Unjustified conclusions should be removed: the authors do not provide sufficient data to conclude that "ens and Khc oocytes MT organizational defects are caused by decreased ncMTOC cortical anchoring", because the actual cortical microtubule anchoring was not measured.

      Minor comment: Microtubule growth velocity must be expressed in units of length per time, to enable evaluating the quality of the data, and not as a normalized value. 5. A significant part of the Discussion is dedicated to the potential role of Ensconsin in cortical microtubule anchoring and potential transport of ncMTOCs by kinesin. It is obviously fine that the authors discuss different theories, but it would be very helpful if the authors would first state what has been directly measured and established by their data, and what are the putative, currently speculative explanations of these data.

      Minor comment: The writing and particularly the grammar need to be significantly improved throughout, which should be very easy with current language tools. Examples: "ncMTOCs recruitment" should be "ncMTOC recruitment"; "Vesicles speed" should be "Vesicle speed", "Nin oocytes harbored a WT growth,"- unclear what this means, etc. Many paragraphs are very long and difficult to read. Making shorter paragraphs would make the authors' line of thought more accessible to the reader.

      Significance

      This paper represents significant advance in understanding non-centrosomal microtubule organization in general and in developing Drosophila oocytes in particular by connecting the microtubule minus-end regulation pathway to the Kinesin-1 and Ensconsin/MAP7-dependent transport. The genetics and imaging data are of good quality, are appropriately presented and quantified. These are clear strengths of the study which will make it interesting to researchers studying the cytoskeleton, microtubule-associated proteins and motors, and fly development.

      The weaknesses of this study are due to the lack of clarity of the overall molecular model, which would limit the impact of the study on the field. Some interpretations are not sufficiently supported by data, but this can be solved by more precise and careful writing, without extensive additional experimentation.

      My expertise is cell biology and biochemistry of the microtubule cytoskeleton, including both microtubule-associated proteins and microtubule motors.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      In this manuscript, Petelinec et al compared mitotic characteristics of cells cultured in 2D versus 3D using RPE1 p53KD, MDA-MB-231 (p53 R380K), U2OS (p53 WT), and OVSAHO (p53 R342*) cells. Magnetic particles were added to cells and those grown in 3D were transferred to a cell-repellent plate with a magnetic lid. The fraction of cells in mitotic stages after anaphase onset was reduced in cancer cell lines grown in 3D. In 1 of 3 cancer cell lines, this correlated with a ~20% increase in uncongressed chromosomes, though uncongressed chromosomes were also elevated in RPE1 p53KD cells, which did not exhibit a significant difference in mitotic stages in 2D versus 3D culture. Cell height increased in all 4 cell lines grown in 3D, and RPE1 p53KD and U2OS cells were more likely to exhibit a round morphology. Spindles in 3D culture were smaller in all four cell lines. Proteomic analysis showed a decrease in expression of mitotic proteins in 3D culture. Overall, the authors conclude that 3D culture induces shared and cell line-specific differences and that they have established a framework that connects proteome state to mitotic architecture.

      Major comments:

      1. The figure legend for S1A indicates that MDA-MB-231 cells grown in 3D expressed H2B-GFP, while the cells grown in 3D did not. Was that the case for all experiments? If so, comparison of these two different populations of cells could account for some of the differences observed throughout.
      2. The number of biological replicates as well as the number of cells analyzed per biological replicate should be clearly stated in the figure legends. As presented, much of the data appear to come from a single biological replicate, which would be insufficiently rigorous.
      3. The downregulation of mitotic proteins that are cell cycle regulated (Aurora A, cyclin A2, cyclin B1, Bub1B, CDC20, KIF11; doi: 10.1091/mbc.E13-05-0264) strongly suggests that, rather than the proposed "global rewiring of cell-cycle regulation in 3D", the proliferation rate is lower in 3D. Ki67 expression is markedly lower in MDA-MB-231 and RPE1 p53KD cells grown in 3D (Fig S4J). Quantitation of mitotic index is only provided for MDA-MB-231 and OVSAHO cells, and the values for the different cell lines are combined (Fig S1A). This is an unusual way to present the data, and obscures any differences that may be occurring. Together with the reported p value of 0.052, this does not provide strong evidence that proliferation rate is not reduced in 3D culture. Reporting the mitotic index for each cell line in 2D and 3D is a rapid and straightforward way to address this issue.
      4. The manuscript concludes that 3D culture increases multipolar spindles. However, this only appears to be true in MDA-MB-231 cells. In the 3 other cell types examined, the incidence of multipolarity appears to be <5%.
      5. Similarly, spindles in 3D culture are reported to be prone to "misalignment", but there are no data reporting the incidence of misaligned chromosomes in this section. Perhaps this is meant to indicate that they are misoriented with respect to the long axis of the cell, but changes in this orientation were only observed for 2 of the 4 cell lines.

      Minor comments:

      1. Though the model is described as "spheroids", the example in Fig 1B is not spherical, nor are the measurements described. Based on this, the term "spheroid" seems like a misnomer and another term (perhaps "organoid") would be a better descriptor.
      2. It would be helpful to include measurements for spindle height (in addition to length and width) in Fig 3.
      3. Based on the p values, it seems like the comparisons in Fig 1D, F, 2B,C,E, 3B,C,F,G,I,K were done by comparing the total number of cells rather than comparing the average of each biological replicate, which would be more rigorous.
      4. It is stated that SAC proteins were generally downregulated in 3D culture, and data for BUB1B are shown, but data for MAD2 should also be shown.
      5. The images in Fig 1C are too small to readily show that cells are elongated in 2D and round in 3D. Insets/higher magnification views are warranted.
      6. In Fig 2A, it would be helpful to indicate what stain was used to demarcate the cell boundaries to measure length and width in the figure legend.
      7. In Fig 2F, it isn't possible to distinguish the dots from the 8 different groups. It would be helpful to have 2 different graphs, one showing the data for cells grown in 2D and the other for cells grown in 3D.
      8. In Fig 3G, were the "round" and "elongated" categories based on measurements in Fig 3B-C? Or was this a qualitative assessment? It would be helpful to clarify this in the figure legend.

      Significance

      This article will be of interest to a specialized audience. Its strengths are that it provides 1) measurements of changes that occur in cell and spindle size in four human cell types by varying growth conditions in 2D versus 3D and 2) matched proteomics analysis. Its limitations are that 1) it is descriptive and 2) the physiological relevance of growth in spheroids due to magnetic levitation is unclear. While it seems reasonable that 3D growth is more physiologic than growth on 2D, and there are certainly differences between 2D and 3D culture, it is not clear that the changes that occur in 3D magnetic spheroids hold true for spheroids grown using other methodologies. Importantly, while it is implied that the changes observed in 3D growth are more representative of what occurs in the body, evidence for that is lacking. Directly providing these comparisons to other 3D systems or to human tissues would be both challenging and time consuming and is not considered necessary for publication of this work. However, a thorough and well-cited discussion of previous studies with such quantitation and clear acknowledgement of the extent to which the similarities between 3D culture and in vivo tissue environments remain unknown would provide substantial benefit.

      The proposed framework connecting proteome state to mitotic architecture would be an additional strength of the manuscript, but the link is underdeveloped in the current version of the manuscript. It would be helpful to describe multiple examples in which differing protein expression in the various cell lines correlated with the differential phenotypes observed.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      Petelinec et al. have documented thoroughly mitotic progression characteristics - mitotic timing, spindle assembly and chromosome segregation - in tumor cell lines from different organ origin. Taking advantage of a magnetic levitation approach to establish 3D cultures, they compared the same population of cells in this 3D setting with conventional 2D monolayers. This description is coupled with a proteomic profiling of mitotic cells that highlights differences in the level of key proteins involved in the regulation of the mitotic checkpoint and regulatory proteins essential for spindle assembly and mitotic timing.

      Major comments:

      The manuscript is well documented, explained and illustrated. Figures are self-explanatory and convincing. 1. Nonetheless, the manuscript in its current state is clearly lacking validation of some hits identified after the comparative proteomic profiling to demonstrate that the differences observed between the 3D and 2D settings can readily be explained by these cell intrinsic factors. If the authors correlate in figure 5 spindle morphometrics and proteomics, this is clearly not sufficient to prove any causal relationship. Along this line, the authors report a global downregulation of mitotic proteins from 2D to 3D settings (Figure 5). Nonetheless, they also report a mitotic index of 2.97% in 2D versus 1.62% in 3D, which is not significant. If mitotic proteins are readily downregulated, the index should be significantly different. This justifies the necessity to further validate functionally the differences observed regarding the mitotic protein level between the two settings. 2. The magnetic levitation approach is efficient to enable the organization of cells in multilayers and the establishment of 3D cell-cell contacts. Nonetheless, the flat appearance of the "spheroid" might reflect some stretching forces applied to the cells. Application of such forces might, on top of 3D cell-cell contacts impact mitotic progression and spindle organization. To address this point, comparison of mitotic characteristics of at least one cell line (MDA cells for example) cultured under magnetic levitation and in 3D round spheroid shape (which can be enabled by culturing the cells in suspension on a repulsive culture substrate) should be performed by the authors. 3. The authors report minor chromosome misalignments, probably due to prometaphase delay, based on immunofluorescent approaches using fixed samples (Figure 1). It is always better to perform time-lapse experiments to confirm deviations in mitotic timing, time spent in the different phases of mitosis and to evaluate final chromosome alignment before anaphase onset.

      Minor comments:

      1. Multipolar spindles appear more frequent in 3D settings (Figure 3). Can the authors relate this increase to polyploidization after more frequent cytokinesis failures in the 3D setting for example? Or to defects in spindle assembly by spindle pole splitting for example? They could perform centrosome protein staining to address this question.
      2. Do the authors have any explanation regarding the increased frequency of off-centered spindles in the 3D setting? They propose in the discussion a link with NuMA. Can the authors verify this point by immunofluorescent staining?

      Significance

      This is an unprecedented descriptive study of the impact of 3D cell-cell contacts on mitotic progression and spindle assembly in tumor cell lines in relation with proteomic profiling. In its state, the limitation of the study is the lack of validation of differences between 3D and 2D settings in protein level and impact of these differences on mitotic entry, progression or spindle formation. These findings will further fuel the concept that studying cancer cells in 3D is a pre-requisite (at least for some cancer cells) to study and/or target mitotic processes. This study will be of interest for cell biologists and especially mechanobiologists, with a particular interest in cancer biology. I am expert in cell biology, especially in the regulation of cell cycle progression.

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      Referee #1

      Evidence, reproducibility and clarity

      The authors investigate the impact of 3D culture systems compared to traditional 2D models on mitosis, with a particular focus on spindle assembly. To address this, they combine live imaging and mass spectrometry to analyze M-phase progression in 2D monolayers versus 3D spheroid cultures.

      While the figures are visually compelling, I found it difficult, by the end of the manuscript, to distill the main finding into a single clear statement-an issue that raises concerns about the overall focus of the study. In its current form, the central message and the novelty of the work remain unclear.

      I also have a few technical comments:

      1/ The choice of the 3D model, flat Spheroids generated using magnetic cell levitation (Souza et al., 2010), is somewhat unsatisfactory. As stated in the manuscript, 2 to 4 cell layers encompassing 20 to 50 m in Z, does not constitute a true 3D model. Did the authors observe differences in behavior depending on the thickness in Z (20 versus 50 m-wide regions)?

      2/Related to this, one of the conclusions from the work is that: "while 3D culture reshapes interphase cells, mitotic entry and overall cell cycle progression appear largely similar." But maybe it is the case because the 3D model is not really 3D, but closer to a 2D-one.

      3/ I have a difficulty to understand the difference in the quantification of phenotypes between 3F and 3G. What exactly is the difference between multipolar or irregular spindle?

      4/ The rationale behind the mass spectrometry approach is not entirely clear, or at least it is not sufficiently explained. It is unclear whether the authors performed mass spectrometry on asynchronous cell populations in both 2D and 3D conditions. Moreover, the proportion of mitotic cells differs between these conditions (approximately 3% in 2D versus 1.6% in 3D) and remains low overall. As a result, the mass spectrometry samples are likely to be predominantly composed of interphase cells. This raises concerns about the ability to draw meaningful conclusions regarding differences in the mitotic proteome and to reliably link these differences to observed mitotic phenotypes.

      5/Some of the mass spectrometry conclusions put forward (such as levels of KIF11 or NUMA) should at least be verified using immunofluorescence of mitotic in the different culture conditions.

      6/ The scheme presented in Fig 4B is very difficult to read and should be simplified

      Significance

      It is somewhat surprising that the authors neither cite nor discuss prior work on spindle scaling derived from embryonic models. Indeed, numerous studies using embryonic systems-which represent physiologically relevant 3D contexts-have extensively characterized the scaling relationship between mitotic spindle size and blastomere (i.e., cell) size (e.g., Wühr et al., Curr Biol 2008; Greenan et al., Curr Biol 2010; Courtois et al., J Cell Biol 2012; Wilbur & Heald, eLife 2013). Incorporating and discussing this body of work might help better contextualize the present findings and clarify how they relate to established scaling principles.

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      Reply to the reviewers

      Reviewer #1 (Evidence, reproducibility and clarity (Required)): __ In this manuscript, the authors describe the discovery of a molecular regulator of the immune transcriptional program, which is activated by intestinal distension upon bacterial colonization of the C. elegans intestine. Taking advantage of the fact that inhibition of aex-5 is known to cause intestinal distension and a C-type lectin gene clec-60 as a marker for the immune response to intestinal distension (clec-60p::gfp), the authors performed a forward genetic screen for suppressors of the immune response activation. Of the two mutants isolated, they focused on the stronger suppressor, which corresponded to a cysteine-type DUB, the Ubiquitin Specific Peptidase-14 (usp-14). Through rescue experiments, phenocopy analyses, and quantitative RT-PCR, they validated usp-14 as the causal gene and initiated characterization of its role in immune response activation. To this end, the authors investigated the tissue of action, identifying the intestine as the tissue in which usp-14 mediates the regulation of the immune response. Through transcriptomic analyses, they found that the signalling pathway likely regulated by usp-14 in response to intestinal distension is the Wnt pathway, as they have observed reduction in the transcriptional level of some of the Wnt pathway components in usp-4(tm1481), in response to infection with S. aureus. Additionally, transcriptomic data indicate that usp-14 plays a role in immunity regulation even in the absence of infection. Based on these findings, the authors propose that usp-14 has a dual role in immune regulation: one in surveillance immunity, preventing overactivation of immune responses, and another as a mediator of pathogen-induced responses, such as those triggered by P. aeruginosa or S. aureus. The experiments are rigorous and the results robust; however, some points would benefit from further investigation or clarification. __Response: We thank the reviewer for an excellent summary of our work and for the valuable feedback.

      Comment: The expression domain of usp-14 appears to be quite expanded based on single cell RNAseq data (e.g. PMID: 28818938) therefore it is likely that the transgenes used for expression analysis are lacking key regulatory information. Alternative methods like smFISH would be more appropriate to characterise the spatiotemporal pattern of usp-14 expression in more detail. Response: We thank the reviewer for this valuable suggestion. In the original version of the manuscript, we used a 714 bp region upstream of the usp-14 start codon to generate the transcriptional reporter. In the revised manuscript, we reconstructed the reporter using a longer 1924 bp upstream promoter region together with a portion of exon 1. Using this updated reporter, we observed substantially broader expression of usp-14, particularly during the early larval stages. These results are described on page 6, lines 148-153: “We next examined the spatiotemporal expression pattern of usp-14 in C. elegans. To this end, we generated transgenic worms expressing GFP under the control of the usp-14 promoter (usp-14p::gfp). During early larval development, usp-14 was broadly expressed across multiple tissues (Figure 3A). However, in L4 larvae and adult animals, expression became more restricted and was predominantly observed in the intestine and a subset of neuronal cells. Notably, both intestinal and neuronal expression persisted throughout development (Figure 3A).

      Comment: __The mutation mapped in usp-14(jsn19) is a missense mutation (E122K) that suppresses the immune response to a degree comparable to the usp-14(tm1481) deletion allele. However, the authors do not show the functional domains in Fig. 1E potentially affected by this missense mutation. __Response: We have now updated Figure 1E to include the functional domains of USP-14 and mapped both the usp-14(jsn19) missense allele and the usp-14(tm1481) deletion allele onto the protein schematic.

      Comment: __How USP-14 regulates Wnt and how Wnt signalling relates to activation of immune responses is not fully supported. Are the Wnt components mentioned in the study induced specifically in the intestine upon infection and does USP-14 act in the intestine in the context of this regulation? How do the authors interpret that both Wnt ligands and receptors are induced ? Does Wnt signalling appear as a GO term in the transcriptomic analysis? The authors can include Wnt signalling components in the analysis of the transcriptomic results. __Response: We thank the reviewer for these insightful comments. Previous studies have shown that the Wnt pathway components examined in our study are induced in the intestine upon infection and function within the intestine to regulate host defense against bacterial pathogens (PMID: 29768179; PMID: 36323254).

      We did not observe significant enrichment of Wnt signaling terms in the GO analysis of our transcriptomic dataset. We believe this is likely due to the stringent thresholds used for differential expression analysis (fold change > 2 and p At present, the precise mechanism by which USP-14 regulates Wnt pathway components remains unclear. One possibility is that USP-14 influences Wnt signaling indirectly through additional substrates or interacting proteins that regulate transcriptional outputs. We have now clarified this point in the Discussion (page 13, lines 344–349): “These observations raise the possibility that additional USP-14 substrates or interacting proteins modulate transcriptional outputs downstream of intestinal distension. Future studies aimed at identifying the direct substrates of USP-14 and defining how USP-14 interfaces with neuronal ACC-4 signaling and other distension-responsive pathways will provide important mechanistic insight into how intestinal distension is coupled to innate immune activation.

      Regarding the simultaneous induction of Wnt ligands and receptors, we interpret this as a potential amplification or reinforcement mechanism that enhances Wnt/β-catenin signaling during infection-induced intestinal distension. However, further studies will be required to determine the mechanistic significance of this coordinated transcriptional regulation.

      Comment: __Overall, in most of the figures, the micrographs are in general quite dark and exhibit poor contrast between signal and background, particularly in Fig. 1, panels B and J, and Fig. 2, panels B and F (upper rows). Even though these panels are intended to show absence of response, the outlines of the worms are difficult to discern. __Response: We thank the reviewer for the feedback. We have now improved the image presentation throughout the manuscript by either increasing the intensity or adding dotted outlines to more clearly indicate worm positions.

      Comment: __In Figure S3, panels A and B, the pmk-1(km25); usp-14(tm1481) animals subjected to aex-5 RNAi show some level of fluorescence/response induction comparable to pmk-1(km25) alone. This observation is not discussed in the text. __Response: We have now discussed this observation in the text. These results are described on page 9, lines 244-248: “Although pmk-1(km25);usp-14(tm1481) worms displayed relatively higher GFP levels than usp-14(tm1481) single mutants upon aex-5 RNAi treatment, this effect likely reflects the elevated basal GFP expression observed in pmk-1(km25) mutants (Figure S4B). Importantly, pmk-1(km25);usp-14(tm1481) animals still exhibited significantly lower GFP levels than pmk-1(km25) single mutants.

      Reviewer #1 (Significance (Required)): __ __Comment: __The work is interesting because it expands some previous work in the field demonstrating immune response induction as a consequence of intestinal distension even in the absence of bacterial infection. This is known to be mediated by the neuronal acetylcholine receptor ACC-4, which signals to the intestine where it regulates immune genes via the Wnt pathway. However, how USP-14 relates to ACC-4 is currently unclear and whether USP-14 function is really required in the intestine to control Wnt signalling is not demonstrated. The authors should include a model to describe how their findings relate to the previous literature and how USP-14 may link mechanistically to Wnt signalling pathway activation. __Response: We thank the reviewer for this insightful comment. We agree that the relationship between USP-14, ACC-4, and Wnt signaling requires further clarification. As suggested by the reviewer, we have now included a model summarizing the current understanding of intestinal distension-induced immune activation and integrating our findings with previous literature (Figure 6H).

      Comment: __It remains also unclear whether usp-14 is the only deubiquitinase involved in intestinal distension-induced signalling via the Wnt pathway, or whether other paralog usp genes might also contribute to regulation of immune-responsive transcription. Notably, several mammalian deubiquitinases have established roles in cancer suppression and inflammatory response and innate immunity in other systems so this would increase the potential significance of the work. __Response: We thank the reviewer for this valuable suggestion. To systematically examine whether additional DUBs contribute to intestinal distension-induced immune activation, we performed an RNAi screen targeting all DUBs available in the Ahringer RNAi library using the aex-5(sa23);clec-60p::gfp reporter strain. Among the DUBs tested, knockdown of usp-14 produced the strongest suppression of clec-60p::gfp expression. Although knockdown of usp-5 also partially suppressed GFP induction, usp-5 RNAi did not affect survival during P. aeruginosa infection, suggesting that usp-5 is not required for host defense under these conditions. Together, these findings identify USP-14 as the major DUB required for intestinal distension-induced immune activation in our experimental system. These results are now included in Figure 1G, H, and Figure S2.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)): __ Summary C. elegans are soil-dwelling nematodes that feed on bacteria and fungi and thus must be able to distinguish between innocuous and pathogenic species of microbes to survive. Though they lack adaptive immunity, these animals have an ancient version of an innate immune system that has no circulating sentinel or phagocytic cells yet can still mount a response to pathogen exposure. A consequence of the mode of infection of some ingested bacterial pathogens is intestinal distension which by itself, even in the absence of pathogens, is sufficient to trigger the expression of genes encoding immune effectors, including proteins that are bactericidal. The complete mechanistic scheme connecting intestinal distension to the expression of immunity genes has not been resolved, motivating the authors to perform a forward genetic screen for additional components of this pathway. One mutant that the authors isolated was usp-14, encoding an evolutionarily conserved deubiqutinating enzyme. Functional analysis revealed that usp-14 confers protection from microbial pathogens and that the intestine is its primary site of action for its role in host defense. The authors' data indicate that while USP-14 regulates the expression of innate immunity genes that are induced by intestinal distension, surprisingly it functions independently of several canonical innate immune signaling pathways, including the pmk-1/p38 MAPK pathway. Instead, USP-14 appears to act through Wnt signaling to regulate immune effectors by upregulating the expression of several components of that pathway, including the C. elegans ß-catenin ortholog bar-1. This places usp-14 within a gut-brain axis previously shown to control the C. elegans innate immune response through acetylcholine-mediated activation of Wnt signaling. The authors' findings provide new mechanistic insight to this pathway and add to the understanding of ubiqutination as an immune regulatory module. __Response: We thank the reviewer for providing an excellent summary of our work.

      Major comments __1. There are three types of experiments in which the authors use the same set of controls across several different figure panels, as stated in the legend to Figure 2. First, when quantifying GFP levels of clec-60::gfp in RNAi-treated animals, the authors use the same clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls for Fig. 1K, 2C, and 2G. For infection assays with S. aureus NCTC8325, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2E are the same as the ones used in Fig. 1M. Similarly, for infection assays with P. aeruginosa PA14, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2I is the same as was used for Fig 1I. In each case, if the authors in fact collected all of the data for each strain that they studied at the same time but then chose to parse larger datasets into separate figure panels to make it more clear to the reader, then this approach is valid but the authors need to explicitly state that this is what they did. However, if the data pertaining to the control strains were collected at a different time or if it comes from a separate biological replicate, then re-using data from the controls is not appropriate because it would not accurately reflect the specific conditions of the experiment to which the data are being compared. If this is indeed the scenario, then the authors will need to repeat these experiments and include the appropriate control in each iteration. __Response: While preparing the manuscript, these experiments were performed simultaneously. Therefore, all panels that share controls have results from experiments performed simultaneously and represent the same biological replicate. We have added this additional information in the relevant figure legends.

      Comment: __2. From the legends describing figure panels that include data pertaining to clec-60p::gfp expression levels as assessed by fluorescence microscopy it seems that, in general, the authors measured GFP fluorescence in about 30 animals to produce quantitative data. How many biological replicates of these types of experiments were carried out? This is not explicitly stated in the section describing fluorescence imaging in the Methods section. Following the description of their methodology regarding statistical analysis of survival curves from microbial infection assays, however, the authors state that, "[a]ll experiments were performed independently at least three times unless otherwise noted." Does this statement apply to microscopy or only to experiments involving infection assays? If the data reporting quantitation of GFP signal is based on only 30 animals, then additional biological replicates are necessary, along with appropriate statistical analyses. __Response: The quantified GFP fluorescence data are derived from three independent biological replicates. In each experiment, we typically imaged and quantified approximately 10 worms per condition, yielding a total of ~30 worms analyzed per genotype or treatment across all replicates (except Figure S1B, where we had two independent replicates). We have added the number of experiments in the figure legends for these data.

      Comment: __3. The authors have made all of the RNASeq data publicly available on the Sequence Read Archive, and they include data from several pairwise comparisons for differential gene expression analysis in their supplemental files. One of the most important facts to come out of the authors' Gene Ontology analyses of their RNASeq data is that the genes that are upregulated in a usp-14-dependent manner upon intestinal distension are enriched for those whose products play a role in innate immunity/host defense. The authors should say more about these genes. Are there any commonalities between them with regard to function? Are any of them targets of transcription factors that are known to function in C. elegans innate immunity? If so, this could provide clues as to what the substrates of USP-14 might be. Importantly, the specific identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense should be revealed in a supplemental file, and designated as being dependent on or independent of usp-14 for their expression during intestinal distension. __Response: We thank the reviewer for this insightful suggestion. We have now expanded the Results section to describe the functional categories enriched among the USP-14-dependent intestinal distension-induced immune genes, including C-type lectins, ShK toxin domain-containing proteins, and lysozymes (page 7, lines 194-196).

      In addition, we compared our transcriptomic dataset with previously published transcription factor-regulated gene sets using WormExp analysis and identified a substantial overlap with genes regulated by the GATA transcription factor ELT-2. These new analyses are described on page 7, lines 197-210: “To identify transcription factors potentially involved in intestinal distension-induced immune activation, we performed transcription factor enrichment analysis using WormExp on genes upregulated in N2 worms following aex-5 RNAi treatment. This analysis revealed a substantial overlap between aex-5 RNAi-induced genes and genes regulated by the GATA transcription factor ELT-2 (Figure S3D). We next examined whether USP-14-dependent immune genes overlapped with ELT-2-dependent immunity genes induced by intestinal distension. To this end, we identified innate immune genes common to both ELT-2-regulated gene sets and aex-5 RNAi-induced genes. Strikingly, these ELT-2-dependent intestinal distension-induced immune genes showed substantial overlap with USP-14-dependent immune genes (Figure S3E and Table S5), suggesting that USP-14 may regulate distension-induced immunity, at least in part, through ELT-2-dependent transcriptional programs. Consistent with this possibility, RNAi-mediated knockdown of elt-2 did not further increase the susceptibility of usp-14(tm1481) worms to P. aeruginosa infection relative to wild-type worms (Figure S3F), supporting a model in which USP-14-mediated immune responses require ELT-2 activity.

      Finally, we have created a new table (Table S5) that specifies the identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense, for USP-14-dependent and independent genes.

      Comment: __4. The authors' data suggest that in response to bacterial infection USP-14 upregulates the expression of bar-1, along with other components of the Wnt signaling pathway, which in turn upregulates innate immunity genes. This could be further substantiated by directly demonstrating that there are USP-14-regulated innate immunity genes whose induced expression in the presence of microbial pathogens also requires bar-1. Along those lines, an initial test would be to assess clec-60p::gfp expression in bar-1 animals versus bar-1;usp-14 double mutants, similar to the experiment whose results are reported in Fig. S4. If generating the bar-1;usp-14 double mutant is not feasible, then RNAi could be used to knockdown bar-1 expression in clec-60p::gfp;usp-14(tm1481) animals. To expand this analysis, the expression of the six innate immunity genes shown to be regulated upon intestinal distension in usp-14-dependent manner could be measured in the presence and absence of intestinal distension or microbial infection in bar-1 and bar-1;usp-14 animals by qRT-PCR. At a minimum, the authors should conduct a bioinformatics analysis to compare the USP-14-regulated innate immunity genes identified in their RNAseq studies to lists of known BAR-1 transcriptional targets to look for potential overlap. __Response: We agree that extending these analyses to qRT-PCR experiments examining additional immune genes would be informative. However, both bar-1 mutants and bar-1 RNAi-treated worms exhibited severe developmental and physiological defects, including sick and dead animals during development, likely reflecting the pleiotropic developmental roles of BAR-1. Although fluorescence imaging and survival assays could be performed by selectively transferring surviving adults, we were concerned that bulk collection of worms for qRT-PCR analyses would introduce confounding effects arising from developmental defects and reduced viability.

      To further address the reviewer’s suggestion, we carried out a comparative analysis between USP-14-dependent intestinal distension-induced immune genes and previously identified BAR-1-dependent immune genes. Although transcriptome-wide datasets for BAR-1-dependent pathogen-induced immune genes are not currently available, an earlier study identified seven immune response genes regulated by BAR-1 during infection (PMID: 18981407). We found that six of these genes overlap with the USP-14-dependent intestinal distension-induced immune genes identified in our study. These analyses have now been added to the Results section and included in Table S5.

      Comment: __5. While in their Discussion section the authors mention evolutionarily conserved roles for protein ubiquitination as means of immunomodulation, there are few if any comments regarding ubiqutination as a regulatory scheme in C. elegans innate immunity or how their findings enhance our understanding of this phenomenon. Ubiquitination affects C. elegans immunity at multiple levels, from avoidance behavior to gene regulation, and it seems appropriate for the authors to address this in order to more fully contextualize their findings. __Response: We thank the reviewer for the suggestion. We have now added a new paragraph to the Discussion that places our findings in the context of the existing literature on ubiquitination, deubiquitination, and innate immunity in C. elegans. The discussion is added on pages 11-12, lines 299-312: “Although ubiquitin-mediated signaling has emerged as a central regulator of innate immunity across metazoans (Jiang & Chen, 2011; Mello-Vieira & Dikic, 2026), the contribution of DUBs to host defense in C. elegans remains poorly understood. Previous studies in C. elegans have shown that ubiquitin-dependent processes regulate diverse aspects of immunity, including immune surveillance, xenophagy, and pathogen tolerance (Garcia-Sanchez et al, 2021). Perturbations in proteasome function have also been shown to activate surveillance immunity (Ghosh & Singh, 2026; Troemel et al, 2026), highlighting the importance of ubiquitin-associated pathways in sensing pathogen-induced cellular damage. However, most prior studies have focused on ubiquitin ligases, proteasome-associated pathways, or global ubiquitin signaling rather than on specific DUBs directly regulating antibacterial immune responses. To our knowledge, our study provides the first direct evidence that a specific DUB regulates antibacterial innate immunity in C. elegans. Thus, our findings establish USP-14 as a previously unrecognized regulator of host defense and identify deubiquitination as an important regulatory layer in intestinal distension-mediated immunity.

      __Minor comments __1. In the Results section, the authors state that "[k]nockdown of cec-10 led to only a marginal decrease in survival during P. aeruginosa infection" (lines 92 and 93) and that cec-10 "has minimal impact on C. elegans survival during infection" (lines 93 and 94). However, as reported in Supplemental Table 5 the magnitude of the calculated difference in mean survival time between animals treated with RNAi targeting cec-10 and untreated control animals (-20% to -24% and statistically significant in 3/3 replicates) closely approximates the difference in mean survival between usp-14 mutants and controls (-19% to -28% and statistically significant in 3/3 replicates), which the authors clearly find to be significant. If by this metric usp-14 is important for host defense, then so too is cec-10. In light of this, the authors should use different language to describe the impact of cec-10 knockdown on the susceptibility of C. elegans to microbial infection and the potential role of cec-10 in immunity.

      Response: We chose not to pursue cec-10 further primarily because it lacks a clear human homolog and because the mutant exhibited reduced expression of the co-injection marker, raising the possibility of broader transgene-related effects. We have modified the text on page 4, lines 93-97: “Knockdown of cec-10 resulted in a significant reduction in survival during P. aeruginosa infection (Figure S1C). However, we did not pursue cec-10 further for two reasons: (i) cec-10(jsn20) mutants exhibited a modest but significant reduction in the myo-2p::mCherry co-injection marker (Figure 1D), raising the possibility of broader transgene-related defects, and (ii) cec-10 lacks a clear human homolog.

      Comment: __2. All of the micrographs in Fig. 1B appear very dark. The GFP expression in the control animals appears dim, making it difficult for the reader to compare the signal in those animals to the GFP expression levels in the mutants. I recommend adjusting the brightness level in an equivalent manner across all of the micrographs to account for this. __Response: We have increased the brightness of all the images, as suggested by the reviewer.

      __Comment: __3. Fig. 1E depicts a gene structure diagram for usp-14 with the position of the point mutation in the jsn19 allele isolated in the authors' forward genetic screen indicated by the amino acid substitution symbol drawn over the second exon. Instead of mixing gene- and protein-level information about the jsn19 allele, I recommend replacing the gene structure diagram with a domain structure diagram of the USP-14 protein that depicts the conserved C19 peptidase and ubiquitin-like domains. The relative position of the E122K substitution should still be noted. __Response: __We have now updated Figure 1E to include the functional domains of USP-14 and mapped both the usp-14(jsn19) missense allele and the usp-14(tm1481) deletion allele onto the protein schematic.

      Comment: __4. Since all of the information in Fig. 1F appears elsewhere in the text, I recommend eliminating this panel. __Response: We have removed it.

      Comment: __5. Regarding the RNAseq analysis, the authors state that 1241 genes are upregulated upon aex-5 knockdown (line 162). The authors then ask which of these genes are regulated by usp-14 in the context of intestinal distension and find that 633 are upregulated a usp-14-dependent manner when aex-5 is targeted by RNAi and that 595 are upregulated even in the absence of usp-14 (Fig. 3D). This accounts for 1228 genes in total, not 1241. Can the authors explain this discrepancy? __Response: We thank the reviewer for carefully noting this discrepancy. The difference arises from the criteria used to classify genes into the categories shown in Figure 5D (previously Figure 3D). Specifically, genes uniquely upregulated in usp-14(tm1481) worms were defined as genes that were either exclusively induced in usp-14(tm1481) worms or expressed at levels more than 2-fold higher in usp-14(tm1481) worms compared to N2 worms. During this classification, 13 genes that were initially identified as upregulated in N2 worms following aex-5 RNAi were found to be expressed at levels more than 2-fold higher in usp-14(tm1481) worms than in N2 worms (Table S4). These genes were therefore reassigned to the “usp-14(tm1481)-specific” category in the Venn diagram. Consequently, the total number of genes represented in the Venn diagram becomes 1228 instead of 1241. To clarify this point, we have now added an explanation to the figure legend.

      Comment: __6. For the sake of clarity, in the legend to Fig. 3D I recommend expanding the description of the categories of genes depicted in the Venn diagram by using the same language as in the first worksheet of Supplemental Table 4. __Response: We thank the reviewer for the suggestion. We have now added these details to the legend of Figure 5D (previously Figure 3D). The legend reads: “(D) Venn diagram showing the overlap between genes upregulated upon aex-5 RNAi in N2 and usp-14(tm1481) worms. The GO analyses for the biological processes of unique and common genes are shown. USP-14-dependent genes were defined as genes that were either exclusively upregulated in N2 worms or expressed at levels greater than 2-fold higher in N2 worms than in usp-14(tm1481) worms. USP-14-independent genes were defined as genes upregulated in both N2 and usp-14(tm1481) worms with expression differences of less than 2-fold between the two strains. Genes uniquely upregulated in usp-14(tm1481) worms were defined as genes that were either exclusively induced in usp-14(tm1481) worms or expressed at levels greater than 2-fold higher in usp-14(tm1481) worms than in N2 worms. Thirteen genes classified as upregulated in N2 worms were more than 2-fold higher in usp-14(tm1481) worms than in N2 worms (Table S4) and were therefore included in the usp-14(tm1481)-specific category.

      Comment: __7. In Fig. 4B, the authors' annotation indicates that there is a statistically significant difference (**, p __Comment: __8. In Fig. S5, the shade of blue used to represent the data from the nhr-49(nr2041);usp-14(tm1481);clec60p::gfp animals in panel E is different from that used to represent data from the same animals in panel B. This breaks the pattern of all of the other panels of this figure in which the data pertaining to a given phenotype are depicted in the same color. Also, in the symbol key in panel E there is an extra semi-colon before clec-60p::gfp that should be eliminated in the second genotype notation. __Response: We thank the reviewer for carefully examining the figure and for bringing these issues to our attention. We have made the changes.

      Comment: __9. The authors' data show that USP-14 regulates bar-1 expression, and in the Discussion section they mention that in mammals beta-catenin is a substrate of USP14. Can the authors comment on the possibility of/evidence for BAR-1 autoregulation in C. elegans and the prospect of it being facilitated by USP-14? This could be a minor point to add to the Discussion. __Response: In both contexts, USP-14 appears to stabilize BAR-1 by regulating it at either the transcriptional or post-translational level. However, it is currently unknown whether BAR-1 regulates USP-14 expression and thereby participates in an autoregulatory mechanism. Nevertheless, we have added to the Discussion that USP14 may regulate the Wnt pathway through both transcriptional and post-translational mechanisms, depending on the biological context. __Reviewer #2 (Significance (Required)): __ The study described in this manuscript ties in to the findings from two prior genetic screens carried out in C. elegans that aimed to identify immune regulators (Ren et al., Cell Reports, 2022 and Labed et al., Immunity, 2018). Though their strategies differed, both of these previous studies uncovered a role for acetylcholine receptors in modulating the response to ingested microbial pathogens, especially when infection is associated with intestinal distension, indicating that a neuron-to-gut axis controls innate immunity in C. elegans. Labed and colleagues were the first to show that activation of this pathway results in the upregulation of genes encoding Wnt signaling pathway components, including the worm ortholog of beta-catenin called bar-1, which are necessary for the expression of immune effectors in the intestine. The Labed study also revealed that protein ubiquitination could contribute to regulating host defense gene induction because knockdown of lin-23, the substate binding subunit of a ubiquitin ligase complex that mediates BAR-1 degradation, results in constitutive expression of clec-60p::gfp, the same transcription reporter used by Ghosh and Singh as a readout for the expression of innate immunity genes. In their screen that revisits the Ren et al. approach, Ghosh and Singh find that another protein implicated in regulating protein stability via ubiquitination status, USP-14, also controls the expression of innate immunity genes in response to intestinal distension. Interestingly, their data indicate that it does so by upregulating bar-1. This discovery therefore adds an element of mechanistic detail regarding the regulation of Wnt signaling in immunity. While the Labed data suggest that ubiquitination may regulate BAR-1 at the post-translational level, Ghosh and Singhs' results indicate a second layer of regulation of bar-1 at the transcriptional level that also appears to involve ubiquitination. In this case, USP-14 is predicted to modulate the ubiquitination status of a yet-to-be-identified substrate that directly or indirectly governs bar-1 expression. The authors' findings thus bring the field closer to having a complete picture of the Ach-Wnt pathway in C. elegans. As they point out in the Discussion section of their manuscript, ubiquitination is an evolutionarily conserved yet complex means of tuning the immune system. The work described here helps to shed light on this important immune regulatory mode and could have implications for aspects of epithelial immunity that are in common to both invertebrates and vertebrates.

      Response: We thank the reviewer for providing such a thoughtful overview of the field and for placing our findings in the context of previous studies on intestinal distension-induced immunity in C. elegans. We also sincerely appreciate the reviewer’s constructive feedback and insightful comments, which have helped us improve the quality and clarity of the manuscript.

      My research interest and specific area of expertise pertains to evolutionarily conserved genetic pathways that control healthspan through affecting cellular resilience later in life. Using C. elegans as a surrogate for aging humans, my group studies age-dependent changes in the activity of regulatory modules that protect older animals from the molecular damage associated with intrinsic and extrinsic sources of cellular stress, with a particular emphasis on microbial infection and oxidative stress.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      C. elegans are soil-dwelling nematodes that feed on bacteria and fungi and thus must be able to distinguish between innocuous and pathogenic species of microbes to survive. Though they lack adaptive immunity, these animals have an ancient version of an innate immune system that has no circulating sentinel or phagocytic cells yet can still mount a response to pathogen exposure. A consequence of the mode of infection of some ingested bacterial pathogens is intestinal distension which by itself, even in the absence of pathogens, is sufficient to trigger the expression of genes encoding immune effectors, including proteins that are bactericidal. The complete mechanistic scheme connecting intestinal distension to the expression of immunity genes has not been resolved, motivating the authors to perform a forward genetic screen for additional components of this pathway. One mutant that the authors isolated was usp-14, encoding an evolutionarily conserved deubiqutinating enzyme. Functional analysis revealed that usp-14 confers protection from microbial pathogens and that the intestine is its primary site of action for its role in host defense. The authors' data indicate that while USP-14 regulates the expression of innate immunity genes that are induced by intestinal distension, surprisingly it functions independently of several canonical innate immune signaling pathways, including the pmk-1/p38 MAPK pathway. Instead, USP-14 appears to act through Wnt signaling to regulate immune effectors by upregulating the expression of several components of that pathway, including the C. elegans ß-catenin ortholog bar-1. This places usp-14 within a gut-brain axis previously shown to control the C. elegans innate immune response through acetylcholine-mediated activation of Wnt signaling. The authors' findings provide new mechanistic insight to this pathway and add to the understanding of ubiqutination as an immune regulatory module.

      Major comments

      1. There are three types of experiments in which the authors use the same set of controls across several different figure panels, as stated in the legend to Figure 2. First, when quantifying GFP levels of clec-60::gfp in RNAi-treated animals, the authors use the same clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls for Fig. 1K, 2C, and 2G. For infection assays with S. aureus NCTC8325, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2E are the same as the ones used in Fig. 1M. Similarly, for infection assays with P. aeruginosa PA14, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2I is the same as was used for Fig 1I. In each case, if the authors in fact collected all of the data for each strain that they studied at the same time but then chose to parse larger datasets into separate figure panels to make it more clear to the reader, then this approach is valid but the authors need to explicitly state that this is what they did. However, if the data pertaining to the control strains were collected at a different time or if it comes from a separate biological replicate, then re-using data from the controls is not appropriate because it would not accurately reflect the specific conditions of the experiment to which the data are being compared. If this is indeed the scenario, then the authors will need to repeat these experiments and include the appropriate control in each iteration.
      2. From the legends describing figure panels that include data pertaining to clec-60p::gfp expression levels as assessed by fluorescence microscopy it seems that, in general, the authors measured GFP fluorescence in about 30 animals to produce quantitative data. How many biological replicates of these types of experiments were carried out? This is not explicitly stated in the section describing fluorescence imaging in the Methods section. Following the description of their methodology regarding statistical analysis of survival curves from microbial infection assays, however, the authors state that, "[a]ll experiments were performed independently at least three times unless otherwise noted." Does this statement apply to microscopy or only to experiments involving infection assays? If the data reporting quantitation of GFP signal is based on only 30 animals, then additional biological replicates are necessary, along with appropriate statistical analyses.
      3. The authors have made all of the RNASeq data publicly available on the Sequence Read Archive, and they include data from several pairwise comparisons for differential gene expression analysis in their supplemental files. One of the most important facts to come out of the authors' Gene Ontology analyses of their RNASeq data is that the genes that are upregulated in a usp-14-dependent manner upon intestinal distension are enriched for those whose products play a role in innate immunity/host defense. The authors should say more about these genes. Are there any commonalities between them with regard to function? Are any of them targets of transcription factors that are known to function in C. elegans innate immunity? If so, this could provide clues as to what the substrates of USP-14 might be. Importantly, the specific identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense should be revealed in a supplemental file, and designated as being dependent on or independent of usp-14 for their expression during intestinal distension.
      4. The authors' data suggest that in response to bacterial infection USP-14 upregulates the expression of bar-1, along with other components of the Wnt signaling pathway, which in turn upregulates innate immunity genes. This could be further substantiated by directly demonstrating that there are USP-14-regulated innate immunity genes whose induced expression in the presence of microbial pathogens also requires bar-1. Along those lines, an initial test would be to assess clec-60p::gfp expression in bar-1 animals versus bar-1;usp-14 double mutants, similar to the experiment whose results are reported in Fig. S4. If generating the bar-1;usp-14 double mutant is not feasible, then RNAi could be used to knockdown bar-1 expression in clec-60p::gfp;usp-14(tm1481) animals. To expand this analysis, the expression of the six innate immunity genes shown to be regulated upon intestinal distension in usp-14-dependent manner could be measured in the presence and absence of intestinal distension or microbial infection in bar-1 and bar-1;usp-14 animals by qRT-PCR. At a minimum, the authors should conduct a bioinformatics analysis to compare the USP-14-regulated innate immunity genes identified in their RNAseq studies to lists of known BAR-1 transcriptional targets to look for potential overlap.
      5. While in their Discussion section the authors mention evolutionarily conserved roles for protein ubiquitination as means of immunomodulation, there are few if any comments regarding ubiqutination as a regulatory scheme in C. elegans innate immunity or how their findings enhance our understanding of this phenomenon. Ubiquitination affects C. elegans immunity at multiple levels, from avoidance behavior to gene regulation, and it seems appropriate for the authors to address this in order to more fully contextualize their findings.

      Minor comments

      1. In the Results section, the authors state that "[k]nockdown of cec-10 led to only a marginal decrease in survival during P. aeruginosa infection" (lines 92 and 93) and that cec-10 "has minimal impact on C. elegans survival during infection" (lines 93 and 94). However, as reported in Supplemental Table 5 the magnitude of the calculated difference in mean survival time between animals treated with RNAi targeting cec-10 and untreated control animals (-20% to -24% and statistically significant in 3/3 replicates) closely approximates the difference in mean survival between usp-14 mutants and controls (-19% to -28% and statistically significant in 3/3 replicates), which the authors clearly find to be significant. If by this metric usp-14 is important for host defense, then so too is cec-10. In light of this, the authors should use different language to describe the impact of cec-10 knockdown on the susceptibility of C. elegans to microbial infection and the potential role of cec-10 in immunity.
      2. All of the micrographs in Fig. 1B appear very dark. The GFP expression in the control animals appears dim, making it difficult for the reader to compare the signal in those animals to the GFP expression levels in the mutants. I recommend adjusting the brightness level in an equivalent manner across all of the micrographs to account for this.
      3. Fig. 1E depicts a gene structure diagram for usp-14 with the position of the point mutation in the jsn19 allele isolated in the authors' forward genetic screen indicated by the amino acid substitution symbol drawn over the second exon. Instead of mixing gene- and protein-level information about the jsn19 allele, I recommend replacing the gene structure diagram with a domain structure diagram of the USP-14 protein that depicts the conserved C19 peptidase and ubiquitin-like domains. The relative position of the E122K substitution should still be noted.
      4. Since all of the information in Fig. 1F appears elsewhere in the text, I recommend eliminating this panel.
      5. Regarding the RNAseq analysis, the authors state that 1241 genes are upregulated upon aex-5 knockdown (line 162). The authors then ask which of these genes are regulated by usp-14 in the context of intestinal distension and find that 633 are upregulated a usp-14-dependent manner when aex-5 is targeted by RNAi and that 595 are upregulated even in the absence of usp-14 (Fig. 3D). This accounts for 1228 genes in total, not 1241. Can the authors explain this discrepancy?
      6. For the sake of clarity, in the legend to Fig. 3D I recommend expanding the description of the categories of genes depicted in the Venn diagram by using the same language as in the first worksheet of Supplemental Table 4.
      7. In Fig. 4B, the authors' annotation indicates that there is a statistically significant difference (**, p<0.01) in the fluorescence signal from clec-60p::gfp in usp-14(jsn19);aex-5(sa23);clec-60p::gfp_EV versus usp-14(jsn19);aex-5(sa23);clec-60p::gfp_bar-1 animals. This is likely a typographical error that should be changed to "ns" to indicate no significant difference in the fluorescence signal between these two groups, which is consistent with what the data show and with the authors' description of these data in the text (lines 211-214).
      8. In Fig. S5, the shade of blue used to represent the data from the nhr-49(nr2041);usp-14(tm1481);clec60p::gfp animals in panel E is different from that used to represent data from the same animals in panel B. This breaks the pattern of all of the other panels of this figure in which the data pertaining to a given phenotype are depicted in the same color. Also, in the symbol key in panel E there is an extra semi-colon before clec-60p::gfp that should be eliminated in the second genotype notation.
      9. The authors' data show that USP-14 regulates bar-1 expression, and in the Discussion section they mention that in mammals beta-catenin is a substrate of USP14. Can the authors comment on the possibility of/evidence for BAR-1 autoregulation in C. elegans and the prospect of it being facilitated by USP-14? This could be a minor point to add to the Discussion.

      Significance

      The study described in this manuscript ties in to the findings from two prior genetic screens carried out in C. elegans that aimed to identify immune regulators (Ren et al., Cell Reports, 2022 and Labed et al., Immunity, 2018). Though their strategies differed, both of these previous studies uncovered a role for acetylcholine receptors in modulating the response to ingested microbial pathogens, especially when infection is associated with intestinal distension, indicating that a neuron-to-gut axis controls innate immunity in C. elegans. Labed and colleagues were the first to show that activation of this pathway results in the upregulation of genes encoding Wnt signaling pathway components, including the worm ortholog of beta-catenin called bar-1, which are necessary for the expression of immune effectors in the intestine. The Labed study also revealed that protein ubiquitination could contribute to regulating host defense gene induction because knockdown of lin-23, the substate binding subunit of a ubiquitin ligase complex that mediates BAR-1 degradation, results in constitutive expression of clec-60p::gfp, the same transcription reporter used by Ghosh and Singh as a readout for the expression of innate immunity genes. In their screen that revisits the Ren et al. approach, Ghosh and Singh find that another protein implicated in regulating protein stability via ubiquitination status, USP-14, also controls the expression of innate immunity genes in response to intestinal distension. Interestingly, their data indicate that it does so by upregulating bar-1. This discovery therefore adds an element of mechanistic detail regarding the regulation of Wnt signaling in immunity. While the Labed data suggest that ubiquitination may regulate BAR-1 at the post-translational level, Ghosh and Singhs' results indicate a second layer of regulation of bar-1 at the transcriptional level that also appears to involve ubiquitination. In this case, USP-14 is predicted to modulate the ubiquitination status of a yet-to-be-identified substrate that directly or indirectly governs bar-1 expression. The authors' findings thus bring the field closer to having a complete picture of the Ach-Wnt pathway in C. elegans. As they point out in the Discussion section of their manuscript, ubiquitination is an evolutionarily conserved yet complex means of tuning the immune system. The work described here helps to shed light on this important immune regulatory mode and could have implications for aspects of epithelial immunity that are in common to both invertebrates and vertebrates.

      My research interest and specific area of expertise pertains to evolutionarily conserved genetic pathways that control healthspan through affecting cellular resilience later in life. Using C. elegans as a surrogate for aging humans, my group studies age-dependent changes in the activity of regulatory modules that protect older animals from the molecular damage associated with intrinsic and extrinsic sources of cellular stress, with a particular emphasis on microbial infection and oxidative stress.

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      Referee #1

      Evidence, reproducibility and clarity

      In this manuscript, the authors describe the discovery of a molecular regulator of the immune transcriptional program, which is activated by intestinal distension upon bacterial colonization of the C. elegans intestine. Taking advantage of the fact that inhibition of aex-5 is known to cause intestinal distension and a C-type lectin gene clec-60 as a marker for the immune response to intestinal distension (clec-60p::gfp), the authors performed a forward genetic screen for suppressors of the immune response activation. Of the two mutants isolated, they focused on the stronger suppressor, which corresponded to a cysteine-type DUB, the Ubiquitin Specific Peptidase-14 (usp-14). Through rescue experiments, phenocopy analyses, and quantitative RT-PCR, they validated usp-14 as the causal gene and initiated characterization of its role in immune response activation. To this end, the authors investigated the tissue of action, identifying the intestine as the tissue in which usp-14 mediates the regulation of the immune response. Through transcriptomic analyses, they found that the signalling pathway likely regulated by usp-14 in response to intestinal distension is the Wnt pathway, as they have observed reduction in the transcriptional level of some of the Wnt pathway components in usp-4(tm1481), in response to infection with S. aureus. Additionally, transcriptomic data indicate that usp-14 plays a role in immunity regulation even in the absence of infection. Based on these findings, the authors propose that usp-14 has a dual role in immune regulation: one in surveillance immunity, preventing overactivation of immune responses, and another as a mediator of pathogen-induced responses, such as those triggered by P. aeruginosa or S. aureus. The experiments are rigorous and the results robust; however, some points would benefit from further investigation or clarification.

      The expression domain of usp-14 appears to be quite expanded based on single cell RNAseq data (e.g. PMID: 28818938) therefore it is likely that the transgenes used for expression analysis are lacking key regulatory information. Alternative methods like smFISH would be more appropriate to characterise the spatiotemporal pattern of usp-14 expression in more detail.

      The mutation mapped in usp-14(jsn19) is a missense mutation (E122K) that suppresses the immune response to a degree comparable to the usp-14(tm1481) deletion allele. However, the authors do not show the functional domains in Fig. 1E potentially affected by this missense mutation.

      How USP-14 regulates Wnt and how Wnt signalling relates to activation of immune responses is not fully supported. Are the Wnt components mentioned in the study induced specifically in the intestine upon infection and does USP-14 act in the intestine in the context of this regulation? How do the authors interpret that both Wnt ligands and receptors are induced ? Does Wnt signalling appear as a GO term in the transcriptomic analysis? The authors can include Wnt signalling components in the analysis of the transcriptomic results.

      Overall, in most of the figures, the micrographs are in general quite dark and exhibit poor contrast between signal and background, particularly in Fig. 1, panels B and J, and Fig. 2, panels B and F (upper rows). Even though these panels are intended to show absence of response, the outlines of the worms are difficult to discern.

      In Figure S3, panels A and B, the pmk-1(km25); usp-14(tm1481) animals subjected to aex-5 RNAi show some level of fluorescence/response induction comparable to pmk-1(km25) alone. This observation is not discussed in the text.

      Significance

      The work is interesting because it expands some previous work in the field demonstrating immune response induction as a consequence of intestinal distension even in the absence of bacterial infection. This is known to be mediated by the neuronal acetylcholine receptor ACC-4, which signals to the intestine where it regulates immune genes via the Wnt pathway. However, how USP-14 relates to ACC-4 is currently unclear and whether USP-14 function is really required in the intestine to control Wnt signalling is not demonstrated. The authors should include a model to describe how their findings relate to the previous literature and how USP-14 may link mechanistically to Wnt signalling pathway activation.

      It remains also unclear whether usp-14 is the only deubiquitinase involved in intestinal distension-induced signalling via the Wnt pathway, or whether other paralog usp genes might also contribute to regulation of immune-responsive transcription. Notably, several mammalian deubiquitinases have established roles in cancer suppression and inflammatory response and innate immunity in other systems so this would increase the potential significance of the work.

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      Reply to the reviewers

      Revision Plan

      1. General Statements

      We thank the reviewers for their positive and constructive assessment of the manuscript. We are encouraged that all three reviewers recognise the value of coelsch as an open-source framework for haplotyping and crossover detection from single-cell gamete sequencing data, and that they view the study as a useful contribution to the fields of recombination and genetic research. We are particularly grateful that Reviewer 1 described the manuscript as an "interesting and important study" and a "genuinely useful methodological framework that fills a real gap in the recombination biology toolkit", while Reviewer 2 highlighted its "strong innovation, complete technical pipeline, and significant biological implications" and considered it an "important technical breakthrough". We also appreciate Reviewer 3's assessment that the study provides "timely guidance for experimental design", that the results are "important for guiding plant single-cell research" in general, and that the work "has the potential to attract a broad readership".

      In our view, the main contribution of the manuscript is the development of a platform-agnostic method for recovering haplotypes and crossover events from single-cell sequencing data. This addresses an important practical gap: single-cell gamete sequencing has strong potential for high-throughput haplotyping and recombination mapping, but its broader use requires tools that can accommodate the very different coverage structures produced by different sequencing modalities and platforms. coelsch was designed to meet this need.

      The experimental datasets in the manuscript serve two purposes. First, they demonstrate that coelsch can be applied across multiple single-cell modalities and platforms, including scRNA, scATAC and scWGA sequencing from 10x Genomics, BD, and Takara platforms. Second, they illustrate the kinds of biological and practical questions that can be addressed with single-cell gamete sequencing, including crossover detection in meiotic mutants and large-scale analysis of natural variation in recombination.

      While all reviewers strongly supported the publication of the work, they also raised important points about specific aspects, including technical variation and reproducibility, the rationale for using 10x scRNA to generate the diversity panel dataset, and the effects of coverage on crossover localisation, amongst others. We agree that addressing these points will make the manuscript clearer and more useful to readers. Our planned revisions therefore aim to strengthen the experimental and computational support for the framework, clarify the interpretation of the modality comparisons, and provide additional guidance for researchers who may wish to apply coelsch or related single-cell sequencing approaches in future studies.

      2. Description of the planned revisions

      2.1. Additional technical replicates and clearer treatment of batch/sample-handling effects

      Reviewers 1, 2 and 3 all noted that the comparison of different platforms and modalities is based on limited replication, with different nuclei isolation and processing strategies used for different technologies. Reviewer 3 requested a fully controlled benchmark in which the same nuclei preparation is split across all tested platforms. We agree that this would be the ideal design for a dedicated head-to-head benchmarking study. However, the primary aim of the manuscript is to demonstrate the applicability of coelsch across different single-cell sequencing data types, rather than to provide a definitive benchmark of the intrinsic performance of each modality and platform.

      In addition, a fully matched and replicated cross-platform experiment for all technologies is not feasible. Isolated nuclei deteriorate rapidly after preparation and must be processed promptly for single-cell library construction; this makes it impractical to distribute the same preparation across multiple time- and labour-intensive workflows. However, this design is feasible for 10x scRNA-seq and 10x scATAC-seq. To address this point directly, we will therefore generate two matched technical replicates each of 10x scRNA-seq and 10x scATAC-seq from nuclei isolated in the same sorting run.

      We will also improve our library-level QC summary tables. We will report, where available, the number of nuclei used for loading, recovered barcodes, barcodes retained after QC, inferred high-quality nuclei and artefacts, informative fragments per nucleus, genomic bin coverage, and final nuclei used for crossover calling. This will make the effects of loading, capture efficiency, QC filtering, and modality-specific data loss more transparent.

      In the revised text, we will distinguish more clearly between modality-specific effects and possible batch/sample-preparation effects. Where the current manuscript implies that differences are intrinsic properties of sequencing platforms, we will soften the interpretation unless supported by the new replicate data, reproducibility analyses, or well-supported properties that have been reported previously in literature.

      2.2. Rationale for using 10x scRNA-seq in the natural variation panel

      Reviewers 1 and 3 asked why the natural variation panel was analysed using 10x scRNA-seq, given that Takara scWGA produced higher per-cell crossover localisation accuracy in the modality comparison. We will revise the manuscript to explain this experimental decision more clearly.

      The natural variation panel was designed as a high-throughput experiment requiring sufficient numbers of usable nuclei from many pooled F₁ hybrids. In our hands, 10x scRNA-seq has generally produced the largest number of usable nuclei barcodes and the lowest proportion of artefacts. This makes 10x scRNA-seq well suited to experiments where many nuclei are required per genotype. By contrast, applying Takara scWGA to a pooled panel of this scale would be expected to recover only tens of usable nuclei per F₁ hybrid, which would be insufficient for robust recombination-rate or landscape estimation.

      We will add this explanation to the relevant Results section and clarify that the choice of 10x scRNA-seq reflects a trade-off between per-cell crossover resolution and the number of informative nuclei recovered per genotype. We will also add genotype-level summaries for the pooled natural variation experiment, including assigned nuclei per genotype and genotype-specific genomic coverage of informative fragments.

      2.3. Reproducibility of recombination landscapes across replicates and modalities

      Reviewer 1 requested recombination landscape plots for all tested modalities, and several comments raised the need to show within-modality reproducibility. We will add recombination landscape plots for wild-type Col-0 × Ler libraries across the tested modalities, including the newly generated replicate 10x scATAC and scRNA libraries.

      We will assess reproducibility using comparisons of unsmoothed, non-overlapping windowed recombination-rate estimates, both within and between modalities. These will be quantified using bootstrapped estimates of spearman rank correlation coefficient, and visualised using scatterplots and/or recombination landscapes.

      2.4. Sequencing depth, coverage, and crossover localisation resolution

      Reviewers 1 and 3 requested clearer quantitative reporting of crossover resolution and a stronger analysis of depth effects. We will revise the manuscript to report practical crossover localisation resolution for each modality, including median and interquartile localisation error or interval size in genomic units.

      We will expand the simulation analyses to compare false-positive and negative rates and localisation accuracy across modalities, including telomere-proximal error profiles for scWGA and scATAC as well as 10x RNA data. We will perform downsampling analyses to assess how crossover detection accuracy changes as a function of informative-fragment depth. Where feasible, we will compare depth-matched subsets across modalities to distinguish effects of sequencing depth from modality-specific coverage structure.

      These analyses will be used to clarify the extent to which each modality is suitable for different applications, such as broad landscape estimation, crossover counting, or fine localisation.

      2.5. Artefact detection, high doublet rates, and representativeness after filtering

      All three reviewers raised concerns about the high proportion of barcodes excluded by the filtering procedure, particularly in the Takara scWGA dataset. In hindsight, we believe part of this concern stems from the poor choice of terminology ("doublets") we used to describe these excluded barcodes.

      While true doublets (i.e. two nuclei entering a single droplet or nanowell) are one likely source of such signals, the filtering procedure more broadly identifies artefactual barcodes that do not exhibit a clear single-gamete haplotype structure. These barcodes may arise from a variety of sources, including doublets, multiplets, high levels of ambient DNA or RNA, or empty droplets containing only ambient material. Although visual examination can be used to make predictions about the source of these artefacts, our detection method does not attempt to distinguish between them, and artefacts in different modalities may stem from different sources in varying proportions. We will therefore revise the terminology throughout the manuscript to clarify that these represent a broader class of low-confidence or noise barcodes, rather than confirmed doublets.

      For the Takara scWGA data, we will revise the manuscript to discuss the discrepancy between the CellSelect well classifications (which uses proprietary software to label doublets) and the final artefact predictions from coelsch. We can only speculate as to why CellSelect failed to detect many apparent doublet and multiplet artefacts in this experiment, but we agree with the reviewer that the most likely explanation is the small size of Arabidopsis pollen nuclei relative to the expectations of the imaging and classification procedure. To support this interpretation, we will add supplementary analysis comparing the CellSelect images from individual nanowells with the final doublet predictions inferred from scWGA data. This will allow readers to see examples of wells classified as acceptable by CellSelect but subsequently inferred to contain artefacts based on their haplotype structure.

      We will also add sensitivity analyses showing how key results change under different artefact-filtering thresholds. These analyses will include crossover count distributions, recombination landscape estimates, and modality-level comparisons. We will examine the extreme upper tail of crossover counts observed in 10x scATAC-seq and assess whether these barcodes are artefacts that have escaped detection.

      Finally, we will assess whether retained singlets are representative of the input data with respect to informative-fragment counts, coverage, and inferred crossover patterns. This will address the concern that filtering could preferentially remove nuclei with particular recombination profiles.

      2.6. Biases arising from pollen nuclear biology

      Reviewer 2 raised an issue concerning the biases arising from the two different nuclei types present in mature trinuclear Arabidopsis pollen, and reviewer 3 endorsed this point. While we do not agree with the reviewer that scRNA and scATAC cannot capture sperm nuclei due to their condensed nature (see Parker et al. 2025 PLoS Biology for evidence against this claim), it is true that technical variation in nuclei isolation and sorting may affect the relative representation of nuclei types - usually, however, resulting in the underrepresentation of vegetative nuclei (Parker et al. 2025). We will add text addressing this point to the manuscript.

      It is also true that differences in expressed genes between vegetative and sperm nuclei, which have very different transcriptomic profiles, will affect the distribution of informative reads for crossover analysis in scRNA data, and therefore may also have an impact on the recovered recombination landscapes (despite that the underlying landscapes are biologically identical). We will address this in the manuscript by adding recombination landscape plots and reproducibility scatterplots (as described in point 2.3) comparing sperm and vegetative nuclei from scRNA-seq to the manuscript.

      2.7. Robustness of the pipeline and parameter choices

      Reviewer 3 raised the concern that quantitative conclusions depend on a single pipeline with fixed parameter choices. We will address this by adding a parameter-sensitivity analysis for the main computational steps. Specifically, we will test the robustness of crossover calling on simulated data to changes in bin size and rHMM parameters, showing how these affect sensitivity to noise and agreement of predictions with ground truth data.

      2.8. Natural variation analysis: genotype-specific coverage and terminal crossover enrichment

      Reviewers 1, 2 and 3 raised concerns about whether natural variation in crossover rate and terminality could be influenced by genotype-specific coverage, marker density, pooling imbalance, or dropout. We will add a more detailed description of how pollen from different F₁ hybrids was pooled and how genotype assignment was performed. We will report genotype-level recovery statistics, including the six hybrids excluded from downstream analysis, and discuss how imbalances may arise, e.g. through biological variation in pollen count and fertility, biases in nuclei isolation or sequencing, and biases in genotyping and informative fragments.

      Reviewer 1 specifically asked whether the lower terminal crossover index observed in Cvi-0 crosses compared with Col-0 crosses could reflect systematic differences in informative-fragment distributions rather than true biological differences in crossover localisation. We will address this by using the genotype-specific informative-fragment distributions observed in the diversity-panel scRNA-seq dataset to simulate crossover datasets with known ground truth. This will allow us to test whether differences in marker variant or expressed-gene distributions causing variation in informative-fragment distribution could systematically bias terminal crossover detection in Cvi-0 crosses relative to Col-0 crosses.

      If feasible within the revision timeframe, we will also perform an orthogonal validation experiment for a selected comparison showing a clear difference in crossover terminality, such as Col-0 × Sah-0 and Cvi-0 × Sah-0. This would use progeny sequencing of backcross populations to estimate recombination landscapes independently of single-cell scRNA-seq, providing a direct test of whether the inferred terminality difference is supported by conventional recombination mapping. If this experiment cannot be completed within the revision timeframe, we will clearly state this limitation and base the revised interpretation on the simulation analyses described above.

      2.9. Broader applicability and practical guidance for users

      Reviewer 1 requested more discussion of applicability beyond Arabidopsis and to outcrossing or polyploid species. We will expand the Discussion to address the requirements and limitations of applying coelsch in other systems.

      2.10. Minor figure, reference, and presentation revisions

      We will address the remaining minor comments, including adding missing axis labels and checking duplicated references.

      3. Description of the revisions that have already been incorporated in the transferred manuscript

      No revisions have yet been incorporated in the transferred manuscript.

      4. Description of analyses that authors prefer not to carry out

      4.1. Full new benchmark across all modalities from the same nuclei preparation.

      As acknowledged in section 2.1, we agree with Reviewer 3 that a fully controlled benchmark in which the same isolated nuclei preparation is split across all tested platforms would be the ideal experimental design for separating intrinsic modality- or platform-specific effects from sample-handling and batch effects. However, this is not feasible for all technologies within the scope of this revision, because isolated nuclei degrade quickly, the single-cell sequencing methods are time- and labour-intensive, and the relevant platforms are not all available to us in the same location.

      We will therefore not perform a complete new cross-platform benchmark across all modalities. Instead, we will address this issue in the parts of the experiment where a matched design is feasible: we will generate two additional matched technical replicates each for 10x scRNA-seq and 10x scATAC-seq from nuclei isolated in the same sorting run. We will also revise the manuscript to more clearly acknowledge the limitations imposed by the lack of a fully matched cross-platform design and to ensure that our conclusions are interpreted in that context.

      4.2. Profiling the natural variation panel with a second modality

      Reviewer 1 suggested profiling at least a subset of the diversity panel with an additional single-cell modality. We agree that this would be useful, but we do not currently plan to generate a second-modality dataset for the natural variation panel. We would like to point out that this dataset introduces 34 genetic maps in a single sequencing experiment, which is not easily repeated.

      The natural variation experiment was designed as a high-throughput survey across many F₁ hybrids, and repeating even a subset with scWGA or scATAC would require substantial additional sample preparation and sequencing. Instead, we will strengthen the justification for the use of 10x scRNA-seq by adding genotype-level coverage summaries and simulations to show which conclusions are well supported at the observed data density.

      4.3. Orthogonal progeny sequencing from the exact same F₁ plants

      Reviewer 3 suggested that progeny sequencing from the same F₁ plants used for single-cell assays would provide a direct ground truth. This experiment would require additional crosses, progeny generation, and matched single-cell and progeny sequencing, which would not be justified by the insights that this effort delivers: While progeny sequencing can provide an independent validation dataset, we do not agree that it would constitute a substantially better ground truth than the simulations used here. Simulations provide a known ground truth for every individual barcode, whereas progeny sequencing cannot, for the obvious reason that pollen grains are destroyed during single-cell sequencing and therefore cannot be used to generate offspring. In addition, progeny-derived recombination landscapes are not a perfect ground truth at the population level, since segregation distortion and post-meiotic selection can alter the observed distribution of recombination events relative to those present in the original pollen population.

      4.4. Formal benchmarking of ____coelsch____ as a structural-variant detection method

      Reviewer 2 asked whether large structural variants were identified in other accessions besides Zin-9, and what sensitivity and specificity can be expected from recombination coldspot-based structural-variant detection. We agree that this is an interesting question, given that the Zin-9 inversion was identified through its strong effect on recombination. However, we do not plan to develop or benchmark coelsch as a comprehensive structural-variant detection method as part of this revision.

      The Zin-9 event was identified by visual inspection of the recombination maps, where it appeared as an unusually large and conspicuous recombination coldspot. We did not develop a systematic structural-variant calling procedure, as we do not view recombination suppression alone as a sufficiently specific signal for structural-variant detection. Coldspots can arise for many reasons, including centromere proximity or local recombination modifiers. Therefore, although large rearrangements such as inversions or translocations may sometimes be detectable through their effects on recombination, coelsch should not be considered as a general-purpose structural-variant caller.

      In the revised manuscript, we will clarify this limitation and avoid implying that recombination coldspot analysis provides comprehensive structural-variant discovery. We will report that we did not observe other genotype-specific coldspots of comparable scale to the Zin-9 event among the other analysed accessions, although smaller coldspots such as one corresponding to the previously reported 2.2Mb inversion on Chromosome 1 of N13 were identifiable. We will not provide formal estimates of sensitivity and specificity for structural-variant detection, as this would require independent benchmark datasets or dedicated simulations that are beyond the scope of the present study.

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      Referee #3

      Evidence, reproducibility and clarity

      In this study, Parker et al. benchmark three single-cell sequencing modalities (scRNA-seq, scATAC-seq, and scWGA) in Arabidopsis gametes and deliver an open-source, end-to-end framework for data processing that enables high-throughput crossover mapping across hybrids. By systematically comparing these modalities, the work quantifies trade-offs in throughput, genomic coverage, and crossover detection sensitivity, offering timely guidance for experimental design in plant systems where single-cell genomics is still emerging and platform benchmarks are very limited. The pipelines are further supported by the discovery of a previously unrecognized ~10 Mb pericentric inversion in the Zin-9 accession. The experimental design is technically interesting, and the results are important for guiding plant single-cell research. The work has the potential to attract a broad readership. However, several aspects of the experimental design, validation strategy, and parameter robustness require further clarification and, where possible, additional analyses.

      Major comments

      1. The modality comparison is based on one scRNA-seq library and two libraries each for scATAC-seq and scWGA. While the limited replication is acknowledged in the Discussion, the authors also report unexpected and run-specific observations (e.g. unusually high doublet rates in the 10x scRNA-seq library; "unexpected" doublet behavior in scWGA), making it difficult to separate platform-intrinsic properties from sample preparation and run-to-run variation. Differences in nuclei isolation buffers, purification strategies (e.g. density gradients, FACS, centrifugation), and potentially loaded nuclei numbers between platforms (which have not been specified in detail) further confound modality-level conclusions. For example, total usable barcodes vary drastically between the samples (e.g. 15k/20k/33k for 10x scRNA-seq, only 3.8k for BD even though it has the same capture capacity as 10X). Do these differences reflect different capture efficiencies between the platforms, or variation in nuclei quality/quantity, or modality-specific limitations in QC thresholds? It would strengthen the study to provide, for each library, the number of nuclei prior to loading and before/after QC, and to add independent biological replicates under modality-appropriate, optimized handling, ideally including a design where the same nuclei pool is split across all three modalities.
      2. All quantitative inferences rely on one custom analysis pipeline with multiple interdependent steps and fixed parameter choices (e.g. bin size, HMM transition structure, smoothing settings, background subtraction, doublet filters). The lack of benchmarking against independent crossover callers, or of systematic parameter sweeps, leaves it unclear how robust key patterns are to alternative analytical choices. It would substantially increase confidence to assess sensitivity of the main conclusions to key parameters (for example varying bin size, rigid chain length/transition penalties, enabling/disabling background subtraction and doublet filtering), and/or compare coelsch to other HMM-based crossover callers such as sgcocaller/comapr on at least a subset of the data.
      3. Accuracy is evaluated by comparisons to prior backcross/progeny datasets generated in different conditions, and by simulations calibrated to those references. While this is informative, systematic biases shared between the new pipeline and the reference datasets could remain undetected. Internal, orthogonal validation (e.g. progeny sequencing performed on the same F₁ plants used for single-cell assays) would provide a more direct ground truth and avoid potential circularity in bias assessment.
      4. The benchmark does not evaluate the impact of sequencing depth across modalities, which could influence the variation in per-barcode fragment counts and genomic bin coverage between scRNA-seq, scATAC-seq, and scWGA. Down-sampling aligned reads or informative fragments to fixed per-barcode targets (e.g. 250, 500, 1000 informative fragments) within each modality would clarify how much of the observed performance gap is attributable to depth rather than modality-specific biology or library structure. Constructing depth-matched subsets between scWGA and scATAC/scRNA datasets would help to test whether the breadth vs. depth trade-offs persist when sequencing resources are equalized.
      5. In the pooled 34-hybrid single-nucleus RNA-seq dataset, it would be very informative to present detection sensitivity and resolution across genotypes (e.g. captured nuclei, distributions of informative fragments, covered bins, and expected localization error by genotype). Genotypes will differ in expression patterns, which will alter the number and distribution of informative fragments per nucleus, and thus ultimately influence inferred recombination rates and crossover terminality. Furthermore, the background subtraction filter relies on genotype-level background models. Given that all genotypes were pooled prior to nuclei isolation, can the authors show that estimated ambient/background profiles are comparable across genotypes?

      Minor comments

      1. The manuscript currently attributes more uneven coverage in scRNA-seq primarily to expression-biased sampling of heterozygous sites. Would the choice of using nuclei, rather than whole cells which would also allow the capture of cytosolic RNA, for the scRNA-seq be an additional reason for lower total number and genomic dispersion of informative fragments?
      2. The sentence "This allows informed experimental and analytical choices ..." could be accompanied with a compact infographic or table (for example as an extension of Fig. 1B) summarizing key trade-offs and recommended use-cases for each modality (throughput, per-cell resolution, coverage breadth, susceptibility to doublets/ambient RNA, recommended applications).
      3. Related to the point above, the choice to profile the F₁ hybrids using the 10x scRNA-seq modality is understandable from a throughput perspective, but the results presented in Fig. 1 and Table 1 suggest scWGA offers higher crossover accuracy, scATAC superior genomic breadth, compared to 10x scRNA-seq which in addition also showed a high doublet rate. Expanding the rationale for prioritizing scRNA-seq here (e.g. cost, compatibility with downstream expression analyses, or technical constraints for scWGA/scATAC at this scale) would clarify the experimental logic for the reader.

      Referee cross-commenting

      I strongly agree with the points raised by Reviewers #1 and #2. In particular, including additional replicates (ideally derived from the same pollen pool, processed identically and run across all modalities) would provide robustness to the benchmark. However, repeating these experiments, re-running the benchmark, and updating the interpretation would require substantial additional time, likely exceeding the suggested 1-3 month revision timeframe proposed by the other reviewers. Additional clarification of the analysis and representation of requested details (e.g. the recombination landscape plots (Reviewer #1), clarification of balanced pollen representation from each F₁ during pooling (Reviewers #2 and #3), and evaluation of how varying filtering strategies (e.g. doublet detection thresholds) affect the observed recombination patterns (Reviewers #2 and #3)) would also improve evaluation and transparency of the study. From a technical perspective major point 3 raised by Reviewer #2 (including information on the intrinsic biological characteristics of the material in the modality performance analysis) would provide substantially important context for users and improve interpretation of the benchmark.

      Significance

      Previous studies have successfully applied single-cell whole-genome amplification and linked-read sequencing to individual gametes to measure recombination rates and distributions, demonstrating the feasibility of this high-throughput alternative to progeny sequencing. This study extends that concept by delivering open-source pipelines for multiple single-cell modalities and by directly comparing the performance of scRNA-seq, scATAC-seq, and scWGA for mapping meiotic recombination in Arabidopsis gametes, offering both a practical resource and a performance evaluation for plant single-cell genomics.

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      Referee #2

      Evidence, reproducibility and clarity

      This manuscript presents coelsch, a cross-platform computational framework for single-cell gamete recombination analysis. It systematically benchmarks the performance of four mainstream single-cell sequencing modalities in meiotic crossover detection, successfully applies the method to a natural variation panel of Arabidopsis thaliana, and identifies the largest natural inversion reported in this species to date. This work demonstrates strong innovation, a complete technical pipeline, and significant biological implications. I would like to recommend revision. My concerns are listed below for the authors' consideration and revision.

      Major concerns

      1. Biological Replicates and Batch Effect Control The number of biological replicates per sequencing modality is limited (2 libraries for 10x scATAC and Takara scWGA, 1 library each for 10x scRNA and BD scRNA), and experiments for different modalities were performed in separate batches. Have the authors evaluated the impact of inter-batch technical variation on recombination rate estimates? In particular, for platforms with drastically different doublet rates (e.g., 49.7% for 10x scRNA vs. 26.3% for BD scRNA), how did the authors distinguish or avoid inherent platform differences from batch effects?

      The natural variation analysis used a pooled library strategy for 40 F₁ hybrids without biological replicates. How did the authors ensure balanced pollen representation of each F₁ during pooling? For the 6 F₁ hybrids excluded due to insufficient data, was this due to initial pooling bias or sequencing capture preference? Could this introduce systematic bias into the natural variation analysis results? 2. Consistency of Pollen Nuclei Isolation Methods Different nuclei isolation protocols were used for each sequencing modality: Percoll density gradient centrifugation for 10x scATAC, no Percoll purification for Takara scWGA, and flow cytometry sorting combined with 10x/BD scRNA. Have the authors assessed how these different isolation methods affect nuclei integrity, viability, and capture bias for pollen nuclei? For example, could flow cytometry sorting selectively exclude nuclei of specific sizes or densities, thereby compromising the representativeness of recombination rate estimates? 3.Systematic impact of the inherent structure of pollen on different sequencing modalities Mature Arabidopsis thaliana pollen has a canonical trinucleate structure, consisting of one transcriptionally hyperactive vegetative nucleus and two sperm nuclei with highly condensed chromatin and almost complete transcriptional silencing. While all three nuclei share identical genome sequences, they exhibit fundamental differences in chromatin state and molecular features, which will have profoundly distinct effects on different sequencing modalities-an issue not addressed or controlled for in this study.

      Differential technical capture bias: scRNA-seq and scATAC-seq rely on mRNA and accessible chromatin signals, respectively, and thus theoretically can only capture valid data from vegetative nuclei; sperm nuclei will be filtered out during quality control due to insufficient signal. In contrast, scWGA is based on whole-genome DNA amplification, independent of transcriptional activity or chromatin state, and can capture both vegetative and sperm nuclei. Have the authors validated the actual nuclear type composition in datasets from each modality through experiments (e.g., nuclear size sorting, DAPI staining quantification, immunofluorescence labeling)? Could this systematic difference in nuclear type composition compromise the fairness of performance comparisons between modalities? The uneven coverage of scRNA/scATAC is primarily determined by gene expression levels and chromatin accessibility (e.g., high coverage at highly expressed genes, extremely low coverage at heterochromatic regions such as centromeres), whereas coverage bias in scWGA mainly stems from technical preferences of whole-genome amplification. When comparing the resolution and accuracy of recombination detection across modalities, did the authors clarify the contributions of "intrinsic biological characteristics of nuclear types" from "technical characteristics of the sequencing technologies themselves"? 4. Accuracy and Validation of Doublet Detection Method This study reports exceptionally high doublet rates (~49% for 10x scATAC, ~70% for Takara scWGA), and there is a significant discrepancy with the results from Takara's official CellSelect software (80% of wells labeled "Good" by CellSelect were classified as doublets by coelsch). Have the authors validated the false positive and false negative rates of coelsch's doublet detection method through independent experiments (e.g., mixing pollen of known genotypes, manual microscopic validation of selected wells)? Such a high doublet filtering rate leads to a drastic reduction in the number of effective cells (e.g., only 628 singlets remained from a total of 2081 barcodes in the two Takara scWGA libraries). Have the authors assessed the representativeness of the remaining cells after filtering? In particular, for low-coverage scRNA data, could filtering result in the loss of cells with specific recombination patterns? 5. Depth and Breadth of Natural Variation Analysis This study finds significant differences in recombination rate and terminal crossover enrichment among different natural accessions, with Cvi-0 hybrids exhibiting higher overall recombination rates but lower terminal recombination rates. Have the authors further explored the genetic basis underlying these differences? Besides the 10 Mb inversion in Zin-9, did the authors identify similar large structural variations in other natural accessions? What is the sensitivity and specificity of the recombination coldspot-based method for detecting structural variation? For example, what is the minimum size of inversions or translocations that can be reliably detected?

      Minor concerns

      • The mutants used in this study (zyp1, figl1, recq4ab, etc.) were generated by crossing mutant lines in the Col-0 background with corresponding mutant lines in the Ler background, resulting in heterozygous F₁ backgrounds. For example, the zyp1 mutant used Col-0 background zyp1-1 and Ler background zyp1-6. Could this heterozygous mutant background affect the accurate measurement of meiotic processes and recombination rates? Have the authors considered validation using F₁ populations from homozygous mutant lines?
      • The Takara scWGA dataset for wild-type Col-0 × Ler contains only 224 high-quality nuclei, while mutant sample sizes range from tens to hundreds. Is this sample size sufficient for fine-scale analysis of recombination rate distributions, especially for the detection of low-frequency recombination events? There are also a few minor issues regarding the references-some appear to be duplicates, such as references 11 and 31, which seem to be the same in both the published version and the bioRxiv preprint. Please double check. Additionally, have the authors considered the cost implications of these single-cell-based technologies, as well as their previously published linked-read sequencing approach?

      Overall, this manuscript represents an important technical breakthrough in the field of meiotic recombination research, providing a unified computational framework for large-scale, cross-platform single-cell gamete recombination analysis. The above questions mainly focus on the rigor of experimental design (especially the omission of the unique biological issue of pollen trinucleate structure), the depth of computational method validation, and the expansion of biological findings, and do not affect the core conclusions of the manuscript. I suggest that the authors address these questions and provide clear responses in the revised manuscript. If these issues are properly resolved, this work will provide a powerful tool for investigating the genetic and molecular mechanisms of plant meiotic recombination.

      Referee cross-commenting

      I agree with Reviewers 1 and 3. Addressing most of the points we raised would bring this manuscript to publication standard.

      Significance

      This study develops a unified computational framework for meiotic crossover (CO) mapping using single‑cell sequencing of Arabidopsis pollen, benchmarks four single‑cell modalities, and identifies natural recombination variation and a large novel pericentric inversion. Overall, the work is technically sound, biologically meaningful, and fills a key gap in scalable gamete‑based recombination profiling.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      Parker et al. present coelsch and coelsch_mapping_pipeline, two open-source tools for platform-agnostic haplotyping and crossover detection from single-cell sequencing data, benchmarked across four modalities: 10x scATAC, 10x scRNA, BD scRNA, and Takara scWGA. The study applies these tools to Arabidopsis thaliana F₁ pollen to recover known recombination frequencies, characterise the effects of coverage sparsity via simulation, and profile natural variation in crossover rate and distribution across 34 F₁ hybrids from 22 diverse accessions. As a by-product of the recombination maps, the authors identify a previously unrecognised ~10 Mb pericentric inversion in the accession Zin-9 - the largest natural inversion described to date in A. thaliana.

      This is an interesting and important study and is suitable in scope and rigour for publication in a Review Commons affiliate journal. By combining computational and experimental framework, the authors address a genuine methodological gap: while single-cell gamete sequencing is a powerful approach for recombination mapping, the consequences of choosing among available sequencing modalities have not been systematically evaluated. The tools are open-source, data are deposited, and the biological conclusions are well-grounded. Importantly, the limitations of the tools are also mentioned, which is appreciated. Therefore, this manuscript presents a genuinely useful methodological framework that fills a real gap in the recombination biology toolkit. The biological discovery (Zin-9 inversion) adds independent value. However, several analytical choices require better justification, some results sections are under interpreted, and a number of presentation issues should be addressed before acceptance.

      Major comments:

      1. Mismatch between best-performing modality and diversity panel application

      The most critical concern is a logical inconsistency in the experimental design. The authors demonstrate convincingly that Takara scWGA achieves higher per-cell resolution and more accurate crossover detection than the droplet-based RNA methods. Yet the diversity panel - the study's key biological application - is analysed exclusively using 10x scRNA. No comparison with other modalities is provided for the panel, and no external recombination data for these accessions are included for validation. The authors should either: (i) include at least a subset of accessions profiled by an additional modality; or (ii) provide a more thorough quantitative justification for why 10x scRNA throughput outweighs the loss of resolution in this specific context, showing that cross-accession comparisons remain interpretable at scRNA coverage levels. 2. Could variation in crossover terminality result from analysis artefacts?

      The authors demonstrate consistently higher rates of terminal crossovers in Col hybrids than in Cvi hybrids, 'implying genetic background modulation of crossover localisation'. However, their simulation analysis also demonstrates that telomere proximal crossovers are disproportionally missed in 10x RNA data. Therefore, could the Col vs. Cvi terminality differences result from a greater/lower occurrence of false negatives in different genotypes using this approach, rather than bona fide differences in CO number (caused by e.g. differences in telomere proximal marker density in Col vs. Cvi)? If so, this should be explicitly mentioned.<br /> 3. Doublet rates in Takara scWGA are unexplained

      The Takara iCELL8 platform implements microscopy-based automated well selection to prevent doublets, yet coelsch identifies a ~70% doublet rate in these libraries. This is mentioned briefly but not adequately explained in the main text. The authors should provide a more thorough explanation for why the CellSelect imaging software fails to exclude pollen nuclei doublets (likely due to small nuclear size), and they should discuss what this implies for the utility of this platform for future experiments. This is important practical information for readers considering the Takara workflow. 4. Recombination landscape figures are incomplete

      Figure 2C shows recombination landscapes only for mutant genotypes profiled by Takara scWGA. Equivalent per-chromosome landscape plots should be provided for all modalities tested on wild-type Col-0 × Ler material. This is essential to visually communicate the coverage-driven differences in landscape resolution that the authors describe, and to verify that 10x scATAC and scRNA recover similar gross distributions despite lower per-cell depth. 5. Extreme crossovers number in 10x scATAC are not discussed

      The violin plots in Figure 2A show that 10x scATAC produces a wider upper tail of estimated crossover numbers than other modalities, with some barcodes exceeding 20 crossovers per nucleus - values far above the biological expectation for Arabidopsis. This is not acknowledged or explained. Is this an artefact of the high doublet contamination in this dataset (even after filtering), or a property of the HMM applied to fragmented ATAC data? An explicit discussion or supplementary analysis is required. 6. Resolution of crossover detection is undereported

      Figure 3C shows boxplots of crossover localisation error across modalities, but this analysis is not discussed quantitatively in the main text. Readers need to understand the practical resolution (in kb) achievable by each modality in terms of crossover interval size. This is particularly important because the paper claims applicability for genetic mapping experiments, where localisation precision directly determines utility. 7. Telomeric false-negative rate in scWGA is not reported

      The simulation analysis of false negatives near telomeres (Figure 3B) is presented only for 10x RNA data. Given that the authors use Takara scWGA for mutant genotyping and claim higher sensitivity, it is critical to also show the telomeric false-negative profile for scWGA. The current text implies that scWGA should avoid this problem, but this is not demonstrated. 8. Comparison between libraries from the same modality is absent

      Two independent 10x scATAC and two Takara scWGA libraries were generated, but no within-modality reproducibility analysis of crossover rates or landscapes is presented. Crossover rates and landscape correlations between technical replicates should be shown to establish that the observed modality-level differences are not driven by library-preparation variability. 9. Applicability to non-Arabidopsis and heterozygous species

      The Discussion notes that the approach relies on isogenic founder crosses and high-quality parental assemblies but does not explore the practical barriers to applying coelsch in outcrossing or polyploid species. Given the broad framing of the title ('platform-agnostic'), the authors should discuss what adaptations would be needed for crop species or other organisms where chromosome-scale haplotype-resolved assemblies are not available.

      Minor comments:

      1. Figure 5B - Please add axis labels in Mb.
      2. Figure 2A - library replicates: The two 10x scATAC libraries are not differentiated in Figure 2A. Showing them separately (or indicating per-library medians) would improve transparency.
      3. Droplet vs. plate combination: The Discussion does not address whether complementary modalities could be combined (e.g., using droplet-based data for landscape estimation and scWGA for localisation refinement within the same experiment). A brief discussion of this possibility would strengthen the practical utility of the framework.

      Referee cross-commenting

      All points raised by reviewers 2 & 3 seem reasonable and would substantially improve the quality of the manuscript

      Significance

      General assessment: The paper from Parker et al., provides the first systematic evaluation of single-cell sequencing modalities for recombination mapping in Arabidopsis and presents new bioinformatic tools for analysing recombination in single-cell data. The novel utility of the approach is demonstrated for assessing recombination rate across a wide variety of Arabidopsis hybrids. Different platforms provide different benefits/limitations and these are well presented. However, the manuscript would benefit from a more thorough presentation of all the different analyses that were performed.

      Advance: Most recombination mapping studies in Arabidopsis utilise progeny sequencing. Here, the authors present an alternative approach, using single-cell gamete sequencing which will more easily facilitate recombination mapping in large populations, which will be particularly useful for future studies investigating the influence of natural variation on recombination rate and location. The advance is mostly technical, but the study also generates novel biological observations about chromosome structural rearrangements in Arabidopsis.

      Audience: The study is likely to be of main interest to individuals studying recombination in plants (particularly using bioinformatic approaches and analysing the influence of natural variation). However, researchers with an interest in single-cell sequencing and broader genomics will also be an audience for this paper.

      Describe your expertise:

      I am a researcher in plant meiotic recombination and I am well placed to assess the general importance and impact of the study within the context of the field. However, I would not consider myself a specific expert in bioinformatics.

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      Reply to the reviewers

      RESPONSE TO REVIEWERS

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      Summary:

      This is an interesting and ambitious study by Tabilo-Agurto and co-workers. It combines deep learning structure prediction (AlphaFold2), targeted molecular dynamics simulations, and in vivo functional assays to probe structural, functional, and evolutionary aspects of the metamorphic protein RfaH. More broadly, the work addresses an important question: whether intermediate structural states may exist along evolutionary trajectories of metamorphic proteins. A particular strength of the study is the integration of computational and experimental approaches. The manuscript is generally well written and clearly organized.

      Major comments:

      A key aspect of the study is the classification of predicted structures into three classes based on the conformation of the C-terminal domain (CTD): the autoinhibited alpha-helical fold, a beta-barrel fold, and a mixed alpha/beta fold. These classes are further described as corresponding to metamorphic (alpha fold), mixed alpha/beta, and monomorphic (beta fold) proteins.

      While I can see how this organizational scheme is helpful in some respects, it may also overstate what can be concluded from the data. As the authors are well aware, AlphaFold2 tends to predict a single conformation even for genuine metamorphic proteins, and therefore does not, on its own, distinguish between monomorphic and fold-switching proteins. I note in particular that the functional data indicates that the "monomorphic" variants studied in the in vivo assays behave similarly to the RfaH E48A mutant. However, E48A is known to remain metamorphic, populating both alpha and beta folds with roughly equal probability. This suggests that the sequences in this class may retain some degree of fold-switching capability, even if the underlying regulatory mechanism differs from that of wild-type RfaH. In other words, the presented data does not fully support these sequences as monomorphic. I am not suggesting that the authors must revise their classification scheme. However, it may strengthen the manuscript if the authors explicitly acknowledge this alternative interpretation and moderate the corresponding claims.

      We appreciate the comment from the reviewer, which can be seen from two different perspectives.

      On the one hand, it might be reasonable to think that the ‘monomorphic’ RfaH orthologs have lower transcription elongation activity than E. coli RfaH. Other highly divergent orthologs of E. coli RfaH (Salmonella enterica serovar Typhimurium, Klebsiella pneumoniae, Yersinia enterocolitica and Vibrio cholerae) have similar in vitro recruitment and pausing at the C45 nucleotide from the ops element, as well as restoring the RfaH-dependent hemolytic activity of E. coli in a strain that lacks chromosomal RfaH to levels similar to the wild-type strain (doi: 10.1128/jb.186.9.2829-2840.2004). However, V. cholerae RfaH (43% sequence identity to E. coli RfaH) exhibits diminished antitermination effects in in vitro transcription assays, better resembling the antitermination levels in the absence of RfaH (doi: 10.1128/jb.186.9.2829-2840.2004), despite this protein also being predicted in the alpha-folded state when using AF2 (10.1016/j.csbj.2022.10.024). A particular observation from the RfaH complementation work is that increasing the concentration of V. cholerae in in vitro transcription assays lessens the transcription elongation effects observed when using concentrations similar to E. coli RfaH. These transcription elongation defects can be extrapolated to potentially similar issues with transcription in vivo and, therefore, luciferase translation in our in vivo translation assays for our ‘monomorphic’ proteins.

      On the other hand, it is possible that these so-called ‘monomorphic proteins’ still populate the alpha-folded state, but that their predominant fold in solution is the one corresponding to the active beta-fold. This can be biophysically tested using circular dichroism to distinguish their alpha or beta propensity, as proposed in a remarkable work from Porter et al (10.1038/s41467-022-31532-9).

      In both cases, quantification of the protein titers obtained after attempts of protein purification of the ‘monomorphic’ RfaH orthologs would be required. In this way, we can ascertain whether the differences in activity are due to differences in expression levels and determine if sufficient amounts of stable and well-folded protein can be obtained for these RfaH orthologs, followed by measuring their circular dichroism spectra to ascertain their secondary structure propensity.

      Our current attempts are to recombinantly express these proteins for determining their protein titers and solubility in the supernatant, which will enable us to indirectly ascertain their expression levels, and test those solubly expressed proteins biophysically using circular dichroism experiments. If the circular dichroism experiments prove to be unsuccessful due to problems with the solubility of the purified proteins, we strongly believe that the aforementioned discussion should be included in the manuscript to take into account the limitations of the methods utilized in our work.

      Therefore, we will add the following paragraph in the discussion, while we work on ascertaining the feasibility of the circular dichroism assays:

      “It is worth noting that, in the absence of RBS (Figure 5C-F), the putative monomorphic RfaH orthologs have similar or lower in vivo activity than the E. coli RfaH E48A mutant; a similar mutant (E48S) exhibits a 1:1 equilibrium between the autoinhibited and active states (Burmann et al, 2012). This observation can be partly explained by two factors. First, sequence divergence and expression levels may limit functional compatibility with the host machinery. Highly divergent V. cholerae RfaH ortholog, which shares only 43% sequence identity with E. coli RfaH but is predicted to fold into the autoinhibited state (Artsimovitch & Ramírez-Sarmiento, 2022), maintains both ops-dependent recruitment and hemolysin secretion in the ∆rfaH E. coli strain, yet exhibits transcription elongation defects in vitro, requiring a 5-fold higher concentration than E. coli RfaH to match increased elongation rates of E. coli RNAP (Carter et al, 2004). Low in vivo protein titers or structural mismatches between the monomorphic orthologs and E. coli RNAP may prevent higher luciferase expression relative to the E48A mutant. This limitation is supported by the fact that IPTG-induced overexpression rescues activity when an RBS is present (Figure 5B). Second, these proteins may be predominantly folded in the active state while still transiently populating the autoinhibited state. Confirming this conformational equilibrium would require overexpression and purification of these proteins followed by biophysical assays, such as circular dichroism (Porter et al, 2022).”

      Reviewer #1 (Significance (Required)):

      An intriguing, but speculative, aspect of the study is the finding that some sequences are predicted to adopt a CTD with mixed alpha/beta secondary structure, and that such structures also appear in targeted molecular dynamics simulations. If this idea holds up, it could represent an intermediate along the evolutionary pathway between the alpha-helical and beta-barrel folds of RfaH. Although the evidence is only computational, it is a compelling idea and it would benefit from further investigation.

      It is indeed very compelling, and this is something that we should immediately address in a revised version of our manuscript. We somehow missed an article published in 2025, regarding the study of the structural interconversion of the isolated CTD using NMR, finding at least three intermediate states along the fold-switching pathway of RfaH (doi: 10.1073/pnas.2506441122). One of such intermediate states observed, which is also one of the highest populated ones (~23%), corresponds to an ensemble of largely unfolded structures that include the formation of transient alpha-helix a5 (corresponding to helix a2 in our article) and beta-hairpin (b1/b2) secondary structure elements, which fold to form a compact ensemble of structures in which the beta-hairpin lies on top of the alpha-helix. This is fully consistent with our predictions of a mixed alpha/beta state in full-length.

      We will add this external experimental validation of the mixed alpha/beta secondary structure of the CTD of RfaH in the discussion of our final manuscript:

      “Interestingly, a recent nuclear magnetic resonance spectroscopy study of the E. coli RfaH CTD, aimed to uncover transient states potentially en route of the αCTD interconversion (Cai et al, 2025), described an intermediate state (populated in ~23% of the captured ensembles) in which a β-hairpin formed by β-strands β1-β2 lies on top of a transient α-helix α5 that corresponds to helix α2 in our article. This finding is fully consistent with the mixed α/β CTD structures found both in our TMD simulations and our AF2 predictions of divergent RfaH orthologs.”

      In summary, the work is a valuable contribution to the field of protein fold switching. The combination of computational tools with experimental validation makes it interesting and the results should be of broad interest. The manuscript should be well positioned for publication in a high-impact journal.

      We are very thankful for the reviewer’s comments on our manuscript.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary:

      In their paper "Exploration of the structural and functional diversity in the metamorphic RfaH subfamily," Tabilo-Agurto et al. use AlphaFold2 to predict the structures of ~3,900 RfaH homologs, sort the predicted C-terminal domains into α-helical (autoinhibited), β-barrel (NusG-like), and mixed α/β topologies, and find that about 14% of homologs come out predominantly in the β-barrel state. They then take nine representative homologs and run them through a heterologous *E. coli* DH5α Δ*rfaH* reporter assay. The putative monomorphic candidates behave a lot like the constitutively active E48A variant - active across every ops context and even without an RBS - while the mixed α/β candidates barely show activity. Targeted MD simulations of *E. coli* RfaH, run through AF2Rank, also pulls out the mixed α/β state as its own distinct cluster, hinting that it sits somewhere along the fold-switching transition path.

      This is a genuinely interesting piece of work that pulls together structure prediction, in vivo activity, and genomic context to make a concrete case for extant monomorphic βRfaH proteins - a long-hypothesized but until now unseen intermediate in the proposed stepwise evolution of RfaH from NusG. The experimental design is thoughtful, especially the five-construct ops/RBS matrix, and comparing the monomorphic candidates against the E48A benchmark is a nice touch as a positive control. Overall, I think the paper deserves to be published, but a few things would need shoring up before acceptance.

      Major comments:

      1. The paper would be a lot stronger with at least one biophysical measurement (a CD spectrum, say) on a purified monomorphic candidate. I get that this might be outside the planned scope, but even a single CD trace showing β-rich content for an isolated full-length protein would move the claim from "putative" to "demonstrated."

      We agree with the comment from the reviewer, and as such we are currently attempting to recombinantly express these proteins for determining first their solubility after purification (which will largely determine our ability to characterize them by circular dichroism) and then follow up with circular dichroism experiments if the solubility and protein concentration of these ‘monomorphic’ homologs is sufficient to pursue these experiments. In case this is unfeasible, we will include the solubility analysis in our revised version of the article, as well as a discussion on this topic – and also on the topic of why the activity of the ‘monomorphic’ proteins resembles the E48A mutant of E. coli RfaH that co-exists between two folds – as indicated in our response to the major comment from reviewer #1.

      1. Only nine homologs were tested - three per category. The conclusions about monomorphic behavior generalizing across the whole βRfaH clade are basically resting on three proteins. Bringing in even one or two phylogenetically distant βRfaH candidates would help guard against the possibility that what they're seeing is just a genus-specific quirk. If new experiments aren't on the table, the limitation should at least be called out explicitly in the Discussion.

      We agree with the reviewer that drawing conclusions from a single clade of RfaH could raise concerns about bias, although we must note that the tested putative monomorphic candidates were selected before a phylogenetic tree was constructed. What we propose is to perform a phylogenetic analysis for the InterPro sequences and look at their genomic neighborhood as well, replicating what was done in the manuscript for the Genomic Cluster group. We hope this would provide more compelling evidence that the predictions, phylogeny and gene organization of these extant monomorphic RfaH is distinct from those metamorphic.

      1. The classification thresholds (α > 32.5% / β 30.0% / α

      Thanks to the reviewer for raising this concern. We will perform a sensitivity analysis by slightly nudging the cutoffs by ±5% as recommended by the reviewer and indeed we see minimal changes in the number of structures in each class. We have added a small paragraph indicating this sensitivity test:

      “To determine that these values were adequate for our analysis, we performed a sensitivity test by changing the thresholds by ±5% over the data for all structures predicted from all databases, showing that the predictions of RfaH orthologs with monomorphic CTD and mixed secondary structure in their CTD is robust, and only metamorphic RfaH orthologs were reduced with an increase in uncategorized structures (Supplementary Figure S13)”

      1. The Discussion notes that uncontrolled, ops-independent RfaH recruitment could be lethal, since RfaH outcompetes the much more abundant NusG. But if monomorphic RfaH proteins really are extant and stably maintained in these genomes, there has to be something keeping them from interfering with NusG's essential functions - maybe very low expression, restricted induction, or compensating differences in NusG affinity. The paper would benefit from tackling this directly, even speculatively.

      We agree with the reviewer in this point, and after careful consideration we believe that we did not emphasize this point appropriately in the manuscript. In fact, we included Figure 7 to state our perspective on how RfaH may have evolved but we did not emphasize how this perspective stems from a previous work that we thoroughly discussed in the introduction (doi: 10.1038/emboj.2008.268) and that explicitly states that low solubility of the dissociated NTD and CTD could be a factor imposing this restricted action in cis operons. We have included this in our revised version of the manuscript as follows:

      “Our findings are in line with the previous hypothesis regarding the emergence of RfaH within the universally conserved family of NusG transcription factors (Belogurov et al, 2009). Under that model, a gene duplication event produced an intermediate variant (NusG2 in Figure 7) that lost its Rho-binding capability and acquired a deletion in the NTD that reduced the protein's overall size and remodeled its hydrophobic profile. Crucially, this intermediate retained an exposed, hydrophobic RNAP-binding region, a feature shared by monomorphic RfaH and the ancestor of all RfaH orthologs (NusGSP in Figure 7). This increased hydrophobicity would have reduced solubility, restricting its regulatory activity to the site of synthesis, i.e. in cis. Indeed, when structural alignment is used to identify conserved NTD residues that bind to RNAP, orthologs contain more than 70% hydrophobic residues (Supplementary Figure S11) at those positions. This percentage is much closer to that of RfaH (80%) than NusG (57.14%). The protein only regains solubility and the ability to operate in trans when its CTD refolds into a helical conformation. Ultimately, our results strengthen this evolutionary model by demonstrating that several extant RfaH orthologs appear to resemble this insoluble, cis-acting ancestral state.”

      Minor comments:

      Table 1 should show percentages alongside the raw counts. 7/7 LPS-in-operon for monomorphic candidates is striking, but with n=10, the small denominator really deserves to be flagged.

      We agree with the reviewer in that the higher raw count of metamorphics may undersell the message the article conveys. We added the percentages next to raw counts in Table 1, regarding “Total” and “Next to operon” categories. We also modified the legend as follows:

      “A summary of genomic contexts of RfaH orthologs classified according to the AF2 predictions. The numbers indicate how many rfaH genes are next to an operon and whether the operon contains lipopolysaccharide biosynthesis genes, and the percentages next to them display the relation to the previous category, i.e, “Next to operon”/”Total” and “LPS in operon”/”Next to operon”.”

      In Figure 3, the sequence logo on top is informative - consider adding the number of sequences per dataset to the axis labels so readers can interpret the boxplot widths.

      We believe that this would be rather confusing for the readers, because it is counting all 5 structures predicted by AlphaFold2 for each sequence in each dataset that fit each classification, and thus the same sequence can lead to structures that are monomorphic, metamorphic of have mixed secondary structure in their CTD. Thus, the number of sequences per box plot will be higher than the number of sequences per dataset. For example, one sequence from InterPro can be present in more than one box plot, because different AlphaFold2 models can lead to the prediction of different states from the same sequence. We believe it is less confusing if it is presented as it is.

      There's some redundancy between the Results (pp. 14-17) and the Discussion that could probably be trimmed, particularly the recap of the ops/RBS construct logic.

      Thanks for the recommendation. We reduced this redundancy in the new version of the manuscript, mainly on page 16:

      “The orthologs classified as monomorphic, and thus expected to be constitutively active, exhibited activity across all tested ops contexts, including in the absence of RBS (Figure 5B-F). Notably, their activity levels were comparable to the ops-independent E. coli RfaH E48A mutant, in which the key salt bridge at the NTD:CTD interface is disrupted. All monomorphic orthologs were found to lack a few key residues that make contacts to ops DNA in RfaH, as well as the conserved residues in loop 2 that mediate contacts with Rho in NusG (Supplementary Figure 11). This mosaic architecture enables these orthologs to promote the expression of the long lux operon even when the RBS is absent. Our study provides the first indirect evidence of putative, constitutively active RfaH proteins, which are predicted to have monomorphic NusG-like fold, in other bacteria.”

      Reviewer #2 (Significance (Required)):

      If the central claim holds up, this is a meaningful contribution to the metamorphic-protein and bacterial-transcription literatures: it identifies what appear to be extant evolutionary "way-stations" in the NusG→RfaH transition, and it does so using a tractable computational pipeline that could be applied to other suspected fold-switch families. The work is timely given the ongoing discussion about how AF2 and its descendants handle conformational heterogeneity. With the strengthening suggested above - particularly any direct biophysical confirmation of a monomorphic candidate - I would expect this to be a well-cited paper in its niche.

      We are very thankful for the reviewer’s comments on our manuscript.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      Summary:

      The manuscript by Tabilo-Agurto et al. uses in silico and experimental methods to elucidate the diversity of the metamorphic RfaH protein family. Of particular note is the sophisticated usage of AlphaFold2 to reconstruct the evolutionary tree of RfaH as well as the in vivo luminescence assays to substantiate the different structural states of the RfaH-CTD. Overall this is a well-written manuscript providing deeper insight into the structural and functional diversity of RfaH proteins, potentially relevant for other metamorphic proteins as well.

      Minor comments:

      1. 3rd paragraph of the introduction: The sentence starting with "To date, ...and nuclear magnetic resonance of these ancestors.." seems incomplete as this reviewer believes the author´s wanted to say "..and structural characterization by nuclear magnetic resonance spectroscopy of these ancestors..."

      Thanks for the attention to these details, we will amend this paragraph appropriately.

      1. 4th paragraph of the introduction: "..., that binds Rho or the ribosome (Mooney et al. 2009b). Whereas this citation is correct for NusG-Rho interactions it does not indicate ribosome binding. The direct interaction of NusG with the ribosome was shown in Burmann et al. Science 2010 and this reference should be added here.

      Thanks for the recommendation, we will include both citations in this section of the manuscript.

      1. More a curiosity question, did the author also test for a subset of the RfaH variants the AlphaFold3 predictions and obtain similar or different results?

      Thanks for the comment. The reason we did not use AlphaFold3 predictions to check on the variability of the results is that there is much more known about the use of AlphaFold2 – and its limitations – regarding their use in the study of metamorphic proteins, whereas a deep understanding of the advantages and limitations of AlphaFold3 for studying metamorphic proteins is still under development.

      Referees cross-commenting:

      Overall there is an agreement among all reviewers that the present MS is an interesting and timely study. The point raised by reviewer 2 to add simple biophysical characterization, if feasible, would be clearly an excellent addition and likely make the MS stronger. In general all three reviewers mainly point to minor changes and additions to improve the MS in a rather short timeframe.

      We indeed agree with this comment, which is why we will commit to attempt the recombinant expression and protein purification of the RfaH orthologs and to perform circular dichroism assays if the solubility of the obtained proteins allows for such experiments to be done.

      Reviewer #3 (Significance (Required)):

      The present MS is an interesting large-scale usage of the AlphaFold2 algorithm to reconstruct the evolutionary tree of the specialized transcription elongation factor RfaH. Revealing a different degree of this evolution in a diverse set of bacterial strains indicating its evolutionary distance from the cognate NusG transcription elongation factor. Of particular note is the experimental verification of the obtained in silico finding by in vivo luminescence approaches.

      We are very thankful for the reviewer’s comments on our manuscript.

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      Referee #3

      Evidence, reproducibility and clarity

      The manuscript by Tabilo-Agurto et al. uses a in silico and experimental methods to elucidate the diversity of the metamorphic RfaH protein family. Of particular note is the sophisticated usage of AlphaFold2 to reconstruct the evolutionary tree of RfaH as well as the in vivo luminescence assays to substantiate the different structural states of the RfaH-CTD. Overall this is a well-written manuscript providing deeper insight into the structural and functional diversity of RfaH proteins, potentially relevant for other metamorphic proteins as well.

      Minor Points:

      • 3rd paragraph of the introduction: The sentence starting with "To date, ...and nuclear magnetic resonance of these ancestors.." seems incomplete as this reviewer believes the author´s wanted to say "..and structural characterization by nuclear magnetic resonance spectroscopy of these ancestors..."
      • 4th paragraph of the introduction: "..., that binds Rho or the ribosome (Mooney et al. 2009b). Whereas this citation is correct for NusG-Rho interactions it does not indicate ribosome binding. The direct interaction of NusG with the ribosome was shown in Burmann et al. Science 2010 and this reference should be added here.
      • More a curiosity question, did the author also tested for a subset of the RfaH variants the AlphaFold3 predictions and obtained similar of different results?

      Referees cross commenting

      Overall there is an agreement among all reviewers that the present MS is an interesting and timely study. The point raised by reviewer 2 to add simple biophysical characterization, if feasible, would be clearly an excellent addition and likely make the MS stronger. In general all three reviewers mainly point to minor changes and additions to improve the MS in a rahter short timeframe.

      Significance

      The present MS is an intereting large scale uage of the AlphaFold2 algorithm to reconstruct the evolutionary tree of the specialized transcription elongation factir RfaH. Revealing a different degree of this evolution in a diverse set of bacterial strains indicating its evolutionary distance from the cognate NusG transcription elongation factor. Of particular note is the experimental verification of the obtained in silico finding by in vio luminescence approaches.

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      Referee #2

      Evidence, reproducibility and clarity

      In their paper "Exploration of the structural and functional diversity in the metamorphic RfaH subfamily," Tabilo-Agurto et al. use AlphaFold2 to predict the structures of ~3,900 RfaH homologs, sort the predicted C-terminal domains into α-helical (autoinhibited), β-barrel (NusG-like), and mixed α/β topologies, and find that about 14% of homologs come out predominantly in the β-barrel state. They then take nine representative homologs and run them through a heterologous E. coli DH5α ΔrfaH reporter assay. The putative monomorphic candidates behave a lot like the constitutively active E48A variant - active across every ops context and even without an RBS - while the mixed α/β candidates barely show activity. Targeted MD simulations of E. coli RfaH, run through AF2Rank, also pulls out the mixed α/β state as its own distinct cluster, hinting that it sits somewhere along the fold-switching transition path.

      This is a genuinely interesting piece of work that pulls together structure prediction, in vivo activity, and genomic context to make a concrete case for extant monomorphic βRfaH proteins - a long-hypothesized but until now unseen intermediate in the proposed stepwise evolution of RfaH from NusG. The experimental design is thoughtful, especially the five-construct ops/RBS matrix, and comparing the monomorphic candidates against the E48A benchmark is a nice touch as a positive control. Overall, I think the paper deserves to be published, but a few things would need shoring up before acceptance.

      Major comments

      1. The paper would be a lot stronger with at least one biophysical measurement (a CD spectrum, say) on a purified monomorphic candidate. I get that this might be outside the planned scope, but even a single CD trace showing β-rich content for an isolated full-length protein would move the claim from "putative" to "demonstrated."
      2. Only nine homologs were tested - three per category. The conclusions about monomorphic behavior generalizing across the whole βRfaH clade are basically resting on three proteins. Bringing in even one or two phylogenetically distant βRfaH candidates would help guard against the possibility that what they're seeing is just a genus-specific quirk. If new experiments aren't on the table, the limitation should at least be called out explicitly in the Discussion.
      3. The classification thresholds (α > 32.5% / β < 2.5% for αRfaH; β > 30.0% / α < 2.5% for βRfaH) are described as coming from histogram inspection, but they feel a bit arbitrary as stated. A quick sensitivity analysis - how do the population fractions shift if you nudge the cutoffs {plus minus}5%? - would help reassure the reader.
      4. The Discussion notes that uncontrolled, ops-independent RfaH recruitment could be lethal, since RfaH outcompetes the much more abundant NusG. But if monomorphic RfaH proteins really are extant and stably maintained in these genomes, there has to be something keeping them from interfering with NusG's essential functions - maybe very low expression, restricted induction, or compensating differences in NusG affinity. The paper would benefit from tackling this directly, even speculatively.

      Minor comments

      Table 1 should show percentages alongside the raw counts. 7/7 LPS-in-operon for monomorphic candidates is striking, but with n=10, the small denominator really deserves to be flagged.

      In Figure 3, the sequence logo on top is informative - consider adding the number of sequences per dataset to the axis labels so readers can interpret the boxplot widths.

      There's some redundancy between the Results (pp. 14-17) and the Discussion that could probably be trimmed, particularly the recap of the ops/RBS construct logic.

      Significance

      If the central claim holds up, this is a meaningful contribution to the metamorphic-protein and bacterial-transcription literatures: it identifies what appear to be extant evolutionary "way-stations" in the NusG→RfaH transition, and it does so using a tractable computational pipeline that could be applied to other suspected fold-switch families. The work is timely given the ongoing discussion about how AF2 and its descendants handle conformational heterogeneity. With the strengthening suggested above - particularly any direct biophysical confirmation of a monomorphic candidate - I would expect this to be a well-cited paper in its niche.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      This is an interesting and ambitious study by Tabilo-Agurto and co-workers. It combines deep learning structure prediction (AlphaFold2), targeted molecular dynamics simulations, and in vivo functional assays to probe structural, functional, and evolutionary aspects of the metamorphic protein RfaH. More broadly, the work addresses an important question: whether intermediate structural states may exist along evolutionary trajectories of metamorphic proteins. A particular strength of the study is the integration of computational and experimental approaches. The manuscript is generally well written and clearly organized.

      Major comment:

      A key aspect of the study is the classification of predicted structures into three classes based on the conformation of the C-terminal domain (CTD): the autoinhibited alpha-helical fold, a beta-barrel fold, and a mixed alpha/beta fold. These classes are further described as corresponding to metamorphic (alpha fold), mixed alpha/beta, and monomorphic (beta fold) proteins.

      While I can see how this organizational scheme is helpful in some respects, it may also overstate what can be concluded from the data. As the authors are well aware, AlphaFold2 tends to predict a single conformation even for genuine metamorphic proteins, and therefore does not, on its own, distinguish between monomorphic and fold-switching proteins. I note in particular that the functional data indicates that the "monomorphic" variants studied in the in vivo assays behave similarly to the RfaH E48A mutant. However, E48A is known to remain metamorphic, populating both alpha and beta folds with roughly equal probability. This suggests that the sequences in this class may retain some degree of fold-switching capability, even if the underlying regulatory mechanism differ from that of wild-type RfaH. In other words, the presented data does not fully support these sequences as monomorphic. I am not suggesting that the authors must revise their classification scheme. However, it may strengthen the manuscript if the authors explicitly acknowledge this alternative interpretation and moderate the corresponding claims.

      Significance

      An intriguing, but speculative, aspect of the study is the finding that some sequences are predicted to adopt a CTD with mixed alpha/beta secondary structure, and that such structures also appear in targeted molecular dynamics simulations. If this idea holds up, it could represent an intermediate along the evolutionary pathway between the alpha-helical and beta-barrel folds of RfaH. Although the evidence is only computational, it is a compelling idea and it would benefit from further investigation.

      In summary, the work is a valuable contribution to the field of protein fold switching. The combination of computational tools with experimental validation makes it interesting and the results should be of broad interest. The manuscript should be well positioned for publication in a high-impact journal.

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      Reply to the reviewers

      Manuscript number: RC-2026-03474

      Corresponding author(s): Priyanka, Verma

      [Please use this template only if the submitted manuscript should be considered by the affiliate journal as a full revision in response to the points raised by the reviewers.

      • *

      If you wish to submit a preliminary revision with a revision plan, please use our "Revision Plan" template. It is important to use the appropriate template to clearly inform the editors of your intentions.]

      1. General Statements [optional]

      Point-by-point rebuttal is presented below. Reviewer’s comments are in BLACK; author’s response is in BLUE and figure numbers corresponding to the manuscript are in RED.

      2. Point-by-point description of the revisions

      • *

      Reviewer #1 (Evidence, reproducibility and clarity (Required):

      ALC1 suppression has been shown to potentiate PARP inhibitor lethality in HR-deficient cells. Rather than revisiting the underlying mechanism, which has been characterized and remains an active area of investigation, this study aims to define the clinical contexts in which combined ALC1 and PARP inhibition may be beneficial. The clinical efficacy of PARP inhibitors, and their FDA approval, is largely restricted to HR-deficient tumors. This study dissects the combined effects of ALC1 and PARP suppression across a panel of HRD ovarian cancer cell lines, multiple classes of PARP inhibitor, and cells harboring distinct PARPi resistance mechanisms. In doing so, the authors delineate both the potential utility and the limitations of combined ALC1 and PARP inhibitor treatment in HRD ovarian cancers. The most impactful finding of the study, however, is likely the demonstration that ALC1 suppression sensitizes HR-proficient, CCNE1-amplified high-grade serous ovarian cancers to PARP inhibitors. These tumors are associated with particularly poor outcomes owing to the current absence of effective targeted therapies, making this observation of considerable clinical relevance.

      We thank the reviewer for appreciating the significance of our work in “HR-proficient, CCNE1-amplified high-grade serous ovarian cancers to PARP inhibitors” which is a critical unmet need.

      Of note, the study relies on genetic rather than pharmacological depletion of ALC1, a choice likely reflecting the current lack of a commercially available ALC1 inhibitor. While genetic suppression may not fully recapitulate the effects of combined drug treatment, it offers the advantage of not being tied to any specific compound, allowing the authors to establish more general principles. I have only a few comments.

      We are grateful to the reviewer for providing the unique perspective on our genetic study that “it offers the advantage of not being tied to any specific compound, allowing the authors to establish more general principles.”

      We have included this in our discussion to strengthen the study.

      The effect of ALC1 KO on PARPi sensitivity is less pronounced in OVSAHO cells (BRCA2-mutated) than in BRCA1-mutated cells. In these cells, it looks like there is an additive effect rather than synergy. 1- The authors should calculate, if possible, whether there is synergy or additive effect of ALC1-KO lethality (BLISS).

      We thank the reviewer for recognizing our limitations to perform BLISS score analysis, as our experiments were conducted at a single level of total protein depletion. Ideally, synergy assessments require a range of depletion levels to generate a full response matrix. Regardless, to address the reviewer’s concern regarding the impact of ALC1 on olaparib response in BRCA1- and BRCA2-mutant cells, we performed a BLISS score calculation under the conservative assumption that total ALC1 depletion alone has no effect on cell viability. We then employed the following formula for BLISS score calculation:

      Bliss Score =Eobs- (EA+EB-EAX EB)

      Where Eobs is viability of ALC1-depleted cells at a given drug concentration. This is observed impact upon combined loss of ALC1 and olaparib treatment.

      EA is impact on viability upon ALC1 depletion only. This was considered to be zero.

      EB is impact on viability on ALC1 WT in the presence of drug. This assesses the impact of drug alone.

      BLISS score was calculated at all non-saturating drugs concentration and then averaged to obtain a final BLISS value. We used the following cut off:

      > 10: Synergistic (the interaction is considered significant);

      -10 to 10: Additive (no significant interaction);

      __

      Olaparib

      Rucaparib

      Niraparib

      Veliparib

      Cisplatin

      UWB1.289

      22.34

      25.21

      13.24

      14.95334

      0.26

      JHOS-4

      37.27

      47.14

      26.3

      27.94

      -0.37

      OVSAHO

      19.34

      27.6

      23.2

      19.15

      7.04

      Kuramochi

      11.38

      11.98

      -3.56

      6.79

      -0.39

      We observe that ALC1 loss synergistically enhances olaparib and rucaparib response in both BRCA1- and 2-mutant cells. However, as correctly noted by the reviewer, we notice that the BLISS score is higher in BRCA1-mutant cells compared to BRCA-2 mutant, OVSAHO.

      In the revised manuscript, we have also included data for another BRCA-2-mutant cell line: KURAMOCHI (Fig.1d; Supp. Fig1b). We chose this cell line because, despite having a BRCA2-mutation, it is highly resistant to PARP inhibitors and cisplatin, owing to KRAS amplification. Notably, we observe that ALC1 loss can synergistically enhance the response of Kuramochi to olaparib and rucaparib.

      We have included a statement in the manuscript that the impact of ALC1 loss was more profound in BRCA1- versus BRCA2-settings. However, if acceptable to the reviewer, we would prefer not to include the BLISS values in the manuscript, as these calculations were not performed using the standard approach of titrating multiple levels of protein depletion.

      2- Another BRCA2-mutated cell line should be included.

      As discussed above, we have now included data from another BRCA2-mutant cell line, Kuramochi. Consistent with data in other BRCA-mutant cell lines, loss of ALC1 enhances olaparib and rucaparib sensitivity in these cells (Fig. 1d; Supp. Fig.1b).

      Minor comments: • Figure key is missing for S2C (I assume it's grey DMSO, blue olaparib)

      We apologize for this oversight. Figure key has now been included.

      • Page 8: "BRCA1-mutant ovarian cancer cells eventually develop chemoresistance when exposed to PARPi for a prolonged period. Mechanistically, this is due to rewiring of ATR signaling, which enables RAD51 loading at DNA breaks and reversed forks independent of BRCA1 protein(25)." This sentence suggest this is the only existing resistance mechanism, which should be correct. Modify to "mechanistically, this CAN be due to", or "this is OFTEN due to".

      We thank for the reviewer for suggesting this important correction. This has now been fixed.

      Reviewer #1 (Significance (Required)):

      ALC1 inhibitors have been developed and clinical trials are starting. The significance of this manuscript lies in establishing the clinical potential for combined ALC1-PARP inhibition in high grade serous ovarian cancer. Especially, the authors demonstrate that combined ALC1 suppression with PARP inhibition efficiently kills HR-proficient CCNE1-amplified ovarian cancers, which represent 20% of ovarian cancers and are resistant to current therapies.

      __Reviewer #2 (Evidence, reproducibility and clarity (Required)): __ The manuscript by Lindsey et al. explores the role of ALCN1 (Amplified in Liver Cancer 1) loss in enhancing the sensitivity of PARPi in ovariar carcinomas, including BRCA1/2 mutated tumors (both sensitive and resistant to platinum) as well as cyclin E amplified settings. The data are interesting but the in some cases there is an overinterpretation of the results. I have listed below my major concerns.

      We appreciate that the reviewer finds our data interesting. We also appreciate the reviewer insightful comments and have addressed them below.

      Figure 1. Could the authors demonstrate that OVASAHO cells are BRC2 muted? Indeed, I have always though they were BRCA wt type (10.1016/j.ygyno.2015.08.017).

      OVSAHO cells have a homozygous deletion in the BRCA2 gene (PMID:23839242), which could be the reason why a mutation was not detected in the study referred to by the reviewer (PMID: 26321251). We have now included the Domcke et al; 2013 reference in manuscript. The loss of BRCA2 expression in OVSAHO is also evident in our blots (Fig. 1a), as well as in data from protein atlas analysis.

      While the data on cisplatin suggest that indeed ALC1 loss do not impact its sensitivity, I disagree with the statant that "the correlation between dispensability of ALC1 in platinum response suggests that this chromatin remodeler likely does not contribute to MMEJ (page 6)" or " is dispensable for HR (page 7). Indeed, it is has to be stressed that cisplatin induced DNA damage (interstrand crosslinks) are substrates also for nucleotide excision repair, that has a key role in repairing these lesions.

      We agree with the reviewer that transcription-coupled NER is the key pathway for the resolution of cisplatin-induced damage. We therefore have revised this statement in the manuscript as “Our data showing the dispensability of ALC1 in cisplatin response, both in BRCA1 and 2-mutant settings, is consistent with previous reports demonstrating the dispensability of this remodeler for MMEJ or transcription-coupled nucleotide excision repair.” We have cited previous work where ALC1 has been shown to be dispensable for MMEJ or TC-NER. Similarly, we have modified the text on page 7 as “Furthermore, ALC1 loss did not impact sensitivity to cisplatin in HRP cyclin E1-high cells. This observation is consistent with previous studies showing its dispensability for HR repair.”

      Figure 2. Please explain better why niraparib is not active in cyclinE1-high cells.

      Our comprehensive studies examining the impact of ALC1 depletion on PARPi response uncover the generalized theme that targeting is most effective in enhancing sensitivity of olaparib and rucaparib, which have moderate PARP1/2 trapping ability, as compared to niraparib and talazoparib, which are strong trappers. One possible explanation could be that moderate PARP1/2 trappers are more amenable for combination strategies because their effects do not reach full saturation, preserving a dynamic range that allows for additive or synergistic enhancement. This was included in the discussion section of the manuscript.

      It is not clear to me if the authors consider a cyclin E "gain" an overexpressing tumor (i.e. OVCAR8). The authors need to show the response to PARPi in one (possibly two) cell lines with very low expression of cyclin E and knock-down of ALC1.

      We have present data in multiple BRCA1-WT cell lines with very low expression of cyclin E compared to OVCAR8. These include: FT282 cell line (Fig. 4), two FT282 clones of BRCA1-/+ FT cells (Fig. 5), and full length BRCA1 addback UWB1.289 (Fig. 3c). Additionally, we have added immunoblotting data showing that in OVCAR8, the level of cyclin E1 protein and activity as assessed by pCdk2 is comparable to OVCAR3 and OVCAR4, two CCNE1-amplified lines (Fig. S2d). In contrast, FT 282 and UWB1.289 BRCA1 add back cells have low levels of cyclin E and thus low pCdk2.

      The deletion of ALC1 do interfere with tumor take and tumor growth? No clear is the in vivo experiments.

      Tumor uptake: We injected OVCAR8 cells in mice three days post-transduction of sgALC1. Depletion of ALC1 is only achieved at 14 days post transduction. This explains why tumor uptake is not impacted. We do not observe a significant impact of ALC1 loss on tumors derived from OVCAR8 cells. This is consistent with the dispensability of ALC1 in the proliferation of HR-proficient cells (PMID: 33333017; PMID: 33462394). We have added text in the manuscript to clarify this point.

      Injecting OVCAR8 cells in the peritoneum is not associated with the formation of ascites?

      We thank the reviewer to bring up this important point. The objective of this study is to examine how ALC1 loss can enhance PARPi responses and therefore we chose an earlier time point (~50 days) to assess the impact on tumor growth. Ascites formation upon intraperitoneal injection of OVCAR8 cells has primarily been reported at late stages of disease development. For example, Anirban Mitra et al. (2015) (PMID: 26050922) reported consistent ascites formation, but only at extended timepoints (up to ~90 days post-injection). Similarly, Yong-Tae Shen et al. (2019) (PMID: 31117198) injected 5-10 x106 cells and observed ascites emergence beginning around day 49, with progressive accumulation toward the endpoint, indicating that fluid buildup coincides with advanced peritoneal dissemination. In contrast, studies using comparable inoculation doses (e.g., 1×10⁶ cells) and shorter observation periods (~6 weeks) such as Luis Hernandez et al. (2016) (PMID: 27235858) did not report detectable ascites. Taken together, these findings suggest that, while OVCAR8 cells can generate ascites, this phenotype typically manifests at later stages of disease progression and is not expected within shorter experimental windows. Therefore, the absence of ascites in our model is consistent with the study design and timeframe, rather than indicative of a failure of tumor establishment.

      We have added relevant discussion in the results section to clarify this point.

      How was tumor weight calculated?

      Tumor burden was quantified by direct collection and measurement of peritoneal tumor nodules. For the sacrificed mice, all visible tumor nodules within the peritoneal cavity were carefully excised, counted, and pooled per animal. The total tumor weight was then determined by weighing the combined mass of all collected nodules using an analytical balance. Thus, “tumor weight” represents the cumulative mass of macroscopic peritoneal implants per mouse. No estimations or indirect calculations were used. This has now been elaborated on in the methods section.

      It seems that tumors grow as solid mass, but how were nodulesAll mice at endpoint exhibited disseminated peritoneal disease, characterized by multiple tumor nodules and invasion into the peritoneal wall. Tumor nodules were quantified by direct visual inspection during necropsy. Small nodules ( Why survival curves were not shown?

      Survival analysis was not included because the study was designed with a predefined experimental endpoint to enable controlled comparison of tumor burden across groups. Animals were therefore euthanized at the same timepoint rather than followed longitudinally to survival. As a result, Kaplan–Meier analysis was not applicable to this experimental design. We agree that survival is an important outcome and would be valuable in future studies specifically powered and designed for that purpose.

      The dose of 50mgr/kg every third day is a very low olaparib dose. Generally the in vivo dosing is 100mgr/kg , 5 days a week for 4 weeks (doi: 10.1158/1535-7163.MCT-21-0420; 10.1158/2767-9764.CRC-22-0423).

      We agree that higher doses of olaparib (e.g., 100 mg/kg, 5 days/week) are commonly used and have demonstrated single-agent efficacy in vivo. In this study, however, our objective was to specifically evaluate the combinatorial effect of olaparib with genetic knock-out of ALC1. To enable this, we intentionally employed a reduced dosing regimen (50 mg/kg every third day) to minimize single-agent activity. This approach allowed us to establish a condition in which olaparib in sgAAVS1 control tumors had limited impact on tumor burden, thereby providing a dynamic range in which to detect potential sensitization effects mediated by sgALC1. Using a fully efficacious dose would likely mask such interactions by producing a near-maximal response in the control group. Thus, the selected dosing strategy reflects a deliberate experimental design to assess potentiation effects rather than to model maximal therapeutic efficacy of olaparib as a monotherapy.

      Figure 4. I could not find the data of the minimal impact of ALC1 in UWB1.289 cells. What the author refer to? They refer to the fact that ALC1 deletion di not cause any cell growth alteration or to something else? But were there the data?

      The minimal impact being referred to was PARPi responses in BRCA1-proficient UWB1.289. We have now fixed the statement to read: “The minimal impact of ALC1 in BRCA1-proficient UWB1.289 cells on PARPi responses suggested that targeting this remodeler may have minimal impact on normal healthy cells.” and included the relevant figure number (Fig.3c) for clarity.

      The modest increment in pRPA in hTER-FT282 is statistically significant and not very different from what observed in UWB.289, suggesting that ACL1 deletion could indeed impact normal cells. These data should be interpreted more conservatively.

      The increase in pRPA levels upon ALC1 loss in hTERT FT282 BRCA1 het cells and UWB1.289 cells is 1.2 and 1.4 respectively. This is consistent with the literature that BRCA1-/+ het cells have compromised replication stress response. Unresolved replication stress gets processed into double-strand breaks (DSBs). Consistent with the proficiency of hTERT FT282 BRCA1-/+ het cells in DSBs repair, ALC1 deficiency does not increase yh2ax in these cells. Hence, despite an increase in pRPAS33 signal in hTERT FT282 BRCA1 het cells, these cells can resolve downstream breaks. In contrast, a profound, 1.7-fold increase in yh2ax signal was observed upon ALC1 loss in BRCA-mutant UWB1.289 cells, reinforcing that ALC1 loss has a more profound response in BRCA-mutant cancer cells.

      To align with the reviewer’s suggestion, we have removed the word “modest’ and have retained the fold differences in the median values.

      Figure 6. Questionable is the OS as endpoint in this heterogeneous patient population (treated in front line and recurrent) and in my opionion OS, much more than PFS, is influences by the many different treatment these patients underwent and that could influence the OS. Why not considering PFS after/or on PARPi treatment? The authors should clarify the patient population, Indeed, 48 patients were treated with PARPI and were platinum sensitive and possibly HRD. What patients are the HPR patients? How many were they? It is not clear the HRP and high replication stress cohort were treated with PARPi? How many of these were Cyclin E amplified or with high levels? Figure 6F should also include, beside UVB+BRCA1, other tumor cells with no Cyclin E overexpression and non BRCA mutation or HRD. The discussion of limitations should be addressed to strengthen the manuscript.

      We thank the reviewer and agree that PFS is often preferred for evaluating treatment-specific effects. However, in this cohort, PFS was not a reliable endpoint for several reasons. Tumor samples were obtained at diagnosis, whereas PARPi was administered later, in either the frontline maintenance or recurrent setting, introducing temporal and prognostic heterogeneity that limits the interpretability of PFS. These factors confound attribution of PFS specifically to PARPi response. We therefore selected OS from the time of PARPi exposure as a more consistently defined endpoint across this heterogeneous cohort, while acknowledging its limitations.

      Reviewer #2 (Significance (Required)):

      The manuscript by Lindsey et al. explores the role of ALCN1 (Amplified in Liver Cancer 1) loss in enhancing the sensitivity of PARPi in ovarian carcinomas, including BRCA1/2 mutated tumors (both sensitive and resistant to platinum) as well as cyclin E amplified settings. The data are interesting but the in some cases there is an overinterpretation of the results.

      __Reviewer #3 (Evidence, reproducibility and clarity (Required)): __ The manuscript by Aubuchon, Wong et al. presents strong insights into the value of ALC1 as novel target for sensitization strategies against PARPi. The authors show that a PARPi resistance is reversible when ALC1 is knocked down and convincingly highlight the genetic circumstances for these approaches. Also, the authors point out that especially the weak PARP-trappers olaparib and rucaparib could benefit from concomitant ALC1 inhibiton and high levels of replication stress by elevated p-T21 RPA2 could serve as biomarker in clinical settings. Furthermore, the authors show that benign fallopian tube cells are not affected by ALC1-kd, which is an important finding for in vivo approaches.

      We thank the reviewer for acknowledging that our work provides “strong insights” and makes “important finding for in vivo approaches”.

      As the manuscript covers a broad experimental field, I would only suggest a few additional experiments to further strengthen the overall story:

      1. How does an ALC1 knock-down affect the expression of PARP1 and if so, how does this contribute to the effects seen by ALC1-kd? The authors could add Western Blot experiments for cell lines belonging to the respective groups that are distinguished in the manuscript: BRCA wt, BRCA mutated and Cyclin E1-high cancer cells and also a benign fallopian tube cell line.

      This was an interesting point brought up by the reviewer. To address this, we examined and compared total PARP1 protein levels in BRCA1 add-back UWB1.289, BRCA1-mutant UWB1.289, cyclin E1-high OVCAR8, and FT282, between ALC1 WT and depleted cells. However, we do not observe any consistent alteration in PARP1 level upon ALC1 depletion (Fig. Supp. Fig. 6a, b).

      In some of the Western Blot data, it also looks like BRCA1 expression is affected by ALC1 kd. The authors could provide some quantified protein expression or qPCR data if there is a correlation between both expressions.

      To address the reviewer’s question, we quantified changes in BRCA1 levels upon ALC1 loss across all cell lines used in this study. As expected, BRCA1 levels were higher in UWB del 11q and Cyclin E1-overexpressing cell lines. In contrast, cell lines harboring heterozygous BRCA1 mutations or BRCA1 promoter methylation were among those with the lowest BRCA1 expression. This trend provides us confidence in reliably quantifying our immunoblotting data. Although minor fluctuations in BRCA1 protein levels were observed following ALC1 depletion, no consistent trend towards either an increase or decrease was evident (Fig. Supp. Fig. 6c). Likewise, when cell lines were grouped according to their sensitivity to PARP inhibition upon ALC1 loss, no clear pattern emerged (Fig. Supp. Fig. 6d). Together, these data suggest that ALC1 depletion does not substantially affect BRCA1 protein levels, consistent with our previous RNA-seq and functional studies indicating that this chromatin remodeler is dispensable for transcriptional regulation or homologous recombination (PMID: 33462394).

      To further strengthen the hypothesis that the effects of strong PARP-trappers are not improved by ALC1 kd, the authors should add data regarding the viability of the cells presented in Figure 3b upon treatment with niraparib and talazoparib in sgALC1 cells (versus vector control). Also, the authors should add cell viability data using talazoparib for the sgALC1 OVCAR cell lines (versus vector control) in Figure 2 and Supplement Figure 3.

      Sensitivity to niraparib and talazoparib upon ALC1 depletion have now been added in Figure 3b, and for OVCAR lines in Supplement Figure 3. As correctly pointed by the reviewer, we consistently observe that impact of ALC1 loss is more profound on olaparib and rucaparib compared to niraparib and talazoparib.

      Some minor points I noticed while reading the manuscript:

      We apologize for the oversight and thank the review for pointing this out.

      • in Figure 3b, both graphs have the same title. I think the right one should be "SYr14" instead of "SYr12" again

      Fixed. - In the heading of Figure 2 an "in" is missing

      Fixed.

      • There are some citations, that seem to be made with another citation style (superscript numbers) than numbers in brackets across the manuscript.

      Fixed.

      Reviewer #3 (Significance (Required)):

      The most important aspect resulting from this manuscript is that ALC1 inhbitors could improve the response to some PARPi without damaging healthy cells. Thereby, the authors also mention the limitation of the use of ALC1 as a target and offer a potential biomarker for combinatory approaches. This study offers a very detailed insight into the potential role of ALC1 as a target for sensitization approaches under the different genetic conditions that can occur in HGSOC. These novel insights contribute to further broaden the therapeutic options by PARPi in clinical settings if the results can be approved by in vivo trials.

      • *
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      Referee #3

      Evidence, reproducibility and clarity

      The manuscript by Aubuchon, Wong et al. presents strong insights into the value of ALC1 as novel target for sensitization strategies against PARPi. The authors show that a PARPi resistance is reversible when ALC1 is knocked down and convincingly highlight the genetic circumstances for these approaches. Also, the authors point out that especially the weak PARP-trappers olaparib and rucaparib could benefit from concomitant ALC1 inhibiton and high levels of replication stress by elevated p-T21 RPA2 could serve as biomarker in clinical settings. Furthermore, the authors show that benign fallopian tube cells are not affected by ALC1-kd, which is an important finding for in vivo approaches.

      As the manuscript covers a broad experimental field, I would only suggest a few additional experiments to further strengthen the overall story:

      1. How does an ALC1 knock-down affect the expression of PARP1 and if so, how does this contribute to the effects seen by ALC1-kd? The authors could add Western Blot experiments for cell lines belonging to the respective groups that are distinguihed in the manuscript: BRCA wt, BRCA mutated and Cyclin E1-high cancer cells and also a benign fallopian tube cell line.
      2. In some of the Western Blot data, it also looks like BRCA1 expression is affected by ALC1 kd. The authors could provide some quantified protein expression or qPCR data if there is a correlation between both expressions.
      3. To further strengthen the hypothesis that the effects of strong PARP-trappers are not improved by ALC1 kd, the authors should add data regarding the viability of the cells presented in Figure 3b upon treatment with niraparib and talazoparib in sgALC1 cells (versus vector control). Also, the authors should add cell viability data using talazoparib for the sgALC1 OVCAR cell lines (versus vector control) in Figure 2 and Supplement Figure 3.

      Some minor points I noticed while reading the manuscript:

      • in Figure 3b, both graphs have the same title. I think the right one should be "SYr14" instead of "SYr12" again
      • In the heading of Figure 2 an "in" is missing
      • There are some citations, that seem to be made with another citation style (superscript numbers) than numbers in brackets across the manuscript.

      Significance

      The most important aspect resulting from this manuscript is that ALC1 inhbitors could improve the response to some PARPi without damaging healthy cells. Thereby, the authors also mention the limitation of the use of ALC1 as a target and offer a potential biomarker for combinatory approaches. This study offers a very detailed insight into the potential role of ALC1 as a target for sensitization approaches under the different genetic conditions that can occur in HGSOC.

      These novel insights contribute to further broaden the therapeutic options by PARPi in clinical settings if the results can be approved by in vivo trials.

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      Referee #2

      Evidence, reproducibility and clarity

      The manuscript by Lindsey et al. explores the role of ALCN1 (Amplified in Liver Cancer 1) loss in enhancing the sensitivity of PARPi in ovariar carcinomas, including BRCA1/2 mutated tumors (both sensitive and resistant to platinum) as well as cyclin E amplified settings.

      The data are interesting but the in some cases there is an overinterpretation of the results. I have listed below my major concerns

      Figure 1. Could the authors demonstrate that OVASAHO cells are BRC2 muted? Indeed, I have always though they were BRCA wt type (10.1016/j.ygyno.2015.08.017). While the data on cisplatin suggest that indeed ALC1 loss do not impact its sensitivity, I disagree with the statant that "the correlation between dispensability of ALC1 in platinum response suggests that this chromatin remodeler likely does not contribute to MMEJ (page 6)" or " is dispensable for HR (page 7). Indeed, it is has to be stressed that cisplatin induced DNA damage (interstrand crosslinks) are substrates also for nucleotide excision repair, that has a key role in repairing these lesions. Figure 2. Please explain better why niraparib is not active in cyclinE1-high cells. It is not clear to me if the authors consider a cyclin E "gain" an overexpressing tumor (i.e. OVCAR8). The authors need to show the response to PARPi in one (possibly two) cell lines with very low expression of cyclin E and knock-down of ALC1.<br /> The deletion of ALC1 do interfere with tumor take and tumor growth? No clear is the in vivo experiments. Injecting OVCAR8 cells in the peritoneum is not associated with the formation of ascites? How was tumor weight calculated? It seems that tumors grow as solid mass, but how were nodules<1mm quantified? Please clarify. Why survival curves were not shown? The dose of 50mgr/kg every third day is a very low olaparib dose. Generally the in vivo dosing is 100mgr/kg , 5 days a week for 4 weeks (doi: 10.1158/1535-7163.MCT-21-0420; 10.1158/2767-9764.CRC-22-0423).

      Figure 4. I could not find the data of the minimal impact of ALC1 in UWB1.289 cells. What the author refer to? They refer to the fact that ALC1 deletion di not cause any cell growth alteration or to something else? But were there the data? The modest increment in pRPA in hTER-FT282 is statistically significant and not very different from what observed in UWB.289, suggesting that ACL1 deletion could indeed impact normal cells. These data should be interpreted more conservatively.

      Figure 6. Questionable is the OS as endpoint in this heterogeneous patient population (treated in front line and recurrent) and in my opionion OS, much more than PFS, is influences by the many different treatment these patients underwent and that could influence the OS. Why not considering PFS after/or on PARPi treatment? The authors should clarify the patient population, Indeed, 48 patients were treated with PARPI and were platinum sensitive and possibly HRD. What patients are the HPR patients? How many were they? It is not clear the HRP and high replication stress cohort were treated with PARPi? How many of these were Cyclin E amplified or with high levels? Figure 6F should also include, beside UVB+BRCA1, other tumor cells with no Cyclin E overexpression and non BRCA mutation or HRD.

      The discussion of limitations should be addressed to strengthen the manuscript.

      Significance

      The manuscript by Lindsey et al. explores the role of ALCN1 (Amplified in Liver Cancer 1) loss in enhancing the sensitivity of PARPi in ovarian carcinomas, including BRCA1/2 mutated tumors (both sensitive and resistant to platinum) as well as cyclin E amplified settings. The data are interesting but the in some cases there is an overinterpretation of the results.

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      Referee #1

      Evidence, reproducibility and clarity

      ALC1 suppression has been shown to potentiate PARP inhibitor lethality in HR-deficient cells. Rather than revisiting the underlying mechanism, which has been characterized and remains an active area of investigation, this study aims to define the clinical contexts in which combined ALC1 and PARP inhibition may be beneficial. The clinical efficacy of PARP inhibitors, and their FDA approval, is largely restricted to HR-deficient tumors. This study dissects the combined effects of ALC1 and PARP suppression across a panel of HRD ovarian cancer cell lines, multiple classes of PARP inhibitor, and cells harboring distinct PARPi resistance mechanisms. In doing so, the authors delineate both the potential utility and the limitations of combined ALC1 and PARP inhibitor treatment in HRD ovarian cancers. The most impactful finding of the study, however, is likely the demonstration that ALC1 suppression sensitizes HR-proficient, CCNE1-amplified high-grade serous ovarian cancers to PARP inhibitors. These tumors are associated with particularly poor outcomes owing to the current absence of effective targeted therapies, making this observation of considerable clinical relevance. Of note, the study relies on genetic rather than pharmacological depletion of ALC1, a choice likely reflecting the current lack of a commercially available ALC1 inhibitor. While genetic suppression may not fully recapitulate the effects of combined drug treatment, it t offers the advantage of not being tied to any specific compound, allowing the authors to establish more general principles. I have only a few comments.

      The effect of ALC1 KO on PARPi sensitivity is less pronounced in OVSAHO cells (BRCA2-mutated) than in BRCA1-mutated cells. In these cells, it looks like there is an additive effect rather than synergy.

      1. The authors should calculate, if possible, whether there is synergy or additive effect of ALC1-KO lethality (BLISS).
      2. Another BRCA2-mutated cell line should be included.

      Minor comments:

      • Figure key is missing for S2C (I assume it's grey DMSO, blue olaparib)
      • Page 8: "BRCA1-mutant ovarian cancer cells eventually develop chemoresistance when exposed to PARPi for a prolonged period. Mechanistically, this is due to rewiring of ATR signaling, which enables RAD51 loading at DNA breaks and reversed forks independent of BRCA1 protein(25)." This sentence suggest this is the only existing resistance mechanism, which should be correct. Modify to "mechanistically, this CAN be due to", or "this is OFTEN due to".

      Significance

      ALC1 inhibitors have been developed and clinical trials are starting. The significance of this manuscript lies in establishing the clinical potential for combined ALC1-PARP inhibition in high grade serous ovarian cancer. Especially, the authors demonstrate that combined ALC1 suppression with PARP inhibition efficiently kills HR-proficient CCNE1-amplified ovarian cancers, which represent 20% of ovarian cancers and are resistant to current therapies.

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      Reply to the reviewers

      Reviewer #1

      Evidence, reproducibility, and clarity

      Summary: Edvalson and colleagues use transcriptomics, cell biology and genetics to study variation between segregation distorter (meiotic drive) strains and find several important results. These include apparent suppression of small RNAs mapping to responder (the drive target) in one of the lines, a general pattern of differential expression consistent with the drive mechanism being upstream of sperm individualization (where defects have been seen previously), and genetic confirmation that perturbing Rsp expression can influence the strength of drive.

      Major comments: I found the total RNA sequencing experiment a bit oddly presented. This is partly because it was in the middle of the results (might fit better first), partly because few specific genes were discussed (this might be appropriate given then question, but maybe the question should be more clearly stated), and the complexity of the approach (WCGNA + PANGEA) and how it all fits together. I suggest working to clarify the main points of this section (which are a bit different than the main focus of the Rsp work).

      We thank the reviewer for these important points. We liked the suggestion to swap the order of our results. We attempted the change, but we found that we weren't able to make the flow of the results much better. Instead, we primed the transition from smRNA to totRNA in the last paragraph of the smRNA results (lines 190-196). This paragraph now reads:

      The dearth of Rsp smRNAs in SD-Mad heterozygotes could be due to a disruption in transcription of the locus or subsequent processing steps. Many factors can influence piRNA production. For example, the piRNA pathway can amplify piRNAs independently of transcription, such as the ping pong cycle, (Czech and Hannon 2016). Notably, Rsp piRNAs do not have a strong ping pong signature in testes (Wei et al. 2021; Chen et al. 2021a). To distinguish between a disruption in transcription or some downstream process, we examined total RNA.

      The main reason we elected to describe patterns rather than specific genes is that the 2nd chromosomes we tested (R-16, SD-Mad, SD-5) have all diverged from each other and any single differentially expressed gene could be due to differences in genetic background. Therefore, we elected to point out more broad systematic changes in pathways and correlated gene networks rather than specific genes. We have made it more obvious throughout the total RNA section in the text what our question is regarding the transcriptome and the reasoning for using WGCNA and gene set analysis.

      We also appreciate the reviewers point that the complex approach we used to extract changes in pathways and networks is difficult to follow. We have modified our wording to better describe the flow of analyses.

      We also note that we have extended our analysis for the comparison of SD-Mad and SD-MadRev, which only differ by the Sd-RanGAP locus. Here we do discuss individual genes that are differentially expressed. See below for details about this new analysis.

      Minor comments:

      Abstract - Probably worth mentioning Sd-RanGAP here, even if you are using it as a straw man. I agree that the specific mechanism is not known, but some of the genetics are established.

      This is a good point. While our study doesn't address RanGAP, it is important to point out that, although its role in drive is unclear, Sd-RanGAP is a necessary component of the system. We added the following language to the abstract:

      SD is a multigene complex, frequently associated with chromosomal inversions, where the main driver locus, a truncated duplication of the gene RanGAP kills wild-type sperm containing a satellite DNA called Responder (Rsp).

      Line 80 and elsewhere - it would be helpful to be specific here - you are looking at both small and total RNA

      We've modified our wording throughout the manuscript to specify when we are referring to total RNA and small RNA.

      Fig 1B - is there a reason not to show the values of the replicates here? It would be more transparent.

      We thank the reviewer for this comment. We replaced Fig 1B with a chart that is computed from the DESeq2 normalized counts for each comparison and added replicates to all related graphs.

      Line 139 - does the experimental design control for 1.688 genomic copy number? Where is it located?

      We indeed control for the 1.688 copy number here. Most 1.688 repeats are found on the X chromosome and all flies in our experiments have identical X chromosomes. We changed the text to specify that copy number for 1.688 are the same between conditions.

      144-146 - this could be written clearer, and I think it should only refer to 1C, not 1B. Part of the issue is that there are several repeats not discussed, and it isn't clear what is happening with them. I suggest expanding this description so it is more clear.

      Thank you for this feedback. We have expanded the description to make this section clearer.

      Line 161 - what do you mean (specifically) by "repetitive loci"?

      Repetitive loci in this case refers to transposons, satellite DNAs (except simple satellites), and piRNA clusters. We have added text explaining what is included the grouping of "repetitive loci". We have added the following sentence to the text:

      Our results demonstrate that SD-Mad and SD-5 haplotypes, despite sharing the same main drive locus, have different effects on smRNAs derived from repetitive loci such as complex satellites (including Rsp), transposable elements, and piRNA clusters.

      193-203 - This is an important finding that is somewhat lost in trying to keep track of WCGNA and PANGEA and the different Modules. I suggest clarifying to drive home the point that differential expression appears to start prior to individualization, which suggests and earlier mechanism of drive.

      We thank the reviewer for this feedback. We have added wording to out discussion that points out this finding in lines 501-505 which reads:

      We suspect that the timing of the proximal cause of SD-mediated drive may align with early spermatogenetic processes; perhaps where cell cycle-related genes are active and appear to be broadly differentially expressed (Figure 2B, Module H). This earlier timing is consistent with temperature shift experiments that place the critical period for SD at or before meiosis (Mange 1968).

      Fig 3B & 3C, Fig 4 - same as 1B, is there a reason not to show the actual data points?

      A similar issue was brought up earlier, in response we modified all our figures to show replicate points where applicable.

      Line ~245 - was the same experiment done with SD-5? (as you do below for Rsp overexpression)

      We originally did not include SD5 in this experiment, but we have since measured drive strength of SD5 in a kipfKO background. We found a small but statistically significant difference in drive strength. We added the new SD5 results to the figure and moved the kipfKD data to the supplement along with some added data on a Rsp deletion line generated from Iso1 that bolsters our confidence in the SDMad results.

      Significance

      This is a strong paper that moves the field forward, even if it leaves questions still to be answered (why the difference between drivers? what is the mechanism? how is rsp interacting with drive?

      Several findings move the field forward: the Rsp small RNA results, the differential expression hinting at a molecular mechanism that is upstream of sperm individualization.

      The audience is moderately broad. Genetic conflict is gaining in general interest, but aspects of this will be mostly interesting to the hardcore drive crowd.

      Reviewer #2

      Evidence, reproducibility and clarity

      I have only one request: I found it unclear whether the authors were referring to small RNAs or their precursor (long RNA). By reading the text carefully, I could deduce that Fig1A/Table S2 represent the small RNA sequencing, while FigS3A represents total RNA seq (detecting precursor). However, the labeling in the Fig1A and Table S2 only says 'piRNA cluster' or 'Rsp' (without clarifying 'piRNA from piRNA cluster' or 'piRNA from Rsp'), and it took quite some time for me to understand which Fig/data is smallRNA vs. longRNA.

      This is helpful feedback. We have added more clarity to which type of RNA is being represented in our figures throughout.

      Significance

      This manuscript by Edvalson et al. describes their study on SD (segregation distorter) meiotic drive system, examining the role of piRNA derived from Rsp satellite. Although the exact mechanism of drive is still unknown, this study represents a significant step forward in understanding SD-mediated drive.

      By using two SD alleles (SD-5 and SD-Mad), they show that Rsp-derived piRNA is depleted in SD-Mad. The authors used total RNA sequencing/small RNA sequencing mutants and carefully designed controls (such as deletion of Sd-RanGAP) to reach the model that Rsp-derived piRNA is involved in SD-Mad-mediated drive. The result that kipferl depletion (that lead to sat DNA expression) rescues SD-Mad's drive phenotype is very interesting. This supports that the decreased Rsp piRNA indeed corresponds to SD-Mad-mediated drive. They further back up this idea by overexpressing Rsp.

      Interestingly, SD-5 was not impacted by changes in Rsp expression. Based on this result, the authors state that there are mechanistic variations in the same (SD) drive system. This statement is certainly justified by the data, but I cannot help wondering there might be a unifying mechanism that explains both SD-5 and SD-Mad. I am not suggesting to edit the manuscript or add the discussion: but do they have any speculations on this? For example, SD-5 is simply epistatic to Rsp piRNA production? For example, SD-RanGAP > SD-Mad (some gene on SD-Mad inversion) > Rsp piRNA production > SD-5 > sperm killing?

      We thank the reviewer for this insight. We indeed think that the proximal cause of sperm dysfunction could be the same, but there are components of SD5 that act downstream of Rsp piRNAs. The small difference in drive strength in the SD5 KipfKO experiments might support this hypothesis, although it is also possible instead that drive is influenced by changes in some other piRNAs (from the piRNA clusters or satellites).

      We modified our wording in the first paragraph of the discussion to point out this possibility. Lines 367-370 now reads

      These results suggest that, while SD chromosomes share a target and main drive locus (Sd-RanGAP), the modifiers accumulated on each haplotype may influence the drive mechanisms, either by creating new pathways to drive or acting as tuning knobs on drive strength.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      Summary

      In the presented manuscript Edvalson and Wei et al use Drosophila genetics and NGS experiments to investigate the mechanism of meiotic drive through the Segregation Distorter (SD) system. They reveal that two driving haplotypes seem to function via different mechanisms, with drive through SD-Mad but not SD-5 involving small RNAs produced from the Responder (Rsp) satellite, the target of SD drive. SD-Mad testes displaying drive are characterized by lower levels of Rsp sRNAs compared to non-drive controls as well as SD-5, and the ectopic overexpression of Rsp sRNAs through two distinct mechanisms decrease drive in SD-Mad genetic background, specifically. With this work, the authors are adding an important piece of information to the highly complex SD system, indicating that sperm killing is likely achieved by different mechanisms in different SD haplotypes, despite sharing a common driver.

      Major comments

      Fig1C: It might be interesting to show the fold change between SD-Mad and SD-MadRev in addition to what is displayed. Moreover, can the authors comment on what might be causing the increased smRNA counts for 38C2? Is this because R16 has particularly low 38C2 values?

      We appreciate the reviewer's comment concerning the fold change between SD-Mad and SD-MadRev. We have made a figure showing the difference between and put it in Figure S1.

      We suspect that the expression difference in 38C2 between the R16 heterozygotes and SD heterozygotes may be due to genetic divergence, since these are different 2nd chromosomes. We have added language pointing this out to the manuscript in line 182. The paper now reads:

      *There is no evidence that either 38C2 or Flamenco are involved in SD-mediated drive. *

      Fig1/S1: Could the authors also display the Rsp smRNA counts for all Gla crosses similar to panel 1B? What is the interpretation for the increase in Rsp smRNAs in SD-5/Gla relative to R16/Gla but the lack of such an increase in the SD-5/iso1 vs R16/iso1 comparison? Do SD-Mad and SD-5 induce the same strength of drive against each of the two wildtype chromosomes? Experiments: smRNAseq for SD-MadRev/Gla.

      We have added a plot to Fig S1 to show the abundance of Rsp small RNAs in the Gla background, similar to Figure 1.

      It is difficult to interpret the apparent overabundance of Rsp small RNAs in the SD-5/Gla background. Because differences in Rsp smRNA abundance for SD-5 are inconsistent between the Iso1 and Gla background, our interpretation is that SD-5 is not manipulating Rsp levels. The apparent overabundance of Rsp in the Gla background could be due to an epistatic interaction between Rsp and other components of that particular background. Consistent with this interpretation, the SD-Mad induced reduction of Rsp smRNAs in the Gla background is less dramatic than in the Iso1 suggesting that something about that background is increasing Rsp expression slightly when paired with an SD chromosome.

      Fig1: The authors note changes in smRNA levels for other satellites as well as piRNA clusters but do not give any interpretation to this observation. Are they meaningful? Should they be attributed to genetic background?

      Our interpretation of the observation that some satellites or piRNA clusters are differentially expressed is that these differences are likely due to epistatic effects from the different 2nd chromosomes used in the study or are incidental to mechanism of SD.

      FigS2: Same question also for the deregulated TEs: do they share sequence features with Rsp or are they overrepresented in the clusters that change? Are these explained by differences in insertions between genotypes? Do their total RNAseq values change in any way? What do the percentages in line 162 correspond to? Number of TEs that are deregulated? At which cutoff? It might be informative to compare the data to a cross between driver and R16, or even better the SD-MadRev control. Experiments: totRNAseq for SD-MadRev crosses and optionally crosses to R16.

      The Rsp repeat unit does not share significant homology to portions of the genome outside of the pericentromere of 2R with the exception of ~6-12 copies in the intron of Ago3.

      As far as TEs are concerned, we surprisingly don't see a strong correlation between piRNA cluster content, dysregulation, and TE transcript abundance. For example, in the SD/Gla backgrounds the total RNA for R1, R2, IGS, and Tc1-Mariner family TEs is down regulated. However, the only major piRNA cluster that is upregulated in both SD/Gla backgrounds (80F) is not enriched for TE fragments matching any of those 4 families. One thing we can note is that the definition of the major piRNA clusters are given in relation to the Iso1 genome which may differ from that of our experimental backgrounds. Without long read resolved genomes for our specific experimental lines generated at the same time as the RNA samples it is difficult to determine how expression at the major piRNA clusters and the corresponding TEs are related. We have described this lack of a correlation in lines 210-217 in the text along with our interpretation for why this could be. The paper now reads:

      On the other hand, we did find some differences in repetitive elements related to rDNA (R1, R2, and IGS) and Tc1-Mariner family TEs (all backgrounds; Figure S6). Interestingly, there was no correlation between the expression of TEs and the expression of piRNA clusters that contain fragments of these TEs in the total RNA, nor was there any correlation between the small RNAs from piRNA clusters and the total RNAs for those TEs. PiRNA clusters are usually defined in one isolate of Iso1: rapid turnover of TEs and piRNA sources could explain why we do not see a correlation between piRNA cluster expression and TE expression in our backgrounds.

      We investigated differences in TE and piRNA cluster expression in our SD-Mad/Iso1 vs SD-MadRev/Iso1 comparison, but a lack of power due to inter-sample variation prevents us from confidently making any assessments on any TEs or piRNA clusters in that comparison. We did however generate additional gene level transcriptomic data using 3' Digital Gene Expression to bolster our confidence in the totRNA data and found some interesting genes that were in the top most differentially expressed. We have noted those genes in lines 276-287 which read:

      To identify genes that might interact to cause drive, we compared the gene expression of SD-Mad/Iso1 to SD-MadRev/Iso1. These genotypes only differ by the presence of the main drive locus, Sd-RanGAP. We performed both totRNA and 3' Digital Gene Expression (DGE) RNA sequencing and examined the overlap in differential expression between the totRNA and DGE sequencing. There are 69 differentially expressed genes where the DGE comparison is significant (PDGE {less than or equal to} 0.01), and the sign of the Log2FC of the totRNA matches that of the DGE. Among this set of differentially expressed genes, 57 show at least a 50% difference in gene expression (absolute Log2FC value of at least 0.58 in DGE). These genes are not enriched in any Reactome gene sets. The top 20 most differentially expressed genes consists of 9 lncRNAs (3 anti- sense RNAs) and 11 protein coding genes: 8 of which are uncharacterized. The 3 characterized genes are Artemis (Arts), Gr61a, and Tono (Figure S98, Supplemental File 1).

      We discuss two of these genes in further detail in the discussion in lines 476-486 which read:

      First, Tono, a BTB zinc finger-containing transcription factor is upregulated (Log2FCDGE = 1.7) in all SD-Mad comparisons. Tono plays a role in regulating transcription in muscle cells in response to mechanical pressure (Zhang et al. 2024) but also shows enrichment in male germ cells (Li et al. 2022). The putative DNA-binding capacity and ability to form nuclear condensates (Zhang et al. 2024) makes this an interesting candidate gene for interacting with the Rsp satellite. Second, the importin-4 ortholog, Artemis (Arts), which facilitates Ran-mediated import of H3 and H4 is overexpressed in SD-Mad (Log2FCDGE = 2.5). Interestingly, Arts expression is antagonistic to male fertility (VanKuren and Long 2018). Also of note, Apollo, a duplicate of Arts which supports male fertility (VanKuren and Long 2018) is downregulated (Log2FCDGE = -0.6) though it is not in the top-most differentially expressed genes.

      Figure S3: Am I reading the PCA plots right in that there are very few gene expression changes when the drivers are in iso1 background but much more in the Gla background? Comment on possible explanations for that. Please indicate the number of significantly changed genes in each comparison. Again, are these changes correlated between the two drivers or can they be attributed to genetic background of Gla vs R16? Would it be interesting to see how SD-Mad/Gla and SD-5/Gla gene expression profiles compare? Experiment: totRNAseq for SD-MadRev crosses.

      There did tend to be more differences in the Gla background compared to Iso1. This difference can best be explained by inter-sample variation in the SD-Mad/Iso1 background which we see in the PCA plot in Fig S4A. Another reason for the difference could be that the Gla and Iso1 chromosomes are very different from each other which prevents us from making any 1-to-1 comparisons between the SD/Iso1 and SD/Gla backgrounds. We generally avoid comparing between genetic backgrounds for this reason unless they share differences as these are more likely related to drive.

      In Figure S5A it seems that totalRNA levels of Rsp are strongly increased in SD-Mad/Gla but not in SD-Mad/iso1. The iso comparison (less piRNAs but same transcript) could indicate that it is actually transcription of the Rsp that is affected here. This is even pointed out in line 205 without discussion of the fact that the Gla comparison (less piRNAs but more transcript) would rather indicate that transcription is intact, but processing into piRNAs is defective. Could this be clarified using FISH as in Figure S8? If true, SD-Mad/Gla should have much more FISH signal than SD-Mad/iso1. Either way, this discrepancy should be further discussed. Experiments: comprehensive smFISH panel for all crosses (including SD-MadRev).

      The reviewer makes an excellent point. Why would Rsp long RNAs be overexpressed in the SD-Mad/Gla background? Earlier we noted that in the Gla background specifically the genotypes that contain an SD chromosome seem to have a higher level of Rsp small RNAs than we might expect given our Iso1 results. We conclude that this is likely due to an epistatic interaction between the 2nd chromosomes used in the study and the rest of the chromosomes. This interpretation could extend to the long noncoding precursors as well.

      Further, although the difference between SD-Mad/Gla is significant and SD-5/Gla is not, they do move in the same direction. This is also true in the Iso1 backgrounds but in the opposite direction. Given an interpretation that Rsp expression is higher than expected in the SD/Gla background due to epistatic effects, it becomes clearer that changes in long RNA abundance are related to changes in small RNA abundance though not perfectly indicative. However, due to lower count levels for Rsp in the totRNA, we do not have the power to confidently draw that conclusion.

      In general, the totRNA profiles of repeats don't seem to correlate well between the genotypes (iso vs Gla crosses, neither for SD-5 nor for SD-Mad). Is this because values are in general small and/or replicates don't correlate? Should these data even be considered? Also panels 2A and S5C are very different from each other. The additional comparison with the SD-MadRev allele crossed into both Iso1 and Gla should give additional insight. Experiment: totRNAseq for SD-MadRev crosses.

      The reviewer brings up a good point. While some repetitive elements had relatively small counts in the totRNA (like Rsp) most had adequately high counts. But these differences are to some degree expected. Although the other chromosomes are controlled for, the second chromosomes are different by design including the two SD haplotypes. In this context, similarities between the two haplotypes may be helpful in determining some unifying aspects of the SD mechanism but differences could be incidental to the genotype and not necessarily related to SD.

      It may be generally informative to set the sRNA and RNA comparisons into perspective, for example by including the comparison of SD-Mad crosses versus SD-MadRev crosses to exclude unrelated genetic background components as much as possible.

      The reviewer is correct here. Differences in the transcriptomes of SD-Mad and our revertant are much more likely due to the drive phenotype. Due to variation between SD-Mad total RNAseq replicates, we have substantially less power when comparing SD-Mad/Iso1 to SD-MadRev/Iso1. We therefore generated new data to address this point: we did digital gene expression for three biological replicates of SD-Mad/Iso-1 and SD-MadRev/Iso1. We described the results of this new analysis above.

      FigS6: I assume this is given, but as it is not specified: is the directionality of differential expression taken into account here? Or could it be significantly up in one and down in the other? Please specify / adjust color scale to allow this distinction.

      This is a good point. We have modified the figure to not only indicate significance but also direction and magnitude.

      FigS8: Please add a scale bar for all images. 1.688 is labeled as 359 in the legend, please unify or/and explain nomenclature. Consider adding a nuclear outline based on DAPI. It looks like 1.688 is actually more different between control and SD-Mad/Iso than Rsp. Could the authors comment on this? In the text the authors mention that these experiments were done for both SD-Mad and SD-5 heterozygotes, but only the SD-Mad data are shown.

      The most abundant component of 1.688 repeats is the 359bp repeat, which is used as a proxy for 1.688 and our 359-bp probe cross hybridizes with other abundant variants of 1.688 on chromosome 3. We agree, there does seem to be some differences in the 1.688 RNA FISH, however we do not yet have evidence that 1.688 is related to the drive phenotype. We have expanded that figure (now supplemental figure 7) with multiple images for each genotype to demonstrate the lack of change in Rsp and 1.688 localization. We have added an explanation of the nomenclature.

      The reference to SD-5 in the text was made in error. We do not have RNA FISH images of SD-5/Iso1 heterozygotes. We've modified the text to reflect this.

      FigS9B: What does the y-axis label mean? Fold change relative to what? Is this not displaying counts?

      This is a good catch by the reviewer. The y-axis is mislabeled and should read "TPM". We have made this change.

      To set the KipfKD/KO data in context, please give also the k value for SD-MadRev and compare the smRNA values in this context to the data displayed in F1B. Experiment: drive analysis for SD-MadRev.

      Our basis for concluding that Rsp smRNA overexpression may reduce drive strength is in demonstrating that kipfKO is sufficient to rescue wild type sperm in driving backgrounds. We did not introduce KipKD (or KO) to the SD-MadRev background because this chromosome does not drive.

      The note that the 3XP3-dsRed cassette needs to be flipped out for Rsp overexpression to influence drive is interesting. It would be great if the authors could show a more detailed scheme of the structure of this insertion including the directionality of the promoter relative to the Rsp fragment and the rest of cluster 38C (including dm6 coordinates perhaps). Small RNA sequencing compared to totRNA sequencing should reveal if the transcription or the processing into piRNAs of the inserted piece is affected, and if more of the 38C piRNAs are affected. Genic transcription has been previously observed to limit Rhino-dependent piRNA production from piRNA clusters (Andersen et al 2017). It might be of interest to the general piRNA community to see how cluster output is influenced through the integration of an internal genic promoter.

      We agree that this is an interesting result. We have added more detail to Fig 4A to indicate directionality and genomic location of the insert in terms of dm6.

      Figure panel 4A should be adjusted to include annotations of the black boxes and to give genomic locations. It is unclear what the blue brackets mean, and where exactly the insertion took place. Are the attP sites relevant for the experiments? It might be nice to see a piRNA profile over the locus, to put the levels of additional Rsp piRNAs into perspective.

      We have removed the black boxes from the schematic as they were only there as an aesthetic choice. We have indicated where exactly the insertion was made. The attP sites are there for future experimental flexibility.

      Minor comments

      Figure 3B: fold change of satellite RNA is shown. It might be obvious that the fold change relates to KipfKO / WT but this should be stated explicitly. What is the genetic background here?

      Thank you for the comment. We added information on the genetic background in the figure.

      Figure legends should be extended for clarity throughout the manuscript in main and supplementary figures. All color codes and abbreviations as well as samples / genotypes and assay used should be clearly explained. Few examples include: F1B: smRNA or totalRNA? F3B: fold change relative to what? F4B: what are these data relative to? F4C: smRNA or totalRNA? S2: Is this smRNAseq? Further description of the color code in the volcano panels would be desirable. FS3: typo in A-B should be A-D. Fold changes relative to what. Etc.

      Thank you for these helpful suggestions. We have edited the figure legends as suggested to improve the clarity. We appreciate the feedback.

      The abbreviation for Kipferl is kipf, not kip.

      Thank you for pointing this out, we have made the corrections.

      I don't understand the sentence on lines 310-312.

      We agree that sentence was confusing. We replaced it with:

      "Identifying potential proteins that interact with Rsp may therefore provide important clues about why satellites like Rsp are targets of drive."

      **Referee cross-commenting**

      I agree with the other reviewer's assessments

      Reviewer #3 (Significance (Required)):

      General assessment

      This study of a highly complex and poorly understood drive system adds a very interesting piece to the puzzle of understanding the interplay between a RanGAP duplication and a large satellite array. It's strengths lay in the use of genetics tricks to modify drive (SD-MadRev allele, KipfKO, Rsp cluster insertion). The main weakness of the study is the relatively low correlation of several observations between drive crosses to the Iso1 and Gla lines and lack of explanations thereof. Neither gene nor repeat expression seem to give a convincing overlap in any direction.

      Furthermore, it is interesting that SD-Mad and SD-5 have such different dependencies on Rsp sRNA. While outside the scope of this work, it would be very interesting to see how other drive haplotypes behave: is SD-5 the exception or is it SD-Mad (as the authors have also wondered in the discussion). Such additional comparisons may clarify also the discrepancies in RNAseq.

      Advance

      While it has been previously shown by the same group that Rsp satellites give rise to smRNAs through the piRNA pathway, it is to my knowledge unclear how and if these smRNAs influence drive. This study thus presents a conceptual advance in that it demonstrates that the role of Rsp smRNAs is not shared among driving haplotypes.

      Audience

      This study is relevant for a highly specialized audience interested in meiotic drive. It contributes to the understanding of the SD system and may serve as a basis for future research in this area. In addition, results reported in Figure 4 may be of peripheral interest for the Drosophila piRNA community for technical interests.

      This reviewers expertise: Drosophila, piRNA pathway, heterochromatin, sRNA

      This reviewers limitations: nuclear-cytoplasmic trafficking, cytoskeleton

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      Referee #3

      Evidence, reproducibility and clarity

      Summary

      In the presented manuscript Edvalson and Wei et al use Drosophila genetics and NGS experiments to investigate the mechanism of meiotic drive through the Segregation Distorter (SD) system. They reveal that two driving haplotypes seem to function via different mechanisms, with drive through SD-Mad but not SD-5 involving small RNAs produced from the Responder (Rsp) satellite, the target of SD drive. SD-Mad testes displaying drive are characterized by lower levels of Rsp sRNAs compared to non-drive controls as well as SD-5, and the ectopic overexpression of Rsp sRNAs through two distinct mechanisms decrease drive in SD-Mad genetic background, specifically. With this work, the authors are adding an important piece of information to the highly complex SD system, indicating that sperm killing is likely achieved by different mechanisms in different SD haplotypes, despite sharing a common driver.

      Major comments

      Fig1C: It might be interesting to show the fold change between SD-Mad and SD-MadRev in addition to what is displayed. Moreover, can the authors comment on what might be causing the increased smRNA counts for 38C2? Is this because R16 has particularly low 38C2 values?

      Fig1/S1: Could the authors also display the Rsp smRNA counts for all Gla crosses similar to panel 1B? What is the interpretation for the increase in Rsp smRNAs in SD-5/Gla relative to R16/Gla but the lack of such an increase in the SD-5/iso1 vs R16/iso1 comparison? Do SD-Mad and SD-5 induce the same strength of drive against each of the two wildtype chromosomes? Experiments: smRNAseq for SD-MadRev/Gla.

      Fig1: The authors note changes in smRNA levels for other satellites as well as piRNA clusters but do not give any interpretation to this observation. Are they meaningful? Should they be attributed to genetic background?

      FigS2: Same question also for the deregulated TEs: do they share sequence features with Rsp or are they overrepresented in the clusters that change? Are these explained by differences in insertions between genotypes? Do their total RNAseq values change in any way? What do the percentages in line 162 correspond to? Number of TEs that are deregulated? At which cutoff? It might be informative to compare the data to a cross between driver and R16, or even better the SD-MadRev control. Experiments: totRNAseq for SD-MadRev crosses and optionally crosses to R16.

      Figure S3: Am I reading the PCA plots right in that there are very few gene expression changes when the drivers are in iso1 background but much more in the Gla background? Comment on possible explanations for that. Please indicate the number of significantly changed genes in each comparison. Again, are these changes correlated between the two drivers or can they be attributed to genetic background of Gla vs R16? Would it be interesting to see how SD-Mad/Gla and SD-5/Gla gene expression profiles compare? Experiment: totRNAseq for SD-MadRev crosses.

      In Figure S5A it seems that totalRNA levels of Rsp are strongly increased in SD-Mad/Gla but not in SD-Mad/iso1. The iso comparison (less piRNAs but same transcript) could indicate that it is actually transcription of the Rsp that is affected here. This is even pointed out in line 205 without discussion of the fact that the Gla comparison (less piRNAs but more transcript) would rather indicate that transcription is intact, but processing into piRNAs is defective. Could this be clarified using FISH as in Figure S8? If true, SD-Mad/Gla should have much more FISH signal than SD-Mad/iso1. Either way, this discrepancy should be further discussed. Experiments: comprehensive smFISH panel for all crosses (including SD-MadRev).

      In general, the totRNA profiles of repeats don't seem to correlate well between the genotypes (iso vs Gla crosses, neither for SD-5 nor for SD-Mad). Is this because values are in general small and/or replicates don't correlate? Should these data even be considered? Also panels 2A and S5C are very different from each other. The additional comparison with the SD-MadRev allele crossed into both Iso1 and Gla should give additional insight. Experiment: totRNAseq for SD-MadRev crosses.

      It may be generally informative to set the sRNA and RNA comparisons into perspective, for example by including the comparison of SD-Mad crosses versus SD-MadRev crosses to exclude unrelated genetic background components as much as possible.

      FigS6: I assume this is given, but as it is not specified: is the directionality of differential expression taken into account here? Or could it be significantly up in one and down in the other? Please specify / adjust color scale to allow this distinction.

      FigS8: Please add a scale bar for all images. 1.688 is labeled as 359 in the legend, please unify or/and explain nomenclature. Consider adding a nuclear outline based on DAPI. It looks like 1.688 is actually more different between control and SD-Mad/Iso than Rsp. Could the authors comment on this? In the text the authors mention that these experiments were done for both SD-Mad and SD-5 heterozygotes, but only the SD-Mad data are shown.

      FigS9B: What does the y-axis label mean? Fold change relative to what? Is this not displaying counts?

      To set the KipfKD/KO data in context, please give also the k value for SD-MadRev and compare the smRNA values in this context to the data displayed in F1B. Experiment: drive analysis for SD-MadRev.

      The note that the 3XP3-dsRed cassette needs to be flipped out for Rsp overexpression to influence drive is interesting. It would be great if the authors could show a more detailed scheme of the structure of this insertion including the directionality of the promoter relative to the Rsp fragment and the rest of cluster 38C (including dm6 coordinates perhaps). Small RNA sequencing compared to totRNA sequencing should reveal if the transcription or the processing into piRNAs of the inserted piece is affected, and if more of the 38C piRNAs are affected. Genic transcription has been previously observed to limit Rhino-dependent piRNA production from piRNA clusters (Andersen et al 2017). It might be of interest to the general piRNA community to see how cluster output is influenced through the integration of an internal genic promoter.

      Figure panel 4A should be adjusted to include annotations of the black boxes and to give genomic locations. It is unclear what the blue brackets mean, and where exactly the insertion took place. Are the attP sites relevant for the experiments? It might be nice to see a piRNA profile over the locus, to put the levels of additional Rsp piRNAs into perspective.

      Minor comments

      Figure 3B: fold change of satellite RNA is shown. It might be obvious that the fold change relates to KipfKO / WT but this should be stated explicitly. What is the genetic background here?

      Figure legends should be extended for clarity throughout the manuscript in main and supplementary figures. All color codes and abbreviations as well as samples / genotypes and assay used should be clearly explained. Few examples include: F1B: smRNA or totalRNA? F3B: fold change relative to what? F4B: what are these data relative to? F4C: smRNA or totalRNA? S2: Is this smRNAseq? Further description of the color code in the volcano panels would be desirable. FS3: typo in A-B should be A-D. Fold changes relative to what. Etc.

      The abbreviation for Kipferl is kipf, not kip.

      I don't understand the sentence on lines 310-312.

      Referee cross-commenting

      I agree with the other reviewer's assessments

      Significance

      General assessment

      This study of a highly complex and poorly understood drive system adds a very interesting piece to the puzzle of understanding the interplay between a RanGAP duplication and a large satellite array. It's strengths lay in the use of genetics tricks to modify drive (SD-MadRev allele, KipfKO, Rsp cluster insertion). The main weakness of the study is the relatively low correlation of several observations between drive crosses to the Iso1 and Gla lines and lack of explanations thereof. Neither gene nor repeat expression seem to give a convincing overlap in any direction.

      Furthermore, it is interesting that SD-Mad and SD-5 have such different dependencies on Rsp sRNA. While outside the scope of this work, it would be very interesting to see how other drive haplotypes behave: is SD-5 the exception or is it SD-Mad (as the authors have also wondered in the discussion). Such additional comparisons may clarify also the discrepancies in RNAseq.

      Advance

      While it has been previously shown by the same group that Rsp satellites give rise to smRNAs through the piRNA pathway, it is to my knowledge unclear how and if these smRNAs influence drive. This study thus presents a conceptual advance in that it demonstrates that the role of Rsp smRNAs is not shared among driving haplotypes.

      Audience

      This study is relevant for a highly specialized audience interested in meiotic drive. It contributes to the understanding of the SD system and may serve as a basis for future research in this area. In addition, results reported in Figure 4 may be of peripheral interest for the Drosophila piRNA community for technical interests.

      This reviewers expertise: Drosophila, piRNA pathway, heterochromatin, sRNA

      This reviewers limitations: nuclear-cytoplasmic trafficking, cytoskeleton

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      Referee #2

      Evidence, reproducibility and clarity

      I have only one request: I found it unclear whether the authors were referring to small RNAs or their precursor (long RNA). By reading the text carefully, I could deduce that Fig1A/Table S2 represent the small RNA sequencing, while FigS3A represents total RNA seq (detecting precursor). However, the labeling in the Fig1A and Table S2 only says 'piRNA cluster' or 'Rsp' (without clarifying 'piRNA from piRNA cluster' or 'piRNA from Rsp'), and it took quite some time for me to understand which Fig/data is smallRNA vs. longRNA.

      Referee cross-commenting

      I agree with other reviewers' comments, which all seem to be reasonable.

      Significance

      This manuscript by Edvalson et al. describes their study on SD (segregation distorter) meiotic drive system, examining the role of piRNA derived from Rsp satellite. Although the exact mechanism of drive is still unknown, this study represents a significant step forward in understanding SD-mediated drive.

      By using two SD alleles (SD-5 and SD-Mad), they show that Rsp-derived piRNA is depleted in SD-Mad. The authors used total RNA sequencing/small RNA sequencing mutants and carefully designed controls (such as deletion of Sd-RanGAP) to reach the model that Rsp-derived piRNA is involved in SD-Mad-mediated drive. The result that kipferl depletion (that lead to sat DNA expression) rescues SD-Mad's drive phenotype is very interesting. This supports that the decreased Rsp piRNA indeed corresponds to SD-Mad-mediated drive. They further back up this idea by overexpressing Rsp.

      Interestingly, SD-5 was not impacted by changes in Rsp expression. Based on this result, the authors state that there are mechanistic variations in the same (SD) drive system. This statement is certainly justified by the data, but I cannot help wondering there might be a unifying mechanism that explains both SD-5 and SD-Mad. I am not suggesting to edit the manuscript or add the discussion: but do they have any speculations on this? For example, SD-5 is simply epistatic to Rsp piRNA production? For example, SD-RanGAP > SD-Mad (some gene on SD-Mad inversion) > Rsp piRNA production > SD-5 > sperm killing?

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      Referee #1

      Evidence, reproducibility and clarity

      Summary: Edvalson and colleagues use transcriptomics, cell biology and genetics to study variation between segregation distorter (meiotic drive) strains and find several important results. These include apparent suppression of small RNAs mapping to responder (the drive target) in one of the lines, a general pattern of differential expression consistent with the drive mechanism being upstream of sperm individualization (where defects have been seen previously), and genetic confirmation that perturbing Rsp expression can influence the strength of drive.

      Major comments: I found the total RNA sequencing experiment a bit oddly presented. This is partly because it was in the middle of the results (might fit better first), partly because few specific genes were discussed (this might be appropriate given then question, but maybe the question should be more clearly stated), and the complexity of the approach (WCGNA + PANGEA) and how it all fits together. I suggest working to clarify the main points of this section (which are a bit different than the main focus of the Rsp work).

      Minor comments:

      Abstract - Probably worth mentioning Sd-RanGAP here, even if you are using it as a straw man. I agree that the specific mechanism is not known, but some of the genetics are established.

      Line 80 and elsewhere - it would be helpful to be specific here - you are looking at both small and total RNA

      Fig 1B - is there a reason not to show the values of the replicates here? It would be more transparent.

      Line 139 - does the experimental design control for 1.688 genomic copy number? Where is it located?

      144-146 - this could be written clearer, and I think it should only refer to 1C, not 1B. Part of the issue is that there are several repeats not discussed, and it isn't clear what is happening with them. I suggest expanding this description so it is more clear.

      Line 161 - what do you mean (specifically) by "repetitive loci"?

      193-203 - This is an important finding that is somewhat lost in trying to keep track of WCGNA and PANGEA and the different Modules. I suggest clarifying to drive home the point that differential expression appears to start prior to individualization, which suggests and earlier mechanism of drive.

      Fig 3B & 3C, Fig 4 - same as 1B, is there a reason not to show the actual data points?

      Line ~245 - was the same experiment done with SD-5? (as you do below for Rsp overexpression)

      Referee cross-commenting

      I agree with the comments as well.

      Significance

      This is a strong paper that moves the field forward, even if it leaves questions still to be answered (why the difference between drivers? what is the mechanism? how is rsp interacting with drive?

      Several findings move the field forward: the Rsp small RNA results, the differential expression hinting at a molecular mechanism that is upstream of sperm individualization.

      The audience is moderately broad. Genetic conflict is gaining in general interest, but aspects of this will be mostly interesting to the hardcore drive crowd.

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      Reply to the reviewers

      Reviewer #1

      Minor comments 1) The authors suggest that the weak 4th protomer in the HCMV UL52 3-mer map is a consequence of flexibility. This may be the case, but it may also be the case that the class is polluted with 4-mer particles leading to reduced occupancy. Erasing the weak density and running a multi-model 3D classification providing the erased 3-mer and a 4-mer starting map may separate these.

      We performed additional analysis (i.e., 3-mer and 4-mer particles were combined into a multi-class ab initio reconstruction followed by multi-class heterogenous refinement) and found that the original 3-mer map was a mixture of 3-mer and 4-mer states.

      We have updated Fig. 2a, Supplementary Fig. 2, Supplementary Fig. 3, Supplementary Table 1, Supplementary Movie 1, and removed the discussion of the weak protomer in the 3-mer map from the results section. We have updated our EMDB and PDB depositions accordingly.

      • 2) I found the supplemental figure to show the DNA in the tripentamer map too small, this is an interesting finding and should be shown more clearly.*

      We have increased the size of Supplementary Fig. 6 and moved the figure caption to another page to accommodate this enlargement.

      Reviewer #2

      *Major issues 1) There is a high probability that the tripentamer is an artifact of the cross-linking. Because of this, it'd be great to know more about the cross-linking reaction, ideally mass spec identification and quantification of cross-links. This would also address the authors' speculation of contacts that stabilize the tripentamer. *

      Crosslinking is a commonly used technique to stabilize complexes that are observed through other means but do not survive the cryo-EM vitrification process. In an EMSA experiment (Supplementary Fig. 4a), UL32 binds 30 bp DNA and migrates slower than when bound to a 10 bp probe, consistent with formation of a supra-pentameric complex. The samples in the EMSA gels are not crosslinked. Additionally, an SDS-PAGE gel of the crosslinked product used for cryo-EM showed tight bands at molecular weights expected for oligomers, supporting specific crosslinking (Supplementary Fig. 4b). These results suggest that crosslinking stabilizes a species that can form but is relatively unstable in solution.

      Moreover, the author's claim "However, mutation of K532A/C535A reduced infectious virion production by half (Fig. 4b), suggesting that the tripentamer interface may play a role in the viral life cycle." Seems to be an overreach. Perhaps this is semantics but the data just show that these residues play a role in viral replication (albeit not a huge role based on the modest effect).

      We have modified the title of the results section (Line 216-217) to state that "Residues at the tripentamer interfaces contribute to infectious virion production in HSV-1" as well as Line 234 and 241 to indicate that the residues play a role in the viral life cycle.

      2) The density for the potential DNA does not look very convincing, although it still remains the strongest hypothesis. The authors should try to strengthen their argument. Does this putative DNA contact residues that they show are necessary for viral replication? Showing seq conservation on the structure could help their argument for the shared function of DNA-binding.

      The DNA likely contacts conserved residues at the base and midsection of the central channel (residues R302, R301, R293, K289, R580, R579, R572; see Fig. 6a). We have shown that these residues are important for the production of infectious virions (Fig. 6c): even a single point mutation (R572A) decreased production of infectious virus particles by more than 90%, and double and triple point mutants (R579A/R580A, K289A/R293A/R301A) eliminated production of infectious virus. Sequence conservation of these charged residues in the central channel regions is shown in Supplementary Fig. 1d, f.

      3) My last major issue is stylistic and concerns the descriptions of cryoEM structures. I found that the paper was a bit of challenge to read when the authors would introduce each structure. It was a bit of a slog to get through. Descriptions of the structures veered off into overly detailed comparisons that required constant comparison with the figure and didn't really advance my understanding past "the outer surfaces of the three orthologs are different." This masked the more interesting aspects of the authors' findings. Perhaps this could be summarized in supplementary figures or a table. Because this is a stylistic suggestion, the authors should feel free to ignore this request.

      We appreciate the reviewer's concerns about accessibility, but we are excited that these structures allowed us to thoroughly describe the convergent and divergent structural features across the Herpesviridae and hope that our in-depth analysis will allow for detailed mechanistic follow-up.

      *Minor comments 1) The descriptions of structure determination in the text were often unclear. For example, "In the 3-mer map, a poorly-resolved fourth protomer is visible at low contour levels, suggesting that an additional protomer is present but highly flexible in this class (Supplementary Fig. 3a)." Alternatively, it could be that the classification algorithm wasn't able to fully separate particles that were 3-mers from the 4mers. *

      The reviewer is correct. As described above (Reviewer #1 comment 1), we performed additional analysis and found that the original 3-mer map was a mixture of 3-mer and 4-mer states. We have updated Fig. 2a, Supplementary Fig. 2, Supplementary Fig. 3, Supplementary Table 1, Supplementary Movie 1, the EMDB and PDB depositions, and removed the discussion of the weak protomer in the 3-mer map from the results section.

      *When describing the structure determination of the HSV1 accessory factor, the authors describe no other particles other than the tripentamer. Were there other particles observed? It'd be a bit surprising that all of the protein adopted the tripentamer state. *

      We agree that this result is striking. We picked particles using a 'blob picker' to avoid introducing template bias and found that the tripentamer is the predominant species. Below we show the results of 2D classification of blob picked particles (classes sorted by particle number; obvious junk classes excluded for clarity). There is one class that suggests a pentamer, but template picking with a pentamer template (based on ORF68) did not yield a pentamer class.

      Additionally, as we describe in the results section and show in Supplementary Fig. 6a, further processing of the consensus UL32 map showed that 60% of particles formed a complete tripentamer (i.e., 15-mer) while other the remaining 40% formed incomplete tripentamers, missing one or more protomers (e.g., 17% of particles formed a 14-mer).

      Was symmetry applied, particularly for the tripentamer that appears to have C-3 symmetry? This is in materials and methods but not clear why it isn't mentioned when describing the structure determination and results.

      No symmetry was applied in the reconstruction for either UL32 or UL52. While we previously noted this in the methods section and in Supplementary Table 1, we have added this information to the results section (Line 169-170), the Fig. 3 legend, and cryo-EM processing figures (Supplementary Figures 2, 5, 6) for clarity.

      2) Throughout the paper, the authors use the word "remodel" to describe structural differences between orthologs. However, this word usually carries the implication of conformational rearrangement within a protein, and not across orthologs. Please consider a different description.

      We agree with the reviewer and have removed the term "remodel" throughout the manuscript text (i.e., Lines 116, 118, 120, 122, 302, 306) and from Supplementary Figures 1, 3, and 5.

      3) Figure 2F is confusing and difficult to interpret. It seems that the main point is that these interfaces are conserved, which might be more easily displayed as a standard sequence conservation score mapped onto the structure. I'm also not sure that this figure is necessary as a main figure and could be supplemental.

      We agree that the conservation could also be shown this way and have added labels to universally conserved residues of the protomer interface to Supplementary Fig. 1b, c. We have also moved Fig. 2f to the supplement (now Supplementary Fig. 2g).

      • 4) The authors write "UL32 bound to the shortest probe tested (10 bp, Supplementary Fig. 4a)." This implies that ONLY the shortest probe is bound and that others are not bound. Consider rephrasing.*

      We have rephrased to clarify at all probes tested, included the shortest, bound DNA (Line 153).

      • 5) Frustum is misspellt. ;)*

      Thank you. Spelling has been corrected (Line 185).

      6) In the discussion, the authors speculate that the variability of the outer surface is due to "virus- or host-specific interactions". I'm confused by "host-specific interactions", because the host is the same for all three viruses. Perhaps the authors mean that the different accessory factors could interact with different host factors? If so, are the authors making a Red Queen argument? If so, it'd be pretty cool to do dN/dS analysis to test that hypothesis.

      The reviewer is correct in that all three viruses (HSV-1, HCMV, KSHV) infect the same host; however, they replicate in different cell types, which could potentially express different host factors. We have no evidence to support this hypothesis and intended to propose that UL32 and UL52 may be interacting/co-evolving with other viral factors required for genome packaging. We have clarified Line 308 to generalize that "these regions are involved in virus-specific interactions".

      To me, this window into evolution of this factor is the biggest advance of the work, and tbh I felt that the authors could lean into this a bit more in the discussion section. Are there any differences in the packaging mechanisms of the different herpes families that can be related to their different behavior? Any other molecular evolution analyses (e.g. dN/dS ratio analysis) that could inform their study?

      We agree that understanding the evolution of the packaging accessory factor is an interesting future area of research. There are differences in capsid structure and occupancy of capsid-associated factors across the herpesvirus family (PMID: 34696343). However, we lack a mechanistic (or structural) understanding of viral genome packaging components across the herpesviruses, raising the possibility that there are differences in packaging mechanisms.

      Interestingly, the further diverged alloherpesviruses and malacoherpesviruses (other families in the order Herpesvirales) do not appear to encode a factor with similar predicted structure to the Herpesviridae packaging accessory factor (PMID: 41902279). It is unclear how the mechanism of packaging differs in the Orthoherpesviridae and whether replication in mammalian/avian/reptilian cells places additional evolutionary pressure on the viral genome packaging mechanism.

      Reviewer #3

      Major comments

      *1) [I]t is not clear whether the structures presented in the manuscript reflect those produced during HCMV or HSV-1 infection. *

      We agree with the reviewer that it is important to consider to what extent purified biomolecules resemble their in vivo counterparts. This criticism can be applied to any ex situ structural analysis. However, our experimental structures allowed us to make testable observations, including the correct assignment of structurally important zinc fingers and the identification of functionally important residues in the central channel.

      2) HCMV UL52 was presented to form two distinct structures, a 3-mer and a 4-mer (Fig. 2a). However, the authors acknowledge that the 3-mer is actually a 4-mer when the threshold for the cryo-EM map is lowered. The density is also visible in the PDB validation report for the 3-mer; EMD-74418.

      Reviewers #1 and #2 were also curious about the 3-mer. As described above, we performed additional analysis that showed that the original 3-mer map was a mixture of 3-mer and 4-mer states. We have updated Fig. 2a, Supplementary Fig. 2, Supplementary Fig. 3, Supplementary Table 1, Supplementary Movie 1, EMDB and PDB depositions, and removed the discussion of the weak protomer in the 3-mer map from the results section.

      *Given that ORF68, BFLF1, and UL32 (Didychuk et al., 2021) form complete pentamer rings, with BFLF1 forming stacked rings, it would seem odd for a protein with conserved function to deviate from a pentamer configuration, suggesting that the structures reported do not reflect the natively produced and functional protein. *

      We agree that this is a surprising finding; we initially anticipated that UL32 and UL52 would also form stable pentameric rings. While this study does not resolve a complete mechanism for this factor, it does provide the first structural evidence for the implications of their poor sequence conservation and lack of complementarity.

      Furthermore, this is not the first example of a conserved herpesvirus factor that possesses different oligomeric states across different subfamily homologs. As mentioned in the discussion, herpesvirus encode a sliding clamp processivity factor (HSV-1 UL42/HCMV UL44/KSHV ORF59) that shares a common PCNA-like fold, but which has varied oligomeric state across these herpesviruses.

      *3) Unlike ORF68 (Didychuk et al., 2021) and UL32 (Suppl. Fig. 4), dsDNA binding experiments were not performed with UL52. Could the partial pentamers simply be poorly formed due to expression in insect cells (mammalian cells were used for protein purification in Didychuk et al., 2021), absence of dsDNA, or inappropriate buffer conditions? Moreover, were the EM grid and vitrification parameters optimized? Grid geometries and chemistries can have profound effects of protein stability especially in the context of the air-water interface, leading to degradation of protein complexes (Glaeser, 2018; D'Imprima et al., 2019). Does UL52 form complexes with dsDNA? Data are shown for the HSV-1 packaging accessory factor. Perhaps dsDNA would stabilize the UL52 pentamer. *

      We have purified ORF68 and homologs from both human and insect cell expression systems, and do not observe changes in oligomeric behavior. We find that ORF68 purified as a stable pentamer from human cells (Didychuk eLife 2021) and from insect cells (this work). We have also recombinantly expressed and purified UL32 from human cells. UL32 was largely monomeric after strep affinity purification (chromatogram below, unpublished), as we report from insect cells (this work, Fig. 1c). We switched to insect cell expression systems because of the easier scalability.

      Our SEC-MALS data (Fig. 1d) shows that purified UL52 does not oligomerize into a pentamer in solution, so the observed sub-pentameric (3-mer/4-mer) assemblies are unlikely to be an artifact of cryo-EM freezing conditions or the air-water interface. We have not tested if UL52 forms complexes with dsDNA, although it likely does; it is possible that this interaction would stabilize a pentamer.

      4) In Didychuk et al., 2021, HSV UL32 is shown to form pentameric rings; negative stained 2D class averages were generated from tagged protein (twin strep tag), produced in mammalian cells (HEK293T), and not purified using size exclusion chromatography. In the present study HSV UL32 was not observed to form pentameric complexes "We first attempted to visualize the pentameric species by negative stain electron microscopy but were unable to identify particles of the expected dimensions." However, it is not clear why this was the case. If the pentameric structures were readily produced in previous experiments, why was cross-linking needed in the current study? As such, the tripentamer complexes seem artifactual in nature.

      While a sufficient number of particles were observed in a pentameric state to do 2D class averages in the eLife paper, this was not the dominant state. The results we report in this work are consistent with those reported in the eLife paper. Reviewer #2 (comment #1) was also concerned about the possibility of a crosslinking artifact: we reproduce our response below:

      "Crosslinking is a commonly used technique to stabilize complexes that are observed through other means but do not survive the cryo-EM vitrification process. In an EMSA experiment (Supplementary Fig. 4a), UL32 binds 30 bp DNA and migrates slower than when bound to a 10 bp probe, consistent with formation of a supra-pentameric complex. The samples in the EMSA gels are not crosslinked. Additionally, an SDS-PAGE gel of the crosslinked product used for EM showed tight bands, supporting specific crosslinking (Supplementary Fig. 4b). These results suggest that crosslinking stabilizes a species that can form but is relatively unstable in solution."

      We have updated Line 148 to clarify this. We have also included a negative stain micrograph, below, in which UL32 pentamers (purified from insect cells) are visible in the absence of crosslinking.

      5) Although the data presented in Fig. 4b suggest that interface residues, K532 and C535, might play a role in the formation of the tripentamer and have a minor role in HSV-1 replication, these experiments are incomplete. Single mutations are needed for each residue to assess their individual contribution to tripentamer formation, evidence for a loss of tripentamer formation is needed, and evidence for protein expression is needed.

      We agree that we have not unambiguously defined the role of the tripentamer, the precise contributions of residues K532 and C535, or defined the contribution of the tripentamer to HSV-1 viral replication. We seek to report this novel structure to lay the basis for future mechanistic work. Reviewer #2 (comment 1) also questioned the role of these residues in HSV-1 replication, and we addressed this by modifying the title of the results section (Line 216) to state that "Residues at the tripentamer interfaces contribute to infectious virion production in HSV-1" as well as Line 246 and 253 to indicate that the residues play a role in the viral life cycle.

      Please refer to Supplementary Fig. 7e for a western blot showing that these mutants do not impact UL32 expression. We included explicit references to UL32 expression on Lines 239 and 288.

      *6) In the previous negative stain electron micrographs reported by Didychuk et al., 2021, were the higher order tripentamer complexes seen? *

      We did not observed tripentamers in the Didychuk et al. 2021 negative dataset. Tripentamer formation may be concentration dependent. Negative stain EM carried out at nanomolar concentrations would likely cause dissociation of tripentamers, but cryo-EM and EMSA in our work were carried out at micromolar concentrations and were able to capture the higher order tripentamer.

      • 7) Formation of disulphide bonds between cysteine residues in vitro is not indicative of complexes forming in vivo during replication. What evidence is there for disulphide bond formation between packaging accessory factor pentamers for KSHV, EBV, and LCMV? In the present study, the disulphide bond could form due to proximity as a result of the cross-linking and the presence of molecular oxygen rather than a bona fide enzyme catalysed reaction during herpesvirus replication to generate packaging accessory factor tripentamers. *

      We agree that it is unlikely that disulfide bonds form during infection and have removed this speculation from the manuscript (Line 343-346).

      8) The DNA densities in Suppl. Fig. 6e to 6g are curious. As noted by the authors, the 30mer dsDNAs do not traverse through the central cavity of the pentamer. They appear to make contact with neighboring pentamers, again suggesting that these complexes are artefacts from cross-linking. This should be discussed more thoroughly.

      Please refer to above discussion of crosslinking and Supplementary Fig. 4.

      9) Previously proposed functional roles for ORF68 include a scaffold for terminase assembly, association of the terminase with the portal, generation of initial free ends, or coordination with other replication machinery (Didychuk et al., 2021). Presuming that the new structures for HCMV UL52 and HSV-1 UL32 occur naturally, how do they fit with the previously proposed functional roles of the herpesvirus packaging accessory factor? A more in-depth discussion of this would be valuable.

      The common core fold and pentamer/pentamer-like assemble are common features, as is the conserved, positively-charged central channel. We have added additional discussion of this.

      *Minor comments A lack of page numbers and line numbers made reviewing this manuscript more challenging than necessary. *

      We have included page numbers and line numbers in the revised manuscript.

      *As noted in the 'General comments' section above, ORF68 (3.37Å) and BFLF1 (3.60Å) both form pentamers (Didychuk et al., 2021) and were produced in mammalian systems HEK293T cells. Protein purification in the present study was performed in insect (SF9 or High Five) cells. Does this affect complex stability. Also, the tag was retained for UL32 in Didychuk et al., 2021; could this provide stability of the pentamer in the original studies? *

      As discussed above, we have no evidence to suggest that expression in human vs. insect cell expression systems dramatically changes oligomerization behavior (Reviewer #3, comment 3). N-terminal purification tags were also retained in this study for structural work but were removed for SEC-MALS, which shows that UL32 is likely in concentration dependent equilibrium between (unstable) pentamers and monomers.

      Suppl. Fig. 3 is missing.

      We apologize for this oversight and have included Supplementary Fig. 3.

      *"UL52 has two regions remodeled" The use of the word 'remodeled' is not appropriate in this context as it implies a single protein can form two shapes under different conditions rather than distinct structures between two disparate proteins; UL52 compared to ORF68. This should be rephrased. *

      This was also noted by reviewer 2, and we have removed the term "remodel" throughout the manuscript text (i.e., Lines 134, 138, 140, 337, 341) and from Supplementary Figures 1, 3, and 5.

      *What is the density in the central core of UL52 (Fig. 2a; Suppl. Fig. 2e)? Was any form of focused classification performed to establish the identity of the density within the central pseudocavity? *

      As noted in the manuscript, this density could be which could be attributed to co-purified protein or nucleic acid, or part of the unresolved, negatively charged loop (residues 82-181) interacting with the positively charged central channel. We have done additional analysis of the central channel density (3D classification with a focus mask) and do not resolve any distinct densities, suggesting that the density is very dynamic.

      *Does UL52 bind to dsDNA? To support the hypothesis that the herpesvirus packaging accessory factor has conserved functions across the three subfamilies dsDNA binding experiments should be performed. *

      We have not done this experiment. We think that demonstrating this finding for two of the three herpesvirus subfamilies is sufficient.

      There is no discussion about how these data relate to the previous functional model for ORF68 presented in Didychuk et al., 2021. Do the new data alter the previous functional models?

      The precise mechanistic contribution of the packaging accessory factor remains unknown, and our data do not delineate between the proposed potential roles described in Didychuk et al. 2021. Importantly, our structural information, demonstration of pentameric ring formation, and significance of the positively charged central channel show that the core function of this factor is likely conserved across the virus family. This was not known before our work.

      *There are some interesting grammatical phrases; please address throughout the manuscript. One example - "...a notable shared aspiration..." Proteins do not have aspirations. Please use a more formal scientific statement. *

      We have updated the language on Line 327.

      *Fig. 4b - Statistical analyses missing. Please provide. *

      Fig. 6c - Statistical analyses are missing. Please provide. Protein folding/expression data missing; see Fig. 5C showing mutations that result in poor protein expression.

      Suppl. Fig. 7f - Statistical analyses absent.

      Statistical analysis of the viral complementation in Figs. 4b and 6c has been included. Note that the viral yields reported in Supplementary Fig. 7f were used to calculate complementation efficiency in Figs. 4b and 6c. Protein expression of mutants shown in Fig. 6c was previously included in Supplementary Fig. 7e and is referenced on Lines 288 and 293.

      *Suppl. Fig. 2 and 5 - FSC curves have oddities, especially in the corrected curves. The cryo-EM resolution estimates calculated by CryoSPARC for the UL52 '3-mer' and 4-mer, and UL32 tripentamer are likely overestimated. In the PDB validation files each of the deposited structures has a warning for the resolution estimate "The value from deposited half-maps intersecting FSC 0.143 CUT-OFF 4.31 differs from the reported value 3.32 by more than 10 %", suggesting that the resolution estimates are inaccurate. The authors should provide a resolution estimate using loose masks and generate FSC curves using another software program such as RELION's postprocess to provide resolution estimates. *

      Thank you for bringing this to our attention. The differences in the resolution estimates are a known issue and are highly influenced by the tightness of the mask. In the revised manuscript we have updated the FSC curves to not include auto-tightened masks and revised our resolution estimates. This slightly changed the resolution to 3.29 Å for both UL52 3-mer and 4-mer and to 3.09 Å for the UL32 consensus map. Please also see the local resolution estimation maps in Supplementary Figures 2e and 5e for an illustration of the range of resolutions in each map.

      Suppl. Fig. 6f and 6g - Is there any visible density that might resemble the EGS crosslinking reagent?

      We do not expect to observe density for EGS due to the long flexible linker (~16 Å) between the two reactive groups.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary.

      The manuscript describes the cryo-EM structures of a conserved, necessary, herpesvirus genome packaging accessory factor for human cytomegalovirus (HCMV), UL52, and herpes simplex virus type-1 (HSV-1), UL32. Herpesvirus packaging accessory factors have unknown function but bind dsDNA. The UL52 and UL32 structures revealed a 5-fold symmetry similar to the previous X-ray crystallography structure for Kaposi's Sarcoma-associated herpesvirus (KSHV) ORF68 and the cryo-EM structure of Epstein-Barr virus (EBV) BFLF1. However, HCMV UL52 was reported to form two structures, a 3-mer and 4-mer whereas, HSV UL32 formed a supercomplex of trimeric pentamers (tripentamer) produced by dsDNA binding and crosslinking. Similar to previous studies with ORF68, mutagenesis of HSV-1 UL32 demonstrated the importance of zinc finger residues C297, C308, C544, and H581 for core fold stability and positively charged residues H563, R572 in the central channel in the pentamer for HSV-1 recovery in virus complementation assays. In addition, mutagenesis of K532 and C535 at the tripentamer interface helix reduced virus complementation by 50%. These findings have significant overlap and similarities to previously published experiments and confirm the properties of ORF68 and BFLF1, demonstrating the conserved nature of the required packaging accessory factor for herpesviruses.

      Major comments.

      The manuscript is generally well written with beautifully presented cryo-EM figures. Unfortunately, the new data seem to muddy the water rather than provide clarification about the role or function of the herpesvirus packaging accessory factor. Furthermore, it is not clear whether the structures presented in the manuscript reflect those produced during HCMV or HSV-1 infection. HCMV UL52 was presented to form two distinct structures, a 3-mer and a 4-mer (Fig. 2a). However, the authors acknowledge that the 3-mer is actually a 4-mer when the threshold for the cryo-EM map is lowered. The density is also visible in the PDB validation report for the 3-mer; EMD-74418. Given that ORF68, BFLF1, and UL32 (Didychuk et al., 2021) form complete pentamer rings, with BFLF1 forming stacked rings, it would seem odd for a protein with conserved function to deviate from a pentamer configuration, suggesting that the structures reported do not reflect the natively produced and functional protein. Unlike ORF68 (Didychuk et al., 2021) and UL32 (Suppl. Fig. 4), dsDNA binding experiments were not performed with UL52. Could the partial pentamers simply be poorly formed due to expression in insect cells (mammalian cells were used for protein purification in Didychuk et al., 2021), absence of dsDNA, or inappropriate buffer conditions? Moreover, were the EM grid and vitrification parameters optimized? Grid geometries and chemistries can have profound effects of protein stability especially in the context of the air-water interface, leading to degradation of protein complexes (Glaeser, 2018; D'Imprima et al., 2019). Does UL52 form complexes with dsDNA? Data are shown for the HSV-1 packaging accessory factor. Perhaps dsDNA would stabilize the UL52 pentamer.

      In Didychuk et al., 2021, HSV UL32 is shown to form pentameric rings; negative stained 2D class averages were generated from tagged protein (twin strep tag), produced in mammalian cells (HEK293T), and not purified using size exclusion chromatography. In the present study HSV UL32 was not observed to form pentameric complexes "We first attempted to visualize the pentameric species by negative stain electron microscopy but were unable to identify particles of the expected dimensions." However, it is not clear why this was the case. If the pentameric structures were readily produced in previous experiments, why was cross-linking needed in the current study? As such, the tripentamer complexes seem artifactual in nature. Although the data presented in Fig. 4b suggest that interface residues, K532 and C535, might play a role in the formation of the tripentamer and have a minor role in HSV-1 replication, these experiments are incomplete. Single mutations are needed for each residue to assess their individual contribution to tripentamer formation, evidence for a loss of tripentamer formation is needed, and evidence for protein expression is needed. In the previous negative stain electron micrographs reported by Didychuk et al., 2021, were the higher order tripentamer complexes seen?

      Formation of disulphide bonds between cysteine residues in vitro is not indicative of complexes forming in vivo during replication. What evidence is there for disulphide bond formation between packaging accessory factor pentamers for KSHV, EBV, and LCMV? In the present study, the disulphide bond could form due to proximity as a result of the cross-linking and the presence of molecular oxygen rather than a bona fide enzyme catalysed reaction during herpesvirus replication to generate packaging accessory factor tripentamers.

      The DNA densities in Suppl. Fig. 6e to 6g are curious. As noted by the authors, the 30mer dsDNAs do not traverse through the central cavity of the pentamer. They appear to make contact with neighboring pentamers, again suggesting that these complexes are artefacts from cross-linking. This should be discussed more thoroughly.

      Previously proposed functional roles for ORF68 include a scaffold for terminase assembly, association of the terminase with the portal, generation of initial free ends, or coordination with other replication machinery (Didychuk et al., 2021). Presuming that the new structures for HCMV UL52 and HSV-1 UL32 occur naturally, how do they fit with the previously proposed functional roles of the herpesvirus packaging accessory factor? A more in-depth discussion of this would be valuable.

      Minor comments.

      A lack of page numbers and line numbers made reviewing this manuscript more challenging than necessary.

      As noted in the 'General comments' section above, ORF68 (3.37Å) and BFLF1 (3.60Å) both form pentamers (Didychuk et al., 2021) and were produced in mammalian systems HEK293T cells. Protein purification in the present study was performed in insect (SF9 or High Five) cells. Does this affect complex stability. Also, the tag was retained for UL32 in Didychuk et al., 2021; could this provide stability of the pentamer in the original studies?

      Suppl. Fig. 3 is missing.

      "UL52 has two regions remodeled" The use of the word 'remodeled' is not appropriate in this context as it implies a single protein can form two shapes under different conditions rather than distinct structures between two disparate proteins; UL52 compared to ORF68. This should be rephrased.

      What is the density in the central core of UL52 (Fig. 2a; Suppl. Fig. 2e)? Was any form of focused classification performed to establish the identity of the density within the central pseudocavity?

      Does UL52 bind to dsDNA? To support the hypothesis that the herpesvirus packaging accessory factor has conserved functions across the three subfamilies dsDNA binding experiments should be performed. There is no discussion about how these data relate to the previous functional model for ORF68 presented in Didychuk et al., 2021. Do the new data alter the previous functional models?

      There are some interesting grammatical phrases; please address throughout the manuscript. One example - "...a notable shared aspiration..." Proteins do not have aspirations. Please use a more formal scientific statement.

      Fig. 4b - Statistical analyses missing. Please provide.

      Fig. 6c - Statistical analyses are missing. Please provide. Protein folding/expression data missing; see Fig. 5C showing mutations that result in poor protein expression.

      Suppl. Fig. 2 and 5 - FSC curves have oddities, especially in the corrected curves. The cryo-EM resolution estimates calculated by CryoSPARC for the UL52 '3-mer' and 4-mer, and UL32 tripentamer are likely overestimated. In the PDB validation files each of the deposited structures has a warning for the resolution estimate "The value from deposited half-maps intersecting FSC 0.143 CUT-OFF 4.31 differs from the reported value 3.32 by more than 10 %", suggesting that the resolution estimates are inaccurate. The authors should provide a resolution estimate using loose masks and generate FSC curves using another software program such as RELION's postprocess to provide resolution estimates.

      Suppl. Fig. 6f and 6g - Is there any visible density that might resemble the EGS crosslinking reagent?

      Suppl. Fig. 7f - Statistical analyses absent.

      References.

      Didychuk AL, Gates SN, Gardner MR, Strong LM, Martin A, Glaunsinger BA. A pentameric protein ring with novel architecture is required for herpesviral packaging. Elife. 2021 Feb 8;10:e62261. doi: 10.7554/eLife.62261. PMID: 33554858; PMCID: PMC7889075.

      D'Imprima E, Floris D, Joppe M, Sánchez R, Grininger M, Kühlbrandt W. Protein denaturation at the air-water interface and how to prevent it. Elife. 2019 Apr 1;8:e42747. doi: 10.7554/eLife.42747. PMID: 30932812; PMCID: PMC6443348.

      Gardner MR, Glaunsinger BA. Kaposi's Sarcoma-Associated Herpesvirus ORF68 Is a DNA Binding Protein Required for Viral Genome Cleavage and Packaging. J Virol. 2018 Jul 31;92(16):e00840-18. doi: 10.1128/JVI.00840-18. PMID: 29875246; PMCID: PMC6069193.

      Glaeser RM. PROTEINS, INTERFACES, AND CRYO-EM GRIDS. Curr Opin Colloid Interface Sci. 2018 Mar;34:1-8. doi: 10.1016/j.cocis.2017.12.009. Epub 2017 Dec 22. PMID: 29867291; PMCID: PMC5983355.

      Significance

      General assessment: The strengths of this manuscript are the structural information provide by the cryo-EM maps for the HCMV UL52 and HSV-1 UL32 and the mutagenesis studies that corroborate previous studies for the packaging accessory factor for gammaherpesviruses KSHV and EBV. However, there are limitations. These are centered on whether the structures are representative of UL52 and UL32 complexes produced during replication rather than over expression in insect cells and stabilization using chemical cross-linking.

      There is a lack of novelty in the context of the herpesvirus packaging factor. The pentameric architecture, DNA binding, zinc fingers (4), and charged residues required for DNA binding were conclusively demonstrated in previous studies (Gardner and Glaunsinger, 2018; Didychuk et al., 2021). Thus, the novelty comes from the different pentameric structures; UL52 4-mer and UL32 tripentamer. However, if these are artefactual structures due to the expression system (mammalian versus insect) used, air-liquid interface induced protein instability, or cross-linking, the novelty is lost. That's not to say the data are not informative for the herpesvirus community.

      Advance: The advance in this manuscript is the new structural information for the UL52 and UL32. Even if the higher order complexes are potential artefacts, high resolution structure information for the subunit is especially informative. The mutagenesis data for UL32 are also informative in that the provide important information about a conserved and necessary protein needed for herpesvirus replication and has the potential to be used as a novel druggable target.

      Audience: The manuscript will appeal to specialized and broad audiences and could influence research into antiviral therapies for herpesviruses. My field of expertise is herpesvirology, structural biology, and cryogenic electron microscopy modalities,

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      Referee #2

      Evidence, reproducibility and clarity

      Bailey et al investigate DNA packaging accessory factors of various herpesviruses. The central findings are the cryo-EM structures of the accessory factors from HSV1 and HCMV. Combined with the corresponding author's previous structure of the KSHV accessory factor, these new findings now provide a window into packaging in all three families of human herpesviruses. They reveal that the overall structure of a ring of pentameric symmetry is conserved, the overall oligomeric stabilities are not conserved across all herpesviruses. Moreover, the authors have the important finding that basic residues in the ring pore are required for viral replication. Overall, this study represents a strong extension of the authors' study of packaging accessory proteins, with solid data and very few concerns to be addressed.

      Major issues.

      1) There is a high probability that the tripentamer is an artifact of the cross-linking. Because of this, it'd be great to know more about the cross-linking reaction, ideally mass spec identification and quantification of cross-links. This would also address the authors' speculation of contacts that stabilize the tripentamer. Moreover, the author's claim "However, mutation of K532A/C535A reduced infectious virion production by half (Fig. 4b), suggesting that the tripentamer interface may play a role in the viral life cycle." Seems to be an overreach. Perhaps this is semantics but the data just show that these residues play a role in viral replication (albeit not a huge role based on the modest effect).

      2) The density for the potential DNA does not look very convincing, although it still remains the strongest hypothesis. The authors should try to strengthen their argument. Does this putative DNA would contact residues that they show are necessary for viral replication? Showing seq conservation on the sturcutre could help their argument for the shared function of DNA-binding.

      3) My last major issue is stylistic and concerns the descriptions of cryoEM structures. I found that the paper was a bit of challenge to read when the authors would introduce each structure. It was a bit of a slog to get through. Descriptions of the structures veered off into overly detailed comparisons that required constant comparison with the figure and didn't really advance my understanding past "the outer surfaces of the three orthologs are different." This masked the more interesting aspects of the authors' findings. Perhaps this could be summarized in supplementary figures or a table. Because this is a stylistic suggestion, the authors should feel free to ignore this request.

      Minor comments

      1) The descriptions of structure determination in the text were often unclear. For example, "In the 3-mer map, a poorly-resolved fourth protomer is visible at low contour levels, suggesting that an additional protomer is present but highly flexible in this class (Supplementary Fig. 3a)." Alternatively, it could be that the classification algorithm wasn't able to fully separate particles that were 3-mers from the 4mers. When describing the structure determination of the HSV1 accessory factor, the authors describe no other particles other than the tripentamer. Were there other particles observed? It'd be a bit surprising that all of the protein adopted the tripentamer state. Was symmetry applied, particularly for the tripentamer that appears to have C-3 symmetry? This is in materials and methods but not clear why it isn't mentioned when describing the structure determineation and results.

      2) Throughout the paper, the authors use the word "remodel" to describe structural differences between orthologs. However, this word usually carries the implication of conformational rearrangement within a protein, and not across orthologs. Please consider a different description.

      3) Figure 2F is confusing and difficult to interpret. It seems that the main point is that these interfaces are conserved, which might be more easily displayed as a standard sequence conservation score mapped onto the structure. I'm also not sure that this figure is necessary as a main figure and could be supplemental.

      4) The authors write "UL32 bound to the shortest probe tested (10 bp, Supplementary Fig. 4a)." This implies that ONLY the shortest probe is bound and that others are not bound. Consider rephrasing.

      5) Frustum is misspellt. ;)

      6) In the discussion, the authors speculate that the variability of the outer surface is due to "virus- or host-specific interactions". I'm confused by "host-specific interactions", because the host is the same for all three viruses. Perhaps the authors mean that the different accessory factors could interact with different host factors? If so, are the authors making a Red Queen argument? If so, it'd be pretty cool to do dN/dS analysis to test that hypothesis.

      Significance

      This paper represents an advance in the field of genome packaging. The herpesvirus packaging mechanism is still mysterious, and the role of this accessory factor is one of the biggest gaps in knowledge. Although this study doesn't uncover the role, this provides new details into the evolution of this factor across the herpesvirus lineages. To me, this window into evolution of this factor is the biggest advance of the work, and tbh I felt that the authors could lean into this a bit more in the discussion section. Are there any differences in the packaging mechanisms of the different herpes families that can be related to their different behavior? Any other molecular evolution analyses (e.g. dN/dS ratio analysis) that could inform their study?

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      Referee #1

      Evidence, reproducibility and clarity

      Bailey et al. present the results of their structural analysis of packaging factors encoded by the β-herpesvirus human cytomegalovirus (UL52) and the ⍺-herpesvirus herpes simplex virus type 1 (UL32). The authors have previously published structures for orthologous proteins in the γ-herpesviruses Kaposi sarcoma associated herpes virus (ORF68) and Epstein-Barr virus (BFLF-1), showing both to form pentameric rings having a positively charged central channel. Here HCMV UL52 is found to form 3-mer and 4-mer assemblies that resemble incomplete pentameric rings. The complexes are formed by a screw displacement however, having both rotation about- and translation along the central axis. The structure shows fold conservation with the previously described structures, including preservation of the positively charged central channel.

      Attempts to image HSV-1 UL32 were initially unsuccessful, despite light-scattering analysis indicating the presence of pentamers. DNA binding is shown by EMSA, but these complexes were also not stable for cryo-EM analysis. Chemical crosslinking of the DNA bound complex was therefore employed, resulting in production of higher-order assemblies including one comprising three pentamers, that was successfully resolved by cryo-EM. Interestingly focussed classification analysis highlighted the presence of rod-shaped density passing through the central channels of two pentameric rings in this complex. Mutation of the interface that gives rise to the formation of tripentamers reduced progeny virion production by half, leading the authors to suggest that this complex may be a biologically important assembly.

      The importance of zinc-fingers identified in these structures was probed showing that mutation abolishes protein production. Similarly, mutation of the positively charged residues lining the central channel of HSV-1 UL32 greatly reduced or completely ablated progeny virion production in an assay where either WT or mutant UL32 was transfected into cells to complement UL32 knockout virus.

      Overall, I found the manuscript very easy to read and the analysis appears to be expertly performed. I have no substantive criticisms of the work and think it would be suitable for publication in its current form, or subject to some small edits.

      Minor comments

      The authors suggest that the weak 4th protomer in the HCMV UL52 3-mer map is a consequence of flexibility. This may be the case, but it may also be the case that the class is polluted with 4-mer particles leading to reduced occupancy. Erasing the weak density and running a multi-model 3D classification providing the erased 3-mer and a 4-mer starting map may separate these.

      I found the supplemental figure to show the DNA in the tripentamer map too small, this is an interesting finding and should be shown more clearly.

      Significance

      Herpesviruses are important pathogens of humans and are biologically complex systems. The structural analysis of this essential packaging co-factor is an important contribution to the field. It builds on the previous work by this group concerning the packaging factors of the gamma-herpesviruses KSHV and EBV. I consider this paper to be high-quality and worthy of publication in a very good journal with a microbiology/virology, biochemistry or molecular biology focussed readership. The process of genome packaging in herpesviruses is not as well characterised as in bacteriophages (and even in that case it is not well understood). This work provides important knowledge that will support future studies on this critical process in herpesvirus replication.

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      Reply to the reviewers

      Responses to the reviewers

      First of all, we would like to thank all the reviewers for their valuable and constructive comments on our manuscript. We have considered each comment and revised the manuscript accordingly. We respond to each comment below in blue font.

      To Reviewer #1

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      *Iwase et al have used multiomics and spatial transcriptomics to comprehensively map neural crest cell contributions to the mouse heart and great arteries. This careful and detailed analysis reveals changes in the transcriptional profile of neural crest cells as they give rise to different regions and cell types in the heart and great vessels. The study significantly builds on a number of recent scRNA-seq analyses of neural crest cell development and includes development of a new informatic tool for regulatory network investigation. Among the new findings documented are downregulation of Hox gene expression in intracardiac crest cells and regulation of Sox9 by Meis transcription factors. Addressing the following points would improve clarity and accessibility. *

      Thank you for your encouraging feedback and comments. We have responded to your comments below.

      * In Figure 1C it is difficult to visualize all the colors given the mixed contribution of NCC and nonNCC cells to mesenchyme. Please also show YFP transcript distribution in NCC versus nonNCC plots. In addition, it would be helpful to show plots for both NCC and nonNCC for Gata4 and Tbx20. *

      To improve visualization, we separated EYFP-positive NCCs and EYFP-negative non-NCCs into distinct plots (Figure 1e), rather than displaying EYFP transcript distribution within a single combined plot. In addition, we have included separate plots for both NCCs and non-NCCs showing the expression of Gata4 and Tbx20 (Figure 1g, h).

       Furthermore, in the revised manuscript, we subdivided the original clusters c5 and c13 into two subclusters each, resulting in a total of 23 clusters in the UMAP shown in Figure 1. This refinement was introduced to facilitate clearer interpretation and subsequent analyses.
      

      * The authors identify a cardiomyocyte cell cluster in their integrated NCC scRNA-seq plots. Are these cells labelled by Wnt1-Cre in the authors' own dataset? Is the trajectory analysis informative as to the steps preceding acquisition of cardiomyocyte fate? *

      A total of 20 EYFP-positive NCCs in our own dataset were assigned to the cardiomyocyte cluster in the integrated UMAP. Of these, 6 cells were located within the cardiomyocyte cluster (c21), while the remaining cells were classified as pharyngeal mesenchyme but positioned in close proximity to c21 in the original UMAP (Figure 1e). Although this observation is consistent with previous reports showing that NCCs give rise to cardiomyocytes, the small number of cells precluded meaningful characterization or trajectory analysis of cardiomyocyte fate acquisition. Accordingly, we have addressed this point only briefly in the revised manuscript as follows:

      Only a few NCCs were detected within cardiomyocyte clusters, which were predominantly composed of non-NCCs, consistent with previous reports demonstrating NCC differentiation into cardiomyocytes15,16. The overall number of cardiomyocytes was low, likely reflecting the restricted sampling of the cardiac outflow tract (Figure 1a).

      (P6, L20–25)

      * Linked with this point, is it possible that there are nonNCC cells in the integrated plots? Of note, many of the NCC genes overlap with genes that have also been shown to be expressed in mesodermal cardiac progenitors (including Osr1, Pparg, Dlk1, Tcf21, Ebf2, Tbx20, Sox9). For example, is it possible to distinguish NCC derived smooth muscle within the heart from cells originating from the second heart field that may express smooth muscle genes? Cluster 27 for example appears broadly expressed in the region of ventricular outlets in Figure 3. Comparison with YFP transcript distribution may be helpful here. *

      In principle, non-NCCs were excluded from the integrated plots shown in Figure 3. However, we cannot completely rule out the possibility that a small number of non-NCC cells were inadvertently included, for example due to false-positive signals during cell isolation. In our dataset, NCCs and non-NCCs were stringently distinguished based on FACS profiles, detection of EYFP transcript reads in the RNA-seq data, and rigorous exclusion of doublets and low-quality cells.

       Regarding the distinction between NCC- and non-NCC-derived SMCs, a key challenge lies in defining comparable cell populations. We first validated the annotations of SMC clusters (C4, C23, and C27) using immunostaining for Myh11, Sost, and Reln, confirming consistency with their transcriptomic identities. We then re-clustered the SMC populations and projected non-NCC SMCs (clusters 4 and 20 in Figure 1d) onto this UMAP. These non-NCC SMCs were mapped to clusters corresponding to great artery and coronary artery SMCs (C27 and C23, respectively).
      
       However, we lack confidence that these projected populations are directly comparable. For example, non-NCC SMCs mapped to C23 or C27 may not necessarily represent bona fide coronary or great artery SMCs from equivalent anatomical regions, and could include other SMC subtypes such as venous SMCs or pericytes. Given the known regional heterogeneity of SMCs and the absence of strict spatial matching criteria, such comparisons would be difficult to interpret. This limitation is further compounded by the relatively small number of cells available.
      
       For these reasons, we focused on spatial validation of cluster annotations by immunostaining in this study, and have reserved detailed comparisons between NCC- and non-NCC-derived SMCs for future work. We believe this does not detract from the overall consistency or value of the present study.
      

      * Can the authors add any validation of key expression patterns, for example using fluorescent in situ hybridization? *

      Figures 2n-y present Xenium-based multiplexed fluorescent in situ hybridization data that validate the spatial expression patterns of marker genes characterizing NCC derivatives in pharyngeal mesenchyme, intracardiac mesenchyme, and SMC populations. In addition, we have incorporated new Xenium images highlighting key gene expression patterns in the aorticopulmonary (AP) septum at E12.5 (Figure S4), supporting the annotation of cluster C16 in the integrated UMAP as corresponding primarily to the AP septum. We have also added immunostaining data for Myh11, Sost, and Reln to further validate the annotations of SMC clusters (see the response above). Together, these data provide independent spatial confirmation of the transcriptional signatures identified in our single-cell analyses. Based on these data, we revised the relevant section of the Results as follows:

      The SMC clusters, which were continuous with the pharyngeal mesenchyme via transitional populations in the UMAP, were identified by high expression of the mature SMC marker Myh11 (Figure 3i). Differential gene expression analysis further distinguished individual clusters (Figure S4a-g). Among these, C27 displayed a transcriptomic profile characteristic of the great artery SMCs, including high expression of Sost (Figure S3j). C4 was enriched for Tfap2b and Ptger4 (Figure S3j), markers of the ductus arteriosus SMCs21,22, supporting its annotation. C0 and C7 likely represent transitional states between pharyngeal mesenchyme and differentiated lineages, potentially bifurcating toward great artery SMCs or cardiac cushion mesenchyme (Figure S3a and Table S6). C23 was characterized by high expression of Gja4, a marker of coronary artery SMCs, along with pericyte markers Kcnj8 and Rgs5 (Figure 3j and Figure S3k), corresponding to the cluster similarly annotated by Chen et al14. In addition, C23 was also distinguished from C4 and C27 by its expression of Reln (Figure S4d).

      • Immunostaining supported these cluster annotations. Sost expression is observed in great artery SMCs but not in ductus arteriosus and coronary artery SMCs, whereas Myh11 expression was higher in ductus arteriosus and coronary artery SMCs than in aortic SMCs (Figure S4f-m). Furthermore, Reln expression was restricted to coronary artery SMCs (Figure S4n-s).*

      (P8, L30 – P9, L14)

      * Please elaborate on the decoded Hox code patterns that appear to be indicative of arch origins. Do the results allow determination of whether the trajectories to different cardiac fates inferred in Figure 3D differ in different arches? *

      • *

      In response to the reviewer’s suggestion, we have further elaborated on the decoded Hox code patterns indicative of pharyngeal arch origin and examined whether trajectories toward distinct cardiac fates differ between arch-derived NCC populations (see new supplemental figure).

      To further delineate Hox code patterns associated with pharyngeal arch origin, we stratified the integrated UMAP by distinct Hox expression profiles (Figure S9). Cells expressing any Hox2 paralog, but lacking Hox3–5 paralogs, were defined as PA2-derived preotic NCCs, whereas cells expressing any of Hox3–5 paralogs were classified as PA3/4/6-derived postotic NCCs. Preotic, postotic, and Hox-negative populations were then projected onto the integrated UMAP across developmental stages (E10.5–E14.5). Trajectory inference indicated that transitions toward intracardiac mesenchyme occur earlier in preotic cells (E10.5) than in postotic cells (E11.5), consistent with their known sequential migration into the cardiac cushion8. From E12.5 to E14.5, postotic cells showed a progressive emergence of the aorticopulmonary septum–associated cluster C16 from transitional states. Notably, the proportion of Hox-negative cells increased within intracardiac mesenchyme, except in C16 where Hox expression was retained, supporting the notion that Hox genes are broadly downregulated in cushion-associated intracardiac NCCs (Figure 4k, S9).

      (P11, L24 – P12, L4)

      * The authors need to explain why the authors place an arrow from mesenchymal cluster 18 to 23 in Figure 3D while the trajectory analysis in 3C predicts the opposite direction. *

      RNA velocity analysis of scRNA-seq data is fundamentally based on splicing dynamics. The original framework assumes that transcriptional induction and repression persist long enough for cells to reach active (transcribing) or inactive (silenced) steady-state equilibrium. However, this assumption is often violated during cell differentiation, where transient cell populations frequently exhibit rapidly changing mRNA levels that do not reach steady-state equilibrium. To address this limitation, the scVelo method was developed (Bergen et al., 2020, Nature Biotechnology), and we applied this approach to the integrated NCC datasets in the present study. This analysis successfully inferred directional flows from the pharyngeal mesenchyme toward SMCs and intracardiac mesenchyme through transitional states (Figure 3c,d). However, as the reviewer correctly pointed out, the analysis predicted a directional flow from C23 to C18, apparently opposite to the biological directionality supported by previous findings (see P9, L15–19).

       We consider this discrepancy to reflect intrinsic limitations of RNA velocity analysis. As discussed by Bergen et al., in systems containing multiple lineages and cellular processes, differences in gene regulatory networks among heterogeneous cell states can generate multiple trajectories in phase space owing to distinct splicing kinetics. In addition, incompletely captured splicing kinetics may represent only a limited portion of the overall dynamics, particularly near terminal differentiation states. In such cases, phase portraits of unspliced versus spliced transcripts may appear nearly linear rather than curved, potentially leading to erroneous assignment of positive or negative RNA velocities. Consistent with this limitation, we obtained opposite directionalities between C18 and C23 depending on whether steady-state or dynamical models were applied and according to different parameter settings. Through these repeated computational re-evaluations of lineage directionality, we concluded that RNA velocity analysis is suitable for capturing the global landscape of differentiation flow, but that accurate inference of local lineage directionality may require careful model selection and parameter optimization to ensure consistency with established biological evidence.
      
       To avoid arbitrariness and potential confusion, we removed the arrow between C18 and C23 from the revised Figure 3d. Instead, we now describe the observed continuity between these populations in the Discussion section as follows:
      

      Notably, the UMAP revealed a continuum between C23 and C18 within the intracardiac mesenchyme population. Given previous findings that the proximal coronary artery SMCs originate from preotic NCCs8 and that pericytes give rise to coronary artery SMCs23, this connection likely represent a differentiation trajectory from intracardiac mesenchyme to coronary artery SMCs via a pericyte-like intermediate stage.

      (P9, L15–19)

      The continuity between intracardiac mesenchyme and coronary artery SMCs through a pericyte-like intermediate state is consistent with previous developmental studies showing that proximal coronary artery SMCs originate from preotic NCCs and may arise through pericyte intermediates8,21.

      (P18, L24-27)

      * The authors nicely show downregulation of Hox gene expression in NCC cells entering the heart. Can they add discussion of any insights into this from prior studies of loss or gain of Hox gene function? *

      • *

      We have added the following discussion on the roles of anterior Hox genes in cardiovascular development, together with appropriate references on loss or gain of Hox gene function:

      • The regional identities of pharyngeal NCCs that contribute to cardiac development are established by Hox genes and their associated regulatory networks. Genetic studies have demonstrated essential roles for the anterior Hox genes in patterning the pharyngeal arch artery system and semilunar valve structures. Loss of Hoxa1 and Hoxb1 results in severe defects in pharyngeal arch artery development42, whereas ectopic or sustained expression of Hoxb1 in NCCs disrupts cardiovascular morphogenesis and causes malformations of the great arteries and semilunar valves43. Likewise, Hoxa3 contributes to proper patterning of the pharyngeal arch region and its NCC-derived derivatives44,45. These findings underscore the importance of precise spatial and temporal regulation of Hox genes during cardiovascular development. Among pharyngeal NCCs contributing to cardiac development, cushion-independent NCC derivatives (great artery SMCs and the aorticopulmonary septum) retain their origin-specific Hox-codes. In contrast, cushion-associated NCC derivatives (coronary artery SMCs and valvular/subvalvular interstitial cells) downregulate Hox expression and transition toward region-specific GRNs involving TFs such as Tbx20 and Gata4, whose expression is known to be induced by BMP signaling in cardiomyocytes46,47. Bmp2 and Bmp4 are expressed in the regions of the pericardial reflection traversed by NCCs en route to the cardiac cushion48. Together, these observations suggest that appropriate repression of Hox programs, coupled with activation of cardiac-specific regulatory networks, is required for normal differentiation of cushion-associated NCC derivatives.*

      (P18, L30 – P19, L16)

      • Roux, M. et al. Hoxa1 and Hoxb1 are required for pharyngeal arch artery development. Mech. Dev. 143, 1–8 (2017).*
      • Zaffran, S., Odelin, G., Stefanovic, S., Lescroart, F. & Etchevers, H. C. Ectopic expression of Hoxb1 induces cardiac and craniofacial malformations. genesis 56, (2018).*
      • Chisaka, O. & Capecchi, M. R. Regionally restricted developmental defects resulting from targeted disruption of the mouse homeobox gene hox-1.5. Nature 350, 473–479 (1991).*
      • Kameda, Y., Watari-Goshima, N., Nishimaki, T. & Chisaka, O. Disruption of the Hoxa3 homeobox gene results in anomalies of the carotid artery system and the arterial baroreceptors. Cell Tissue Res. 311, 343–352 (2003).*

        In addition, we previously generated conditional Hoxa2 overexpression mice and demonstrated that ectopic Hoxa2 expression in Hox-negative PA1 cranial neural crest derivatives induced PA2-like structures, indicating a partial homeotic transformation (Kitazawa et al., Developmental Biology, 2015; 10.1016/j.ydbio.2015.04.007). Because cardiovascular phenotypes were not examined in that study, we have now resumed breeding of these mice for detailed cardiovascular phenotypic analyses.

        In parallel, we have also established knockout mice for a downstream target of Hoxa2, which are expected to complement the Hoxa2 gain-of-function model and provide further insight into the regulatory mechanisms underlying cardiac NCC differentiation and patterning. Although we have obtained preliminary observations from these models, a comprehensive analysis is still ongoing, and we therefore prefer to reserve these results for a future study with more detailed investigation.*

      • Figure 3Y could be simplified to more clearly distinguish the two types of Meis binding sites. For example, it may be helpful to reorder the mesenchymal cell types based on Hox expression. *

      To improve clarity and better distinguish the two types of Meis binding sites, we have reordered the heatmap of motif enrichment based on the hierarchical clustering with the updated JASPAR2024 database. In parallel, we have revised the heatmap of transcription factor gene expression to provide a more consistent and interpretable presentation. These diagrams were now presented as Figures 4k and 4l of the revised manuscript.

      * The authors provide nice in vitro and in vivo evidence for an upstream role of Meis transcription factors in regulating Sox9 expression. Can the authors identify from the enhancer sequence (or their transcriptomic dataset) any of the non-Hox transcription factors that Meis may be working with here? Please discuss the significance of Sox9 expression in epicardium driven by the same enhancer. Might this regulation also operate in second heart field progenitor cells where both genes are expressed? It is not evident in Figure 7 that Sox9-EGFP is also expressed in epicardium. *

      The distal Sox9 enhancer containing Meis2 binding site that we identified (chr11-112850240-112851186) also contains several consensus motifs including predicted Hand2- and Nfatc1-binding sites. However, to our knowledge, these transcription factors have not been reported as non-Hox partners of Meis proteins. Their recruitment to this enhancer, as well as potential cooperative interactions with Meis transcription factors, were not examined in the present study and remain subjects for future investigation.

       As the reviewer pointed out, Sox9 was expressed not only in intracardiac NCCs but also in the epicardium (revised Figure S13). Consistent with this expression pattern, distal *Sox9* enhancer was accessible in both intracardiac mesenchyme and epicardial cells (revised Figure S13). Especially, *Wt1*low/*Sox9*high mesenchymal cells, likely derived from the epicardium via epithelial-mesenchymal transition, also exhibit chromatin accessibility at this enhancer comparable to that observed in NCC-derived mesenchymal cells. These findings suggest that the same regulatory element may function across multiple cardiac lineages.
      
       We have addressed these points in the revised manuscript as follows, including additional supporting data in the supplementary figures.
      

      *Enhancer activity in the epicardium corresponds to Sox9 expression and an open chromatin peak at the putative distal enhancer region in clusters 22 and 5 in Figure 1d, which represent Wt1high epicardial cells and intracardiac mesenchyme likely including Wt1low epicardial EMT derivatives, respectively (Figure S13). *

      (P16, L28–32)

      • *

      • Could this approach yield similar data for Osr1? Please clarify if there is any experimental evidence supporting the predicted negative regulation of Sox9 by Osr1 in the heart illustrated in Figure 8. *

      There are currently no experimental data demonstrating Sox9 repression by Osr1 in the heart. However, such an effect has been reported in tongue and limb mesenchyme (Liu et al., PNAS, 2013), as noted in P16, L5–7. Although direct experimental validation, such as Osr1 overexpression in cardiopharyngeal NCCs, would provide stronger evidence, preparation of this specific NCC lineage is difficult. Given this limitation, we instead performed in silico gene perturbation analysis using CellOracle, which predicted antagonistic roles for Sox9 and Osr1 during lineage bifurcation from pharyngeal NCCs. Because this regulatory relationship has not yet been experimentally validated in the cardiac context, we revised the illustration accordingly by adding a question mark to indicate the hypothetical nature of this antagonism (Figure 9 in the revised version).

      * Concerning the links between valve mesenchyme and skeletogenic programs it would be relevant to cite the earlier work of Lincoln and Yutzey (reviewed in PMID: 16643886): *

      • *

      We cited the suggested work in the relevant portion of the Discussion section as follows:

      By analogy, Sox9high/Scxhigh NCCs at the base of semilunar valves may form a structural attachment unit linking cushion tissues to valvular leaflets57.

      (P20, L30–32)

      • Lincoln, J., Lange, A. W. & Yutzey, K. E. Hearts and bones: Shared regulatory mechanisms in heart valve, cartilage, tendon, and bone development. Dev. Biol. 294, 292–302 (2006).* *
      • In order to increase accessibility of the dataset the authors are encouraged to include a browser link. *

      We agree with the reviewer that improving dataset accessibility is important for facilitating exploration of NCC diversity. Therefore, we have already uploaded our original fastq sequence files and count matrices in the DDBJ and GEO servers. In addition, we will upload our gene expression datasets projected onto the UMAP in UCSC cell browser, enabling readers to more easily visualize and interrogate the dataset.

      Minor points:

      *13. The authors could rephrase the title since the term topographical genetic switch is unclear. *

      • *

      We thank the reviewer for this suggestion. To improve clarity, we revised the title as follows:

      Hox–Meis-relayed spatial gene regulatory transition underlies cardiopharyngeal neural crest diversification revealed by multimodal analysis * 14. In the introduction, with reference to the De Bono study, please note that Tbx1 was shown to regulate pharyngeal NCC differentiation stage transitions non-cell autonomously. *

      According to the reviewer’s suggestion, we rephrased the relevant section of the introduction as follows:

      De Bono et al. elaborated the transition of pharyngeal NCCs through multiple differentiating stages toward SMC fates, identifying Tbx2 and Tbx3 as key TFs in this process13. They also showed that Tbx1, the gene for 22q11.2 deletion syndrome, regulates pharyngeal NCC differentiation stage transitions non-cell autonomously13.

      (P5, L1–4)

      Reviewer #1 (Significance (Required)):

      *Iwase et al have used multiomics and spatial transcriptomics to comprehensively map neural crest cell contributions to the mouse heart and great arteries. This careful and detailed analysis reveals changes in the transcriptional profile of neural crest cells as they give rise to different regions and cell types in the heart and great vessels. The study significantly builds on a number of recent scRNA-seq analyses of neural crest cell development and includes development of a new informatic tool for regulatory network investigation. Among the new findings documented are downregulation of Hox gene expression in intracardiac crest cells and regulation of Sox9 by Meis transcription factors. *

      Again, thank you for giving us the opportunity to strengthen our manuscript with your valuable comments and queries. We have worked hard to incorporate your feedback and hope that these revisions persuade and satisfy you.

      To Reviewer #2

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary *In this manuscript, Iwase et al. cleverly make use of different modalities, spatial transcriptomics and single-cell omics datasets, in conjunction with a well-established Wnt1-Cre;R26R-EYFP line to trace neural crest cells (NCCs) contributing to the cardiovascular system during embryonic development in the mouse. By doing so, the authors identified a bifurcation between cardiac NCCs contributing to the OFT cushions and forming the aorticopulmonary (AP) septation complex. Thus, the authors split "intracardiac NCCs" into two different NCC programs/compartments, even though both reside in the broad OFT region. The NCCs that enter and associate with the OFT cushions undergo a Hox off transition (Hox-positive to Hox-negative once intracardiac), with a corresponding shift in Meis binding and GRN wiring. The authors propose these cells pass through a Meis2-Sox9-Scx "skeletogenic progenitor-like" intermediate and contribute to semilunar valves and coronary artery smooth muscle. By contrast, the NCCs assigned to aorticopulmonary septum (APS) formation and great vessel smooth muscle retain a distinct Hox codes. *

      Thank you for your encouraging feedback and comments. We have responded to your comments below.

      Major Comments *1. The manuscript would benefit from clearer delineation between the different NCC contributions, particularly for non-specialist readers. The distinction between (i) CNCCs in OFT cushions and (ii) CNCCs forming the aorticopulmonary (AP) septation complex is not adequately explained. While both populations contribute to OFT septation, according to the authors, they represent distinct compartments with different developmental trajectories. The authors could clarify this using anatomically labelled hearts at the stages they conduct their analysis, along with additional text and schematics explaining what is meant by each compartment. This would greatly enhance the accessibility of the manuscript. *

      To clarify the distinction between the two components of intracardiac NCCs, cushion-associated mesenchyme and cushion-independent aorticopulmonary (AP) septum, we substantially revised the description of cluster characterization (P9, L24–P10, L6). We added new figures (Figure S5) showing their spatial relationships and distinct gene expression signatures, including E12.5 Xenium data demonstrating Vegfc expression in cushion-associated NCCs and Tcf24 expression in AP septum NCCs.

       In addition, we revised the schematic diagram of intracardiac NCC distribution in Figure 4m and added Figure S9, which spatially delineates three major NCC trajectories with distinct Hox codes: (1) migration of preotic NCCs into the outflow tract cushions, (2) migration of postotic NCCs into the outflow tract cushions, and (3) protrusion of the AP septum from the dorsal wall of the aortic sac. We also incorporated additional explanatory text and cited relevant review articles on cardiac outflow tract development. We hope that these revisions substantially improve the clarity and accessibility of the manuscript, particularly for non-specialist readers.
      
      • The Methods state that "Decomposition of cell clusters of scRNA-seq was performed by RCTD to map them onto the Xenium dataset," but this description is insufficient. The authors should clarify whether RCTD was applied separately for each developmental stage (i.e., E11.5 scRNA-seq reference for E11.5 Xenium, E12.5 reference for E12.5 Xenium), or whether a pooled reference was used across stages. This clarification is important because RCTD performance depends critically on the correspondence between reference and target datasets. Using a multi-stage integrated reference to deconvolve stage-specific spatial data could introduce artifacts, as cell states and cluster compositions vary considerably across developmental timepoints. *

      The pooled scRNA-seq data of NCCs or non-NCCs at E11.5 and E12.5 were used for RCTD to decompose for the spatial allocation in the Xenium dataset. We agree with the reviewer that a multi-stage integrated reference may introduce artifacts. In fact, datasets at E11.5 and E12.5 were similarly distributed in UMAP space and exhibited similar transcriptomic signatures, whereas those at E14.5 and E17.5 demonstrated different characteristics in the integrated UMAP in Figure. 1c. Therefore, we used only E11.5 and E12.5 datasets for RCTD decomposition. We added the bellow sentence in Method section.

      The pooled scRNA-seq data of NCCs or non-NCCs at E11.5 and E12.5 were used for RCTD.

      (P33, L6)

      • *

      • Figure 2j-m needs annotations and schematics. It is currently very difficult to identify the different compartments. See Figure C in Chen et al. for an example of this approach. In addition, what are the fine clusters from 1 to 20? Which ones are NCC-derived? *

      We added anatomical annotations to the revised Figure 2a, b, j–m to facilitate identification of the different compartments. The fine clusters labeled 0–20 in the previous Figure 2j–m corresponded to the multiome clusters (NCC and non-NCC) shown in Figure 1d. In the revised manuscript, the same dataset was re-clustered into 23 clusters (0–22), which were subsequently used for decomposition analysis to predict cell compartments with maximum likelihood. We also revised the color scheme of the segmented cells in Figure 2j–m to improve visual distinction between compartments and facilitate interpretation of the spatial distribution patterns.

       Putative NCCs were identified through the following procedure:
      
      1. EYFP expression was estimated across 39 cell types in the Xenium dataset by integration with the single-cell multiome dataset (including both NCCs and non-NCCs) using Tangram.
      2. Xenium clusters enriched for EYFP expression, defined as clusters whose mean estimated EYFP level exceeded the threshold corresponding to the 65th percentile across all spots, and consistent with known neural crest derivatives were extracted as putative NCC populations.
      3. For each spot within these EYFP-enriched Xenium clusters, RCTD was used to estimate the corresponding multiome cluster identity. Thus, the diagrams in Figure 2j–m indicate the most likely multiome subpopulation assignment for each putative NCC spot, rather than categorizing the multiome clusters themselves as NCC- or non-NCC-derived. This description has been included in the Method section (P33, L6–14).

      * The panels show pharyngeal markers, OFT/intracardiac markers, and SMC markers in Figures 2n-y, but could the authors show the proportion of NCC-derived (YFP+) cells for each cluster? Could the authors also map only the YFP+ cells on the Xenium data? It would be useful to see the proportion of YFP-positive (NCC-derived) cells for each delineated compartment. YFP-positive cells appear to exist at the boundary between LV and RV in the septum, this observation would benefit from proper quantification. *

      Our Xenium analysis could not detect EYFP signals; therefore, as noted above, we estimated EYFP expression by integrating the scRNA-seq and Xenium datasets using Tangram. To clarify the relative enrichment of distribution for each Xenium cluster, we summarized the mean estimated EYFP expression as bar plots (Revised Figure S2q, r). Consistent with their established neural crest origin, Xenium clusters annotated as neuron (38), ganglion (32), and Schwann cell (17) showed high estimated EYFP expression. In addition, Xenium clusters 15 (SMC) and 25 (cushion mesenchyme) were also enriched for EYFP expression.

       Unfortunately, currently available algorithms for Xenium data analysis do not reliably allow visualization or extraction of gene expression profiles exclusively from putative EYFP-positive cells. Instead, we improved the visualization of the spatial distribution of putative EYFP-positive cells by replacing centroid-based signal display with segmentation-based rendering (Revised Figure 2f, g).
      
       As pointed out by the reviewer, putative YFP-positive cells appear to be present at the boundary between the LV and RV within the interventricular septum. However, the estimated EYFP signals in this region were substantially lower than those observed in well-established neural crest derivatives, suggesting that most of these signals likely represent background noise, although a minor population of sparsely distributed neural crest-derived cells cannot be excluded. More precise characterization of potential neural crest derivatives in the ventricular region will require future investigation.
      

      * Figure 3 is confusing because it integrates data from multiple overlapping stages (E8.5 to P7). While the authors identify distinct compartments, pharyngeal mesenchyme, intracardiac mesenchyme, and SMCs, it is unclear why stages beyond E14.5 and E17.5 (corresponding to the initial single-cell omics and Visium analysis) were included. Although leveraging additional datasets is a clever approach, the integration of data from such disparate developmental timepoints confounds interpretation. For example, Cluster 6 appears to include cells from both P7 and E12.5 stages. Given that the Visium data represent hearts at E14.5 and E17.5, it is problematic to map clusters derived from other stages onto these spatial datasets. *

      We integrate data from multiple overlapping stages (E8.5 to P7) in Figure 3 to capture diachronic cell identity and also stage-specific features, particularly within intracardiac mesenchyme and SMC populations. This approach enabled us to assess core lineage relationships, including trajectories linking pharyngeal mesenchyme to intracardiac mesenchyme and SMCs, each comprising multiple distinct subpopulations. These findings support the biological relevance of the integration as a framework for understanding lineage relationships across developmental time. However, we agree with the reviewer that it is problematic to map clusters derived from other stages onto these spatial datasets. Indeed, we restricted the spatial mapping analysis to cells from E14.5 and E17.5 within the integrated dataset, thereby ensuring consistency with the developmental stages represented in the Visium data. To address concerns about this issue, we have clarified this point in the Methods section by adding the underlined words in the following sentence.

      Spatial mapping of scRNA-seq data onto Visium sections was performed using only E14.5 and E17.5 datasets and the RCTD algorithm, as described above.

      (P 34, L12–13)

      • *

      • Throughout the manuscript, the authors describe "lineage relationships" between cell populations, but these are in fact developmental trajectories inferred computationally (via UMAP connectivity and RNA velocity), not true lineage relationships. This distinction is critical and should be explicitly stated. *

      • *

      We agree with the reviewer that the present “lineage relationships” described in the original manuscript were primarily inferred from computational analyses, including UMAP connectivity and RNA velocity, rather than being directly demonstrated by lineage-tracing experiments. We also acknowledge that some RNA velocity results were not fully consistent with known in vivo developmental trajectories.

       We strengthened the biological validation of the inferred trajectories by incorporating extensive spatial verification of gene expression using immunohistochemistry and Xenium in situ hybridization analyses to confirm the identity and localization of each cell population. We also refined the computational analyses to better resolve regional differences in NCC dynamics and added comprehensive schematic illustrations based on established models of heart development from previous studies, with appropriate citations throughout the manuscript.
      
       In the revised manuscript, we have added much spatial verification of gene expression by immunohistochemistry and Xenium in situ hybridization data to confirm the identity of each cell population, and also include proper citation in the appropriate context. We also improved computational analysis to clarify the regional difference in NCC dynamics with comprehensive schematic illustration based on heart developmental processes established by previous literatures. In response to the reviewer’s comment and these revisions, we have carefully rephrased the relevant descriptions to clarify that the observed relationships represent computationally inferred developmental trajectories rather than definitive lineage relationships as follows.
      

      (original) RNA velocity analysis in conjunction with developmental context, revealed lineage relationships among these groups (Figure 3c, d).

      (revised) RNA velocity analysis in conjunction with developmental context, inferred global lineage relationships among these groups (Figure 3c, d), consistent with developmental trajectories in vivo.

      (P8, L21–23)

      (original) …, we present a comprehensive map of cardiopharyngeal NCC lineages …

      (revised) …, we present a comprehensive map of cardiopharyngeal NCC populations …

      (P18, L1)

      (original) Overall, this study proposes a new framework for understanding cardiac NCCs heterogeneity based on the association with the cardiac cushion and the accompanying transition in Hox gene expression and regulatory programs. Our findings provide a basis for systematically dissecting the developmental diversity of cardiac NCCs.

      (revised) Overall, this study proposes a new framework for understanding cardiac NCCs heterogeneity based on developmental route, Hox-code retention, and region-specific regulatory programs. Importantly, the developmental relationships and differentiation pathways described here are inferred from integrated computational analyses, including transcriptomic similarity, UMAP connectivity, and RNA velocity, rather than direct lineage-tracing experiments. Within this framework, our findings suggest distinct differentiation trajectories leading to great artery, ductus arteriosus, and coronary artery SMCs, as well as the aorticopulmonary septum and valvular/subvalvular mesenchyme.

      (P20, L33 – P21, L7)

      We also rephrased additional relevant sections throughout the manuscript in accordance with the reviewer’s comment (Please see below).

      * For example, the statement "we propose that intracardiac NCCs within C10 and C22 differentiate via C2 into valvular (C21) and subvalvular (C18) interstitial cells" should be framed as a computational inference, not an established lineage relationship. Without clonal lineage tracing data, these claims cannot be verified. *

      • *

      We have changed the word “propose” to “infer” (P10, L24).*

      Similarly, the claim that "NCCs contributing to the AP septum are distinct from other intracardiac NCCs in that they do not populate the cardiac cushions but remain continuous with NCCs populating the distal outflow tract cushion" lacks direct lineage evidence. What experimental data support this assertion? *

      We agree with the reviewer that the original statement lacked direct lineage evidence, although the anatomical distinction between the outflow tract cushions and the AP septum—a protruding structure arising from the dorsal wall of the aortic sac—is well established. In the revised manuscript, we therefore removed this speculative statement and rewrote the section to more accurately describe the developmental process with appropriate references. The spatial and temporal features of AP septum formation are now also illustrated in Figure S9a (UMAP plots and schematic illustration) and described as follows:

      *From E12.5 to E14.5, postotic cells showed a progressive emergence of the aorticopulmonary septum–associated cluster C16 from transitional states. * (P11, L32 – P12, L1)

      In addition, we further validated the identity of the C16 cluster as AP septum–associated NCCs by incorporating additional marker analyses together with spatial verification using Xenium in situ analysis. In addition to Penk and Sfrp2, which were previously reported by Chen et al., C16 also highly expressed Postn, similar to other intracardiac clusters. Furthermore, C16 was characterized by relatively high expression of Tcf24 and low expression of Vegfc. Based on the reviewer’s comment and these additional experimental data, we revised the relevant Results section as follows:

      (original) Within the intracardiac mesenchyme group, C16 exhibited high expression of Penk and Sfrp2 (Figure S3i and Table S6), corresponding to the cluster annotated as the aorticopulmonary septum in the previous study by Chen et al14. This annotation was further supported by enriched expression of Hox4 and Hox5 paralogs, consistent with its origin between PA4 and PA6 (Figure 3t, u). The aorticopulmonary septum originates as a protrusion from the dorsal wall of the aortic sac and is primarily derived from NCCs6,18–20. This septal structure fuses with the distal outflow tract cushions to divide the common arterial trunk into the aortic and pulmonary channels. Notably, NCCs contributing to this septum are distinct from other intracardiac NCCs in that it does not populate the cardiac cushions but remain continuous with NCCs populating the distal outflow tract cushion, suggesting that C16 represents this distinct NCC-derived population.

      (revised) C16 was distinguished by high expression of Penk and Sfrp2 (Figure S3i and Table S6), corresponding to the cluster annotated as the aorticopulmonary septum in the previous study by Chen et al14. This cluster also exhibited robust expression of mesenchymal markers, including Postn, similar to other intracardiac clusters (Figure S3i). In addition, C16 showed relatively high expression of Tcf24 and low expression of Vegfc compared with the other intracardiac clusters (Figure S5a-e). These gene expression features of the aorticopulmonary septum were further validated by Xenium in situ hybridization (Figure S5f-j).

      • Unlike other intracardiac NCCs that populate the distal outflow tract cushions, the aorticopulmonary septum originates as a protrusion from the dorsal wall of the aortic sac and is primarily derived from NCCs residing in PA4 and PA66,22–24. This septal structure subsequently fuses with the distal outflow tract cushions to partition the common arterial trunk into the aortic and pulmonary channels. Consistent with this developmental origin, C16 was enriched for the expression of Hox4 and Hox5 paralogs (Figure 3t, u), indicating that NCCs in this population retain their Hox code, in contrast to other intracardiac NCCs, in which most Hox genes were downregulated (see later details).*

      (P9, L24 – P10, L6)

      * In addition, the authors state that what De Bono et al. identified as "outflow smooth muscle" corresponds in their dataset to early intracardiac mesenchymal clusters C2, C10, and C22, present as early as E10.5, when mesenchymal NCC derivatives express immature SMC markers, and that these cells later differentiate into coronary artery SMCs around E14.5 (C23) as well as other non-muscle components. This claim is not verified, whether these cells are indeed the ones differentiating into coronary artery SMCs is based solely on computational inference from C2, C10, C22 to C23. *

      • *

      To validate that C23 corresponds to coronary artery SMCs, we performed additional immunostaining analyses for Myh11, Sost, and Reln, which distinguish great artery SMCs, ductus arteriosus SMCs, and coronary artery SMCs, respectively, consistent with their transcriptomic identities. Regarding differentiation of NCC-derived mesenchymal cells into coronary artery SMCs, we previously demonstrated using chick–quail chimera experiments and specific Cre-reporter mouse lines that proximal coronary artery SMCs originate from preotic NCCs rather than postotic NCCs (Arima Y et al. Nature Communications 3:1267, 2012). In addition, coronary artery SMCs have been reported to differentiate through pericyte intermediates (Volz KS et al., eLife 4:1–22, 2015). Consistent with these findings, our present lineage-tracing analyses using Sox9-CreERT2; Ai14 and Scx-CreERT2; Ai14 mice demonstrated that progenies of Sox9high and Scxhigh intracardiac cushion mesenchymal cells contributed to the coronary artery SMCs as well as the surrounding mesenchyme.

       We agree with the reviewer that the relationship between the early intracardiac mesenchymal clusters (C2, C10, and C22) and C23 is primarily inferred from computational trajectory analyses and is not demonstrated by direct clonal lineage tracing. Accordingly, we revised the Discussion to avoid overstatement and to clarify that these lineage relationships are inferred based on computational analyses together with prior experimental findings and the additional validation data described above. The revised text is as follows:
      
      • *

      (original) Our integrated map incorporates previously published lineage analyses of cardiac NCCs at early and late stages13,14, providing continuity through complementary single-cell and spatial transcriptomic data, although our interpretation of certain clusters differs from those of prior studies. For example, the cell population identified by De Bono et al. as outflow smooth muscle13corresponds in our dataset to early intracardiac mesenchymal clusters C2, C10, and C22, present as early as E10.5, when mesenchymal NCC derivatives express immature SMC markers. These cells later differentiate into coronary artery SMCs around E14.5 (C23) as well as other non-muscle components. Despite such differences in interpretation, the integrated map robustly captures lineage relationships, supported by accumulated developmental and anatomical evidence regarding cardiac outflow tract formation, particularly in relation to the outflow tract cushion.

      (revised) Our integrated map incorporates previously published lineage analyses of cardiac NCCs at early and late stages13,14, providing continuity through complementary single-cell and spatial transcriptomic data. The present study further extends these datasets by resolving the heterogeneity of intracardiac mesenchymal populations and their lineage relationships. For example, the cell population identified by De Bono et al. as outflow smooth muscle13 corresponds in our dataset to early intracardiac mesenchymal clusters expressing immature SMC markers, which subsequently diverged into multiple derivatives including coronary artery SMCs. In addition, we identified distinct SMC populations corresponding to great artery SMCs, ductus arteriosus SMCs, and coronary artery SMCs, each characterized by unique molecular signatures such as Sost, Tfap2b/Ptger4, and Reln/Gja4, respectively. The continuity between intracardiac mesenchyme and coronary artery SMCs through a pericyte-like intermediate state is consistent with previous developmental studies showing that proximal coronary artery SMCs originate from preotic NCCs and may arise through pericyte intermediates8,21. Together, these findings provide a refined framework for understanding the diversification of cardiac NCC derivatives during outflow tract remodeling.

      (P18, L14–29)

      * Claims regarding marker expression in specific compartments (for example Hapln1 and Postn in cushions) require additional spatial validation at higher resolution than what is currently provided by the Visium data. Moreover, it is unclear whether these data are single-cell resolution; the authors need to clarify this. HCR staining would be ideal to confirm these expression patterns. Currently, all conclusions are based solely on gene expression without orthogonal spatial confirmation. At minimum, the authors should provide references from the literature supporting these expression patterns. *

      As reviewer suggested, the confirmation of spatial context for the gene expression patterns of scRNA-seqs data is important to validate. We further investigated the spatial expression patterns through Xenium in situ hybridization system. Among cardiac mesenchyme subpopulation, Postn was dominantly expressed, however, Tcf24 was specifically expressed in AP septum (C16) not in cushion (C2, 10, 18, 21 and 22) in scRNA-seq data. On the other hand, Vegfc was expressed except in the AP septum. To confirm these opposing expression patterns, we newly added Figure S5, showing Tcf24 and Vegfc expression revealed by Xenium.

      According to the reviewer’s suggestion, we added the sentence in the revised manuscript as follows:

      C16 was distinguished by high expression of Penk and Sfrp2 (Figure S3i and Table S6), corresponding to the cluster annotated as the aorticopulmonary septum in the previous study by Chen et al14. This cluster also exhibited robust expression of mesenchymal markers, including Postn, similar to other intracardiac clusters (Figure S3i). In addition, C16 showed relatively high expression of Tcf24 and low expression of Vegfc compared with the other intracardiac clusters (Figure S5a-e). These gene expression features of the aorticopulmonary septum were further validated by Xenium in situ hybridization (Figure S5f-j).

      (P9, L24–31)

      * Could the authors confirm the absence of the Sox9high/Scxhigh population in AP septum descendants? *

      Sox9high/Scxhigh NCCs are enriched not only in intracardiac NCC clusters C2, C10, and C14, but also in the AP septum-associated cluster C16, as stated in the manuscript as follows:

      In the integrated UMAP, Sox9high/Scxhigh NCCs were enriched in C2, C10, C14 and C16.

      (P17, L7–8)

      However, based on our previous finding that proximal coronary artery SMCs originate from preotic rather than postotic NCCs (Arima Y et al. Nature Communications 3:1267, 2012), we infer that the intermediate population contributing to coronary artery SMCs is more likely derived from intracardiac NCC clusters C2 and C10 than from the pharyngeal arch 4/6-derived AP septum-associated cluster C16. To clarify this interpretation, we have added the following statement to the final paragraph of the Results section:

      Together with our previous report that proximal coronary artery SMCs originate from preotic rather than postotic NCCs8, these results suggest that the intermediate population contributing to coronary artery SMCs likely represents a subset of Hox-downregulated intracardiac NCCs corresponding to clusters C2 and C10.

      (P17, L29–33)

      Minor Comments *Could the authors better justify their choice of stages (E11.5 to E17.5) for the single-cell multiomic assay? Given that OFT cushions are already populated by NCCs by E10.5 and that AP septum formation is already underway at this stage (see Development (2007) 134(8): 1593-1604), the rationale for beginning at E11.5 should be explicitly stated. *

      We agree that NCCs have already populated the OFT cushions and that AP septum formation is underway by E10.5. Our selection of stages from E11.5 to E17.5 was intended primarily to enable synchronous comparisons between pharyngeal and intracardiac NCC populations across developmental stages, rather than to capture the earliest spatiotemporal events of cardiopharyngeal NCC lineage establishment. We have clarified this rationale in the revised manuscript by revising the statement as follows:

      • *

      (original) To elucidate the spatiotemporal dynamics of cardiopharyngeal NCC lineages, we performed single-cell multiome analysis on pharyngeal and cardiac tissues from E11.5 and E12.5 and ...

      • *

      (revised) To compare pharyngeal and intracardiac NCCs across developmental stages and characterize their temporal changes, we performed single-cell multiome analysis on pharyngeal and cardiac tissues from E11.5 and E12.5 and ...

      (P6, L3-5)

      • *

      • *

      *Spelling errors in Figure 2e: "ambious" should be "ambiguous"; "atrium venticle" should be "atrium/ventricle"; "ventricle" is misspelled in several locations. The clustering resolution is very high, yielding many clusters that are difficult to distinguish based on the colour code alone. What does "ventricle_CL" refer to? What is the "marginal layer"? A clearer legend or supplementary table defining each cluster would be helpful. *

      To improve the clarity of the high-resolution clustering, we added Xenium cluster numbers to Figures 2c and 2d, enabling clusters to be distinguished not only by color but also by their anatomical locations. We also revised the cluster annotations in Figure 2e and corrected all spelling errors, including “ambiguous,”. In addition, we replaced “ventricle_CL” with “Cardiac muscle 1” and the formerly misspelled “atrium ventricle CM” with “Cardiac muscle 2.” The annotation “marginal layer” was also revised to “Spinal cord, marginal layer” for clarity.

      *Figure 2j: The image is very dim. *

      • *

      We have improved the image quality and added regional annotations to enhance visibility in the revised figure.

      * Figure 3b: What do the numbers correspond to? Additionally, "mesenchyme" is misspelled. *

      We have revised Figure 3b to clarify different characteristics of mesenchymal subpopulations. We have also corrected the misspelling of “mesenchyme.”

      **Referees cross-commenting**

      *I also agree with the other reviewers' comments. Many thanks. *

      Reviewer #2 (Significance (Required)):

      *The overall approach is sound and the datasets generated are valuable resources for the field. The manuscript presents interesting findings regarding NCC heterogeneity in cardiac development.

      As I understand the authors' model: OFT cushion-associated NCCs enter and associate with the OFT cushions, undergoing a Hox-positive to Hox-negative transition, accompanied by a shift in Meis binding and GRN rewiring. These cells pass through a Meis2-Sox9-Scx "skeletogenic progenitor-like" intermediate state and contribute to semilunar valves and coronary artery smooth muscle. Aorticopulmonary septum NCCs, by contrast, retain distinct Hox codes (Hox4/5 enrichment) rather than becoming Hox-negative, and contribute to the AP septum and great vessel smooth muscle.

      Strengths: The integration of multiple omics modalities with lineage tracing is a powerful approach, and the identification of a Hox-dependent bifurcation in NCC fate is a novel conceptual advance.

      Limitations: The reliance on computational trajectory inference without orthogonal lineage validation, combined with the integration of datasets spanning very different developmental stages, limits the strength of some conclusions. The analysis also required more precise anatomical annotations to facilitate accessibility to the readers - to visualise better the distinguishable contribution of the cardiac NCCs to the OFT.

      Advance The study extends knowledge in the field by providing novel mechanistic insight into neural crest diversification in the context of cardiovascular development. The nature of the advance is primarily mechanistic, identifying a Hox-Meis regulatory switch that distinguishes cushion-associated from cushion-independent NCC lineages.

      Audience This work will be of interest to a specialised audience interested in neural crest cells and developmental biologists using omics approaches to address cell fate diversification in complex tissues.

      Reviewer Expertise Developmental biology, lineage analysis, mouse genetics. I do not have the expertise to assess the computational methods used in this paper. *

      Again, thank you for giving us the opportunity to strengthen our manuscript with your valuable comments and queries. We have worked hard to incorporate your feedback and hope that these revisions persuade and satisfy you.

      To Reviewer #3

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      Summary: *Iwase et al. presents a comprehensive multiomics analyses of cardiac neural crest cell (NCC) differentiation during cardiopharyngeal development. Using Wnt1Cre;R26R-EYFP mice, the authors isolated NCCs and non-NCCs at E11.5, E12.5, E14.5 and E17.5 stages and performed single-cell RNA-seq, ATAC-seq, spatial transcriptomics analyses. Spatial resolution of NCC-derived populations was achieved using Xenium (E11.5-E12.5) and Visium (E14.5-E17.5) platforms. Integration of single cell and spatial datasets identified distinct NCC-derived populations with defined spatial organization within the pharyngeal and intracardiac regions. The study concludes that Hox gene patterning underlies NCC subpopulation identity during cardiopharyngeal development and reveals a developmental transition from Hox-dependent to Hox-independent transcriptional regulation. Furthermore, the authors identify a Meis2-Sox9-Scx gene regulatory network making a skeletogenic progenitor-like intermediate that contribute to coronary smooth muscle and semilunar valve formation.

      While the dataset is comprehensive and technically strong, several key conclusions are not always convincingly supported by enough data. As a result, some claims appear speculative and would benefit from additional experimental validation to strengthen the proposed developmental models.

      I would strongly encourage authors to consider the following points to provide additional details that will strengthen their study: *

      Thank you for your encouraging feedback and comments. We have responded to your comments below.

      Major comments:

      *- The authors should provide detailed FACS gating strategies and sorting conditions used to selectively isolate EYP-positive and EYP-negative NCC populations, including representative plots and information on exclusion criteria (e.g., doublets, dead cells). *

      • *

      We added the sorting gates to the revised Figure S1 and described the detailed FACS gating strategy and sorting conditions in the revised Methods section as follows:

      • *

      (original) EYFP-positive and -negative single cells were sorted using a FACSAria II or FACSMelody (BD Biosciences), freshly processed or cryopreserved.

      • *

      (revised) Single-cell suspensions were stained with 7-AAD (BD Pharmingen) for 3 min at 4℃, and EYFP-positive and -negative single cells were sorted using a FACSAria II or FACSMelody (BD Biosciences). The sorting strategy was as follows:

      *Step 1. All events were gated by forward scatter (FSC) and side scatter (SSC) including area (A), height (H), and width (W) to obtain FSC singlets and remove doublets. *

      *Step 2. FSC singlets were gated for the 7-AAD negative fraction to isolate viable cells. *

      *Step 3. Viable cells were gated to isolate EYFP-positive NCCs or EYFP-negative non-NCCs. *

      Sorted cells were freshly processed or cryopreserved for the following procedure.

      (P28, L21–30)

      * - Although the authors isolated nuclei for both scRNA-seq and ATAC-seq, the number of cardiomyocytes within the EYFP-negative population is unexpectedly low. The authors should clarify potential technical or biological reasons for this underrepresentation (e.g., nuclei isolation efficiency, sorting strategy, filtering criteria, or developmental stage-specific composition). *

      • *

      The unexpectedly low proportion of cardiomyocytes within the EYFP-negative population likely reflects the restricted sampling region used in this study. Specifically, we dissected cardiopharyngeal tissue and the outflow tract region rather than the whole heart as shown in Figure 1a, which likely introduced a sampling bias that reduced the representation of cardiomyocytes in the dataset.

      Although the FACS gating strategy could potentially influence the recovery of specific cell types, we consider this possibility unlikely because cardiomyocyte populations were successfully detected in our dataset. In addition, during the quality-control process for scRNA-seq data, we applied a mitochondrial gene threshold of 25% to exclude low-quality cells. While mature cardiomyocytes typically exhibit high mitochondrial gene expression, embryonic cardiomyocytes at the analyzed developmental stages are immature and therefore were unlikely to be disproportionately excluded by this criterion. Consistent with this interpretation, distinct cardiomyocyte clusters remained detectable after filtering, indicating that cardiomyocytes were retained through the quality-control process.

      Based on these considerations, we conclude that the low abundance of EYFP-negative cardiomyocytes primarily reflects the limited anatomical region sampled. We have clarified this point in the revised Results section as follows:

      The overall proportion of cardiomyocytes was low, likely reflecting the restricted sampling of the cardiac outflow tract region (Figure 1a).

      (P6, L23–25)

      * - In figure 1, the authors present results from unsupervised clustering of 9,420 cells into 21 distinct clusters, many of which are broadly labeled as "mesenchymal cells". The authors should refine this nomenclature by providing more specific annotations or defining criteria, as this broad classification limits interpretability of the identified subpopulations. *

      • *

      In the revised manuscript, we further refined the clustering analysis by subdividing the original clusters C5 and C13 into two subclusters each, resulting in a total of 23 clusters in the UMAP shown in Figure 1d. This refinement improved the resolution and interpretability of the identified cell populations. In addition, we replaced the broad “mesenchymal cells” annotation with more specific classifications, including pharyngeal mesenchymal cells, intracardiac mesenchymal cells, and smooth muscle–like cells. To further clarify lineage relationships, we also provided UMAPs separately displaying NCC and non-NCC populations in Figure 1e, as suggested by the reviewer.

      *- To integrate spatial annotated Xenium datasets with scRNA-seq data, the authors used Tangram, enabling estimation of the spatial distribution of EYFP-positive NCCs within the pharyngeal region of E11.5 and 12.5 embryos. However, the E11.5 section show a relatively low number of EYFP-positive cells (Figure 2f). The authors should clarify whether this reflects technical limitations (e.g., probe design, segmentation efficiency, or integration parameters) or biological factors and explain how this affects interpretation of the spatial analyses. *

      *- The author used RCTD tool to decompose the scRNA-seq dataset into NCC and non-NCC components and mapped these onto the Xenium dataset. However, panels j and l in Figure 2 show low signal in the E11.5 sections. The authors should clarify whether this reflects technical limitations of the RCTD deconvolution, differences in sampling, or biological factors, and discuss how this result impacts of interpretation of the spatial mapping results at this stage. *

      • *

      In the original manuscript, estimated EYFP expression levels were visualized using a minimum cutoff of 0.1, with the remaining values mapped onto a 100-step color scale. However, this approach resulted in apparently weak signal intensity in the E11.5 sections because high-level noisy signals, including signals detected in the atrial lumen and outside the embryo, broadened the dynamic range of the visualization. In the revised manuscript, we applied an upper cutoff at the 90th percentile to reduce the influence of these noisy signals, resulting in improved visualization of EYFP-positive regions in Figure 2f, with signal intensity now comparable to that observed in Figure 2g. In addition, we further improved the spatial visualization of putative EYFP-positive cells by replacing centroid-based signal display with segmentation-based rendering in the revised Figure 2f, g. Importantly, these revisions affected only the visualization method and did not alter the underlying analyses or conclusions, as the integration and downstream analyses were performed using the original quantitative data.

       We also clarified the procedure used for NCC estimation and spatial mapping in the Methods section as follows:
      

      Putative NCCs were identified through the following procedure:

      Step 1. EYFP expression was estimated across 39 cell types in the Xenium dataset by integration with the single-cell multiome dataset (including both NCCs and non-NCCs) using Tangram.

      Step 2. Xenium clusters enriched for EYFP expression, defined as clusters whose mean estimated EYFP level exceeded the threshold corresponding to the 65th percentile across all spots, and consistent with known neural crest derivatives were extracted as putative NCC populations.

      Step 3. For each spot within these EYFP-enriched Xenium clusters, RCTD was used to estimate the corresponding multiome cluster identity.

      (P33, L7–16).

      *- The authors integrated their data with publicly available scRNA-seq datasets of NCCs from E8.5 to P7 hearts and present results from unsupervised clustering of 67,208 cells into 28 distinct clusters. Figures 3a and 3b show that cardiomyocyte (C26) is included in NCC-derivatives. The authors should clarify whether this reflects technical issue when they made FACS. *

      • *

      In our original datasets in Figure 1d, only a small number of NCCs were detected within the cardiomyocyte cluster (corresponding to C26 in Figure 3b), which was otherwise predominantly composed of non-NCCs. Cardiomyocytes assigned to C26 were also present in both publicly available scRNA-seq datasets included in the integrated analysis. Previous studies have reported that a limited subset of NCCs can differentiate into cardiomyocytes (Tomita, Y. et al., J. Cell Biol. 170:1135–1146, 2005; Tamura, Y. et al., Arterioscler. Thromb. Vasc. Biol. 31:582–589, 2011). Therefore, we consider that C26 likely represents a small population of NCC-derived cardiomyocytes rather than contamination caused by technical issues during FACS isolation, although the low cell number precluded further characterization.

       To clarify this point, we added the following statement to the Results section:
      
      • *

      *Only a few NCCs were detected within cardiomyocyte clusters, which were predominantly composed of non-NCCs, consistent with previous reports demonstrating NCC differentiation into cardiomyocytes15,16. *

      (P6, L20–23)

      * - The authors used RNA-velocity to infer relationship among the identified clusters. However, this analysis requires particular caution given that data were generated from multiple datasets obtained under different conditions. Several conclusions drawn from the RNA-velocity analysis are not convincing, as illustrated in Figures 3c and 3d, where the inferred velocity directions appear inconsistent with the proposed developmental model (e.g., trajectory from cluster 23 toward 18 or from 4 toward 6). The authors should clarify these discrepancies, justify the integration of heterogenous datasets and reassess the interpretation of the inferred lineage relationships. *

      In the default setting, the integration workflow provided by Seurat which is widely used for scRNA-seq analysis employs canonical correlation analysis (CCA). CCA effectively corrects batch effects across datasets generated from different experimental platforms. However, it sometimes causes overcorrection to attempt to forcibly integrate different cell populations that are not shared among datasets (Andreatta, Bioinformatics, 2021). To minimize overcorrection for multiple datasets obtained under different experimental conditions, we applied reciprocal principal component analysis (RPCA) method recommended for comparative integration of heterogeneous scRNA-seq datasets (Luecken et al., Nature Methods, 2021). This selection is suitable for the integration of multiple datasets provided by different independent studies as in case of the present study.

       To infer relationship among the identified clusters, we then used RNA velocity analysis of scRNA-seq data fundamentally based on splicing dynamics. The original framework assumes that transcriptional induction and repression persist long enough for cells to reach active (transcribing) or inactive (silenced) steady-state equilibrium. However, this assumption is often violated during cell differentiation, where transient cell populations frequently exhibit rapidly changing mRNA levels that do not reach steady-state equilibrium. To address this limitation, the scVelo method was developed (Bergen et al., 2020, *Nature Biotechnology*), and we applied this approach to the integrated NCC datasets in the present study. This analysis successfully inferred directional flows from the pharyngeal mesenchyme toward SMCs and intracardiac mesenchyme through transitional states (Figure 3c,d). However, as the reviewer correctly pointed out, the analysis predicted a directional flow from C23 to C18, apparently opposite to the biological directionality supported by previous findings (see P9, L15–19).
      
       We consider this discrepancy to reflect intrinsic limitations of RNA velocity analysis. As discussed by Bergen et al., in systems containing multiple lineages and cellular processes, differences in gene regulatory networks among heterogeneous cell states can generate multiple trajectories in phase space owing to distinct splicing kinetics. In addition, incompletely captured splicing kinetics may represent only a limited portion of the overall dynamics, particularly near terminal differentiation states. In such cases, phase portraits of unspliced versus spliced transcripts may appear nearly linear rather than curved, potentially leading to erroneous assignment of positive or negative RNA velocities. Consistent with this limitation, we obtained opposite directionalities between C18 and C23 depending on whether steady-state or dynamical models were applied and according to different parameter settings. Through these repeated computational re-evaluations of lineage directionality, we concluded that RNA velocity analysis is suitable for capturing the global landscape of differentiation flow, but that accurate inference of local lineage directionality may require careful model selection and parameter optimization to ensure consistency with established biological evidence.
      
       To avoid arbitrariness and potential confusion, we removed the arrow between C18 and C23 from the revised Figure 3d. Instead, we now describe the observed continuity between these populations in the Results and Discussion sections as follows:
      

      Notably, the UMAP revealed a continuum between C23 and C18 within the intracardiac mesenchyme population. Given previous findings that the proximal coronary artery SMCs originate from preotic NCCs8 and that pericytes give rise to coronary artery SMCs23, this connection likely represent a differentiation trajectory from intracardiac mesenchyme to coronary artery SMCs via a pericyte-like intermediate stage.

      (P9, L15–19)

      The continuity between intracardiac mesenchyme and coronary artery SMCs through a pericyte-like intermediate state is consistent with previous developmental studies showing that proximal coronary artery SMCs originate from preotic NCCs and may arise through pericyte intermediates8,21.

      (P18, L24-27)

      *- The authors should provide more detail on how they identified bifurcation points and more clearly explain the transition from intracardiac mesenchyme to smooth muscle cells (SMC). Additionally, they should clarify what distinguishes the three clusters (C4, C23, C27) in terms of transcription programs, marker expression, or functional states, to better support their proposed differentiation trajectories. *

      To clarify the distinctions among the three SMC clusters (C4, C23, C27), we added a heatmap showing differentially expressed genes, violin plots for the mature SMC marker Myh11, and feature plots with immunostaining images for Myh11, Sost, and Reln expression (Figure S4). These additional analyses further validate the molecular and spatial characteristics of the three SMC clusters. Based on these data, we revised the relevant section of the Results as follows:

      The SMC clusters, which were continuous with the pharyngeal mesenchyme via transitional populations in the UMAP, were identified by high expression of the mature SMC marker Myh11 (Figure 3i). Differential gene expression analysis further distinguished individual clusters (Figure S4a-g). Among these, C27 displayed a transcriptomic profile characteristic of the great artery SMCs, including high expression of Sost (Figure S3j). C4 was enriched for Tfap2b and Ptger4 (Figure S3j), markers of the ductus arteriosus SMCs21,22, supporting its annotation. C0 and C7 likely represent transitional states between pharyngeal mesenchyme and differentiated lineages, potentially bifurcating toward great artery SMCs or cardiac cushion mesenchyme (Figure S3a and Table S6). C23 was characterized by high expression of Gja4, a marker of coronary artery SMCs, along with pericyte markers Kcnj8 and Rgs5 (Figure 3j and Figure S3k), corresponding to the cluster similarly annotated by Chen et al14. In addition, C23 was also distinguished from C4 and C27 by its expression of Reln (Figure S4d).

      • Immunostaining supported these cluster annotations. Sost expression is observed in great artery SMCs but not in ductus arteriosus and coronary artery SMCs, whereas Myh11 expression was higher in ductus arteriosus and coronary artery SMCs than in aortic SMCs (Figure S4f-m). Furthermore, Reln expression was restricted to coronary artery SMCs (Figure S4n-s).*

      (P8, L30 – P9, L14)

      To further clarify the identification of bifurcation points and the transition from intracardiac mesenchyme to SMCs, we additionally stratified the integrated UMAP according to distinct Hox expression profiles and inferred lineage trajectories corresponding to different neural crest and pharyngeal arch origins (Figure S9). Based on the inferred differentiation trajectory from C18 to C23 (P9, L15–19), together with the identification of C2 and C10 as Sox9high and Scxhigh intracardiac cushion mesenchymal populations contributing to coronary artery SMCs (P17, L27–33), we incorporated these lineage relationships into the schematic model presented in Figure 9.

      Minor comments:

      *- The authors convincingly demonstrate a switch in Meis-binding motifs across NCC populations, supporting a model in which cardiac cushion-associated NCCs transition from Hox-dependent to Hox-independent transcriptional regulation via alternative cofactor interactions and DNA-binding preferences. However, the authors should provide evident on whether GATA motifs are enriched within Meis peaks, as this could further clarify potential cooperative interactions during this transition. *

      Although GATA-binding motifs were enriched within Meis-associated open chromatin regions in intracardiac NCCs compared with many other motifs, a substantial proportion of GATA motifs were located in peaks distinct from those containing Meis motifs. This observation raises the possibility that GATA and Meis transcription factors may cooperate through interactions across separate regulatory elements to modulate enhancer activity. However, we did not directly investigate this possibility in the present study. Instead, we found that the Meis-associated peaks identified in intracardiac NCCs, including the distal Sox9 enhancer containing a Meis2-binding site (chr11:112850240–112851186), more prominently contained several other consensus motifs, including predicted Hand2- and Nfatc1-binding sites. To our knowledge, however, these transcription factors have not previously been described as non-Hox cofactors of Meis proteins. Their potential recruitment to this enhancer, as well as possible cooperative interactions with Meis transcription factors during intracardiac NCC differentiation, was not examined in the current study and remains an important subject for future investigation.

      * - In Figure 5 panels g, j and k are difficult to interpret. The authors should provide clearer annotations, labeling, or additional explanations to improve readability and facilitate understanding of the data. *

      • *

      We added the annotations to UMAP in Figure 6h (and 6i) corresponding to Figure 4a and included color bars in Figure 6k as well as in 6i. To further improve readability and facilitate understanding of the data, we added the explanation of the perturbation scores in the legends for Figure 6i and k.

      (original)

      *(g) Pseudotime trajectory analysis of integrated NCC clusters inferred using CellOracle. *

      *(h-k) Sox9 (h, i) and Osr1 (j, k) knockout simulation presented as altered differentiation vector flows (h, j) and perturbation scores which was inner product of perturb simulation (i, k). *

      • *

      (revised)

      *(g) Pseudotime developmental flow of integrated NCC clusters from the neural tube, inferred using CellOracle and projected onto the UMAP space shown in Figure 4a. *

      *(h-k) Sox9 (h, i) and Osr1 (j, k) knockout simulations presented as altered differentiation vector flows (h, j) and perturbation scores, defined as the inner product between the simulated perturbation vectors and the original developmental flow (i, k). Green and magenta color bars indicate normal developmental flow and reverse flow induced by perturbation of the indicated genes, respectively. *

      (P41, L3–L9)

      *- In Figure 6, results support the role of hexameric Meis-binding motif-containing region as a distal enhancer of Sox9. The authors should provide additional results from a ChIP-qPCR experiment to further validate this model. *

      • *

      We attempted ChIP-seq experiments on O7-1 neural crest cell line using two different anti-Meis antibodies. However, we were unable to detect specific binding of Meis proteins to this enhancer region, although the luciferase assays clearly demonstrated the enhancer activity that was significantly attenuated by deletion of the Meis-binding motif. This discrepancy may reflect differences between endogenous chromatin and plasmid-based reporter contexts, including epigenetic modifications and chromatin accessibility. We are now investigating experimental conditions that would allow direct verification of endogenous Meis binding to this region.

      * - Panel l in Figure S3 requires better annotation. *

      • *

      We added annotations including the aorta, pulmonary valve, left coronary artery, and its septal branch.

      * - Correct the typo errors in Figure 5a. *

      • *

      The typographical errors “consercvation” and “Visuzalization” were corrected to “conservation” and “Visualization”, respectively.

      * - The authors should refer to previous studies showing the role of Hoxa1 and Hoxb1 in the development of great arteries or semilunar valves. *

      We have added the following discussion on the roles of anterior Hox genes in cardiovascular development, together with appropriate references:

      • The regional identities of pharyngeal NCCs that contribute to cardiac development are established by Hox genes and their associated regulatory networks. Genetic studies have demonstrated essential roles for the anterior Hox genes in patterning the pharyngeal arch artery system and semilunar valve structures. Loss of Hoxa1 and Hoxb1 results in severe defects in pharyngeal arch artery development42, whereas ectopic or sustained expression of Hoxb1 in NCCs disrupts cardiovascular morphogenesis and causes malformations of the great arteries and semilunar valves43. Likewise, Hoxa3 contributes to proper patterning of the pharyngeal arch region and its NCC-derived derivatives44,45. These findings underscore the importance of precise spatial and temporal regulation of Hox genes during cardiovascular development. Among pharyngeal NCCs contributing to cardiac development, cushion-independent NCC derivatives (great artery SMCs and the aorticopulmonary septum) retain their origin-specific Hox-codes. In contrast, cushion-associated NCC derivatives (coronary artery SMCs and valvular/subvalvular interstitial cells) downregulate Hox expression and transition toward region-specific GRNs involving TFs such as Tbx20 and Gata4, whose expression is known to be induced by BMP signaling in cardiomyocytes46,47. Bmp2 and Bmp4 are expressed in the regions of the pericardial reflection traversed by NCCs en route to the cardiac cushion48. Together, these observations suggest that appropriate repression of Hox programs, coupled with activation of cardiac-specific regulatory networks, is required for normal differentiation of cushion-associated NCC derivatives.*

      (P18, L30 – P19, L16)

      • Roux, M. et al. Hoxa1 and Hoxb1 are required for pharyngeal arch artery development. Mech. Dev. 143, 1–8 (2017).*
      • Zaffran, S., Odelin, G., Stefanovic, S., Lescroart, F. & Etchevers, H. C. Ectopic expression of Hoxb1 induces cardiac and craniofacial malformations. genesis 56, (2018).*
      • Chisaka, O. & Capecchi, M. R. Regionally restricted developmental defects resulting from targeted disruption of the mouse homeobox gene hox-1.5. Nature 350, 473–479 (1991).*
      • Kameda, Y., Watari-Goshima, N., Nishimaki, T. & Chisaka, O. Disruption of the Hoxa3 homeobox gene results in anomalies of the carotid artery system and the arterial baroreceptors. Cell Tissue Res. 311, 343–352 (2003).*

      **Referees cross-commenting**

      *Having read the comments of the other reviewers, I totally agree with them. All our comments converge and should allow the authors to improve their manuscript. *

      Reviewer #3 (Significance (Required)):

      *The study provides high-resolution spatial and temporal mapping of NCC-derived populations and proposes mechanistic insights into Hox-dependent versus Hox-independent transcriptional regulation, as well as a Meis2-Sox9-Scx gene regulatory network contributing to smooth muscle and semilunar valve formation.

      Strengths and limitations: The datasets are rich and well-integrated, offering valuable resources for the field. However, several key conclusions rely on correlative analyses and heterogeneous datasets, making some claims speculative. Technical details, such as FACS gating, low representation of cardiomyocytes, and interpretation of RNA velocity, require further clarification, which currently limits the strength of the mechanistic inferences.

      Advance: This work advances the understanding of NCC lineage diversification and gene regulatory dynamics in cardiopharyngeal development, particularly highlighting potential transcriptional switches and intermediate progenitor states that guide structural formation in the heart.

      Audience: The study will be of interest to researchers in developmental biology, cardiovascular biology, and single-cell multi-omics, particularly those studying neural crest cell differentiation and cardiac morphogenesis.*

      Again, thank you for giving us the opportunity to strengthen our manuscript with your valuable comments and queries. We have worked hard to incorporate your feedback and hope that these revisions persuade and satisfy you.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      Iwase et al. presents a comprehensive multiomics analyses of cardiac neural crest cell (NCC) differentiation during cardiopharyngeal development. Using Wnt1Cre;R26R-EYFP mice, the authors isolated NCCs and non-NCCs at E11.5, E12.5, E14.5 and E17.5 stages and performed single-cell RNA-seq, ATAC-seq, spatial transcriptomics analyses. Spatial resolution of NCC-derived populations was achieved using Xenium (E11.5-E12.5) and Visium (E14.5-E17.5) platforms. Integration of single cell and spatial datasets identified distinc NCC-derived populations with defined spatial organization within the pharyngeal and intracardiac regions. The study concludes that Hox gene patterning underlies NCC subpopulation identity during cardiopharyngeal development and reveals a developmental transition from Hox-dependent to Hox-independent transcriptional regulation. Furthermore, the authors identify a Meis2-Sox9-Scx gene regulatory network making a skeletogenic progenitor-like intermediate that contribute to coronary smooth muscle and semilunar valve formation.

      While the dataset is comprehensive and technically strong, several key conclusions are not always convincingly supported by enough data. As a result, some claims appear speculative and would benefit from additional experimental validation to strengthen the proposed developmental models.

      I would strongly encourage authors to consider the following points to provide additional details that will strengthen their study:

      Major comments:

      • The authors should provide detailed FACS gating strategies and sorting conditions used to selectively isolate EYP-positive and EYP-negative NCC populations, including representative plots and information on exclusion criteria (e.g., doublets, dead cells).
      • Although the authors isolated nuclei for both scRNA-seq and ATAC-seq, the number of cardiomyocytes within the EYPF-negative population is unexpectedly low. The authors should clarify potential technical or biological reasons for this underrepresentation (e.g., nuclei isolation efficiency, sorting strategy, filtering criteria, or developmental stage-specific composition).
      • In figure 1, the authors present results from unsupervised clustering of 9,420 cells into 21 distinct clusters, many of which are broadly labeled as "mesenchymal cells". The authors should refine this nomenclature by providing more specific annotations or defining criteria, as this broad classification limits interpretability of the identified subpopulations.
      • To integrate spatial annotated Xenium datasets with scRNA-seq data, the authors used Tangram, enabling estimation of the spatial distribution of EYFP-positive NCCs within the pharyngeal region of E11.5 and 12.5 embryos. However, the E11.5 section show a relatively low number of EYFP-positive cells (Figure 2f). The authors should clarify whether this reflects technical limitations (e.g., probe design, segmentation efficiency, or integration parameters) or biological factors and explain how this affects interpretation of the spatial analyses.
      • The author used RCTD tool to decompose the scRNA-seq dataset into NCC and non-NCC components and mapped these onto the Xenium dataset. However, panels j and l in Figure 2 show low signal in the E11.5 sections. The authors should clarify whether this reflects technical limitations of the RCTD deconvolution, differences in sampling, or biological factors, and discuss how this result impacts of interpretation of the spatial mapping results at this stage.
      • The authors integrated their data with publicly available scRNAs-eq datasets of NCCs from E8.5 to P7 hearts and present results from unsupervised clustering of 67,208 cells into 28 distinct clusters. Figures 3a and 3b show that cardiomyocyte (C26) is included in NCC-derivatives. The authors should clarify whether this reflects technical issue when they made FACS.
      • The authors used RNA-velocity to infer relationship among the identified clusters. However, this analysis requires particular caution given that data were generated from multiple datasets obtained under different conditions. Several conclusions drawn from the RNA-velocity analysis are not convincing, as illustrated in Figures 3c and 3d, where the inferred velocity directions appear inconsistent with the proposed developmental model (e.g., trajectory from cluster 23 toward 18 or from 4 toward 6). The authors should clarify these discrepancies, justify the integration of heterogenous datasets and reassess the interpretation of the inferred lineage relationships.
      • The authors should provide more detail on how they identified bifurcation points and more clearly explain the transition from intracardiac mesenchyme to smooth muscle cells (SMC). Additionally, they should clarify what distinguishes the three clusters (C4, C23, C27) in terms of transcription programs, marker expression, or functional states, to better support their proposed differentiation trajectories.

      Minor comments:

      • The authors convincingly demonstrate a switch in Meis-binding motifs across NCC populations, supporting a model in which cardiac cushion-associated NCCs transition from Hox-dependent to Hox-independent transcriptional regulation via alternative cofactor interactions and DNA-binding preferences. However, the authors should provide evident on whether GATA motifs are enriched within Meis peaks, as this could further clarify potential cooperative interactions during this transition.
      • In Figure 5 panels g, j and k are difficult to interpret. The authors should provide clearer annotations, labeling, or additional explanations to improve readability and facilitate understanding of the data.
      • In Figure 6, results support the role of hexameric Meis-binding motif-containing region as a distal enhancer of Sox9. The authors should provide additional results from a ChiP-qPCR experiment to further validate this model.
      • Panel l in Figure S3 requires better annotation.
      • Correct the typo errors in Figure 5a.
      • The authors should refer to previous studies showing the role of Hoxa1 and Hoxb1 in the development of great arteries or semilunar valves.

      Referees cross-commenting

      Having read the comments of the other reviewers, I totally agree with them. All our comments converge and should allow the authors to improve their manuscript.

      Significance

      The study provides high-resolution spatial and temporal mapping of NCC-derived populations and proposes mechanistic insights into Hox-dependent versus Hox-independent transcriptional regulation, as well as a Meis2-Sox9-Scx gene regulatory network contributing to smooth muscle and semilunar valve formation.

      Strengths and limitations: The datasets are rich and well-integrated, offering valuable resources for the field. However, several key conclusions rely on correlative analyses and heterogeneous datasets, making some claims speculative. Technical details, such as FACS gating, low representation of cardiomyocytes, and interpretation of RNA velocity, require further clarification, which currently limits the strength of the mechanistic inferences.

      Advance: This work advances the understanding of NCC lineage diversification and gene regulatory dynamics in cardiopharyngeal development, particularly highlighting potential transcriptional switches and intermediate progenitor states that guide structural formation in the heart.

      Audience: The study will be of interest to researchers in developmental biology, cardiovascular biology, and single-cell multi-omics, particularly those studying neural crest cell differentiation and cardiac morphogenesis.

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      Summary

      In this manuscript, Iwase et al. cleverly make use of different modalities, spatial transcriptomics and single-cell omics datasets, in conjunction with a well-established Wnt1-Cre;R26R-EYFP line to trace neural crest cells (NCCs) contributing to the cardiovascular system during embryonic development in the mouse. By doing so, the authors identified a bifurcation between cardiac NCCs contributing to the OFT cushions and forming the aorticopulmonary (AP) septation complex. Thus, the authors split "intracardiac NCCs" into two different NCC programs/compartments, even though both reside in the broad OFT region. The NCCs that enter and associate with the OFT cushions undergo a Hox off transition (Hox-positive to Hox-negative once intracardiac), with a corresponding shift in Meis binding and GRN wiring. The authors propose these cells pass through a Meis2-Sox9-Scx "skeletogenic progenitor-like" intermediate and contribute to semilunar valves and coronary artery smooth muscle. By contrast, the NCCs assigned to aorticopulmonary septum (APS) formation and great vessel smooth muscle retain a distinct Hox codes.

      Major Comments

      1. The manuscript would benefit from clearer delineation between the different NCC contributions, particularly for non-specialist readers. The distinction between (i) CNCCs in OFT cushions and (ii) CNCCs forming the aorticopulmonary (AP) septation complex is not adequately explained. While both populations contribute to OFT septation, according to the authors, they represent distinct compartments with different developmental trajectories. The authors could clarify this using anatomically labelled hearts at the stages they conduct their analysis, along with additional text and schematics explaining what is meant by each compartment. This would greatly enhance the accessibility of the manuscript.
      2. The Methods state that "Decomposition of cell clusters of scRNA-seq was performed by RCTD to map them onto the Xenium dataset," but this description is insufficient. The authors should clarify whether RCTD was applied separately for each developmental stage (i.e., E11.5 scRNA-seq reference for E11.5 Xenium, E12.5 reference for E12.5 Xenium), or whether a pooled reference was used across stages. This clarification is important because RCTD performance depends critically on the correspondence between reference and target datasets. Using a multi-stage integrated reference to deconvolve stage-specific spatial data could introduce artifacts, as cell states and cluster compositions vary considerably across developmental timepoints.
      3. Figure 2j-m needs annotations and shcematics. It is currently very difficult to identify the different compartments. See Figure C in Chen et al. for an example of this approach. In addition, what are the fine clusters from 1 to 20? Which ones are NCC-derived?
      4. The panels show pharyngeal markers, OFT/intracardiac markers, and SMC markers in Figures 2n-y, but could the authors show the proportion of NCC-derived (YFP+) cells for each cluster? Could the authors also map only the YFP+ cells on the Xenium data? It would be useful to see the proportion of YFP-positive (NCC-derived) cells for each delineated compartment. YFP-positive cells appear to exist at the boundary between LV and RV in the septum, this observation would benefit from proper quantification.
      5. Figure 3 is confusing because it integrates data from multiple overlapping stages (E8.5 to P7). While the authors identify distinct compartments, pharyngeal mesenchyme, intracardiac mesenchyme, and SMCs, it is unclear why stages beyond E14.5 and E17.5 (corresponding to the initial single-cell omics and Visium analysis) were included. Although leveraging additional datasets is a clever approach, the integration of data from such disparate developmental timepoints confounds interpretation. For example, Cluster 6 appears to include cells from both P7 and E12.5 stages. Given that the Visium data represent hearts at E14.5 and E17.5, it is problematic to map clusters derived from other stages onto these spatial datasets.
      6. Throughout the manuscript, the authors describe "lineage relationships" between cell populations, but these are in fact developmental trajectories inferred computationally (via UMAP connectivity and RNA velocity), not true lineage relationships. This distinction is critical and should be explicitly stated.

      For example, the statement "we propose that intracardiac NCCs within C10 and C22 differentiate via C2 into valvular (C21) and subvalvular (C18) interstitial cells" should be framed as a computational inference, not an established lineage relationship. Without clonal lineage tracing data, these claims cannot be verified.

      Similarly, the claim that "NCCs contributing to the AP septum are distinct from other intracardiac NCCs in that they do not populate the cardiac cushions but remain continuous with NCCs populating the distal outflow tract cushion" lacks direct lineage evidence. What experimental data support this assertion?

      In addition, the authors state that what De Bono et al. identified as "outflow smooth muscle" corresponds in their dataset to early intracardiac mesenchymal clusters C2, C10, and C22, present as early as E10.5, when mesenchymal NCC derivatives express immature SMC markers, and that these cells later differentiate into coronary artery SMCs around E14.5 (C23) as well as other non-muscle components. This claim is not verified, whether these cells are indeed the ones differentiating into coronary artery SMCs is based solely on computational inference from C2, C10, C22 to C23. 7. Claims regarding marker expression in specific compartments (for exmaple Hapln1 and Postn in cushions) require additional spatial validation at higher resolution than what is currently provided by the Visium data. Moreover, it is unclear whether these data are single-cell resolution; the authors need to clarify this. HCR staining would be ideal to confirm these expression patterns. Currently, all conclusions are based solely on gene expression without orthogonal spatial confirmation. At minimum, the authors should provide references from the literature supporting these expression patterns. 8. Could the authors confirm the absence of the Sox9high/Scxhigh population in AP septum descendants?

      Minor Comments

      Could the authors better justify their choice of stages (E11.5 to E17.5) for the single-cell multiomic assay? Given that OFT cushions are already populated by NCCs by E10.5 and that AP septum formation is already underway at this stage (see Development (2007) 134(8): 1593-1604), the rationale for beginning at E11.5 should be explicitly stated. Spelling errors in Figure 2e: "ambious" should be "ambiguous"; "atrium venticle" should be "atrium/ventricle"; "ventricle" is misspelled in several locations. The clustering resolution is very high, yielding many clusters that are difficult to distinguish based on the colour code alone. What does "ventricle_CL" refer to? What is the "marginal layer"? A clearer legend or supplementary table defining each cluster would be helpful. Figure 2j: The image is very dim. Figure 3b: What do the numbers correspond to? Additionally, "mesenchyme" is misspelled.

      Referees cross-commenting

      I also agree with the other reviewers' comments. Many thanks.

      Significance

      The overall approach is sound and the datasets generated are valuable resources for the field. The manuscript presents interesting findings regarding NCC heterogeneity in cardiac development.

      As I understand the authors' model: OFT cushion-associated NCCs enter and associate with the OFT cushions, undergoing a Hox-positive to Hox-negative transition, accompanied by a shift in Meis binding and GRN rewiring. These cells pass through a Meis2-Sox9-Scx "skeletogenic progenitor-like" intermediate state and contribute to semilunar valves and coronary artery smooth muscle. Aorticopulmonary septum NCCs, by contrast, retain distinct Hox codes (Hox4/5 enrichment) rather than becoming Hox-negative, and contribute to the AP septum and great vessel smooth muscle.

      Strengths: The integration of multiple omics modalities with lineage tracing is a powerful approach, and the identification of a Hox-dependent bifurcation in NCC fate is a novel conceptual advance.

      Limitations: The reliance on computational trajectory inference without orthogonal lineage validation, combined with the integration of datasets spanning very different developmental stages, limits the strength of some conclusions. The analysis also required more precise anatomical annotations to facilitate accessibility to the readers - to visualise better the distinguishable contribution of the cardiac NCCs to the OFT.

      Advance

      The study extends knowledge in the field by providing novel mechanistic insight into neural crest diversification in the context of cardiovascular development. The nature of the advance is primarily mechanistic, identifying a Hox-Meis regulatory switch that distinguishes cushion-associated from cushion-independent NCC lineages.

      Audience

      This work will be of interest to a specialised audience interested in neural crest cells and developmental biologists using omics approaches to address cell fate diversification in complex tissues.

      Reviewer Expertise

      Developmental biology, lineage analysis, mouse genetics. I do not have the expertise to assess the computational methods used in this paper.

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      Referee #1

      Evidence, reproducibility and clarity

      Iwase et al have used multiomics and spatial transcriptomics to comprehensively map neural crest cell contributions to the mouse heart and great arteries. This careful and detailed analysis reveals changes in the transcriptional profile of neural crest cells as they give rise to different regions and cell types in the heart and great vessels. The study significantly builds on a number of recent scRNA-seq analyses of neural crest cell development and includes development of a new informatic tool for regulatory network investigation. Among the new findings documented are downregulation of Hox gene expression in intracardiac crest cells and regulation of Sox9 by Meis transcription factors. Addressing the following points would improve clarity and accessibility.

      1. In Figure 1C it is difficult to visualize all the colors given the mixed contribution of NCC and nonNCC cells to mesenchyme. Please also show YFP transcript distribution in NCC versus nonNCC plots. In addition, it would be helpful to show plots for both NCC and nonNCC for Gata4 and Tbx20.
      2. The authors identify a cardiomyocyte cell cluster in their integrated NCC scRNA-seq plots. Are these cells labelled by Wnt1-Cre in the authors' own dataset? Is the trajectory analysis informative as to the steps preceding acquisition of cardiomyocyte fate?
      3. Linked with this point, is it possible that there are nonNCC cells in the integrated plots? Of note, many of the NCC genes overlap with genes that have also been shown to be expressed in mesodermal cardiac progenitors (including Osr1, Pparg, Dlk1, Tcf21, Ebf2, Tbx20, Sox9). For example, is it possible to distinguish NCC derived smooth muscle within the heart from cells originating from the second heart field that may express smooth muscle genes? Cluster 27 for example appears broadly expressed in the region of ventricular outlets in Figure 3. Comparison with YFP transcript distribution may be helpful here.
      4. Can the authors add any validation of key expression patterns, for example using fluorescent in situ hybridization?
      5. Please elaborate on the decoded Hox code patterns that appear to be indicative of arch origins. Do the results allow determination of whether the trajectories to different cardiac fates inferred in Figure 3D differ in different arches?
      6. The authors need to explain why the authors place an arrow from mesenchymal cluster 18 to 23 in Figure 3D while the trajectory analysis in 3C predicts the opposite direction.
      7. The authors nicely show downregulation of Hox gene expression in NCC cells entering the heart. Can they add discussion of any insights into this from prior studies of loss or gain of Hox gene function?
      8. Figure 3Y could be simplified to more clearly distinguish the two types of Meis binding sites. For example, it may be helpful to reorder the mesenchymal cell types based on Hox expression.
      9. The authors provide nice in vitro and in vivo evidence for an upstream role of Meis transcription factors in regulating Sox9 expression. Can the authors identify from the enhancer sequence (or their transcriptomic dataset) any of the non-Hox transcription factors that Meis may be working with here? Please discuss the significance of Sox9 expression in epicardium driven by the same enhancer. Might this regulation also operate in second heart field progenitor cells where both genes are expressed? It is not evident in Figure 7 that Sox9-EGFP is also expressed in epicardium.
      10. Could this approach yield similar data for Osr1? Please clarify if there is any experimental evidence supporting the predicted negative regulation of Sox9 by Osr1 in the heart illustrated in Figure 8.
      11. Concerning the links between valve mesenchyme and skeletogenic programs it would be relevant to cite the earlier work of Lincoln and Yutzey (reviewed in PMID: 16643886):
      12. In order to increase accesibility of the dataset the authors are encouraged to include a browser link.

      Minor points:

      1. The authors could rephrase the title since the term topographical genetic switch is unclear.
      2. In the introduction, with reference to the De Bono study, please note that Tbx1 was shown to regulate pharyngeal NCC differentiation stage transitions non-cell autonomously.

      Significance

      Iwase et al have used multiomics and spatial transcriptomics to comprehensively map neural crest cell contributions to the mouse heart and great arteries. This careful and detailed analysis reveals changes in the transcriptional profile of neural crest cells as they give rise to different regions and cell types in the heart and great vessels. The study significantly builds on a number of recent scRNA-seq analyses of neural crest cell development and includes development of a new informatic tool for regulatory network investigation. Among the new findings documented are downregulation of Hox gene expression in intracardiac crest cells and regulation of Sox9 by Meis transcription factors.

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      Reply to the reviewers

      We thank all reviewers for the valuable feedback and critical insight on our study. We acknowledge the concern that the manuscript, in its initial form, appeared descriptive and did not provide the mechanistic insight inferred from the current data. In the revised manuscript, we will (i) more clearly delineate what mechanistic inferences can be drawn from the existing data, (ii) expand our discussion of the caspase-independent mechanisms, and (iii) incorporate additional experiments/analyses aimed at identifying downstream effectors that mediate the observed phenotypes. In this revision plan, we have included six new figures addressing some of the major issues raised by reviewers.

      1. Specifically, to address questions about mechanistic insight, we generated stable ACSL1:HaloTag expressing hESCs. Currently presented as Figure 1A for reviewers____. __ACSL1 is a critical enzyme that catalyzes the first step of fatty acid oxidation at the outer mitochondrial membrane. Our previous analysis and work from the Opferman lab demonstrated that ACSL1 contains a BH3-like domain. Thus, we examined the effects of MCL-1 inhibition on the mitochondrial localization of this enzyme. Our findings pinpoint that MCL-1 inhibition is causing the displacement of ACSL1 from the mitochondria (__Figures 1B-C for reviewers). Our interpretations of the effects of MCL-1 inhibition are 2-fold: 1) as we show in our data, MCL-1 inhibition causes disruption of the mitochondrial cristae, altering the microenvironment for fatty acid oxidation, and 2) as seen in cancer cells, the MCL-1 inhibitor may also displace ACSL1 from the mitochondria. In the new version of the manuscript, we will focus on these 2 mechanisms as mechanistic outcomes of MCL-1 inhibition.
      2. We have included data of cells treated with Perhexilin (CPT1/2 inhibitor), and Etomoxir (CPT1a inhibitor) (Figure 2 for reviewers). This experiment determines whether direct perturbation the FAO pathway mimics the effects of the MCL-1i.
      3. We have assayed the effects of MCL-1 inhibition on oxygen consumption rates in NPCs. Currently presented as Figure 3 for reviewers.
      4. We will perform MCL-1:MICOS proximity ligation assays and/or immunoprecipitation assays to determine whether MCL-1 inhibitors disrupt the association of MCL-1 with MICOS. Preliminary data suggesting an association (albeit, very weak) are shown in Figure 4 for reviewers. __Reviewer #1____ (Evidence, reproducibility and clarity (Required)): __

      Summary: This study claims that beyond its canonical anti-apoptotic function, MCL-1 has essential non-apoptotic roles in human neurodevelopment. Pharmacologic inhibition of MCL-1 in human neural stem cells disrupts mitochondrial inner membrane architecture by destabilizing cristae and the OPA1-MICOS complex, leading to swollen mitochondria with disorganized cristae. These structural defects impair fatty acid oxidation and lipid droplet homeostasis, linking cristae integrity to metabolic competence. Independently of apoptosis or proliferation, MCL-1 inhibition selectively depletes intermediate neural progenitors, indicating a direct role in lineage progression. Overall, the work positions MCL-1 as a key regulator of mitochondrial structure-metabolism coupling that instructs neural progenitor identity and human neurogenesis.

      Overall: The study does a good job of using (in most assays) caspase inhibition (e.g., QVD treatment) to block apoptotic responses induced by MCL-1 inhibition. As a result, many of the phenotypes caused by inhibition are likely to be independent of caspase activation. As a result, this manuscript would be of interest to researchers that study the topics of the BCL-2 family and cell death signaling, mitochondrial bioenergetics and dynamics, neurodevelopment, and cellular metabolism. However, as currently presented the manuscript is only descriptive and lacks mechanistic insight.

      We thank Reviewer 1 for the insightful evaluation of our work. We are encouraged that the reviewer finds the study relevant to investigators in the fields of BCL-2 family biology, mitochondrial dynamics and bioenergetics, neurodevelopment, and cellular metabolism. We also thank the reviewer for pointing out the need to increase the mechanistic insight of our findings. As mentioned above, in the revised manuscript, we are proposing to address this.

      Major Concerns:

      1) The authors only use a single MCL-1 inhibitor and never use other non-targeting BH3-mimetics (such as venetoclax) as negative controls. This seems like a missed opportunity to demonstrate that the phenotypes observed are MCL-1 dependent.

      This is an excellent point. We will include venetoclax (ABT-199) to examine their effect on intermediate progenitors (TBR2 +) and early born neurons (BIII tubulin +).

      2) There is no mechanism proposed in this study other than reliance upon QVD as not affecting the phenotypes. As submitted, the manuscript only can speculate that these phenotypes are due to non-apoptotic roles of MCL-1 inhibition. The authors have missed an opportunity to explore MCL-1's non-apoptotic functions directly.

      Mechanistically, we propose MCL-1 is acting in 2 ways: 1) as we show in our data, MCL-1 inhibition causes disruption of the mitochondrial cristae, altering the microenvironment for fatty acid oxidation, and 2) as seen in cancer cells, MCL-1 inhibitors may also displace ACSL1 from the mitochondria.

      In the past few weeks, since receiving the initial reviews, we have focused on testing the 2nd possibility, since the accumulation of lipids was also seen in cancer cells (see PMID: 38503284). We have successfully generated stable ACSL1:HaloTag expressing hESCs (Figure 1A for reviewers). Our findings included here, ACSL1 is displaced from the mitochondria by MCL-1 inhibition in NPCs (Figures 1B-C for reviewers).

      Other concerns exist that weaken the impact of the study.

      1. Figure 1 should include the fact that QVD inhibition (shown in Sup Fig 2) does not obviate the phenotype induced by pharmacological inhibition of MCL-1 on mitochondrial morphology. We would like to clarify that QVD does prevent the phenotypes induced by MCL-1 inhibition on mitochondrial morphology. In Fig1B, we report an increase in volume and surface area at 24h and 48h along with a decrease in mitochondrial content at 48h when NPCs were treated with MCL-1i only. However, NPCs co-treated with QVD in Supp Fig 2B did not exhibit any significant morphological phenotypes on average or at min/max values. Reviewer 1 may be referring to Fig 1B's corresponding min/max values presented in Supp Fig 2A where we reported an increase in __max __volume.

      Figure #

      Volume

      Surface Area

      Fig 1B (MCL-1i only, avg values)

      Increase (avg vol)

      increase (avg)

      Supp Fig 2B (MCL-1i+QVD)

      no change

      no change

      Supp Fig 2A (MCL-1i only, max/min values)

      increase (max vol)

      no change (max)

      For clarity, we will move Supplementary Fig 2A into Supplementary Fig 1.

      Figure 2 would benefit from evidence that caspase inhibition does not repress the phenotype on mitochondrial cristae morphology (volume and area). Furthermore, the FIB-SEM data are very hard to appreciate as the size precludes visualization of individual mitochondria.

      While we included the visualization of the segmented mitochondria and cristae (Figure 2C), as well as snapshots through the z-stack for segmented cristae only (Figure 2E) and segmented mitochondria separately (Supp Figure 3A) in the original manuscript, we are also now attaching the FIB-SEM 3D reconstruction videos (New Supplementary Videos 1-2 for reviewers) (1. Mito and cristae, 2. Cristae only, 3. Mito only) for ease of visualization purposes.

      Figure 3 reports that MIC60 and OPA1 appear to be downregulated in response to MCL-1 inhibition, but these appear to be more significant only when QVD is added. Why would the phenotype be obscured in the non-QVD setting (Fig. 2B&C). How does MCL-1 inhibition lead to changes in MIC60/MICOS/OPA1? This seems quite preliminary at this point.

      In Figures 3B and 3C, we report decreased protein levels of short-form OPA1 and MIC10 only, not MIC60. We argue that our data with QVD shows that the cell death function of MCL-1 (i.e., inhibiting cell death effectors from initiating the caspase cascade) is not the main trigger of the phenotypes we report (cristae dysregulation and fatty acid oxidation disruption), however, cells without a functional cristae and/or defects in FAO, may not be able to survive long-term. Thus, QVD treatment preserves these cells that may not survive the dismantling of such an essential structure. To confirm this, we have performed immunofluorescence of cleaved caspase 3 (Figure 5 for reviewers). These results show that indeed MCL-1 inhibition at the time points of our study doesn't result in increased activation of Caspase-3. We reported similar results of MCL-1 inhibition in oligodendrocyte precursor cells (Gil and Hanna et al., Glia, 2025, PMID: 41420072)

      The loss of MIC60 and OPA1 should repress electron transport chain function, are such impacts observed in the cultured cells? This could be shown by assessing oxygen consumption, etc. Such data would enhance the authors' conclusion that MCL-1 inhibition leads to defects in mitochondrial physiology*. *

      We completely agree with this comment by Reviewer 1. In our revision, we will include an assessment of mitochondrial oxygen consumption rate, using the Seahorse analyzer (mitochondrial stress test), of NPCs treated with MCL-1i. Preliminary data (n=3) are currently presented as Figure 3 for reviewers. Interestingly, these data show a more nuanced cellular response. Consistent with our conclusion that MCL-1 inhibition does not cause apoptotic cell death, MCL-1i did not affect mitochondrial respiration at baseline. The specific deficits appear in spare respiratory capacity and maximal respiration, meaning cells can sustain routine mitochondrial function but lose the ability to respond to increased energetic demand. This suggests MCL-1 loss creates a mitochondrial reserve deficiency rather than a generalized bioenergetic failure. The results with caspase inhibitors show a near-zero OCR across both 24h and 48h timepoints, and significant reductions in maximal respiration, spare respiratory capacity, and non-mitochondrial OCR. Remarkably, these conditions are not detrimental to newborn neurons, as shown in Figure 7. This is very interesting because it suggests that, under severe bioenergetic failure, neural stem cells (PAX6+) can differentiate into newborn neurons in a TBR2-independent manner. More relevant to this study, our results unequivocally demonstrate that TBR2-positive cells depend on the non-apoptotic function of MCL-1

      In Figure 4, the differences between transcripts (qPCR data) and protein (immunoblot) data are often confusing and not well explained. Why do the authors propose that mRNA expression is decreasing whereas the protein expression is increasing? Example CPT1. Furthermore, it is unclear what these data mean functionally? Is this reflective of enhanced lipid oxidation or simply a response to inhibition of fatty acid oxidation? Clarification of the impact of these findings is necessary.

      We agree with Reviewer 1 that the results could be hard to interpret. However, the effects of MCL-1 inhibitors on the transcription of fatty acid oxidation genes have been widely cited by the work of Opferman and Walensky (PMID: 36198266). We speculate that the effects on transcription are triggered by mitochondrial signaling. The mechanistic insight into this phenomenon would be an interesting next step.

      In the case of CPT1, we addressed this comment and found that the difference is due to differential expression of isoforms The RT-qPCR shown in Figure 4, is on CPT1c, whereas the western blot is on CPT1a. Unfortunately, after trying several products, we determined that there are no good antibodies for CPT1c. Thus, since we can't compare gene and protein expression, we will include CPT1a RT-qPCR data to complement the western blot.

      The increase in lipid droplet number induced by MCL-1 inhibition has been previously documented, but it is unclear whether this increase is related to an inability to oxidize lipid (defective fatty acid oxidation) that leads to increases in the cellular abundance or whether this indicates that MCL-1 inhibition leads to enhanced storage. Do other inhibitors of fatty acid oxidation lead to similar increases in lipid droplet size and abundance? Does QVD inhibition affect this phenotype?

      This is a great point raised by Reviewer 1, and one we have also wondered about. We conducted an experiment using C16 BODIPY to address this point (Figure 6 for Reviewers). We observed no changes in C16 lipid droplet accumulation in count, volume, or surface area when cells were treated with MCL-1 inhibitor for 24 hours total with or without a starvation period in the last 6 hours of treatment. However, we observed significant pan-lipid droplet accumulation in the same conditions. This contrast suggests that FAO of exogenous LC-fatty acids is not reliant on MCL-1. This finding does not discount from the requirement of MCL-1 for other FAO processes especially given the major limitation of how much C16 BODIPY (fluorescent palmitate) can be administered to the cells (10µM) which was 10-fold less than what we exogenously supplied to the cells for the pan-BODIPY experiment (100µM, see Figure 5). It is entirely possible that this small dose was not enough to detect any lipid droplet accumulation.

      We have now also included experiments using etomoxir and perhexiline to assess their effects on TBR2/PAX6 (Figure 2 for reviewers). The results indicate that inhibiting the FAO pathway does not fully mimic the effects of MCL-1i on TBR2. However, we show that MCL-1i displaces ACSL1 from the mitochondria, a step that is upstream of CPT1/2. We suggest a model in which the coordinated non-apoptotic function of MCL-1 at the outer mitochondrial membrane promotes ACSL1 activity and, in the inner mitochondrial membrane, regulates mitochondrial cristae morphology. While our data point to this model, we are limited by the tools to investigate it further, but it will be a great direction for future experiments.

      For Figure 6, while these data may be very meaningful, as presented they are very hard to appreciate. Insets that show the neuronal populations would help to convey the point that the differentiation is impacted. Also, are there other methods that could confirm these observations (qPCR to show changes in differentiation).

      We agree with Reviewer 1. In the new version of the manuscript, we will include panels that zoom into the cell populations we quantified. The current panels will go to a new Supplemental figure. We will also add the TUBB3 to the qPCR panel in the new version.

      Figure 7 is also very hard to appreciate. What is the reader to see? Can these be quantified? It seems that QVD may be rescuing in this figure, does this suggest that MCL-1 inhibition might be inducing death. All of this needs to be quantified.

      We will provide quantification of BIII tubulin branching, and it will be included next to the images provided.

      BCL-XL has also been implicated in affecting mitochondrial electron transport chain function (See PMID: 19255249, 21926988, 21987637). Can BCL-XL inhibitors affect any of the phenotypes associated here?

      We will include experiments to test the effect of BCL-2 and BCL-XL inhibitors on TBR2 cells to address this comment.

      Please be carefully avoid using the term "MCL-1 loss", when talking about pharmacological inhibition. Only genetic ablation (e.g. knockout, silencing, etc.) should be termed loss.

      We have now removed the reference to MCL-1 loss in line 199.

      __*Reviewer #1 (Significance (Required)):

      The study advances in human cells the impacts of MCL-1 inhibition. They replicate many impacts previously observed in mouse systems and refine analyses to impacts on MICOS complex, lipid droplet storage, and neuronal differentiation. While these findings are important and would be well received by a wide audience, the study fails to provide almost any mechanistic insight into how these phenotypes are being induced. The only common theme is that blocking caspase activation in many assays fails to block the phenotype.

      *__

      __Reviewer #2_ (Evidence, reproducibility and clarity (Required)): _*

      Summary: This manuscript by Hanna et al. investigates non-apoptotic roles of MCL-1 in human neural stem cells and connects MCL-1 inhibition to mitochondrial cristae formation and beta-oxidation. Connecting these roles to brain development, the authors also show a reduction in the number of progenitor cells upon MCL-1 inhibition, independently of caspase activity. Throughout their work, the authors make use of an impressive array of imaging techniques. While the methods used offer sufficient evidence to connect MCL-1 inhibition to cristae architecture, the mechanistic underpinnings of this effect remain unexplored. *__

      We thank Reviewer 2 for the thoughtful and positive assessment of our manuscript. We appreciate the reviewer's recognition that our study reveals non-apoptotic roles of MCL-1 in human neural stem cells. We are also grateful for the acknowledgment of the imaging approaches employed, which allowed us to connect MCL-1 function to cristae architecture with multiple complementary techniques. We acknowledge the reviewer's point that the mechanistic basis by which MCL-1 influences cristae structure remains insufficiently defined. In the revised manuscript, we will clarify the limitations of the current data, expand our discussion of potential mechanisms, and incorporate additional analyses to identify downstream effectors that mediate these structural and metabolic changes.

      Major comments:

      - In Fig. 1B, the very same representative images are shown for both conditions (DMSO and S63845) at 48 hours.

      We deeply appreciate Reviewer 2 for catching this unintentional duplication that occurred during figure preparation. We have now corrected this issue.

      - For Western Blot analysis, it looks like the authors only quantified the band density of their proteins of interest without considering varying levels of control protein (Actin) levels. Normalizing the protein levels to actin would account for any differences in loaded protein amounts (although a Ponceau staining might be preferable still to exclude this). This is especially relevant for Fig. 4E, where actin levels visibly differ between the conditions.

      All WB quantifications were normalized to Actin (this detail is now added to the y-axis of all band density graphs and figure legends). In addition, we will transform the data to a logarithmic scale to "normalize" for gel-to-gel variability.

      - The authors offer evidence that MCL-1 inhibition impedes proteolytic cleavage of OPA1-L into the OPA-1-S isoforms, yet do not explore the mechanism behind this. Since OPA1 is cleaved by both OMA1 and YME1L, determination of the levels of these proteases could help shed some light on the mechanism leading to cristae reorganization.

      We will follow up on Reviewer 2's comment with a WB analysis of OMA1 and YMEL in cells treated with an MCL-1 inhibitor.

      - Generally speaking, while the authors show all those effects (cristae defects, FAO dysfunction) upon MCL-1 inhibition, it would be interesting to see whether any of those effects can be rescued by blocking FA import e.g. through carnitine palmitoyl- transferase 1a (CPT1a) inhibition with etomoxir to understand if they are downstream of altered Fa supply. This could affect cristae morphology through altered Cardiolipin biogenesis.

      This is an excellent point, which was also raised by reviewer 1. We have now included experiments using etomoxir and perhexiline to assess their effects on TBR2/PAX6 (Figure 2 for Reviewers). As mentioned above, the results indicate that inhibiting the FAO pathway does not fully mimic the effects of MCL-1i on TBR2. However, we show that MCL-1i displaces ACSL1 from the mitochondria, a step that is upstream of CPT1 and 2. We suggest a model in which the coordinated non-apoptotic function of MCL-1 at the outer mitochondrial membrane promotes ACSL1 activity and, in the inner mitochondrial membrane, regulates mitochondrial cristae morphology. While our data point to this model, we are limited by the tools to investigate it further, but it will be a great direction for future experiments. The suggestion of Reviewer 2 that the effects on FAO could impact cardiolipin biogenesis is a very exciting possibility. However, difficult to test with the tools available.

      - In line 262 the authors discuss that mitochondria lose metabolic function upon MCL-1 inhibition. This claim would require additional experiments. While the authors look at lipid droplet accumulation and FAO enzymes, there are many more aspects to mitochondrial metabolic function that should be investigated. While measuring the oxygen consumption rate via Seahorse might require additional resources (optional), measurements of ATP production, ROS generation or determination of the mitochondrial membrane potential should be feasible.

      We fully agree with Reviewer 2's comment, which was also raised by Reviewer 1. In our revision, we will include an assessment of the mitochondrial oxygen consumption rate of NPCs treated with MCL-1i, measured using the Seahorse analyzer (mitochondrial stress test). These data are presented as Figure 3 for reviewers. Interestingly, these data show a more nuanced cellular response. While MCL-1i does not globally collapse mitochondrial respiration at baseline, the specific deficits appear in spare respiratory capacity and maximal respiration, meaning cells can sustain routine mitochondrial function but lose the ability to respond to increased energetic demand. This suggests MCL-1 loss creates a mitochondrial reserve deficiency rather than a generalized bioenergetic failure. The results with caspase inhibitors show a near-zero OCR across both 24h and 48h timepoints, and significant reductions in maximal respiration, spare respiratory capacity, and non-mitochondrial OCR. These conditions are detrimental for TBR2-positive NPCs (Figure 6) , but not for newborn neurons (Figure 7).

      - While the authors "propose a model in which MCL-1 associates with MICOS", they do not offer direct scientific to support this hypothesis. Co-immunoprecipitation experiments or e.g. proximity ligation assays would better support the proposed model.

      We agree with this statement. Preliminary, we have performed proximity ligation assays and immunoprecipitation analyses to test for this interaction (see below and ____Figure 4 for reviewers), and the results indicate an interaction, albeit very weak. In the revised version of the manuscript, we will attempt to repeat these experiments with MCL-1i.

      - While Fig. 7 shows representative images, quantification e.g. for the truncation of neuronal processes is missing.

      We will provide quantification of BIII tubulin branching, which will be included alongside the images provided.

      - In lines 219f. the authors state that they "observed a significant downregulation of PAX6 and EOMES at 24 hours that was not rescued by QVD co-treatment". While there is still a trend towards a downregulation, there is no statistical significance anymore. In fact, PAX6 levels almost mirror those of SOX2 which is not described as "downregulated" by the authors. In order to be more consistent, I would suggest rephrasing this part, or at least reword it to be less absolute.

      In the new version, we will clarify that while QVD rescued TBR2 and PAX6 transcript levels at 24h, it did not rescue them at 48h. We will also mention the downregulation of SOX2 at 48h that persists with co-treatment.

      - Brinkmann et al. (2025) also investigated cristae structure upon MCL-1 deletion in vivo and found no effect when MCL-1 was replaced with other Bcl-2 family members. It would be interesting to combine MCL-1 inhibition with overexpression of MCL-1 versus BCL-XL to reconsolidate some of the discrepant findings.

      While this is a great suggestion for future studies, there are some complications. Specifically, it is likely that the inhibitor may also target the overexpressed MCL-1 and thus, a mutant form is needed.

      To address this, we generated a Flag-tagged MCL-1 construct with a mutated BH3 domain, previously described by Kotschy et al. Nature 2016. We validated the construct in HeLa cells, but unfortunately the mutant protein appears to be significantly less stable than the WT construct, complicating analysis of this experiment.

      Minor comments:

      - In Supp. Fig. 1C the MCL-1 protein is shown both to run above 37kDa (upper panel) and below 37 kDa (lower panel). Could the authors please comment on why this is the case?

      The observed variation is caused by drift in the gel during electrophoresis. In Fig 1C, the protein ladder is on the edge of the gel, whereas in Fig 1E, the protein ladder is in the middle of the gel, and the last sample is on the edge and also exhibits edge drift.

      - In line 64 of the introduction the authors mention clinical trials yet do not give a citation for these trials making it hard to judge whether the content of these trials is actually related to the brain.

      This information is anecdotal, based on an Amgen press release.

      - MCL-1 as well as ACSL-1 are sometimes written without the hyphen both in the text and figures.

      We will carefully check the manuscript before submission.

      - Lines 92-94 and 106-108 essentially highlight the same existing knowledge gap. Maybe the content of these two paragraphs could be combined in order to avoid repetition.

      We thank Reviewer 2 for this suggestion. We will do this in the new version of the manuscript.

      - In Fig. 1A, the authors provide a schematic for their experimental design. While the figure legend is very thorough, some of this information (like the days of collection) could also be included in the figure itself. The same is true for schematics in the following figures.

      We agree with this and will incorporate the suggestion in the new version.

      - Fig. 2A includes a typo (analyze) but would maybe also be more suitable for the supplement figures or could even be combined with Fig. 1A as not much new content is added.

      We already incorporated these changes in the new version of the manuscript.

      - Regarding statistical analysis, could the authors please comment on why they did not consider one-sample t-tests suitable for the cases where control values were set at 1 (e.g. Fig. 4B, C for the relative expression).

      This is a valid suggestion. We will rerun RT-qPCR data using a one-sample t-test.

      - In lines 247f. the authors state that "inhibition of MCL-1 leads to [...] and disassembly of the MICOS complex as well as OPA1". This sounds like OPA1 is still cleaved upon MCL-1, which is not at all what the authors showed and further discuss. Rewording of the sentence would help in avoiding any misunderstandings.

      We agree with this comment and have now reworded the paragraph: "Inhibition of MCL-1 leads to structural collapse of the cristae likely due to the possible disassembly of the MICOS complex, as suggested by decreased MIC10 levels, and interruption of OPA1 cleavage, as suggested by decreased short-form OPA1, two scaffolds required for cristae maintenance."

      - In lines 210f. the authors state that "quantitative imaging increased the average and maximum volume of lipid droplets". While there is definitely a trend towards an increase for the maximum volume, the increase is in fact not statistically significant. This should be reflected in the wording.

      We have reworded this to "Quantitative imaging revealed a significant increase in average lipid droplet volume and a trending increase in maximum volume of lipid droplets."

      - In Fig. 6 the overlap between TBR2 and PAX6 is hard to judge when printed out. Including a zoom-in may make it easier to judge.

      We agree with Reviewer 2. In the new version of the manuscript, we will include panels that zoom into the cell populations we quantified. The current panels will go to a new Supplemental figure. We will also add the TUBB3 to the qPCR panel in the new version.

      - In Fig. 7 the color-coding is listed in the figure legend but is missing from the figure itself. If the authors could include this, as they did for the other figures, it would further improve this figure.

      We agree. We have specified the channel color in the new figure.

      - Line 238 should reference Fig. 7A, as Fig 7B does not exist.

      Thanks for catching this. It is already corrected

      - In the figure legends the authors state that biological replicates were used. Were technical replicates also performed?

      Yes, technical replicates were performed for RT-qPCR.

      Reviewer #2 (Significance (Required)):____ Significance

      The authors make use of a wide array of imaging techniques to further elucidate non-apoptotic roles of MCL-1. The study has the potential to offer new insights into mitochondrial biology on the level of basic research rather than translational. While the methods used offer sufficient evidence to connect MCL-1 inhibition to cristae architecture, the mechanistic underpinnings of this effect remain unexplored. Nevertheless, the study offers additional knowledge on the role of MCL-1 in human neural stem cells, whereas previous research mostly focused on cardiomyocytes or cancer cells.

      Reviewer #3____ (Evidence, reproducibility and clarity (Required)):

      Summary: ____ In this study, Gama et al. describe a non-canonical role for the anti-apoptotic protein Myeloid Cell Leukemia-1 (MCL-1) in mitochondrial cristae organization and suggest a role of MCL-1 in regulating metabolism and neuronal differentiation. Using fluorescence microscopy imaging and electron microscopy, the authors show changes to mitochondrial morphology upon treatment with MCL-1 inhibitor S63845. MCL-1 inhibition results in altered protein and transcript levels of some key proteins involved in mitochondrial cristae organization and fatty acid metabolism. While some of the findings are interesting and indeed point towards a non-canonical role of MCL-1, several key conclusions of the authors are not sufficiently supported by the data shown in the manuscript.

      We thank Reviewer 3 for the careful evaluation of our manuscript. We appreciate the reviewer's recognition that our study identifies a potential non-canonical role for MCL-1 in mitochondrial cristae organization, metabolism, and neuronal differentiation. As with Reviews 1 and 2, we are encouraged that the reviewer finds these observations interesting and suggestive of previously unappreciated functions for MCL-1. We agree that stronger evidence is required to firmly link MCL-1 inhibition to specific changes in MICOS organization and metabolic regulation. In the revised manuscript, we will (i) more clearly distinguish between observations and mechanistic inferences, (ii) temper conclusions where appropriate, and (iii) incorporate additional analyses and controls to better substantiate the proposed model.

      Major comments:

      1. The authors try to disentangle the apoptotic and non-apoptotic role of MCL-1 through addition of a caspase inhibitor. However, I am not convinced that phenotypes found under the addition of caspase inhibitor are necessarily caused by non-canonical functions independent of apoptosis. It could also be that the observed changes happen upstream of caspase activation. In addition, many of the described finding, such as CPT1 expression changes, only happen in the presence of the caspase inhibitor. If one follows the logic of the authors, changes associated by non-canonical MCL-1 functions should happen under MCL-1 inhibition and caspase inhibition, but not with MCL-1 inhibition only____. __ The reviewer is right that we expected non-canonical functions to happen under MCL-1 inhibition and caspase inhibition. Our data with QVD shows that the cell death function of MCL-1 (i.e., inhibiting cell death effectors from initiating the caspase cascade) is not the main trigger of the phenotypes we report (cristae dysregulation and fatty acid oxidation disruption), however, cells without a functional cristae and/or defects in FAO, may not be able to survive long-term. Thus, QVD treatment preserves these cells that may not survive the dismantling of such an essential structure. To confirm this, we performed immunofluorescence of cleaved caspase 3 (__Figure 5 for reviewers). These results show that, indeed, MCL-1 inhibition at the time points of our study doesn't result in increased Caspase-3 activation. We reported similar results of MCL-1 inhibition in oligodendrocyte precursor cells (Gil and Hanna et al., Glia, 2025, PMID: 41420072).

      The authors show no data on the viability of the cells in response to the MCL-1 inhibitor. To exclude secondary effects of the inhibitor, at least some of the results should be validated with an MCL-1 knock down.

      We will include this experiment in our revised manuscript. To check the effects of MCL-1 knockdown on TBR2 positive cells, we tested 5 different ASOs for MCL-1. Knockdown efficiency with ASOs was very low (on average In Figure 1, the authors show immunofluorescence data of mitochondria and nucleus staining and conclude that MCL-1 inhibition alters mitochondrial morphology. Based on the images shown in Fig. 1, I do not think that individual mitochondria can be segmentd to measure their volume and length. In addition, some metrics such as mitochondrial content are not explained in the text or methods.

      We can achieve mitochondrial segmentation with a SoRa Spinning Disk Confocal Microscope, which has a lateral (XY) resolution of approximately 120 nm to 150 nm and an axial (Z) resolution of approximately 300 nm-320 nm. All images are first denoised prior to sharpening using the Richardson-Lucy deconvolution algorithm. Additionally, the FIB-SEM data are consistent with the IF data (both show increase in mitochondrial volume and surface area).

      We agree with Reviewer 3 that we need to explain some metrics in the revised version. We will specify the meaning of mitochondrial content (count of all mitochondria in FOV, not normalized to Hoechst).

      In Fig. 2 B-D, the authors show TEM and FIB-SEM imaging to demonstrate alterations in the cristae architecture upon treatment with MCL-1 inhibitor. However, based on the images shown, it looks that cristae area and density is reduced under S63845 treatment in TEM images, while the FIB-SEM data come to the opposite conclusion. In addition, the quantification of cristae volume quantified as cristae volume in percentage is unclear to me.

      We apologize for the confusion. No conclusions about the cristae area and density were made using the TEM data, because TEM data represent a single snapshot section of a mitochondrion without a discernible orientation. Cristae from TEM were described as "aberrant" and preliminarily revealed changes in cristae and were followed up with FIB-SEM, 3D reconstruction of intact mitochondria, and quantification of volume.

      In the new version of the manuscript, we will specify that the cristae volume is normalized to the volume of its respective mitochondria (i.e., how much of the mitochondrial volume is attributed to cristae).

      The change in CPT1/2 protein levels (Fig. 4) is interesting but does not directly proof that fatty acid oxidation is altered, as concluded by the authors. For this, the authors would need to directly measure fatty acid oxidation for example using Seahorse or metabolic tracing experiments. Also, to prove that the MCL-1 inhibition affects neural differentiation through fatty acid oxidation, a rescue experiment should be performed through CPT1 overexpression.

      We agreed that this is an important point. We have optimized the fatty acid oxidation test using Seahorse and will make sure to include it in the revised version of the manuscript.

      In Figure 6, the authors show decreased intermediate progenitor cells after MCL-1 inhibition by immunofluorescence staining. I am not convinced that this can be concluded from the data shown, since the concentration of intermediate progenitor cells is very close to the noise levels. Since the MCL-1 treated cells look much less sparse, I don't think the percentages can be compared (total counts are between 2-20). Although this data might give some indication that differentiation could be impaired, the measured effect could be very well due to lower viability of the cells. The authors need to control for this or come up with a different method for measuring differentiation.

      The number of TBR2 is low, but we disagree with the reviewer's assessment of noise levels. We focused on cells expressing only TBR2 and rigorously examined this population of cells. The percentages are compared to account for the lower density of the MCL-1i-treated cultures, as the IPC counts are normalized to the Hoechst total cell count within the FOV. Moreover, the immunofluorescence images are complemented with RT-qPCR, which shows significant downregulation of EOMES (gene encoding TBR2).

      Figure 7 is missing quantification

      We will include this quantification in the revised version of the manuscript.

      Reviewer #3 (Significance (Required)):

      General assessment____: The manuscript reports an interesting finding, which suggest a non-canonical role of MCL-1 in mitochondrial remodeling, regulation of fatty acid oxidation and neuronal fate. While this finding would be highly interesting and relevant, the presented data do not sufficiently support this conclusion. Further experiments would have to be performed to proof causality. ____ Advance: Should the authors manage to proof their hypothesis by additional experiments, this would indeed advance the field on mitochondrial remodeling and its effect on neuronal differentiation by

      identifying a novel molecular player. ____ Audience: mitochondrial biology, cell biology, developmental neuroscience Own expertise: mitochondrial biology, cell biology, advanced imaging techniques

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      In this study, Gama et al. describe a non-canonical role for the anti-apoptotic protein Myeloid Cell Leukemia-1 (MCL1) in mitochondrial cristae organization and suggest a role of MCL1 in regulating metabolism and neuronal differentiation. Using fluorescence microscopy imaging and electron microscopy, the authors show changes to mitochondrial morphology upon treatment with MCL1 inhibitor S63845. MCL1 inhibition results in altered protein and transcript levels of some key proteins involved in mitochondrial cristae organization and fatty acid metabolism. While some of the findings are interesting and indeed point towards a non-canonical role of MCL1, several key conclusions of the authors are not sufficiently supported by the data shown in the manuscript.

      Major comments:

      1. The authors try to disentangle the apoptotic and non-apoptotic role of MCL1 through addition of a caspase inhibitor. However, I am not convinced that phenotypes found under the addition of caspase inhibitor are necessarily caused by non-canonical functions independent of apoptosis. It could also be that the observed changes happen upstream of caspase activation. In addition, many of the described finding, such as CPT1 expression changes, only happen in the presence of the caspase inhibitor. If one follows the logic of the authors, changes associated by non-canonical MCL1 functions should happen under MCL1 inhibition and caspase inhibition, but not with MCL1 inhibition only.
      2. The authors show no data on the viability of the cells in response to the MCL1 inhibitor. To exclude secondary effects of the inhibitor, at least some of the results should be validated with an MCL1 knock down.
      3. In Figure 1, the authors show immunofluorescence data of mitochondria and nucleus staining and conclude that MCL1 inhibition alters mitochondrial morphology. Based on the images shown in Fig. 1, I do not think that individual mitochondria can be segmentd to measure their volume and length. In addition, some metrics such as mitochondrial content are not explained in the text or methods.
      4. In Fig. 2 B-D, the authors show TEM and FIB-SEM imaging to demonstrate alterations in the cristae architecture upon treatment with MCL1 inhibitor. However, based on the images shown, it looks that cristae area and density is reduced under S63845 treatment in TEM images, while the FIB-SEM data come to the opposite conclusion. In addition, the quantification of cristae volume quantified as cristae volume in percentage is unclear to me.
      5. The change in CPT1/2 protein levels (Fig. 4) is interesting but does not directly proof that fatty acid oxidation is altered, as concluded by the authors. For this, the authors would need to directly measure fatty acid oxidation for example using Seahorse or metabolic tracing experiments. Also, to prove that the MCL1 inhibition affects neural differentiation through fatty acid oxidation, a rescue experiment should be performed through CPT1 overexpression.
      6. In Figure 6, the authors show decreased intermediate progenitor cells after MCL1 inhibition by immunofluorescence staining. I am not convinced that this can be concluded from the data shown, since the concentration of intermediate progenitor cells is very close to the noise levels. Since the MCL1 treated cells look much less sparse, I don't think the percentages can be compared (total counts are between 2-20). Although this data might give some indication that differentiation could be impaired, the measured effect could be very well due to lower viability of the cells. The authors need to control for this or come up with a different method for measuring differentiation.
      7. Figure 7 is missing quantification

      Significance

      General assessment: The manuscript reports an interesting finding, which suggest a non-canonical role of MCL1 in mitochondrial remodeling, regulation of fatty acid oxidation and neuronal fate. While this finding would be highly interesting and relevant, the presented data do not sufficiently support this conclusion. Further experiments would have to be performed to proof causality.

      Advance: Should the authors manage to proof their hypothesis by additional experiments, this would indeed advance the field on mitochondrial remodeling and its effect on neuronal differentiation by identifying a novel molecular player.

      Audience: mitochondrial biology, cell biology, developmental neuroscience

      Own expertise: mitochondrial biology, cell biology, advanced imaging techniques

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      This manuscript by Hanna et al. investigates non-apoptotic roles of MCL-1 in human neural stem cells and connects MCL-1 inhibition to mitochondrial cristae formation and beta-oxidation. Connecting these roles to brain development, the authors also show a reduction in the number of progenitor cells upon MCL-1 inhibition, independently of caspase activity. Throughout their work, the authors make use of an impressive array of imaging techniques.While the methods used offer sufficient evidence to connect MCL-1 inhibition to cristae architecture, the mechanistic underpinnings of this effect remain unexplored.

      Major comments:

      • In Fig. 1B, the very same representative images are shown for both conditions (DMSO and S63845) at 48 hours.
      • For Western Blot analysis, it looks like the authors only quantified the band density of their proteins of interest without considering varying levels of control protein (Actin) levels. Normalizing the protein levels to actin would account for any differences in loaded protein amounts (although a Ponceau staining might be preferable still to exclude this). This is especially relevant for Fig. 4E, where actin levels visibly differ between the conditions.
      • The authors offer evidence that MCL-1 inhibition impedes proteolytic cleavage of OPA1-L into the OPA-1-S isoforms, yet do not explore the mechanism behind this. Since OPA1 is cleaved by both OMA1 and YME1L, determination of the levels of these proteases could help shed some light on the mechanism leading to cristae reorganization.
      • Generally speaking, while the authors show all those effects (cristae defects, FAO dysfunction) upon MCL-1 inhibition, it would be interesting to see whether any of those effects can be rescued by blocking FA import e.g. through carnitine palmitoyl- transferase 1a (CPT1a) inhibition with etomoxir to understand if they are downstream of altered Fa supply. This could affect cristae morphology through altered Cardiolipin biogenesis.
      • In line 262 the authors discuss that mitochondria lose metabolic function upon MCL-1 inhibition. This claim would require additional experiments. While the authors look at lipid droplet accumulation and FAO enzymes, there are many more aspects to mitochondrial metabolic function that should be investigated. While measuring the oxygen consumption rate via Seahorse might require additional resources (optional), measurements of ATP production, ROS generation or determination of the mitochondrial membrane potential should be feasible.
      • While the authors "propose a model in which MCL-1 associates with MICOS", they do not offer direct scientific to support this hypothesis. Co-immunoprecipitation experiments or e.g. proximity ligation assays would better support the proposed model.
      • While Fig. 7 shows representative images, quantification e.g. for the truncation of neuronal processes is missing.
      • In lines 219f. the authors state that they "observed a significant downregulation of PAX6 and EOMES at 24 hours that was not rescued by QVD co-treatment". While there is still a trend towards a downregulation, there is no statistical significance anymore. In fact, PAX6 levels almost mirror those of SOX2 which is not described as "downregulated" by the authors. In order to be more consistent, I would suggest rephrasing this part, or at least reword it to be less absolute.
      • Brinkmann et al. (2025) also investigated cristae structure upon MCL-1 deletion in vivo and found no effect when MCL-1 was replaced with other Bcl-2 family members. It would be interesting to combine MCL-1 inhibition with overexpression of MCL-1 versus BCL-XL to reconsolidate some of the discrepant findings.

      Minor comments:

      • In Supp. Fig. 1C the MCL-1 protein is shown both to run above 37kDa (upper panel) and below 37 kDa (lower panel). Could the authors please comment on why this is the case?
      • In line 64 of the introduction the authors mention clinical trials yet do not give a citation for these trials making it hard to judge whether the content of these trials is actually related to the brain.
      • MCL-1 as well as ACSL-1 are sometimes written without the hyphen both in the text and figures.
      • Lines 92-94 and 106-108 essentially highlight the same existing knowledge gap. Maybe the content of these two paragraphs could be combined in order to avoid repetition.
      • In Fig. 1A, the authors provide a schematic for their experimental design. While the figure legend is very thorough, some of this information (like the days of collection) could also be included in the figure itself. The same is true for schematics in the following figures.
      • Fig. 2A includes a typo (analyze) but would maybe also be more suitable for the supplement figures or could even be combined with Fig. 1A as not much new content is added.
      • Regarding statistical analysis, could the authors please comment on why they did not consider one-sample t-tests suitable for the cases where control values were set at 1 (e.g. Fig. 4B, C for the relative expression).
      • In lines 247f. the authors state that "inhibition of MCL-1 leads to [...] and disassembly of the MICOS complex as well as OPA1". This sounds like OPA1 is still cleaved upon MCL-1, which is not at all what the authors showed and further discuss. Rewording of the sentence would help in avoiding any misunderstandings.
      • In lines 210f. the authors state that "quantitative imaging increased the average and maximum volume of lipid droplets". While there is definitely a trend towards an increase for the maximum volume, the increase is in fact not statistically significant. This should be reflected in the wording.
      • In Fig. 6 the overlap between TBR2 and PAX6 is hard to judge when printed out. Including a zoom-in may make it easier to judge.
      • In Fig. 7 the color-coding is listed in the figure legend but is missing from the figure itself. If the authors could include this, as they did for the other figures, it would further improve this figure.
      • Line 238 should reference Fig. 7A, as Fig 7B does not exist.
      • In the figure legends the authors state that biological replicates were used. Were technical replicates also performed?

      Significance

      The authors make use of a wide array of imaging techniques to further elucidate non-apoptotic roles of MCL-1. The study has the potential to offer new insights into mitochondrial biology on the level of basic research rather than translational. While the methods used offer sufficient evidence to connect MCL-1 inhibition to cristae architecture, the mechanistic underpinnings of this effect remain unexplored. Nevertheless, the study offers additional knowledge on the role of MCL-1 in human neural stem cells, whereas previous research mostly focused on cardiomyocytes or cancer cells.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary: This study claims that beyond its canonical anti-apoptotic function, MCL-1 has essential non-apoptotic roles in human neurodevelopment. Pharmacologic inhibition of MCL-1 in human neural stem cells disrupts mitochondrial inner membrane architecture by destabilizing cristae and the OPA1-MICOS complex, leading to swollen mitochondria with disorganized cristae. These structural defects impair fatty acid oxidation and lipid droplet homeostasis, linking cristae integrity to metabolic competence. Independently of apoptosis or proliferation, MCL-1 inhibition selectively depletes intermediate neural progenitors, indicating a direct role in lineage progression. Overall, the work positions MCL-1 as a key regulator of mitochondrial structure-metabolism coupling that instructs neural progenitor identity and human neurogenesis.

      Overall: The study does a good job of using (in most assays) caspase inhibition (e.g., QVD treatment) to block apoptotic responses induced by MCL-1 inhibition. As a result, many of the phenotypes caused by inhibition are likely to be independent of caspase activation. As a result, this manuscript would be of interest to researchers that study the topics of the BCL-2 family and cell death signaling, mitochondrial bioenergetics and dynamics, neurodevelopment, and cellular metabolism. However, as currently presented the manuscript is only descriptive and lacks mechanistic insight.

      Major Concerns:

      1) The authors only use a single MCL-1 inhibitor and never use other non-targeting BH3-mimetics (such as venetoclax) as negative controls. This seems like a missed opportunity to demonstrate that the phenotypes observed are MCL-1 dependent.

      2) There is no mechanism proposed in this study other than reliance upon QVD as not affecting the phenotypes. As submitted, the manuscript only can speculate that these phenotypes are due to non-apoptotic roles of MCL-1 inhibition. The authors have missed an opportunity to explore MCL-1's non-apoptotic functions directly.

      Other concerns exist that weaken the impact of the study.

      1. Figure 1 should include the fact that QVD inhibition (shown in Sup Fig 2) does not obviate the phenotype induced by pharmacological inhibition of MCL-1 on mitochondrial morphology.
      2. Figure 2 would benefit from evidence that caspase inhibition does not repress the phenotype on mitochondrial cristae morphology (volume and area). Furthermore, the FIB-SEM data are very hard to appreciate as the size precludes visualization of individual mitochondria.
      3. Figure 3 reports that MIC60 and OPA1 appear to be downregulated in response to MCL-1 inhibition, but these appear to be more significant only when QVD is added. Why would the phenotype be obscured in the non-QVD setting (Fig. 2B&C). How does MCL-1 inhibition lead to changes in MIC60/MICOS/OPA1? This seems quite preliminary at this point.
      4. The loss of MIC60 and OPA1 should repress electron transport chain function, are such impacts observed in the cultured cells? This could be shown by assessing oxygen consumption, etc. Such data would enhance the authors' conclusion that MCL-1 inhibition leads to defects in mitochondrial physiology.
      5. In Figure 4, the differences between transcripts (qPCR data) and protein (immunoblot) data are often confusing and not well explained. Why do the authors propose that mRNA expression is decreasing whereas the protein expression is increasing? Example CPT1. Furthermore, it is unclear what these data mean functionally? Is this reflective of enhanced lipid oxidation or simply a response to inhibition of fatty acid oxidation? Clarification of the impact of these findings is necessary.
      6. The increase in lipid droplet number induced by MCL-1 inhibition has been previously documented, but it is unclear whether this increase is related to an inability to oxidize lipid (defective fatty acid oxidation) that leads to increases in the cellular abundance or whether this indicates that MCL-1 inhibition leads to enhanced storage. Do other inhibitors of fatty acid oxidation lead to similar increases in lipid droplet size and abundance? Does QVD inhibition affect this phenotype?
      7. For Figure 6, while these data may be very meaningful, as presented they are very hard to appreciate. Insets that show the neuronal populations would help to convey the point that the differentiation is impacted. Also, are there other methods that could confirm these observations (qPCR to show changes in differentiation).
      8. Figure 7 is also very hard to appreciate. What is the reader to see? Can these be quantified? It seems that QVD may be rescuing in this figure, does this suggest that MCL-1 inhibition might be inducing death. All of this needs to be quantified.
      9. BCL-XL has also been implicated in affecting mitochondrial electron transport chain function (See PMID: 19255249, 21926988, 21987637). Can BCL-XL inhibitors affect any of the phenotypes associated here?
      10. Please be carefully avoid using the term "MCL-1 loss", when talking about pharmacological inhibition. Only genetic ablation (e.g. knockout, silencing, etc.) should be termed loss.

      Significance

      The study advances in human cells the impacts of MCL-1 inhibition. They replicate many impacts previously observed in mouse systems and refine analyses to impacts on MICOS complex, lipid droplet storage, and neuronal differentiation. While these findings are important and would be well received by a wide audience, the study fails to provide almost any mechanistic insight into how these phenotypes are being induced. The only common theme is that blocking caspase activation in many assays fails to block the phenotype.

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      Reply to the reviewers

      We thank the reviewers for their time and constructive comments on our manuscript.

      Reviewer #1 recognizes the importance of the question we address (namely, the early consequences of Wilms' tumour inducing mutations on kidney development in two models for different Wilms' tumour initiating mutations) and provides useful suggestions for improvement of the manuscript.

      Reviewer #2 raises the concern regarding the novelty of the study. We appreciate these comments and this implies the necessity of mainly textual changes we have to do to highlight the novel aspects of our study and findings and their significance in the revision of the manuscript.

      Reviewer #3 offers a generally positive assessment of the data, while suggesting that the work may be interpreted primarily from a developmental perspective rather than a Wilms' tumour-focused one. In the revision there is need to better emphasize how these perspectives are closely interconnected in the context of Wilms' tumour biology.

      Reviewer #1 (Evidence, reproducibility and clarity (Required)):

      This manuscript addresses an important gap in Wilms tumor (WT) biology: what are the earliest pathogenic events following WT driver mutation induction, and how do these early developmental trajectories differ across genotypes? The authors provide a carefully staged and comparative analysis of two WT-associated genetic contexts-conditional Wt1 loss (using lineage-specific Cre drivers targeting nephrogenic (Six2-Cre) versus stromal (Foxd1-Cre) compartments, as well as a temporally controlled Wt1CreERT2 model targeting both lineages upon tamoxifen induction) and inducible LIN28B overexpression, and relate the resulting developmental phenotypes to two CSC marker paradigms derived from patient-based studies. A major strength is the precise, time-resolved description of the earliest initiating phenotypes (E12.5 and E18.5, with additional postnatal analysis for LIN28B) and the direct side-by-side comparison of how each genotype perturbs nephrogenesis. The authors conclude that Wt1 loss (especially in the nephrogenic lineage) leads to a severe developmental block accompanied by a disturbance of lineage identity ("lineage confusion"), whereas LIN28B overexpression causes a disturbed transition between uninduced and induced nephron progenitor cell (NPC) states, producing blastemal-like regions that persist postnatally. Using immunostaining for NCAM1, SIX2, CITED1, and ALDH1A2, the authors map marker combinations during normal kidney development and across mutant contexts, and propose that tumor-initiating alterations, most clearly in the LIN28B model, and more suggestively in the Wt1CreERT2 (Wt1CE) context, promote the emergence of a CSC-like population inferred to co-express all four markers (NCAM1+SIX2+CITED1+ALDH1A2+), a state not observed in normal kidneys.

      We thank Reviewer #1 for this correct and complete summary of our manuscript. This reviewer recognizes the current gap in our understanding of the origins of Wilms' tumors and appreciates the approach we have chosen to start filling this gap using two different mouse models.

      Overall, this study provides a particularly clear direct comparison of the earliest tumor-initiating events triggered by distinct WT-relevant driver alterations. While the manuscript does not yet offer a detailed molecular mechanistic framework explaining why these two mutations produce such divergent developmental and marker-state outcomes (which would further strengthen the work), the careful comparison and the conclusions drawn from it are meaningful and make an important contribution to our understanding of the developmental processes that can lead to Wilms tumor initiation.

      We thank this reviewer for recognizing the importance of a direct comparison of the early consequences of two different Wilms' tumour mutations. We agree we do not yet provide a mechanistic framework for these differences. Although these studies are on-going, they are outside the scope of this manuscript.

      *Major comment: 1. A central and highly emphasized conclusion of this manuscript is that tumor-initiating alterations induce a CSC-like population co-expressing all four markers (NCAM1, SIX2, CITED1, and ALDH1A2), and that this state is not observed during normal kidney development. Because this "quadruple-positive" population is a key mechanistic take-home message and closely linked to the overall conceptual model, the manuscript would be substantially strengthened by a direct, same-cell demonstration of co-expression of all four markers, rather than inference from consecutive sections. The authors state that they were unable to do so due to a technical limitation, namely, antibody host-species constraints that prevent co-detection of CITED1 and ALDH1A2 within the same section. *

      We agree that not being able to show co-expression of all 4 CSC markers is a serious limitation for the interpretation of our data. The reviewer suggests the following alternatives:

      *Several feasible approaches could address this limitation for example: - Identify an alternative antibody reagent from a different host species. *

      The 'problematic' antibodies are the ones staining for ALDH1A2 and CITED1, which are both Rabbit IgG. Alternative antibodies for ALDH1A2 are all raised in rabbit, so these will not solve this problem. For CITED1 we have now identified a biotin-conjugated antibody which could be used in additional co-staining. We propose to test this antibody for the revision of this manuscript.

      *- RNAscope / smFISH for in situ single-cell co-detection. *

      We are aware of these techniques as alternative for antibody staining. However, we have no experience with these techniques, nor do we have access to the required technologies. After discussions with collaborators with much experience in this technique, we realized the combination of the potential extensive optimization and costs does not make this a suitable alternative for the limited samples we have available.

      *- Single-cell RNA-seq (scRNA-seq) to test whether a bona fide quadruple-positive transcriptional state exists. *

      This could be an option but is itself a huge project and therefore outside the scope of this manuscript. We note that the known scarcity in single cell data might still complicate the detection of each marker in individual cells, especially for low-expressed TFs like Six2 and Cited1.

      *Overall, resolving this technical limitation would markedly increase confidence in one of the manuscript's most important claims and strengthen the proposed genotype-phenotype/CSC-marker framework

      *

      _As discussed above, we propose the t_ry the biotin-conjugated CITED1 antibody__

      • It is somewhat unexpected that the Six2-specific Wt1 deletion appears to produce a more severe phenotype than the tamoxifen-inducible Wt1CreERT2 approach, which is intended to target a broader Wt1-derived lineage (both nephrogenic and stromal). The Discussion offers several plausible, non-mutually exclusive explanations for this observation (e.g., timing, recombination efficiency/mosaicism, and the rescue contribution of "escaping" wild-type cells). It would be helpful to support at least one of these explanations experimentally. For example, the authors could quantify the extent of "escape" (percentage of non-recombined cells within the lineage) across embryos/timepoints to validate that mosaicism is indeed the cause of the milder phenotype. *

      We can address this experimentally by making use of the tdTomato Cre reporter that was included in our model which allows us to follow the fate of mutated and non-mutated cells in the lineage. We propose to combine Six2 antibody staining with the tdTomato signal to quantify the percentage of cells that has maintained Six2 expression and is therefore likely an escaping cell/nephron.

      Minor comments 1. Please clarify whether the difference shown in Fig. 2C is statistically significant, and report n, error bars/variation, the statistical test used, and p-values (if applicable).

      These details will all be added.

      • The authors note the presence of some SIX2+; tdTomato+ cells in Foxd1GC control kidneys. Given the expected stromal restriction of Foxd1 lineage labeling, please clarify the likely explanation and, if possible, indicate how frequent this is.

      *

      The reviewer here points to the important question regarding the origin and potential overlap between the stromal and nephrogenic lineages. This is not only an important but highly relevant question for origin and biology of Wilms' tumours, but also for normal kidney development. Kobayashi et al (2014) reported some contribution of the Foxd1 lineage in the Six2 lineage. Also Magella et al (2018) found some signs for this, as did a recent pre-print (Haghighitalab et al. 2026). There is even data suggesting that (part of) the renal stromal is derived from the paraxial instead of intermediate mesoderm in chicken (Guillaume et al. 2009) with some supportive data from mouse development as well (Levinson et al. 2005). The latter is especially interesting given the commonly found ectopic muscle differentiation in WT1-mutant Wilms' tumours (Miyagawa et al. 1998; Schumacher et al. 2003; Gadd et al. 2012). However, if a common, potentially Foxd1+/Six2+ double positive, progenitor exists, it will in the normal developing kidney be present before E11.5 and therefore the data in our current manuscript, or the unpublished scMultiome data, is not informative for this. We propose to discuss this in detail in the Discussion of the manuscript, and speculate on its relevance for Wilms' tumours.

      It is somewhat unexpected that Six2-specific Wt1 deletion appears to produce a more severe phenotype than the tamoxifen-inducible Wt1CreERT2 approach, which is intended to target a broader Wt1-derived lineage. The Discussion offers several plausible, non-mutually exclusive explanations (e.g., timing and/or recombination efficiency/mosaicism and the contribution of "escaping" cells). it would be helpful to support at least one of these explanations experimentally, for example by quantifying the extent of "escape" across embryos/timepoints and tamoxifen dosing.

      This was addressed above.

      *4. A careful proofreading pass is needed to ensure text-figure consistency, particularly for arrow annotations. For example, the Results text refers to "Fig. 1F, arrows," but arrows are not apparent in that panel. Likewise, the Results text mentions a "white filled arrow" in Fig. 2H, whereas the figure appears to show only open arrows. Please align the wording with the annotations actually shown in the figures. *

      We apologize for these errors and thank the reviewer for pointing them out. These, and all other textual and graphical errors, will be corrected in the new version of the manuscript.

      __Reviewer #1 (Significance (Required)): __

      Overall, this study provides a particularly clear direct comparison of the earliest tumor-initiating events triggered by distinct WT-relevant driver alterations. While the manuscript does not yet offer a detailed molecular mechanistic framework explaining why these two mutations produce such divergent developmental and marker-state outcomes (which would further strengthen the work), the careful comparison and the conclusions drawn from it are meaningful and make an important contribution to our understanding of the developmental processes that can lead to Wilms tumor initiation.

      We thank the reviewer for this comment, and like to emphasize that this is precisely the scope we intended with the current manuscript.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      *Wilm's Tumor, a pediatric kidney cancer, is associated with gain or loss of activity of a number of genes including the loss of activity of the nucleic acid binding protein WT1 and gain of activity (enhanced expression at the mRNA level) of the RNA binding protein Lin28 which negatively impacts the maturation of the miicroRNA let-7, elevating levels of let-7 targets. Previous mouse studies have examined the impact of loss of Wt1 throughout within the nephron progenitor and interstitial cell compartments in capping mesenchyme that is thought to be the source of the tumor and of broad elevated expression in all kidney progenitors. *

      *In this manuscript, the authors have refined the loss of Wt1 to nephron or stromal progenitors and compared the phenotype to loss of Wt1 in both lineages examining cultured kidneys over a 72 hr period, in addition to uncultured kidneys examined at e18.5. A similar analysis was performed on Lin28 mutants. The analysis itself consisted of video imaging, limited immunostaining and histochemistry. *

      Reviewer #2 provides, in our opinion, a very limited overview of the contents of our manuscript. Our work presented here shows:

      • A detailed analysis of effects of Wt1 loss or activation of LIN28B in the following systems:
      • 5 embryonic kidneys
      • 5 embryo kidneys
      • P19 postnatal kidneys (for the LIN28B model)
      • In vitro cultured kidneys.
      • Time-laps analysis of in vitro cultured kidneys

      • In the case of the Wt1 knockout this was studied in nephrogenic, stromal, and the combination of nephrogenic and stromal lineages

      • Whereas our previous work (Berry et al. 2015) focused on different stages of nephron development, we now focus on the different lineages.
      • For the first time we study the different marker sets for Wilms' tumour cancer stem cells in their developmental context. Important take-home messages for this are:
      • The two published maker sets behave different in the normal developing kidney, and no cell types or developmental stages exist in the normal developing kidney that expresses all four markers
      • In contrast, after either of the two Wilms' tumour mutations are induced, we have strong, though not yet conclusive, evidence that this event induces cells that are positive for all four CSC markers, suggesting these quadruple-positive cells could be the functional CSCs. This mutation-dependent appearance of the CSCs would be a complete different mechanism for the origin of CSCs than believed for, for instance, leukemia and colorectal cancer, where an existing cell type with stem- or progenitor cell characteristics which already express the CSC markers picks up the tumour initiating mutations and thus starts behaving as CSC. The cascade our data suggests for the Wilms' tumour CSCs is much more complex.

      • To our knowledge this is the first direct and side-by-side comparison of the early effects of different Wilms' tumour mutations. This analysis clearly shows the differences in underlying biology for these two situations, and this can have important consequences for interpretation of patients data (which was historically almost always generated without knowing the initiating mutation) and opens the possibility of mutation-specific therapeutic possibilities and requirements. This is funcamentally different from the current patient stratification based on clinical outcome (favorable vs non-favorable histology) or very general molecular markers with clear biological consequences (like chr 1p status).

      • With respect to the mutation-dependent accumulation of CSC markers, although in both Wt1 and LIN28B models this seems to be happening, for the LIN28B model this seems to be the result of a simple developmental block, whereas for the Wt1 mutants this appears to be a lineage conversion phenotype. This is again something that has to our knowledge never been suggested for the origin of CSCs and even in the context of normal kidney development is almost unprecedented.
      • We optimize the use of the Wt1CreERT2 driver to target different lineages in the developing kidney using different timepoints for tamoxifen treatment. Not only does this have technical use, it also illustrates the complex role of Wt1 in the earliest stages of kidney development.

      Although the data presented are descriptive and do not yet provide a complete molecular mechanism, we believe they offer novel, unexpected and important insights that merit publication. We acknowledge that these aspects may not have been sufficiently clear in the original version of the manuscript, and therefore not being picked up by the reviewer. In response to Reviewer #2 comments, we propose a thorough rewrite of the Discussion of the manuscript to emphasize these aspects more.

      *While wholly qualitative and largely observational and descriptive, the limited data are of good quality and the conclusions drawn are reasonable. *

      We thank the reviewer for their compliments on the quality and conclusions of the data. While we acknowledge the reviewer's characterization of the study as quantitative and descriptive, we respectfully do not consider this to diminish its suitability for publication. We believe the dataset provides substantial and meaningful insights (definitely not limited), and we have clarified and expanded upon the novel aspects and significance of our findings as outlined above.

      *For the Wt1 study, most interesting would be in the loss of Wt1 from the NPC lineage. Clearly, there is already a significant phenotype at the time of study (E12.5) hence there is no strong insight into the earliest effects of Wt1 loss and how this might contribute to tumor formation. Quite what happens to these cells phenotypically is unclear given the limited set of markers used to look at the cells. Specific removal of Wt1 from the stromal lineage generates a milder phenotype, indicating a role for Wt1 there, but without a mechanistic analysis of the resultant products, the underlying mechanisms remain unclear. *

      As discussed in our response to reviewer #1, we agree on the lack of mechanism in the current study but emphasize here as well that although this is the topic of the on-going follow-up studies this is outside the scope of the current manuscript. We refer to the same response for our proposal for additional experiments for the revised version of the manuscript.

      *Wt1 removal from both lineages generated a phenotype less severe than removal from nephron progenitors (and previous data on "double lineage removal" with a Nestin1 cre), an indication that the genetic approach was not up to the task. *

      Respectfully, we would like to emphasize the practical challenges associated with the use of genetically modified mouse models for developmental (and other) studies. We doubt there are many Cre drivers that do exactly what they were intended to do, do only that, and at full 100% efficiency. Many Cre drivers are, when originally described, only described for the cell type they were intended for, and any other activities or limitations are missed or ignored. One could rightfully argue that is bad science, but unfortunately this is often the reality and the starting point for many in vivo analyses. And these are only the complications regarding the behaviour of the Cre driver, and does not even touch on issues like the biological processing of tamoxifen, and the stability of already existing mRNA and protein of the gene of interest in the context of, in this case, a rapidly developing organ. Simply dismissing technical complications as 'not up to the task' is in our opinion not the way forward for studying the origin of diseases.

      What is important, and what we demonstrate, is the realization of the limitations of a system, test them and where possible take them into account in the interpretation of data. In this case, instead of hiding the incompleteness of the Cre activity, we actually demonstrate this using retained staining of Wt1 and discuss this in the context of the different phenotypes. We have carefully tried not to overinterpret our data, and note that this reviewer does not give any specifics where this could be affecting our manuscript.

      We also like to stress that in the context of Wilms' tumour development the incomplete activity of this Cre driver could even increase the relevance of this model, since the early stages of Wilms' tumourigenesis in the (future) patient happen in a few mutant cells in the context of a further normal developing kidney. The effect of the normal cells in our model that we speculate about could also be important in the patient, we just don't have the technical possibilities to test this yet.

      *In some sense, one could regard this work as a pilot study, looking to optimize expensive and time-consuming mouse experiments to maximize insight (ie choose optimum model, address most informative time points, decide on analytical approaches). As a stand-alone paper, the work may not significantly advance our understanding of the topic. *

      As argued above, in our opinion this does not do justice to the work we describe in our manuscript.

      For example, can simple loss of Wt1 tells us anything about Wt? Yes Wt1 is lost in a subset, but even in these there are additional genetic mutations.

      Of course even in WT1-mutant tumours there will be additional mutations found in the tumour. In fact, it has been known for a long time that WT1-mutant Wilms' tumours select for oncogenic mutations in β-catenin with a surprising preference for specific mutations affecting Ser45. However, it is clear that in these tumours the loss of WT1 is the first, rate-limiting step (Fukuzawa et al. 2004; Li et al. 2004; Zirn et al. 2006; Uschkereit et al. 2007). These β-catenin mutations are selected for in an already WT1-mutant context. If we want to understand the full biology of the WT1 mutant tumours including the β-catenin mutation, we will first need to understand the effect of only losing WT1 because that is what provide the selective pressure for the next step (oncogenic mutation in β-catenin). The work described here is an essential first step in that.

      • For Lin12, there is no significant advance beyond the studies of the Daly lab. *

      As argued above, this is not correct. The following aspects were not covered in the original paper describing this model:

      • The in vitro analysis of control and LIN28B embryonic kidneys, including the time-lapse analysis demonstrating how the phenotype develops over time
      • The expression of the Wilms' tumour cancer stem cell markers and how these change as a result of the LIN28B activation
      • The direct comparison to the Wt1 loss phenotypes, and the demonstration these different mutations lead to fundamentally different biological phenotypes despite both eventually being classified as Wilms' tumours.

        I have no useful suggestions for improvement which would require a completely different approach to the problem from the start.

      We respect this reviewer's opinion, but based on the above we do not agree and maintain a different interpretation.

      Reviewer #2 (Significance (Required)):

      *The authors set out the goal in the introduction - to obtain a better understanding of the origins of Wilm's tumor. There doesn't appear to be an insight of cancer relevant significance beyond earlier studies. *

      Our work studies the very first steps in the development of Wilms' tumours. It will never be possible to study this in the (future) patient as these happen around wk 8-10 of pregnancy. By instead analyzing this in mouse models we show fundamental biological differences between different Wilms' tumour inducing mutations which is for sure relevant for patients, the interpretation of patient data (or more the difficulties with interpreting patient data if the initiating mutation or tumour class is not known). Moreover, the data provides new insights in the Wilms' tumour cancer stem cells, a preferred target for any therapy, and suggests the combination of all four known markers might be required to identify and study the true WT CSC. In our opinion such findings provide extremely relevant insights for the field.

      *To a readership now/too used to analysis at genome scales (genomic, transcription), this study might appear modest. *

      While we agree that genome-wide approaches can provide valuable insights, this doesn't mean that work that doesn't use them cannot provide important insights nor does it mean that every piece of work that does use them provides any new insights. We respectfully emphasize that the merit of a study should be assessed based on the data presented and their interpretation, rather than on the techniques that were used to obtain them.

      The target audience is unclear.

      Our target audience for this manuscript is everybody who is interested, for whatever reason, in the biology of Wilms' tumours.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      *Wilms tumor arises from disrupted kidney development. Progenitor-like populations and cancer stem cell (CSC) fractions have been described in patient tumors, but how specific mutations alter embryonic programs to generate these states remains unresolved. *

      *Pop et al. model genotype-phenotype relationships during kidney embryogenesis. Using Six2- and Foxd1-driven Cre lines, they test the effects of Wt1 loss-of-function and Lin28b gain-of-function in nephron and stromal progenitors. Through explant imaging, histology, and immunofluorescence, they define mutation-specific effects on ureteric branching, cap mesenchyme organization, stromal composition, and nephron differentiation. *

      *Lineage-restricted Wt1 deletion produces distinct outcomes depending on whether nephron progenitors, stromal progenitors, or both are targeted. Lin28b overexpression causes delayed nephrogenesis and lobular organization resembling human Wilms tumor morphology, with expansion of blastemal-like populations. *

      This is a correct summary of this part of our data.

      These genetic removals of Wt1 and overexpression of Lin28b are useful for the field in understanding where and how Wt1 functions and whether Lin28b could be a model for Wilms' tumor.

      We agree that our data on Wt1 loss focusses on the role of Wt1 in normal kidney development, how its loss disrupts normal kidney development and how this could be important for Wilms' tumourigenesis. This includes but goes beyond being only relevant for the function of Wt1, it informs on the biology of WT1-mutant Wilms' tumours.

      There is in our mind no doubt whether the LIN28B model is a model for Wilms' tumours. Activating mutations in LIN28B are found in human patient tumours, and already in the original publication of this model (Urbach et al. 2014) it was convincingly shown that the phenotype in the kidneys after less than 3 weeks (when the animals have to be culled animal welfare reasons) represents early stages of Wilms' tumours. Our data presented here confirms this, and extends it with respect to the behavior of the CSC markers and the comparison to the Wt1 loss phenotypes.

      Whether the use of previously defined markers NCAM and Aldeflour serve the authors well or is a distraction is to be determine but it is unclear how useful these have been for understanding WT biology thus far. The authors describe these in the developing kidney in explants and in vivo.

      *Overall, the data support the view that distinct mutations generate different forms of lineage derailment but it is unclear how this links to Wilms tumor. It is better suited to dsescribe the role of an interesting protein Wt1 in kidney development and lineages therein. Connecting it to tumor biology would require further scrutiny of tumors. *

      Since CSCs are, according to the cancer stem cell model, the cells in a tumour that should preferentially be targeted, the exact identification of the CSC markers is directly important for the treatment of tumours. Our data analyzes two different sets of CSC markers, we show these cells label non-overlapping cell types in the normal kidney but that after mutation induction their expression changes and potentially become co-expressed in a single cell type (see our response to Reviewer #1 for more details on this). Identifying the developmental origins of CSCs in a tumour that is the direct result of disturbance of normal embryonic development (Hohenstein et al. 2015; Li et al. 2021) can be used as an entry point into understanding the biology of these tumours. Based on this we argue that although our analysis is on embryonic kidneys, their implications are highly relevant for the actual tumours and their treatment. We propose to further emphasize this in the Introduction and Discussion of our manuscript.

      *The study shows that removal of Wt1 in the stromal compartment has distinct phenotypes, which could be important for Wilms tumor biology as this is an poorly understood part of this tumor. *

      As already discussed in our response to Reviewer #1, we agree this is a potential important and poorly understood part of Wilms' tumours, directly for WT1 mutant tumours which are stromal-predominant, but potentially also for other tumours. We propose to further address this in the Discussion of the manuscript.


      *Major comments: *

        • This manuscripts uses elegant genetics to scrutinize the role of Wt1 and Lin28b. These stand out as difficult to conduct experiments and are of high value. *

      We thank this Reviewer's appreciation for the design, challenges and value of our data.

      In contrast, the section on ALDH1A2 and ALDEFLUOR activity is less integrated with the developmental framework.

      We discussed our reasons for focusing on the normal developmental context of the cells expressing the CSC markers in the previous section. Since the originally described CSC marker was activity for the AldeFluor enzymatic assay (Pode-Shakked et al. 2013) which we could not use on sections or kidney rudiments, we had to conclusively identify which ALDH isozyme is responsible for this signal in this context. There is much inconsistency about this in the literature, and whichever isozyme is important in these tumours might not be the causative factor in other tumours where AldeFluor labels the CSCs. We therefore use previously published microarray data from the group that originally identified the NCAM1/ AldeFluor combination as Wilms' tumour CSCs to identify ALDH1A2 as the culprit in this cancer type. With this knowledge we could move our analyses to antibodies, allowing co-staining with the other markers. Note that if the signal in these CSCs would have been the result of ALDH1A1 or ALDH1A3 which we show are expressed in the developing ureteric bud, the implications of this for the biology of the tumours would be totally different. We propose to discuss this aspects and its importance in more detail in the revised manuscript.

      *Much is unclear here e.g, antibody validation, rationale for performing these assays in explants rather than in vivo tissue, and the shift in Aldh1a2 staining pattern between E12.5 and E18.5, including reported nuclear localization.

      *

      We need to correct the reviewer on this remark, part of our data is using in vivo samples (E12.5 and E18.5) as well as cultured kidney rudiments. We will clarify which technique we use in the legends of the figures. We prefer to use this combination of techniques for several reasons: 1) the additional 3D information obtained from kidney rudiments can help with identifying specific developmental stages in the developing kidney; 2) due to the different fixation more antibodies work reliably in cultured rudiments than on paraffin frozen sections; 3) this is an important extra factor in the validation of antibodies; and 4) the possibility of culturing kidney rudiments on a time-lapse imaging system allows us to study phenotypes over time (this also greatly reduces the number of animals we need to study multiple timepoints in a developing system, an important aspect for the 3Rs). A good example of this in the timelapse data shown for the nephrogenic Wt1 knockout. The extreme outwards migration of the mutant cells (we show this using the tdTomato reporter) could only be identified in timelapse experiments, but is fully consistent with the sections of the corresponding E12.5 and E18.5 in vivo sections.

      We have no explanation for the shift to nuclear localization for ALDH1A2. We are not aware of any other publications showing this. We cannot rule out this is a technical artifact but based on all other expression data obtained with this antibody and their consistency with other publication we don't think this is very likely.

      *It is unclear how the manuscript is strengthened by this component. NCAM1 is referenced in the context of Wilms tumor CSCs, but unlike the rest of the manuscript which is mechanistic, it is unclear whether NCAM1 represents a mechanistic node in tumor initiation or merely a surface marker used for cell isolation? If NCAM1 functions just as a proxy for a progenitor-like state rather than a driver of tumor biology surely Wilms tumors will be full of progenitors or blastemal cells and many surface markers. It is unclear what strong evidence shows NCAM1 to be useful, this distinction should be stated. *

      Cancer stem cells are defined based in functional characteristics, i.e. the capability of reconstituting a complete tumour with all of its complexity after transplantation in immune-compromised mice. The markers are usually, indeed, merely proxy markers for a specific cell type in the tumour with this functional capacity. The same can be said in this case for the AldeFluor activity, it is used as CSC marker for many cancer types but we are not aware of any data on a functional role for this pathway in any of them. It would be a really interesting experiment to combine our models with an additional conditional knockout for Ncam1 or Aldh1a2 to see if the phenotype we describe here changes. The genetics of such an experiment with so many alleles are however horrendous, would come with an enormous surplus of animals and would take too long for the average project.

      The developmental framework presented argues that mutation-specific lineage derailment underlies tumor formation. Marker identity alone does not define pathogenesis. Perhaps reorganize this section to align it with the lineage-confusion model or removing it altogether would make the manuscript punchier?

      • *

      We propose to rewrite these parts to make this more clear.

      • *
      • The manuscript is highly focused on the nephrogenic compartment yet removes Wt1 from the stroma as part of one of the main lines of experiments. At several occasions, stromal changes are described qualitatively but using quantitative terms. As such, the manuscript currently comes across as having a bit of a black box where we cannot see the stroma beyond H&E stains. Could there additional antibody stains for stromal markers e.g., Pdgfra, Pdgfrb, or Meis1 to better visualize this compartment and perhaps enable quantification of changes?*

      We agree this lack of additional stromal markers is a limitation of the current manuscript. Our reason for so far not including these was our doubts on the usefulness and relevance for the complete renal stroma of many commonly used markers. The scarceness of detailed studies on the developing stroma was a big part of this doubt. Some preliminary tests show that Meis1 is not exclusively found in the developing stroma of the mouse kidney but is also expressed in early stages of the nephrogenic lineage, and is therefore not a good marker for this purpose. Pdgfra and Pdgfrb however seem to be expressed throughout the complete stroma and not in the other lineages. __We propose to analyze these two additional markers for the revised manuscript. __

      *Minor comments: *

      *Page 4, Lines 89-95: Remove the repeated sentence beginning "Although best known as a transcription factor...". *

      *Page 8, Line 164: Arrows referenced in Figure 1F are not visible. *

      *Page 8, Lines 164-166: The sentence may refer to Figure 1G; this figure is not otherwise cited. *

      *Page 18, Lines 413-414: (Pode-Shakked et al., 2013) is cited twice. *

      *Figure 2C: Error bars are missing. Indicate number of biological replicates. *

      *Gene nomenclature should be consistent throughout the manuscript. A mouse protein/gene is Six2/Six2. *

      *Use precise language when referring to protein detection rather than "expression." *

      *Standardize corticomedullary orientation across figures. *

      *Page 7, Lines 160-161: Provide immunostaining supporting WT1+/Tdtomato− stromal identity. Co-staining with Foxd1 would clarify lineage assignment. *

      *At E18.5 in the Six2-driven Wt1 mutant, WT1 signal is absent despite earlier stromal WT1+ cells. Clarify the fate of these cells. *

      *Comment on the lower recombination efficiency observed in Wt1CE at E11.5. *

      *Page 14, Lines 321-322: Determine how long CITED1 persists in WTCE mice. Co-staining with later differentiation markers would clarify whether progenitor retention coexists with nephron maturation. *

      Page 15, Lines 352-353: Clarify whether the sentence describing blastemal-like regions should reference Figure 5D.

      We thank the reviewer for these correction and other minor comments. We will address them in the revised manuscript. With respect to the remark regarding the gene nomenclature, until recently we were also under the assumption that mouse proteins only have the first character as capital. However, to our surprise we recently realized the official mouse nomenclature states that the protein (but not the gene) is in fact in all capitals. We refer for this to section 1.5.2 at https://www.informatics.jax.org/mgihome/nomen/gene.shtml.

      References.

      Berry RL, Ozdemir DD, Aronow B, Lindstrom NO, Dudnakova T, Thornburn A, Perry P, Baldock R, Armit C, Joshi A et al. 2015. Deducing the stage of origin of Wilms' tumours from a developmental series of Wt1-mutant mice. Dis Model Mech 8: 903-917.

      Fukuzawa R, Breslow NE, Morison IM, Dwyer P, Kusafuka T, Kobayashi Y, Becroft DM, Beckwith JB, Perlman EJ, Reeve AE. 2004. Epigenetic differences between Wilms' tumours in white and east-Asian children. Lancet 363: 446-451.

      Gadd S, Beezhold P, Jennings L, George D, Leuer K, Huang CC, Huff V, Tognon C, Sorensen PH, Triche T et al. 2012. Mediators of receptor tyrosine kinase activation in infantile fibrosarcoma: a Children's Oncology Group study. J Pathol 228: 119-130.

      Guillaume R, Bressan M, Herzlinger D. 2009. Paraxial mesoderm contributes stromal cells to the developing kidney. Dev Biol 329: 169-175.

      Haghighitalab A, Nosrati F, Dehghani-Ghobadi Z, Sayed M, Ahn C, Hu Y-C, Chung E, Lim H-W, Park J-S. 2026. A knock-in Six2Cre line reveals transient interstitial potential in nephron progenitors. bioRxiv: 2026.2002.2004.703893.

      Hohenstein P, Pritchard-Jones K, Charlton J. 2015. The yin and yang of kidney development and Wilms' tumors. Genes Dev 29: 467-482.

      Kobayashi A, Mugford JW, Krautzberger AM, Naiman N, Liao J, McMahon AP. 2014. Identification of a Multipotent Self-Renewing Stromal Progenitor Population during Mammalian Kidney Organogenesis. Stem Cell Reports 3: 650-662.

      Krishna A, Meynert A, Dolt KS, Kelder M, Mesropian A, Ewing A, Brouwers C, Claassens JW, Linssen MM, Sheraz S et al. 2026. Mutational scanning reveals oncogenic CTNNB1 mutations have diverse effects on signaling. Nat Genet 58: 366-375.

      Levinson RS, Batourina E, Choi C, Vorontchikhina M, Kitajewski J, Mendelsohn CL. 2005. Foxd1-dependent signals control cellularity in the renal capsule, a structure required for normal renal development. Development 132: 529-539.

      Li CM, Kim CE, Margolin AA, Guo M, Zhu J, Mason JM, Hensle TW, Murty VV, Grundy PE, Fearon ER et al. 2004. CTNNB1 mutations and overexpression of Wnt/beta-catenin target genes in WT1-mutant Wilms' tumors. Am J Pathol 165: 1943-1953.

      Li H, Hohenstein P, Kuure S. 2021. Embryonic Kidney Development, Stem Cells and the Origin of Wilms Tumor. Genes (Basel) 12.

      Magella B, Adam M, Potter AS, Venkatasubramanian M, Chetal K, Hay SB, Salomonis N, Potter SS. 2018. Cross-platform single cell analysis of kidney development shows stromal cells express Gdnf. Dev Biol 434: 36-47.

      Miyagawa K, Kent J, Moore A, Charlieu JP, Little MH, Williamson KA, Kelsey A, Brown KW, Hassam S, Briner J et al. 1998. Loss of WT1 function leads to ectopic myogenesis in Wilms' tumour. Nat Genet 18: 15-17.

      Pode-Shakked N, Shukrun R, Mark-Danieli M, Tsvetkov P, Bahar S, Pri-Chen S, Goldstein RS, Rom-Gross E, Mor Y, Fridman E et al. 2013. The isolation and characterization of renal cancer initiating cells from human Wilms' tumour xenografts unveils new therapeutic targets. EMBO Mol Med 5: 18-37.

      Schumacher V, Schuhen S, Sonner S, Weirich A, Leuschner I, Harms D, Licht J, Roberts S, Royer-Pokora B. 2003. Two molecular subgroups of Wilms' tumors with or without WT1 mutations. Clin Cancer Res 9: 2005-2014.

      Urbach A, Yermalovich A, Zhang J, Spina CS, Zhu H, Perez-Atayde AR, Shukrun R, Charlton J, Sebire N, Mifsud W et al. 2014. Lin28 sustains early renal progenitors and induces Wilms tumor. Genes Dev 28: 971-982.

      Uschkereit C, Perez N, de Torres C, Kuff M, Mora J, Royer-Pokora B. 2007. Different CTNNB1 mutations as molecular genetic proof for the independent origin of four Wilms tumours in a patient with a novel germ line WT1 mutation. J Med Genet 44: 393-396.

      Zirn B, Samans B, Wittmann S, Pietsch T, Leuschner I, Graf N, Gessler M. 2006. Target genes of the WNT/beta-catenin pathway in Wilms tumors. Genes Chromosomes Cancer 45: 565-574.

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      Referee #3

      Evidence, reproducibility and clarity

      Wilms tumor arises from disrupted kidney development. Progenitor-like populations and cancer stem cell (CSC) fractions have been described in patient tumors, but how specific mutations alter embryonic programs to generate these states remains unresolved. Pop et al. model genotype-phenotype relationships during kidney embryogenesis. Using Six2- and Foxd1-driven Cre lines, they test the effects of Wt1 loss-of-function and Lin28b gain-of-function in nephron and stromal progenitors. Through explant imaging, histology, and immunofluorescence, they define mutation-specific effects on ureteric branching, cap mesenchyme organization, stromal composition, and nephron differentiation. Lineage-restricted Wt1 deletion produces distinct outcomes depending on whether nephron progenitors, stromal progenitors, or both are targeted. Lin28b overexpression causes delayed nephrogenesis and lobular organization resembling human Wilms tumor morphology, with expansion of blastemal-like populations. These genetic removals of Wt1 and overexpression of Lin28b are useful for the field in understanding where and how Wt1 functions and whether Lin28b could be a model for Wilms' tumor. Whether the use of previously defined markers NCAM and Aldeflour serve the authors well or is a distraction is to be determine but it is unclear how useful these have been for understanding WT biology thus far. The authors describe these in the developing kidney in explants and in vivo.

      Overall, the data support the view that distinct mutations generate different forms of lineage derailment but it is unclear how this links to Wilms tumor. It is better suited to dsescribe the role of an interesting protein Wt1 in kidney development and lineages therein. Connecting it to tumor biology would require further scrutiny of tumors. The study shows that removal of Wt1 in the stromal compartment has distinct phenotypes, which could be important for Wilms tumor biology as this is an poorly understood part of this tumor. My recommendation is that the manuscript would be considered for a major revision where it is more focused on kidney biology.

      Major comments:

      1. This manuscripts uses elegant genetics to scrutinize the role of Wt1 and Lin28b. These stand out as difficult to conduct experiments and are of high value. In contrast, the section on ALDH1A2 and ALDEFLUOR activity is less integrated with the developmental framework. Much is unclear here e.g, antibody validation, rationale for performing these assays in explants rather than in vivo tissue, and the shift in Aldh1a2 staining pattern between E12.5 and E18.5, including reported nuclear localization. It is unclear how the manuscript is strengthened by this component. NCAM1 is referenced in the context of Wilms tumor CSCs, but unlike the rest of the manuscript which is mechanistic, it is unclear whether NCAM1 represents a mechanistic node in tumor initiation or merely a surface marker used for cell isolation? If NCAM1 functions just as a proxy for a progenitor-like state rather than a driver of tumor biology surely Wilms tumors will be full of progenitors or blastemal cells and many surface markers. It is unclear what strong evidence shows NCAM1 to be useful, this distinction should be stated. The developmental framework presented argues that mutation-specific lineage derailment underlies tumor formation. Marker identity alone does not define pathogenesis. Perhaps reorganize this section to align it with the lineage-confusion model or removing it altogether would make the manuscript punchier?
      2. The manuscript is highly focused on the nephrogenic compartment yet removes Wt1 from the stroma as part of one of the main lines of experiments. At several occasions, stromal changes are described qualitatively but using quantitative terms. As such, the manuscript currently comes across as having a bit of a black box where we cannot see the stroma beyond H&E stains. Could there additional antibody stains for stromal markers e.g., Pdgfra, Pdgfrb, or Meis1 to better visualize this compartment and perhaps enable quantification of changes?

      Minor comments:

      Page 4, Lines 89-95: Remove the repeated sentence beginning "Although best known as a transcription factor...".

      Page 8, Line 164: Arrows referenced in Figure 1F are not visible.

      Page 8, Lines 164-166: The sentence may refer to Figure 1G; this figure is not otherwise cited.

      Page 18, Lines 413-414: (Pode-Shakked et al., 2013) is cited twice.

      Figure 2C: Error bars are missing. Indicate number of biological replicates.

      Gene nomenclature should be consistent throughout the manuscript. A mouse protein/gene is Six2/Six2.

      Use precise language when referring to protein detection rather than "expression."

      Standardize corticomedullary orientation across figures.

      Page 7, Lines 160-161: Provide immunostaining supporting WT1+/Tdtomato− stromal identity. Co-staining with Foxd1 would clarify lineage assignment.

      At E18.5 in the Six2-driven Wt1 mutant, WT1 signal is absent despite earlier stromal WT1+ cells. Clarify the fate of these cells.

      Comment on the lower recombination efficiency observed in Wt1CE at E11.5.

      Page 14, Lines 321-322: Determine how long CITED1 persists in WTCE mice. Co-staining with later differentiation markers would clarify whether progenitor retention coexists with nephron maturation.

      Page 15, Lines 352-353: Clarify whether the sentence describing blastemal-like regions should reference Figure 5D.

      Significance

      Overall, the data support the view that distinct mutations generate different forms of lineage derailment but it is unclear how this links to Wilms tumor. It is better suited to dsescribe the role of an interesting protein Wt1 in kidney development and lineages therein. Connecting it to tumor biology would require further scrutiny of tumors. The study shows that removal of Wt1 in the stromal compartment has distinct phenotypes, which could be important for Wilms tumor biology as this is an poorly understood part of this tumor.

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      Referee #2

      Evidence, reproducibility and clarity

      Wilm's Tumor, a pediatric kidney cancer, is associated with gain or loss of activity of a number of gene including the loss of activity of the nucleic acid binding protein WT1 and gain of activity (enhanced expression at the mRNA level) of the RNA binding protein Lin28 which negatively impacts the maturation of the miicroRNA let-7, elevating levels of let-7 targets. Previous mouse studies have examined the impact of loss of Wt1 throughout within the nephron progenitor and interstitial cell compartments in capping mesenchyme that is thought to be the source of the tumor and of broad elevated expression in all kidney progenitors.

      In this manuscript, the authors have refined the loss of Wt1 to nephron or stromal progenitors and compared the phenotype to loss of Wt1 in both lineages examining cultured kidneys over a 72 hr period, in addition to uncultured kidneys examined at e18.5. A similar analysis was performed on Lin28 mutants. The analysis itself consisted of video imaging, limited immunostaining and histochemistry.

      While wholly qualitative and largely observational and descriptive, the limited data are of good quality and the conclusions drawn are reasonable. For the Wt1 study, most interesting would be in the loss of Wt1 from the NPC lineage. Clearly, there is already a significant phenotype at the time of study (E12.5) hence there is no strong insight into the earliest effects of Wt1 loss and how this might contribute to tumor formation. Quite what happens to these cells phenotypically is unclear given the limited set of markers used to look at the cells. Specific removal of Wt1 from the stromal lineage generates a milder phenotype, indicating a role for Wt1 there, but without a mechanistic analysis of the resultant products, the underlying mechanisms remain unclear. Wt1 removal from both lineages generated a phenotype less severe than removal from nephron progenitors (and previous data on "double lineage removal" with a Nestin1 cre), an indication that the genetic approach was not up to the task.

      In some sense, one could regard this work as a pilot study, looking to optimize expensive and time-consuming mouse experiments to maximize insight (ie choose optimum model, address most informative time points, decide on analytical approaches). As a stand-alone paper, the work may not significantly advance our understanding of the topic. For example, can simple loss of Wt1 tells us anything about Wt? Yes Wt1 is lost in a subset, but even in these there are additional genetic mutations. For Lin12, there is no significant advance beyond the studies of the Daly lab.

      I have no useful suggestions for improvement which would require a completely different approach to the problem from the start.

      Significance

      The authors set out the goal in the introduction - to obtain a better understanding of the origins of Wilm's tumor. There doesn't appear to be an insight of cancer relevant significance beyond earlier studies. To a readership now/too used to analysis at genome scales (genomic, transcription), this study might appear modest. The target audience is unclear.

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      Referee #1

      Evidence, reproducibility and clarity

      This manuscript addresses an important gap in Wilms tumor (WT) biology: what are the earliest pathogenic events following WT driver mutation induction, and how do these early developmental trajectories differ across genotypes? The authors provide a carefully staged and comparative analysis of two WT-associated genetic contexts-conditional Wt1 loss (using lineage-specific Cre drivers targeting nephrogenic (Six2-Cre) versus stromal (Foxd1-Cre) compartments, as well as a temporally controlled Wt1CreERT2 model targeting both lineages upon tamoxifen induction) and inducible LIN28B overexpression, and relate the resulting developmental phenotypes to two CSC marker paradigms derived from patient-based studies.

      A major strength is the precise, time-resolved description of the earliest initiating phenotypes (E12.5 and E18.5, with additional postnatal analysis for LIN28B) and the direct side-by-side comparison of how each genotype perturbs nephrogenesis. The authors conclude that Wt1 loss (especially in the nephrogenic lineage) leads to a severe developmental block accompanied by a disturbance of lineage identity ("lineage confusion"), whereas LIN28B overexpression causes a disturbed transition between uninduced and induced nephron progenitor cell (NPC) states, producing blastemal-like regions that persist postnatally. Using immunostaining for NCAM1, SIX2, CITED1, and ALDH1A2, the authors map marker combinations during normal kidney development and across mutant contexts, and propose that tumor-initiating alterations, most clearly in the LIN28B model, and more suggestively in the Wt1CreERT2 (Wt1CE) context, promote the emergence of a CSC-like population inferred to co-express all four markers (NCAM1+SIX2+CITED1+ALDH1A2+), a state not observed in normal kidneys.

      Overall, this study provides a particularly clear direct comparison of the earliest tumor-initiating events triggered by distinct WT-relevant driver alterations. While the manuscript does not yet offer a detailed molecular mechanistic framework explaining why these two mutations produce such divergent developmental and marker-state outcomes (which would further strengthen the work), the careful comparison and the conclusions drawn from it are meaningful and make an important contribution to our understanding of the developmental processes that can lead to Wilms tumor initiation.

      Major comment:

      1. A central and highly emphasized conclusion of this manuscript is that tumor-initiating alterations induce a CSC-like population co-expressing all four markers (NCAM1, SIX2, CITED1, and ALDH1A2), and that this state is not observed during normal kidney development. Because this "quadruple-positive" population is a key mechanistic take-home message and closely linked to the overall conceptual model, the manuscript would be substantially strengthened by a direct, same-cell demonstration of co-expression of all four markers, rather than inference from consecutive sections. The authors state that they were unable to do so due to a technical limitation, namely, antibody host-species constraints that prevent co-detection of CITED1 and ALDH1A2 within the same section. Several feasible approaches could address this limitation for example:
        • Identify an alternative antibody reagent from a different host species.
        • RNAscope / smFISH for in situ single-cell co-detection.
        • Single-cell RNA-seq (scRNA-seq) to test whether a bona fide quadruple-positive transcriptional state exists.

      Overall, resolving this technical limitation would markedly increase confidence in one of the manuscript's most important claims and strengthen the proposed genotype-phenotype/CSC-marker framework 2. It is somewhat unexpected that the Six2-specific Wt1 deletion appears to produce a more severe phenotype than the tamoxifen-inducible Wt1CreERT2 approach, which is intended to target a broader Wt1-derived lineage (both nephrogenic and stromal). The Discussion offers several plausible, non-mutually exclusive explanations for this observation (e.g., timing, recombination efficiency/mosaicism, and the rescue contribution of "escaping" wild-type cells). It would be helpful to support at least one of these explanations experimentally. For example, the authors could quantify the extent of "escape" (percentage of non-recombined cells within the lineage) across embryos/timepoints to validate that mosaicism is indeed the cause of the milder phenotype.

      Minor comments

      1. Please clarify whether the difference shown in Fig. 2C is statistically significant, and report n, error bars/variation, the statistical test used, and p-values (if applicable).
      2. The authors note the presence of some SIX2+; tdTomato+ cells in Foxd1GC control kidneys. Given the expected stromal restriction of Foxd1 lineage labeling, please clarify the likely explanation and, if possible, indicate how frequent this is.
      3. It is somewhat unexpected that Six2-specific Wt1 deletion appears to produce a more severe phenotype than the tamoxifen-inducible Wt1CreERT2 approach, which is intended to target a broader Wt1-derived lineage. The Discussion offers several plausible, non-mutually exclusive explanations (e.g., timing and/or recombination efficiency/mosaicism and the contribution of "escaping" cells). it would be helpful to support at least one of these explanations experimentally, for example by quantifying the extent of "escape" across embryos/timepoints and tamoxifen dosing.
      4. A careful proofreading pass is needed to ensure text-figure consistency, particularly for arrow annotations. For example, the Results text refers to "Fig. 1F, arrows," but arrows are not apparent in that panel. Likewise, the Results text mentions a "white filled arrow" in Fig. 2H, whereas the figure appears to show only open arrows. Please align the wording with the annotations actually shown in the figures.

      Significance

      Overall, this study provides a particularly clear direct comparison of the earliest tumor-initiating events triggered by distinct WT-relevant driver alterations. While the manuscript does not yet offer a detailed molecular mechanistic framework explaining why these two mutations produce such divergent developmental and marker-state outcomes (which would further strengthen the work), the careful comparison and the conclusions drawn from it are meaningful and make an important contribution to our understanding of the developmental processes that can lead to Wilms tumor initiation.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      Building a functional nervous system with the correct number of correctly specified and wired pre- and post-synaptic neurons requires a tight control of proliferation and cell survival during development. Focusing on the latter, Naser Alshami and colleagues in the laboratory of Alicia Hidalgo investigated the role of three neurotrophins and their respective Toll receptors in regulating neuronal survival in the visual system of Drosophila. A combination of expression and genetic loss-of-function and gain-of-function analyses revealed a novel role for the neurotrophin DNT2 (spaetzle-5) in controlling survival, dendritic spine formation, columnar axonal innervation of lamina neuron L1 expressing the receptor Toll-2.

      Major comments:

      • DNT-2 (spz-5) is described to be expressed in non-neuronal cells in the retina. However, the clustered arrangement of cells in cross-sections of the retina during pupal development (72h DNT-2 bottom panel) suggests that photoreceptors could be labeled by the reporter as well. This should be assessed by co-labeling experiments with Elav and/or mAb24B10. This is important, as photoreceptors may represent a presynaptic additional source of this neurotrophin to lamina neurons L1 (see below).
      • The most right hand panel of Figure 2A, first row, Toll-2, does not resemble a 24h APF optic lobe, and would need to be replaced by a correctly staged younger sample. This is relevant, as the image at 48 h APF shows extensive staining in a cluster at the medulla edge, suggesting that expression in medulla neurons may be more abundant at younger stages. The expression of Toll-2 in L3 neurons is not unambiguously demonstrated at the angle shown in Figure 1E first panel. Normally, MCFO clones should be able to reveal single cells instead of L1 and L3 together.
      • Related to this part of the study, the authors describe that Toll-2 is expressed by connecting neurons (L1, Mi1, Tm3...). This is solely based on RNAseq data. In the next paragraph, the authors describe that Toll-2 is expressed in L1 and DNT-2 in Mi1 (or related) medulla neurons. However, this is rather vague, as it is not clear what "related" medulla neurons refers to. As expression in Mi1 neurons is at the heart of this study, it would be essential to verify that Mi1 is included in the Toll-2-Gal4 and DNT-2 expression pattern. Indeed, in Figure 1A (right panel, row 2, 48 h APF) expression of DNT-2 in this neuron subtype may be visible. This should be verified by markers and single cell labeling such as MCFO. Finally, the authors mention that the DNT-2 ligand could "reach" the Toll-2 receptor. Here some more precision would be helpful, as it is not clear, how far neurotrophins would need to travel, and synaptic contacts may form too late for mediating survival. Furthermore, there seems to be also the possibility that there is a substantial contribution of autocrine signaling, if L1 neurons indeed express both the ligand and the receptor, which would need to be presented more clearly.
      • The next set of experiments uses over-expression of DNT-2 and DNT-3 in Toll-8 expressing neurons and assessment of survival rates in lamina neurons. Survival is determined by evaluating Dcp-1 signals rather than cell numbers. During normal larval development, 7 future lamina neurons per column are formed, two of which are eliminated by apoptosis. Thus, it would be important to verify whether it is these neurons that are surviving, using for instance Elav labeling; moreover lamina neuron specific markers (see Xu et al., 2024) may enable assessment whether the surviving neurons adopt specific lamina neuron identities in excess to the normal 5. It may also need to be considered that both neurotrophins could affect proliferation, if the numbers do not add up (as drivers may be active already during the third instar larval stage, this is possible).
      • Gain-of-function experiments are followed by loss-of-function experiments, assessing the impact of loss of DNTs in entire animal mutants on lamina neuron survival. As for the gain-of-function studies, it would be important to know, which lamina neuron subtypes are dying in the absence of DNT-2 and DNT-3. Indeed, Figure 4C reveals a substantial loss of L1 and L3 neurons. The over-expression experiments of the ligands using the Toll-2 driver are complicating matters, considering that the driver line is described to be a mutant in Toll-2, and the ligand is expressed in the same neuron, creating an autocrine signaling situation. Moreover, since Toll-2-Gal4 is used to drive expression in all lamina neurons L1 and L3, and entire optic lobes are assessed, the numbers should be around 1600 in wild type, but are not, suggesting that there might have been some cell death in controls. If there are more lamina neurons in the over-expression situation, it would mean that additional neurons are adopting L1 and L3 identity and thus reveal an additional direct role in cell fate determination by DNT-2 and Toll-2 or an indirect role considering the intricate interactions of lamina neurons to adopt specific identities via N signaling (see Xu et al. 2024). This would need to be assessed more in detail using for instance independent drivers or markers for lamina neuron subtypes.
      • The statement, that the remaining signal is coming from macrophages would need to supported by additional markers or described more carefully (as it could be glia).
      • Page. 9. The study reports a new interaction between DNT-2 and Toll-2 as its possible receptor. This is in part based on whole animal lethality, without providing quantification. This should be added.
      • Interestingly, knock-down of Toll-2 in all neurons led to increased cell death of lamina neurons, which cannot be overcome by over-expression of DNT-2 [FL]. It would be interesting to assess whether cell death is even higher by providing a statistical test comparing the knock-down of Toll-2 with the knock-down of Toll-2 and the simultanous over-expression of DNT-2 in Figure 4B.
      • Page 11 (also page 4). The authors describe that "connectivity of lamina neurons to medulla neurons takes place at 30-48 h APF and between medulla and lobula complex at 60-70h APF, and that expression of synaptic markers starts at 24h APF". It is not clear how the authors define connectivity (here and throughout the manuscript). While axonal and dendritic projections are established during the first half of pupal development, functional synapses are thought to be solely established from mid-pupal development onwards (early expression of synaptic markers may not be indicative of synapse formation as early as 24h APF). Moreover, there is no solid evidence yet that connections form sequentially between the lamina and medulla, and medulla and lobula and lobula plate neurons. This description would need to be adjusted. A reference for the occurrence of spontaneous activity (prior to synapse formation) should be provided: Akin et al. 2019. This is important for the subsequent interpretation that cell death overlaps with "connectivity": if this term is used to refer to synapse formation, this may not hold, and need adjustment.
      • Next, the study assesses the impact of loss of Toll-2 in surviving lamina neurons L1 on columnar axonal branching. The authors observed that loss of Toll-2 or over-expression of DNT-2 leads to extension of axonal branches into neighboring columns in the medulla neuropil layer M1. Here, it would be important to assess, whether this phenotype is really due to the loss of Toll-2 or the fact that neighboring L1 neurons are missing (even just one neighbor missing may be enough to create this defect as contact-dependent repulsion may no longer work, Millard et al. 2007). Toll-2 MARCM clones would be able to address this point. Without further experiments conclusions need adjustments. Finally, the authors conclude that this is an indication for a role in connectivity, but indeed, it is not clear whether these projections lead to abnormal connections, as the thin projections may not form synapses. This statement would need to be adjusted or supported by including synaptic markers, such as Brp/or TransTango experiments.
      • The study concludes with the statement that over-expression of DNT-2 FL and knock-down of Toll-2 alters dendritic spine formation of lamina neurons L1 in the lamina, it increases by over-expression and decreases in Toll-2 knock-down. This is in contrast to the axonal projections, where additional extensions are observed in both genotypes. This should be discussed, as the opposite effects may be in line with an indirect effect through loss of neighbors in medulla columns (in contrast to the lamina).
      • The authors conclude in the discussion (page 15 and 17) that DNT-2 by medulla neurons Mi1 or related medulla neurons is key to promoting survival of lamina neurons L1, expressing the Toll-2 receptor. However, the manuscript does not provide any direct evidence that it is indeed Mi1 (or other medulla neurons) playing this role. Considering that DNT-2 may also be provided by photoreceptors (see above), this statement may need support by additional experiments, such as a Mi1 specific or photoreceptor-specific over-expression of DNT-2 in a DNT-2 whole animal mutant background and assessment of survival of labeled L1 neurons (e.g. using the markers Svp/Zfh1 (Xu et al. 2024). Moreover, it would be crucial to indeed determine the time point of when cells are undergoing apoptosis and to assess whether this would coincide with synaptogenesis. Such experiments would allow to comment on a potential retrograde signaling process between connecting neurons.
      • The data and molecular and genetic methods are presented in detail in the Material and Method sections, as well as through pertinent supplementary tables. Similarly, the statistical analyses and sample numbers are indicated in the Material and Methods section and related supplementary tables. Table S4 does not indicate genotypes, but short versions of crosses, which should be corrected. Moreover, the list of fly lines seems to miss one line (UAS-mCherry). Concerning the antibody list, sources are not provided (unlike stated in the main text). In the Result section, differences are described simply as statistically significant decreases and increases, however, at times it would be useful to add some indication about the level of differences (percentage or fold times).

      Minor comments:

      • The figures are informative, however, their orientations are not as indicated horizontal or lateral, but often oblique and not consistent (e.g. Fig 1a, last four panels). This makes comparisons more difficult. The authors could possibly find more suitable optical sections and present images more consistently.
      • Please provide the correct reference describing the occurrence of spontaneous activity (Akin et al. 2019).
      • The manuscript would be more easily accessible to non-experts, if schematic drawings would be provided (neuron subtypes, model).
      • The final paragraph of the discussion about DNT-2 keeping connecting neurons together is not easily understandable, as the term "keeping together" remains undefined.

      Significance

      As in the vertebrate nervous system, insect nervous systems rely on neurotrophins to control the survival and correct wiring of neurons. This study proposes a model, that advances our understanding as to how a specific neurotrophin, delivered by a post-synaptic neuron, acting via a specific receptor, controls several developmental steps of one of its pre-synaptic partners. The study assessed the expression patterns of three neurotrophins and the Toll receptor family, using the T2A-Gal4 expression system, revealing their dynamic expression in photoreceptors, specific lamina and medulla neurons, as well as tracheae and glia during pupal development. A strength of the study represents the identification of DNT-2 and Toll-2 as interacting partners, which could be assessed by the extensive set of specifically generated reagents for this study (Gal4 drivers and mutants). However, a number of statements may require additional experiments to conclusively support the proposed model, in particular the action of DNT-2 and Toll-2 in Mi1 and L1, respectively. Moreover, it would be important to critically assess the timing of events of cell death, setting up of projection patterns and synapse formation.

      Audience: The outlined findings, if strengthened further, will be of interest for scientists studying nervous system development in vertebrates and invertebrates in general, and the action of neurotrophins in particular.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      The authors investigate the role of neurotrophins in development of the Drosophila visual system, where multiple waves of cell death eliminate populations of neurons. Using transgenic reporter lines, the authors examine expression of four spz genes, which encode ligands and four Toll receptor genes in the optic lobe. The authors argue that two of these ligands, spz-3/DNT-3 and spz-5/DNT-2, are expressed in the optic lobe concurrently with a wave of cell death. Through gain- and loss of function studies they argue that DNT-3 promotes survival through Toll-8 whilst DNT-2 promotes survival through novel interactions with Toll-2 (with a focus on the lamina neurons). Finally, the authors argue that DNT-2 and Toll-2 regulate L1 neuron targeting and size.

      The involvement of neurotrophins in neuronal apoptosis has not been explored in detail in the visual system, making this a potentially interesting topic. However, there are several issues with the manuscript: The primary concern is that most of the authors' conclusions are not supported by the data presented. Many of the figures are difficult to interpret without the addition of appropriate markers. In addition, there are several inconsistencies both within the manuscript and within the context of existing literature that are not addressed. For example, the authors have not demonstrated that lamina neurons undergo apoptosis. This point is critical, as apoptosis, particularly that likely to be affected by neurotrophic factors, fine-tunes multicolumnar neuron numbers after they establish connections with their partners. On the other hand, unicolumnar neurons such as those in the lamina are not thought to need much fine-tuning because of their unicolumnar status. This distinction is not addressed in the manuscript. At present, the evidence presented does not convincingly support the authors' conclusions, and substantial further work is needed before the claims can be firmly established. Overall, these limit the credibility and significance of this study.

      Major comments:

      In general, the conclusions drawn about neuropil regions and specific cell identities are not supported by sufficient evidence. Across the figures, the identity of neurons and neuropils remains unclear due to the absence of subtype-specific markers or neuropil labelling that would place the data in the anatomical context of the optic lobe.

      (1) The authors claim that spz and Toll genes are differentially expressed in the optic lobe throughout pupal development. However, the data presented do not convincingly support this conclusion. The primary concern is that the Gal4 reporter insertions used to infer gene expression do not match published single-cell transcriptomic datasets (as noted by the authors). This discrepancy calls into question the accuracy of these reporters (or the transcriptomics) and raises uncertainty about which dataset can be trusted. Given that these data are inconsistent, gene expression should be assessed directly by HCR to draw reliable conclusions.

      Related comments: The authors claim that spz and Toll genes are expressed differentially in the optic lobe throughout pupal development. However, the characterisation of these expression patterns is lacking in the following aspects: - Time courses are inconsistent and incomplete across the different genes. - The conclusion that DNT-2/3 are expressed concurrently with cell death lacks evidence is not supported: DNT2/3 expression does not appear restricted to a clear time window and without co-staining for apoptotic markers this conclusion cannot be substantiated. - There is insufficient evidence to support the claim that spz-2 is specifically expressed in Mi1 neurons or that Toll-8 is specific to L4/L2. These claims are largely based on the transcriptomics data, which were inconsistent with the reporters in many other contexts. There are no neuron type markers costained to validate this claim. - Sample sizes are too low for some reporter lines (~2-4).

      (2) The authors quantified cell death using Dcp-1 signal volume and concluded that overexpression of DNT-2 or DNT-3 reduces cell death, while loss of either increases cell death in the lamina. However, the lamina is not labelled with an appropriate marker, nor are neuropils labelled to make the structure recognisable making it unclear whether this wave of cell death is truly occurring in the lamina. This is a recurring issue throughout the manuscript. Related comments: the reported values for Dcp-1 signal volume differ dramatically between the Gal4 (~40,000) and mutant (~2,000) controls, without an explanation for this discrepancy.

      (3) The claim that DNT-2 and DNT-3 promote survival via Toll-2 and Toll-8, respectively, is not sufficiently supported. The authors do not show that manipulation of each ligand specifically affects neurons expressing the relevant receptor. To substantiate this conclusion, the specificity of ligand manipulation should be tested. For example, through compensation experiments or by demonstrating that DNT-2 loss of function specifically induces cell death in Toll-2+ neurons.

      (4) The authors further investigate a potential interaction between DNT-2 and Toll-2, concluding that DNT-2 promotes survival in the lamina, medulla, and lobula complex through Toll-2. However, no evidence is presented showing altered levels of apoptosis in the medulla or lobula/lobula plate following DNT-2 manipulation. The conclusion that DNT-2 promotes survival via Toll-2 is based on a Toll-2RNAi;DNT-2FL epistasis experiment, but this interpretation does not account for the reduced expression of each construct due to Gal4 titration. This issue also applies to subsequent experiments (Figs. 5 and 6). A Gal4 titration control is required for each of these experiments to exclude this confound.

      (5) The authors conclude that DNT-2 production in Mi1 medulla neurons is required for L1 connectivity, survival, and morphology. However, these conclusions are based on manipulating DNT-2 and Toll-2 expression in L1 neurons, which does not directly test the requirement for DNT-2 in Mi1 neurons. In addition, the image quality in Figure 5 is problematic: brightness and contrast differ visibly between panels, making them challenging to interpret. Finally, the discussion states that "loss of function for DNT-3 (spz-3) causes lamina cell death that is not naturally compensated for by DNT-2," but no evidence is presented in this manuscript to support that conclusion.

      Other general comments:

      • Lack of labels for each individual image makes figures and text difficult to interpret/reference.
      • Gene names not italicised in figures
      • Inconsistent aspect ratio for graph axes (Obvious in figure 5C,D)
      • Image borders often not completely vertical/horizontal making them appear jagged in some figures e.g. Figure1A.
      • General typos e.g. (n=10 10 brains), inhibitor pf apoptosis p35
      • Lobula complex should not be used to refer to lobula plate and lobula plug at this stage as they are distinct neuropils

      Figure 1:

      • Arrows not explained
      • N-Cadherin absent from some images without explanation
      • First two images of 1B are identical.
      • Images in panel B at different timepoints and spz-4 is missing without explanation.

      Figure 3:

      • Dark spot in DNT-3FL 3A image.
      • Descriptions in text often lack specific details "Dcp1+ apoptosis in the lamina and outside the lamina too." Supplementary:
      • Figures S2-S6 lack labels denoting the timepoint of each figure
      • Figure S7 is illegible
      • Supplementary figure 8 is referred to as S9 in text and is missing genotype information as well as neuropil labels on images

      Significance

      Significance: This is an interesting topic of investigation, and the findings-if substantiated-would be of interest to the field of Drosophila visual system development and programmed cell death. In particular, it would be valuable to place these results in the broader context of programmed cell death as a mechanism for eliminating excess multicolumnar neurons during visual system development. However, at present the evidence presented does not convincingly support the authors' conclusions, and substantial further work is needed before the claims can be firmly established.

      Expertise:

      Drosophila neurogenesis, neuron specification, cell signalling

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      Alshamsi et al. investigate the role of Drosophila neurotrophins (DNTs) and their Toll receptors in regulating neuronal apoptosis during optic lobe development.

      The authors provide compelling evidence that different DNTs and their Toll receptors are expressed in optic lobe neurons, and their activity regulates neuronal survival during optic lobe development. They further show that disruption of DNT/Toll signaling impacts neuronal morphologies.

      Comments

      ABSTRACT

      "Over-expression of DNT-3 (spz-3) and DNT-2 (spz-5) could rescue natural occurring cell death, whereas their loss of function caused cell death, showing that DNT-3 and DNT-2 can, and are required to, promote cell survival during optic lobe development."

      I find it more appropriate to say that OE prevents naturally occurring cell death because it inhibits a normal physiological process."rescue" would only be correct if there were an experimental or genetic loss (e.g., deletion of a survival factor) and you are restoring normal survival levels

      "Importantly, DNT-2 is expressed in Mi1 neurons and Toll-2 in connecting L1 neurons. We show that DNT-2 functions in concert with Toll-2, as Toll-2 RNAi knock-down prevented the rescue of apoptosis by DNT-2 over-expression and all Toll-2+ neurons were lost in DNT-2 mutants."

      I find this sentence very difficult to follow

      i suggest moving "Importantly, DNT-2 is expressed in Mi1 neurons and Toll-2 in connecting L1 neurons."

      to the next sentence. "by specifically investigating the Mi1 (DNT-2+) and L1 (Toll-2) synaptic partners", alterations in DNT-2 or Toll-2 expression levels impaired connectivity of L1 neurons at the M1 medulla layer and altered dendritic morphology of L1 neurons

      "As DNT-3 (spz-3) and DNT-2 (spz-5) are expressed in the medulla and they could influence both lamina and medulla neurons, this suggests that their function maintaining cell survival could enable the stabilisation or alignment of connected neurons across medulla columns."

      influence what? this is very vague and needs a temporal understanding of when neurons die, synapses are formed, and consider the phenotypes of the mutants and RNAi experiments.

      INTRODUCTION

      "Neuronal survival is maintained by neurotrophic factors secreted in limited amounts by target cells, leading to the survival of only those neurons that receive trophic support (Levi-Montalcini, 1987, Davies, 2003)."

      Perhaps the authors can be more precise, e.g. One mechanism by which Neuronal survival is regulated is through neurotrophic factors secreted in limited amounts by to be synaptic partners and adjacent cells

      "In this context, if neurotrophism is fundamental for nervous system development, it could have been enabled by evolutionarily conserved molecular mechanisms."

      I think the authors want to suggest that given the fundamental and widespread role of neurotrophism in nervous system development, it remains unknown if it relies on evolutionarily conserved molecular players.

      "Neurotrophins - NGF, BDNF, NT3, NT4 - are the main growth factors maintaining neuronal survival in the vertebrate nervous system (Levi-Montalcini, 1987, Lu et al., 2005). Importantly, they can also promote cell death, depending on context (Lu et al., 2005). They can promote cell survival via their Trk receptors and ERK and AKT downstream and via p75NTR and NFB downstream, or cell death via p75NTR, Sortilin, and JNK signalling instead (Lu et al., 2005). mechanisms."

      The authors should avoid the repeated use of "they"

      "There are six spz and nine Toll paralogous genes in Drosophila, which could play distinct functions. In fact, at least full-length DNT-1 and Toll-1 can promote cell death instead, and at least Toll-6 can promote either cell survival or cell death, depending on context (Foldi et al., 2017, Singh et al., 2025, Zhu et al., 2008) . Importantly, mature DNT-1 and DNT-2 with Toll-6 and Toll-7 are required for and can promote neuronal survival during circuit formation in the embryonic ventral nerve cord (McIlroy et al., 2013, Zhu et al., 2008)."

      I find this paragraph difficult to follow. I suggest the following editing, which the authors might want to consider:

      "There are six spz and nine Toll paralogous genes in Drosophila, which could play distinct functions. In fact, at least full-length DNT-1 and Toll-1 can promote cell death instead, while and at least Toll-6 can promote either cell survival or cell death, depending on context (Foldi et al., 2017, Singh et al., 2025, Zhu et al., 2008) . Importantly, mature DNT-1 and DNT-2 with Toll-6 and Toll-7 are required necessary and sufficient to promote for and can promote neuronal survival during circuit formation in the embryonic ventral nerve cord (McIlroy et al., 2013, Zhu et al., 2008).

      "During this time (24-50h APF), connectivity between photoreceptors, lamina and medulla neurons is established; this is followed by medulla neurons connecting to lobula neurons;"

      I find this sentence misleading, if not incorrect. If by connectivity the authors mean synaptogenesis, for all that is known, synaptogenesis has been shown to occur from from mid-pupal development (P50) onwards If by connectivity, the authors mean the targeting of specific neuropiles and layer organization, it is also incorrect that lamina and medulla organization precedes the connectivity between medulla and lobula neurons. These processes are all concurrent. Can the authors please clarify?

      "and by 72h APF cell death has greatly diminished and synaptogenesis completes connectivity patterns, in preparation for adult eclosion at 96h APF (Millard and Pecot, 2018, Melnattur and Lee, 2011, Hadjieconomou et al., 2011, Kurmangaliyev et al., 2020) "

      Kurmangaliyev et al., 2020 is probably not an appropriate citation here as it mostly deals with transcriptional programs of circuit assembly in the developing optic lobe

      "Thus, 24-48h APF is a critical period to maintain necessary lamina and medulla neurons alive in the optic lobe."

      Perhaps the authors want to revisit this sentence and explicitly say that 24-48h APF is a period where apoptosis defines cell numbers

      "The development of the Drosophila visual system has been well described (Holguera and Desplan, 2018, Melnattur and Lee, 2011, Millard and Pecot, 2018, Hadjieconomou et al., 2011, Behnia and Desplan, 2015)."

      I find that Behnia and Desplan, 2015 is not appropriate, as it is a review that describes the characterization of neuronal circuits underlying visual modalities in the fly brain, and not their development. The following reviews dealing with different aspects of neurogenesis, neuropile development and circuit formation are likely more relevant: Bakshi et al Current Opinion in Neurobiology 2025 Malin et al PNAS 2021 Ngo Dev Bio 2017

      "R7 and R8, together with lamina neurons target to medulla layers M6 and M3, respectively, organizing into medullar columns that respond to the same point in visual space and maintain retinotopy."

      I find this sentence misleading because lamina neurons do not target M6 and only L3 targets M3.

      "Medullar interneurons also form connections across multiple layers, where each layer represents different visual features (Fischbach and Hiesinger, 2008, Millard and Pecot, 2018)."

      Here, Behnia and Desplan, 2015, Matsliah et al Nature 2024, Borst and Groschner , Annu. Rev. Neurosci. 2023, and even Schnaitmann et al J Comp Physiol A Neuroethol Sens Neural Behav Physiol 2020 are better references that review feature detection and circuit organization in the optic lobe.

      "Neurons within the lobula complex integrate signals from the medulla and project to the optic glomeruli in the central brain and motor outputs to enable appropriate behavior (Behnia and Desplan, 2015, Borst et al., 2020, Courgeon and Desplan, 2019b)."

      I find Courgeon and Desplan, 2019b is not very appropriate here, as it reviews the coordination of neural patterning in the Drosophila visual system. More adequate and relevant manuscripts and reviews are Wu et al. elife 2016, Tanaka and Clark, 2022, Lapoetke et al. Neuron 2022 , even Zhao et al. elife 2024

      "Spz-5 is well known as Drosophila neurotrophin-2 (DNT-2), and as Spz-3 has been proposed to have neurotrophin functions which we expand on and demonstrate here, we refer to Spz-3 as DNT-3 (Zhu et al., 2008, Coutinho-Budd et al., 2017, Sun et al., 2024, Ballard et al., 2014, Ulian-Benitez et al., 2017)."

      This last paragraph of the introduction seems out of place, and partly redundant with page 3. Perhaps the authors would like to finish the introduction with a paragraph highlighting the major findings and conceptual advance of the manuscript? This seems to be a good and natural way of following their previous sentence "Here, we asked whether neurotrophin family ligands encoded by DNTs (spzs) and their Toll receptors could regulate cell survival during neural circuit formation, in the Drosophila pupal optic lobe."

      RESULTS

      I suggest the following edit: To ask whether DNTs (spzs) are expressed in the pupal optic lobe, we generated T2A-Gal4 driver lines for spz-1,3,4,5 fly lines , crossed them to 10xUASmyrGFP or 20UAS6xmCherry reporter flies, and analysed resulting progeny optic lobes during development and in the adult with anti-GFP antibodies, as required (Figure 1A).

      Also, If the lines were also crossed with mcherry, mentioning anti-GFP antibodies is incomplete.

      "spz-1MIO2318-T2A>myrGFP and spz-1MIO2318-T2A>6xmCherry revealed expression in a few centrifugal neurons in the lobula complex that projected to the lamina,"

      At which stage?

      "subsequently medulla neurons and abundant arborisations into the lobula complex and medulla."

      Subsequent to what? I am sorry, but I don't understand this description.

      "Expression from spz4MI5678 -T2A->myrGFP was not detected until 72h APF" Data before 72h APF is missing Where was it expressed? Which cell types? Which neuropiles?

      "And then was found in the medulla and lobula complex and followed by the trachea." At which stage? What was followed by the trachea? I think the authors mean that at later staged (in the adult) expression was restricted to the trachea in both medulla and lobula

      "spz-3-T2A>6xmCherry (hereby named DNT-3) was highly expressed in non-neuronal retinal cells and medulla neurons;"

      At what stage?

      "And subsequently in the trachea and possibly glia."

      The authors could and should explain how they reach this conclusion. Given that no cell type specific markers were used, this identification was likely based on morphological features.

      "Finally, DNT-2-T2A>6xmCherry (spz-5) was found in medulla neurons, which could be tentatively identified as Mi1 medulla neurons (Nern et al., 2025) by 48h APF, and this pattern was maintained."

      The authors suggest these neurons are Mi1 based on what? Also, Fischbach's Cell Tissue Res (1989) seminal paper is probably worth mentioning.

      "Abundant cells expressed spz-1 in the lobula complex (Figure 1B, left) and medulla (Figure 1B, right), and DNT-3 (spz-3) and DNT-2 (spz-5) in the medulla (Figure 1B) during optic lobe development. DNT-3 (spz-3) and DNT-2 (spz-5) were expressed in distinct non-neuronal cells in the retina, seen in Multi Colour Flip Out (MCFO) clones (Figure 1C)."

      This sentence is misleading. These experiments allow the authors to conclude that spz+ neurons innervate these neuropiles. It does not allow the authors to conclude that spz molecules localize to the neuropiles. The authors should revise these claims in the main text and relevant figure legends

      "To visualize the distribution of Tolls in the optic lobes during pupal development, we used the GAL4 lines previously described (Li et al., 2020), driving expression of the reporter myrGFP (Figure 2A)."

      Same comment as above

      "Using MCFO clones as well as myrGFP, we could identify some of the Toll-8+ neurons as Lawf1, feedback neurons projecting from the medulla to the lamina (Figure 2B), and L2 and L4 lamina neurons (Figure 2B, C); Toll-6+ cells to include L3 and L4 lamina neurons (Figure 2B,D); and Toll-2+ neurons as L1 lamina neurons which target to M1 and M5 medulla layers and L3 lamina neurons that project to M3 (Figure 3B,E) (Hakeda-Suzuki and Suzuki, 2014, Behnia et al., 2014)."

      Hakeda-Suzuki and Suzuki, 2014, Behnia et al., 2014 are not the most appropriate references. Instead, I suggest the authors should cite Fischbach's Cell Tissue Res (1989).

      "Overall, the expression in the scRNAseq dataset (Kurmangaliyev et al., 2020) of the spz ligands and Toll-8 (also known as Tollo) data were less consistent with the cell biology data, whereas the expression of Toll-1, -2 and -6 confirmed cells seen with the cell-biology based reporters"

      It is perhaps more accurate to refer to the cell-biology based reporters as translation reporters, which is what T2a based Gal4 drivers are.

      "Most particularly, Toll-2 mRNA (synonym 18w) was found in L1 and L3 lamina neurons over time, plus also in L5 at 24h APF, and Toll-6 mRNA was found in L2, L3, L4 over time, plus also in L1 at 24h (Supplementary Figure 1-6)."

      This sentence is difficult to read and could be considered poorly written for several reasons including: - "plus also" is repetitive. "Plus" and "also" serve the same function. - Inconsistent punctuation. The lack of commas before "and Toll-6 mRNA..." makes the sentence feel unbalanced. -Vague time reference. "Over time" is imprecise. It's unclear whether it means during development, at multiple timepoints, or something else. Also regarding scRNAseq analysis: - the authors mention "We compared our reporter-based profiles with published scRNAseq datasets of the optic lobe through development (Kurmangaliyev et al., 2020, Ozel et al., 2021)" however the Ozel dataset doesn't seem to be used.

      Also, from the Material and Methods section:

      "The data were imported as a Seurat object, and cells corresponding to specific timepoints (e.g., 24 h, 36 h) were subsetted based on the provided metadata. Dimensionality reduction was carried out using principal component analysis (PCA), followed by Uniform Manifold Approximation and Projection (UMAP) embedding computed on the first 30 principal components. Cluster annotations provided by the original authors were used for all cluster-level analyses and visualisations."

      The Kurmangaliyev dataset is already processed. I am probably missing something here, but is not obvious to me why the authors performed PCA again

      "To conclude, at the time of naturally occurring cell death (0-48h APF), Toll-1 is highly expressed throughout the optic lobe; Toll-2, -6 and -8 are expressed in the medulla; Toll-8 and Toll-6 are prominently expressed in the lobula complex, and Toll-6 and Toll-2 are prominent in the lamina."

      This is misleading. These experiments allow the authors to conclude that toll+ neurons innervate these neuropiles. It does not allow us to conclude that toll molecules localize to the neuropiles. The authors should revise these claims in the main text and relevant figure legends

      "To ask whether DNTs can promote cell survival in developing optic lobes, we over-expressed DNT-2 (spz-5) and DNT-3 (spz-3) and visualized dying cells with the apoptotic marker anti-Dcp1 at the peak of naturally occurring cell death (24h APF)."

      These experiments were done using Toll8-Gal4 and nsyb-Gal4 drivers. What's nsyb-Gal4 expression during development? Is the expression of this driver consistent with the conclusions drawn from these experiments?

      "To test whether DNT-2 could promote cell survival during optic lobe development, we over-expressed full-length DNT-2FL or cleaved DNT-2CK in all neurons with nsybGAL4. This reduced the incidence of Dcp1+ apoptosis in the lamina and outside the lamina too (Figure 3C-D and Supplementary Figure S9C,D)."

      How do the authors explain that DNT-2CK reduced the number of Dcp1+ cells?

      "We generated DNT-3 (spz-3) loss of function mutants by P-element mobilization. DNT-2 and DNT-3 loss of function mutants caused considerable cell debris in the medulla and lobula complex, which compromised the analysis in this region, so we focused on the lamina."

      Perhaps, rather than stating that the mutants caused considerable cell debris, the authors could say that the mutants displayed considerable cell debris

      More importantly, I have concerns with the data from these experiments (Figure 3). Dcp1 signal volume intensity using Imaris. In all panels (A,C,E) the segmented images do not match the raw DCP1 staining, raising concerns on how much can one rely on this quantification. Could this be because the Dcp1 staining shown is a single z plane and the segmentation is a 3d rendering? The authors should carefully and robustly explain this discrepancy which is present in all images where Dcp1 signal volume intensity was quantified.

      Also, could the authors explain why the quantifications in Figure 3B and 3C differ by an order of magnitude (10×) from those in panel 3D? Please look at the WT control, there is a 10X difference in signal volume intensity.

      "Toll-2pTVGAL4 flies are heterozygous mutant for Toll-2, and, remarkably, in combination with DNT-2 homozygous mutants resulted in semi-lethality, revealing a functional interaction between these two genes.

      I cannot entirely follow this conclusion. I understand the authors propose that the combination of partial loss of Toll-2 and full loss of DNT-2 affects viability, more than either mutation alone. Is this what they mean? Can the authors comment on the viability of DNT-2 mutants?

      "Macrophages loaded with HisYFP and distributed mostly between the retina and lamina could be observed across these samples (Figure 4C), suggesting they had engulfed dead cells" How do the authors identify these YFP+ cells as macrophages?

      "Together, these data show that DNT-2 functions as a ligand for Toll-2 to maintain the survival of neurons in the lamina, medulla and lobula complex during optic lobe development." While the results from Figure 4 showing that DNT-2 acts as a ligand for Toll-2 to support neuron survival are solid ( in particular panels C-F), it doesn't necessarily mean all neurons die directly due to loss of Toll-2 signaling. It is plausible that Neurons that express Toll-2 die because they lose critical survival signals. The death of these Toll-2-expressing neurons could then cause a cascade effect, where neighboring or connected neurons die indirectly due to loss of trophic support, disrupted circuits, or secondary damage. So, the observed cell death in multiple regions may be a combination of direct effects on Toll-2-positive neurons and indirect effects on other neurons. "In the Drosophila pupa, connectivity of lamina to medulla neurons takes place at 30-48h APF, and between medulla and lobula complex at 60-70h APF (Kurmangaliyev et al., 2020, Millard and Pecot, 2018, Pecot et al., 2014, Hadjieconomou et al., 2011)." I have the same comment as mentioned above regarding the timing of connectivity. If by connectivity, the authors mean the targeting of specific neuropiles and layer organization, it is incorrect that lamina and medulla organization precedes the connectivity between medulla and lobula neurons. These processes happen concurrently. Can the authors please clarify?

      "Importantly, the expression of synaptic markers starts at 24h, peaks at 60h APF and spontaneous neuronal activity takes place at 48h APF, meaning that at least some neural circuits are already connected by this point (Kurmangaliyev et al., 2020)."

      The correct placement of the reference to Kurmangaliyev et al. is after "peaks at 60h APF " A reference to Akin et al and Bajar et al when referring to PSINA is missing.

      "Thus, the period of naturally occurring cell death overlaps with connectivity" I think the authors mean that the period of cell death is concurrent with the development of synaptic connectivity.

      "L1 neurons normally project along columns that can be labelled with mAb24B10, and target to layers M1 and M5 of the medulla." The authors should mention that 24b10 labels the photoreceptors, providing a spatial reference to identify medulla columns

      "Interestingly, Toll-2RNAi knock-down did not alter the phenotype caused by DNT- 112FL overexpression, and impaired targeting to the same extent as each genetic manipulation alone (Figures 5B,D)."

      How do the authors interpret these results? And perhaps the authors would like to explain the rationale of overexpressing DNT-2fl in L1 neurons, that do endogenously express it.

      "To conclude, these data show that DNT-2 and Toll-2 are required for appropriate connectivity of L1 neurons to target Mi1 medulla neurons at M1 medulla layer."

      The authors characterize neuronal morphologies but do not directly assess connectivity using synaptic markers. While defective morphologies are likely to impact connectivity, the conclusion that DNT-2 and Toll-2 are required for appropriate connectivity should be tempered. The authors should revise their wording to reflect that their data support morphological defects rather than direct evidence of altered synaptic connectivity.

      DISCUSSION

      "In fact, throughout animal development, between 50% (e.g. in Drosophila) and 80% (e.g. in vertebrates) are lost to naturally occurring cell death"

      "of neurons" is missing before "are lost"

      "Consistently with these findings, we have shown that the survival of L1 neurons depends on DNT-2 functioning together with Toll-2."

      The authors state that "the survival of L1 neurons depends on DNT-2 functioning together with Toll-2." It seems that what they intend to convey is that DNT-2 acts as a ligand for Toll-2. The text should be clarified to explicitly indicate this ligand-receptor relationship rather than implying a cooperative function.

      "These data demonstrate that DNT-2 and Toll-2 function together in visual system development."

      Since the authors did not use tub-GAL80 or another temporal control to restrict gene expression specifically to development, the observed phenotypes could reflect combined developmental and adult effects. Throughout the text, the authors should revise their wording to acknowledge this limitation.

      "Finally, interference with the normal levels of DNT-2 and Toll-2 also impaired axon targeting and dendritic morphology, consistently with the coupling between cell survival with connectivity."

      The authors state that interference with normal levels of DNT-2 and Toll-2 "impaired axon targeting and dendritic morphology, consistently with the coupling between cell survival and connectivity." This statement seems tautological, as neurons that die cannot form connections. The authors should clarify whether they are referring to a specific mechanistic link beyond this obvious consequence.

      "Our findings are consistent with prior reports that had shown the maintenance of cell survival to be required during neural circuit formation."

      This statement seems tautological. It is generally expected that neurons must survive in order to contribute or be part of neural circuits. The authors should clarify if they are highlighting a specific mechanistic insight beyond this obvious requirement.

      "In the medulla, Dm8 medulla neurons are produced in excess and are eliminated during connectivity to their R7 inputs (Courgeon and Desplan, 2019a). This is enabled by the cell surface molecular tags DIP in yDm8 binding Dpr11 in yR7, during synaptic matching (Courgeon and Desplan, 2019a)."

      The statement that "Dm8 medulla neurons are produced in excess and are eliminated during connectivity to their R7 inputs" is both unclear and inaccurate. It is not evident what is meant by "during connectivity." Moreover, Courgeon and Desplan (2019a) show that Dm8 neurons undergo cell death before or by P40, prior to synaptogenesis. The authors should correct this statement and clarify the timing and mechanism of Dm8 neuron elimination.

      "Importantly, the maintenance of cell survival takes place during connectivity, and enables synaptic matching between connecting neurons."

      It is unclear what is meant by "during connectivity." Moreover, both Courgeon et al. (2019a) and Xu et al. (2018, 2022) show that these neurons (e.g., Dm8, Dm12, Dm14) undergo cell death before or by P40, prior to synaptogenesis. The authors should clarify the timing and mechanism of cell survival and revise this statement accordingly.

      "By contrast, it has also been proposed that apoptosis plays a minor role in cell number control during visual system development, depending instead on cell proliferation and spatial patterning through Dpp/BMP signalling (Malin et al., 2024). However, those findings were based on events taking place at the larval third instar wandering stage, when proliferation and spatial patterning are prevalent, whereas apoptosis peaks in pupa."

      It seems that the authors are trying to suggest that different mechanisms control cell numbers at different developmental stages: during larval neurogenesis (L3), cell numbers are regulated primarily by proliferation and spatial patterning, whereas in the pupal stage, neuronal survival via apoptosis plays a key role. If this is the intended point, it should be stated more clearly, as the current comparison to Malin et al. (2024) is confusing and does not make this distinction explicit.

      "However, Toll-2 mutant MARCM clones generated in the pupa result in a dramatic loss of lamina neuron dendrites and aberrant axonal navigation in the medulla, as well as widespread neuronal loss (Li et al., 2020)." This statement is puzzling. Neurogenesis occurs during the larval stage until P15, and MARCM requires progenitor cell division. The authors should clarify how MARCM clones were generated during pupation and provide the relevant experimental details in the Materials and Methods. "Importantly, connectivity between L1 and medulla neurons takes place between 20-48h APF, during the period of naturally occurring cell death, and spontaneous activity in the optic lobe takes place at 48h, meaning at least some circuits are connected by then (Kurmangaliyev et al., 2020)."

      The authors state that "connectivity between L1 and medulla neurons takes place between 20-48h APF," but no reference is provided for this timing. To my knowledge, no study has directly demonstrated this, so the authors should either provide supporting evidence or revise this statement. Additionally, citing Kurmangaliyev et al. (2020) for spontaneous activity in the optic lobe is not appropriate for this point, as PSINA was originally described by Orkun Akin.

      "When altering DNT-2 or Toll-2 levels, L1 axonal terminals in the medulla were misrouted, rather than being confined to a single column. This is reminiscent of the phenotypes caused by alterations in Dscam and Fez levels (Millard et al., 2007, Peng et al., 2018)."

      The authors note that altering DNT-2 or Toll-2 levels causes L1 axonal terminal phenotypes reminiscent of phenotypes caused by changes in Dscam and Fez levels (Millard et al., 2007; Peng et al., 2018). However, they only reference these previous studies without discussing whether there could be a shared mechanism. While these comparisons are interesting, the manuscript would benefit from either a deeper discussion of potential mechanistic links or a clear statement that the comparison is purely phenotypic.

      "As DNT-2 is secreted in medulla neurons and Toll-2 is expressed along neurons that connect in the medulla (e.g. L1, Mi1, Tm3, Dm9, T4), DNT-2 could help keep connecting neurons together during dynamic cellular events in development."

      This sentence is poorly written and vague. It is unclear what "keep connecting neurons together" means mechanistically. Likely, DNT-2 is secreted by postsynaptic medulla neurons (e.g., Mi1), whereas Toll-2 is expressed in neurons innervating the medulla (e.g., L1, Mi1, Tm3, Dm9, T4). The authors should rephrase this sentence to clearly convey their mechanistic and cellular interpretation.

      FIGURES

      Figure 1 Arrowheads point to what? OL orientations should be described in the figure captions

      Figure 5 The title of Figure 5 ("Altering the levels of DNT-2 and Toll-2 modifies L1 axon targeting at medulla M1 layer") is misleading. The correct layer targeting is preserved; what changes is the pattern of unicolumnar innervation. When DNT-2 or Toll-2 levels are altered, L1 neurons innervate multiple columns rather than maintaining their normal single-column specificity. The title should be revised to reflect that the defect is in columnar specificity rather than layer targeting.

      Supplementary Figures S1 to S6 Combined UMAPs showing the expression of spz-1, -3 (DNT-3),-4 and -5 (DNT-2) and Toll-1, -2 (18w), -6 and -8 (Tollo) in distinct cells over time.

      Information about which UMAP corresponds to which time point is missing

      MATERIALS AND METHODS Genetics. Please see S1 Table for the list of the stocks used and Table S3 for full genotypes for each experiment. Table S3 is not the full genotypes for each experiment. This information is partly available in the Source Data excel file

      Significance

      During development, neurons are initially produced in excess. One mechanism by which the final neuronal numbers are refined relies on trophic support, which maintains the survival of necessary neurons, while excess neurons are eliminated.

      In the Drosophila optic lobe, a wave of apoptosis occurs during pupation, peaking at a critical period thought to be essential for establishing final neuronal numbers and supporting proper neural circuit formation. However, the mechanisms underlying this developmental process remain poorly understood. In this manuscript, Alshamsi et al. investigate this wave of apoptosis by examining the role of Drosophila neurotrophins (DNTs), which are encoded by spätzle (spz) paralogous genes and signal through Toll receptors to regulate neuronal survival during brain development.

      The authors use translation reporters to demonstrate that DNTs and Toll receptors are differentially expressed across various neuronal types innervating all optic lobe neuropils during development. They then focus on DNT-3 and DNT-2, which they show to be necessary for controlling neuronal numbers, likely by maintaining neuronal survival during pupal stages.

      Notably, the results reveal a previously uncharacterized interaction between DNT-2 and Toll-2. The findings suggest that DNT-2 acts as a neurotrophic factor produced by medulla intrinsic neurons, binding to the Toll-2 receptor expressed in other neurons innervating the medulla. By examining Toll-2+ L1 neurons, which are postsynaptic in the lamina and presynaptic in the medulla, the authors provide compelling evidence that DNT-2/Toll-2 signaling regulates L1 neuronal numbers.

      Interestingly, the authors also show that disruption of DNT-2/Toll-2 signaling affects L1 axonal and dendritic morphologies. However, the extent to which changes in neuronal survival and neuronal morphology are mechanistically or cellularly linked is not addressed. These findings are consistent with previous reports showing that DNTs and Toll receptors regulate neuronal survival in embryonic, larval, and pupal ventral nerve cords, as well as in the adult. Importantly, DNTs and Tolls can also promote cell death, highlighting their dual role in controlling neuronal number and circuit formation.

      While the data is for the most part solid, I have concerns regarding the execution, interpretation of certain results and the conclusions drawn. Additionally, references to previous work are often incorrect or incomplete; I provide several examples below along with non-exhaustive suggestions for improvement. Finally, the manuscript would benefit from careful text revision and improvements to figure presentation, for which I also offer non-exhaustive guidelines.

      Overall, I would recommend this manuscript undergo revision before its publication and I would be happy to reassess a revised version that addresses the comments above.

  4. May 2026
    1. Note: This response was posted by the corresponding author to Review Commons. The content has not been altered except for formatting.

      Learn more at Review Commons


      Reply to the reviewers

      Manuscript number: RC-2023-01861

      Corresponding author(s): Manuela, Baccarini

      1. General Statements

      We were happy to learn that all three reviewers found the paper novel and of interest for a cell biology audience. They especially highlighted the carefully conducted screen, whose results will be integrally published with this paper and will be of use for scientists interested in lysosome biology. The revised manuscript contains key validation experiments (antibody/KO controls, lysosome positioning quantification, live-cell actin dynamics) to strengthen our central conclusions.

      2. Point-by-point description of the revisions

      This section is mandatory. Please insert a point-by-point reply describing the revisions that were already carried out and included in the transferred manuscript.

      Reviewer 1

      • The colocalization of endogenous PLEKHG3 and LAMP1 as depicted in figures 3B and 3C (data from fixed cells) is not convincing. PLEKHG3 appears to be present on cortical actin structures as opposed to being colocalized with LAMP1 on lysosomes. And related to this point:

      • There is no apparent colocalization of PLEKHG3 and lysotracker in the movie S5.

      Answer:

      We do not claim that the two structures always colocalize, but that PLEKHG3 is a LAMTOR3 vicinal protein that co-enriches with a subset of peripheral lysosomes at focal adhesions (FAs)/protrusions. The images in Figure 3C are schematic for how PLEKHG3-high/low and LAMP1-high/low regions were defined for quantification. We agree with the Reviewer and with the previous literature that PLEKHG3 main localization is to cortical actin structures, as reaffirmed by the strong cortical actin localization shown in Figure 3F of the original version and in Figure S2C (HEK293T cells) and in Figure S3A in HeLa cells in the revised version. We have clarified the text referring to Figure 3F on page 26, line 11-14 as follows:

      “Immunofluorescence experiments showed the reported colocalization of endogenous PLEKHG3 (Figure S2C in HEK293T cells, Figure S3A in HeLa cells) and GFP-PLEKHG3 with cortical actin structures and the partial localization of LAMP1-positive vesicles to these structures in correspondence with vinculin-positive focal adhesions.”

      Live imaging in GFP-PLEKHG3-expressing cells (including movie S5, and particularly the stills of the leading edge in Figure 4F) further supports this spatial association without implying obligate colocalization. We added explicit language (p. 27, lines 19-21): “Following a single cell over time, we could observe that __a subset of __lysosomes appears to travel to PLEKHG3 accumulation sites and specifically move into developing protrusions.”

      • The authors should also confirm the specificity of the PLEKHG3 antibody in immunofluorescence using control and PLEKHG3 siRNA in untransfected cells that have not been transfected with GFP-PLEKHG3 (as is shown in Fig. S2C). Numerous antibodies recognize the overexpressed protein but do not recognize the same protein at endogenous expression levels.

      Answer: To assess the specificity of the antibody for endogenous PLEKHG3 we have used HEK293T cells, which based on the fact that PLEKHG3 is most highly expressed in neuronal cells (https://www.proteinatlas.org/ENSG00000126822-PLEKHG3/tissue#expression_summary) should yield a clearer endogenous signal. The pattern of PLEKHG3-positive bands is similar to that observed in HeLa cells, and only the band around 250 kD is clearly reduced by the siPLEKHG3. The IF images show a selective loss of the PLEKHG3 signal in correspondence of actin filaments close to the plasma membrane, whereas the nuclear signal is preserved, and therefore to be considered non-specific (revised Figure S2B-C).

      Extract from revised Figure S2B-C: ____PLEKHG3 KD test in HEK293T cells: B) Western blot of HEK293T cells showing downregulation of PLEKHG3 expression upon siPLEKHG3 treatment compared to siScr. Bar plot shows quantification of PLEKHG3 bands from immunoblot above. Error bars = SEM, n=3. * = p values according to student's t-test. C) Immunofluorescence images of HEK293T cells. siPLEKHG3 shows drop in PLEKHG3 intensity in the periphery of the cell and less colocalization with Phalloidin. Scale bar = 50 µm. Line plots show intensity profiles of Phalloidin (green) and PLEKHG3 (red) along the white lines in the merged inset images. Scale bar = 10 µm.

      In addition, we have now generated a PLEKHG3 CRISPR-Cas KO in HeLa cells. The results, shown in revised Figure S2G-I, confirm the specificity of our reagents and the localization of PLEKHG3 seen in HEK293T cells.

      Extract from revised Figure S2G-I: G) Immunoblot and quantification of HeLa PLEKHG3 KO cells represents the degree of PLEKHG3 depletion achieved using different guides compared to WT cells transfected with empty vector (EV). The most potent guides (8-9) are boxed in red. H) Immunofluorescence images of WT and PLEKHG3 KO8 cells reveal an overall drop in PLEKHG3 intensity and the specific loss of PLEKHG3 signal at the periphery of the cells. I) Quantification of PLEKHG3 intensity as displayed in H for two KO cell lines compared to WT cells. Dots represent individual data points of each of the three-color coded replicates; diamonds represent the mean of each replicate; black bars represent the mean ± the SEM of three biological replicates; * = p values according to 2-way-ANOVA. Error bars = SEM.

      These results establish that the peripheral cortical signal is specific for endogenous PLEKHG3; the nuclear signal is non-specific. Loss of PLEKHG3, however, had no effect on lysosomal distribution, morphometric parameters (see revised Figure S4A-C) or protrusive activity (see revised Figure S6E-F) compared to WT cells.

      Extract from revised Figure S4A-C: ____PLEKHG3 KO does not influence lysosomal distribution or cell morphometry: A) __Quantification of lysosomal distribution in WT compared to two KO cell lines. N ≥ 50 cells in three biological replicates. __B) Schematic representation of analysis of cell shape descriptors as referred to in C). Left picture shows the calculated outline in yellow based on which the cell area and circularity are calculated. Right picture shows the minor and major cell axis which, calculated as fraction, result in the aspect ratio of the cell. Scale bar = 50 µm. C) Quantification of cell morphometric parameters Area, Circularity and Aspect ratio. N ≥ 50 cells in three biological replicates. Black dots represent mean of each biological replicate. Statistical analysis according to student’s t-test. Error bars = SEM.


      • The claim that "peripheral accumulation of lysosomes inhibits protrusion formation and limits cell motility" should be tested more rigorously using the RAMP method, preferably in living cells. Other approaches, such as overexpression/siRNA of Arl8b and other motor adaptors, such as SKIP/PLEKHM2, can be used to alter lysosome positioning and confirm this central finding of the manuscript. The authors could also consider including additional mechanistic data in order to comprehend how lysosome positioning controls cell motility. For instance, the RAMP approach could be employed to investigate cortical actin dynamics upon repositioning of lysosomes to the peripheral/perinuclear region.

      Answer: We have purchased the RAMP system from Addgene and adapted the reporters to express fluorophores compatible with our color setup in the different respective cell lines (HeLa GFP/GFP-PLEKHG3 as well as in HeLa PLEKHG3 KO cells. Unfortunately, we’ve experienced difficulties with imaging due to suboptimal efficiency of the double transfection necessary to introduce the RAMP system into the cell lines. The LAMP1 and the KIF plasmids were co-expressed at very different levels in the cells, leading to the need for high laser power in both channels, which too often resulted in cell death. Additionally, the redistribution of the lysosomes after biotin addition was incomplete and slower than initially expected, which made it impossible to investigate cortical actin dynamics.

      To gain some mechanistic insight, we have performed further live cell imaging analyses comparing PLEKHG3 WT vs KO cells and GFP vs GFP-PLEKHG3 cells expressing a combination of BFP-LifeAct (to visualize F-actin) with either control mCherry or mCherry-KIF1A to move lysosomes to the periphery.

      • In all experiments, locking lysosomes in the periphery drastically reduces membrane dynamics (protrusion formation and retractions).
      • PLEKHG3 remains colocalized with LifeAct under KIF1A (Fig. S6C–D), indicating that the reduced protrusiveness is upstream or independent of PLEKHG3’s cortical localization
      • Live-cell BFP-LifeAct imaging revealed that KIF1A-driven peripheral lysosomes reduce protrusion formation/retraction and dampen cortical actin dynamics in both WT and PLEKHG3 KO cells (Fig. S6A–B, E–G; Movies S12–15; S18–21), indicating that these phenomena are independent of PLEKHG3. We believe these data, together with the quantitative lysosome repositioning and FA analyses, substantiate the central finding that forced peripheral lysosome clustering correlates with more adhesive FA states and suppressed protrusive activity. We have clarified scope and limitations accordingly.

      Extract from Figure S____1____A-C,E,G: PLEKHG3 localizes to F-actin independently of lysosomal transport but is dispensable for protrusive activity. A) __Stills from live cell imaging (Movies S12-15). Cells stably expressing GFP or GFP-PLEKHG3 were transfected with the indicated mCherry constructs. Yellow arrows = forming protrusions; blue arrows = retracting protrusions. Stills were generated over a period of 2 hrs. Scale bar = 50 µm. __B) __Quantification of protrusions formed and retracted over time in cells from A. Values indicate average number of protrusions formed in a timespan of three hours from a total of ≥ 15 cells per condition. Error bars = SEM. C) Quantification of colocalization by Fijis Coloc2 Plugin (see materials and methods) over a timespan of three hours. Lines represent mean of all cells per condition, and light-color shading represents the SEM. __E) Stills from live cell imaging (Movies S18-21). PLEKHG3 WT and PLEKHG3 KO cells were transfected with the indicated mCherry constructs and incubated with LysoTracker. Yellow arrows = forming protrusions; blue arrows = retracting protrusions. Stills were generated over a period of 2 hrs. Scale bar = 50 µm. G) Quantification of protrusions formed and retracted over time in cells from E. Values indicate average number of protrusions formed in a timespan of one hour from a total of ≥ 15 cells per condition. Error bars = SEM. In B,G, black asterisks denote p values according to Kruskal-Wallis and Bonferroni post-hoc testing, comparing the effect of KIF1A against mCherry or PLEKHG3 WT against KO.__ __

      • It is not clear how the authors conclude that Figure 4E graph shows "the LAMP1 signal was stronger in paxillin-labeled FA compared to control regions". The 4E graph shows LAMP1 signal in GFP versus GFP-PLEKHG3 and shows a modest enrichment of LAMP1 in FAs in GFP-PLEKHG3 overexpression. LAMP1 enrichment in FAs is also not obvious in the image shown in Figure 4B.

      Answer: We stand corrected – the Figure we referred to was not in the manuscript. It has been inserted now, as a plot next to Figure. Figure 4B (schematic representation of colocalization analysis) was designed to explain how we define focal adhesions (paxillin positive) and adjacent control regions (same size and shape, but paxillin-negative). The actual analysis was missing and has now been inserted. We apologize for this mistake.

      We do not claim that PLEKHG3 brings lysosomes to FAs. The enrichment of lysosomes in FA regions of cells expressing GFP-PLEKHG3 compared to GFP-expressing cells shown in 4E, as the Reviewer correctly notes, is marginal and is not highlighted anywhere in the text exactly for this reason.

      • In Fig. 2B, there appears to be a labeling error. The lanes 2,4 and 7 appear to be transfected with L3-T-V5 but labeled as GFP-V5-cyto. Here the PLEKHG3 band should be indicated.

      • AND -Fig. 2C is an IP experiment as per the manuscript text but it is labeled as pulldown.

      Answer: We stand corrected, and the necessary changes have been made in the revised version in Figure 2B.

      Reviewer 2

      1 - Specificity of PLEKHG3 antibody: In Fig. S2, authors show that PLEKHG3 antibody recognizes 3 bands (above 100 kDa, above 130 kDa and 250 kDa) and all of them are reduced by the silencing of PLEKHG3. Then, in Fig. 2A and C, authors only show the band above 130 kDa, despite implying that the specific band should be "much higher than the 134 kDa calculated from the aminoacid sequence of the protein".

      In Fig. 2 B, they show all the bands shown in Fig. S2 and presumably favor that the specific band is the 250 kDa one. Finally, in Fig. 2D, they show all bands and note that the band above 130 kDa is not specific. Therefore, authors need to conclude what is the specific band and always analyze the same one, and, possibly, use a different antibody or purify this one to remove non-specific binding. Without this, the main result of the paper, cannot be substantiated.

      Answer: We apologize for this misunderstanding. The antibody recognizes three bands, all reduced by siRNA treatment. These three bands are only resolved in the gels in Figure S2A and B, and in Figure 2B. The reason for this is the high molecular weight of the isoforms, that are resolved in these 8% gels, but collapse into one band in the 15% gels shown in Figure 2A and C. Therefore, the high molecular weight bands are not resolved under these conditions. 8% gels such as the ones in Figure 2B are needed to resolve the high molecular weight bands.

      Figure 2D shows an 8% gel, and therefore all bands are visible. The band marked by an arrow is only present in the streptavidin pulldowns but not in the input or in the supernatant and is therefore considered unspecific. This has been clarified in the revised figure legend on page 41. In addition, to assess the specificity of the antibody for endogenous PLEKHG3 we have used HEK293T cells, which based on the fact that PLEKHG3 is most highly expressed in neuronal cells (https://www.proteinatlas.org/ENSG00000126822-PLEKHG3/tissue#expression_summary) should yield a clearer endogenous signal. The results of this experiment are shown in Figure S2B-C of the revised manuscript. The pattern of PLEKHG3-positive bands is similar to that observed in HeLa cells, and only the band around 250 kD is clearly reduced by the siPLEKHG3. The IF images show a selective loss of the PLEKHG3 signal in correspondence of actin filaments close to the plasma membrane, whereas the nuclear signal is preserved, and therefore to be considered non-specific. More importantly, we have now generated a PLEKHG3 CRISPR-Cas KO in HeLa cells. The results, shown in Figure S2G-I confirm the specificity of our reagents and the localization of PLEKHG3 seen in HEK293T cells. Loss of PLEKHG3 however, had no effect on lysosomal distribution or morphometric parameters compared to WT cells (Figure S4A-C).

      2 - In page 12, authors state that "These results indicated that PLEKHG3 is a transient interactor, or a proximal, not directly binding protein, of L3" and in page 14 that "... PLEKHG3 is a proximal L3 protein rather than a transient physical interactor". It is not clear at all how did the authors reach such conclusions, nor they have data to conclude this. Indeed, they would have to express the proteins in vitro and test their interaction to conclude about a direct binding. They also do not know what is the stability of the interaction.

      Answer: This is also a misunderstanding. We mislabeled Figure 2C as “pulldown”, rather than “IP”, as it is characterized in the text. We revised terminology to “vicinal (proximity-labeled) protein” throughout, avoiding claims on directness. Our basis is: robust L3 TurboID labeling of PLEKHG3; failure to co-immunoprecipitate PLEKHG3 with V5-tagged L3 (Fig. 2C); lack of PLEKHG3 labeling by TMEM192; and unchanged PLEKHG3 FA localization in L3 KO (Fig. S3H–J). Together, these support spatial proximity rather than a stable L3–PLEKHG3 complex. We explicitly state that we did not perform in vitro binding due to the negative co-IP.

      Based on these negative data, we did not proceed to test the possibility of complex formation in vitro.

      3 - Still in page 12, authors state that "... two different membrane structures, protrusions and ruffles". What do the authors mean exactly by "protrusions", as there are several different ones (e.g., lamellipodia, filopodia, pseudopods)? And how can they distinguish between ruffles and, for example, lamellipodia? They need to use markers and more carefully analyze their morphology to be able to distinguish these. Like this, it is too preliminary.

      Answer: It was our intention to indicate with the arrows the trajectories in the figure along which we measured the MFI of LAMP1 and PLEKHG3. Although this is indicated in the figure legend, it had apparently given the impression that the arrows indicated specific membrane structures. Since we are focusing on different types of membrane protrusions rather than ruffles, we replaced the ambiguous terms "ruffles" and "protrusions" with the terms "elongated protrusions" (Figure 3D upper panel) and then compared these with "non" elongated protrusions” (Figure 3D lower panel). Indeed, we note that PLEKHG3 accumulation is possible below and along the plasma membrane, but colocalization with lysosomes occurs preferentially in elongated protrusions. We therefore amended the text on page 26, line 4-9 as follows:

      „More specifically, we found that PLEKHG3 colocalized more strongly with LAMP1-positive vesicles in elongated membrane structures (Figure 3D-E). Focal adhesion sites, which anchor the intracellular cortical actin network to the extracellular matrix and are remodeled with the help of late endosomes/lysosomes during protrusion formation and cell motility, can also be found in such elongated membrane protrusions (reviewed in [58,59]).”

      5 - It is not clear if in cells KO for PLEKHG3, the overexpression of KIF1A leads to more lysosomes localizing close to the PM, as well as more protrusions and more cell motility, as the authors only compare cell overexpressing GFP or GFP-PLEKHGL3.

      Answer: We have now generated a PLEKHG3 KO cell line. In these cells, KIF1A still drives peripheral lysosome clustering and suppresses protrusive activity and actin dynamic (see revised Figure S4A-C displayed below). Baseline lysosome distribution and morphometric parameters are unchanged in KO cells (see revised Figure S6E-F displayed below).

      Extract from revised Figure S4A-C: ____PLEKHG3 KO does not influence lysosomal distribution or cell morphometry: A) __Quantification of lysosomal distribution in WT compared to two KO cell lines. N ≥ 50 cells in three biological replicates. __B) Schematic representation of analysis of cell shape descriptors as referred to in C). Left picture shows the calculated outline in yellow based on which the cell area and circularity are calculated. Right picture shows the minor and major cell axis which, calculated as fraction, result in the aspect ratio of the cell. Scale bar = 50 µm. C) Quantification of cell morphometric parameters Area, Circularity and Aspect ratio. N ≥ 50 cells in three biological replicates. Black dots represent mean of each biological replicate. Statistical analysis according to student’s t-test. Error bars = SEM.

      Extract from revised Figure S6E,G: ____PLEKHG3 localizes to F-actin independent of lysosomal transport but is neglectable for lysosomal effect on protrusive activity. E) Stills from live cell imaging (Movies S18-21). PLEKHG3 WT and PLEKHG3 KO cells were transfected with the indicated mCherry constructs and incubated with LysoTracker. Yellow arrows = forming protrusions; blue arrows = retracting protrusions. Stills were generated over a period of 2 hrs. Scale bar = 50 µm. G) Quantification of protrusions formed and retracted over time in cells from E. Values indicate average number of protrusions formed in a timespan of one hour from a total of ≥ 15 cells per condition. Error bars = SEM. In F,G, black asterisks denote p values according to Kruskal-Wallis and Bonferroni post-hoc testing, comparing the effect of KIF1A against mCherry or PLEKHG3 WT against KO.

      6 - Regarding the statistical analysis, authors assert that it was done using Student's t tests, unless otherwise stated. However, they never refer in figure legends other statistical analysis methods. If so, they cannot use such test, for example, in cases where more than two groups are compared.

      Answer: We clarified in Methods that we performed two-group comparisons unless otherwise stated. Where >2 groups are compared, we used appropriate tests with correction (e.g., Kruskal–Wallis with Bonferroni in Fig. S6B, S6G). Figure legends now explicitly state the test used.

      __Minor comments: __

      1 - In the abstract, authors refer that cytosolic proteins are recruited to platforms on the limiting membrane of lysosomes. What do they mean by "platforms"? Is it microdomains?

      Answer: We apologize for this lack of clarity and have now changed the first sentence in the abstract on page 1 to “Lysosomes are key organelles involved in metabolic signaling pathways through their ability to recruit cytosolic molecules to protein platforms bound to the lysosomal membrane”. We refer to protein platforms as multifunctional protein complexes that can recruit and assemble signaling components (e.g., the recruitment of mTORC1 activating proteins by the LAMTOR complex).

      2 - In the Introduction, there is a period before the reference at the end of the first paragraph.

      Answer: We stand corrected. See changes on page 18, line 9.

      3 - In the results, Fig. 1E is mentioned before Fig. 1D and Figure S1F before Fig S1E, which can be confusing.

      Answer: Figure S1E on page 6 was mislabeled as Figure 1E and Figure S1K on page 9 was mislabeled as Figure 1K. We stand corrected. See changes on page 21, line 21+23 and page 23, line 5.

      4 - All the immunofluorescence images need to be bigger, in general, and have zoom-ins, except Fig. 3A, 4B, 4F, and S2C. Also, in Fig. S1F, the green channel has different intensities and the V5-lyso signal is clearly saturated. Finally, Fig. S1D, S1I and S3F must be enlarged, too.

      Answer: We appreciate the Reviewer's suggestion, but enlarging all the immunofluorescence images and including zoom-ins would make the manuscript very crowded and could distract from the main findings. Regarding the expression levels of the baits, as mentioned in the manuscript, we aimed to express them at near-endogenous levels. However, TMEM192 is expressed at higher levels than LAMTOR3 in these cells, which may have resulted in the observed discrepancy. We hope the Reviewer will understand our decision and find the current presentation of the data clear and informative.

      5 - In page 9, where it reads "Figure 1K", should read "Figure S1K".

      Answer: See answer to minor point 3.

      6 - The observation that PLEKHG3 silencing leads to loss of the perinuclear clustering of LAMP1-positive vesicles, and increase in their accumulation at the cell tips, is not referred in the text.

      Answer: While this might seem the case in part of the cells shown in the representative image in Figure S2C, population-level analysis (n > 30 cells) did not support a shift in lysosome distribution with PLEKHG3 silencing.

      __Figure 1 for Reviewer 2: __Lysosomal distribution in HeLa cells transfected with either siScr or siPLEKHG3. X-axis is relative distance from the nucleus and Y-axis the normalized intensity of the LAMP1 channel. Results are averages of >30 cells from one experiment (only displayed in “final revision” document).

      Similar results were obtained using two independent PLEKHG3 KO cell lines, and are shown in Figure S4A

      __Extract from revised Figure S4A-C: PLEKHG3 KO does not influence lysosomal distribution or cell morphometry: A) __Quantification of lysosomal distribution in WT compared to two KO cell lines. N ≥ 50 cells in three biological replicates.

      7 - Fig. 2C is not referred in the legend.

      Answer: We stand corrected and have changed the legend of Figure 2 accordingly on page 41.

      8 - Figure S3A and B: authors should show the colocalization of endogenous PLEKHG3 with phalloidin and not only the GFP-tagged protein.

      Answer: We thank the Reviewer for this comment and have performed this experiment showing the colocalization of endogenous PLEKHG3 with F-actin structures stained by Phalloidin. Even though the endogenous PLEKHG3 staining in HeLa cells is rather weak, sites where membrane protrusions are formed are clearly marked with PLEKHG3 staining below the plasma membrane. These data confirm the specific colocalization of PLEKHG3 with Phalloidin shown in the revised Figure S3A. See also the extract from Figure S3A below.

      Extract from revised Figure S3A: Immunofluorescence images of HeLa cells. A) HeLa cells stained with PLEKHG3 (red) and Phalloidin (green). The nucleus is indicated by DAPI staining (blue). Scale bar = 50 µm. Insets on the right as indicated by white box in image on the left. Scale bar = 10 µm. Line plot corresponds to white line in merged inset.

      9 - In page 14, authors refer to Fig. 3G, which does not exist.

      Answer: We stand corrected, the sentence on page 14, line 9 (now page 26 line 24 in revised document) refers to Figure S3G.

      10 - In page 30 and page 32, different antibodies for LAMP1 and PLEKHG3 are mentioned, but in the figure legends authors do not refer which one they used.

      Answer: We tried different PLEKHG3 antibodies but ended up using only one. The other antibody has been excluded from the list on page 32, line 18 (now page 9, lines 4-5 in revised manuscript). We have specified which LAMP1 antibodies were used in which Figure in the Material and Methods on page 6, line 23 and page 7, line 4-5.

      11 - In page 33, where it reads "300 µm protein", it should probably read "300 µg protein".

      Answer: We stand corrected. See changes on page 10, line 2.


      Reviewer 3

      A key issue … is that the authors focus solely on peripheral lysosomes as target compartments for PLEKHG3. This is not self-evident, particularly in light of images presented in Figures 2 and 3, where colocalization of PLEKHG3 with perinulcear lysosomes appears very likely. The authors should make differences/similarities they observe between effects on perinuclear versus peripheral lysosomes explicit both with data and in the text, if such differences exist.

      Answer: The Reviewer is likely addressing the images in Figure 3, which were obtained by staining endogenous PLEKHG3 and do diffuse staining around the nucleus. This perinuclear haze is resistant to siPLEHG3 (revised Figure S2C) or to PLEKHG3 CRISPR-Cas9-mediated ablation (revised Figure S2H) and is not observed with the GFP-PLEKHG3 fusion protein (revised Figure S2E-F), which gives a less diffuse signal. This is why we are confident about the colocalization of PLEKHG3 with peripheral lysosomes.

      Data presented in Figure 6 showing cell motility analysis is interesting and has potential to make the manuscript impactful. Similarly, data in Figure 4F (live cell imaging) looks attractive but is not informative in the absence of relevant genetic perturbations as comparisons. These types of experiments would benefit greatly from PLEKHG3 loss of function analysis, as well as mutational analysis in the over-expression setting.

      Answer: We have now generated a PLEKHG3 KO cell line. Loss of PLEKHG3, however, had no effect on lysosomal distribution or morphometric parameters compared to WT cells, and it does not impact the suppression of protrusions/actin dynamics by KIF1A is preserved in KO, indicating PLEKHG3 is not required for this phenotype.

      Mutational analysis of PLEKHG3–LAMTOR binding is not feasible in the absence of co-IP or other direct binding evidence (see revised Figure S6E,G displayed in the answer above).

      Minor point: 1. Multicolor overlays with one of the channels in white is in my view not reader-friendly. Appreciating colocalization between endosomes/lysosomes, actin and G is very important for this study, and while is typically reserved to show overlay between green and magenta or green (standard for 2 channels), red and blue (standard for 3-channels). I therefore advise the authors to choose a different color combination throughout the figures when presenting microscopy images.

      Answer: White as a channel color has been substituted for with red (in the 2- and 3-color images) or with blue (in the 4-color images) throughout the images of the revised manuscript, except for the stills from the videos that have not been changed because no colocalization analysis has been performed in this case.

      1. Description of analyses that authors decided not to carry out

      Please include a point-by-point response explaining why some of the requested data or additional analyses might not be necessary or cannot be provided within the scope of a revision. This can be due to time or resource limitations or in case of disagreement about the necessity of such additional data given the scope of the study. Please leave empty if not applicable.

      Reviewer 2

      4 - At least Fig. 2F and 3A need quantification. Regarding cell motility, there is no quantification and the authors must perform a quantitative assay (despite stating that "As another measure of cell motility, analysis of the number of forming protrusions and retracting membranes..."). Not only this is not a measure of cell motility, but there the issue of what are "protrusions" referred above. Therefore, authors need to quantify the distance that the cells move and/or perform quantitative motility/migration assays.

      Answer: We appreciate the Reviewer’s attention to detail and agree that the quantification of these figures is essential to understand the results. We believe that the Reviewer refers to Figure 3F and Figure 4A, as there is no Figure 2F, and Figure 3A only confirms the localization of endogenous PLEKHG3, as previously reported in (Nguyen et al., PNAS 2016). If our assumption is correct, then the salient aspects of Figure 3F, which is a representative image, are quantified

      • in Figure 3C-E (endogenous PLEKHG3 colocalization with LAMP1/lysosomes)
      • In Figure 4E and 5F-G (FA with LAMP1/lysosomes).
      • Figure 4A is quantified in Figure 4C-E (GFP-PLEKHG3 colocalization with FAs, labeled with paxillin in this experiment, and LAMP1 colocalization with FAs). In response to the Reviewer's comment regarding the absence of quantification for cell movement/migration in our study, we apologize for any confusion that may have arisen from our use of the term "cell motility." We have clarified usage to mean membrane remodeling dynamics integral to migration rather than net displacement. To avoid overclaiming, we removed statements that could imply directed migration and focused on protrusion/retraction metrics and shape changes. In this context, our statement that lysosomal subcellular localization plays a role in cell motility remains valid. The relationship between membrane protrusive activity and motility is evident from our observations in cells overexpressing KIF1A-mCherry, where both membrane remodeling/protrusive activity and movement are significantly impaired compared to control cells (refer to Movie S7 vs. S6 and S10 vs. S9).

      To address the Reviewer's concern, we have clarified our definition of motility in the introduction by stating on page 19, line 23 – page 20, line 2: "We demonstrate that PLEKHG3 colocalizes with lysosomes at focal adhesion and protrusion sites, and that the localization and function of this protein – and consequently, overall cell motility – are fundamentally dependent on lysosomal dynamics." This revision ensures that our results are accurately described and minimizes any potential confusion. Additionally, we have removed the statement on page 23, line 1 of the original manuscript. We apologize for any confusion our original wording may have caused and appreciate the opportunity to clarify our intentions.

      Reviewer 3

      1. The mechanism of PLEKHG3 action on lysosomes/late endosomes is underdeveloped in my view. In the absence of for instance mutational analyses to examine what drives the interaction of PLEKHG3 with LAMTOR3, as well as delineation of at least some molecular consequences of this binding, the study remains incomplete.

      Answer: We are grateful for the Reviewer's feedback and concur that gaining insight into the mechanistic details of PLEKHG3's interaction with LAMTOR3 would be beneficial. We now consistently refer to PLEKHG3 as a L3 vicinal protein based on TurboID and lack of co-IP. Because L3 KO does not alter PLEKHG3 FA localization and we find no evidence for a stable complex, mutational binding analyses lack a clear readout and are beyond the scope of this revision. We emphasize the conceptual advance—lysosome positioning gates PLEKHG3 cortical enrichment at FAs while peripheral lysosome clustering correlates with more adhesive, less protrusive behavior—and explicitly flag mechanistic questions (e.g., integrin turnover, IQGAP, Rac1 pools) as future work.

      We hope that the Reviewer will bear with us on this point, considering the novelty of our findings, which illuminate the interplay between lysosomes and actin dynamics as well as the role of PLEKHG3 in regulating cell protrusions—findings not previously reported in the literature.

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      Referee #3

      Evidence, reproducibility and clarity

      The manuscript by Ettelt et al describes the identification of PLEKHG3 as a collaborator of the LAMTOR complex on lysosomes using proximity-based biotinylation. The biotinylation screen is well executed and controlled. The authors choose to follow up on PLEKHG3, a protein involved in actin dynamics, which they refer to as understudied (I let the validity of the latter statement to be evaluated by the editor). Generally speaking, the data are of good quality, and the manuscript is clear and well written. However, much of the evidence on the role of PLEKHG3 on lysosomes is suggestive at best and further investigation into its mechanisms of action is warranted. Some important points to address prior to publication are detailed below.

      Major Points:

      1. The mechanism of PLEKHG3 action on lysosomes/late endosomes is underdeveloped in my view. In the absence of for instance mutational analyses to examine what drives the interaction of PLEKHG3 with LAMTOR3, as well as delineation of at least some molecular consequences of this binding, the study remains incomplete.
      2. A key issue possibly (but not necessarily) related to the point above is that the authors focus solely on peripheral lysosomes as target compartments for PLEKHG3. This is not self-evident, particularly in light of images presented in Figures 2 and 3, where colocalization of PLEKHG3 with perinulcear lysosomes appears very likely. The authors should make differences/similarities they observe between effects on perinuclear versus peripheral lysosomes explicit both with data and in the text, if such differences exist.
      3. Data presented in Figure 6 showing cell motility analysis is interesting and has potential to make the manuscript impactful. Similarly, data in Figure 4F (live cell imaging) looks attractive but is not informative in the absence of relevant genetic perturbations as comparisons. These types of experiments would benefit greatly from PLEKHG3 loss of function analysis, as well as mutational analysis in the over-expression setting.

      Minor point

      1. Multicolor overlays with one of the channels in white is in my view not reader-friendly. Appreciating colocalization between endosomes/lysosomes, actin and G is very important for this study, and while is typically reserved to show overlay between green and magenta or green (standard for 2 channels), red and blue (standard for 3-channels). I therefore advise the authors to choose a different color combination throughout the figures when presenting microscopy images.

      Significance

      In principle, I consider this study to be of interest to the community of cell biologists working on the endolysosomal system and/or the actin cytoskeleton and its relationship to intracellular membranes. However, the authors find themselves in a rather crowded field. I feel that developing the mechanism of action of PLEKHG3 on lysosomes beyond this first submission could help with boosting the impact of the study. There is clearly something interesting going on, but what that is exactly, remains unclear in my view.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary: The authors use proximity-dependent labelling and mass spectrometry to identify cytoplasmic proteins that interact with lysosomes. They show that PLEKHG3 interacts with the LAMTOR complex; that PLEKH3 accumulates in focal adhesion sites, where it colocalizes with peripheral lysosomes; and that the increased translocation of lysosomes to the periphery leads to less "protrusions", as well as rounder cells and less motile cells.

      Major comments: While the study is generally carefully performed and thorough, there are major shortcomings that affect the conclusions taken, namely the specificity of the PLEKHG3 antibody, the identification of "protrusions" and ruffles, several quantifications missing, and the data used to conclude about cell motility. There are also conclusions for which there is no concrete or solid evidence.

      Specific issues:

      1. Specificity of PLEKHG3 antibody: In Fig. S2, authors show that PLEKHG3 antibody recognizes 3 bands (above 100 kDa, above 130 kDa and 250 kDa) and all of them are reduced by the silencing of PLEKH3. Then, in Fig. 2A and C, authors only show the band above 130 kDa, despite implying that the specific band should be "much higher than the 134 kDa calculated from the aminoacid sequence of the protein". In Fig. 2 B, they show all the bands shown in Fig. S2 and presumably favor that the specific and is the 250 kDa one. Finally, in Fig. 2D, they show all bands and note that the band above 130 kDa is not specific. Therefore, authors need to conclude what is the specific band and always analyze the same one, and, possibly, use a different antibody or purify this one to remove non-specific binding. Without this, the main result of the paper, cannot be substantiated.
      2. In page 12, authors state that "These results indicated that PLEKHG3 is a transient interactor, or a proximal, not directly binding protein, of L3" and in page 14 that "... PLEKHG3 is a proximal L3 protein rather than a transient physical interactor". It is not clear at all how did the authors reach such conclusions, nor they have data to conclude this. Indeed, they would have to express the proteins in vitro and test their interaction to conclude about a direct binding. They also do not know what is the stability of the interaction.
      3. Still in page 12, authors state that "... two different membrane structures, protrusions and ruffles". What do the authors mean exactly by "protrusions", as there are several different ones (e.g., lamellipodia, filopodia, pseudopods)? And how can they distinguish between ruffles and, for example, lamellipodia? They need to use markers and more carefully analyze their morphology to be able to distinguish these. Like this, it is too preliminary.
      4. At least Fig. 2F and 3A need quantification. Regarding cell motility, there is no quantification and the authors must perform a quantitative assay (despite stating that "As another measure of cell motility, analysis of the number of forming protrusions and retracting membranes..."). Not only this is not a measure of cell motility, but there the issue of what are "protrusions" referred above. Therefore, authors need to quantify the distance that the cells move and/or perform quantitative motility/migration assays.
      5. It is not clear if in cells KO for PLEKHG3, the overexpression of KIF1A leads to more lysosomes localizing close to the PM, as well as more protrusions and more cell motility, as the authors only compare cell overexpressing GFP or GFP-PLEKHGL3.
      6. Regarding the statistical analysis, authors assert that it was done using Student's t tests, unless otherwise stated. However, they never refer in figure legends other statistical analysis methods. If so, they cannot use such test, for example, in cases where more than two groups are compared.

      Minor comments:

      1. In the abstract, authors refer that cytosolic proteins are recruited to platforms on the limiting membrane of lysosomes. What do they mean by "platforms"? Is it microdomains?
      2. In the Introduction, there is a period before the reference at the end of the first paragraph.
      3. In the results, Fig. 1E is mentioned before Fig. 1D and Figure S1F before Fig S1E, which can be confusing.
      4. All the immunofluorescence images need to be bigger, in general, and have zoom-ins, except Fig. 3A, 4B, 4F, and S2C. Also, in Fig. S1F, the green channel has different intensities and the V5-lyso signal is clearly saturated. Finally, Fig. S1D, S1I and S3F must be enlarged, too.
      5. In page 9, where it reads "Figure 1K", should read "Figure S1K".
      6. The observation that PLEKHG3 silencing leads to loss of the perinuclear clustering of LAMP1-positive vesicles, and increase in their accumulation at the cell tips, is not referred in the text.
      7. Fig. 2C is not referred in the legend.
      8. Figure S3A and B: authors should show the colocalization of endogenous PLEKHG3 with phalloidin and not only the GFP-tagged protein.
      9. In page 14, authors refer to Fig. 3G, which does not exist.
      10. In page 30 and page 32, different antibodies for LAMP1 and PLEKHG3 are mentioned, but in the figure legends authors do not refer which one they used.
      11. In page 33, where it reads "300 µm protein", it should probably read "300 µg protein".

      Significance

      The study provides evidence that lysosome positioning can affect cortical actin cytoskeleton dynamics, as well as cell shape and motility. Experiments are in general thorough and data subjected to quantification. However, there are fundamental conclusions that are preliminary at this stage, as some of the data is not yet solid enough. Therefore, it needs to be further strengthened to be considered for publication. In general, it reads well but the amount of abbreviations (e.g. in the case of the constructs) makes it somehow difficult to follow. The study will be interesting for the cell biology, membrane trafficking and cytoskeleton dynamics communities.

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      Referee #1

      Evidence, reproducibility and clarity

      The manuscript by Ettelt et al., describes identification of Rho guanine nucleotide exchange factor- PLEKHG3 as one of the positive hits from a TurboID proximity-dependent labeling screen using LAMTOR3 (one of the subunits of the pentameric LAMTOR complex/Ragulator) as a bait protein. The authors find that PLEKHG3 colocalizes with lysosomes at focal adhesions and that peripheral clustering of lysosomes promotes PLEKHG3 localization near the plasma membrane, and also inhibits protrusion formation and cell motility. The experiments, particularly the Turbo ID proximity-dependent labeling screen, are well-executed, and the imaging data is aptly quantified. The manuscript explores an exciting question of how lysosome positioning regulates cortical actin dynamics and thereby cell motility.

      Major comments:

      • The colocalization of endogenous PLEKHG3 and LAMP1 as depicted in figures 3B and 3C (data from fixed cells) is not convincing. PLEKHG3 appears to be present on cortical actin structures as opposed to being colocalized with LAMP1 on lysosomes. The authors should also confirm the specificity of the PLEKHG3 antibody in immunofluorescence using control and PLEKHG3 siRNA in untransfected cells that have not been transfected with GFP-PLEKHG3 (as is shown in Fig. S2C). Numerous antibodies recognize the overexpressed protein but do not recognize the same protein at endogenous expression levels.

      Moreover, do the authors observe colocalization between GFP-PLEKHG3 and lysotracker in living cells? There is no apparent colocalization of PLEKHG3 and lysotracker in the movie S5. - The authors observe that GFP-PLEKHG3 is concentrated at the cell's periphery when KIF1A is overexpressed, whereas RUFY3 overexpression results in more cytosolic staining. To bolster their conclusion that a change in lysosomal positioning alters the subcellular localization of PLEKHG3, it is preferable to employ inducible techniques, such as the recently described "reversible association with motor proteins" (RAMP) (PMID: 31100061). The method is a rapid and reversible method for altering organelle positioning. It is still unknown whether PLEKHG3 is associated with lysosomes and mechanism of how positioning of lysosomes affects PLEKHG3 localization. - Similarly to the preceding point, the claim that "peripheral accumulation of lysosomes inhibits protrusion formation and limits cell motility" should be tested more rigorously using the RAMP method, preferably in living cells. Other approaches, such as overexpression/siRNA of Arl8b and other motor adaptors, such as SKIP/PLEKHM2, can be used to alter lysosome positioning and confirm this central findings of the manuscript. The authors could also consider including additional mechanistic data in order to comprehend how lysosome positioning controls cell motility. For instance, the RAMP approach could be employed to investigate cortical actin dynamics upon repositioning of lysosomes to the peripheral/perinuclear region. - It is not clear how the authors conclude that Figure 4E graph shows "the LAMP1 signal was stronger in paxillin-labeled FA compared to control regions". The 4E graph shows LAMP1 signal in GFP versus GFP-PLEKHG3 and shows a modest enrichment of LAMP1 in FAs in GFP-PLEKHG3 overexpression. LAMP1 enrichment in FAs is also not obvious in the image shown in Figure 4B. - In Fig. 2B, there appears to be a labeling error. The lanes 2,4 and 7 appear to be transfected with L3-T-V5 but labeled as GFP-V5-cyto. Here the PLEKHG3 band should be indicated. - Fig. 2C is an IP experiment as per the manuscript text but it is labeled as pulldown.

      Significance

      Using a TurboID proximity-dependent labelling screen, the authors identified an interesting subset of actin-remodeling proteins that interact with the lysosomal protein LAMTOR3. The authors further characterized one of these proteins, PLEKGH3, and found that lysosome positioning regulates PLEKGH3 localization, as well as plasma membrane protrusion formation and cell motility. This study suggests that lysosome peripheral accumulation could regulate cortical actin remodelling and consequently cell migration by regulating PLEKGH3 localization (although this is not tested in the manuscript). This study adds to the previous findings that microtubule-based transport of late endosomes regulate delivery of late endosomal LAMTOR proteins to the vicinity of focal adhesions, which in turn, regulate focal adhesion dynamics. The mechanism of how lysosomes can influence actin remodeling will be important in the context of cancer cell migration. My area of expertise is lysosome fusion and motility and I have limited expertise in regulation of actin dynamics and how Rho family members regulate actin remodeling.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      In this manuscript, the authors investigate the role of Transcription Termination Factor 2 (TTF2) in the regulation of mitotic transcription. Using siRNA-mediated knockdown in two distinct human cell types combined with nascent RNA labeling (EU pulse), the authors identify an unexpected role for TTF2 in the timing of RNA Polymerase I (Pol I) reactivation following mitosis. The study suggests that this temporal misregulation may have downstream consequences for nucleolar morphology and function in interphase. The manuscript is well-written, and the figures are of high quality and clearly presented.

      Major comments:

      1. A primary limitation of the current study is that it does not deeply explore the underlying mechanism of the observed phenomenon. To strengthen the claims, the following points should be addressed:

      1a. Directionality of Phenotype: In Page 9, the authors conclude that TTF2 depletion is linked to abnormal nucleolar organization during interphase. It remains unclear if this is a direct result of mitotic misregulation or an independent interphase effect. To distinguish between these possibilities, I suggest the following experiment: perform a mitotic shake-off early in the siRNA treatment (~24h), collect mitotic cells, and allow them to re-enter G1 to image for nascent RNAs and nucleolin. This would clarify if the mitotic defect precedes and causes the interphase morphology changes. Alternatively, the authors should state that their current study cannot distinguish between these two possibilities.

      1b. Secondary Effects: The long duration of siRNA treatment (48h) raises the possibility that TTF2 knockdown misregulates the expression of other Pol I regulatory factors, leading to secondary effects. This limitation should be explicitly acknowledged in the Discussion. 2. The term "significant" is used throughout the manuscript without accompanying statistical testing.

      2a. Please provide statistical analyses (e.g., p-values) for the average plots in Figures 1-3 to substantiate the findings.

      2b. Where statistics are not performed, the language should be softened to "notable" or "observed increase" rather than "significant." 3. siRNA knockdowns are generally supported by quantification. Please provide the percentage reduction of the target protein by quantifying the blots provided in the supplemental figures. 4. To rule out the possibility that the increased nucleolin signal observed after TTF2 KD is simply due to higher protein abundance, the authors should perform a western blot to confirm that total nucleolin protein levels remain unchanged upon TTF2 depletion.

      Minor comments:

      1. The abstract and discussion refer to the role of TTF2 as a "conserved" process. As the study only tested human cell lines, "conserved" is technically inaccurate (as it implies evolutionary comparison). I recommend using "general" or "cell-type independent."
      2. While the Methods section is detailed, the Results section would benefit from brief descriptions of the treatments to improve flow.

      Example revision (Page 4): "...we treated two distinct cell lines with control and TTF2-specific siRNAs for 48 hours, followed by a 30-minute EU pulse to label nascent RNAs. Click chemistry and Hoechst labeling enabled 2-color imaging of mitotic chromosomes and nascent RNA..." 3. The data generally agree across both cell types; however, the presence of clustered signals in HeLa metaphase chromosomes is a notable divergence. It would be beneficial to include speculation in the Discussion on whether this represents a failure to silence Pol I transcription or an even earlier reactivation, and what this implies about a cancer cell line.

      Significance

      General assessment:

      The study is strong in its use of two different cell systems, providing confidence that the observed effects are not cell-line-specific. The figures are beautifully presented and the writing is clear. The primary limitation is the lack of mechanistic depth regarding how TTF2 specifically interfaces with the Pol I machinery compared to its known roles with Pol II.

      Advance:

      This work reports a previously unrecognized role for TTF2 in the temporal control of Pol I reactivation. While TTF2 is well-known for its role in terminating transcription and facilitating Pol II release during mitosis, its specific influence on the nucleolar transcription cycle provides a new perspective on how cells transition out of the mitotic state.

      Audience:

      This research will be of interest to researchers in the fields of gene regulation, the cell cycle, and nucleolar biology. Because it touches on the fundamental process of how transcriptional machinery is reset after cell division, it has implications for the broader basic research community interested in epigenetic memory and cellular identity.

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      Referee #1

      Evidence, reproducibility and clarity

      In this paper by the Oliveira lab a new perspective on TTF2 function during mitosis is proposed. Known for its role to terminate transcription at mitotic onset, this paper further shows an exciting involvement of TTF2 to schedule timely rDNA transcription at mitotic exit. Moreover, this role is shown to have a clear importance in the structuration of nucleoli, since TTF2 depletion is associated with premature partial assembly of nucleoli on the mitotic chromosomes and, subsequently, to fragmented nucleoli in interphase. These conclusions, which are well supported by imaging data, are original, interesting and, in fact, largely unexpected.

      The paper is very simple in its execution, based on siRNA depletion of TTF2 and monitoring of transcription by imaging using EU incorporation and rRNA-FISH, as well as nucleoli morphology and dynamics using immunostainings. Yet, it is well executed and has no major caveats. However, the authors should consider the following:

      1. The Teves lab has shown that TBP is a key factor maintaining its binding at rDNA loci during mitosis, enabling a prompt reactivation of rRNA production in interphase (Kwan et al. RNA 2024). This paper should be discussed on the light of current findings.
      2. In relation to the previous comment, I would strongly recommend the authors to analyse TBP-depleted cells, ideally using the line generated in the Teves lab, to address whether delayed rDNA transcription after mitosis leads to delayed nucleoli structuration. This assay would allow them to further confirm their model.
      3. In addition, it would be important to test if in the absence of mitotic TBP, the depletion of TTF2 does also lead to mitotic transcription.

      Significance

      Strengths: originality of the observation and simplicity of the experimental setup

      Limitations: exclusively based on imaging data

      Advance: completely unanticipated observation

      Audience: general readers interested in gene regulation

      My expertise: gene regulation through mitosis

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      Reply to the reviewers

      Manuscript number: RC-2026-03407

      Corresponding author(s): Laura Cantini, Julio Saez-Rodriguez

      [The "revision plan" should delineate the revisions that authors intend to carry out in response to the points raised by the referees. It also provides the authors with the opportunity to explain their view of the paper and of the referee reports.

      • *

      The document is important for the editors of affiliate journals when they make a first decision on the transferred manuscript. It will also be useful to readers of the reprint and help them to obtain a balanced view of the paper.

      • *

      If you wish to submit a full revision, please use our "Full Revision" template. It is important to use the appropriate template to clearly inform the editors of your intentions.]

      1. General Statements [optional]

      This section is optional. Insert here any general statements you wish to make about the goal of the study or about the reviews.

      We thank both reviewers for their thorough and constructive evaluation of our manuscript.

      Reviewer 1 highlighted that the manuscript would benefit from 1) a stronger positioning of ReCoN within the existing literature on multicellular modelling and network exploration, 2) a justification of our methodological choices, including the use of Random Walk with Restart (RWR), 3) the choice of input datasets for GRN inference and an assessment of the robustness of ReCoN's predictions to noise in these networks, 4) a more systematic exploration of ReCoN's parameter space (restart probability, layer transition probabilities, filtering thresholds).

      Reviewer 2 raised concerns about 1) the generalisability of the α parameter value (by default, 0.8) across independent datasets, 2) the expected contribution of the indirect effect in prediction performances, 3) the robustness of GRN across datasets and systems, and 4) the need for more quantitative validation in the spatial/microenvironment showcase. They also pointed out an unsupported claim regarding gene knockout prediction in the abstract.

      Several clarifications on figures, methods, and writing were also requested by both reviewers.

      As the main addition to the manuscript, we propose a new showcase based on the recently published Human Cytokine Dictionary (Oesinghaus et al., 2025). This showcase will simultaneously address several reviewer concerns by allowing us to 1) test the robustness and performance of α = 0.8 in an independent dataset, 2) evaluate the impact of different GRN inference methods (HuMMuS, SCENIC+, CellOracle, GRNBoost2) and noise on ReCoN's predictions..

      We will conduct a systematic parameter exploration on the Heart Atlas showcase, covering restart probability and inter-layer transition probabilities. We will additionally strengthen the validation of the microenvironment showcase by providing additional comparison to matched single-cell fibroblast data.

      Regarding the manuscript, we will substantially expand the discussion to better contextualise ReCoN within existing multicellular modelling approaches and the methods to justify our methodological choices (RWR/MultiXrank, dataset selection). We will remove the unsupported gene knockout claim from the abstract and reframe it as a future direction. In addition, we will clarify the distinction between ReCoN variants and rename them for clarity in the results section 1.2., improve figure legends. Finally, we will also work on the tool's documentation, including new tutorials on using spatial data and on running ReCoN with scRNA-seq-only GRN inference.

      We believe these revisions will substantially strengthen the manuscript and address the reviewers' concerns regarding method's robustness, generalisation, and contextualisation.

      2. Description of the planned revisions

      Reviewers' comments are in blue

      Authors' answers are in black

      Proposed text modifications are in green

      Reviewer #1

      R1.1. This is a very well-written paper; the methods used are adequate, and the use cases are relevant and broad, exploiting state-of-the-art datasets and tools.

      The author's claims are mostly justified. The authors could make an effort to more explicitly cite other efforts in similar directions. The claim 'We envision ReCoN as an extension to prior multicellular modelling, offering an interesting compromise between prediction of cell type responses and understanding of their molecular coordination.' is very general and could be better substantiated. In fact, the authors do not really give examples of alternative approaches to study systems of interacting cells, other than mechanistic agent-based models, which are clearly very different.

      Response:

      We thank the reviewer for pointing out the lack of contextualisation for ReCoN in this closing discussion.

      We wanted to remind that ReCoN builds notably on multicellular factor decomposition methods. We also want to emphasise the interest in completing cell communication methods that describe the big picture in multicellular interactions.

      • *

      We proposed to *explicitly state these two points with such rephrasing: *

      • *

      Network-based representations of multicellular systems have been an active field for many years, from early conceptual cytokine networks (Frankenstein, Alon, and Cohen 2006) to curated ligand-receptor cascades of hematopoietic tissue (Kirouac et al. 2010, Qiao et al. 2014). In parallel, and from bulk RNA-seq, the consideration of tissue specificities in GRN inference has been another way to consider the importance of the context in molecular mechanisms reconstruction (Sonawane et al. 2017). Single-cell analysis allowed decomposing tissue composition and quantifying gene expression, opening the possibility of scaling the inference of these networks and the inference of multicellular mechanisms in general, to large sets of molecules. Several methods have been developed to recover multicellularity. A first direction extends ligand-receptor interaction inference into the receiver cell response through curated signalling cascades, yielding ligand to target cascades (Browaeys, Saelens, and Saeys 2020, Jin et al. 2021, Zhang et al. 2021, Yan et al. 2025). A second direction leverages spatial context through explainable multi-view models that decompose marker variation in both intra- and intercellular contributions (Arnol et al. 2019, Tanevski et al. 2022), without considering the mediating cascades. Finally, the more recent family of multicellular factor decomposition methods focuses on the coordinated aspect of cellular programs rather than on the mechanisms. ReCoN's methodology proposes a network-based approach based on single-cell data and the philosophy of this last group of methods. Indeed, ReCoN aims to retrieve links between molecular drivers and such coordinated multicellular programs by bridging and exploring CCC inference and GRN modelling (Badia-i-Mompel et al. 2023) within large and coherent heterogeneous multilayer network.

      Arnol D, Schapiro D, Bodenmiller B et al. Modeling Cell-Cell Interactions from Spatial Molecular Data with Spatial Variance Component Analysis. Cell Rep 2019;29(1):202-211.e6. https://doi.org/10.1016/j.celrep.2019.08.077.

      Badia-i-Mompel P, Casals-Franch R, Wessels L et al. Comparison and evaluation of methods to infer gene regulatory networks from multimodal single-cell data. Preprint, bioRxiv, 21 Dec. 2024, 2024.12.20.629764. https://doi.org/10.1101/2024.12.20.629764.

      Badia-i-Mompel P, Wessels L, Müller-Dott S et al. Gene regulatory network inference in the era of single-cell multi-omics. Nat Rev Genet 2023;24(11):739-54. https://doi.org/10.1038/s41576-023-00618-5.

      Browaeys R, Saelens W, Saeys Y. NicheNet: modeling intercellular communication by linking ligands to target genes. Nat Methods 2020;17(2):159-62. https://doi.org/10.1038/s41592-019-0667-5.

      Frankenstein Z, Alon U, Cohen IR. The immune-body cytokine network defines a social architecture of cell interactions. Biol Direct 2006;1(1):32. https://doi.org/10.1186/1745-6150-1-32.

      Jin S, Guerrero-Juarez CF, Zhang L et al. Inference and analysis of cell-cell communication using CellChat. Nat Commun 2021;12(1):1088. https://doi.org/10.1038/s41467-021-21246-9.

      Kirouac DC, Ito C, Csaszar E et al. Dynamic interaction networks in a hierarchically organized tissue. Mol Syst Biol 2010;6(1):MSB201071. https://doi.org/10.1038/msb.2010.71.

      Oesinghaus L, Becker S, Vornholz L et al. A single-cell cytokine dictionary of human peripheral blood. Preprint, bioRxiv, 15 Dec. 2025, 2025.12.12.693897. https://doi.org/10.64898/2025.12.12.693897.

      Qiao W, Wang W, Laurenti E et al. Intercellular network structure and regulatory motifs in the human hematopoietic system. Mol Syst Biol 2014;10(7):MSB145141. https://doi.org/10.15252/msb.20145141.

      Radig J, Droit R, Doncevic D et al. Tracking biological hallucinations in single-cell perturbation predictions using scArchon, a comprehensive benchmarking platform. Preprint, bioRxiv, 27 June 2025, 2025.06.23.661046. https://doi.org/10.1101/2025.06.23.661046.

      Sonawane AR, Platig J, Fagny M et al. Understanding Tissue-Specific Gene Regulation. Cell Rep 2017;21(4):1077-88. https://doi.org/10.1016/j.celrep.2017.10.001.

      Tanevski J, Flores ROR, Gabor A et al. Explainable multiview framework for dissecting spatial relationships from highly multiplexed data. Genome Biol 2022;23(1):97. https://doi.org/10.1186/s13059-022-02663-5.

      Yan L, Cheng J, Nie Q et al. Dissecting multilayer cell-cell communications with signaling feedback loops from spatial transcriptomics data. Genome Res published online 12 May 2025. https://doi.org/10.1101/gr.279857.124.

      Zhang Y, Liu T, Hu X et al. CellCall: integrating paired ligand-receptor and transcription factor activities for cell-cell communication. Nucleic Acids Res 2021;49(15):8520-34. https://doi.org/10.1093/nar/gkab638.

      R1.2. Moreover, the exploration of the multilayer networks with RWR is a very reasonable choice but could there be other approaches? I think the authors could discuss this issue to briefly support their choice of this method.

      Response:

      It is a very relevant comment, as this choice has not been discussed in the paper; we propose extending the method section about ReCoN's networks exploration with a justification about this choice.

      • *

      There is currently a limited set of network exploration methods that have been implemented for multilayer networks. It includes notably pymnet (Nurmi et al., 2024), natively adapted to heterogenous multilayer networks, and multinet (Bagavathi et al., 2019) and muxviz (De Domenico et al., 2015), initially developed for multiplexed networks (e.g. social network where the same set of nodes is present in each layer) but adaptable to more complex multilayer networks. However, to our knowledge, only MultiXrank proposes a robust measurement of proximity between each pair of nodes.

      Indeed, pymnet does not propose implementation for pairwise distance, similarly for muxViz, which focuses on community and motif detection. Multi-net does propose pairwise distance based on shortest paths, but implements it only for nodes of the same multiplex (e.g. in our network, it would only be two genes, or two receptors, respectively). https://www.rdocumentation.org/packages/multinet/versions/4.3.2/topics/multinet.distance

      • *

      We provide the additional justification for choosing RWR and MultiXrank over a reimplementation of another method or an extension of another method.

      • *

      • The total complexity of the RWR is O(δm) - when the number of nodes is negligible compared to the number of edges, with m the number of edges and δ the number of iterations in the walk (Baptista et al., 2022 - Supp Notes 2.A; Jin W. et al, 2019). This linear increase with the number of edges is particularly interesting for large networks, such as ReCoN ones that can contain several million* edges. The number of iteration δ and the computational time increases inversely to the restart probability, which is an important factor to keep this probability high. *

      • *

      • *MultiXrank is particularly interesting for its flexibility as it allows to easily attribute different weights to the different layers and to precise the direction of the exploration easily. *

      • *

      • It also produces deterministic results by prolonging exploration until convergence.

      • *

      • Additionally, in the context of ReCoN, the indirect effect of each cell is run independently. We previously extended the implementation of multiXrank for running RWR in parallel in a previous work (Trimbour et al., 2024), making it already adapted for optimising ReCoN's explorations.

      • *

      For all these reasons MultiXRank implementation seemed to be the best choice for robust and efficient exploration of ReCoN's HMLN.

      • *

      Bagavathi, A., Krishnan, S. (2019). Multi-Net: A Scalable Multiplex Network Embedding Framework. In: Aiello, L., Cherifi, C., Cherifi, H., Lambiotte, R., Lió, P., Rocha, L. (eds) Complex Networks and Their Applications VII. COMPLEX NETWORKS 2018. Studies in Computational Intelligence, vol 813. Springer, Cham. https://doi.org/10.1007/978-3-030-05414-4_10

      Manlio De Domenico, Mason A. Porter, Alex Arenas, MuxViz: a tool for multilayer analysis and visualization of networks, Journal of Complex Networks, Volume 3, Issue 2, June 2015, Pages 159-176, https://doi.org/10.1093/comnet/cnu038

      Nurmi et al., (2024). pymnet: A Python Library for Multilayer Networks. Journal of Open Source Software, 9(99), 6930, https://doi.org/10.21105/joss.06930

      Jin, Woojeong, Jinhong Jung, and U. Kang. "Supervised and extended restart in random walks for ranking and link prediction in networks." PloS one 14.3 (2019): e0213857

      R1.3. Generally the discussion should provide the reader the context in the existing literature in which the work can be set, detailing its impact. I think this could be improved.

      Response:

      • *

      We hope that the correction on the context proposed for comment R1.1 offers a first clarification on the context in the literature.

      • *

      We also propose to extend the description of ReCoN's impact with the following sentences in the discussion: "Unlike purely data-driven approaches, ReCoN contextualizes prior knowledge balancing both robustness through literature data, and specificity through new measurements. This mechanistic approach opens new possibilities for understanding how cellular coordination shapes tissue-level responses and for designing targeted molecular interventions."

      • *

      R1.4. Regarding the choice of datasets, it is clear that the method is quite demanding, requiring single cell and different omics to build the model, in addition to the expression dataset that is used as a use case. This inevitably leads to using a mix of datasets.

      For example in the mouse experiments the gene regulatory network was inferred from both a lymph node scRNA-seq dataset and a splenic scATAC-seq dataset, presumably due to the lack of multiome data in this setting. However the cell-cell communication network was inferred from the control case of the Immune Dictionary. Why can't the authors use the control data also for inferring GRNs?

      Is atac-seq really necessary in the inference of the GRN? What is the impact of the fact that lymph node and spleen samples might be different?

      :

      • *

      Is it a very *interesting comment, and we propose to add both 1) an explanation about our dataset choice to generate the GRN as a Supplementary text, and 2) a new experiment about the effect of GRNs built from multi-omics and scRNA-seq alone. *

      • *

      • Dataset choice

      • *

      We decided to infer a GRN using multiomics data, as these methods seem to perform better and are becoming the state of the art (Badia-i-Mompel et al. 2023, Trimbour, Deutschmann, and Cantini 2024, Yuan and Duren 2025).

      As scATAC-seq data was not produced for the Mouse Immune dictionary, we tried to find an external dataset, used HuMMuS, the method we previously developed, as it is also based on RWR and performs well on unpaired data.

      • *

      scATAC-seq

      Our first criteria was to match the mouse model used in the immune dictionary dataset, which reduced importantly the number of multicellular immune cell datasets available. We extended our research to a splenic dataset, as spleen is itself classified as a high specialised lymphatic structure, (check) and contains notably the same cell types than classical lymph nodes.

      • *

      scRNA-seq

      While we could technically use the control mice of the Immune Dictionary single-cel RNA-seq data with the spleen scATAC-seq data, the Immune Dictionary only provides 100 or less cells for each cell types per stimulation, which would results in a low number of cells. As GRN quality seems to depend a lot on the number of cell used, we favoured choosing a larger dataset.

      • *

      Our choice to use single-cell multiomics methods was driven by the novelty of these methods over scRNA-seq based ones, the performance improvement that they seemed to offer in several benchmarkings, and the will of developing a pipeline integrating the most complete data available for contextualization (Badia-i-Mompel et al. 2024).

      • *

      • GRN impact over the Human Immune Dictionary

      • *

      While it does not relate directly to this showcase, we will also add a new dataset analysis, detailed in the the comment R1.12. In the Human Cytokine Dictionary showcase,, we propose exploring the effect of choosing different GRNs, built from external multi-omics data or from the control scRNA-seq data of the dataset itself. We hope it can partially help users to decide in general wether to use external datasets of higher quality or sample-specific datasets.

      • *

      Finally, we propose to add in the documentation of the tool, a section showing how to use ReCoN with only scRNA-seq for the GRN inference, and the performance of different GRNs for the Human Cytokine Dictionary dataset directly in the paper.

      • *

      R1.5. The code is very clear, we were able to install and run it and it is quite well-documented. However, a few more details should be given in the text regarding how the evaluation of the performance is carried out.

      For example: If I understand correctly, when predicting the impact of cytokine perturbations the ReCoN predictions of genes impacted are compared to differentially expressed genes identified through traditional DEG analysis. What is compared is the ranking of these genes from ReCoN with the ranking provided by DEseq2. There is no description of how this comparison of ranking gives rise to AUROC values. Also, is it just the ranking that is predicted or can they also estimate how well they can predict the effect size?

      Response:

      • *

      We are thankful for pointing out the unclear technical details. DEG results were binarised, to obtain the list of differentially genes using the thresholds indicated in the section 4.4.4. We considered a gene as perturbed in each cytokine treatment if the comparison of control and treated cells had a t-test p-value below 0.1 and if the log-fold change was above 1.

      • *

      The second, and more general point of the reviewers, ReCoN scores should be considered to provide ranking on the possible regulations, but cannot be considered proportional to the effect size. As they are represent a likelihood more than a score, the binarisation should be the most appropriate transformation for the validation

      • *

      *Moreover, as the scores can be seen as the probability to end up the exploration on each node, they are always summing to one. This also prevents interpreting the scores as the amplitude of change. As an illustration example: if a receptor regulates three genes identically, they would (hopefully) all be having a score of (1 - R)/3, R being the restart probability in ReCoN, whether their expression doubles or is multiplied by 10. *

      • *

      While it can legitimately be seen as a downside, we believe it is similar in practice to most methods inferring GRN methods in practice, where trying to predict the true amplitude of gene perturbations usually results in very low performances (Badia-i-Mompel et al. 2024).

      • *

      We propose changes related to this comment.

      • *

      • We would modify the section 4.4.4. of the method with the following paragraph to explicit that it consists in a binary selection: "For each cytokine-cell type pair, differentially expressed genes were binarised: genes passing the significance thresholds (FDR P-val 1) were labelled as positives, and all remaining genes as negatives. ReCoN scores were then used to rank all genes, and AUROC values were computed from this ranking against the binary labels."

      • *

      • We will also include a section "ReCoN scores interpretation" on the documentation website, as score interpretation precisions will be particularly useful for users.

        R1.6. When describing the use cases, I think a bit more detail would help.

      For example 'To identify the cell-type-specific genes associated with HF, we used the MOFAcell scores of the multicellular factor 1 (MCP1) reported in ReHeat236' I supposed the explanation is on the dataset but for the sake of clarity it would be good to expand this sentence to give at least an idea of the approach.

      Response:

      • *

      We completely agree that more explanations should be provided, to avoid for the reader having to switching between articles to understand the concepts behind this showcase. As suggested by the reviewer, we propose a general description of the approach with the short paragraph, and to remove the term "loading":

      • *

      "In the ReHeat2 study, the first multicellular factor (MCP1) was associated with heart failure. We used the gene loadings of MCP1 as a proxy for the cell-type-specific transcriptomic changes associated with heart failure, ranking genes by their absolute loading values."

      • *

      We also propose to complete the method section: "MOFAcell is a multicellular factor analysis method that decomposes multi-sample single-cell data into latent factors representing coordinated gene expression patterns across cell types. Each factor is characterised by cell-type-specific gene scores, reflecting their individual contribution to the coordinated program. In this showcase, we use the first multicellular program (MCP1), as it was associated with heart failure"

      R1.7. Regarding the calculation of the R matrix from the NichNet matrices L and G, I gather that the R matrix is calculated once and is thus fully data-independent and available just like the L and G matrices from NichNet. This was not very clear in the tutorials.

      Response:

      • *

      We are very thankful for the reviewers' involvement in testing the tools itself and its documentation. First, we propose a new website page explaining the pre-computed resources available for receptor - gene links, and added a descriptive paragraph in the tutorial themselves.

      *Second, we notice a typo in the equation, where it should actually be L = R * G with the current definition. We corrected it in the next version, and precised that R is fully data independent and solely inferred from prior knowledge. *

      R1.8. Also, this might just be a typo in the tutorial: 'The default α = 0.8 gives more weight to direct effects, which has been empirically validated. You can adjust this based on your biological question." I believe the manuscript says alpha>0.5 refers to indirect effects dominating.

      Response:

      • *

      We corrected the saying in the tutorials. Indeed, a high alpha represents a stronger indirect effect. Additionally, a similar typo was in the first equation of the paper, we are correcting it too.

      R1.9. Same for the pre-processing of the spatial data for the third use case, a little more details on how this was done would help the users and readers.

      Response:

      • *

      We propose adding a specific section about the spatial pre-processing and analysis in the methods.

      We are also adding a tutorial on spatial data. Since spatial data processing is computationally intensive without GPUs, we will also provide the data already processed, in order to allow anyone to test this tutorial too.

      • *

      R1.10. I don't see issues with the statistical power of the analysis.

      Rather, I think the authors should provide some examination of the parameter space for their model. Whereas ana analysis of the impact of the Alpha parameter is provided, I believe there are several more parameters that have a crucial impact and choices for their values should be discussed.

      For example 'In the GRN reconstruction only the links with a score above 1.5e-7 were retained in ReCoN's gene regulatory layer. How was this chosen?

      We have identified the following parameters that are somehow justified but could be explored to have a better feel for how they impact the results

      Restart probability: How often the walker goes back to the starting seed/molecule

      Layer transition probability: How often the walker stays in the same layer - different cell? - different layers? Gamma

      Node transition within a layer: How often one jumps to a different layer

      Response:

      This is a very valid point raised by the reviewer about parameters explorations.

      • *

      We focused on exploring the alpha (direct/indirect effect) parameter, as its value was the incertitude when designing the model.

      • *

      We would like to address this comment by adding new explorations for the restart probability and the transition probability between layers. The probability to transition between specific nodes inside a layer directly depends itself on 1) the restart probability, 2) the transition probabilities, and 3) the weights of the edges, that are determined before and independently to ReCoN's exploration.

      • *

      The Heart Atlas showcase allows to evaluate each set of parameters in around 10 min instead of 10h for the Immune Dictionary. We thus propose to evaluate restart probability and layer transition probabilities on the data of this showcase.

      • *

      • We would explore the restart probability of 0.1 * N, with N between 1 and 9.

      • *

      • For transitions probabilities we propose varying GRN, receptor, and cell communication importance with the following configurations: - Staying in CCC probabilities (- not jumping to receptor layer) among (0.1, 0.3, 0.5, 0.7, 0.9), staying in receptor layer (- not jumping to GRN) of (0.25, 0.5, 0.75), staying in GRN layer (- not jumping to CCC) of (0.25, 0.5, 0.75). It would result in 9 intracellular variations combined with 5 intercellular variations.

      • *

      We envision an evaluation by measuring the correlation between the results of the different configurations, and the time before convergence of the results, as it could potentially increase drastically when decreasing the restart probability. If correlations below 0.9 are observed between some results, we will compare their absolute performances.

      • *

      We would include the figures related to these explorations in the supplementary data. We would highlight the main findings in the method section dedicated to the random walk with restart. Finally, we would briefly describe the parameter exploration design in the first section of the results, for curious readers who would like to verify parameter choice before reading the showcases.

      • *

      R1.11. Weighting parameters: How much weight for direct or indirect effect to account for the combined effect - alpha - this is the only one that is explicitly explored.

      Response:

      We are very thankful for this comment, and we decided to modify our tutorial guidelines to make this choice more intuitive and general.

      • *

      Indeed, 1.5e-7 would hardly make sense for most methods, which would not produce such low scores. We now propose to select the first 2 million connections of GRNs, in order to keep a complete or a large portion of the network if other methods than HuMMuS are applied.

      • *

      In our case, 1.5e-7 was empirically determined from the distribution of HuMMuS scores, to keep the 2 million top connections as HuMMuS networks are generally almost fully connected, which is a particularity for classical GRN inference methods, and keeping it entirely would make exploration time much longer.

      • *

      R1.12. Finally, this might be considered OPTIONAL but would greatly improve the work in our opinion:

      The method crucially depends on the networks that are used in the different layers and to connect layers and cell types. As we know, biological data is noisy and incomplete (FP and FN) at each level and in each datatype. It would be really useful to estimate what is the robustness of the results to this noise. Particularly, from personal experience, we think the GRNs reconstructed from data are often almost fully connected and it is exceedingly difficult to validate them in specific contexts. This means that some 'errors' are likely to be present.

      Since several methods exist for inferring GRNs one could simply compare the results using different methods for this part of the network.

      A related point involves the characteristics of the RWR algorithm, that will be quite impacted by the presence of hubs in these networks (either in single layers or across several) that is likely to impact the exploration. If proteins that are hub are effectively important, that is not a problem, but in some layers, for example, the receptor-receptor layer that presumably will contain PPIs, there might be biases in hubs being just better studied proteins, and these hubs might have an 'unjustified' weight in the walks.

      One potential approach to assess the robustness of the method to these issues could be an empirical one that just randomly perturbs the networks in ReCoN to see to what extent similar predictions are achieved.

      *Response: *

      • *

      We are thankful for this relevant comment on GRN and prediction stability, and would like to take it as an opportunity to support the hypothesis that different GRN methods can be used in ReCoN.

      • *

      When developing our previous HMLN-based tool, HuMMuS (Trimbour et al. 2024 - Supp Figure 6), we observed that its multilayer structure provided more robust results than individual layers. We would like to reproduce such an analysis, verifying that ReCoN results have less variability than the GRN layers individually.

      We propose to integrate a new showcase on the Human Cytokine Dictionary (Oesinghaus et al. 2025), trying to predict cytokine downstream effects similarly to the Mouse Immune Dictionary showcase.

      This showcase would be useful to confirm the contribution of the indirect effect and test the impact of different GRN on the results.

      We would generate different GRN with several other GRNs methods: SCENIC+, CellOracle, and GRNBoost2 - the latest using only the scRNA-seq of the control samples in the Human Cytokine Dictionary.

      • *

      The GRN methods produce generally output with very low overlap (Badia-i-Mompel et al. 2024)*. *

      *If we observe high correlations between the ReCoN predictions associated with the different GRNS, it would provide already a validation of ReCoN's robustness to GRN noise. *

      If lower correlations between ReCoN's predictions are obtained, we will add a specific permutation experience over the HuMMuS GRN, creating different level of artificial noise and assessing more precisely the robustness of ReCoN to GRN stochasticity.

      • *

      Regarding PPI hub justification, our *applications did not use receptor PPI and are not affected by bias at this level in the showcases. This bias could specifically be present in the receptor-gene links, as we derive it from the ligand-gene connections of Nichenet which was itself partially based on prior knowledge. It is thus possible that some receptor are reached more often due to this bias and not a stronger effect. It seems however, hard to control in this context, as ReCoN currently relies on this prior knowledge. Currently, we hope that the combination of personalised, literature-agnostic GRN with literature-based receptor - gene can provide an interesting trade-off. In future development, we could imagine a receptor-gene network based solely on perturbations, but it would require controlling also the bias of ligand - receptor binding couples, which limits even the use of ligand-based experience. *

      We propose adding a short point in the discussion about hub effects from RWR-based methods.

      • *

      R1.13. Please add page numbers.

      *Response: *

      • *

      We will add the page numbers.

      • *

      R1.14. Figures are nice and clear.

      Some specific minor points are listed here below.

      Define hMLN on first appearance fig1 caption (no page numbers..

      2nd appearance heterogeneous multilayer structure (HMLN) ...

      Response:

      • *

      We updated the legend of the figure to include the definition of the acronym, as it arrives before first text occurrence. (Or define at both positions ?)

      R1.15. Bi_j not so clear to what it refers when first mentioned

      Response:

      • *

      *Bi_j represents a weight that can be attributed to favour some cell-to-cell transitions. It is usually not necessary to use them.

      *

      *It is of interest notably to model 1) known spatial patterns in situ and hypothesis/design where cell types favour some connections. *

      • *

      E.g.: for modelling the skin, a user might notably want to increase connections between epidermic and dermic cells, and between dermic and hypodermic cells.

      • *

      We propose a new explanation of Bi_j to both explain it's meaning in the modelling, and illustrates situations for using it: "The coefficient B_{i,j} modulates the influence of cell type i on cell type j in the indirect effect computation. By default, all B_{i,j} are set to one, weighting each cell type's contribution equally per cell. However, it can be adjusted to encode additional biological knowledge, such as spatial proximity between cell types or known cooperation patterns. For instance, when modelling the skin, a user might increase B_{i,j} between epidermal and dermal cells, and between dermal and hypodermal cells, to reflect their spatial organisation."

      R1.16. personalized interaction specificity. - maybe better word than personalised (contextualised?)

      Response:

      • *

      We agree that contextualised explicits better the meaning behind this model. Personalised might notably lead to expect patient-specific data, which is not the case here.

      • *

      We propose to rephrase all the model names to : Receptor-matrix, ReCoN-no-CCC, ReCoN-no-context, ReCoN-complete.

      R1.17. ReCoN-genetic and ReCoN, ( generic?)

      Response:

      • *

      We will correct this typo.

      R1.18. responses. It is expected to observe common behaviors in-between cell-type, that the GRN

      and the generic CCC network already contribute captures.

      • not very clear

      Response:

      • *

      We aimed here to provide an explanation to the already good performance of the "ReCoN-no-context" (or its name updated according to comment R1.16), which could be surprising as no cell-type specific information is used. The explanation proposed is the good prediction of several properties shared by all immune cell types, such as similar metabolic pathways, despite their specific roles. If we adopt a quantitative view on their transcriptome like in this showcase, it can be expected that the cell type responses are relatively well predicted through the common properties only.

      • *

      As this is a very relevant comment, and that several comments pre-submission we received were also related to this result, we would like to keep an explanatory sentence.

      • *

      R1.19. Figure 2b the icon of cells with double arrows might suggest phenotype shift when instead this is just communication

      Response:

      (left side) We are very thankful for paying attention to the details of the paper and fully agree with this analysis. We propose to represent ligand emission instead of arrows, reusing the convention of the Figure 1.

      R1.20. eTACs explain acronym and what they are

      Response:

      • *

      We update the first occurrence of eTACS to extrathymic Aire-expressing cells (eTACS).

      R1.21. Due to very few genes being differentially

      expressed, only cDC1 was conserved and evaluated for IL22,

      Not so clear

      Response:

      • *

      As we are commenting on IL22 stimulation results, we reorganised the sentence to make it less convoluted: "For IL22 stimulation, only cDC1 presented enough genes being differentially expressed."

      R1.22. In this showcase (not very clear, use case?)

      Response:

      • *

      We perceive "use case" as describing a type of use for the method, while a show case is a specific example of a use case. We thus find showcase more appropriate here. We will however go over all use of the word, to be sure it is only used for the precise examples we provided, and not to describe "use cases".

      R1.23. different fibroblast specializations - maybe phenotypes?

      Response:

      • *

        • It is a very good suggestion, as specialisation would involve functional aspects (that we can't really be sure of), and a chronological evolution*
      • Phenotype generally includes numerous properties, such as morphology, that we cannot validate here. We think the use of phenotype might be stronger than specialisation here. To simplify, phenotype can work, to be more precise: transcriptomic specialisation? I am honestly not sure of the best change here.

      R1.24. Figure 4b

      1. b) Schematic view of the deconvolution process and cell type-specific count inference from the spatial niches.

      Not so clear what the heatmap shows, rows and columns

      Spots heatmap : label niche on rectangles in cols

      And each col is a spot

      Rows are cell types or cells?

      In the cell types x spot

      Response:

      This figure can indeed benefit strongly from legend modifications. On both matrix, lines represent the genes, while columns represent the spot / individual cells deconvoluted per spots

      • *

      • We would annotate the niche legend (here the colour surroundings) by a symbolic drawing instead of writing it on the matrix

      • *

      Legend "genes" on the first matrix

      • *

      Write deconvolution ON the figure directly

      R1.25. Cell2location. Add reference, maybe explain basic functionality?

      Response:

      • *

      Cell2location was not referenced in the results section, and was only referenced in the section 4.6.2 of the methods, as the 72th citation. We corrected this oversight, and propose 1) a brief explanation of deconvolution right before, 2) a brief explanation of Cell2location particularity in inferring individual cell profiles - which is not common in spatial deconvolution.

      R1.26. reconstructing different patients, tissues, and microenvironments to predict

      context-specific molecular treatments.

      Unclear

      fibrosis in different - at

      molecular levels

      Response:

      • *

      We will modify this section title according to the reviewer's citation and the different reformulation.

      R1.27. Figure 5d myeloid and endothelial colour code inversed from 5 BC

      Response:

      • *

      The legends are individually correct, but there is no reason to not make them coherent across panels. We will update the legend of the panel 5.d..

      • *

      R1.28. 5d indicate important pathways in organe should not change the colour of the nodes (purple=common, blue or green specific). Use border colour maybe?

      Response:

      • *

      We had forgotten to precise the colour code of this panel, where the choice of orange highlighted here the gene set related to molecular pathways instead of functional annotations. As the name already explicits pathway, we now think that the orange background is redundant informations and may create some confusion. We thus would like to update Wnt and TNFA pathways backgrounds to ___ (more enriched in cell type), and purple (significantly enriched in all cell types).

      R1.29. 5e is not a venn diagram

      1. e) Venn diagram showing the overlap between transcription factors (TFs) predicted by ReCoN (green) and those previously

      implicated in fibrosis (orange) or cardiac diseases (violet). Only the top 10 TFs were annotated from literature

      sources; full sizes of fibrosis- and cardiac disease-related receptor sets can therefore not be represented.

      1. f) also not a venn diagram e/f now in supp

      the "NABA ECM collagens" gene set. Nodes are

      grouped by molecular type (e.g., transcription factors, receptors, ligands), and links represent the weighted,

      direct regulatory interactions present in the ReCoN-constructed

      Response:

      • *

      As the diagrams do not indicate the total number of receptor/TF that are in the literature, it cannot be Venn diagrams. We updated the legend to :Venn diagram showing the Overlapp between [...]

      • *

      As we reorganised the paper, these plots are now only in supplementary; we removed the duplicate occurrence in the figure 5 legend.

      R1.30. Why Sankey plot? Normally sankey plot represents flow (of regions changing from 1 state to another) but here this is just a weighted network?

      No communication from firbos back to other cell types? No communication between ventricular/myeloid/lymphoid?

      Response:

      • *

      We are thankful for this useful feedback which helped us realising interesting details were missing from the paragraph.

      • *

      *This is only intended for visualising regulatory cascade, so users have to decide on one receiving cell, a set of target genes, and sending cells. It includes a specific subset of regulatory cells, and only their interactions with the target cells. Here, we illustrated the regulation of some ECM genes produced by fibroblast. *

      • *

      Sankey Diagram might indeed not be the clearest representation, as we are not modelling the all diffusion, and not a flow per se. We propose to replace by another representation that we hope will be more intuitive for biologists (and more aesthetic), such as illustrated below:

      R1.31. as a extension to - an

      underrepresented in the current. - current framework?

      Response:

      • *

      framework works perfectly to fill the missing word in the sentence

      • *

      R1.32. However, it can't represent more - cannot

      Borrowing representation from hypergraphs, which introduces

      The network exploration implementation of ReCoN also present some limitations.

      limitations. While random walks

      with restarts offer a stable and fast exploration workflow for multilayer networks, it

      currently only considers positive weights to predict regulation strengths. It involves that the

      nature of the regulation, as activation or inhibition, has to be identified a posteriori.

      • check concordance/grammar

      Response:

      • *

      We will update the raised grammatical errors

      • *

      R1.33. Only the nodes that are included in one of the layers are present in the

      final results, ignoring the ones present only in bipartites.

      Unclear

      Response:

      • *

      Layers and bipartites are treated differently by the algorithm, and layer presence is necessary to appear in the results.

      • *

      In practice, it just means that receptors/ligands not paired in the CCC, or genes not regulated by any TF in the GRN, won't appear.

      • *

      We propose clarifying with this second explanation

      • *

      "In practice, a node must have at least one connection in its layer to appear in the final results. It thus means that receptors or ligands absent from the CCC network and genes not targeted by any transcription factor in the GRN will not receive a score from the random walk exploration."

      • *

      R1.34. a scATAC - an

      • *

      Barsi et al is published https://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1013188

      Response:

      • *

      We updated the reference with the published article.

      R1.35. effects, allowing for modulating in a second

      time their contribution. - word order

      Response:

      • *

      We propose to formulate "allowing in a second time to modulate their contribution"

      R1.36. others. However, it is possible to adjust the Beta coefficient to

      represent it based on the available information for each dataset.

      Represent- adjust?

      Response:

      • *

      We agree with the reviewer's suggestion to use adjust.

      R1.37. We use the latter to compare the different models. - what is the latter?

      Response:

      • *

      The latter referred to the 25 cytokines of the Immune Dictionary which had at least one connection in the inferred cell communication network with CellPhoneDB. We propose clarifying this formulation to "..."

      R1.38. It resulted in the scRNA-seq in 1,789 cells with 13,167

      genes, and for the scATAC-seq in 3,759 cells with 254,545 regions.

      Check english

      Response:

      • *

      We propose replacing this sentence by the following: "It resulted in a scRNAseq dataset of 1,789 cells with 13,167 genes, and a scATACseq dataset of 3,759 cells with 254,545 regions."

      R1.39. GRETA pipeline.- reference

      Response:

      • *

      We added the citation to the paper of the GRETA pipeline in the section 4.5 of the methods: "Badia-i-Mompel et al., 2026"

      R1.40. We kept all the cells whose annotations through unsupervised clustering,

      followed by marker gene annotations, through scANVI were coherent.

      Word order

      Response:

      • *

      We propose the following reformulation to correct the sentence: "We kept all cells whose annotations were coherent between unsupervised clustering with marker-gene labelling and scANVI-based label transfer"

      R1.41. In parallel, pairs of ligands and receptors with both associated with scores above

      an absolute gene loading of 0.1 were considered potential driver interactions in HF.

      Unclear

      Response:

      • *

      In the MOFAcell results, factors correspond to linear combination of genes that explain a large part of the data variance; the contribution of each gene is called loading. We chose the factor that classified the best patient with and without fibrosis, and kept all the top genes, all of those with a score above 0.1.

      • *

      We propose reformulating this sentence as the word "loading" could overcomplicate here for most readers: "To identify the ligand and receptors driving heart failure, we considered all of those with an absolute contribution to the multicellular factor of 0.1."

      R1.42. gseapy Python - reference?

      Response:

      • *

      The gseapy package was indeed not cited, we now include the citation : "Zhuoqing Fang, Xinyuan Liu, Gary Peltz, GSEApy: a comprehensive package for performing gene set enrichment analysis in Python, Bioinformatics, 2022;, btac757, https://doi.org/10.1093/bioinformatics/btac757"

      R1.43. and to calculate average for each spatial context the average cell type expression.

      Unclear

      Response:

      • *

      we propose to reformulate the sentence to: "These cell-type-spot profiles were used later for each spatial context to create a specific cell-cell communication networks and to calculate cell type average expressions."

      R1.44. We only used the loadings of all cell

      types but the fibroblasts to consider the effect of the sole environment.

      Unclear

      Response:

      • *

      we propose to use "APART from the fibroblast" to clarify the sentence and "to ONLY consider the environment effect".

      R1.45. We realised a downstream - performed

      Response:

      • *

      We fully agree with the reviewer's suggestion.

      R1.46. The profiles inferred by ReCoN were first very correlated in all three contexts. - unclear

      Response:

      • *

      The sentence was missing clarity and deserved being rephrased. We propose: "When looking at the absolute scores of ReCoN in all three contexts, results were initially highly correlated. To focus on context-specific differences, enrichments were performed using the log-ratio of each context profile over the mean of the other profiles."

      • *

      R1.47. Potentially the closest results are models that can predict the effect of perturbations on cell line cultures. Several approaches in the literature employ either transformers or optimal transport to predict the effect of perturbations in single cell datasets. One of the main issues is an underlying necessary assumption that the perturbation effect will be larger than the heterogeneity (in cell lines for example), which becomes increasingly difficult when considering in-vivo experiments. ReCoN obviously goes beyond this by considering explicitly the presence of different cell types but distinctions of cell types are sometimes quite arbitrary and potentially application of ReCoN to some of the in-vitro culture datasets, even on cell lines, could be a way to test its performance and benchmark it against other methods.

      The main bottleneck in the application of this framework to 'personalisation' of therapies, mentioned even in the abstract as a potential future goal for such an approach, will be the lack of data. This approach requires single cell level descriptions of the system at hand, plus additional datasets to build the model structure. To a certain extent, public data of related tissues/contexts can be used, but it will be necessary to test the dependence of performance on coherence of the input data to develop sufficient trust to use it for new predictions, especially in a medical field.

      • *

      We thank the reviewer for these reflections, which raise several distinct points that we would like to add in the discussion.

      Cell line perturbation is indeed a close and active field of research, with notably numerous models based on optimal transport and VAE and relevant benchmarks(Radig et al. 2025)*. In our view, ReCoN tries to take a complementary angle, by both focusing on the environment effect and using a network-driven approach providing explainability. *

      These perturbation methods are typically benchmarked on single cell line screenings, where cell-cell communication is highly limited or absent by design, while ReCoN is specifically designed to exploit multiple cell types interactions. Furthermore, ReCoN relies on a network that aims to provide only explainable hypotheses and molecular cascades. They also typically learn from different data, as ReCoN only uses single-cell data and best perturbation prediction methods learn from a subset of perturbation experiments.

      Exploring the performance of ReCoN in perturbation predictions would require designing extensive comparisons with the state-of-the-art taking into account all these nuances which we believe goes outside of the scope of the present study. It however still raises a fundamental question for the development of the next methods and the need to assess whether the perturbation effect is actually larger than the heterogeneity, and we propose to extend the discussion to cover these aspects.

      Secondly, this comment raised a point about cell type definition, which can be a hard task and sometimes a wrong description of cells heterogeneity. We note that even if ReCoN relies on grouping cells in some way, it does not impose any particular cell type ontology: users can define their own cell types or cell states, since the CCC layer is typically inferred from single-cell RNA-seq alone and does not require canonical cell-type annotations. This flexibility allows ReCoN to accommodate finer or coarser groupings depending on the biological question. We do not propose a framework to take into account diversity in other ways than homogeneous clusters of cells, but we think that it constitutes an interesting future development of ReCoN or new multicellular modelling methods.

      Lastly, we fully agree that an important limitation for ReCoN's use is data availability and generation, which was also a limitation when identifying datasets for the manuscript's applications. We hope that the development of open source atlases will make it easier to leverage tissue-specific prior knowledge and increase potential application, prediction performances, and trust in ReCoN results.

      In conclusion, we propose to state in the discussion two new points:

      *1) extending multicellular perturbations (including gene knock-out) to conditions where cell types cannot be defined prior to the analysis, or are more to consider across a spectrum, will be an interesting future direction. *

      2) there is new a need for broad benchmarks covering both multicellular and single-cell line tasks to evaluate the trade-off between accounting for cell heterogeneity and overall prediction accuracy.

      Radig, J., Droit, R., Doncevic, D. et al. scArchon: a scalable benchmarking framework for assessing single-cell perturbation models. Genome Biol 27, 162 (2026). https://doi.org/10.1186/s13059-026-04104-z

      R1.48. The authors could comment on how their method compares to others that do not require single cell level information. Despite clear differences, it might be important to show the advantage of using this more complex approach that requires data that is less available. Given the ease with which bulk profiles can be constructed from single cell data, it might be possible to compare the approaches directly. For example, see

      1. Wang, S. Patkar, J.S. Lee, E.M. Gertz, W. Robinson, F. Schischlik, D.R. Crawford, A.A. Schäffer, E. Ruppin Deconvolving Clinically Relevant Cellular Immune Cross-talk from Bulk Gene Expression Using CODEFACS and LIRICS Stratifies Patients with Melanoma to Anti-PD-1 Therapy

      Mike van Santvoort, Óscar Lapuente-Santana, Maria Zopoglou, Constantin Zackl, Francesca Finotello, Pim van der Hoorn, Federica Eduati,

      Mathematically mapping the network of cells in the tumor microenvironment,

      Cell Reports Methods 2025

      We propose to extend the discussion with additional methods, notably from before single-cell technology developments. We did not plan to include this two specific methods, as to our knowledge, they don't provide output directly comparable to ReCoN's purpose.

      • The first work proposes to deconvolute the bulk RNA-seq profile into cell-type-specific expression profiles. It is an interesting reference, as it could allow applying ReCoN even to bulk RNA-seq, but they do not provide comparable results, as their final task corresponds to inferring the ligand-receptor interactions, without providing downstream molecular mechanisms.
      • The second method proposed in this paper, RaCInG builds cell-to-cell networks for individual patients. They do not explore the molecular interactions inside the cells themselves, which could be used to build personalised ReCoN's model but seem to be more a prior to recent CCC than ReCoN itself.
      • *

      • *

      Reviewer #2

      R2.1. It is not clear how well it performs in independent validations. Authors showed that it can predict the effect of cytokine perturbations in the immune dictionary by selecting an optimal alpha. Authors should validate that using the same alpha value of 0.8, it is possible to accurately predict the effect of cytokine perturbations in independent datasets. This is particularly concerning for cytokine-cell type pairs where the optimal alpha is not known. Therefore, the potential utility of Recon to estimate the effect of multicellular perturbations is not well established.

      • *

      Response:

      • *

      *The reviewers raised a very relevant point by pointing out that the alpha coefficient might vary between datasets. *

      • *

      The value of 0.8 was chosen because it produced the best results in two independent datasets, the immune dictionary and the heart failure showcases. We could here observe some cross-dictionary reproducibility. To complete these findings, we will also verify that 0.8 provides the best performance in a new showcase: the Human Cytokine Dictionary (Oesinghaus et al. 2025)

      • *

      We tried to contrast this choice by opening on the need to confirm the importance of the indirect effect. We propose to add a sentence explicitly commenting on the impact of these new findings on the alpha coefficient and its robustness value.

      • *

      It is also accurate to say that ReCoN cannot currently estimate the alpha parameter autonomously. We proposed this default value as it worked on both datasets, but it is possible that no default value could fit them all. The value of alpha is currently a default value, but users are completely free in the current implementation of ReCoN to modify its value depending on their needs

      If it was not the case, one option could be to fit its value using similar prior perturbations, when such data is available. For example, perturbing one or a few cytokines, a user could choose the value that explained the best the gene expression responses.

      • *

      R2.2. Authors claimed that optimal alpha value of 0.8 implies the dominance of indirect effect. But in contrast to this claim, the performance across cytokine-celltype pair only increased from 0.72 to 0.76, which seem to imply that indirect effects do not add much.

      *Response: *

      • *

      The range of performance improvement is an interesting point to discuss for us, as it roughly doubles the computational time and consequently a trade-off between resource usage and this improvement.

      • *

      While the average improvement from combining the direct and indirect effects observed on the first showcase was around 5%, it reached more than 10% in some cell types. We consider that it still corresponds to an interesting improvement for the current task. Indeed, it here "only" incorporates the coordination of immune cells to a cytokine stimulation, which should not necessarily change their profile drastically compared to isolated exposition.

      R2.3. How does the cell-type specific effects prediction perform by just considering the intracellular layers? The authors constructed multiple variants of ReCoN to estimate unicellular and multicellular effects. How is the variant ReCoN-grn different from full ReCoN where gamma is set to zero.

      *Response: *

      • *

      We are thankful for this comment, which will help to restructure the section 2.2.

      • *

      As the ReCoN-GRN differs from the full ReCoN model, even with a gamma value of 0, as the latest include ligand-to-receptor weights. However, the ReCoN-GRN would correspond to the ReCoN-generic with an alpha of 0, which does not weight ligand-to-receptor links.

      • *

      We propose to clarify this detail in the section 2.2.2 by adding after the introduction of the ReCoN-generic model the sentence: "Note that ReCoN-grn corresponds to the ReCoN-generic model with alpha set to zero, where no indirect effects are considered. It differs from the full ReCoN model with alpha set to zero, which still includes ligand-to-receptor weights through the receptor-gene bipartite network."

      R2.4. In section 2.2, authors assert that if matching datasets are not available, GRN layer can be extracted from other datasets. How well does the GRN layer from one system generalizes to the other system in terms of perturbation prediction?

      *Response: *

      • *

      It is, of course, a complex question, as it probably strongly depends on the studied system. However, we believe while it is important to consider similar systems, using the same samples for the cell-communication and the GRN layer is not necessary.

      • *

      The first showcase that we propose explores exactly this case. We built the GRN from two unpaired datasets, and the cell communication from a third one. It provided convincing performances, justifying our earlier claim. It is additionally something done in most methods contextualising prior knowledge, which usually comes from other samples and sometimes even other organs (Browaeys, Saelens, and Saeys 2020, Jin et al. 2021, Badia-i-Mompel et al. 2023).

      • *

      To provide additional insights, we will run the new Human Cytokine Dictionary showcase using both 1) multiomics methods on external PBMC datasets, and 2) a single-cell RNA-seq only method on the Human Dictionary directly. We will then be able to show performances using both data and corresponding methods.

      • *

      To justify more clearly our claim according to reviewer's comment, we propose highlighting in the showcase itself this justification: ".... this showcase highlights the possibility to combine networks obtained from distinct datasets...".

      Related to combining datasets, we propose to clarify the reasons behind our choices for the Immune Dictionary showcase with the additional supplementary text proposed in response to the comment R1.4.

      • *

      Badia-i-Mompel P, Wessels L, Müller-Dott S et al. Gene regulatory network inference in the era of single-cell multi-omics. Nat Rev Genet 2023;24(11):739-54. https://doi.org/10.1038/s41576-023-00618-5.

      Browaeys R, Saelens W, Saeys Y. NicheNet: modeling intercellular communication by linking ligands to target genes. Nat Methods 2020;17(2):159-62. https://doi.org/10.1038/s41592-019-0667-5.

      Jin S, Guerrero-Juarez CF, Zhang L et al. Inference and analysis of cell-cell communication using CellChat. Nat Commun 2021;12(1):1088. https://doi.org/10.1038/s41467-021-21246-9.

      R2.5. In the abstract, authors claimed that ReCoN can predict the effect of gene knockouts. But authors did not show any application or validation to support this claim.

      Response:

      • *

      We indeed had no showcase that could explicitly measure the performance of ReCoN directly for gene knockout, while the possible application was introduced in the abstract.

      * We believe that ReCoN could be used in the future to infer such perturbations, but we fully agree that this claim cannot be presented without justification.

      We propose to remove the introduction of gene-knockout there, and to introduce it in the discussion opening instead, specifying that it will require specific experience and constitutes a possible future extension of the work.*

      R2.6. The communication between cells might be dependent on their spatial proximity. Is it possible to construct the CCC layer by incorporating the context-matched spatial data? How would that affect the performance of multicellular response prediction?

      Response:

      • *

      *This is a very interesting comment as numerous methods using spatial transcriptomic data have been published recently. *

      • *

      In the current formulation, the beta coefficient Bi_j modulates the impact of the cell type i on the cell type j. If the spatial transcriptomic data can inform on the proximity between cell types, and its overall impact on their communication, users could enforce more communication between some.

      • *

      However, as ReCoN is a cell-type centric model, adding spatial information can only be done at a general scale, or by modelling independently spatial regions such as presented in the Microenvironments heart infarction showcase. It means that ReCoN cannot beneficiate from the potential of spatial transcriptomic as much as models representing the tissue structure.

      R2.7. In the fibroblast application in Fig 4d, based on the cardiac cell types expression in region type, they are predicting fibroblast gene expression. Wouldn't the most direct benchmarking be comparison with observed fibroblast expression from the ST (after deconvolution perhaps)?

      Response:

      • *

      This was a helpful comment to guide the restructuration of the microenvironment heart infarction showcase, as we believe the whole showcase objective was not formulated clearly enough.

      • *

      We aim at modelling the impact of the environment on the transcriptome. As the complete transcriptome of a cell results from numerous interacting variables, we believe that comparing the correlation between ReCoN's scores and the transcriptome would not evaluate the prediction of the environment impact.

      • *

      For this reason, we wanted to compare the results to the specific differences from the microenvironment. We focused on gene set enrichment that seemed less noisy for such a comparative experiment, in particular from Visium10X data that has a particularly high dropout rate.

      • *

      We propose to strengthen the validation by providing molecular insights into the three groups of cells studied.

      The spatial data themselves are bulk, adding a layer of noise over the small number of genes captured by Visium. Instead of a correlation with the deconvoluted spots, we have equivalent single-cell RNA-seq fibroblast data annotated in the same study, which matches the three modelled niches. We propose to conduct a differential expression here and try to compute a correlation between these groups and ReCoN scores, providing a quantitative analysis.

      If the correlation was low because of the noise in the data (notably leading to the permutation of individual gene orders even if overall biological signals and gene set orders are conserved), we will additionally do a pathway enrichment over this data, enriching also the qualitative validation.

      R2.8. Section 2.6 Besides the cytokine section, it is difficult to assess the added value of this approach. Likely there is a lot of valuable findings here but difficult to say because the assessment is very qualitative.

      Response:

      • *

      One of the challenges around this work was to find relevant dataset to evaluate ReCoN. We tried to complete the direct quantitative evaluation from the Immune Dictionary with another quantitive evaluation from the heart atlas multicellular programs, despite a much less direct validation.

      • *

      We hope that the production of new perturbation experiments over multicellular datasets, especially cell-type targeted perturbations, will provide more opportunities to validate the different findings and claim from our current manuscript.

      • *

      On a similar note, no method seemed proposing similar predictions to be compared to. It led to the use of Nichenet score and the current decomposition of the ReCoN model in the section 2.2.1 to evaluate the contribution of the model.

      R2.9. The article is dense and writing should be reorganized for better readability.

      Minor issues -

      No p-values in figures.

      *Response: *

      • *

      We agree that integrating values directly in the panels would make the reading of the figure easier. We would like to introduce the p-values in the panels 2d, 2e, 2f, 2g. We had forgot to indicate in the legend of the panel 4.d that all bold scores were associated with a p-value *

      R2.10. Typo - ReCoN-genetic should be - ReCoN-generic.

      • *

      Response:

      • *

      We are thankful for noticing the typo and corrected it in the new version.

      • *

      R2.11. Authors may consider adding figures to describe their results on balance between direct and indirect effects in section 2.2.2.

      • *

      Response:

      • *

      Depending on the new findings on the indirect effect iterations, we propose adding an additional panel on their combination or a supplementary figure.

      • *

      R2.12. Redundancy in the following two lines -

      o While these approaches effectively describe what tissue-wide programs are coordinated, they generally offer limited insight into the molecular mechanisms that establish or regulate these programs.

      o Despite their ability to identify coordinated tissue-wide programs, multicellular program analyses typically offer limited insight into the underlying molecular mechanisms that orchestrate these programs.

      • *

      Response:

      • *

      We propose in the version of the manuscript to remove the first sentence. In our opinion, starting the next paragraph by this clarification seems more helpful to guide the reader than having it at the end of the previous one.

      3. Description of the revisions that have already been incorporated in the transferred manuscript

      Please insert a point-by-point reply describing the revisions that were already carried out and included in the transferred manuscript. If no revisions have been carried out yet, please leave this section empty.

      • *

      4. Description of analyses that authors prefer not to carry out

      Please include a point-by-point response explaining why some of the requested data or additional analyses might not be necessary or cannot be provided within the scope of a revision. This can be due to time or resource limitations or in case of disagreement about the necessity of such additional data given the scope of the study. Please leave empty if not applicable.

      R2.13. The direct and indirect effects are treated in two separate steps. In reality of course these effects are operating simultaneously. I wonder if this could be better modelled by iterating through the two steps. It might be worthwhile

      trying to see if that improves the performance.

      We thank the reviewer for this interesting idea, and propose to add a supplementary text to present the result of this discussion to the readers.

      • *

      The direct effect is supposed to be measurable from the first iteration only, as we try to represent the effect of direct receptor binding. Regarding the indirect effect, iterations could be done to model the indirect effect, which could represent more distant effect in time.

      • *

      On an algorithmic note, the indirect effect already allow several "iterations" of this effect, as each random walk can loop between all cell types until restart. However, it does not allow to control the weight of the different successive transition. In practice, with a high restart probability, an extreme weight is given to the first "iteration" over the second, as there is three layers to cross to explore the next cell.

      • *

      First, we propose clarifying this section of the manuscript, to explain the depth of the indirect effect explorations.

      • *

      Biologically, it is highly possible that these iterations have an important role to explain the complete reaction of the cells. However, we believe that it hits a major limitation of our modelling, and RWR based exploration in general, as it goes against the enforcement of restarts.

      • *

      We aim to represent pairwise measurements, representing the impact of one node on another. But random walks without restart are not naturally well fitted to this problem, as they naturally converge to a stationary distribution ((László, Lov, and Erdos 1996)). In the case of ReCoN, it means that each gene and receptor, if we pushed the exploration indefinitely, would have the same probability to end up on each node of the system.

      • *

      The restart mitigates this impact and enforces the impacts of the seeds by ensuring that the walkers stay close to the seed. (Tong, Faloutsos, and Pan 2006). By iterating successively from the new distribution obtained from the RWR, we would go against this important probability and progressively converge toward the stationary distribution from classical random walks.

      • *

      So we completely share the opinion of the reviewer that the iterative nature of the indirect effect should be explored too, but we don't believe that ReCoN can model them accurately. We hope that new exploration methods will be able to decipher the importance of these iterations, once additional arguments have been gathered to justify the global interest of considering the indirect effect.

      • *

      Bibliography:

      • *

      László L, Lov L, Erdos O. Random Walks on Graphs: A Survey. 1 Jan. 1996:1-46.

      • *

      Tong H, Faloutsos C, Pan J yu. Fast Random Walk with Restart and Its Applications. Sixth Int Conf Data Min ICDM06 Dec. 2006:613-22. https://doi.org/10.1109/ICDM.2006.70.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary - This is an interesting paper where the authors predict the multicellular response to the molecular perturbations. The idea is somewhat novel and offers a conceptual enhancement by modelling the multicellular response as collective outcome of cell intrinsic gene regulatory changes coupled with cell-cell communication by using a simple network diffusion-based approach. We have a few comments to help strengthen the work.

      • It is not clear how well it performs in independent validations. Authors showed that it can predict the effect of cytokine perturbations in the immune dictionary by selecting an optimal alpha. Authors should validate that using the same alpha value of 0.8, it is possible to accurately predict the effect of cytokine perturbations in independent datasets. This is particularly concerning for cytokine-cell type pairs where the optimal alpha is not known. Therefore, the potential utility of Recon to estimate the effect of multicellular perturbations is not well established.
      • Authors claimed that optimal alpha value of 0.8 implies the dominance of indirect effect. But in contrast to this claim, the performance across cytokine-celltype pair only increased from 0.72 to 0.76, which seem to imply that indirect effects do not add much.
      • How does the cell-type specific effects prediction perform by just considering the intracellular layers? The authors constructed multiple variants of ReCoN to estimate unicellular and multicellular effects. How is the variant ReCoN-grn different from full ReCoN where gamma is set to zero.
      • In section 2.2, authors assert that if matching datasets are not available, GRN layer can be extracted from other datasets. How well does the GRN layer from one system generalizes to the other system in terms of perturbation prediction?
      • In the abstract, authors claimed that ReCoN can predict the effect of gene knockouts. But authors did not show any application or validation to support this claim.
      • The communication between cells might be dependent on their spatial proximity. Is it possible to construct the CCC layer by incorporating the context matched spatial data? How would that affect the performance of multicellular response prediction?
      • The direct and indirect effects are treated in two separate steps. In reality of course these effects are operating simultaneously. I wonder if this could be better modelled by iterating through the two steps. It might be worthwhile trying to see if that improves the performance.
      • In the fibroblast application in Fig 4d, based on the cardiac cell types expression in region type, they are predicting fibroblast gene expression. Wouldn't the most direct benchmarking be comparison with observed fibroblast expression from the ST (after deconvolution perhaps)?
      • Section 2.6 Besides the cytokine section, it is difficult to assess the added value of this approach. Likely there is a lot of valuable findings here but difficult to say because the assessment is very qualitative.
      • The article is dense and writing should be reorganized for better readability.

      Minor issues

      • No p-values in figures.
      • Typo - ReCoN-genetic should be - ReCoN-generic.
      • Authors may consider adding figures to describe their results on balance between direct and indirect effects in section 2.2.2.
      • Redundancy in the following two lines -
        • While these approaches effectively describe what tissue-wide programs are coordinated, they generally offer limited insight into the molecular mechanisms that establish or regulate these programs.
        • Despite their ability to identify coordinated tissue-wide programs, multicellular program analyses typically offer limited insight into the underlying molecular mechanisms that orchestrate these programs.

      Significance

      This is an interesting paper where the authors predict the multicellular response to the molecular perturbations. The idea is somewhat novel and offers a conceptual enhancement by modelling the multicellular response as collective outcome of cell intrinsic gene regulatory changes coupled with cell-cell communication by using a simple network diffusion-based approach.

    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #1

      Evidence, reproducibility and clarity

      The authors propose an approach to model complex regulatory processes in tissue or cell collections in specific environments taking into account intra- cellular regulatory processes at multiple levels and inter-cellular communication, importantly offering a chance to estimate the importance of indirect effects of perturbations on one cell type via processes in other cell types. Increasingly more complete models allow testing the impact of each component and of integrating data as context-specific information versus general prior knowledge. 3 main use cases are provided exploiting public datases: prediction of the effect of specific in-vivo cytokine perturbations on mouse lymph node tissues Healthy and disease myocardium in a heart failure multiome dataset Myocardial infarction spatial transcriptomics to identify how different cellular neighbourhoods are related to fibroblast phenotype and fibrosis The main framework is an extension of their previous HuMMus framework to investigate multilayer networks of regulation within a single cell type to also consider inter-cellular interactions, thus including i) tf-target GRN, ii) receptor a receptor layer based on PPI, and cell-cell communication based on LR interactions. These complex networks are then explored within the framework of Random Walk with Restart, which allows to establish 'interaction weights' between different nodes in the network, based on repeated simulations of spreading on the network that thus produce scores of proximity between network nodes, across possible paths. In this study first RWR that only allow intra-cell type walks are performed to calculate direct interaction of perturbation on node states, then RWRs across layers are also enabled, to calculate the importance of inter-cell interactions (via coeff gamma). The importance of each cell type is given by another coeff B that can either correspond to cell type proportions or spatial proximity of cell pairs and finally the scores of within and inter-cell interactions are weighted with a coefficient alpha.

      The central contribution that allows coupling of intra with inter-cellular interactions is the establishment of receptor-gene links. Instead of inferring it from data, they propose to express the receptor-gene matrix as: R = L ⋅ G taking ligand-receptor (L) and ligand-gene (G) adjacency matrices from NicheNet and using NNLS to compute R.

      Generally, for all these cases, comparison between performance in inferring the effect of perturbation or the upstream regulators or downstream targets are provided with assessment of AUROC/AUPRC values.

      • Are the claims and the conclusions supported by the data or do they require additional experiments or analyses to support them?

      This is a very well-written paper, the methods used are adequate and the use cases are relevant and broad, exploiting state of the art datasets and tools.

      The author's claims are mostly justified. The authors could make an effort to more explicitly cite other efforts in similar directions. The claim 'We envision ReCoN as a extension to prior multicellular modelling, offering an interesting compromise between prediction of cell type responses and understanding of their molecular coordination.' is very general and could be better substantiated. In fact, the authors do not really give examples of alternative approaches to study systems of interacting cells, other than mechanistic agent based models, that clearly are very different. Moreover, the exploration of the multilayer networks with RWR is a very reasonable choice but could there be other approaches? I think the authors could discuss this issue to briefly support their choice of this method.

      Generally the discussion should provide the reader the context in the existing literature in which the work can be set, detailing its impact. I think this could be improved.

      Regarding the choice of datasets, it is clear that the method is quite demanding, requiring single cell and different omics to build the model, in addition to the expression dataset that is used as a use case. This inevitably leads to using a mix of datasets. For example in the mouse experiments the gene regulatory network was inferred from both a lymph node scRNA-seq dataset and a splenic scATAC-seq dataset, presumably due to the lack of multiome data in this setting. However the cell-cell communication network was inferred from the control case of the Immune Dictionary. Why can't the authors use the control data also for inferring GRNs? Is atac-seq really necessary in the inference of the GRN? What is the impact of the fact that lymph node and spleen samples might be different?

      '

      • Please request additional experiments only if they are essential for the conclusions. Alternatively, ask the authors to qualify their claims as preliminary or speculative, or to remove them altogether.

      • If you have constructive further reaching suggestions that could significantly improve the study but would open new lines of investigations, please label them as "OPTIONAL".

      • Are the suggested experiments realistic in terms of time and resources? It would help if you could add an estimated time investment for substantial experiments.

      • Are the data and the methods presented in such a way that they can be reproduced? The code is very clear, we were able to install and run it and it is quite well-documented. However, a few more details should be given in the text regarding how the evaluation of the performance is carried out. For example: If I understand correctly, when predicting the impact of cytokine perturbations the ReCoN predictions of genes impacted are compared to differentially expressed genes identified through traditional DEG analysis. What is compared is the ranking of these genes from ReCoN with the ranking provided by DEseq2. There is no description of how this comparison of ranking gives rise to AUROC values. Also, is it just the ranking that is predicted or can they also estimate how well they can predict the effect size?

      When describing the use cases, I think a bit more detail would help. For example 'To identify the cell-type-specific genes associated with HF, we used the MOFAcell scores of the multicellular factor 1 (MCP1) reported in ReHeat236' I supposed the explanation is on the dataset but for the sake of clarity it would be good to expand this sentence to give at least an idea of the approach.

      Regarding the calculation of the R matrix from the NichNet matrices L and G, I gather that the R matrix is calculated once and is thus fully data-independent and available just like the L and G matrices from NichNet. This was not very clear in the tutorials.

      Also, this might just be a typo in the tutorial: 'The default α = 0.8 gives more weight to direct effects, which has been empirically validated. You can adjust this based on your biological question." I believe the manuscript says alpha>0.5 refers to indirect effects dominating.

      Same for the pre-processing of the spatial data for the third use case, a little more details on how this was done would help the users and readers.

      • Are the experiments adequately replicated and statistical analysis adequate? I don't see issues with the statistical power of the analysis. Rather, I think the authors should provide some examination of the parameter space for their model. Whereas ana analysis of the impact of the Alpha parameter is provided, I believe there are several more parameters that have a crucial impact and choices for their values should be discussed.

      For example 'In the GRN reconstruction only the links with a score above 1.5e-7 were retained in ReCoN's gene regulatory layer. How was this chosen?

      We have identified the following parameters that are somehow justified but could be explored to have a better feel for how they impact the results

      Restart probability: How often the walker goes back to the starting seed/molecule Layer transition probability: How often the walker stays in the same layer - different cell? - different layers? Gamma Node transition within a layer: How often one jumps to a different layer Weighting parameters: How much weight for direct or indirect effect to account for the combined effect - alpha - this is the only one that is explicitly explored.

      Finally, this might be considered OPTIONAL but would greatly improve the work in our opinion: The method crucially depends on the networks that are used in the different layers and to connect layers and cell types. As we know, biological data is noisy and incomplete (FP and FN) at each level and in each datatype. It would be really useful to estimate what is the robustness of the results to this noise. Particularly, from personal experience, we think the GRNs reconstructed from data are often almost fully connected and it is exceedingly difficult to validate them in specific contexts. This means that some 'errors' are likely to be present. Since several methods exist for inferring GRNs one could simply compare the results using different methods for this part of the network. A related point involves the characteristics of the RWR algorithm, that will be quite impacted by the presence of hubs in these networks (either in single layers or across several) that is likely to impact the exploration. If proteins that are hub are effectively important, that is not a problem, but in some layers, for example, the receptor-receptor layer that presumably will contain PPIs, there might be biases in hubs being just better studied proteins, and these hubs might have an 'unjustified' weight in the walks. One potential approach to assess the robustness of the method to these issues could be an empirical one that just randomly perturbs the networks in ReCoN to see to what extent similar predictions are achieved.

      Minor comments:

      • Specific experimental issues that are easily addressable.
      • Are prior studies referenced appropriately?
      • Are the text and figures clear and accurate?
      • Do you have suggestions that would help the authors improve the presentation of their data and conclusions?

      Please add page numbers. Figures are nice and clear. Some specific minor points are listed here below.

      Define hMLN on first appearance fig1 caption (no page numbers..;) 2nd appearance heterogeneous multilayer structure (HMLN) ... Bi_j not so clear to what it refers when first mentioned personalized interaction specificity. - maybe better word than personalised (contextualised?) ReCoN-genetic and ReCoN, ( generic?) responses. It is expected to observe common behaviors in-between cell-type, that the GRN and the generic CCC network already contribute captures. - not very clear

      Figure 2b the icon of cells with double arrows might suggest phenotype shift when instead this is just communication eTACs explain acronym and what they are Due to very few genes being differentially expressed, only cDC1 was conserved and evaluated for IL22, Not so clear In this showcase (not very clear, use case?) different fibroblast specializations - maybe phenotypes?

      Figure 4b b) Schematic view of the deconvolution process and cell type-specific count inference from the spatial niches. Not so clear what the heatmap shows, rows and columns Spots heatmap : label niche on rectangles in cols And each col is a spot Rows are cell types or cells? In the cell types x spot

      Cell2location. Add reference, maybe explain basic functionality?

      reconstructing different patients, tissues, and microenvironments to predict context-specific molecular treatments. Unclear fibrosis in different - at molecular levels

      Figure 5d myeloid and endothelial colour code inversed from 5 BC 5d indicate important pathways in organe should not change the colour of the nodes (purple=common, blue or green specific). Use border colour maybe? 5e is not a venn diagram e) Venn diagram showing the overlap between transcription factors (TFs) predicted by ReCoN (green) and those previously implicated in fibrosis (orange) or cardiac diseases (violet). Only the top 10 TFs were annotated from literature sources; full sizes of fibrosis- and cardiac disease-related receptor sets can therefore not be represented. f) also not a venn diagram e/f now in supp the "NABA ECM collagens" gene set. Nodes are grouped by molecular type (e.g., transcription factors, receptors, ligands), and links represent the weighted, direct regulatory interactions present in the ReCoN-constructed

      Why Sankey plot? Normally sankey plot represents flow (of regions changing from 1 state to another) but here this is just a weighted network? No communication from firbos back to other cell types? No communication between ventricular/myeloid/lymphoid?

      as a extension to - an underrepresented in the current. - current framework? However, it can't represent more - cannot Borrowing representation from hypergraphs, which introduces The network exploration implementation of ReCoN also present some limitations. limitations. While random walks with restarts offer a stable and fast exploration workflow for multilayer networks, it currently only considers positive weights to predict regulation strengths. It involves that the nature of the regulation, as activation or inhibition, has to be identified a posteriori.

      • check concordance/grammar

      Only the nodes that are included in one of the layers are present in the final results, ignoring the ones present only in bipartites. Unclear a scATAC - an Barsi et al is published https://journals.plos.org/ploscompbiol/article?id=10.1371/journal.pcbi.1013188 effects, allowing for modulating in a second time their contribution. - word order

      others. However, it is possible to adjust the Beta coefficient to represent it based on the available information for each dataset. Represent- adjust?

      We use the latter to compare the different models. - what is the latter?

      It resulted in the scRNA-seq in 1,789 cells with 13,167 genes, and for the scATAC-seq in 3,759 cells with 254,545 regions. Check english GRETA pipeline.- reference

      We kept all the cells whose annotations through unsupervised clustering, followed by marker gene annotations, through scANVI were coherent. Word order In parallel, pairs of ligands and receptors with both associated with scores above an absolute gene loading of 0.1 were considered potential driver interactions in HF. Unclear gseapy Python - reference?

      and to calculate average for each spatial context the average cell type expression. Unclear

      We only used the loadings of all cell types but the fibroblasts to consider the effect of the sole environment. Unclear We realised a downstream - performed

      The profiles inferred by ReCoN were first very correlated in all three contexts. - unclear

      Significance

      Provide contextual information to readers (editors and researchers) about the novelty of the study, its value for the field and the communities that might be interested.

      This is a very timely paper, dealing with an important gap in the literature. It is not an entirely new framework, but it integrates different existing approaches to solve a complex issue in a creative way. To my knowledge, it is the first attempt to consider and formalise regulation processes involving both intra- and inter-cellular interactions. The results support the importance of distinguishing the different paths that can relate the impact of a perturbation to specific genes/functions in different cells and their overall ecosystem.

      General assessment: provide a summary of the strengths and limitations of the study. What are the strongest and most important aspects? What aspects of the study should be improved or could be developed?

      The tool offers a combination of approaches, providing a coherent framework. The code is well documented and functional. The use cases are quite compelling. Sadly, the only type of validation possible involves confirmation of known facts from the literature, which makes it hard to evaluate the full impact of some of the predictions. I think the details of how the method works and especially how the performance was evaluated could be expanded and an assessment of how different parameters and choices impact the results would also be very helpful. An effort to compare the presented variations of the method to some other approach would be very welcome, but I am finding it hard to identify what an alternative approach could be comparable.

      Advance: compare the study to the closest related results in the literature or highlight results reported for the first time to your knowledge; does the study extend the knowledge in the field and in which way? Describe the nature of the advance and the resulting insights (for example: conceptual, technical, clinical, mechanistic, functional,...).

      Potentially the closest results are models that can predict the effect of perturbations on cell line cultures. Several approaches in the literature employ either transformers or optimal transport to predict the effect of perturbations in single cell datasets. One of the main issues is an underlying necessary assumption that the perturbation effect will be larger than the heterogeneity (in cell lines for example), which becomes increasingly difficult when considering in-vivo experiments. ReCoN obviously goes beyond this by considering explicitly the presence of different cell types but distinctions of cell types are sometimes quite arbitrary and potentially application of ReCoN to some of the in-vitro culture datasets, even on cell lines, could be a way to test its performance and benchmark it against other methods. The main bottleneck in the application of this framework to 'personalisation' of therapies, mentioned even in the abstract as a potential future goal for such an approach, will be the lack of data. This approach requires single cell level descriptions of the system at hand, plus additional datasets to build the model structure. To a certain extent, public data of related tissues/contexts can be used, but it will be necessary to test the dependence of performance on coherence of the input data to develop sufficient trust to use it for new predictions, especially in a medical field.

      The authors could comment on how their method compares to others that do not require single cell level information. Despite clear differences, it might be important to show the advantage of using this more complex approach that requires data that is less available. Given the ease with which bulk profiles can be constructed from single cell data, it might be possible to compare the approaches directly. For example, see K. Wang, S. Patkar, J.S. Lee, E.M. Gertz, W. Robinson, F. Schischlik, D.R. Crawford, A.A. Schäffer, E. Ruppin Deconvolving Clinically Relevant Cellular Immune Cross-talk from Bulk Gene Expression Using CODEFACS and LIRICS Stratifies Patients with Melanoma to Anti-PD-1 Therapy

      Mike van Santvoort, Óscar Lapuente-Santana, Maria Zopoglou, Constantin Zackl, Francesca Finotello, Pim van der Hoorn, Federica Eduati, Mathematically mapping the network of cells in the tumor microenvironment, Cell Reports Methods 2025

      Audience: describe the type of audience ("specialized", "broad", "basic research", "translational/clinical", etc...) that will be interested or influenced by this research; how will this research be used by others; will it be of interest beyond the specific field?

      Broad interest to biomedical researchers and also biologists in other fields. While the method allows advances in basic research on biological process regulation, a clear clinical application can be envisaged in immuno-oncology for example/ immunology and even general molecular medicine.

      Please define your field of expertise with a few keywords to help the authors contextualize your point of view. Indicate if there are any parts of the paper that you do not have sufficient expertise to evaluate.

      I am a computational biologist with expertise in network models, regulatory networks, agent-based models and especially familiar with the tumour microenvironment and processes therein. I can more or less appreciate the meaningfulness of the biological findings related to the mouse lymphnode example. I am much less of an expert on heart tissue modeling, heart failure, fibrosis etc, required to fully comprehend the impact of the second and third use cases.

    1. Note: This response was posted by the corresponding author to Review Commons. The content has not been altered except for formatting.

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      Reply to the reviewers

      Reviewer #1 (Evidence, reproducibility and clarity (Required)): __ In this manuscript, the authors describe the discovery of a molecular regulator of the immune transcriptional program, which is activated by intestinal distension upon bacterial colonization of the C. elegans intestine. Taking advantage of the fact that inhibition of aex-5 is known to cause intestinal distension and a C-type lectin gene clec-60 as a marker for the immune response to intestinal distension (clec-60p::gfp), the authors performed a forward genetic screen for suppressors of the immune response activation. Of the two mutants isolated, they focused on the stronger suppressor, which corresponded to a cysteine-type DUB, the Ubiquitin Specific Peptidase-14 (usp-14). Through rescue experiments, phenocopy analyses, and quantitative RT-PCR, they validated usp-14 as the causal gene and initiated characterization of its role in immune response activation. To this end, the authors investigated the tissue of action, identifying the intestine as the tissue in which usp-14 mediates the regulation of the immune response. Through transcriptomic analyses, they found that the signalling pathway likely regulated by usp-14 in response to intestinal distension is the Wnt pathway, as they have observed reduction in the transcriptional level of some of the Wnt pathway components in usp-4(tm1481), in response to infection with S. aureus. Additionally, transcriptomic data indicate that usp-14 plays a role in immunity regulation even in the absence of infection. Based on these findings, the authors propose that usp-14 has a dual role in immune regulation: one in surveillance immunity, preventing overactivation of immune responses, and another as a mediator of pathogen-induced responses, such as those triggered by P. aeruginosa or S. aureus. The experiments are rigorous and the results robust; however, some points would benefit from further investigation or clarification. __Response: We thank the reviewer for an excellent summary of our work and for the valuable feedback.

      Comment: The expression domain of usp-14 appears to be quite expanded based on single cell RNAseq data (e.g. PMID: 28818938) therefore it is likely that the transgenes used for expression analysis are lacking key regulatory information. Alternative methods like smFISH would be more appropriate to characterise the spatiotemporal pattern of usp-14 expression in more detail. Response: We thank the reviewer for this valuable suggestion. In the original version of the manuscript, we used a 714 bp region upstream of the usp-14 start codon to generate the transcriptional reporter. In the revised manuscript, we reconstructed the reporter using a longer 1924 bp upstream promoter region together with a portion of exon 1. Using this updated reporter, we observed substantially broader expression of usp-14, particularly during the early larval stages. These results are described on page 6, lines 147-152: “We next examined the spatiotemporal expression pattern of usp-14 in C. elegans. To this end, we generated transgenic worms expressing GFP under the control of the usp-14 promoter (usp-14p::gfp). During early larval development, usp-14 was broadly expressed across multiple tissues (Figure 3A). However, in L4 larvae and adult animals, expression became more restricted and was predominantly observed in the intestine and a subset of neuronal cells. Notably, both intestinal and neuronal expression persisted throughout development (Figure 3A).

      Comment: __The mutation mapped in usp-14(jsn19) is a missense mutation (E122K) that suppresses the immune response to a degree comparable to the usp-14(tm1481) deletion allele. However, the authors do not show the functional domains in Fig. 1E potentially affected by this missense mutation. __Response: We have now updated Figure 1E to include the functional domains of USP-14 and mapped both the usp-14(jsn19) missense allele and the usp-14(tm1481) deletion allele onto the protein schematic.

      Comment: __How USP-14 regulates Wnt and how Wnt signalling relates to activation of immune responses is not fully supported. Are the Wnt components mentioned in the study induced specifically in the intestine upon infection and does USP-14 act in the intestine in the context of this regulation? How do the authors interpret that both Wnt ligands and receptors are induced ? Does Wnt signalling appear as a GO term in the transcriptomic analysis? The authors can include Wnt signalling components in the analysis of the transcriptomic results. __Response: We thank the reviewer for these insightful comments. Previous studies have shown that the Wnt pathway components examined in our study are induced in the intestine upon infection and function within the intestine to regulate host defense against bacterial pathogens (PMID: 29768179; PMID: 36323254).

      We did not observe significant enrichment of Wnt signaling terms in the GO analysis of our transcriptomic dataset. We believe this is likely due to the stringent thresholds used for differential expression analysis (fold change > 2 and p At present, the precise mechanism by which USP-14 regulates Wnt pathway components remains unclear. One possibility is that USP-14 influences Wnt signaling indirectly through additional substrates or interacting proteins that regulate transcriptional outputs. We have now clarified this point in the Discussion (page 12, lines 340–345): “These observations raise the possibility that additional USP-14 substrates or interacting proteins modulate transcriptional outputs downstream of intestinal distension. Future studies aimed at identifying the direct substrates of USP-14 and defining how USP-14 interfaces with neuronal ACC-4 signaling and other distension-responsive pathways will provide important mechanistic insight into how intestinal distension is coupled to innate immune activation.

      Regarding the simultaneous induction of Wnt ligands and receptors, we interpret this as a potential amplification or reinforcement mechanism that enhances Wnt/β-catenin signaling during infection-induced intestinal distension. However, further studies will be required to determine the mechanistic significance of this coordinated transcriptional regulation.

      Comment: __Overall, in most of the figures, the micrographs are in general quite dark and exhibit poor contrast between signal and background, particularly in Fig. 1, panels B and J, and Fig. 2, panels B and F (upper rows). Even though these panels are intended to show absence of response, the outlines of the worms are difficult to discern. __Response: We thank the reviewer for the feedback. We have now improved the image presentation throughout the manuscript by either increasing the intensity or adding dotted outlines to more clearly indicate worm positions.

      Comment: __In Figure S3, panels A and B, the pmk-1(km25); usp-14(tm1481) animals subjected to aex-5 RNAi show some level of fluorescence/response induction comparable to pmk-1(km25) alone. This observation is not discussed in the text. __Response: We have now discussed this observation in the text. These results are described on page 9, lines 240-244: “Although pmk-1(km25);usp-14(tm1481) worms displayed relatively higher GFP levels than usp-14(tm1481) single mutants upon aex-5 RNAi treatment, this effect likely reflects the elevated basal GFP expression observed in pmk-1(km25) mutants (Figure S4B). Importantly, pmk-1(km25);usp-14(tm1481) animals still exhibited significantly lower GFP levels than pmk-1(km25) single mutants.

      Reviewer #1 (Significance (Required)): __ __Comment: __The work is interesting because it expands some previous work in the field demonstrating immune response induction as a consequence of intestinal distension even in the absence of bacterial infection. This is known to be mediated by the neuronal acetylcholine receptor ACC-4, which signals to the intestine where it regulates immune genes via the Wnt pathway. However, how USP-14 relates to ACC-4 is currently unclear and whether USP-14 function is really required in the intestine to control Wnt signalling is not demonstrated. The authors should include a model to describe how their findings relate to the previous literature and how USP-14 may link mechanistically to Wnt signalling pathway activation. __Response: We thank the reviewer for this insightful comment. We agree that the relationship between USP-14, ACC-4, and Wnt signaling requires further clarification. As suggested by the reviewer, we have now included a model summarizing the current understanding of intestinal distension-induced immune activation and integrating our findings with previous literature (Figure 6H).

      Comment: __It remains also unclear whether usp-14 is the only deubiquitinase involved in intestinal distension-induced signalling via the Wnt pathway, or whether other paralog usp genes might also contribute to regulation of immune-responsive transcription. Notably, several mammalian deubiquitinases have established roles in cancer suppression and inflammatory response and innate immunity in other systems so this would increase the potential significance of the work. __Response: We thank the reviewer for this valuable suggestion. To systematically examine whether additional DUBs contribute to intestinal distension-induced immune activation, we performed an RNAi screen targeting all DUBs available in the Ahringer RNAi library using the aex-5(sa23);clec-60p::gfp reporter strain. Among the DUBs tested, knockdown of usp-14 produced the strongest suppression of clec-60p::gfp expression. Although knockdown of usp-5 also partially suppressed GFP induction, usp-5 RNAi did not affect survival during P. aeruginosa infection, suggesting that usp-5 is not required for host defense under these conditions. Together, these findings identify USP-14 as the major DUB required for intestinal distension-induced immune activation in our experimental system. These results are now included in Figure 1G, H, and Figure S2.

      Reviewer #2 (Evidence, reproducibility and clarity (Required)): __ Summary C. elegans are soil-dwelling nematodes that feed on bacteria and fungi and thus must be able to distinguish between innocuous and pathogenic species of microbes to survive. Though they lack adaptive immunity, these animals have an ancient version of an innate immune system that has no circulating sentinel or phagocytic cells yet can still mount a response to pathogen exposure. A consequence of the mode of infection of some ingested bacterial pathogens is intestinal distension which by itself, even in the absence of pathogens, is sufficient to trigger the expression of genes encoding immune effectors, including proteins that are bactericidal. The complete mechanistic scheme connecting intestinal distension to the expression of immunity genes has not been resolved, motivating the authors to perform a forward genetic screen for additional components of this pathway. One mutant that the authors isolated was usp-14, encoding an evolutionarily conserved deubiqutinating enzyme. Functional analysis revealed that usp-14 confers protection from microbial pathogens and that the intestine is its primary site of action for its role in host defense. The authors' data indicate that while USP-14 regulates the expression of innate immunity genes that are induced by intestinal distension, surprisingly it functions independently of several canonical innate immune signaling pathways, including the pmk-1/p38 MAPK pathway. Instead, USP-14 appears to act through Wnt signaling to regulate immune effectors by upregulating the expression of several components of that pathway, including the C. elegans ß-catenin ortholog bar-1. This places usp-14 within a gut-brain axis previously shown to control the C. elegans innate immune response through acetylcholine-mediated activation of Wnt signaling. The authors' findings provide new mechanistic insight to this pathway and add to the understanding of ubiqutination as an immune regulatory module. __Response: We thank the reviewer for providing an excellent summary of our work.

      Major comments __1. There are three types of experiments in which the authors use the same set of controls across several different figure panels, as stated in the legend to Figure 2. First, when quantifying GFP levels of clec-60::gfp in RNAi-treated animals, the authors use the same clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls for Fig. 1K, 2C, and 2G. For infection assays with S. aureus NCTC8325, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2E are the same as the ones used in Fig. 1M. Similarly, for infection assays with P. aeruginosa PA14, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2I is the same as was used for Fig 1I. In each case, if the authors in fact collected all of the data for each strain that they studied at the same time but then chose to parse larger datasets into separate figure panels to make it more clear to the reader, then this approach is valid but the authors need to explicitly state that this is what they did. However, if the data pertaining to the control strains were collected at a different time or if it comes from a separate biological replicate, then re-using data from the controls is not appropriate because it would not accurately reflect the specific conditions of the experiment to which the data are being compared. If this is indeed the scenario, then the authors will need to repeat these experiments and include the appropriate control in each iteration. __Response: While preparing the manuscript, these experiments were performed simultaneously. Therefore, all panels that share controls have results from experiments performed simultaneously and represent the same biological replicate. We have added this additional information in the relevant figure legends.

      Comment: __2. From the legends describing figure panels that include data pertaining to clec-60p::gfp expression levels as assessed by fluorescence microscopy it seems that, in general, the authors measured GFP fluorescence in about 30 animals to produce quantitative data. How many biological replicates of these types of experiments were carried out? This is not explicitly stated in the section describing fluorescence imaging in the Methods section. Following the description of their methodology regarding statistical analysis of survival curves from microbial infection assays, however, the authors state that, "[a]ll experiments were performed independently at least three times unless otherwise noted." Does this statement apply to microscopy or only to experiments involving infection assays? If the data reporting quantitation of GFP signal is based on only 30 animals, then additional biological replicates are necessary, along with appropriate statistical analyses. __Response: The quantified GFP fluorescence data are derived from three independent biological replicates. In each experiment, we typically imaged and quantified approximately 10 worms per condition, yielding a total of ~30 worms analyzed per genotype or treatment across all replicates (except Figure S1B, where we had two independent replicates). We have added the number of experiments in the figure legends for these data.

      Comment: __3. The authors have made all of the RNASeq data publicly available on the Sequence Read Archive, and they include data from several pairwise comparisons for differential gene expression analysis in their supplemental files. One of the most important facts to come out of the authors' Gene Ontology analyses of their RNASeq data is that the genes that are upregulated in a usp-14-dependent manner upon intestinal distension are enriched for those whose products play a role in innate immunity/host defense. The authors should say more about these genes. Are there any commonalities between them with regard to function? Are any of them targets of transcription factors that are known to function in C. elegans innate immunity? If so, this could provide clues as to what the substrates of USP-14 might be. Importantly, the specific identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense should be revealed in a supplemental file, and designated as being dependent on or independent of usp-14 for their expression during intestinal distension. __Response: We thank the reviewer for this insightful suggestion. We have now expanded the Results section to describe the functional categories enriched among the USP-14-dependent intestinal distension-induced immune genes, including C-type lectins, ShK toxin domain-containing proteins, and lysozymes (page 7, lines 193-195).

      In addition, we compared our transcriptomic dataset with previously published transcription factor-regulated gene sets using WormExp analysis and identified a substantial overlap with genes regulated by the GATA transcription factor ELT-2. These new analyses are described on page 7, lines 196-206: “To identify transcription factors potentially involved in intestinal distension-induced immune activation, we performed transcription factor enrichment analysis using WormExp on genes upregulated in N2 worms following aex-5 RNAi treatment. This analysis revealed a substantial overlap between aex-5 RNAi-induced genes and genes regulated by the GATA transcription factor ELT-2 (Figure S3D). We next examined whether USP-14-dependent immune genes overlapped with ELT-2-dependent immunity genes induced by intestinal distension. To this end, we identified innate immune genes common to both ELT-2-regulated gene sets and aex-5 RNAi-induced genes. Strikingly, these ELT-2-dependent intestinal distension-induced immune genes showed substantial overlap with USP-14-dependent immune genes (Figure S3E and Table S5), suggesting that USP-14 may regulate distension-induced immunity, at least in part, through ELT-2-dependent transcriptional programs.

      Finally, we have created a new table (Table S5) that specifies the identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense, for USP-14-dependent and independent genes.

      Comment: __4. The authors' data suggest that in response to bacterial infection USP-14 upregulates the expression of bar-1, along with other components of the Wnt signaling pathway, which in turn upregulates innate immunity genes. This could be further substantiated by directly demonstrating that there are USP-14-regulated innate immunity genes whose induced expression in the presence of microbial pathogens also requires bar-1. Along those lines, an initial test would be to assess clec-60p::gfp expression in bar-1 animals versus bar-1;usp-14 double mutants, similar to the experiment whose results are reported in Fig. S4. If generating the bar-1;usp-14 double mutant is not feasible, then RNAi could be used to knockdown bar-1 expression in clec-60p::gfp;usp-14(tm1481) animals. To expand this analysis, the expression of the six innate immunity genes shown to be regulated upon intestinal distension in usp-14-dependent manner could be measured in the presence and absence of intestinal distension or microbial infection in bar-1 and bar-1;usp-14 animals by qRT-PCR. At a minimum, the authors should conduct a bioinformatics analysis to compare the USP-14-regulated innate immunity genes identified in their RNAseq studies to lists of known BAR-1 transcriptional targets to look for potential overlap. __Response: We agree that extending these analyses to qRT-PCR experiments examining additional immune genes would be informative. However, both bar-1 mutants and bar-1 RNAi-treated worms exhibited severe developmental and physiological defects, including sick and dead animals during development, likely reflecting the pleiotropic developmental roles of BAR-1. Although fluorescence imaging and survival assays could be performed by selectively transferring surviving adults, we were concerned that bulk collection of worms for qRT-PCR analyses would introduce confounding effects arising from developmental defects and reduced viability.

      To further address the reviewer’s suggestion, we carried out a comparative analysis between USP-14-dependent intestinal distension-induced immune genes and previously identified BAR-1-dependent immune genes. Although transcriptome-wide datasets for BAR-1-dependent pathogen-induced immune genes are not currently available, an earlier study identified seven immune response genes regulated by BAR-1 during infection (PMID: 18981407). We found that six of these genes overlap with the USP-14-dependent intestinal distension-induced immune genes identified in our study. These analyses have now been added to the Results section and included in Table S5.

      Comment: __5. While in their Discussion section the authors mention evolutionarily conserved roles for protein ubiquitination as means of immunomodulation, there are few if any comments regarding ubiqutination as a regulatory scheme in C. elegans innate immunity or how their findings enhance our understanding of this phenomenon. Ubiquitination affects C. elegans immunity at multiple levels, from avoidance behavior to gene regulation, and it seems appropriate for the authors to address this in order to more fully contextualize their findings. __Response: We thank the reviewer for the suggestion. We have now added a new paragraph to the Discussion that places our findings in the context of the existing literature on ubiquitination, deubiquitination, and innate immunity in C. elegans. The discussion is added on pages 10-11, lines 295-308: “Although ubiquitin-mediated signaling has emerged as a central regulator of innate immunity across metazoans (Jiang & Chen, 2011; Mello-Vieira & Dikic, 2026), the contribution of DUBs to host defense in C. elegans remains poorly understood. Previous studies in C. elegans have shown that ubiquitin-dependent processes regulate diverse aspects of immunity, including immune surveillance, xenophagy, and pathogen tolerance (Garcia-Sanchez et al, 2021). Perturbations in proteasome function have also been shown to activate surveillance immunity (Ghosh & Singh, 2026; Troemel et al, 2026), highlighting the importance of ubiquitin-associated pathways in sensing pathogen-induced cellular damage. However, most prior studies have focused on ubiquitin ligases, proteasome-associated pathways, or global ubiquitin signaling rather than on specific DUBs directly regulating antibacterial immune responses. To our knowledge, our study provides the first direct evidence that a specific DUB regulates antibacterial innate immunity in C. elegans. Thus, our findings establish USP-14 as a previously unrecognized regulator of host defense and identify deubiquitination as an important regulatory layer in intestinal distension-mediated immunity.

      __Minor comments __1. In the Results section, the authors state that "[k]nockdown of cec-10 led to only a marginal decrease in survival during P. aeruginosa infection" (lines 92 and 93) and that cec-10 "has minimal impact on C. elegans survival during infection" (lines 93 and 94). However, as reported in Supplemental Table 5 the magnitude of the calculated difference in mean survival time between animals treated with RNAi targeting cec-10 and untreated control animals (-20% to -24% and statistically significant in 3/3 replicates) closely approximates the difference in mean survival between usp-14 mutants and controls (-19% to -28% and statistically significant in 3/3 replicates), which the authors clearly find to be significant. If by this metric usp-14 is important for host defense, then so too is cec-10. In light of this, the authors should use different language to describe the impact of cec-10 knockdown on the susceptibility of C. elegans to microbial infection and the potential role of cec-10 in immunity.

      Response: We chose not to pursue cec-10 further primarily because it lacks a clear human homolog and because the mutant exhibited reduced expression of the co-injection marker, raising the possibility of broader transgene-related effects. We have modified the text on page 4, lines 92-96: “Knockdown of cec-10 resulted in a significant reduction in survival during P. aeruginosa infection (Figure S1C). However, we did not pursue cec-10 further for two reasons: (i) cec-10(jsn20) mutants exhibited a modest but significant reduction in the myo-2p::mCherry co-injection marker (Figure 1D), raising the possibility of broader transgene-related defects, and (ii) cec-10 lacks a clear human homolog.

      Comment: __2. All of the micrographs in Fig. 1B appear very dark. The GFP expression in the control animals appears dim, making it difficult for the reader to compare the signal in those animals to the GFP expression levels in the mutants. I recommend adjusting the brightness level in an equivalent manner across all of the micrographs to account for this. __Response: We have increased the brightness of all the images, as suggested by the reviewer.

      __Comment: __3. Fig. 1E depicts a gene structure diagram for usp-14 with the position of the point mutation in the jsn19 allele isolated in the authors' forward genetic screen indicated by the amino acid substitution symbol drawn over the second exon. Instead of mixing gene- and protein-level information about the jsn19 allele, I recommend replacing the gene structure diagram with a domain structure diagram of the USP-14 protein that depicts the conserved C19 peptidase and ubiquitin-like domains. The relative position of the E122K substitution should still be noted. __Response: __We have now updated Figure 1E to include the functional domains of USP-14 and mapped both the usp-14(jsn19) missense allele and the usp-14(tm1481) deletion allele onto the protein schematic.

      Comment: __4. Since all of the information in Fig. 1F appears elsewhere in the text, I recommend eliminating this panel. __Response: We have removed it.

      Comment: __5. Regarding the RNAseq analysis, the authors state that 1241 genes are upregulated upon aex-5 knockdown (line 162). The authors then ask which of these genes are regulated by usp-14 in the context of intestinal distension and find that 633 are upregulated a usp-14-dependent manner when aex-5 is targeted by RNAi and that 595 are upregulated even in the absence of usp-14 (Fig. 3D). This accounts for 1228 genes in total, not 1241. Can the authors explain this discrepancy? __Response: We thank the reviewer for carefully noting this discrepancy. The difference arises from the criteria used to classify genes into the categories shown in Figure 5D (previously Figure 3D). Specifically, genes uniquely upregulated in usp-14(tm1481) worms were defined as genes that were either exclusively induced in usp-14(tm1481) worms or expressed at levels more than 2-fold higher in usp-14(tm1481) worms compared to N2 worms. During this classification, 13 genes that were initially identified as upregulated in N2 worms following aex-5 RNAi were found to be expressed at levels more than 2-fold higher in usp-14(tm1481) worms than in N2 worms (Table S4). These genes were therefore reassigned to the “usp-14(tm1481)-specific” category in the Venn diagram. Consequently, the total number of genes represented in the Venn diagram becomes 1228 instead of 1241. To clarify this point, we have now added an explanation to the figure legend.

      Comment: __6. For the sake of clarity, in the legend to Fig. 3D I recommend expanding the description of the categories of genes depicted in the Venn diagram by using the same language as in the first worksheet of Supplemental Table 4. __Response: We thank the reviewer for the suggestion. We have now added these details to the legend of Figure 5D (previously Figure 3D). The legend reads: “(D) Venn diagram showing the overlap between genes upregulated upon aex-5 RNAi in N2 and usp-14(tm1481) worms. The GO analyses for the biological processes of unique and common genes are shown. USP-14-dependent genes were defined as genes that were either exclusively upregulated in N2 worms or expressed at levels greater than 2-fold higher in N2 worms than in usp-14(tm1481) worms. USP-14-independent genes were defined as genes upregulated in both N2 and usp-14(tm1481) worms with expression differences of less than 2-fold between the two strains. Genes uniquely upregulated in usp-14(tm1481) worms were defined as genes that were either exclusively induced in usp-14(tm1481) worms or expressed at levels greater than 2-fold higher in usp-14(tm1481) worms than in N2 worms. Thirteen genes classified as upregulated in N2 worms were more than 2-fold higher in usp-14(tm1481) worms than in N2 worms (Table S4) and were therefore included in the usp-14(tm1481)-specific category.

      Comment: __7. In Fig. 4B, the authors' annotation indicates that there is a statistically significant difference (**, p __Comment: __8. In Fig. S5, the shade of blue used to represent the data from the nhr-49(nr2041);usp-14(tm1481);clec60p::gfp animals in panel E is different from that used to represent data from the same animals in panel B. This breaks the pattern of all of the other panels of this figure in which the data pertaining to a given phenotype are depicted in the same color. Also, in the symbol key in panel E there is an extra semi-colon before clec-60p::gfp that should be eliminated in the second genotype notation. __Response: We thank the reviewer for carefully examining the figure and for bringing these issues to our attention. We have made the changes.

      Comment: __9. The authors' data show that USP-14 regulates bar-1 expression, and in the Discussion section they mention that in mammals beta-catenin is a substrate of USP14. Can the authors comment on the possibility of/evidence for BAR-1 autoregulation in C. elegans and the prospect of it being facilitated by USP-14? This could be a minor point to add to the Discussion. __Response: In both contexts, USP-14 appears to stabilize BAR-1 by regulating it at either the transcriptional or post-translational level. However, it is currently unknown whether BAR-1 regulates USP-14 expression and thereby participates in an autoregulatory mechanism. Nevertheless, we have added to the Discussion that USP14 may regulate the Wnt pathway through both transcriptional and post-translational mechanisms, depending on the biological context. __Reviewer #2 (Significance (Required)): __ The study described in this manuscript ties in to the findings from two prior genetic screens carried out in C. elegans that aimed to identify immune regulators (Ren et al., Cell Reports, 2022 and Labed et al., Immunity, 2018). Though their strategies differed, both of these previous studies uncovered a role for acetylcholine receptors in modulating the response to ingested microbial pathogens, especially when infection is associated with intestinal distension, indicating that a neuron-to-gut axis controls innate immunity in C. elegans. Labed and colleagues were the first to show that activation of this pathway results in the upregulation of genes encoding Wnt signaling pathway components, including the worm ortholog of beta-catenin called bar-1, which are necessary for the expression of immune effectors in the intestine. The Labed study also revealed that protein ubiquitination could contribute to regulating host defense gene induction because knockdown of lin-23, the substate binding subunit of a ubiquitin ligase complex that mediates BAR-1 degradation, results in constitutive expression of clec-60p::gfp, the same transcription reporter used by Ghosh and Singh as a readout for the expression of innate immunity genes. In their screen that revisits the Ren et al. approach, Ghosh and Singh find that another protein implicated in regulating protein stability via ubiquitination status, USP-14, also controls the expression of innate immunity genes in response to intestinal distension. Interestingly, their data indicate that it does so by upregulating bar-1. This discovery therefore adds an element of mechanistic detail regarding the regulation of Wnt signaling in immunity. While the Labed data suggest that ubiquitination may regulate BAR-1 at the post-translational level, Ghosh and Singhs' results indicate a second layer of regulation of bar-1 at the transcriptional level that also appears to involve ubiquitination. In this case, USP-14 is predicted to modulate the ubiquitination status of a yet-to-be-identified substrate that directly or indirectly governs bar-1 expression. The authors' findings thus bring the field closer to having a complete picture of the Ach-Wnt pathway in C. elegans. As they point out in the Discussion section of their manuscript, ubiquitination is an evolutionarily conserved yet complex means of tuning the immune system. The work described here helps to shed light on this important immune regulatory mode and could have implications for aspects of epithelial immunity that are in common to both invertebrates and vertebrates.

      Response: We thank the reviewer for providing such a thoughtful overview of the field and for placing our findings in the context of previous studies on intestinal distension-induced immunity in C. elegans. We also sincerely appreciate the reviewer’s constructive feedback and insightful comments, which have helped us improve the quality and clarity of the manuscript.

      My research interest and specific area of expertise pertains to evolutionarily conserved genetic pathways that control healthspan through affecting cellular resilience later in life. Using C. elegans as a surrogate for aging humans, my group studies age-dependent changes in the activity of regulatory modules that protect older animals from the molecular damage associated with intrinsic and extrinsic sources of cellular stress, with a particular emphasis on microbial infection and oxidative stress.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary

      C. elegans are soil-dwelling nematodes that feed on bacteria and fungi and thus must be able to distinguish between innocuous and pathogenic species of microbes to survive. Though they lack adaptive immunity, these animals have an ancient version of an innate immune system that has no circulating sentinel or phagocytic cells yet can still mount a response to pathogen exposure. A consequence of the mode of infection of some ingested bacterial pathogens is intestinal distension which by itself, even in the absence of pathogens, is sufficient to trigger the expression of genes encoding immune effectors, including proteins that are bactericidal. The complete mechanistic scheme connecting intestinal distension to the expression of immunity genes has not been resolved, motivating the authors to perform a forward genetic screen for additional components of this pathway. One mutant that the authors isolated was usp-14, encoding an evolutionarily conserved deubiqutinating enzyme. Functional analysis revealed that usp-14 confers protection from microbial pathogens and that the intestine is its primary site of action for its role in host defense. The authors' data indicate that while USP-14 regulates the expression of innate immunity genes that are induced by intestinal distension, surprisingly it functions independently of several canonical innate immune signaling pathways, including the pmk-1/p38 MAPK pathway. Instead, USP-14 appears to act through Wnt signaling to regulate immune effectors by upregulating the expression of several components of that pathway, including the C. elegans ß-catenin ortholog bar-1. This places usp-14 within a gut-brain axis previously shown to control the C. elegans innate immune response through acetylcholine-mediated activation of Wnt signaling. The authors' findings provide new mechanistic insight to this pathway and add to the understanding of ubiqutination as an immune regulatory module.

      Major comments

      1. There are three types of experiments in which the authors use the same set of controls across several different figure panels, as stated in the legend to Figure 2. First, when quantifying GFP levels of clec-60::gfp in RNAi-treated animals, the authors use the same clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls for Fig. 1K, 2C, and 2G. For infection assays with S. aureus NCTC8325, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2E are the same as the ones used in Fig. 1M. Similarly, for infection assays with P. aeruginosa PA14, the survival plots for the clec-60p::gfp and usp-14(jsn19);clec-60p::gfp controls shown in Fig. 2I is the same as was used for Fig 1I. In each case, if the authors in fact collected all of the data for each strain that they studied at the same time but then chose to parse larger datasets into separate figure panels to make it more clear to the reader, then this approach is valid but the authors need to explicitly state that this is what they did. However, if the data pertaining to the control strains were collected at a different time or if it comes from a separate biological replicate, then re-using data from the controls is not appropriate because it would not accurately reflect the specific conditions of the experiment to which the data are being compared. If this is indeed the scenario, then the authors will need to repeat these experiments and include the appropriate control in each iteration.
      2. From the legends describing figure panels that include data pertaining to clec-60p::gfp expression levels as assessed by fluorescence microscopy it seems that, in general, the authors measured GFP fluorescence in about 30 animals to produce quantitative data. How many biological replicates of these types of experiments were carried out? This is not explicitly stated in the section describing fluorescence imaging in the Methods section. Following the description of their methodology regarding statistical analysis of survival curves from microbial infection assays, however, the authors state that, "[a]ll experiments were performed independently at least three times unless otherwise noted." Does this statement apply to microscopy or only to experiments involving infection assays? If the data reporting quantitation of GFP signal is based on only 30 animals, then additional biological replicates are necessary, along with appropriate statistical analyses.
      3. The authors have made all of the RNASeq data publicly available on the Sequence Read Archive, and they include data from several pairwise comparisons for differential gene expression analysis in their supplemental files. One of the most important facts to come out of the authors' Gene Ontology analyses of their RNASeq data is that the genes that are upregulated in a usp-14-dependent manner upon intestinal distension are enriched for those whose products play a role in innate immunity/host defense. The authors should say more about these genes. Are there any commonalities between them with regard to function? Are any of them targets of transcription factors that are known to function in C. elegans innate immunity? If so, this could provide clues as to what the substrates of USP-14 might be. Importantly, the specific identity of the genes assigned in the GO analyses to biological processes pertaining to innate immunity and host defense should be revealed in a supplemental file, and designated as being dependent on or independent of usp-14 for their expression during intestinal distension.
      4. The authors' data suggest that in response to bacterial infection USP-14 upregulates the expression of bar-1, along with other components of the Wnt signaling pathway, which in turn upregulates innate immunity genes. This could be further substantiated by directly demonstrating that there are USP-14-regulated innate immunity genes whose induced expression in the presence of microbial pathogens also requires bar-1. Along those lines, an initial test would be to assess clec-60p::gfp expression in bar-1 animals versus bar-1;usp-14 double mutants, similar to the experiment whose results are reported in Fig. S4. If generating the bar-1;usp-14 double mutant is not feasible, then RNAi could be used to knockdown bar-1 expression in clec-60p::gfp;usp-14(tm1481) animals. To expand this analysis, the expression of the six innate immunity genes shown to be regulated upon intestinal distension in usp-14-dependent manner could be measured in the presence and absence of intestinal distension or microbial infection in bar-1 and bar-1;usp-14 animals by qRT-PCR. At a minimum, the authors should conduct a bioinformatics analysis to compare the USP-14-regulated innate immunity genes identified in their RNAseq studies to lists of known BAR-1 transcriptional targets to look for potential overlap.
      5. While in their Discussion section the authors mention evolutionarily conserved roles for protein ubiquitination as means of immunomodulation, there are few if any comments regarding ubiqutination as a regulatory scheme in C. elegans innate immunity or how their findings enhance our understanding of this phenomenon. Ubiquitination affects C. elegans immunity at multiple levels, from avoidance behavior to gene regulation, and it seems appropriate for the authors to address this in order to more fully contextualize their findings.

      Minor comments

      1. In the Results section, the authors state that "[k]nockdown of cec-10 led to only a marginal decrease in survival during P. aeruginosa infection" (lines 92 and 93) and that cec-10 "has minimal impact on C. elegans survival during infection" (lines 93 and 94). However, as reported in Supplemental Table 5 the magnitude of the calculated difference in mean survival time between animals treated with RNAi targeting cec-10 and untreated control animals (-20% to -24% and statistically significant in 3/3 replicates) closely approximates the difference in mean survival between usp-14 mutants and controls (-19% to -28% and statistically significant in 3/3 replicates), which the authors clearly find to be significant. If by this metric usp-14 is important for host defense, then so too is cec-10. In light of this, the authors should use different language to describe the impact of cec-10 knockdown on the susceptibility of C. elegans to microbial infection and the potential role of cec-10 in immunity.
      2. All of the micrographs in Fig. 1B appear very dark. The GFP expression in the control animals appears dim, making it difficult for the reader to compare the signal in those animals to the GFP expression levels in the mutants. I recommend adjusting the brightness level in an equivalent manner across all of the micrographs to account for this.
      3. Fig. 1E depicts a gene structure diagram for usp-14 with the position of the point mutation in the jsn19 allele isolated in the authors' forward genetic screen indicated by the amino acid substitution symbol drawn over the second exon. Instead of mixing gene- and protein-level information about the jsn19 allele, I recommend replacing the gene structure diagram with a domain structure diagram of the USP-14 protein that depicts the conserved C19 peptidase and ubiquitin-like domains. The relative position of the E122K substitution should still be noted.
      4. Since all of the information in Fig. 1F appears elsewhere in the text, I recommend eliminating this panel.
      5. Regarding the RNAseq analysis, the authors state that 1241 genes are upregulated upon aex-5 knockdown (line 162). The authors then ask which of these genes are regulated by usp-14 in the context of intestinal distension and find that 633 are upregulated a usp-14-dependent manner when aex-5 is targeted by RNAi and that 595 are upregulated even in the absence of usp-14 (Fig. 3D). This accounts for 1228 genes in total, not 1241. Can the authors explain this discrepancy?
      6. For the sake of clarity, in the legend to Fig. 3D I recommend expanding the description of the categories of genes depicted in the Venn diagram by using the same language as in the first worksheet of Supplemental Table 4.
      7. In Fig. 4B, the authors' annotation indicates that there is a statistically significant difference (**, p<0.01) in the fluorescence signal from clec-60p::gfp in usp-14(jsn19);aex-5(sa23);clec-60p::gfp_EV versus usp-14(jsn19);aex-5(sa23);clec-60p::gfp_bar-1 animals. This is likely a typographical error that should be changed to "ns" to indicate no significant difference in the fluorescence signal between these two groups, which is consistent with what the data show and with the authors' description of these data in the text (lines 211-214).
      8. In Fig. S5, the shade of blue used to represent the data from the nhr-49(nr2041);usp-14(tm1481);clec60p::gfp animals in panel E is different from that used to represent data from the same animals in panel B. This breaks the pattern of all of the other panels of this figure in which the data pertaining to a given phenotype are depicted in the same color. Also, in the symbol key in panel E there is an extra semi-colon before clec-60p::gfp that should be eliminated in the second genotype notation.
      9. The authors' data show that USP-14 regulates bar-1 expression, and in the Discussion section they mention that in mammals beta-catenin is a substrate of USP14. Can the authors comment on the possibility of/evidence for BAR-1 autoregulation in C. elegans and the prospect of it being facilitated by USP-14? This could be a minor point to add to the Discussion.

      Significance

      The study described in this manuscript ties in to the findings from two prior genetic screens carried out in C. elegans that aimed to identify immune regulators (Ren et al., Cell Reports, 2022 and Labed et al., Immunity, 2018). Though their strategies differed, both of these previous studies uncovered a role for acetylcholine receptors in modulating the response to ingested microbial pathogens, especially when infection is associated with intestinal distension, indicating that a neuron-to-gut axis controls innate immunity in C. elegans. Labed and colleagues were the first to show that activation of this pathway results in the upregulation of genes encoding Wnt signaling pathway components, including the worm ortholog of beta-catenin called bar-1, which are necessary for the expression of immune effectors in the intestine. The Labed study also revealed that protein ubiquitination could contribute to regulating host defense gene induction because knockdown of lin-23, the substate binding subunit of a ubiquitin ligase complex that mediates BAR-1 degradation, results in constitutive expression of clec-60p::gfp, the same transcription reporter used by Ghosh and Singh as a readout for the expression of innate immunity genes. In their screen that revisits the Ren et al. approach, Ghosh and Singh find that another protein implicated in regulating protein stability via ubiquitination status, USP-14, also controls the expression of innate immunity genes in response to intestinal distension. Interestingly, their data indicate that it does so by upregulating bar-1. This discovery therefore adds an element of mechanistic detail regarding the regulation of Wnt signaling in immunity. While the Labed data suggest that ubiquitination may regulate BAR-1 at the post-translational level, Ghosh and Singhs' results indicate a second layer of regulation of bar-1 at the transcriptional level that also appears to involve ubiquitination. In this case, USP-14 is predicted to modulate the ubiquitination status of a yet-to-be-identified substrate that directly or indirectly governs bar-1 expression. The authors' findings thus bring the field closer to having a complete picture of the Ach-Wnt pathway in C. elegans. As they point out in the Discussion section of their manuscript, ubiquitination is an evolutionarily conserved yet complex means of tuning the immune system. The work described here helps to shed light on this important immune regulatory mode and could have implications for aspects of epithelial immunity that are in common to both invertebrates and vertebrates.

      My research interest and specific area of expertise pertains to evolutionarily conserved genetic pathways that control healthspan through affecting cellular resilience later in life. Using C. elegans as a surrogate for aging humans, my group studies age-dependent changes in the activity of regulatory modules that protect older animals from the molecular damage associated with intrinsic and extrinsic sources of cellular stress, with a particular emphasis on microbial infection and oxidative stress.

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      Referee #1

      Evidence, reproducibility and clarity

      In this manuscript, the authors describe the discovery of a molecular regulator of the immune transcriptional program, which is activated by intestinal distension upon bacterial colonization of the C. elegans intestine. Taking advantage of the fact that inhibition of aex-5 is known to cause intestinal distension and a C-type lectin gene clec-60 as a marker for the immune response to intestinal distension (clec-60p::gfp), the authors performed a forward genetic screen for suppressors of the immune response activation. Of the two mutants isolated, they focused on the stronger suppressor, which corresponded to a cysteine-type DUB, the Ubiquitin Specific Peptidase-14 (usp-14). Through rescue experiments, phenocopy analyses, and quantitative RT-PCR, they validated usp-14 as the causal gene and initiated characterization of its role in immune response activation. To this end, the authors investigated the tissue of action, identifying the intestine as the tissue in which usp-14 mediates the regulation of the immune response. Through transcriptomic analyses, they found that the signalling pathway likely regulated by usp-14 in response to intestinal distension is the Wnt pathway, as they have observed reduction in the transcriptional level of some of the Wnt pathway components in usp-4(tm1481), in response to infection with S. aureus. Additionally, transcriptomic data indicate that usp-14 plays a role in immunity regulation even in the absence of infection. Based on these findings, the authors propose that usp-14 has a dual role in immune regulation: one in surveillance immunity, preventing overactivation of immune responses, and another as a mediator of pathogen-induced responses, such as those triggered by P. aeruginosa or S. aureus. The experiments are rigorous and the results robust; however, some points would benefit from further investigation or clarification.

      The expression domain of usp-14 appears to be quite expanded based on single cell RNAseq data (e.g. PMID: 28818938) therefore it is likely that the transgenes used for expression analysis are lacking key regulatory information. Alternative methods like smFISH would be more appropriate to characterise the spatiotemporal pattern of usp-14 expression in more detail.

      The mutation mapped in usp-14(jsn19) is a missense mutation (E122K) that suppresses the immune response to a degree comparable to the usp-14(tm1481) deletion allele. However, the authors do not show the functional domains in Fig. 1E potentially affected by this missense mutation.

      How USP-14 regulates Wnt and how Wnt signalling relates to activation of immune responses is not fully supported. Are the Wnt components mentioned in the study induced specifically in the intestine upon infection and does USP-14 act in the intestine in the context of this regulation? How do the authors interpret that both Wnt ligands and receptors are induced ? Does Wnt signalling appear as a GO term in the transcriptomic analysis? The authors can include Wnt signalling components in the analysis of the transcriptomic results.

      Overall, in most of the figures, the micrographs are in general quite dark and exhibit poor contrast between signal and background, particularly in Fig. 1, panels B and J, and Fig. 2, panels B and F (upper rows). Even though these panels are intended to show absence of response, the outlines of the worms are difficult to discern.

      In Figure S3, panels A and B, the pmk-1(km25); usp-14(tm1481) animals subjected to aex-5 RNAi show some level of fluorescence/response induction comparable to pmk-1(km25) alone. This observation is not discussed in the text.

      Significance

      The work is interesting because it expands some previous work in the field demonstrating immune response induction as a consequence of intestinal distension even in the absence of bacterial infection. This is known to be mediated by the neuronal acetylcholine receptor ACC-4, which signals to the intestine where it regulates immune genes via the Wnt pathway. However, how USP-14 relates to ACC-4 is currently unclear and whether USP-14 function is really required in the intestine to control Wnt signalling is not demonstrated. The authors should include a model to describe how their findings relate to the previous literature and how USP-14 may link mechanistically to Wnt signalling pathway activation.

      It remains also unclear whether usp-14 is the only deubiquitinase involved in intestinal distension-induced signalling via the Wnt pathway, or whether other paralog usp genes might also contribute to regulation of immune-responsive transcription. Notably, several mammalian deubiquitinases have established roles in cancer suppression and inflammatory response and innate immunity in other systems so this would increase the potential significance of the work.

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      Referee #2

      Evidence, reproducibility and clarity

      In the manuscript titled "Multiple Molecular Pathways to Longevity: Opposing Gene Expression Programs Define Distinct Aging Strategies", the authors investigated diverse genetic pathways that contribute to lifespan extension in Caenorhabditis elegans and aimed to identify shared and distinct molecular mechanisms among various longevity mutants. Through comprehensive RNA sequencing of different longevity mutants representing seven distinct pathways, the authors showed that these mutants cluster into three primary groups based on their gene expression profiles. This transcriptomic analysis revealed that while some longevity genes are commonly regulated across multiple pathways, others exhibit opposing expression patterns, suggesting that distinct molecular strategies can lead to increased lifespan. Specifically, they identified a set of 196 genes that are consistently upregulated in most longevity mutants, many of which are involved in innate immunity and stress defense. By performing RNAi-based screening, the authors further validated the functional roles of several candidates, including C08F11.7, ugt-62, and K05C4.9, supporting their contributions to longevity and stress resistance. The authors conclude that longevity is mediated through multiple molecular pathways and provide a public online tool to study these complex transcriptomic landscapes.

      Major comments

      1. While the authors identified a set of 196 upregulated genes, the rationale for narrowing these down to the three final candidates (C08F11.7, ugt-62, and K05C4.9) is not clearly described. The authors show that genetic inhibition of several genes, including DC2.5, C05B5.5, T07C4.5, and W03B1.7, decreases lifespan in both nuo-6 mutants and wild-type animals. However, the authors did not describe why these additional validated candidates, which also showed significant effects on longevity, were not pursued for further characterization. The authors should explicitly state the criteria used to prioritize these three genes over the other validated genes.
      2. The authors conclude that longevity can be mediated by multiple molecular pathways. However, it remains unclear whether these distinct strategies can operate simultaneously or are mutually exclusive. The authors need to test whether lifespan extension in a Group 1 mutant is further enhanced or suppressed by the knockdown of a key Group 2-specific genes. These experiments would help determine these pathways act additively, antagonistically, or as partially redundant survival programs.
      3. The authors provide interesting data on overexpression of the three candidate genes. However, whereas C08F11.7 clearly demonstrates both necessity and sufficiency for lifespan extension, overexpression of ugt-62 and K05C4.9 does not independently extend lifespan. To strengthen the manuscript, the authors should expand the discussion of these divergent results and clarify possible explanations.
      4. Key citations are missing and the authors should add multiple citations including the following ones. Please cite the following paper and discuss the authors' finding with respect to the related work (Lee et al PMID: 40814218). Add citations in the sentence describing changes in the transcriptome of C. elegans associated with age (Lee et al., PMID: 38508494). Furthermore, please cite papers describing the overviews of survival assay using C. elegans (Kwon et al., PMID: 40436148, Hwang et al., PMID: 40436147).

      Minor comments

      1. To improve readability, please provide the full names for all abbreviations at their first appearance in the manuscript.
      2. Please ensure that the labels in the figures match the text exactly. For instance, if different promoters are used for generating overexpression animals, it may be helpful to indicate the specific promoter in the figure panel or legend for clarity.
      3. For all lifespan and stress resistance assays, please include the total number of animals (n) and the number of independent biological replicates (N) in the figure legends to confirm statistical reliability.
      4. Please clearly specify the exact developmental stage of the animals used for the survival assays in the Materials and Methods section.

      Referees cross-commenting

      I also agree with reviewer #1's comments and recommend revision to further improve the manuscript.

      Significance

      This study provides a systematic, side-by-side transcriptomic comparison of nine genetically distinct long-lived C. elegans mutants, revealing that lifespan extension arises from both shared and opposing gene expression programs. By identifying three distinct longevity groups and demonstrating that key pathways can be modulated in opposite directions to achieve long life, the work challenges the notion of a single universal transcriptional signature of aging. Importantly, functional validation shows that select commonly regulated genes can directly modulate lifespan and stress resistance, highlighting actionable molecular targets for promoting healthy aging.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      This manuscript by Rudich ZD et al. systematically profiled the transcriptomic changes in nine long-lived C. elegans mutants and presented a careful and informative comparative analysis of these aging-related changes. In addition to these valuable datasets and bioinformatics analyses, the authors performed a large-scale RNAi screen to assess the role of the differentially expressed genes (DEGs) in these mutants and identify several potential targets to promote healthy aging. Moreover, the authors have provided a user-friendly website to examine genes of interest in those longevity mutants from their datasets.

      Major comments

      The conclusions of this manuscript are generally well supported. The study is also technically sound. Yet, I still have a few concerns that should be carefully addressed.

      1. Although I myself believe that the datasets in this study should be more consistent and comprehensive, the authors should perform a data mining analysis of previously reported transcriptomic changes of these mutants or similar mutants in the same longevity pathway and compare the reported changes with their findings to highlight the necessity and advances of this study.
      2. This manuscript does not perform any regulon or transcription factor (TF) analyses. TFs are the drivers of the transcriptomic changes and multiple conserved TFs (e.g., daf-16) have already been identified in these pathways. Therefore, it is necessary to examine and compare the regulons/TFs in these new datasets by bioinformatics. Such analyses can: a) provide more information of the driving force of these transcriptomic changes; b) show the role of these known longevity TFs; c) propose new TFs driving longevity; d) support the findings of 'longevity strategies' and 'longevity groups' from the perspective of TFs.
      3. osm-5 and daf-2 are categorized into two different groups in this study. Since the longevity of cilia (-) mutants is through daf-16, the same master TF driving daf-2 longevity, please perform further analyses or discussion to clarify this issue.
      4. This manuscript focused on genes whose RNAi suppressed the mutants longevity. Please also use bioinformatics to analyze the functions of those whose RNAi extends the mutants longevity, because these genes could tell the health price these mutants pay and help improve ageing interventions by reducing side effects.
      5. (OPTIONAL) I strongly suggest a comprehensive comparison of these transcriptomic changes in long-lived mutants with published age-related transcriptomic changes in wild type worms. This comparison will significantly All the suggested analyses are pure bioinformatics and should be realistic to finish in several months.

      Minor comments

      I also have a few minor comments on data presentation: 1. Please further clarify the analysis of DEGs correlated with lifespan extension in Fig. 2 by a depiction. In Fig. 2C and D, please label data dots from different strains with different colors. 2. In Fig. 3 and S20, please label the percentage of overlapping genes on top of each bars.

      Referees cross-commenting

      I agree with Reviewer #2's comments and would suggest giving the authors enough time to revise their manuscript.

      Significance

      Compared to previous transcriptomic analyses of these mutants in differen reports, this study minimized the technical variations and benefitted from the advances in RNA-Seq technology and bioinformatics tools. Therefore, it should provide a more consistent and comprehensive view of the molecular mechanisms underlying the longevity of these mutants. The datasets in this manuscript are valuable to other researchers in the biology of aging.

      Meanwhile, since these mutants have been extensively studied, the advance of this study in unknown mechanisms remains limited. Therefore, I would recommend its publication as a 'Resource' article after addressing my concerns.

      (I am an expert in the biology of ageing, using C. elegans and mouse as major models.)

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      Reply to the reviewers

      1. General Statements

      We thank the reviewers for their constructive evaluation of our manuscript. We are pleased by the overwhelmingly positive consensus regarding the quality and significance of our data. In particular, the reviewers highlighted that this is a "nice, clean study with interesting data" and noted that our in vivo functional genetic findings in the Drosophila wing are "clearly a strength" that "moves the paper beyond cell-culture correlations" to provide a "simple, straightforward take-home message".

      The principal critique across the reports concerns the extent of direct mechanistic evidence linking Groucho (Gro) to regulation of the early elongation checkpoint. Several reviewers suggested additional genomic experiments, including RNA-seq, PRO-seq, or Pol II ChIP approaches, to further examine transcription and pausing behaviour. However, we would like to flag up that genomic datasets addressing these questions across multiple Drosophila cell lines have already been published previously, including work from our own group and others.

      The primary objective of the current study is therefore not to replicate these existing genomic analyses, but rather to build directly upon them. We identify a consistent genomic association between Gro and pausing/elongation factors across cell types. Importantly, we extend these findings beyond genomic correlations through in vivo genetic analysis in the developing Drosophila wing.

      1. Description of the planned revisions

      • *

      • *

      Reviewer 1

      The figures and text could lay out the logic of the genetic interactions for non-Drosophila readers. For example, the comparison of single and double copies of Gro-RNAi to combinatorial knockdowns, when it is additive, and when it is interpreted as synergistic.

      The statistical analyses presented in Figure 5C, including Fisher’s exact tests comparing phenotype distributions between genotypes, were intended to address the distinction between additive and synergistic genetic interactions. However, we agree that the presentation of these comparisons could potentially be made clearer for readers less familiar with Drosophila genetic interaction assays. We would therefore be open to revising the presentation of Figure 5 and the accompanying explanatory text following editorial guidance and with consideration of the intended readership of the eventual journal.

      The statistical analysis of the phenotype distributions should be shown more clearly (Fig. 5B).

      Figure 5B is intended to present the distribution of observed phenotypic classes and does not include statistical comparisons. A similar analysis has been published for experiments looking at the phenotypes of moderate Groucho overexpression in the wing in the presence of HDAC inhibitors (Winkler et al., 2010 doi.10.1371/journal.pone.0010166). Statistical analyses of the genetic interaction experiments are presented separately in 5C. We therefore believe the current presentation of Figure 5B is appropriate for illustrating phenotype frequencies rather than statistical inference, but we will consider moving this panel to the Supplementary material.

      Minor comments

      -Figure 5 would gain clarity if the phenotype classes/panel letters were shown more clearly on the images. -The legends of the wing figures should be expanded, especially for readers outside the Drosophila field. -"in vivo" should be italicised consistently.

      We agree that clearer labelling of phenotype classes, panel annotations and expanded figure legends could improve the accessibility of Figure 5, particularly for readers less familiar with Drosophila wing phenotypes and genetic interaction assays. We would therefore be open to revising the presentation of this figure and its accompanying legends in a future revised version.

      We thank the reviewer for noting the typographical inconsistency of italics for in vivo. This will be corrected during manuscript revision and proofing.

      __Reviewer #2 __

      Reviewer #2 (Significance (Required)):

      I think this is nice little paper providing a simple, straightforward take-home message. It does not conceptually shake the world, and the evidence consists of (nice) correlations, with no direct proof put forward for the conclusions. I am not a Drosophila geneticist but probably rather an 'expert' on basic transcription mechanisms. I think the data in the paper are of high quality, if limited in scope, and that the conclusions are supported by the results, but I do not think the results or conclusions will have a big audience. Having said that, I found it interesting to learn about this group of repressors and their likely mode of action.

      On the other hand, it is worth emphasizing that proteins such as NELF and CDK9 would arguably be expected to be found at very many genes, as promoter-proximal pausing does exist at a plethora of genes, also genes that are house-keeping genes, ie not regulated by cell type or stimuli. So, lots of genes with pausing are not regulated by modulation of pausing. So, basically, the fact that knockdown of the repressor Groucho and loss of pausing is additive does not in my opinion necessarily mean that Groucho works by stabilizing pausing. Although it is admittedly a reasonably assumption, Groucho could also work by repressing transcription initiation; the genetic outcomes of 'double relief' would be the same, ie higher transcription levels. I think a brief comment to this effect might be appropriate, especially in the absence of (difficult to obtain) direct evidence that the transcription initiation step is not affected by Groucho.

      While we agree that the current study does not directly exclude possible effects of Groucho on transcription initiation, previously published work has already provided evidence arguing against repression by Groucho occurring primarily through inhibition of transcription initiation or prevention of pre-initiation complex assembly. Groucho-bound transcriptional start sites were previously shown to retain RNAP II occupancy, active chromatin features, and detectable basal transcriptional activity despite repression (Kaul et al., 2014).

      To acknowledge this possibility and explain why it is unlikely, we will add the sentence “While effects on transcription initiation cannot be completely excluded, previous work argues against Gro repressing transcription primarily through inhibition of transcription initiation. Gro-bound promoters remain accessible, overlap RNAP II occupancy, and retain active chromatin features and basal transcriptional activity” to the start of the third paragraph of the Discussion.

      Reviewer #3

      The methods section is lacking details on how ChIP-seq was performed in the BG3 cell line. The methods section does a good job of indicating how the data were processed. Information on the antibodies and conditions used is critical, as is whether spike-in controls were used.

      The generation of the ChIP-seq data from BG3 cells has already been published. __We will add the line “The production of ChIP-seq datasets for Gro binding in Kc167, S2R+ and BG3 cells has been described elsewhere (Kaul, Schuster and Jennings, 2014; Bar-Cohen et al., 2023)” in the Analysis of ChIP-seq data subsection of the Methods. __

      1. Description of analyses that authors prefer not to carry out

      • *

      __Reviewer #1 __ Major comments 1. The main weakness is the lack of a mechanistic link between Gro and the early elongation checkpoint. This is really the main point for this reviewer. The manuscript builds an interesting model, and the data support a functional connection between Gro and pausing-related factors, but the mechanistic link is absent. At present, the paper relies on co-localisation of ChIP peaks and genetic interaction in vivo. This is interesting and supportive, but with several possible interpretations. The title and some parts of the text are thus a bit stronger than what is directly demonstrated. Two possibilities could be proposed: either tone down the mechanistic claim or strengthen it experimentally. A more direct assay of pause release or productive elongation after Gro depletion at endogenous targets would be highly valuable. For example, Gro-KD followed by Pol II Ser2-P ChIP, or promoter vs. gene body analysis on Gro-bound genes, ideally comparing genes with Gro at TSS vs. not-TSS, would greatly support the proposed model. If the assay is established, this seems feasible in about 4 months.

      We thank the reviewer for this thoughtful comment. We agree that the current study does not directly measure genome-wide RNAP II pause release following Gro depletion. However, several key observations linking Gro with promoter-proximal pausing have already been published and are summarised in the Introduction. Previous work demonstrated that Gro occupancy correlates with paused genes and that depletion of Gro reduces RNAP II pausing and increases elongating RNAP II at the endogenous E(spl)mbeta-HLH locus, an established target gene of Groucho-mediated repression (Kaul et al., 2014; doi.10.1371/journal.pgen.1004595). We also note that several of the experiments proposed by the reviewer have already been addressed in previous work. Specifically, Kaul et al. (2014) demonstrated that Gro depletion increases elongating RNAP II (Ser2-P) at the endogenous E(spl)mbeta-HLH locus while total promoter-associated RNAP II occupancy remains largely unchanged. Promoter versus gene body analyses in that study further supported a role for Gro in regulating progression through the early elongation checkpoint rather than transcription initiation.

      The aim of the current manuscript was therefore to build upon these earlier mechanistic and genomic observations by asking whether the relationship between Gro and pausing-associated factors extends across multiple cell types and whether it has functional significance in vivo. By integrating comparative genomic analyses with sensitised developmental genetic assays in the wing, we provide evidence that Gro functionally interacts with multiple regulators of the early elongation checkpoint during development.

      The bioinformatic part could be strengthened on "distinct TF repertoires" between cell types.The authors interpret the cell type-specific Gro recruitment as reflecting distinct transcription factor repertoires in BG3, Kc167 and S2R+ cells. This is interesting, but not really shown. To make this point more strongly, the author could provide a map of TF expression across different cell types, especially for the TFs corresponding to the enriched motifs they discuss. Otherwise, this remains speculative.In line, the manuscript discusses enriched motifs in BG3 and compares them to Kc167 and S2R+ cells, but this remains a bit descriptive. A clearer side-by-side comparison would strengthen the paper. This is particularly relevant to the motifs used in interpreting cell type-specific recruitment.


      The interpretation that cell type-specific Gro recruitment reflects differences in transcription factor repertoires is based on several previously established observations already described in the manuscript. BG3 cells are derived from the larval CNS, whereas Kc167 and S2R+ cells are embryonic haemocyte-like lines (Cherbas et al., 2011; doi.10.1101/gr.112961.110). Transcriptomic analyses have further shown that these Drosophila cell lines maintain stable and distinct lineage-associated transcriptional identities, including differences in transcription factor expression (Cherbas et al., 2011). Given the diversity of transcription factors known to recruit Gro, the observed cell-type-specific binding patterns and motif enrichments are consistent with the distinct lineage-associated transcriptional programmes previously described for these cell lines.

      1. Several overlap analyses could be discussed more in depth. A few statements feel too strong for the actual percentages. For example, the GAF overlap in BG3 is around 51% genome-wide and 56% at TSS, which is meaningful, but not especially high. The text already states that it is not universal, and this point could be discussed more clearly.

      We note that the manuscript already explicitly states that overlap between Gro and GAF is not universal. Given the diversity of factors known to recruit Gro and the broad genomic distribution of GAF, we consider overlap frequencies of approximately 50% to represent a substantial association, particularly at transcription start sites. Importantly, the interpretation does not rely on complete co-occupancy between these factors, but rather on the observation that Gro-bound regions show significant enrichment for multiple factors associated with promoter-proximal pausing across different cell types.

      Similarly, for the UpSet plot, the wording around the "most frequent" combination could be toned down, because this is not a dominant pattern.

      The statement that the overlap between Gro, Nelf-E, GAF, Cdk9 and RNAP II represents the “most frequent” combination refers specifically to the relative frequency of the intersection categories within the UpSet analysis. In this context, the overlap between all five factors represents the largest intersection category identified (306 of 649 Gro peaks), with the next most frequent category containing substantially fewer peaks (90 of 649). We therefore feel that the current wording accurately describes the distribution observed in the analysis.

      More generally, I think the manuscript needs a clearer quantitative breakdown of TSS versus non-TSS peaks for the overlap analyses with NELF, GAF, Cdk9 and CycT. Several interpretations depend on this distinction, and right now, this is not always clear enough.

      The overlap analyses presented in Figure 3 explicitly distinguish between TSS and non-TSS peaks, and the corresponding quantitative overlap frequencies are described in the Results section. We do not consider that additional breakdowns are required for interpretation of the current data as this distinction is already incorporated into both the analyses and figure presentation.


      The "enhancer chromatin" interpretation is interesting, but not fully integrated with the genomic distribution. The observation that Gro is enriched in open enhancer-type chromatin is interesting and supports the idea that Gro does not act mainly through classical repressed chromatin. However, Gro peaks are also enriched at promoters and introns, and this reviewer feels that the manuscript does not fully connect these observations. Where are these enhancer-type peaks located exactly? Are they often intronic? Can this be correlated with the distribution of Gro peaks? This would help the reader and also strengthen the discussion because intronic Gro peaks are present in the data, but are not well integrated into the model.

      In the current manuscript, “enhancer chromatin” refers to chromatin states defined by combinations of enhancer-associated histone modifications, including H3K4me1, H3K27ac and H3K56ac as defined by Skalska et al.,2015 (doi.10.15252/embj.201489923), rather than exclusively to distal intergenic regulatory regions. As described in the chromatin-state analysis, these enhancer-associated chromatin signatures do occur at intronic regulatory regions, including regions classified as active intron chromatin. We therefore do not consider the enrichment of Gro peaks at promoters, enhancers and intronic regions to be mutually exclusive observations within this framework.

      Intronic enhancer localisation is common in Drosophila, where the compact organisation of the genome results in many developmental regulatory elements residing within introns (Arnold et al., 2013; doi.10.1126/science.1232542). We therefore consider the presence of Gro peaks within intronic regions to be fully consistent with the observed enrichment of Gro binding within enhancer-associated chromatin states.

      The in vivo part is a strength, but some important points need clarification.The in vivo section is a clear highlight of the manuscript. It gives functional relevance to the model and moves the paper beyond cell-culture correlations. That said, a few points need to be clearer:-RNAi efficiency is not clear for the tested genes, especially the pausing factors. This is important because the differential effects between NELF subunits could simply reflect differences in knockdown efficiency.

      While differences in RNAi efficiency could potentially contribute to variation in phenotype strength between individual knockdowns, multiple biological explanations could also account for the differing effects observed between NELF subunits, including differences in protein stability, residual complex activity, or subunit-specific functions. Importantly, the central conclusion of the manuscript does not depend on quantitative comparison of phenotype strength between individual NELF components, but rather on the observation that perturbation of multiple pausing-associated factors genetically interacts with Gro in vivo.

      If RNAi validation is possible with existing reagents, this seems realistic within 3 months.

      The manuscript focuses on the genetic interactions observed between Gro and pausing-associated factors in vivo rather than on quantitative comparison between individual RNAi lines. As no specific validation experiments were proposed, we are not currently planning additional RNAi validation analyses for the present study.

      The discussion could be expanded, especially because the mechanism is not fully shown.Since the direct mechanism is still missing, the discussion could compensate. Right now, the proposed model is interesting, but it still leaves many open questions. For example:-Is Gro affecting the recruitment or activity of elongation factors?-Could looping or enhancer-promoter communication contribute?-How should the intronic Gro peaks be interpreted in the model?-In the wing, could the phenotype be discussed more mechanistically, in light of what is already known about Gro and derepression of vein-promoting genes?For example, a model figure could help here.


      We thank the reviewer for these thoughtful suggestions.

      Several of the points raised by the reviewer are discussed in the manuscript already. For example, we discuss the possibility that Gro influences the activity or recruitment of elongation-associated factors. We agree that enhancer-promoter communication and chromatin looping are a plausible component of this mechanism. As the Drosophila genome is compact and intronic enhancers are highly prevalent, topological looping provides a clear physical framework for how Gro molecules distributed at non-TSS sites regulate promoter-proximal machinery. Indeed, we have previously published this model (Kaul, Schuster, and Jennings, 2015; see Figure 1C; doi.10.1080/21541264.2014.1000709). Our current in vivo and genomic findings build directly upon this model, suggesting that within these established looped configurations, Gro acts locally to interface with and stabilize the pausing machinery.

      With respect to the wing phenotypes, the Discussion focuses primarily on the interpretation of the observed genetic interactions between Gro and pausing-associated factors rather than on defining the precise downstream target genes contributing to vein phenotypes. We agree that additional mechanistic dissection of these developmental phenotypes would be interesting. However, this would require a substantial expansion of the study into the detailed developmental and signalling mechanisms underlying vein specification, which lies beyond the primary focus of the current manuscript.

      OPTIONAL: It would be interesting to know whether the same peak distribution / functional logic is observed in mammalian TLE orthologs. This is not essential for the current conclusions, but it would broaden the impact.

      Determining whether similar genomic distributions and functional relationships are conserved for mammalian TLE orthologues will be an important future project. However, relatively little comparable genome-wide TLE occupancy data are currently available, meaning that such analyses would require a substantial independent undertaking beyond the scope of the present study.

      Minor comments -Please explain why promoters were defined as {plus minus}250 bp from the TSS. This seems rather narrow.

      Promoters were defined as ±250 bp from annotated transcription start sites. This window size is commonly used in Drosophila genomic studies, where the compact organisation of the genome means that broader windows frequently overlap adjacent genes.

      -Please clarify why S2R+ cells are included in the comparative part but are not followed in the same way in some downstream analyses.

      S2R+ cells were included in the comparative analyses to determine which aspects of Gro recruitment were shared across multiple cell types and which were cell-type specific. Some downstream analyses focused on BG3 and Kc167 cells because these lines had the most extensive corresponding datasets available for the chromatin and pausing-factor analyses performed in the current study.

      __Reviewer #3 __ Here Martínez Quiles and Jennings investigate the role of the Groucho repressor in BG3 cells. This extends a previous study that used S2R+ cells, published previously by one of the authors, as well as Kc167 cells. They find that Gro is recruited to gene promoters in a cell-type-specific manner. Gro associates with open chromatin, is mostly associated with enhancer regions, and is primarily excluded from regions of the genome that are repressed by Polycomb. After studying its function in cell culture, the authors investigate the role of Gro in a wing-specific background. The findings here are mostly correlative, showing that loss of Gro results in stronger phenotypic defects when combined with loss of factors including NELF-B or NELF-D, LARP7, and bin3. They propose that Gro acts to attenuate gene expression during early gene expression. This claim would be greatly strengthened if the authors provided RNA-seq data in addition to the ChIP-seq data shown in this manuscript, especially to examine gene expression patterns among the different cell lines studied here. At present, this is a correlative study that does not illuminate the mechanism of Gro in directly regulating promoter-proximal pausing or RNA polymerase behavior.

      We thank the reviewer for this suggestion. However, extensive transcriptomic analyses of Drosophila cell lines, including Kc167, S2R+ and BG3-derived lines, have already been published (Cherbas et al., 2011), together with RNA-seq analyses following Gro depletion (Kaul et al., 2014). In addition, the association between Gro occupancy and paused genes has also been reported previously (Kaul et al., 2014; Chambers et al., 2017; doi. 10.1186/s12864-017-3589-6).

      While additional RNA-seq analyses could further characterise transcriptional differences between cell lines, RNA-seq alone would not directly determine whether altered transcript levels arise specifically through changes in promoter-proximal pausing, as opposed to effects on transcription initiation, transcript stability, or indirect downstream regulatory effects. We therefore do not consider additional RNA-seq analyses necessary to support the central conclusions of the present study.

      Figure 2-3: For the ChIP-seq data, scale the y-axis in the same manner to better understand enrichment between the samples.

      These ChIP-seq datasets were generated independently using different antibodies and experimental conditions, direct comparison of enrichment magnitudes across datasets would not be biologically meaningful. Accordingly, our analyses focus on significant peak calls and overlap relationships rather than relative signal intensity. Applying identical y-axis scaling across all tracks would obscure significant enrichment in several datasets and could therefore be misleading.

      RNA-seq data between different cell lines would greatly enhance the authors findings or Pro-Seq to really show a relationship with Gro binding and promoter proximal pausing.

      We note that RNA-seq datasets for Gro depletion in Kc167 and S2R+ cells have already been published previously (Kaul et al., 2014), together with evidence linking Gro occupancy to paused genes (Kaul et al., 2014; Chambers et al., 2017). We therefore do not consider that additional RNA-seq analysis would substantially strengthen the central conclusions of the current manuscript.

      Moreover, RNA-seq alone cannot distinguish if altered transcript abundance reflects changes in promoter-proximal pausing from other mechanisms influencing transcript abundance. While PRO-seq approaches could provide further mechanistic information regarding RNAPII dynamics, such experiments are beyond the scope of the present study.

      This study helps to further clarify how Gro binds DNA in different cell types and indicates that may intersect with factors involved in promoter proximal pausing. The study is highly correlative and would require additional work to show a mechanistic link between Gro and transcription attenuation due to promoter proximal pausing.

      While we agree that PRO-seq approaches could provide additional mechanistic information regarding RNAPII dynamics, establishing an appropriate experimental and analytical framework for these analyses would require a substantial extension beyond the scope of the present study. In addition, several aspects of the relationship between Gro occupancy, transcriptional repression, and promoter-proximal pausing that underpin these suggestions have already been addressed in previously published work, including RNA-seq analyses following Gro depletion (Kaul et al., 2014), evidence linking Gro occupancy with paused genes (Kaul et al., 2014; Chambers et al., 2017), and studies demonstrating that Gro-mediated repression does not occur through inhibition of pre-initiation complex assembly. The current manuscript is therefore intended to build upon these existing findings by integrating comparative genomic analyses with new in vivo genetic interaction data.

      • *
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      Referee #3

      Evidence, reproducibility and clarity

      Here Martínez Quiles and Jennings investigate the role of the Groucho repressor in BG3 cells. This extends a previous study that used S2R+ cells, published previously by one of the authors, as well as Kc167 cells. They find that Gro is recruited to gene promoters in a cell-type-specific manner. Gro associates with open chromatin, is mostly associated with enhancer regions, and is primarily excluded from regions of the genome that are repressed by Polycomb. After studying its function in cell culture, the authors investigate the role of Gro in a wing-specific background. The findings here are mostly correlative, showing that loss of Gro results in stronger phenotypic defects when combined with loss of factors including NELF-B or NELF-D, LARP7, and bin3. They propose that Gro acts to attenuate gene expression during early gene expression. This claim would be greatly strengthened if the authors provided RNA-seq data in addition to the ChIP-seq data shown in this manuscript, especially to examine gene expression patterns among the different cell lines studied here. At present, this is a correlative study that does not illuminate the mechanism of Gro in directly regulating promoter-proximal pausing or RNA polymerase behavior.

      Major comments:

      Figure 2-3: For the ChIP-seq data, scale the y-axis in the same manner to better understand enrichment between the samples.

      The methods section is lacking details on how ChIP-seq was performed in the BG3 cell line. The methods section does a good job of indicating how the data were processed. Information on the antibodies and conditions used is critical, as is whether spike-in controls were used.

      RNA-seq data between different cell lines would greatly enhance the authors findings or Pro-Seq to really show a relationship with Gro binding and promoter proximal pausing.

      Significance

      This study helps to further clarify how Gro binds DNA in different cell types and indicates that may intersect with factors involved in promoter proximal pausing. The study is highly correlative and would require additional work to show a mechanistic link between Gro and transcription attenuation due to promoter proximal pausing.

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      Referee #2

      Evidence, reproducibility and clarity

      This paper describes experiments designed to determine the mechanism of repression by the Groucho co-repressor in flies. The authors first characterize DNA binding by Groucho by ChIP-Seq analysis. This turns out to be consistent with recruitment driven by cell-type specific transcription factors. Nevertheless, its distribution across genomic features is similar across cell types, with enrichment in promoters and introns. It appears to bind in regions otherwise transcriptionally active (ie 'open chromatin'), rather than chromatin that is compacted and repressed. This suggest that Groucho regulates transcription through promoters or promoter-proximal pausing rather than by reducing chromatin accessibility. Groucho binding overlaps with NELF and GAF binding, seemingly consistent with a role in regulating pausing. However, Gro binding was also observed at promoters where P-TEFb components are detected, arguing against Gro repressing transcription P-TEFb exclusion from pausing sites. The authors next switched to investigating the consequences of Groucho kd and tested the idea that co-depletion of pausing factors might inform about the manner of gene repression, the idea being that if Groucho attenuates transcription by promoting or stabilizing promoter proximal pausing, then partial reduction of the pausing factors it affects should enhance the Groucho knock-down phenotype. Interestingly, simultaneous knock-down of Groucho and GAF resulted in enhanced patterning defects relative to Groucho knock-down alone, with the severity of the phenotypes resembling that observed upon increasing Groucho knock-down. Similarly, the knock-down of either Nelf-B or Nelf-D significantly enhanced Groucho phenotype. Finally, Kd of regulators of the pausing regulator CDK9 were tested. The 7SK snRNA complex inhibits CDK9, so any treatment leading to less 7SK will free CDK9 to positively affect pausing release. Larp kd fits that category as it directly leads to less 7SK and thus more CDK9 activity, while Bin3 kd results in less 5'-methyl capping, and thus more 7SK destabilization (less 7SK), again freeing CDK9 from inhibition - so, increasing pause release (like Nelf kd). Gratifyingly, this separate way of de-regulating/decreasing pausing again had an additive effect to Groucho depletion. Together, these genetic data thus overall support the idea that the (non-chromatin regulating) repressor Groucho works by stabilizing pausing complexes at specific genes.

      Significance

      I think this is nice little paper providing a simple, straightforward take-home message. It does not conceptually shake the world, and the evidence consists of (nice) correlations, with no direct proof put forward for the conclusions. I am not a Drosophila geneticist but probably rather an 'expert' on basic transcription mechanisms. I think the data in the paper are of high quality, if limited in scope, and that the conclusions are supported by the results, but I do not think the results or conclusions will have a big audience. Having said that, I found it interesting to learn about this group of repressors and their likely mode of action.

      On the other hand, it is worth emphasizing that proteins such as NELF and CDK9 would arguably be expected to be found at very many genes, as promoter-proximal pausing does exist at a plethora of genes, also genes that are house-keeping genes, ie not regulated by cell type or stimuli. So, lots of genes with pausing are not regulated by modulation of pausing. So, basically, the fact that knockdown of the repressor Groucho and loss of pausing is additive does not in my opinion necessarily mean that Groucho works by stabilizing pausing. Although it is admittedly a reasonably assumption, Grouch could also work by repressing transcription initiation; the genetic outcomes of 'double relief' would be the same, ie higher transcription levels. I think a brief comment to this effect might be appropriate, especially in the absence of (difficult to obtain) direct evidence that the transcription initiation step is not affected by Groucho.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      In this manuscript entitled "the co-repressor Groucho limits progression through the early transcription elongation checkpoint in vivo", the authors study how the co-repressor Groucho (Gro) may repress transcription in Drosophila. They combine Gro ChIP-seq analysis in BG3 cells with published data from Kc167 and S2R+ cells, chromatin-state and overlap analyses with pausing/elongation factors, and functionally link these interactions in vivo by genetic interaction assays in the wing. The manuscript shows that Gro recruitment is largely cell type-specific, while Gro binding is detected as discrete peaks with similar genomic distribution across cell types. Gro peaks are enriched in open enhancer-type chromatin and overlap with factors linked to promoter-proximal pausing. In vivo, knock-down (KD) of several pausing-related factors enhances the gro RNAi phenotype in the wing. Overall, this is a nice, clean study with interesting data, and the in vivo findings are clearly a strength. However, the mechanistic link between Gro and the early elongation checkpoint remains unclear, and several bioinformatics and presentation points could be strengthened.

      Major comments

      1. The main weakness is the lack of a mechanistic link between Gro and the early elongation checkpoint. This is really the main point for this reviewer. The manuscript builds an interesting model, and the data support a functional connection between Gro and pausing-related factors, but the mechanistic link is absent. At present, the paper relies on co-localisation of ChIP peaks and genetic interaction in vivo. This is interesting and supportive, but with several possible interpretations. The title and some parts of the text are thus a bit stronger than what is directly demonstrated. Two possibilities could be proposed: either tone down the mechanistic claim or strengthen it experimentally. A more direct assay of pause release or productive elongation after Gro depletion at endogenous targets would be highly valuable. For example, Gro-KD followed by Pol II Ser2-P ChIP, or promoter vs. gene body analysis on Gro-bound genes, ideally comparing genes with Gro at TSS vs. not-TSS, would greatly support the proposed model. If the assay is established, this seems feasible in about 4 months.
      2. The bioinformatic part could be strengthened on "distinct TF repertoires" between cell types. The authors interpret the cell type-specific Gro recruitment as reflecting distinct transcription factor repertoires in BG3, Kc167 and S2R+ cells. This is interesting, but not really shown. To make this point more strongly, the author could provide a map of TF expression across different cell types, especially for the TFs corresponding to the enriched motifs they discuss. Otherwise, this remains speculative. In line, the manuscript discusses enriched motifs in BG3 and compares them to Kc167 and S2R+ cells, but this remains a bit descriptive. A clearer side-by-side comparison would strengthen the paper. This is particularly relevant to the motifs used in interpreting cell type-specific recruitment.
      3. Several overlap analyses could be discussed more in depth. A few statements feel too strong for the actual percentages. For example, the GAF overlap in BG3 is around 51% genome-wide and 56% at TSS, which is meaningful, but not especially high. The text already states that it is not universal, and this point could be discussed more clearly. Similarly, for the UpSet plot, the wording around the "most frequent" combination could be toned down, because this is not a dominant pattern. More generally, I think the manuscript needs a clearer quantitative breakdown of TSS versus non-TSS peaks for the overlap analyses with NELF, GAF, Cdk9 and CycT. Several interpretations depend on this distinction, and right now, this is not always clear enough.
      4. The "enhancer chromatin" interpretation is interesting, but not fully integrated with the genomic distribution. The observation that Gro is enriched in open enhancer-type chromatin is interesting and supports the idea that Gro does not act mainly through classical repressed chromatin. However, Gro peaks are also enriched at promoters and introns, and this reviewer feels that the manuscript does not fully connect these observations. Where are these enhancer-type peaks located exactly? Are they often intronic? Can this be correlated with the distribution of Gro peaks? This would help the reader and also strengthen the discussion because intronic Gro peaks are present in the data, but are not well integrated into the model.
      5. The in vivo part is a strength, but some important points need clarification. The in vivo section is a clear highlight of the manuscript. It gives functional relevance to the model and moves the paper beyond cell-culture correlations. That said, a few points need to be clearer:
        • RNAi efficiency is not clear for the tested genes, especially the pausing factors. This is important because the differential effects between NELF subunits could simply reflect differences in knockdown efficiency.
        • The figures and text could lay out the logic of the genetic interactions for non-Drosophila readers. For example, the comparison of single and double copies of Gro-RNAi to combinatorial knockdowns, when it is additive, and when it is interpreted as synergistic.
        • The statistical analysis of the phenotype distributions should be shown more clearly (Fig. 5B). If RNAi validation is possible with existing reagents, this seems realistic within 3 months.
      6. The discussion could be expanded, especially because the mechanism is not fully shown. Since the direct mechanism is still missing, the discussion could compensate. Right now, the proposed model is interesting, but it still leaves many open questions. For example:
        • Is Gro affecting the recruitment or activity of elongation factors?
        • Could looping or enhancer-promoter communication contribute?
        • How should the intronic Gro peaks be interpreted in the model?
        • In the wing, could the phenotype be discussed more mechanistically, in light of what is already known about Gro and derepression of vein-promoting genes? For example, a model figure could help here.

      OPTIONAL:

      It would be interesting to know whether the same peak distribution / functional logic is observed in mammalian TLE orthologs. This is not essential for the current conclusions, but it would broaden the impact.

      Minor comments

      • Please explain why promoters were defined as {plus minus}250 bp from the TSS. This seems rather narrow.
      • Please clarify why S2R+ cells are included in the comparative part but are not followed in the same way in some downstream analyses.
      • Figure 5 would gain clarity if the phenotype classes/panel letters were shown more clearly on the images.
      • The legends of the wing figures should be expanded, especially for readers outside the Drosophila field.
      • "in vivo" should be italicised consistently.

      Referee cross-commenting

      My main concerns are broadly echoed by Reviewer 2, notably regarding the need to clarify the level of mechanistic support for the proposed model. Reviewer 3 also raises related points about the correlative nature of the evidence. Overall, I think the reports converge on the need to better align the conclusions with the current data, while recognising the value of the functional in vivo results, though with different levels of requested additional analysis.

      Significance

      General assessment

      This is a nice paper, with clean data and an interesting model. The strongest point is the attempt to connect the Gro genomic localisation with functional interaction in a developmental context. The observation that Gro is found in open enhancer-type chromatin, together with the in vivo genetic interactions, makes the study significant. The main limitation is that the mechanistic link is still missing. Overall, this reviewer finds the study convincing as a functional and descriptive paper but less convincing as a mechanistic one.

      Advance

      The study extends previous work on Gro by comparing several cell types and by adding in vivo genetic data in the wing. The main advance is thus conceptual and functional: it supports the idea that Gro acts in concert with the pausing/elongation machinery rather than simply through repressed chromatin. However, the mechanistic advance remains limited because a direct link to the early elongation checkpoint has not yet been demonstrated. This is the main thing preventing the paper from being stronger.

      Audience

      This reviewer feels that the manuscript will mainly interest a specialised basic research audience: scientists working on transcriptional regulation, co-repressors, RNA polymerase II pausing, chromatin regulation, and Drosophila developmental genetics. It can also be relevant to those broadly interested in Gro/TLE biology.

      Expertise

      This reviewer's expertise includes gene regulation and its nuclear organisation, transcriptional/co-transcriptional and post-transcriptional regulations, transcription factors biology, and Drosophila genetics. This reviewer is comfortable evaluating the developmental genetics, the conceptual aspect, and the interpretation of genomic analyses, but has less competence in evaluating bioinformatic ChIP-seq processing pipelines.

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      Reply to the reviewers

      Manuscript number: RC-2025-03227R

      Corresponding author(s): Dr. David Skerrett-Byrne & Prof. Brett Nixon

      1. General Statements

      We are grateful to the reviewers and editorial team for their thoughtful and constructive evaluation of our manuscript. The comments provided were insightful and have substantially strengthened the rigor, clarity, and presentation of the study. In response, we have carefully revised the manuscript throughout, including clarification of conceptual interpretations, expansion of methodological detail, refinement and condensation of the Discussion, as well as addition of new supplementary analyses and figures. Collectively, we believe these revisions have improved both the transparency and accessibility of the work while reinforcing the central conclusions of the study.

      At its core, this study sought to address a major unresolved question in reproductive biology: how spermatozoa, which are transcriptionally and translationally inert, achieve functional competence during post-testicular maturation. Using deep, stage-resolved phosphoproteomics integrated with functional validation approaches, we demonstrate that the majority of sperm phosphoproteomic remodelling occurs during epididymal maturation rather than during capacitation, challenging long-standing paradigms in the field. Beyond generating one of the deepest sperm phosphoproteomic resources currently available (>14,000 phosphosites), the study also provides functional and physiological context through kinase inhibition studies, in vivo knockout phenotypes, and the development of the ShinySpermPhospho online resource to facilitate community access and future discovery.

      Importantly, through the review process we have worked carefully to ensure that the manuscript more clearly distinguishes data-driven conclusions from hypothesis-generating interpretations, particularly in areas relating to kinase prediction, metabolic regulation, and phosphoproteomic remodelling. We believe the revised manuscript now presents a more balanced and rigorous framework while preserving the significance of the central findings.

      Overall, we hope the revised manuscript now provides a valuable resource and conceptual advance for the reproductive biology community, with implications extending from fundamental sperm cell biology to translational opportunities in male infertility and contraceptive development.

      2. Point-by-point description of the revisions

      REVIEWER #1

      The manuscript by Skerrett-Byrne and collaborators represents a comprehensive and technically sophisticated phosphoproteomics study. Using high-resolution mass spectrometry on mouse sperm obtained from the caput and cauda regions of the epididymis, both before and after capacitation, the authors generated a more complete database of phosphorylation changes in these cells. One of the most interesting outcomes is that most of these changes occur during sperm maturation, rather than sperm capacitation. The work is important and relevant, and the information obtained could be valuable for reproductive biologists working in basic science, as well as for the identification of novel contraceptive targets.

      __Answer: __We thank the reviewer for their positive assessment of our work and for recognising the value of the datasets we have generated for supporting future innovations in both fundamental reproductive biology and the identification of novel contraceptive targets. We are also delighted that the reviewer has recognised the significance that, contrary to previously thought, the majority of the phosphorylation changes we report occur during epididymal maturation, rather than subsequently during capacitation.

      • The title should include a reference to sperm capacitation, as most of the study focuses on comparisons between epididymal maturation and capacitation, and the functional experiments are based on the latter. __Answer: __We thank the reviewer for this suggestion and have revised the title to reflect the importance of our focus on both phases of post-testicular sperm maturation, namely epididymal sperm maturation and sperm capacitation (please see line 1).

      • Considering the newly reported changes in phosphosites, it would be desirable to include validation at the individual protein level for at least a few examples, using an independent technique such as western blotting. __Answer: __We thank the reviewer for this thoughtful suggestion and fully appreciate the motivation to seek orthogonal validation of phosphoproteomic findings. However, we respectfully wish to express our reservations regarding the use of antibody-based validation of site-specific phosphorylation events, a technique that is increasingly being recognised as problematic and, in many cases, less reliable than modern MS-based approaches (Nature, PMID: 39506148). Indeed, high-resolution mass spectrometry provides direct, site-resolved identification and quantification of phosphorylation events with substantially greater specificity, accuracy, and proteoform resolution than antibody-based methods. For this reason, MS-based phosphoproteomics is now widely regarded as the gold standard for mapping phosphorylation dynamics.

      With regard to the use of antibodies, many commercially available phospho-specific antibodies lack sufficient site specificity, often have poorly defined or undocumented epitope recognition, and frequently fail to discriminate between closely related proteoforms or neighbouring phosphorylation sites. Indeed, recent large-scale evaluations have demonstrated that many widely used antibodies do not reliably bind their intended targets, raising concerns about reproducibility and interpretability across the biomedical sciences (PMID: 37995198). In one study, testing the utility of >600 antibodies, two thirds failed to work as described (PMID: 37995198), while the literature also features other studies (e.g. PMID: 31612854) reporting that certain antibodies (SC-138763) do not bind their stated target despite having been "used in 15 published manuscripts to ascribe specific properties to the protein in normal and disease states", collectively cited >3,000 times.

      Accordingly, while we recognise the importance of independent validation, we contend that antibody-based validation may not be the most appropriate strategy to improve the robustness of the conclusions in this study. It is for this reason that we elected to strengthen confidence in our findings through multiple complementary approaches, including rigorous statistical filtering, extensive in-silico pathway and kinase analyses, selective pharmacological inhibition of target proteins, and in vivo functional interrogation using knockout mouse models. Together, these orthogonal strategies provide additional biological validation linking the reported phosphorylation changes to aspects of sperm function.

      We have clarified this rationale in the revised manuscript and briefly expanded the discussion to touch on these methodological strengths and limitations (please see lines 754 - 759).

      • In the knockout models, it is not possible to distinguish between defects in spermatogenesis and those arising during maturation or capacitation. A parameter directly related to spermatogenesis should therefore be included, for example, testicular weight or histology, sperm number, and sperm morphology. __Answer: __We thank the reviewer for raising this important point. We agree that systemic knockout models do not allow definitive discrimination between defects arising during spermatogenesis versus those occurring downstream during post-testicular sperm maturation or capacitation. Unfortunately, the additional parameters suggested by the reviewer do not form part of the standardised phenotyping pipeline implemented by the International Mouse Phenotyping Consortium (IMPC) and the European Mouse Mutant Archive (EMMA). As such, these data are not available for the knockout lines examined in this study and cannot be retrospectively generated. We have therefore clarified this limitation more explicitly in the revised manuscript and have framed the knockout data as physiological validation concerning the functional relevance of the parent protein rather than as definitive evidence of stage-specific or phosphorylation-dependent mechanisms of action. Importantly, the consistency of impaired sperm motility and fertilisation outcomes across multiple independent knockout lines supports the biological importance of the parent proteins identified, while acknowledging that the precise developmental window of their action remains to be resolved. While we regrettably concede that it is beyond the scope of this study, we do acknowledge that future studies will be required to dissect these mechanisms with greater resolution, ideally using germ cell-specific or temporally controlled knockout models, or targeted manipulation of key phosphoproteins and/or their phosphorylation motifs. Such approaches will be essential if we are to be able to distinguish roles of target proteins in spermatogenesis from those that occur downstream during epididymal maturation and capacitation (please see lines 725 - 733).

      • Error values, sample size, and statistical analyses are missing from Figure 7 and should be provided for clarity. __Answer: __We apologise for this omission and have now updated Figure 7 and its legend to include sample sizes, error values, and details of the statistical analyses used, thereby improving clarity and reproducibility of these data.

      In addition, we have clarified that sperm functional data derived from EMMA knockout lines are generated from cryopreserved samples comprising pooled cauda epididymal spermatozoa collected from 10 heterozygous males per line (PMID: 17709347, 38839949). As such, each data point represents a pooled biological sample, consistent with standardised EMMA/INFRAFRONTIER protocols (PMID: 25414328, 27262858, 38839949). Where appropriate, we have also included additional reproductive metrics at the level of IVF cycle (where available) and individual litters, including average litter size and fetal sex distribution (with exceptions for specific lines where such data are not available). These details are now captured in both the Methods and relevant figure legends (please see lines 453 - 457, 1228 - 1234, 1431 - 1434, 1533 - 1536, 1572 - 1575, Figure 7 & S6).


      REVIEWER #2

      In this manuscript, the authors examine dynamic modifications of the sperm phosphoproteome during epididymal transit and capacitation. They compare three distinct populations differing in anatomical localization and activation status: caput sperm, non capacitated cauda sperm, and capacitated cauda sperm. Using high resolution tandem mass spectrometry, they reveal that phosphorylation changes during epididymal passage are far more extensive than previously appreciated. These findings are further validated in genetically modified animal models, where disruption of selected genes encoding for phosphoproteins results in marked defects in sperm motility and fertilization capacity.

      __Answer: __We thank the reviewer for their positive and thoughtful evaluation of our study and for recognising both the depth of the phosphoproteomic dataset and the importance of the functional validation experiments; sentiments that we whole heartly agree with.

      • Throughout the text, and particularly in the paragraph entitled 'Epididymal maturation accounts for the majority of maturation associated sperm cell signaling,' it seems that phosphorylation is interpreted as inherently activatory and dephosphorylation as inhibitory (lines 248-252). Since this relationship is not universally applicable, it would be valuable to address this issue at the outset of the paragraph and to discuss how phosphorylation events are context dependent in their effects on protein function. __Answer: __We thank the reviewer for highlighting this important conceptual point. We fully agree that phosphorylation is not inherently activatory, nor is dephosphorylation necessarily inhibitory, and that the functional consequences of phosphorylation are highly context dependent. We have revised the indicated paragraph to explicitly acknowledge this at the outset to ensure that phosphorylation changes are interpreted as regulatory rather than intrinsically directional (please see lines 219 - 222).

      • Lines 392-393: the claim that "the introduction of each inhibitor to populations of capacitating spermatozoa led to a significant reduction..." is not fully supported by data and should be toned down. In fact, two out of three inhibitors, do not significantly affect the acrosome reaction. __Answer: __We thank the reviewer for this careful assessment and agree that the original wording overstated the nuances of the effects of individual inhibitors. We have revised the text to explicitly report the corresponding p-values and to distinguish between statistically significant and non-significant trends. Specifically, inhibition of PAK1 produced a statistically significant reduction in the acrosome reaction, whereas inhibition of STK33 (p = 0.0574) and HIPK4 (p = 0.0911) resulted in consistent, but non-significant, reductions. Importantly, combined inhibition of all three kinases yielded a robust and statistically significant suppression of acrosomal exocytosis. The revised wording now accurately reflects the quantitative data (please see lines 419 - 424, 700 - 703).

      • The discussion section, spanning 11 pages, is overly long and contains considerable repetition. I recommend transferring the detailed description of experiments to the 'Results' section and using the discussion primarily to synthesize and highlight the novel findings while limiting speculative content. For example, the content in lines 509-530 could be condensed and relocated to the Results. Likewise, other detailed examples would be more appropriately presented within their respective result paragraphs. __Answer: __We thank the reviewer for this constructive feedback. We agree that the Discussion was overly long and on reflection does contain some unnecessary repetition. In response, we have substantially condensed the Discussion (shorten by 641 words), relocated and shorten detailed descriptions of experimental observations to the Results section where appropriate (including the suggestion made), and focused the revised Discussion on synthesis of the key findings and their broader implications. We should note, to address certain review comments, this require further additions to the discussion but we have endeavour to keep this brief (please see lines 309 - 326 and throughout the discussion).

      • Minor points:

      • To improve reproducibility, the suppliers of all reagents should be specified together with their catalogue numbers
      • Figure 7: it is unclear which data are statistically significant
      • Figure 7B: fertilization capacity should be assessed at an earlier stage, as the cleavage rate to 2-cell embryo may be affected by factors unrelated to the sperm ability to fertilize

      __Answer: __We thank the reviewer for these suggestions. We have now added supplier information and catalogue numbers for all reagents to the Methods section to improve reproducibility (please see lines 1256 - 1257, 1295, 1299, 1310, 1333 - 1334, 1343 - 1344, 1388 - 1389, 1401, 1406). We have revised Figure 7 and its legend to clearly indicate statistically significant differences, including sample sizes and statistical tests used. Lastly, we agree that assessment at earlier fertilisation stages would complement our featured assessment of sperm fertilisation competence. Regrettably, all IVF data were generated via standardised and unbiased IMPC/EMMA pipelines. As such, cleavage rate to the 2-cell stage represents the earliest uniformly available endpoint across all knockout lines. We have clarified this limitation in the revised manuscript (please see lines 723 - 724).


      REVIEWER #3

      This is technically sophisticated phosphoproteomic study of mouse sperm maturation across the epididymis and during capacitation. The dataset is deep (>14,000 phosphosites) and the analyses integrate high-resolution MS, immunofluorescence, IPA, kinase mapping, pharmacological inhibition, and knockout mouse models. The manuscript represents a nice resource for the field. However, several issues limit clarity, mechanistic interpretation, and robustness of the conclusions. In particular, the manuscript's scope is extremely large, making some conclusions insufficiently supported, and some analyses require better control, methodological transparency, or deeper mechanistic connection. It gives the impression that some mechanistic data was added to descriptive data in order to increase the manuscript's impact, although the current mechanistic data is not convincing.

      Major concerns

      1. Conceptual Overreach - "Epididymal maturation accounts for 86% of phosphorylation changes" The manuscript repeatedly emphasizes that epididymal maturation causes the majority of phosphoproteomic remodeling. While the data indeed show large quantitative differences, several conceptual issues remain:

        • The caput vs. cauda comparison includes differences in protein abundance, not only phosphorylation*
        • Many phosphosites lost in the cauda may reflect protein loss, not dephosphorylation (the authors acknowledge this, but quantitative controls are insufficient)*
        • The normalization method for phosphopeptide abundance vs total protein abundance is needed*
        • It is unclear whether the same amount of starting material and equal protein loading were used across stages I would suggest to perform (or explicitly describe) normalization using matched proteome intensities. Provide supplementary plots showing phosphosite/parent-protein normalization to avoid overinterpreting phosphosite loss as dephosphorylation*

      __Answer: __We thank the reviewer for this important and constructive critique and agree that interpretation of phosphoproteomic changes during epididymal maturation must carefully consider concurrent remodelling of the underlying sperm proteome.

      To directly address the concern that phosphosites lost in the cauda may reflect protein loss, not dephosphorylation, we have now explicitly compared these phosphoproteins lost during caput-to-cauda transit with proteins shown to be lost or reduced over the same maturation window in a previously published matched proteomic analysis of the same sperm populations. This comparison revealed that 527 phosphoproteins, out of a total of 966 phosphoproteins lost, overlapped with proteins lost during epididymal maturation, while a further 88 phosphoproteins aligning with proteins exhibiting reduced abundance during transit. While these data indicate that a subset of phosphosite loss can be attributed to complete loss of the parent protein, the remaining phosphoproteomic changes (45.4%) cannot be fully explained by protein disappearance alone and are therefore consistent with extensive phosphoproteomic remodelling. We have documented this information in a new panel of Supplementary Figure 1 (Figure S1B) and the corresponding text has been revised accordingly (please see lines 182 - 188).

      With respect to normalisation strategies, we respectfully note that normalisation of phosphopeptide intensities to total protein abundance is not universally accepted in large-scale phosphoproteomic analyses (PMID: 30190555, 34857927, 38576152), particularly in systems undergoing extensive proteome remodelling such as maturing spermatozoa. In many contexts, including our own previous work, phosphoproteomic analyses are performed on equal protein input and interpreted at the level of phosphopeptide abundance, with functional relevance established through orthogonal biological validation rather than ratio-based correction to total protein levels.

      Lastly, all samples in this study were diluted to equal total protein amounts prior to phosphopeptide enrichment, ensuring consistent input material across all sperm populations (originally noted in the manuscript, please see line 1339). We have now clarified this explicitly in the Results section to ensure this is not missed (please see lines 146 - 147). Moreover, our conclusions are supported by independent in-silico analyses, pharmacological inhibition studies, and in vivo knockout models, collectively providing functional validation that extends beyond phosphosite quantification alone.

      Finally, to address concerns regarding potential conceptual overreach, we have revised the language surrounding the statement that epididymal maturation accounts for ~86% of phosphorylation changes to ensure precise interpretation. Specifically, we have clarified that this value refers to the proportion of statistically significant differences in phosphopeptide abundance detected across maturation stages, to avoid implying direct measurement of net enzymatic dephosphorylation (please see lines 519 - 520).

      Importantly, having addressed the reviewer's concerns detailed above, we believe the data do support the conclusion that the majority of sperm phosphoproteomic remodelling occurs during epididymal maturation rather than during capacitation. While we have tempered our language to improve clarity, the central quantitative observation that epididymal transit represents the dominant phase of phosphoproteomic remodelling remains supported by the revised analyses.

      • Capacitation analysis is underpowered and oversimplified*

      The authors state that capacitation leads to "modest" changes. However:

        • The capacitation protocol uses dibutyryl-cAMP + pentoxifylline, which may bypass early physiological signaling. This is a important red flag __Answer: __We thank the reviewer for this important point and agree that the choice of capacitation conditions influences the nature and magnitude of signalling events detected. The use of dibutyryl cAMP and pentoxifylline represents a well-established and widely adopted experimental model to induce robust and synchronised capacitation-associated signalling in mouse spermatozoa, acting specifically via the activation of the canonical cAMP/PKA signalling axis (PMID: 36384108, 22458710, 16221991). While we acknowledge that this approach bypasses some upstream physiological signalling events that initiate capacitation during sperm transit of the female reproductive tract, it is intentionally employed to provide a reproducible capacitation stimulus, specifically enabling us to discriminate phosphorylation changes associated with the attainment of sperm fertilization competence. This strategy also directly addresses a limitation of working with mouse spermatozoa in which these cells rapidly succumb to cell senescence/death within a matter of ~1-3 hours in an in vitro* setting. In our previous studies, we have noted that this time period is insufficient to achieve high levels of capacitation among populations of mouse spermatozoa, unless pharmacological agents (i.e. dibutyryl-cAMP + pentoxifylline) are supplemented to accelerate capacitation (PMID: 15252132). This is now a widely accepted paradigm in the field and one that enables us to deliver on our stated objective of assessing the phosphorylation status of fertilization competent spermatozoa, as opposed to those that are captured during early phases of the capacitation cascade.

      Importantly, our conclusion that capacitation is associated with comparatively fewer phosphoproteomic changes is based on direct quantitative comparison with epididymal maturation under identical analytical conditions, and is not intended to downplay the biological importance of this critical maturation event. Even under the capacitation-inducing conditions employed herein, the scale of phosphoproteomic remodelling observed was substantially smaller than that occurring during epididymal transit, underscoring the influence of epididymal maturation over the status of the sperm phosphoproteome.

      To address this concern, we have revised the manuscript to clarify that the capacitation-associated phosphoproteomic changes reported here are specific to the experimental model used and likely represent a conservative estimate of signalling complexity under physiological conditions. We have also tempered language implying generalisation beyond this context (please see lines 329 - 332, 488 - 491, 673 - 677).

      • *

      • Kinase prediction and functional validation require more rigor*

      The identification of 343 kinases that may regulate phospho-changes is extremely broad. Issues:

        • The kinase-substrate assignments rely heavily on in silico predictions (IPA, PhosphoSitePlus), which often contain non-sperm data. __Answer: __We thank the reviewer for this important observation and fully agree that kinase-substrate assignments inferred from in-silico* resources such as IPA and PhosphoSitePlus are largely derived from non-sperm systems and therefore must be interpreted cautiously.

      Importantly, this limitation reflects a broader and well-recognised gap in the field; regrettably comprehensive, experimentally validated kinase-substrate networks do not currently exist for mammalian spermatozoa on this scale, particularly in the context of epididymal maturation and capacitation. The primary objective of the present study was therefore not to define definitive kinase-substrate relationships, but to generate a high-depth, sperm-specific phosphoproteomic resource that can serve as a foundation for hypothesis generation and future mechanistic interrogation.

      Accordingly, in-silico kinase prediction tools were employed to contextualise the phosphoproteomic data and to prioritise candidate kinases for functional testing, rather than to assert sperm-specific kinase-substrate specificity. We have revised the manuscript to clarify that these predictions represent informed starting points in a system where such information is currently lacking, and that functional relevance was subsequently assessed using complementary pharmacological and genetic approaches (please see lines 383 - 388, 682 - 686).

      By providing a deep, stage-resolved phosphoproteomic dataset encompassing more than 14,000 phosphosites, this study establishes a much-needed reference framework for the reproductive biology community, enabling future targeted validation of kinase-substrate relationships in sperm. We believe this resource-based contribution represents a major strength of the work and addresses a critical knowledge gap in the field.

      • *

        • Please explain the rationale by which, from 343 candidate kinases, 3 (STK33, HIPK4, PAK1) are selected.*
        • The pharmacological inhibitors used have off-target effects (ML281 inhibits multiple CMGC kinases; Foretinib inhibits MET/VEGFR; NVS-PAK1-1 inhibits PAK1/2/3).*
        • No control experiments are included to confirm kinase inhibition in sperm (e.g., phosphosite-specific Western blots)* __Answer: __We split this comment from the above, to best address this important critique. We agree that kinase-substrate relationships inferred from phosphoproteomic data must be interpreted with caution. The identification of 343 kinases in this study was not intended to represent a definitive catalogue of all sperm-specific kinase-substrate interactions, but rather to provide insights into kinases that potentially contribute to phosphoproteomic remodelling of mouse spermatozoa during the different phases of their post-testicular maturation. These kinases were identified through integration of multiple complementary approaches, including direct detection within the phosphoproteome, upstream regulator prediction using IPA, curated kinase-substrate databases, and comparison with previously published epididymal sperm proteomes.

      From this broader resource, we deliberately restricted functional interrogation to a small subset of kinases putatively associated with capacitation-induced phosphoproteomic changes. STK33, HIPK4, and PAK1 were selected based on their predicted association with capacitation-specific phosphorylation events, representation across distinct kinase families, lack of prior functional characterisation in terms of either sperm maturation or function, and availability of well-characterised pharmacological inhibitors suitable for functional perturbation. We fully acknowledge that the inhibitors employed are not absolutely kinase-specific and may exhibit off-target effects. Accordingly, we have revised the manuscript to clarify that these experiments are intended to test functional dependence on kinase activity rather than to establish direct kinase-substrate relationships. The observation that combined inhibition of three mechanistically distinct kinases produced a robust and additive suppression of the acrosome reaction supports the conclusion that kinase activity is required for this process, while avoiding overinterpretation of individual kinase specificity.

      We have revised the language throughout the manuscript to more clearly reflect these limitations and to frame the kinase inhibition experiments as functional validation of phosphoproteomic predictions rather than definitive mechanistic proof (please see lines 383 - 388, 405 - 406, 682 - 686, 705 - 710).

      • *

      • *

      • The knockout-mouse validation section is underdeveloped*

      The linkage of KO phenotypes to phosphorylation changes is potentially powerful but currently weak.

      Issues:

        • Most KOs are systemic deletions, not sperm-specific; phenotypes could stem from developmental defects.*
        • Some proteins validated (e.g., ACO2, CMPK1) regulate core metabolism; their phenotypes may not reflect phosphoregulation but loss of essential protein function.*
        • No evidence is provided that the KO affects the specific phosphosites detected in the MS dataset.* __Answer: __We thank the reviewer for this important clarification. We agree that since the knockout models employed represent systemic deletions, they cannot directly resolve sperm-specific or phosphosite-specific mechanisms, and it was not our intention to suggest otherwise. We have revised the manuscript to explicitly frame the knockout phenotypes as evidence of physiological relevance of the identified phosphoproteins, rather than as direct validation of individual phosphorylation events (please see lines 723 - 734).

      We further clarify that for proteins with central metabolic roles, the observed phenotypes likely reflect loss of essential protein function rather than isolated disruption of phosphoregulation. Accordingly, we have tempered our language and emphasise that these data support functional importance while highlighting the need for future studies employing germ cell-specific or phosphosite-targeted models (please see discussion).

      • *

      • Immunofluorescence and Western blots need improved quantification*

      Figures showing PKA substrate, pY, pT, pS changes are visually compelling but lack:

        • quantification across biological replicates*
        • explanation of antibody specificity (e.g., pan-PKA sites include RRXS/T motifs; cross-reactivity possible). __Answer: __We thank the reviewer for this comment and appreciate the emphasis on rigor in antibody-based analyses. We would like to clarify that the immunofluorescence and immunoblot data presented in this study do include densitometric based quantification taking into account data generated from three independent biological replicates. This is indicated by the inclusion of error bars and as stated in the relevant figure captions. (please see lines 1164 - 1168 "All immunoblotting experiments were repeated with at least three biological replicates. Densitometric data normalization was performed against the loading control protein GAPDH, and each value subsequently expressed as a fold change relative to the caput sperm. Data were analyzed by one way ANOVA with GraphPad Prism.).*

      With respect to antibody specificity, we fully agree that phospho-specific and motif-based antibodies have inherent limitations, including epitope ambiguity and the inability to resolve site-specific phosphorylation with amino acid precision (please see our answer to Comment #2 from Reviewer #1 above). For this reason, the antibodies employed here represent well-established, widely used markers in sperm biology and were included to illustrate global phosphorylation trends rather than to validate individual phosphosites. Importantly, quantitative and site-resolved interpretation of phosphorylation dynamics throughout the manuscript is derived from mass spectrometry based phosphoproteomics, which provides substantially greater specificity and resolution than antibody-based approaches.

      • *

      • Many interpretations about metabolism, storage, oxidative stress, and quiescence are speculative*

      The discussion provides attractive models linking phosphorylation to:

        • suppression of glycolysis*
        • quiescent metabolic state in cauda epididymis*
        • activation of antioxidant pathways*
        • UPR and proteostasis modifications However, no direct functional evidence is provided for any of these pathways.*

      __Answer: __We thank the reviewer for this thoughtful observation and agree that several interpretations linking phosphorylation changes to metabolic regulation, oxidative stress, proteostasis, and cellular quiescence are necessarily inferential in the absence of direct functional assays. With this in mind, we have revised the Discussion to more clearly distinguish data-driven observations from hypothesis-generating interpretations and have tempered language accordingly. These models are now explicitly framed as conceptual frameworks arising from large-scale phosphoproteomic analysis, intended to guide future targeted investigation rather than to assert definitive mechanistic conclusions (please see lines 588, 590, 596 - 599, 609, 613, 621 - 625 ).

      Given the breadth and depth of the dataset, only a limited number of functional pathways could be explored experimentally within the scope of the current study. We anticipate that the phosphoproteomic resource generated here, supported by the accompanying ShinySpermPhospho application, will enable the wider community to interrogate additional pathways and to design focused mechanistic studies building on these findings.

      • Acrosome reaction evaluation*

      I have encountered significant deficiencies in this approach. On one side, testing the effect of a single dose of inhibitors on a specific readout is too preliminary, as stated above. In addition, and due to the presence of possible off target effects, more than one inhibitor is expected to be tested, or a direct biochemical assay to confirm at least targeted action. Even KO models, as proposed for other proteins in Figure 7.

      Acrosome reaction values are expected to be presented, as regularly done, by indicating acrosome reacted percentages, without normalizations that complicate understanding. In addition, consider Pg as a more physiological stimulus instead of A23187 for triggering AR.

      __Answer: __We thank the reviewer for these constructive comments and agree that careful assessment of inhibitor effects on sperm viability and motility is essential. We would like to clarify, in case this was overlooked, that these controls were performed and are presented in Supplementary Figure S4. Specifically, sperm were exposed to four concentrations of each inhibitor and assessed over time (0 and 60 minutes) for viability, total motility, and progressive motility. Across all concentrations, time points, and treatment conditions, including combined inhibitor treatments, no significant reductions in sperm viability or motility parameters were observed. These data support the conclusion that the effects on acrosome reaction are not secondary to general sperm toxicity.

      With respect to data presentation, acrosome reaction values were expressed relative to matched capacitated vehicle-treated controls to account for biological variability in absolute acrosome reaction rates observed between independent sperm preparations and experimental days. This normalisation strategy was used to facilitate direct comparison between treatment groups, and respectfully, we have elected to retain this presentation format in Figure 6. Nonetheless, in the interest of transparency, we have now included the raw acrosome reaction values/ranges in the supplementary material (Table S6) and have provide these as a figure to the reviewer for reference.

      We agree that the use of progesterone represents a more physiological stimulus for inducing the acrosome reaction. However, there is no single universally accepted approach for acrosome reaction induction, and calcium ionophore-based assays remain widely used to assess the capacity for acrosomal exocytosis under defined experimental conditions. In the present study, this approach was selected to provide a robust and reproducible functional readout suitable for comparative analysis.

      We have revised the manuscript to more clearly describe the dose-response and viability control experiments, to acknowledge potential off-target effects of kinase inhibitors, and framed the acrosome reaction assays as functional screening experiments rather than definitive mechanistic dissection (please see lines 415, 705 - 710, Table S7).

      • *

      • Figure legend to Figure 7. How many oocytes, how many replicates were performed. How many transfers. Please add important data to the legend.*

      __Answer: __We thank the reviewer for highlighting this omission. In line with comment 4 from Reviewer #1 (please see above), we have revised the Figure 7 legend and Methods section to provide detailed information regarding sample size and experimental design, including the number of oocytes used per IVF experiment performed and the number of biological replicates.

      Specifically, IVF and oocyte isolation procedures were conducted according to standardised INFRAFRONTIER protocols (PMID: 25414328, 27262858, 38839949). Across knockout lines, IVF experiments were performed over 1 - 6 independent cycles per line, with an average of 24.2 oocytes used per cycle. To provide transparency regarding this variability, we have included a new supplementary figure (Figure S6) summarising the average number of oocytes used per IVF cycle alongside the corresponding cleavage rates (%CR).

      Sperm samples used in these assays were derived from cryopreserved cauda epididymal spermatozoa pooled from 10 heterozygous males per knockout line, as per EMMA guidelines (PMID: 17709347). Additionally , where available, we have incorporated reproductive outcome measures at the level of individual litters (e.g. average pup number and sex distribution) to provide further biological context. These additions improve transparency and ensure that the experimental design and data interpretation are clearly defined (please see lines 453 - 457, 1228 - 1234, 1431 - 1444, 1533 - 1536, 1572 - 1575, Figure 7 & S6).

      • *

      This is technically sophisticated phosphoproteomic study of mouse sperm maturation across the epididymis and during capacitation. The dataset is deep (>14,000 phosphosites) and the analyses integrate high-resolution MS, immunofluorescence, IPA, kinase mapping, pharmacological inhibition, and knockout mouse models.

      __Answer: __We thank the reviewer for this positive assessment and for recognising the technical sophistication and integrative nature of the study. We are also grateful for the constructive feedback provided, which has helped us to substantially strengthen the clarity, rigor, and presentation of the manuscript.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #3

      Evidence, reproducibility and clarity

      This is technically sophisticated phosphoproteomic study of mouse sperm maturation across the epididymis and during capacitation. The dataset is deep (>14,000 phosphosites) and the analyses integrate high-resolution MS, immunofluorescence, IPA, kinase mapping, pharmacological inhibition, and knockout mouse models. The manuscript represents a nice resource for the field. However, several issues limit clarity, mechanistic interpretation, and robustness of the conclusions. In particular, the manuscript's scope is extremely large, making some conclusions insufficiently supported, and some analyses require better control, methodological transparency, or deeper mechanistic connection. It gives the impression that some mechanistic data was added to descriptive data in order to increase the manuscript's impact, although the current mechanistic data is not convincing.

      Major concerns

      1. Conceptual Overreach - "Epididymal maturation accounts for 86% of phosphorylation changes" The manuscript repeatedly emphasizes that epididymal maturation causes the majority of phosphoproteomic remodeling. While the data indeed show large quantitative differences, several conceptual issues remain:
        • The caput vs. cauda comparison includes differences in protein abundance, not only phosphorylation.
        • Many phosphosites lost in the cauda may reflect protein loss, not dephosphorylation (the authors acknowledge this, but quantitative controls are insufficient).
        • The normalization method for phosphopeptide abundance vs total protein abundance is needed.
        • It is unclear whether the same amount of starting material and equal protein loading were used across stages.

      I wwould suggest to perform (or explicitly describe) normalization using matched proteome intensities. Provide supplementary plots showing phosphosite/parent-protein normalization to avoid overinterpreting phosphosite loss as dephosphorylation. 2. Capacitation analysis is underpowered and oversimplified The authors state that capacitation leads to "modest" changes. However: - The capacitation protocol uses dibutyryl-cAMP + pentoxifylline, which may bypass early physiological signaling. This is a important red flag 3. Kinase prediction and functional validation require more rigor The identification of 343 kinases that may regulate phospho-changes is extremely broad. Issues: - The kinase-substrate assignments rely heavily on in silico predictions (IPA, PhosphoSitePlus), which often contain non-sperm data. - Please explain the rationale by which, from 343 candidate kinases, 3 (STK33, HIPK4, PAK1) are selected. - The pharmacological inhibitors used have off-target effects (ML281 inhibits multiple CMGC kinases; Foretinib inhibits MET/VEGFR; NVS-PAK1-1 inhibits PAK1/2/3). - No control experiments are included to confirm kinase inhibition in sperm (e.g., phosphosite-specific Western blots). 4. The knockout-mouse validation section is underdeveloped The linkage of KO phenotypes to phosphorylation changes is potentially powerful but currently weak. Issues: - Most KOs are systemic deletions, not sperm-specific; phenotypes could stem from developmental defects. - Some proteins validated (e.g., ACO2, CMPK1) regulate core metabolism; their phenotypes may not reflect phosphoregulation but loss of essential protein function. - No evidence is provided that the KO affects the specific phosphosites detected in the MS dataset. 5. Immunofluorescence and Western blots need improved quantification Figures showing PKA substrate, pY, pT, pS changes are visually compelling but lack: - quantification across biological replicates - explanation of antibody specificity (e.g., pan-PKA sites include RRXS/T motifs; cross-reactivity possible). 6. Many interpretations about metabolism, storage, oxidative stress, and quiescence are speculative The discussion provides attractive models linking phosphorylation to: - suppression of glycolysis - quiescent metabolic state in cauda epididymis - activation of antioxidant pathways - UPR and proteostasis modifications However, no direct functional evidence is provided for any of these pathways. 7. Acrosome reaction evaluation I have encountered significant deficiencies in this approach. On one side, testing the effect of a single dose of inhibitors on a specific readout is too preliminary, as stated above. In addition, and due to the presence of possible off target effects, more than one inhibitor is expected to be tested, or a direct biochemical assay to confirm at least targeted action. Even KO models, as proposed for other proteins in Figure 7. Acrosome reaction values are expected to be presented, as regularly done, by indicating acrosome reacted percentages, without normalizations that complicate understanding. In addition, consider Pg as a more physiological stimulus instead of A23187 for triggering AR. 8. Figure legend to Figure 7. How many oocytes, how many replicates were performed. How many transfers. Please add important data to the legend.

      Significance

      This is technically sophisticated phosphoproteomic study of mouse sperm maturation across the epididymis and during capacitation. The dataset is deep (>14,000 phosphosites) and the analyses integrate high-resolution MS, immunofluorescence, IPA, kinase mapping, pharmacological inhibition, and knockout mouse models.

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      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      In this manuscript, the authors examine dynamic modifications of the sperm phosphoproteome during epididymal transit and capacitation. They compare three distinct populations differing in anatomical localization and activation status: caput sperm, non‑capacitated cauda sperm, and capacitated cauda sperm. Using high‑resolution tandem mass spectrometry, they reveal that phosphorylation changes during epididymal passage are far more extensive than previously appreciated. These findings are further validated in genetically modified animal models, where disruption of selected genes encoding for phosphoproteins results in marked defects in sperm motility and fertilization capacity.

      Major points:

      Throughout the text, and particularly in the paragraph entitled 'Epididymal maturation accounts for the majority of maturation‑associated sperm cell signaling,' it seems that phosphorylation is interpreted as inherently activatory and dephosphorylation as inhibitory (lines 248-252). Since this relationship is not universally applicable, it would be valuable to address this issue at the outset of the paragraph and to discuss how phosphorylation events are context‑dependent in their effects on protein function.

      Lines 392-393: the claim that "the introduction of each inhibitor to populations of capacitating spermatozoa led to a significant reduction..." is not fully supported by data and should be toned down. In fact, two out of three inhibitors, do not significantly affect the acrosome reaction.

      The discussion section, spanning 11 pages, is overly long and contains considerable repetition. I recommend transferring the detailed description of experiments to the 'Results' section and using the discussion primarily to synthesize and highlight the novel findings while limiting speculative content. For example, the content in lines 509-530 could be condensed and relocated to the Results. Likewise, other detailed examples would be more appropriately presented within their respective result paragraphs.

      Minor points:

      • To improve reproducibility, the suppliers of all reagents should be specified together with their catalogue numbers.
      • Figure 7: it is unclear which data are statistically significant
      • Figure 7B: fertilization capacity should be assessed at an earlier stage, as the cleavage rate to 2-cell embryo may be affected by factors unrelated to the sperm ability to fertilize

      Significance

      A key novel finding of this work is that extensive changes in the sperm phosphoproteome occur during epididymal maturation, whereas capacitation is associated with comparatively modest modifications. This research provides a finely resolved description of phosphorylation events associated with the signaling pathways underlying functional sperm maturation. The methodological innovation -high‑resolution MS‑based phosphoproteomics- unlocks a level of detail and comprehensiveness in phosphorylation analysis that was previously unattainable. Moreover, the identification of previously unrecognized phosphoproteins in sperm cells, together with the development of a dedicated application hosting the complete dataset, represents a valuable resource for researchers in reproductive biology and particularly for experts in sperm development and maturation.

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      Referee #1

      Evidence, reproducibility and clarity

      The manuscript by Skerrett-Byrne and collaborators represents a comprehensive and technically sophisticated phosphoproteomics study. Using high-resolution mass spectrometry on mouse sperm obtained from the caput and cauda regions of the epididymis, both before and after capacitation, the authors generated a more complete database of phosphorylation changes in these cells. One of the most interesting outcomes is that most of these changes occur during sperm maturation, rather than sperm capacitation. The work is important and relevant, and the information obtained could be valuable for reproductive biologists working in basic science, as well as for the identification of novel contraceptive targets.

      Minor comments:

      1) The title should include a reference to sperm capacitation, as most of the study focuses on comparisons between epididymal maturation and capacitation, and the functional experiments are based on the latter.

      2) Considering the newly reported changes in phosphosites, it would be desirable to include validation at the individual protein level for at least a few examples, using an independent technique such as western blotting.

      3) In the knockout models, it is not possible to distinguish between defects in spermatogenesis and those arising during maturation or capacitation. A parameter directly related to spermatogenesis should therefore be included, for example, testicular weight or histology, sperm number, and sperm morphology.

      4) Error values, sample size, and statistical analyses are missing from Figure 7 and should be provided for clarity.

      Significance

      This study shows by high-resolution phosphoproteomics that most phosphorylation changes occur during epididymal transit rather than capacitation, challenging long-standing assumptions. The integration of the new datasets with functional validation of key kinases and knockout models strengthens the study; however, the work lacks single-protein validation of phosphorylation events, and the use of systemic knockouts does not allow confirmation of sperm-specific effects. The open ShinySpermPhospho dataset will be worthwhile to a broad audience of reproductive biologists and cell signaling specialists, and may be of value for future studies on male fertility and the development of novel male contraceptives.

      Field of expertise: reproductive physiology, sperm biology and capacitation, gamete interaction.

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      Reply to the reviewers

      We thank the reviewers and we are glad that they acknowledge this work to be a timely contribution to a quickly moving field and a valuable tool to generate testable hypothesis. We are pleased that reviewer #2 highlights that “a major strength is the combination of orthogonal evidence types” and that the tool serves to generate novel hypothesis. The revised manuscript will sharpen the positioning of the study within this context. Additional experimental evidence will be provided to address the points raised by reviewers #1 and #3.

      Reviewer #1* 1.The authors do not co-IP ARF1. This does not surprise me as small GTPases often hydrolyse their GTP during lysis. *

      We agree that this is likely due to transient association and GTP hydrolysis during lysis and will add a section to the manuscript.

      There have been a number of ARF1 bioID screens done- have the authors checked if their complex has turned up here?

      We will include this in the revised manuscript.

      1. I am a bit confused by some of the interpretation about KO and loss of JTB staining. They interpret: "The SYS1 acts as a Golgi recruitment factor for both ARFRP1 and JTB". The ARFRP1 has been published and is a cytosolic protein, so that makes sense. However, the JTB is not cytosolic by a membrane protein, so cannot be "recruited". Now maybe it is retained in the Golgi by this interaction, but if that is the case you would still expect signal on another organelle or the plasma membrane (and we see it isnt degraded in the lysosome due to the western blot). I am confused by the authors model here.

      We will clarify the phrasing and will provide a clearer interpretation, also considering the other improved imaging experiments that will be included in the revised manuscript.

      4.The authors validate their JTB antibody and confirm the fact that there are not reduced SYS1 levels in the JTBKO- this is very clear (albeit unquantified). What I do not see validated is the SYS1KO. I think this is quite important.

      We will validate SYS1 KO using TIDE and/or western blotting.

      5.The colocalisation in panel 3D is weak and unclear to me. It is not quantified. It is not clear if there have been 3 repeats.

      The revised manuscript will include improved imaging data. We will repeat relevant experiments, include appropriate controls and quantify where necessary.

      6.The imaging in figure 3 is not clear in places, and it stands out in a very clear manuscript. I cannot see the JTB in panel F. There are no scale bars. The dynamic range of the image is not utalised. I do not see the stain in the JTB in either of the sys1 KO, i do not see the SYS1-FLAG staining in the complement, and it is not quantified at all. It may all seem trivial, but (to me) this is an absolutely critical bit of biology data to support the informatics.

      The revised manuscript will include improved imaging data. We will repeat relevant experiments, include appropriate controls and quantify where necessary.

      7.I am a bit unconvinced by the interpretation of it being a retrograde trafficking complex. This is for 2 key reasons- 1) the VSV-G is antrograde (despite unusually they interpret a "severe defect in retrograde transport"). 2) Even if it was only having an effect in the retrograde direction I would still remain a little open minded about it as you can easily mistake trafficking of a protein in one direction for another if an unknown protein (SNARE for example) has defective trafficking.

      We used VSVG-KDEL in this assay. This setup specifically measures retrograde trafficking. We will clarify this in the revised manuscript. We will clarify in the Discussion that we confirmed a role in retrograde trafficking but cannot exclude a role in anterograde trafficking

      Reviewer #2

      Major comment: scope and interpretation of DepMap-derived functional evidence The manuscript could benefit from more clearly defining the scope of the functional evidence used to nominate complexes. The central co-dependency signal is derived from DepMap 24Q2 CRISPR gene-effect profiles, which are primarily cancer cell-line fitness/proliferation data. This is an important limitation because the resulting correlations may preferentially capture complexes or pathways that influence viability in proliferating cancer cells, while missing complexes active in differentiated, tissue-specific, stimulus-dependent, or non-proliferative contexts. Conversely, some correlations may reflect shared cancer-lineage or fitness dependencies rather than direct participation in a stable complex. The authors are appropriately cautious in stating that DepCom is not a complete inventory of human protein complexes, but the title, framing, and resource description could still be read as implying a more general catalogue of functional protein complexes. The authors might consider adding a clearer introduction to DepMap and explicitly discuss how the cancer-cell-line origin of the data affects interpretation of the 518 predicted complexes. This could be addressed without new experiments, for example by adding text early in the Results section explaining what the CRISPR gene-effect scores measure, and by expanding the Discussion to clarify that DepCom represents structurally plausible complexes prioritized by co-dependency across cancer cell lines, rather than an unbiased or context-independent map of human protein complexes. The selection of highlighted examples would also benefit from clearer justification. The peroxisome, actin, WNK/TSC22D2, and Golgi/JASS examples are biologically interesting, but the rationale for choosing them is not always explicit. Were they selected because they were novel, high-confidence, disease-associated, experimentally tractable, or representative of different resource categories? Briefly stating the selection criteria would help readers understand whether these examples are illustrative case studies or representative outcomes of the pipeline.

      We agree with the reviewers' assessment that this resource should be viewed as hypothesis-generating and that the overall framing should be improved. We will revise the manuscript at the appropriate sections, according to the more detailed comments of all reviewers.

      Minor comments

      1. Clarify post-clustering removal of large/problematic protein families and complexes. In the Methods, the authors state that "clusters of histones and keratin clusters, as well as the mito-ribosome, complexes of the electron transport chain and the mediator complex" were removed because of their large sizes. This filtering step would benefit from additional detail. Please specify the criteria used to define these removed clusters, how many clusters/proteins were removed at this stage, and whether removal was based only on size or also on biological/manual curation. It would also be helpful to explain why these proteins or clusters were removed after clustering rather than excluded before graph construction and clustering, since highly connected or compositionally biased protein families could potentially influence neighboring cluster assignments. If available, a brief robustness check showing that pre-removal of these proteins gives similar candidate complexes would strengthen confidence in the clustering procedure.

      We will add the requested information to the relevant section. Alongside the manuscript we will also provide lists of the complexes before and after every filtering step

      1. Clarify the rationale for excluding complexes larger than 5000 residues. The 5000-residue cutoff is understandable for AF3 computational cost, but the manuscript should briefly state how many candidate complexes were excluded by this cutoff and whether this preferentially removes known large assemblies. This would help readers understand the scope of complexes that DepCom is expected to miss.

      Alongside the manuscript we will now also provide lists of the complexes before and after every filtering step.

      1. Improve wording in the CAP1/CFL1/WDR1/ACTB example. The sentence "Additionally, CAP1 works in concert with CFL1 to accelerate depolymerisation, though if a four-protein complex consisting of actin, WDR1, CAP1 and CFL1 is relevant is not clear" is difficult to parse. Possible revision might be something like: "Additionally, CAP1 works in concert with CFL1 to accelerate depolymerisation, although it remains unclear whether actin, WDR1, CAP1 and CFL1 form a stable four-protein complex in cells." This more clearly separates known biology from the speculative interpretation of the DepCom prediction.

      Wording will be improved.

      1. Improve reproducibility details for AF3 predictions. The Methods state that predictions were run using a local AF3 installation, but reproducibility would be improved by reporting relevant AF3 settings, number of seeds/models per complex, whether templates were used, how disordered regions were handled, and whether predictions were repeated for all complexes or only selected examples. This is especially important because the manuscript notes that multiple predictions can yield different subunit arrangements.

      We will provide detailed settings in the methods section. Regarding disordered parts: All predictions used full length sequences (canonical UNIPROT ID) for each protein, so disordered residues are included. If disordered regions have low PLDDT and poor PAE, these regions will simply not score as interfaces in AlphaBridge. The one exception where we did crop structures is Figure 2D, but purely for visualization purposes, the full length complex did score in the pipeline (uncropped).

      Reviewer #3

      Co-essentiality is not the same as physical complex membership. This is the biggest conceptual concern. Genes in the same pathway are co-essential whether or not their products bind. The authors lean on the structural prediction step to filter this out, but that means the entire pipeline rests on AF3+AlphaBridge being correct about who interacts with whom. There is no independent benchmarking shown of how often AlphaBridge calls a true positive vs a false positive at the chosen 0.5 cutoff. Why 0.5? Where does that number come from? A short benchmarking section using known complexes (CORUM 5.0, hu.MAP 2.0, the PDB) would make the choice defensible. Right now it reads as arbitrary.

      We thank the reviewer for bringing up the need for such an important clarification. We fully agree that co-essentiality does not equal physical interaction and structure predictions are imperfect. This is precisely the logic underlying our pipeline design, not a limitation we overlooked. The two data sources are used sequentially and serve distinct roles: first, we construct protein sets that are connected through networks of predicted binary physical interactions; then we cluster these based on DepMap correlations, selecting likely physical complexes that display co-essentiality between their components.

      In other words, clustering on DepMap data alone would certainly return many spurious correlations: as the referee points out “Co-essentiality is not the same as physical complex membership”. Anchoring the search space with structural predictions substantially reduces this noise. Neither data source alone is sufficient, nor do we claim either is definitively "correct": the value lies in their combination. We hope improved phrasing in the revised manuscript will highlight this better.

      Regarding benchmarking AlphaBridge score: we have benchmarked AlphaBridge, in response to reviewer feedback on the original AlphaBridge paper (Structure, Cell Press). In the figure here it is clear that in our benchmark of PDB structures (with

      Comparison to existing resources is incomplete. I can't help but wonder what was found here that would not have been possible by analysing existing resources. CORUM 5.0 (7,193 mammalian complexes, ~71% human-derived; Tsitsiridis et al. 2024 NAR), hu.MAP 2.0 (Drew et al. 2021, ~6,965 complexes from >15,000 MS experiments), BioPlex 3.0 (Huttlin et al. 2021, 118,162 interactions in HEK293T), ad the Complex Portal already cover a large fraction of the human complexome. The authors compare to PDB, the original interactome paper, and Complex Portal, but they explicitly skip CORUM and hu.MAP, both of which are central reference resources in this space. Without including these, the "60 complexes unique to DepCom" number is not really meaningful. This needs to be redone properly.

      We will add the comparison with Corum and hu-MAP in the revision.

      Validation rate is one out of 518. The JASS work is solid, but a single experimentally validated complex out of 518 gives the reader essentially no estimate of how often the rest of the predictions are correct. Even a smaller systematic effort, say IP-MS on five to ten predicted novel complexes in the same cell line, would do an enormous amount to establish how trustworthy the resource is. The authors already have the V5/IP-MS pipeline running. Right now the manuscript implicitly asks the reader to trust 517 predictions on the strength of one validation.

      In this paper we validated one out of the 60 complexes we claim are new. Notably we provide new biological data and demonstrate how consulting our resource, or following the same logic of combining functional and structural information, can lead to new exciting discoveries. We note that out of the 518 complexes we list, 69 complexes are exactly mirrored in the PDB and/or Complex Portal, while for another 389 there is partial evidence. Thus, our dataset is amply validated, and at the same time contains data to enable new discoveries. We also note, that following the release of our resource eight months ago, a new high-impact publication “validated” a complex we have independently picked in DepMap (Oosterheert et al, Choreography of rapid actin filament by coronin, cofilin and AIP1, Cell, 2025). We will rephrase relevant sections (also in response to reviewer 2) to increase clarity about validation.

      The functional and disease clustering is potentially circular. GO terms and STRING associations are themselves derived in large part from the published literature on protein function, including text mining channels in STRING, much of which is downstream of complex membership. Of course complexes cluster into "DNA repair" and "vesicle trafficking" if you cluster on GO and STRING. The same applies to Open Targets, which integrates GWAS Catalog, ClinVar, literature mining, and other sources. The clustering is fine as a navigation aid for the website, but it is not, as currently presented, an independent validation of anything. I would tone the discussion down accordingly.

      We did not mean to present the clustering as an independent validation. We will tone down the discussion accordingly.

      AF3 limitations on this class of problem. AF3 itself acknowledges limitations (Abramson et al. 2024, including the December 2024 addendum), and subsequent benchmarking has flagged disordered regions, dynamic/large assemblies, and certain transmembrane systems as known weak points. The JASS complex is largely transmembrane, the WNK1-TSC22D2 example involves disorder-to-order transitions, and several flagship examples involve large multi-domain proteins. The authors acknowledge some of this in passing but should state explicitly which complexes were trimmed, how the trimming choices were made, and whether predictions were repeated with different seeds to check stability. Figure S4 is a good start, but for a resource paper a more systematic seed-stability analysis is warranted.

      No complexes were trimmed for the initial AF3 predictions. The WNK1-TSC22D2 example was trimmed and re-predicted only for visualization purposes. We apologize for the misunderstanding and will state this more clearly.

      AF3 certainly has limitations. Regarding disordered regions, these will almost always be assigned a poor pLDDT (also if AF3 wrongly folds them into helices). AlphaBridge will not pickup these low pLDDT regions as interfaces. Regarding dynamic assemblies, these might again lead to poor confidence scores and consequently these will not be picked up as interfaces by AlphaBridge. If AF3 confidence metrics are analyzed properly, the main concern for both disordered regions and dynamic assemblies is to miss true positive interactions, rather than finding false positive. As we did not aim to identify all possible human complexes, we consider focusing on the most confidently predicted interactions to be a fair trade off.

      While the JASS complex is indeed a membrane protein complex, the predictions are exceptionally confident across multiple seeds (we can provide predictions from multiple seeds for revision), and validates experimentally. Of course, structure predictions are no substitute for experimental structures, as cautioned multiple times throughout the manuscript.

      Figure S4 shows that despite the complex overall geometry being flexible, the interaction sites are predicted with high confidence across different poses. Since the aim of this study was to identify proteins interacting with each other, not accurate structures (which need to be solved experimentally), we argue that recomputing all structures with multiple seeds is disproportionately expensive computationally and would delay publication of a timely study while adding little.

      Statistics are thin in several places. On the Fisher exact test for Golgi/ER enrichment in V5-JTB IP-MS (Supplemental Table 1), an odds ratio of 2.77 is modest, and there is no comparison to a matched control IP. Is this more than expected by chance against an appropriate background? The IP-MS volcano plots show many significant proteins, but how was the background controlled? On the LLM section, no quantitative evaluation is presented at all and the assessment is admitted to be subjective.

      We will qualify the conclusions drawn from the IP-MS experiments. We maintain that together with the additional cell biology data, we build a compelling and convincing picture for this JASS complex.

      Experimentally, the background is controlled by measuring enrichment over WT cell lines that have undergone the same IP procedure as the V5-SYS1/JTB expressing cells (lysis, incubation with the anti-V5 conjugated beads, same wash procedure and sample processing), as is the standard in the field. We will clarify in the Methods section. Regarding identification, FDR rate was set to 1% at protein and peptide level and peptide spectrum matches (PSMs) were additionally filtered for SequestHT Xcorr score >1.

      We agree with the referee that the LLM interpretation is subjective and cannot be benchmarked. We suggest revising the resource and the paper, only providing structured LLM prompts to facilitate users asking the right questions, but we will not provide the LLM answers as part of the resource.

      The 4�ACTB speculation. The authors themselves note the AlphaBridge score declines from 0.9 (1�ACTB) to 0.78 (4�ACTB), yet they speculate about functional implications. This is exactly the kind of post-hoc rationalisation around weak evidence that should either be supported with experiment or removed. Either remove or qualify as speculative.

      We will qualify this as speculative

      The LLM-assisted analysis. I am genuinely uncomfortable with releasing 76 LLM-generated complex annotations as part of a published resource when the authors openly state these have "not been systematically validated". Putting these summaries on a website with the imprimatur of a peer-reviewed paper will lead to them being cited and reused. At minimum, the website needs prominent warnings on every page where an LLM summary appears, the prompts must be fully reproducible (not just downloadable as JSON), and a small validation table, say 10 complexes scored by a domain expert for accuracy of each claim, should be included as a supplemental figure. As it stands this section reads like an enthusiastic add-on that has not been thought through with the same care as the rest of the work.

      We thank the referee for bringing forward this consideration. We agree to remove the LLM answers for the 78 complexes from the manuscript and from the website, to ensure that the outputs cannot be cited. We will provide two different objective structure prompts for download to encourage variety in responses for curious users who want to explore. We will add a prominent disclaimer noting that responses resulting from these prompts cannot be interpreted as facts without validation.

      We cannot guarantee reproducibility with modern LLM inference architecture. Even if seeds are kept the same and temperature=0, floating-point non-determinism in GPU operations, distributed inference, and batch effects may lead to different results. Furthermore, models go through many different iterations rapidly. As a consequence, it is impossible for us to guarantee reproducibility

      Cutoffs and cluster numbers need stability analysis. The cutoff for the 75th-percentile DepMap correlation (mean of random + 3 SD = 0.147) is reasonable but should be accompanied by an FDR or precision/recall estimate against a labelled reference set. The choice of 20 final clusters in functional clustering (because that gave a peak in silhouette score) and 14 for disease clustering should also be supported by stability analysis, e.g. resampling.

      The 75th percentile cutoff is, in our opinion, well justified and sufficient for our purposes. FDR and precision recall need a set of true and false positives. The DepMap correlation clusters are an intermediate step in our pipeline and do not necessarily hold the final complexes. How can intermediate reference DepMap clusters be constructed and defined as true or false positives? Even if we would score clusters that contain a known complex as true positives, how to define false positives? If clusters do not contain a known complex, that does not necessarily mean that these proteins don’t interact, just that they have not been shown to interact yet.

      We will run resampling to improve confidence in the choice of cluster number.

      Internal numerical consistency. The bioRxiv preprint abstract refers to 354 high-confidence multi-protein complexes, while the body of the manuscript discusses 518 (224 dimers + 294 multimers). The relationship between these numbers should be stated explicitly. Likewise, the breakdown of "60 unique to DepCom" into 41 heterodimers + 19 multimeric should be reconcilable in the figures and tables. The number "9,764 unique seed proteins" should also be clarified to confirm it is the DepCom-internal seed set and not inherited from the Zhang et al. coverage or hu.MAP 2.0 (9,963 proteins). These are easy fixes but matter for a resource paper.

      BioRxiv preprint: The preprint that the reviewer read is an older version, which will be updated. .

      The 9,764 unique seed proteins is from the Zhang et al paper, and are the human proteins identified to confidently interact with at least one other human protein. We will make this more clear.

      Mander's overlap coefficient. The VSV-G(ts045)-KDELR retrograde-transport assay is well established and the experiment is clean, but MOC has been increasingly criticised in the colocalisation literature (Adler & Parmryd 2010, 2021). Best practice is to also report Manders' M1/M2 coefficients or Pearson's correlation alongside MOC. Adding these would be straightforward and would strengthen Fig 4B.

      We will improve co-localization measures where appropriate.

      Minor comments 1. Page 4: "candidate sets of potential multi-protein complex members". Pick one, they are either candidates or potential, not both.

      Will be addressed.

      Page 7: "Complex 294... mechanistic basis for CFL1 and WDR1 cooperation has only recently been described". Please update the reference list and language given how recent this is.

      Will be addressed.

      Page 7: JTB is described as "poorly characterised". This is a bit too strong. JTB has been studied in the context of TGF-β-induced mitochondrial regulation (Kanome et al. 2007), cytokinesis and chromosomal passenger complex association (Platica et al. 2011), the structural characterisation of its extracellular domain (Rousseau et al. 2012), and breast cancer biomarker work (Jayathirtha et al. 2022). A more accurate framing would be "incompletely characterised, with previously reported but functionally unresolved roles". The novelty here is the Golgi connection, which is genuine.

      We will rephrase.

      Page 8: the citation of Blomen et al. 2015 Science for "Golgi-related synthetic lethality" should be checked against the actual supplementary data of that paper to confirm the JTB attribution is correct.

      Will be check.

      Figure 1: as in many omics papers, please think of us colourblind readers. The pink-green DepMap correlation scale will be hard for some of us.

      The color scheme in use, alongside others, was tested with two colleagues that have different variants of colour blindness and was judged to be the best compromise.

      Figure 5A and 5B: 21 and 14 colour-coded clusters respectively in a single UMAP is too much. Consider splitting into separate panels by broad theme or providing an interactive version only.

      We will focus on a subsection, and provide the full interactive version on the homepage

      Page 11: "manually evaluated the quality of outputs". By whom, blinded to which model produced which output? Methods are silent on this.

      As stated above, we will remove the LLM part

      Some figures show "hairballs" with very limited informative content. Fig. 1B left panel and the AlphaBridge wheel plots in particular convey relatively little at the size shown.

      We will try and find a way to draw the AlphaBridge circular plots in better resolution; we do not however that the reviewer’s observation might be an artefact of the PDF file distributed to reviewers.

      The reference list looks a bit thin on prior systematic complexome efforts. BioPlex 3.0 (Huttlin et al. 2021 Cell), hu.MAP 2.0 (Drew et al. 2021 MSB) and CORUM 5.0 (Tsitsiridis et al. 2024 NAR) should all be cited and discussed.

      We will include the additional references where appropriate

      The discussion section drifts into general comments about AI in science that don't add much. I would cut about a third of it and use the space for a more careful framing of the actual contribution.

      We will shorten the discussion section and phrase more carefully.

      General assessment Reviewer #3: The strongest aspect of this study is the JASS complex story. The IP-MS, the SYS1-KO rescue experiment, the VSV-G(ts045)-KDELR transport assay, and the orthogonal CRISPR screens with diphtheria and Pseudomonas exotoxins together build a convincing case for JTB as a regulator of Golgi-to-ER retrograde trafficking. This part of the paper is genuinely nice work and would stand on its own. The pipeline itself, combining structural predictions with functional dependency data and filtering with AlphaBridge, is sensible and timely. It is a reasonable demonstration of how confidence filtering should be done at this kind of scale. The main limitations concern the resource framing. After reading the manuscript several times I am still trying to identify the central novel contribution beyond the JASS validation. The interactome predictions are taken from Zhang et al., DepMap is public, AF3 is public, AlphaBridge is the authors' own previously published tool, and GO/STRING/Open Targets/dbPTM are all public. The manuscript is essentially an integrative pipeline plus a website plus one experimentally followed-up complex. The framing oversells what is genuinely new. The authors' own comparison (Fig. S3) shows 60 complexes "unique to DepCom" out of 518, of which 41 are heterodimers and only 19 are multimeric. Nineteen genuinely novel multi-protein complexes is still a contribution but it is a long way from the 354/518 that the abstract and discussion implicitly emphasise. The validation rate (one of 518) and the missing comparisons to CORUM 5.0 and hu.MAP 2.0 are the two issues that most need addressing.

      We will rephrase these issue to adjust the framing. We would put forward that the main contribution of this manuscript is to present an integrative framework that combines data from orthogonal sources to highlight the possibility of structure prediction models to serve as a discovery tool. The reviewer identifies correctly (albeit derogatorily) that this is “essentially” an integrative pipeline. But it is an integrative pipeline that combines genetics and computational structure predictions in a novel (to the best of our knowledge) way and surfaces interesting new biology. The biology of the JASS complex goes well-beyond simple validation experiments, and we believe its discovery (based on our data) carries more value that the reviewer attributes to it.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      Uckelmann and colleagues combine the recently published binary human interactome predictions from Zhang et al. (2025) with co-essentiality data from DepMap CRISPR screens to nominate sets of proteins that may form higher-order complexes. They cluster proteins around each "seed" using Leiden community detection on the DepMap correlation matrix, run AlphaFold3 on each candidate set, and apply AlphaBridge to retain only those interfaces predicted with confidence. After filtering they arrive at 518 complexes, of which 224 are dimers and 294 are larger assemblies (note: the abstract of the bioRxiv preprint refers to 354 high-confidence complexes, so the relationship between these numbers should be made explicit). They illustrate the resource with a few worked examples (PEX3/16/19/ACBD5, an actin-CFL1-WDR1-CAP1 assembly, a WNK1-NRBP1-TSC22D2 complex), and they experimentally validate one previously uncharacterised assembly that they name JASS (JTB-ARFRP1-SYS1), placing JTB at the Golgi and showing a role for it in Golgi-to-ER retrograde transport. They also provide a web portal (depcom.eu) with PTM mapping, GO/STRING-based functional clustering, Open Targets disease clustering, and LLM-generated executive summaries.

      Major comments:

      I am supportive of integrating orthogonal datasets in this kind of framework, but I am much less enthusiastic about how the analyses are carried through, and I think there are several issues that need adressing before this work is publishable.

      1. Co-essentiality is not the same as physical complex membership. This is the biggest conceptual concern. Genes in the same pathway are co-essential whether or not their products bind. The authors lean on the structural prediction step to filter this out, but that means the entire pipeline rests on AF3+AlphaBridge being correct about who interacts with whom. There is no independent benchmarking shown of how often AlphaBridge calls a true positive vs a false positive at the chosen 0.5 cutoff. Why 0.5? Where does that number come from? A short benchmarking section using known complexes (CORUM 5.0, hu.MAP 2.0, the PDB) would make the choice defensible. Right now it reads as arbitrary.
      2. Comparison to existing resources is incomplete. I can't help but wonder what was found here that would not have been possible by analysing existing resources. CORUM 5.0 (7,193 mammalian complexes, ~71% human-derived; Tsitsiridis et al. 2024 NAR), hu.MAP 2.0 (Drew et al. 2021, ~6,965 complexes from >15,000 MS experiments), BioPlex 3.0 (Huttlin et al. 2021, 118,162 interactions in HEK293T), and the Complex Portal already cover a large fraction of the human complexome. The authors compare to PDB, the original interactome paper, and Complex Portal, but they explicitly skip CORUM and hu.MAP, both of which are central reference resources in this space. Without including these, the "60 complexes unique to DepCom" number is not really meaningful. This needs to be redone properly.
      3. Validation rate is one out of 518. The JASS work is solid, but a single experimentally validated complex out of 518 gives the reader essentially no estimate of how often the rest of the predictions are correct. Even a smaller systematic effort, say IP-MS on five to ten predicted novel complexes in the same cell line, would do an enormous amount to establish how trustworthy the resource is. The authors already have the V5/IP-MS pipeline running. Right now the manuscript implicitly asks the reader to trust 517 predictions on the strength of one validation.
      4. The functional and disease clustering is potentially circular. GO terms and STRING associations are themselves derived in large part from the published literature on protein function, including text mining channels in STRING, much of which is downstream of complex membership. Of course complexes cluster into "DNA repair" and "vesicle trafficking" if you cluster on GO and STRING. The same applies to Open Targets, which integrates GWAS Catalog, ClinVar, literature mining, and other sources. The clustering is fine as a navigation aid for the website, but it is not, as currently presented, an independent validation of anything. I would tone the discussion down accordingly.
      5. AF3 limitations on this class of problem. AF3 itself acknowledges limitations (Abramson et al. 2024, including the December 2024 addendum), and subsequent benchmarking has flagged disordered regions, dynamic/large assemblies, and certain transmembrane systems as known weak points. The JASS complex is largely transmembrane, the WNK1-TSC22D2 example involves disorder-to-order transitions, and several flagship examples involve large multi-domain proteins. The authors acknowledge some of this in passing but should state explicitly which complexes were trimmed, how the trimming choices were made, and whether predictions were repeated with different seeds to check stability. Figure S4 is a good start, but for a resource paper a more systematic seed-stability analysis is warranted.
      6. Statistics are thin in several places. On the Fisher exact test for Golgi/ER enrichment in V5-JTB IP-MS (Supplemental Table 1), an odds ratio of 2.77 is modest, and there is no comparison to a matched control IP. Is this more than expected by chance against an appropriate background? The IP-MS volcano plots show many significant proteins, but how was the background controlled? On the LLM section, no quantitative evaluation is presented at all and the assessment is admitted to be subjective.
      7. The 4×ACTB speculation. The authors themselves note the AlphaBridge score declines from 0.9 (1×ACTB) to 0.78 (4×ACTB), yet they speculate about functional implications. This is exactly the kind of post-hoc rationalisation around weak evidence that should either be supported with experiment or removed. Either remove or qualify as speculative.
      8. The LLM-assisted analysis. I am genuinely uncomfortable with releasing 76 LLM-generated complex annotations as part of a published resource when the authors openly state these have "not been systematically validated". Putting these summaries on a website with the imprimatur of a peer-reviewed paper will lead to them being cited and reused. At minimum, the website needs prominent warnings on every page where an LLM summary appears, the prompts must be fully reproducible (not just downloadable as JSON), and a small validation table, say 10 complexes scored by a domain expert for accuracy of each claim, should be included as a supplemental figure. As it stands this section reads like an enthusiastic add-on that has not been thought through with the same care as the rest of the work.
      9. Cutoffs and cluster numbers need stability analysis. The cutoff for the 75th-percentile DepMap correlation (mean of random + 3 SD = 0.147) is reasonable but should be accompanied by an FDR or precision/recall estimate against a labelled reference set. The choice of 20 final clusters in functional clustering (because that gave a peak in silhouette score) and 14 for disease clustering should also be supported by stability analysis, e.g. resampling.
      10. Internal numerical consistency. The bioRxiv preprint abstract refers to 354 high-confidence multi-protein complexes, while the body of the manuscript discusses 518 (224 dimers + 294 multimers). The relationship between these numbers should be stated explicitly. Likewise, the breakdown of "60 unique to DepCom" into 41 heterodimers + 19 multimeric should be reconcilable in the figures and tables. The number "9,764 unique seed proteins" should also be clarified to confirm it is the DepCom-internal seed set and not inherited from the Zhang et al. coverage or hu.MAP 2.0 (9,963 proteins). These are easy fixes but matter for a resource paper.
      11. Mander's overlap coefficient. The VSV-G(ts045)-KDELR retrograde-transport assay is well established and the experiment is clean, but MOC has been increasingly criticised in the colocalisation literature (Adler & Parmryd 2010, 2021). Best practice is to also report Manders' M1/M2 coefficients or Pearson's correlation alongside MOC. Adding these would be straightforward and would strengthen Fig 4B.

      Minor comments

      1. Page 4: "candidate sets of potential multi-protein complex members". Pick one, they are either candidates or potential, not both.
      2. Page 7: "Complex 294... mechanistic basis for CFL1 and WDR1 cooperation has only recently been described". Please update the reference list and language given how recent this is.
      3. Page 7: JTB is described as "poorly characterised". This is a bit too strong. JTB has been studied in the context of TGF-β-induced mitochondrial regulation (Kanome et al. 2007), cytokinesis and chromosomal passenger complex association (Platica et al. 2011), the structural characterisation of its extracellular domain (Rousseau et al. 2012), and breast cancer biomarker work (Jayathirtha et al. 2022). A more accurate framing would be "incompletely characterised, with previously reported but functionally unresolved roles". The novelty here is the Golgi connection, which is genuine.
      4. Page 8: the citation of Blomen et al. 2015 Science for "Golgi-related synthetic lethality" should be checked against the actual supplementary data of that paper to confirm the JTB attribution is correct.
      5. Figure 1: as in many omics papers, please think of us colourblind readers. The pink-green DepMap correlation scale will be hard for some of us.
      6. Figure 5A and 5B: 21 and 14 colour-coded clusters respectively in a single UMAP is too much. Consider splitting into separate panels by broad theme or providing an interactive version only.
      7. Page 11: "manually evaluated the quality of outputs". By whom, blinded to which model produced which output? Methods are silent on this.
      8. Some figures show "hairballs" with very limited informative content. Fig. 1B left panel and the AlphaBridge wheel plots in particular convey relatively little at the size shown.
      9. The reference list looks a bit thin on prior systematic complexome efforts. BioPlex 3.0 (Huttlin et al. 2021 Cell), hu.MAP 2.0 (Drew et al. 2021 MSB) and CORUM 5.0 (Tsitsiridis et al. 2024 NAR) should all be cited and discussed.
      10. The discussion section drifts into general comments about AI in science that don't add much. I would cut about a third of it and use the space for a more careful framing of the actual contribution.

      Significance

      General assessment:

      The strongest aspect of this study is the JASS complex story. The IP-MS, the SYS1-KO rescue experiment, the VSV-G(ts045)-KDELR transport assay, and the orthogonal CRISPR screens with diphtheria and Pseudomonas exotoxins together build a convincing case for JTB as a regulator of Golgi-to-ER retrograde trafficking. This part of the paper is genuinely nice work and would stand on its own. The pipeline itself, combining structural predictions with functional dependency data and filtering with AlphaBridge, is sensible and timely. It is a reasonable demonstration of how confidence filtering should be done at this kind of scale.

      The main limitations concern the resource framing. After reading the manuscript several times I am still trying to identify the central novel contribution beyond the JASS validation. The interactome predictions are taken from Zhang et al., DepMap is public, AF3 is public, AlphaBridge is the authors' own previously published tool, and GO/STRING/Open Targets/dbPTM are all public. The manuscript is essentially an integrative pipeline plus a website plus one experimentally followed-up complex. The framing oversells what is genuinely new. The authors' own comparison (Fig. S3) shows 60 complexes "unique to DepCom" out of 518, of which 41 are heterodimers and only 19 are multimeric. Nineteen genuinely novel multi-protein complexes is still a contribution but it is a long way from the 354/518 that the abstract and discussion implicitly emphasise. The validation rate (one of 518) and the missing comparisons to CORUM 5.0 and hu.MAP 2.0 are the two issues that most need addressing.

      Advance:

      The advance is incremental rather than conceptual. The idea of intersecting co-essentiality with structural predictions is sensible but not new in spirit, and similar hybrid approaches are now becoming more common in this space (see e.g. EndoMAP.v1, Gonzalez-Lozano et al. 2025 Nature, which the authors do cite). What is new here is the specific implementation, the AlphaBridge filtering layer, and the JASS finding. The technical advance lies in the AlphaBridge filtering step on top of AF3 at a reasonably large scale. The biological advance is the JASS complex and the demonstration that JTB plays a role in Golgi-to-ER retrograde transport, which is genuinely new and well supported.

      Audience:

      This work will be of interest mainly to specialised audiences in structural proteomics, computational biology of protein complexes, and the protein-protein interaction community. The JASS finding will be of interest to a broader readership in cell biology, particularly those working on Golgi trafficking, ARF/ARL family GTPases, and retrograde transport. The web resource will likely find users among researchers studying specific complexes who want a quick structural hypothesis. I do not think the work, in its current form, will reach broad audiences in the way the authors hope, but a more sober framing would actually help it land better in the specialist community where it belong.

      My expertise:

      Mass spectrometry-based proteomics, protein-protein interaction mapping, systems biology, structural biology. I have working knowledge but not deep expertise in: structural prediction confidence metrics (AF3, AlphaBridge implementation details), DepMap CRISPR co-essentiality analysis, and Golgi cell biology. I would defer to a computational structural biology or cell biology specialist on the AF3 confidence interpretation details and on the cell biology specifics of the JASS validation.

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      Referee #2

      Evidence, reproducibility and clarity

      The study presents DepCom as a broad resource for discovering human multi-protein complexes by integrating predicted binary interactions, DepMap co-dependency, AF3 modelling, and AlphaBridge filtering. Overall, the computational strategy is well motivated, and the experimental validation of the JTB/SYS1/ARFRP1 complex provides a compelling example of how the resource can generate testable biological hypotheses.

      Major comment: scope and interpretation of DepMap-derived functional evidence

      The manuscript could benefit from more clearly defining the scope of the functional evidence used to nominate complexes. The central co-dependency signal is derived from DepMap 24Q2 CRISPR gene-effect profiles, which are primarily cancer cell-line fitness/proliferation data. This is an important limitation because the resulting correlations may preferentially capture complexes or pathways that influence viability in proliferating cancer cells, while missing complexes active in differentiated, tissue-specific, stimulus-dependent, or non-proliferative contexts. Conversely, some correlations may reflect shared cancer-lineage or fitness dependencies rather than direct participation in a stable complex. The authors are appropriately cautious in stating that DepCom is not a complete inventory of human protein complexes, but the title, framing, and resource description could still be read as implying a more general catalogue of functional protein complexes. The authors might consider adding a clearer introduction to DepMap and explicitly discuss how the cancer-cell-line origin of the data affects interpretation of the 518 predicted complexes. This could be addressed without new experiments, for example by adding text early in the Results section explaining what the CRISPR gene-effect scores measure, and by expanding the Discussion to clarify that DepCom represents structurally plausible complexes prioritized by co-dependency across cancer cell lines, rather than an unbiased or context-independent map of human protein complexes. The selection of highlighted examples would also benefit from clearer justification. The peroxisome, actin, WNK/TSC22D2, and Golgi/JASS examples are biologically interesting, but the rationale for choosing them is not always explicit. Were they selected because they were novel, high-confidence, disease-associated, experimentally tractable, or representative of different resource categories? Briefly stating the selection criteria would help readers understand whether these examples are illustrative case studies or representative outcomes of the pipeline.

      Minor comments

      1. Clarify post-clustering removal of large/problematic protein families and complexes.

      In the Methods, the authors state that "clusters of histones and keratin clusters, as well as the mito-ribosome, complexes of the electron transport chain and the mediator complex" were removed because of their large sizes. This filtering step would benefit from additional detail. Please specify the criteria used to define these removed clusters, how many clusters/proteins were removed at this stage, and whether removal was based only on size or also on biological/manual curation. It would also be helpful to explain why these proteins or clusters were removed after clustering rather than excluded before graph construction and clustering, since highly connected or compositionally biased protein families could potentially influence neighboring cluster assignments. If available, a brief robustness check showing that pre-removal of these proteins gives similar candidate complexes would strengthen confidence in the clustering procedure. 2. Clarify the rationale for excluding complexes larger than 5000 residues.

      The 5000-residue cutoff is understandable for AF3 computational cost, but the manuscript should briefly state how many candidate complexes were excluded by this cutoff and whether this preferentially removes known large assemblies. This would help readers understand the scope of complexes that DepCom is expected to miss. 3. Improve wording in the CAP1/CFL1/WDR1/ACTB example.

      The sentence "Additionally, CAP1 works in concert with CFL1 to accelerate depolymerisation, though if a four-protein complex consisting of actin, WDR1, CAP1 and CFL1 is relevant is not clear" is difficult to parse. Possible revision might be something like: "Additionally, CAP1 works in concert with CFL1 to accelerate depolymerisation, although it remains unclear whether actin, WDR1, CAP1 and CFL1 form a stable four-protein complex in cells." This more clearly separates known biology from the speculative interpretation of the DepCom prediction. 4. Improve reproducibility details for AF3 predictions.

      The Methods state that predictions were run using a local AF3 installation, but reproducibility would be improved by reporting relevant AF3 settings, number of seeds/models per complex, whether templates were used, how disordered regions were handled, and whether predictions were repeated for all complexes or only selected examples. This is especially important because the manuscript notes that multiple predictions can yield different subunit arrangements.-

      Significance

      General assessment:

      This study presents a timely and useful resource for prioritizing candidate human protein complexes by integrating predicted binary protein-protein interactions, DepMap co-dependency profiles, AlphaFold3 structure prediction, and AlphaBridge confidence filtering. A major strength is the combination of orthogonal evidence types: physical interaction predictions define a tractable search space, functional co-dependency helps identify coherent protein groups, and structure-confidence metrics provide an additional filter on the resulting candidates. The experimental validation of the JTB/SYS1/ARFRP1 complex is also a strong aspect of the study, as it demonstrates that the resource can generate biologically meaningful and experimentally testable hypotheses.

      The main limitation is that the resource should be interpreted as a prioritized, hypothesis-generating dataset rather than a comprehensive or context-independent catalogue of human protein complexes. As noted above, the DepMap-derived signal reflects cancer cell-line fitness/proliferation dependencies, and the final complex set is also shaped by the starting interactome, filtering choices, and computational constraints on complex size. These limitations do not undermine the utility of the resource, but they should be clearly framed for readers.

      One aspect that could further increase the impact and usability of the study is the DepCom web resource. The searchable table of complexes is already useful, particularly for users who want to query by gene or protein name. However, the website also presents functional and disease-based clustering, and many users may want to search or filter complexes by biological process, GO term, pathway, disease association, or disease cluster. Adding GO-term and disease-association fields to the main table, and allowing users to search/filter by these annotations, would make the resource more discoverable and useful to researchers approaching the dataset from a biological process or disease area rather than from a specific gene.

      Advance:

      The advance is primarily technical and resource-oriented, with an accompanying functional biological demonstration. The study helps fill a gap between large-scale binary interaction prediction and the more difficult problem of nominating higher-order assemblies. By using functional dependency profiles to prioritize multi-protein combinations before structure prediction, the authors reduce an otherwise intractable search space and generate a set of structurally plausible candidate complexes. The JASS complex and the proposed role of JTB in Golgi-to-ER retrograde trafficking provide a compelling example of biological discovery enabled by the pipeline.

      The broader DepCom resource, including predicted complex structures, AlphaBridge interface-confidence information, PTM-interface mapping, functional/disease clustering, and downloadable LLM prompts, should provide useful starting points for follow-up studies. These outputs are best viewed as hypothesis-generating rather than definitive biological annotation, but they represent a valuable extension of existing protein-interaction and structure-prediction resources.

      Audience:

      The study will likely interest a broad basic-research audience, especially researchers in protein complex biology, structural biology, functional genomics, systems biology, cancer dependency mapping, cell biology, and computational biology. It may also be useful to investigators studying specific pathways or poorly characterized proteins, since the resource provides candidate interaction partners and structural hypotheses that can guide experiments. The translational relevance is more indirect, mainly through disease-association clustering and potential target-discovery applications, but the immediate audience is likely to be basic and computational researchers.

      My expertise is in computational protein databases, protein domain classification, structural/evolutionary analysis of proteins, and functional annotation resources, including experience with the ECOD database for evolutionary classification of protein domains. I am less able to evaluate the fine details the experimental cell-biology assays beyond their general interpretation and reporting.

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      Referee #1

      Evidence, reproducibility and clarity

      Characterising protein complexes is a fundamental goal in modern molecular cell biology. Here, Uckelmann and colleagues have presented a solution to part of this problem. By combining functional clustering with alphafold modelling, they present a high throughput bioinformatic solution. The paper and figures are exceptionally clear and well presented. The conclusions are reasonable, and the data interesting. I am a cell biologist with expertise in molecular machinery of trafficking, so the focus of my review will be on the identification of a new complex, that is proposed to have a role in retrograde trafficking. On the whole I find this a interesting and convincing finding. However I have some comments and questions that I hope may help the authors. I will naturally focus my comments on the cell biology.

      1.The authors do not co-IP ARF1. This does not surprise me as small GTPases often hydrolyse their GTP during lysis. 2.There have been a number of ARF1 bioID screens done- have the authors checked if their complex has turned up here? 3.I am a bit confused by some of the interpretation about KO and loss of JTB staining. They interpret: "The SYS1 acts as a Golgi recruitment factor for both ARFRP1 and JTB". The ARFRP1 has been published and is a cytosolic protein, so that makes sense. However, the JTB is not cytosolic by a membrane protein, so cannot be "recruited". Now maybe it is retained in the Golgi by this interaction, but if that is the case you would still expect signal on another organelle or the plasma membrane (and we see it isnt degraded in the lysosome due to the western blot). I am confused by the authors model here. 4.The authors validate their JTB antibody and confirm the fact that there are not reduced SYS1 levels in the JTBKO- this is very clear (albeit unquantified). What I do not see validated is the SYS1KO. I think this is quite important. 5.The colocalisation in panel 3D is weak and unclear to me. It is not quantified. It is not clear if there have been 3 repeats. 6.The imaging in figure 3 is not clear in places, and it stands out in a very clear manuscript. I cannot see the JTB in panel F. There are no scale bars. The dynamic range of the image is not utalised. I do not see the stain in the JTB in either of the sys1 KO, i do not see the SYS1-FLAG staining in the complement, and it is not quantified at all. It may all seem trivial, but (to me) this is an absolutely critical bit of biology data to support the informatics. 7.I am a bit unconvinced by the interpretation of it being a retrograde trafficking complex. This is for 2 key reasons- 1) the VSV-G is antrograde (despite unusually they interpret a "severe defect in retrograde transport"). 2) Even if it was only having an effect in the retrograde direction I would still remain a little open minded about it as you can easily mistake trafficking of a protein in one direction for another if an unknown protein (SNARE for example) has defective trafficking.

      Significance

      Characterising protein complexes is a fundamental goal in modern molecular cell biology. Here, Uckelmann and colleagues have presented a solution to part of this problem. By combining functional clustering with alphafold modelling, they present a high throughput bioinformatic solution. The paper and figures are exceptionally clear and well presented. The conclusions are reasonable, and the data interesting. I am a cell biologist with expertise in molecular machinery of trafficking, so the focus of my review will be on the identification of a new complex, that is proposed to have a role in retrograde trafficking. On the whole I find this a interesting and convincing finding.

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      Reply to the reviewers

      Reviewer #1

      Summary: This manuscript has presented a high-throughput fluorescence recovery after photobleaching (HiT-FRAP) platform to screen genes affecting the dynamics of the nucleolar scaffold nucleophosmin (NPM1). The platform included the siRNA-based screening of 65 RNA helicases, 9 phylogenetically related helicase pairs, and 290 ribosomal proteins along with selected assembly factors. These factors were classified as those accelerating or decelerating NPM1 dynamics based on the t1/2 measurements. Combined with nucleolar morphological changes, the authors identified that depletion of early-stage (A-F) and later-stage (G-H) LSU assembly factors resulted in different nucleolar phenotypes, suggesting the pre-ribosome assembly can impact nucleolar morphology. Further exploring the potential mechanis m suggested that the NPM1's intrinsically disordered region (IDR) contributed to the nucleolar organization and dynamics.

      Together, this well-designed study uncovered that the ribosome assembly, both the early and late ribosomal precursors can influence biophysical properties of the nucleolus. Below please find our concerns for the authors to consider to strengthen the major conclusions.

      Major comments:

      The main conclusion that NPM1's biophysical states directly impact its interaction strength with ribosome intermediates (and thereby nucleolar dynamics) should be further strengthened as listed below:

      1). Given the nucleolus's complexity, an additional GC factor, or/and one more marker of other nucleolar regions, should be examined to substantiate the proposed impact of LSU-associated factors on nucleolar morphology (Figures 3, 4).

      We thank the reviewer for this very important point. We have now included representative images for representative hits in major phenotypic clusters co-stained for SURF6, another GC marker, which shows similar localization patterns as NPM1 (Fig. S4B). For other nucleolar subcompartments, we have included images obtained from a cell line harboring endogenously tagged FBL-mNeonGreen (a marker for the DFC) for representative hits (Fig. S4A). We see a similar overall distribution of the DFC within the GC (i.e. DFCs distribute to fill the area of the disrupted GC), confirming our screen results. We look forward to further examining the changes in nucleolar subcompartment architecture in future work.

      As additional support, we note that we probed NOG2, NOP53, and NOP2 in our IF results, all of which are GC-localized factors. We see a very similar distribution for these factors in our hits as for NPM1 (see Fig. S8D). In addition, FISH data for pre-rRNA precursors show similar morphological patterns as NPM1, further confirming our results (Fig. S7). We have noted this in text and have also included representative images in supplement.

      2). Additional experiments are needed to support the proposed model that ribosomal intermediates, especially the pre-LSU complexes could determine nucleolar biophysical properties through the interaction with NPM1. Their direct interaction by biochemical assays should be provided. Also, when analyzing the interaction with other nucleolar factors, the authors should provide data that show NPM1 mutant expression levels were comparable to endogenous levels (Figures 4, 6).

      We agree that directly probing NPM1's interactions with LSU precursors is critical to supporting our model, and we have addressed this through several complementary biochemical approaches. First, we performed immunoprecipitation of tagged NPM1 (NPM1-mScarlet, IP-ed using RFP-trap agarose) and assessed interaction with pre-LSU rRNA transcripts via Northern blot (Fig. 5D). We find that NPM1 interacts strongly with the 32S pre-rRNA. Second, we performed sucrose gradient sedimentation and find that NPM1 preferentially co-migrates with pre-60S complexes (Fig. 5B). Together with previous reports of NPM1-pre-LSU interactions, these data provide direct biochemical support for the proposed interaction.

      To test whether interaction strength with pre-LSUs could regulate NPM1 dynamics, we next asked whether our NPM1 mutants that differ in their dynamics in turn interact differentially with pre-LSU complexes. Using co-IP Northern blot for ITS2 and sucrose co-sedimentation, we find that NPM1 mA3 pulls down more 32S and co-sediments more robustly with pre-60S complexes, while NPM1 mB2 shows reduced association (Fig. 5D, E; Fig. S10F, G). These data support that the strength of the NPM1-pre-LSU interaction is a determinant of NPM1 exchange dynamics, and, by extension, of nucleolar biophysical properties.

      Exogenous mutant NPM1 is expressed at approximately 10% of endogenous levels (Fig. S10A). We address this in two ways. First, all interaction comparisons are made between WT and mutant exogenous constructs, not against endogenous NPM1, controlling for expression level differences. Second, we observe similar effects on interactions both in the presence of endogenous NPM1 and in null backgrounds, indicating that the differences we detect reflect NPM1 mutation, not expression level.

      3). Northern Blotting should be done to dissect which pre-rRNA intermediates interact with NPM1 and contribute to the nucleolar dynamics (Figures 4B, D, F). These additional experiments should be feasible within a reasonable timeframe.

      We agree with the reviewer and have performed northern blots for major hits in our different nucleolar phenotypes, and results reinforce what we see by FISH and qPCR (Fig. S6B). Briefly, depletion of the “RNA Exosome” hit SKIV2L2 results in smearing of pre-rRNA precursors that harbor both ITS1 and ITS2 and an accumulation of the 12S, in keeping with its role in end-processing of these transcripts. For “Other” hit PHF5A, we see an enrichment for 47S/45S/41S species, consistent with an early precursor stall. Notably, we do not see this phenotype for depletion of “Other” hit CNOT1, which suggests multiple processing defects may lead to a similar nucleolar phenotype. Treatment with PolI inhibitor CX5461 shows a depletion in ITS1 containing transcripts, and minimal impact on ITS2-containing transcripts, similar to FISH results. Lastly, depletion of “LSU” hits NOP53 and RPF2 leads to accumulation of the 32S and 12S species, in keeping with accumulation of abortive pre-LSUs.

      In addition, the authors should provide the code and the hardware control procedures for HiT-FRAP to ensure reproducibility.

      We thank the reviewer for this thoughtful suggestion. We have made our software available on GitHub (https://github.com/jess-sheu/colony_blob_bleacher) and archived on Zenodo

      (https://doi.org/10.5281/zenodo.20275447).

      According to the authors' statement, all the experiments are adequately replicated, and the statistical analysis is adequate.

      Minor comments:

      To enhance clarity and focus, consider the following:

      1). Simplifying the HiT-FRAP screening section (Fig. 1-3) would emphasize the significant findings.

      We have simplified text throughout to better highlight significant findings.

      2). Expanding analysis and experimental validation could help to solidify the interdependency between rRNA / ribosome precursors and the NPM1- driven nucleolar dynamics (Fig. 4-5). Indeed, additional experiments suggested above in the major concerns should be supplemented here.

      We have performed additional experiments to demonstrate the interdependency between ribosomal precursors and their interaction with NPM1 in shaping nucleolar dynamics, as described above.

      Reviewer #1 (Significance (Required)):

      This work has established a powerful toolkit, named HiT-FRAP, to identify factors involved in the organization and regulation of the membrane-less nucleolus, which will be useful for understanding the complexity not only the nucleolus, but likely other condensates in cells in the future. Using this platform and with the Granular Component (GC)-localized NPM1 as an indicator of nucleolar morphology, the authors found that the biophysical properties of the nucleolus are sensitive to the ordered assembly of ribosomes, in particular the LSU maturation steps at the GC. This finding is important as it suggests the interdependency between the dynamic rRNA processing and the functional assembly and morphology of the nucleolus. Further studies are warranted to analyze the dynamics of other nucleolar constituents, particularly those localized at other sub-nucleolar regions, to fully depict how exactly the nucleolar function is coordinated with its biophysical properties.

      Reviewer #2

      Reviewer #2 (Evidence, reproducibility and clarity (Required)):

      Summary: The nucleolus is a multiphase biomolecular condensate whose primary function is ribosome biogenesis. There are mounting evidences that the material state of condensates is important for their function. Here the authors have probed how the material property of the nucleolus responds to inhibitions of ribosome biogenesis.

      They have assessed nucleolar dynamics (molecular diffusivity) of a nucleolar protein, NPM1, by fluorescence recovery after photobleaching (FRAP). NPM1 is a protein that labels the periphery of the nucleolus (the so-called granular component, GC). (The nucleolus has 3 main subcompartments: the internal fibrillar centers, the middle dense fibrillar components, and the GC).

      One of the main findings of the work is that inhibition of late steps of ribosome biogenesis increases fluidity (faster recovery of NPM1), while inhibition of earlier (and inhibition of mRNA processing -but see below) rather increases rigidification (slower recovery). They then attempt to correlate what is interpreted as biophysical changes to pre-ribosomal intermediates and interaction with NPM1.

      Practically, the authors have produced reporter cell lines (HeLa) expressing stably (CRISPR engineering) mono or bi-allelic fluorescent version of NPM1; they have developed a powerful platform to conduct high throughout FRAP (this is really good); they have calibrated their system, initially with basic perturbations (ATP depletion, proteasome inhibition, etc), and then they focused on a family of trans-acting factors: the helicases, investigating systematically their effect on NPM1 recovery. They then extended their initial candidate-based screen to additional factors (using STRING interactions). This is nice and useful. Later in the work, they include in their analysis additional (morphological) features of nucleoli to cluster functionally their hits, as was done earlier by others in similar works. Finally, using recently published structural data (CryoEM), they attempt to correlate groups in the cluster with particular pre-ribosomal species. This part is less advanced and weaker than the initial part of the paper (screens and FRAP measurements).

      Major comments:

      -A major comment is with the compositional analysis of precursor intermediates that should be better defined. The stage assignment of particles is not quite as good as the screening part of the paper. At the RNA level, the authors provided FISH, as histograms of quantifications (see e.g. Fig 4D, and Fig SS6E). It would be necessary to show images, and to perform biochemistry. At the protein level, the authors provide immunostaining, but it does not really prove the detected protein is part of a particle,..

      We thank the reviewer for this important critique. We have taken several steps to address both the stage assignment and biochemical characterization concerns.

      Regarding stage assignment: We have consolidated our LSU phenotypic clusters (previously LSU1 and LSU2) into a single "late pre-LSU" group based on their shared features and proximity in PCA space. We want to be clear that this consolidation is intended to more accurately represent what our data can support: the screen reliably identifies factors whose perturbation produces a coherent late LSU assembly phenotype, and we do not wish to overstate the resolution of state assignment from imaging data alone. Sub-cluster distinctions are retained in supplementary materials for transparency. We have revised language throughout to reflect this framing.

      Regarding biochemical characterization of intermediates: We have now performed Northern blots on strong hits within our phenotypic groups (Fig. S6B). For LSU cluster hits, we observe accumulation of the 32S and 12S species, indicating a stall in ITS2 processing, which is directly consistent with our ITS2 FISH results and confirms that the RNA-level phenotypes reflect genuine pre-rRNA processing defects rather than indirect effects. For "Other" group factor PHF5A, we observe 47/45/41S accumulation consistent with an early processing stall. We have also added representative FISH images to Fig. S7 to allow direct visual assessment of RNA-level phenotypes.

      Regarding protein-level particle assignment: We agree that IF alone cannot establish that assembly factors are incorporated into discrete pre-ribosomal particles rather than existing as free factors. To more directly test whether the LSU cluster phenotypes reflect accumulation of genuine pre-ribosomal particles rather than mislocalized free factors we used NOP53 knockdown as a representative LSU cluster perturbation and, similar to RPF2 knockdown, see an accumulation of ITS2 and NOG2 in the nucleolus by FISH and IF (Fig. 4E). We then performed nuclear sucrose gradient fractionation and found that NOG2 co-migrates with the LSU peak and does not enrich in soluble fractions (Fig. 4F-H), supporting the interpretation that late pre-LSU particles accumulate in the nucleolus upon disruption of LSU cluster genes. Importantly, we also observe a strong decrease in co-sedimentation of NPM1 with the LSU peak upon depletion of NOP53 (Fig. 4G,H). This result, together with the Northern blot and FISH data, provides biochemical and cell biological evidence that the nucleolar phenotypes we identified by HiT-FRAP are associated with accumulation of late LSU assembly intermediates.

      -Another concern is to know if NPM: a GC component located periphery of the condensate and a late assembly factor is an appropriate marker for assessing the effects on nucleolar material state of all (including early and late) inhibitions.

      Would factors involved in earlier ribosomal assembly steps, and localized more internally would not be better tools to evaluate change in material states caused by alterations in early steps?

      We appreciate this important point and agree that NPM1 reports primarily on GC dynamics. However, we would argue this is a feature rather than a limitation for two reasons.

      First, the GC is the terminal assembly compartment through which pre-ribosomal particles must transit before nuclear export. Perturbations to earlier assembly steps, including FC/DFC-localized processes, likely propagate into GC dynamics, because stalled or aberrant particles accumulate in or are excluded from the GC. NPM1 FRAP thus functions as a downstream integrator of upstream assembly status, not only a reporter of GC-proximal events. This interpretation is consistent with our observation that depletion of early factors (and, therefore, depletion of downstream intermediates) do produce detectable NPM1 phenotypes in our screen. Second, the pattern of our screen results supports rather than undermines this logic: the striking enrichment of late LSU factors and near-complete absence of SSU hits is precisely what one would predict if NPM1 reports selectively on pre-LSU flux through the GC. A sensor that reported indiscriminately on all condensate perturbations would not produce this specificity.

      We do acknowledge, however, that NPM1 cannot report on material state changes that are compartmentally confined to the FC or DFC and do not propagate outward. Extending this approach to internal markers remains an important future direction. To clarify the scope of our readout, we have revised the text to specify that we are monitoring GC dynamics, and we have added representative images of fibrillarin localization in Supplemental Figure S4A to illustrate the relationship between DFC and GC compartments in our experimental system.

      -About the engineered cell lines used for screening by FRAP (Fig 1S): NPM1-mNeonGreen (biallelic with reduced expression of NPM1) and mScarlet (heterozygous): There is a need to characterize pre-rRNA processing in both cell lines to show they are not affected for ribosome biogenesis. This is important information since the entire work is based on these cells.

      We have performed a Northern blot across the cell lines used in this paper as compared to their parent cell line and see no substantial difference in rRNA processing. We have included this data as Supplemental Figure 1D.

      The screening cells are HeLa cells implying they are not physiologically regulated for p53. Nucleolar surveillance is a key regulatory surveillance loop triggered by ribosome biogenesis inhibitions leading to p53 stabilisation. How could this affect this work? Should key findings be confirmed in diploid p53 positive cells?

      We acknowledge that our choice of HeLa cells limits our ability to distinguish cell-type-specific responses from more universal mechanisms and have added an explicit discussion of cell choice in the main text. To begin exploring the impact of p53, we performed gene depletions for representative hits across phenotypic clusters in untransformed, diploid hTERT-RPE cells that were lentivirally-transduced with NPM1-mScarlet and assessed nucleolar morphological phenotypes at smaller scale (Figure S6C, Supplementary Text). At baseline, RPE cells show more and smaller nucleoli than HeLa cells, which may reflect a difference in basal nucleolar assembly and, potentially, ribosome biogenesis, in keeping with previous observations that transformed cells rely more heavily on ribosome biogenesis than non-transformed.

      Upon gene depletion, we found that hits from the "RNA exosome" cluster shows a different phenotype than seen in HeLa cells, where we observe less size difference and a marked decrease in eccentricity, which may reflect a p53 or cell type specific response. Depletion of the “Other” cluster gene PHF5A results in a milder though qualitatively similar phenotype as seen in HeLa cells, with nucleolar rounding and an increase in NPM1 intensity. Depletion of “LSU”-associated hits in RPE cells very robustly replicated most of the nucleolar features we observed in HeLa, which suggest that these are likely generalizable responses to LSU disruption. We have included this data in Supplementary Figure 5C. We note that we did not directly test whether p53 is stabilized upon depletion of our hits in RPE cells, and whether p53 activation feeds back on condensate dynamics remains an open area for future work. However, the concordance of LSU-associated phenotypes across HeLa and RPE cells, which differ substantially in p53 status, transformation state, and baseline nucleolar architecture, supports the generalizability of our core findings.

      -About factor depletion, e.g. helicases, it's important to consider direct versus indirect effects on ribosome biogenesis, the timeline of depletion should be well described in the paper. Apparently, most factors, including the helicases were depleted for 72 hours, this is very long considering most of them play important roles in essential processes for cell homeostasis implying severely reduced growth at the time of capture (and the possibility of indirect effects).

      We thank the reviewer for this important point. To directly address depletion timeline, we performed time courses for strong hits and monitored nucleolar morphology at 24 and 48 hour intervals (now included in Fig. S3D). Morphological changes begin to emerge by 48 hours across phenotypic classes; for the RPF2 LSU phenotype specifically, nucleolar expansion and decreased NPM1 intensity are detectable as early as 24 hours, inconsistent with a general stress response and more consistent with a direct downstream consequence of LSU assembly disruption. Moreover, despite all targeted genes being essential for homeostasis, phenotypic profiles are cluster-specific and associated with multiple genes of coherent function, which suggests that observed impacts are downstream of specific pathway inhibition rather than a general cellular stress response.

      -Another cause of concern is that some perturbations (factor depletion) affect very deeply nucleolar structure/morphology (eg uL2 depletion shown in Fig 2C); how easy/difficult was it to control/make sure that a correct area was obliterated in the FRAP experiment using the (remarkable) data-adaptive approach. For cases where the nucleolus was deeply affected how did you check that a significant nucleolar area had been selected for analysis? It would be good to describe this in the text.

      We manually ensured our segmentation protocol accurately captured nucleoli, defined by higher intensity regions of NPM1, for all depletion cases during screen development. As this is the key factor in ensuring where the bleach point is, most bleaches, even in disrupted cases, bleached the nucleolar interior. To address this point, we have included figures in the supplement (Fig. S4D) that show bleaching time courses for select highly disrupted hits uL2 and eL39.

      • Fig 6C, interaction of NPM1 constructs with pre-ribosomes: the authors have tested interaction with select nucleolar proteins (NOP53, NOP2, NOG2, and uL2), which is not the same as preribosomes.

      It would be important to see the interactions with precursors (Fig S9C, now histograms) please show the actual data, this was tested by qPCR, please show classical northern blots as RTqPCR have shown their limits in such applications.

      Indeed, we cannot distinguish between assembly factors/ribosomal proteins that are associated with NPM1 in their latent, non-pre-LSU bound state versus those that are part of a developing ribosome. We have addressed this gap in several ways. Firstly, we have performed IP-northern blots for tagged NPM1-mutants, as suggested, and find that the mA3 mutant co-IPs more 32S than WT, while the mB2 binds less (Fig. 5D). We also performed sucrose gradient analysis of pre-ribosomal complexes and find that the mA3 mutant co-sediments more with the pre-60S peak, while mB2 co-sediments less (Fig. 5E). These findings are consistent with in vitro findings in the field that B2 mediates interactions with rRNA, while A3 occludes B2 through intramolecular interactions. Collectively with our co-IP western data, we believe the evidence strongly suggests that NPM1 mutants interact differentially with pre-LSU complexes.

      -Minor comments:

      -The effects of mRNA processing disruption on nucleolar dynamics could be (is most likely) very indirect (the so-called "slow hits"). The respective time course of inhibitions is important to describe.

      We direct the reviewer to our response above for other phenotypes. For our "slow hit" / "Other" cluster, we also used the splicing inhibitor PladB as an orthogonal approach. Strikingly, nucleolar rounding was detectable within less than one hour of treatment, well before any general cell health effects would be expected, while dynamics changes required approximately 24 hours — suggesting that morphological and biophysical responses are kinetically separable and that the early morphological response is directly downstream of splicing inhibition. We have included a representative rounding timecourse in Fig. S8E.

      Reviewer #2 (Significance (Required)):

      -General assessment: strengths and limitations

      Strengths: -The automated platform for high throughput FRAP\

      -The authors develop a potentially interesting model where they attempt to connect rigidification/fluidity of a condensate to its function in assembly of large ribonucleoprotein complexes. -The manuscript reads very well; it has been prepared with great care (figures). Some complicated concepts are explained very well (Introduction/Discussion). Limitations: -particle stage assignment based on FISH and immunostaining only. The authors have not demonstrated that the LSU1 cluster = state F and LSU2 cluster = states G/H

      -Advance: -Technological advance, high throughput FRAP, a powerful platform to interrogate macromolecular diffusivity.

      -Several nucleolar screens have been conducted in the past (but at steady-state, not using FRAP), in these works textural and morphological features were used together with dimensionality reduction techniques to define functional clusters of genes that impact the homeostasis of the nucleolus. Often these references are cited but it could be useful to expand a bit on some of the earlier findings to bring the new ones in perspective. Some clusters (typically, the transcriptional cluster that disrupts the nucleolus; and the late binder ribosomal proteins) have been well identified before.

      -Audience: Cell biologists, scientists involved in ribosome biogenesis research, scientists with an interest in helicases. The growing condensate community.

      -Describe your expertise: ribosome biogenesis, structure-function relationships in the nucleolus, technological development in microscopy.

      Reviewer #3 (Evidence, reproducibility and clarity (Required)):

      Summary: The authors use high throughput FRAP (HiT-FRAP) in arrayed genetic screens of HeLa cells expressing nucleophosmin (NPM1)-fluorescent protein variants to monitor the biophysical properties of the nucleolus in response to genetic perturbations. HiT-FRAP uses a data adaptive imaging strategy to automatically identify and photobleach fluorescently labeled organelles in living cells and acquire movies for FRAP. Quantitative analysis of FRAP curves include t1/2 and mobile fraction. NPM1 was monitored since it is an important nucleolar scaffolding protein that is thought to interact with many pre-ribosome intermediates.

      The authors depleted 65 RNA helicases (+ 9 pairs) with siRNA and found that 15 of them either increased or decreased t1/2. Knockdowns were confirmed with western blotting. RNA helicase knockdowns with faster NPM1 diffusion were associated with large subunit (LSU) assembly. Most RNA helicase knockdowns with slower NPM1 diffusion were associated with early rRNA processing via the small subunit (SSU) intermediate. The authors screened an additional 290 gene depletions of many ribosomal proteins and assembly factors. With this expanded set of perturbations, they categorized nucleoli based on four morphological features in addition to t1/2 and mobile fraction. Using principal component analysis (PCA), the authors identified clusters of genes with similar effects on NPM1 dynamics and nucleolar morphology. From this secondary screen, the majority exhibited slower NPM1 dynamics. The knockdowns associated with faster NPM1 dynamics were associated with LSU assembly, similar to the helicase experiments. The authors further analyzed several mutants of NPM1 to elucidate the likely interactions between the scaffolding protein and ribosome biogenesis factors. The accumulation of early ribosomal intermediates were associated with decreases in NPM1 dynamics, and accumulation of late intermediates led to increased NPM1 dynamics. The findings established a link between the biophysical properties of the nucleolus and the stages of ribosome biogenesis.

      Major comments:

      • The claims are supported by experimentation.
      • No additional experiments requested.
      • The experiments are adequately replicated, and statistical analysis is sufficient. • Methods are very detailed, which should facilitate reproducibility. Minor comments:
      • Prior studies are referenced appropriately.

      • A bit more coverage of background on the nucleolar scaffolding protein, nucleophosmin (NPM1) would be helpful in the introduction, perhaps in favor of the details on ribosome biogenesis o Paragraph 2 could be shorter or placed elsewhere

      We thank the reviewer for this suggestion and have now included some background on NPM1 in the introduction and have shortened paragraph 2.

      • Figures

      o In Figures 2 - 5: explicitly state in the figure caption what dotted lines are encircling (entire cell?)

      We have now included this in the figure captions (they encircle the nucleus).

      o In Figures 2 - 5: explicitly state what the mp-inferno LUT intensity in the images is quantitating (amount of NPM1?)

      We have now included this in the figure captions (NPM1/mScarlet intensity).

      o Figure 7: more detail in the figure caption

      We have now expanded our model figure caption.

      • The paper is quite dense with a lot of nice work, discussing many different genetic perturbations. It feels a bit overwhelming, and I think the biological significance gets somewhat lost in the presentation of all the data. Perhaps some of the presentation of results can be moved to the supplement in favor of a "leaner" main text. Currently, there are only figures in the supplement, but I feel that some of the text that is not central to the key conclusions can be moved to the supplement. I found myself getting a bit bogged down and having to re-read several times to catch the takeaway messages. Some of the clarifying statements that are found in the discussion section can be moved to the results section. In short, some reorganization would help with readability. One suggestion is to move the Inhibition of rRNA transcription or the RNA exosome leads to nucleolar fragmentation and/or the Perturbation of mRNA processing pathways results in slowed NPM1 dynamics and accumulation of rRNA precursors in the nucleolus to the supplement.

      We thank the reviewer for this helpful suggestion. Due to this and other reviewers, we have now simplified discussion of phenotypic groups, including combining the “LSU” phenotypes into a single group and discussing LSU1/2 in the supplementary text. In addition, while we have chosen to keep the “rRNA transcription/exosome” and “Other” descriptions in the main text, they have been condensed and included in one main section with the other ribosome biogenesis phenotypes to highlight this key takeaway. Remaining discussion of phenotypes is now in supplemental text, as suggested.

      Reviewer #3 (Significance (Required)):

      • General Assessment: The main claim of the paper is that nucleolar phenotype (measured by morphology and NPM1 diffusivity) is correlated with stages in ribosome assembly - i.e. the stage of ribosome assembly determines the biophysical properties of the nucleolus. A strength of the study is the wide range of genetic perturbations tested enabled by the high throughput FRAP. With FRAP, I do worry a bit about using t1/2 as the sole dynamic measurement, but it is not a deal breaker. The authors introduce morphology as another way to characterize the nucleoli. • The claims are well supported by extensive experiments and data. The experiments are well designed, and proper controls were conducted. To validate the method, the authors used perturbations of NPM1 dynamics from the literature including ATP depletion, blocking glycolysis and oxidative phosphorylation, inhibition with MG132, and treatment with sodium arsenite. They observed slower NPM1 diffusivity under all validation conditions. • Advance: The authors have introduced a high-throughput technique for extracting diffusivity with FRAP, yielding a lot of data, but I think the paper suffers a bit in trying to present so much data in the main text. The mechanistic biological insights are compelling but get a bit overshadowed. Improved organization can help the messages come across more clearly. • To my knowledge, there is not a similar study in the literature as the detailed mechanisms of ribosome biogenesis are not well studied. • Audience: The audience for this manuscript seems to be biophysical researchers, thought there may be broader interest due to the wide screening of genetic perturbations. • Expertise: I have evaluated this manuscript from the perspective of a single-molecule biophysicist that studies protein-protein interactions between ribosome biogenesis factors. I am not an expert in FRAP, but I use FCS.

    2. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

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      Referee #3

      Evidence, reproducibility and clarity

      Summary:

      The authors use high throughput FRAP (HiT-FRAP) in arrayed genetic screens of HeLa cells expressing nucleophosmin (NPM1)-fluorescent protein variants to monitor the biophysical properties of the nucleolus in response to genetic perturbations. HiT-FRAP uses a data adaptive imaging strategy to automatically identify and photobleach fluorescently labeled organelles in living cells and acquire movies for FRAP. Quantitative analysis of FRAP curves include t1/2 and mobile fraction. NPM1 was monitored since it is an important nucleolar scaffolding protein that is thought to interact with many pre-ribosome intermediates.

      The authors depleted 65 RNA helicases (+ 9 pairs) with siRNA and found that 15 of them either increased or decreased t1/2. Knockdowns were confirmed with western blotting. RNA helicase knockdowns with faster NPM1 diffusion were associated with large subunit (LSU) assembly. Most RNA helicase knockdowns with slower NPM1 diffusion were associated with early rRNA processing via the small subunit (SSU) intermediate. The authors screened an additional 290 gene depletions of many ribosomal proteins and assembly factors. With this expanded set of perturbations, they categorized nucleoli based on four morphological features in addition to t1/2 and mobile fraction. Using principal component analysis (PCA), the authors identified clusters of genes with similar effects on NPM1 dynamics and nucleolar morphology. From this secondary screen, the majority exhibited slower NPM1 dynamics. The knockdowns associated with faster NPM1 dynamics were associated with LSU assembly, similar to the helicase experiments. The authors further analyzed several mutants of NPM1 to elucidate the likely interactions between the scaffolding protein and ribosome biogenesis factors. The accumulation of early ribosomal intermediates were associated with decreases in NPM1 dynamics, and accumulation of late intermediates led to increased NPM1 dynamics. The findings established a link between the biophysical properties of the nucleolus and the stages of ribosome biogenesis.

      Major comments:

      • The claims are supported by experimentation.
      • No additional experiments requested.
      • The experiments are adequately replicated, and statistical analysis is sufficient.
      • Methods are very detailed, which should facilitate reproducibility.

      Minor comments:

      • Prior studies are referenced appropriately.
      • A bit more coverage of background on the nucleolar scaffolding protein, nucleophosmin (NPM1) would be helpful in the introduction, perhaps in favor of the details on ribosome biogenesis
      • Paragraph 2 could be shorter or placed elsewhere
      • Figures
        • In Figures 2 - 5: explicitly state in the figure caption what dotted lines are encircling (entire cell?)
        • In Figures 2 - 5: explicitly state what the mp-inferno LUT intensity in the images is quantitating (amount of NPM1?)
        • Figure 7: more detail in the figure caption
      • The paper is quite dense with a lot of nice work, discussing many different genetic perturbations. It feels a bit overwhelming, and I think the biological significance gets somewhat lost in the presentation of all the data. Perhaps some of the presentation of results can be moved to the supplement in favor of a "leaner" main text. Currently, there are only figures in the supplement, but I feel that some of the text that is not central to the key conclusions can be moved to the supplement. I found myself getting a bit bogged down and having to re-read several times to catch the takeaway messages. Some of the clarifying statements that are found in the discussion section can be moved to the results section. In short, some reorganization would help with readability. One suggestion is to move the Inhibition of rRNA transcription or the RNA exosome leads to nucleolar fragmentation and/or the Perturbation of mRNA processing pathways results in slowed NPM1 dynamics and accumulation of rRNA precursors in the nucleolus to the supplement.

      Significance

      • General Assessment: The main claim of the paper is that nucleolar phenotype (measured by morphology and NPM1 diffusivity) is correlated with stages in ribosome assembly - i.e. the stage of ribosome assembly determines the biophysical properties of the nucleolus. A strength of the study is the wide range of genetic perturbations tested enabled by the high throughput FRAP. With FRAP, I do worry a bit about using t1/2 as the sole dynamic measurement, but it is not a deal breaker. The authors introduce morphology as another way to characterize the nucleoli.
      • The claims are well supported by extensive experiments and data. The experiments are well designed, and proper controls were conducted. To validate the method, the authors used perturbations of NPM1 dynamics from the literature including ATP depletion, blocking glycolysis and oxidative phosphorylation, inhibition with MG132, and treatment with sodium arsenite. They observed slower NPM1 diffusivity under all validation conditions.
      • Advance: The authors have introduced a high-throughput technique for extracting diffusivity with FRAP, yielding a lot of data, but I think the paper suffers a bit in trying to present so much data in the main text. The mechanistic biological insights are compelling but get a bit overshadowed. Improved organization can help the messages come across more clearly.
      • To my knowledge, there is not a similar study in the literature as the detailed mechanisms of ribosome biogenesis are not well studied.
      • Audience: The audience for this manuscript seems to be biophysical researchers, thought there may be broader interest due to the wide screening of genetic perturbations.
      • Expertise: I have evaluated this manuscript from the perspective of a single-molecule biophysicist that studies protein-protein interactions between ribosome biogenesis factors. I am not an expert in FRAP, but I use FCS.
    3. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #2

      Evidence, reproducibility and clarity

      Summary:

      The nucleolus is a multiphase biomolecular condensate whose primary function is ribosome biogenesis. There are mounting evidences that the material state of condensates is important for their function. Here the authors have probed how the material property of the nucleolus responds to inhibitions of ribosome biogenesis. They have assessed nucleolar dynamics (molecular diffusivity) of a nucleolar protein, NPM1, by fluorescence recovery after photobleaching (FRAP). NPM1 is a protein that labels the periphery of the nucleolus (the so-called granular component, GC). (The nucleolus has 3 main subcompartments: the internal fibrillar centers, the middle dense fibrillar components, and the GC).

      One of the main findings of the work is that inhibition of late steps of ribosome biogenesis increases fluidity (faster recovery of NPM1), while inhibition of earlier (and inhibition of mRNA processing -but see below) rather increases rigidification (slower recovery). They then attempt to correlate what is interpreted as biophysical changes to pre-ribosomal intermediates and interaction with NPM1. Practically, the authors have produced reporter cell lines (HeLa) expressing stably (CRISPR engineering) mono or bi-allelic fluorescent version of NPM1; they have developed a powerful platform to conduct high throughout FRAP (this is really good); they have calibrated their system, initially with basic perturbations (ATP depletion, proteasome inhibition, etc), and then they focused on a family of trans-acting factors: the helicases, investigating systematically their effect on NPM1 recovery. They then extended their initial candidate-based screen to additional factors (using STRING interactions). This is nice and useful. Later in the work, they include in their analysis additional (morphological) features of nucleoli to cluster functionally their hits, as was done earlier by others in similar works. Finally, using recently published structural data (CryoEM), they attempt to correlate groups in the cluster with particular pre-ribosomal species. This part is less advanced and weaker than the initial part of the paper (screens and FRAP measurements).

      Major comments:

      • A major comment is with the compositional analysis of precursor intermediates that should be better defined. The stage assignment of particles is not quite as good as the screening part of the paper.

      At the RNA level, the authors provided FISH, as histograms of quantifications (see e.g. Fig 4D, and Fig SS6E). It would be necessary to show images, and to perform biochemistry. At the protein level, the authors provide immunostaining, but it does not really prove the detected protein is part of a particle,.. - Another concern is to know if NPM: a GC component located periphery of the condensate and a late assembly factor is an appropriate marker for assessing the effects on nucleolar material state of all (including early and late) inhibitions. Would factors involved in earlier ribosomal assembly steps, and localized more internally would not be better tools to evaluate change in material states caused by alterations in early steps? - About the engineered cell lines used for screening by FRAP (Fig 1S): NPM1-mNeonGreen (biallelic with reduced expression of NPM1) and mScarlet (heterozygous): There is a need to characterize pre-rRNA processing in both cell lines to show they are not affected for ribosome biogenesis. This is important information since the entire work is based on these cells. The screening cells are HeLa cells implying they are not physiologically regulated for p53. Nucleolar surveillance is a key regulatory surveillance loop triggered by ribosome biogenesis inhibitions leading to p53 stabilisation. How could this affect this work? Should key findings be confirmed in diploid p53 positive cells? - About factor depletion, e.g. helicases, it's important to consider direct versus indirect effects on ribosome biogenesis, the timeline of depletion should be well described in the paper. Apparently, most factors, including the helicases were depleted for 72 hours, this is very long considering most of them play important roles in essential processes for cell homeostasis implying severely reduced growth at the time of capture (and the possibility of indirect effects). - Another cause of concern is that some perturbations (factor depletion) affect very deeply nucleolar structure/morphology (eg uL2 depletion shown in Fig 2C); how easy/difficult was it to control/make sure that a correct area was obliterated in the FRAP experiment using the (remarkable) data-adaptive approach. For cases where the nucleolus was deeply affected how did you check that a significant nucleolar area had been selected for analysis? It would be good to describe this in the text. - Fig 6C, interaction of NPM1 constructs with pre-ribosomes: the authors have tested interaction with select nucleolar proteins (NOP53, NOP2, NOG2, and uL2), which is not the same as preribosomes. It would be important to see the interactions with precursors (Fig S9C, now histograms) please show the actual data, this was tested by qPCR, please show classical northern blots as RTqPCR have shown their limits in such applications.

      Minor comments:

      • The effects of mRNA processing disruption on nucleolar dynamics could be (is most likely) very indirect (the so-called "slow hits"). The respective time course of inhibitions is important to describe.

      Significance

      General assessment: strengths and limitations

      Strengths:

      • The automated platform for high throughput FRAP
      • The authors develop a potentially interesting model where they attempt to connect rigidification/fluidity of a condensate to its function in assembly of large ribonucleoprotein complexes.
      • The manuscript reads very well; it has been prepared with great care (figures). Some complicated concepts are explained very well (Introduction/Discussion).

      Limitations:

      • particle stage assignment based on FISH and immunostaining only. The authors have not demonstrated that the LSU1 cluster = state F and LSU2 cluster = states G/H

      Advance:

      • Technological advance, high throughput FRAP, a powerful platform to interrogate macromolecular diffusivity.
      • Several nucleolar screens have been conducted in the past (but at steady-state, not using FRAP), in these works textural and morphological features were used together with dimensionality reduction techniques to define functional clusters of genes that impact the homeostasis of the nucleolus. Often these references are cited but it could be useful to expand a bit on some of the earlier findings to bring the new ones in perspective. Some clusters (typically, the transcriptional cluster that disrupts the nucleolus; and the late binder ribosomal proteins) have been well identified before.

      Audience: Cell biologists, scientists involved in ribosome biogenesis research, scientists with an interest in helicases. The growing condensate community.

      Describe your expertise: ribosome biogenesis, structure-function relationships in the nucleolus, technological development in microscopy.

    4. Note: This preprint has been reviewed by subject experts for Review Commons. Content has not been altered except for formatting.

      Learn more at Review Commons


      Referee #1

      Evidence, reproducibility and clarity

      Summary:

      This manuscript has presented a high-throughput fluorescence recovery after photobleaching (HiT-FRAP) platform to screen genes affecting the dynamics of the nucleolar scaffold nucleophosmin (NPM1). The platform included the siRNA-based screening of 65 RNA helicases, 9 phylogenetically related helicase pairs, and 290 ribosomal proteins along with selected assembly factors. These factors were classified as those accelerating or decelerating NPM1 dynamics based on the t1/2 measurements. Combined with nucleolar morphological changes, the authors identified that depletion of early-stage (A-F) and later-stage (G-H) LSU assembly factors resulted in different nucleolar phenotypes, suggesting the pre-ribosome assembly can impact nucleolar morphology. Further exploring the potential mechanism suggested that the NPM1's intrinsically disordered region (IDR) contributed to the nucleolar organization and dynamics.

      Together, this well-designed study uncovered that the ribosome assembly, both the early and late ribosomal precursors can influence biophysical properties of the nucleolus. Below please find our concerns for the authors to consider to strengthen the major conclusions.

      Major comments:

      The main conclusion that NPM1's biophysical states directly impact its interaction strength with ribosome intermediates (and thereby nucleolar dynamics) should be further strengthened as listed below:

      1. Given the nucleolus's complexity, an additional GC factor, or/and one more marker of other nucleolar regions, should be examined to substantiate the proposed impact of LSU-associated factors on nucleolar morphology (Figures 3, 4).
      2. Additional experiments are needed to support the proposed model that ribosomal intermediates, especially the pre-LSU complexes could determine nucleolar biophysical properties through the interaction with NPM1. Their direct interaction by biochemical assays should be provided. Also, when analyzing the interaction with other nucleolar factors, the authors should provide data that show NPM1 mutant expression levels were comparable to endogenous levels (Figures 4, 6).
      3. Northern Blotting should be done to dissect which pre-rRNA intermediates interact with NPM1 and contribute to the nucleolar dynamics (Figures 4B, D, F). These additional experiments should be feasible within a reasonable timeframe. In addition, the authors should provide the code and the hardware control procedures for HiT-FRAP to ensure reproducibility. According to the authors' statement, all the experiments are adequately replicated, and the statistical analysis is adequate.

      Minor comments:

      To enhance clarity and focus, consider the following:

      1. Simplifying the HiT-FRAP screening section (Fig. 1-3) would emphasize the significant findings.
      2. Expanding analysis and experimental validation could help to solidify the interdependency between rRNA / ribosome precursors and the NPM1- driven nucleolar dynamics (Fig. 4-5). Indeed, additional experiments suggested above in the major concerns should be supplemented here.

      Significance

      This work has established a powerful toolkit, named HiT-FRAP, to identify factors involved in the organization and regulation of the membrane-less nucleolus, which will be useful for understanding the complexity not only the nucleolus, but likely other condensates in cells in the future. Using this platform and with the Granular Component (GC)-localized NPM1 as an indicator of nucleolar morphology, the authors found that the biophysical properties of the nucleolus are sensitive to the ordered assembly of ribosomes, in particular the LSU maturation steps at the GC. This finding is important as it suggests the interdependency between the dynamic rRNA processing and the functional assembly and morphology of the nucleolus. Further studies are warranted to analyze the dynamics of other nucleolar constituents, particularly those localized at other sub-nucleolar regions, to fully depict how exactly the nucleolar function is coordinated with its biophysical properties.

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      Referee #4

      Evidence, reproducibility and clarity

      RNAi is remarkably efficient in planaria, yet no mechanism for the amplification of the RNAi signal has thus far been observed. In this manuscript, the authors analyse the mechanisms of RNAi spread in planaria. Starting from some basic observations on the identity of the Dicer and Argonaute proteins required for RNAi, the authors performed a set of elegant experiments to conclude that cycling stem cells likely take up dsRNA and excrete Ago-siRNA complexes, which are then taken up by other cells to mediate RNAi. In addition, the authors provide compelling evidence that RNAi is indeed independent of an amplification mechanism.

      Overall, I found the experiments and results compelling and the manuscript a pleasure to read. I have only a few suggestions for consideration, none of which are essential to support the main conclusions:

      • What does the arrest of stem cell proliferation do to the expression of RNAi genes (with and without dsRNA stimulation)?
      • Page 9: top panel. Is there a control that the dsRNA generated by RNaseIII is functional? I.e. that the defect is indeed due to an uptake effect and not the quality of the siRNA preparation itself? (In our hands silencing of siRNA prepared with bacterial RNaseIII has not been efficient at all). As a side note: no method is provided for the RNaseIII treatment.
      • Have the authors analyzed which of the Argonautes are present in the preparations generated with Q-sepharose?

      Data presentation:

      • For all figure legends: please make sure to state animals, number of repeats, define boxplots and what the individual data points represent. Please provide statistics where quantitative statements are made.

      Minor points:

      • First paragraph results: The statement that Ago1 and 3 were "closer to the nematode-specific WAGOs" does not seem correct, (horizontal distance to the miRNA-AGOs is still lower than the the WAGOs). I suggest removing the statement.
      • Use of checkmarks: please define when a checkmark vs cross was indicated? E.g., does a checkmark indicate that 100% of the animals showed efficient RNAi, or a majority of animals?
      • Many of the legends contain conclusions. While this may be a matter of taste/style, I would suggest to introduce conclusions only sparingly, if at all, in the legends
      • Some of the font sizes are rather small on print size (e.g. Fig 1A, S4i). In Fig 1A the black font on dark blue background is hard to distinguish.

      Textual suggestion:

      • Abstract "that rely on dsRNA intermediates, such as viruses" > ".. such as those from viruses..."
      • Materials and Methods: The lowerscript numbers for the ion show as squares in my pdf.

      Significance

      Strength/weaknesses:

      I found the experimental support robust and well supported and I did not find weaknesses that jeopardize the conclusions.

      Significance:

      One of the most intriguing features of RNAi is the systemic spread of a silencing signal across an organism's body. This has received significant attention in C. elegans and plants, but for other organisms, this is much less well explored. Planaria have a very efficient RNAi response, which the authors propose is due to uptake of an initial dsRNA by stem cell and excretion of an Argonaute-siRNA complex, which is then taken up by distal cells in an endocytic mechanism. I find this an intriguing mechanism that to differ from mechanisms for RNAi spread observed in other organisms.

      The work will be of interest to those interested in small RNA pathways (and RNA biology in general) and has practical implications for scientists working on planaria. The fact that small RNAs spread in an Argonaute-siRNA complex in an organism should also be of interest for cell biologists.

      My field of expertise: Small RNA pathways and antiviral defense in insects. No experience working with planaria.

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      Referee #3

      Evidence, reproducibility and clarity

      In RNA interference (RNAi), double-stranded RNA (dsRNA) is processed into small interfering RNAs (siRNAs), which can function locally or act as mobile RNA species that spread between cells. In organisms such as nematodes and plants, the underlying mechanisms and key factors involved in this process, including transporters such as SID-1, have been well characterized. While systemic RNAi has also been reported in other animals, the underlying mechanisms remain largely unclear. In this context, the authors focus on planarians as one such model to investigate these processes. In the planarian S. mediterranea, gene knockdown by dsRNA injection is commonly employed, and the RNAi effect is known to spread rapidly throughout the organism. However, given the absence of RNA-dependent RNA polymerase (RdRP), the mechanism by which RNAi signals are efficiently propagated remains unclear. In this study, the authors provide several important insights into this question.

      First, the authors carefully evaluated the duration of the RNAi effect. In addition, they systematically examined the involvement of known RNAi-related factors and demonstrated that this process depends on ago1 and ago3. Second, interestingly, the authors find that initiation of systemic RNAi depends on neoblasts. Third, Argonaute-siRNA complexes play a crucial role in systemic RNAi. This differs markedly from the nematode system, in which dsRNA itself is transported, highlighting an intriguing mechanistic distinction. Finally, the authors suggest that distinct Argonaute proteins may function at different stages of RNAi propagation. Ago1 + Ago3 play essential roles in the initial phase of systemic RNAi in neoblast, Ago3 but not Ago1 silences the target in the differentiated cells. While the phenomenon described here is highly interesting, the underlying mechanism remains to be fully elucidated. In particular, how different Argonaute proteins functionally coordinate with each other, especially with respect to the transfer of siRNAs between Argonaute complexes, is still unclear and represents an important direction for future studies.

      The study is supported by well-designed control experiments, and the results are consistent with and support the authors' conclusions.

      I have no major concerns about this manuscript. The study is well conducted, and I only have minor comments that could further improve the manuscript.

      (Minor) While the authors have examined the effects of irradiation on the donor, it would be interesting to test the reciprocal experiment in which the recipient is irradiated. In particular, assessing whether the addition of donor lysate to irradiated recipients can recapitulate the observed RNAi propagation would further strengthen the proposed model.

      (Minor) The purity of the AGO complexes obtained via the TraPR anion-exchange procedure is not entirely clear. The authors may consider providing additional evidence of purity (e.g., visualization of small RNAs with T4-PNK), which would strengthen the conclusions.

      (Minor) Figure 4H is not referred to in the main text. The authors may consider incorporating a description of this panel into the Results section for clarity.

      Significance

      Overall, given the substantial amount of data and the overall high quality of the present study, further mechanistic dissection would likely be beyond the scope of the current manuscript. I look forward to future work from the authors addressing these mechanistic questions in more detail. RNAi has been widely used in stem cell research in planarians. In light of the findings presented in this study, however, previous studies that combine UV irradiation and RNAi may warrant careful re-evaluation. In this regard, the present work has important implications and is likely to have a broad impact on the field.

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      Referee #2

      Evidence, reproducibility and clarity

      In this paper, the authors set out to understand how dsRNA elicits a system-wide RNAi effect using planarians as a model system. This is an important question, because it gets at evolution of these processes in different animal models and because knowing more about how RNAi works can allow scientists to tweak their approach for a better knock down efficiency. Importantly, though the system-wide mechanism of RNAi is fairly well understood in C. elegans and in some plants, it isn't clear how conserved these mechanisms are. Some aspects of this paper are quite convincing, including identification of the responsible Argonaute and Dicer proteins. Further, the identification of potential Sid-1 homologs that may allow for import of dsRNA is new. However, the role for Ago-3 was recently reported in Sasidharan, et al (Science Advances, 2026), which is not cited in this manuscript. Perhaps more importantly, several key aspects of the argument set up in this paper are not adequately supported and there are key gaps in the mechanism proposed that prevent its publication in this form. Major and minor suggestions follow:

      Major issues:

      1. The argument that siRNAs must be generated in stem cells that are cycling is not well supported.

      a. The authors only use one approach to reduce stem cell numbers, lethal irradiation. In addition to causing loss of stem cells, lethal irradiation causes wide-spread DNA damage and organismal/cellular stress responses. By 6 days after lethal irradiation, other progenitor cells are lost as well. Epidermal progenitors are known to be very abundant and to play signaling and/or metabolic roles in planarian physiology, so their loss may also be impactful. The authors should consider other orthogonal approaches to eliminate stem cells and to rule out other potential mechanisms.

      b. The authors use camptothecin in planarians and claim that it reduces cell divisions of stem cells. To my knowledge, this drug has not been shown to work in planarians before. The concentration used is also higher than in published studies. The authors should show whether stem cells are lost after this drug treatment (through levels of stem cell markers or stem cell counting) and should clarify the timing of the treatment relative to the RNAi, which is not clear from the figure legend or methods section. The authors should also discuss possible alternative interpretations of this piece of data (e.g. potential off-target effects). Without more information, it is hard to interpret the data relative to the irradiation results. The authors also do not provide any insight into how or why dividing/cycling stem cells would be important for the systemic RNAi mechanism they propose.

      c. ago-1, ago-3, and dcr-2 were shown to be enriched in stem cells (Fig. 3C), but these genes are also expressed in differentiated cells in single-cell sequencing data. Therefore, it isn't intuitive that non-stem cells would lack the capacity to generate siRNAs.

      d. Is there a way to directly test the hypothesis that stem cells are only generated in stem cells, potentially by blocking transport in some way and then visualizing new siRNAs with a miRNA/siRNA version of ISH OR FACS and sequencing? If the Ago-1/3-siRNA complexes are indeed transported by EVs as per Sasidharan, et al then the ESCRT(RNAi) approach might be useful in blocking movement of siRNAs? Or, could the authors show that dsRNAs are preferentially taken up by stem cells using the type of experiment shown in Fig. S5H? 2. It isn't clear from the manuscript how the authors believe that Ago-1/3-siRNA complexes exit and enter cells. The diagram in Fig. 5F describes the complex as moving between cells either through vesicles or extracellularly. How do the authors propose that Ago-siRNA complexes pass through the plasma membrane given that they are not known to go through the secretory pathway? Or once endocytosed, how do they exit the vesicle? Uncertainty on these points makes the molecular mechanism proposed here seem poorly supported by the data provided in the paper. 3. One key result in the paper is the transplant of "AGO complexes" that are purified from lysate. The authors writing about this experiment implies that they are transplanting a fairly pure material representing these RNPs and no others. However, the approach described is unlikely to result in purification of highly specific protein complexes. At a minimum, gels that illustrate protein/complex purity should be provided. Preferably, though, mass spectrometry and sequencing would be provided to detail siRNAs and proteins in this sample. 4. The Sasidharan, et al (Science Advances, 2026) paper should be cited and also the findings of this paper should be put in the context of that work.

      Minor changes:

      1. In several experiments, quantitative assessment of impacts (e.g. eye size or ovo/opsin transcript levels) rather than subjective eye scoring would be preferable for rigor and for statistical analysis of changes rather than check/X (e.g. 4F-H).
      2. F1 and F2 terminology for regenerates is probably not accurate since F in those terms stands for "filial" and is used to denote offspring.
      3. The images in Figure 2 (A, C) are quite hard to see on the printed page. Using white for fluorescence might improve contrast and visibility.
      4. The element of time seems to be very important for transmission of the RNAi effect in sexual offspring. Instead of the claim that hatchlings from RNAi crosses have no effect (Fig. 2H), the detail provided in the results section seems to indicate that there is a time-limited effect. These findings should be clarified with progeny sorted by time of egg laying and with a better sense of time between RNAi injection and hatch. Further, even in animals that do regenerate eyes, it would be nice to see a quantification of transcript as a clearer readout of whether some knockdown persists.
      5. This is more of a curiosity question, but it would be interesting to know how the differences in Ago1/2/3 protein structure might relate to their function, particularly in terms of the PAZ and MID domains.

      Significance

      This paper provides some new insight into mechanisms underlying systemic RNAi in planarians. Some of the results are quite preliminary and the overall interpretation of data is not yet well founded. However, there are some highlights, including the potential identification of dsRNA transporters that will be interesting to those in the planarian field.

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      Referee #1

      Evidence, reproducibility and clarity

      Summary

      In this manuscript, the authors characterized the molecular mechanism of systemic RNAi in planarian Schmidtea mediterranea (Sme) through loss-of-function genetic perturbations. They genetically identified key protein factors involved in the siRNA pathway and assessed the systemic RNAi efficacy at the molecular level. Notably, they find that the proliferating stem cells (neoblasts) are specifically required for systemic RNAi in Sme. They further propose that the requirement of neoblasts in systemic RNAi is mediated by spreading of the RISC RNP to differentiated cells.

      Major Comments

      1. The authors show that in Sme systemic RNAi strictly relies on the presence of neoblasts, which is one of the most interesting finding. It is important to understand the mechanism, specifically whether neoblasts are generally required for dsRNA processing or for conferring mRNA slicing activity. Although the authors claimed in Figure 5 that neoblasts are required for siRNA biogenesis, the results provided do not directly support this claim. An alternative scenario is that dsRNA can still be processed into siRNA in the absence of neoblasts, but the resulting siRNA subsequently fails to function without the neoblast AGOs or other signals. To directly confirm that neoblasts are required for dsRNA processing, one additional experiment should be performed in which irradiated worms are injected with dsRNA, followed by small RNA cloning and sequencing to detect whether processed siRNAs are present.
      2. An alternative mechanism to interpret the role of neoblasts is that, instead of processing dsRNA and/or spreading RISC RNP, the neoblasts may function as regulatory cells that provide signals licensing the dsRNA processing and target slicing in differentiated cells. Under this scenario, the requirement for sid-1 and vha-16 could instead be interpreted as necessitate the dsRNA transfer from the initial uptake tissues (parenchyma for be injection or intestine for feeding) to the target tissues. To rule out this possibility, isolated neoblasts from naive donors could be transplanted into irradiated recipient worms who have been injected with dsRNA, and whether such transplantation can restore the systemic RNAi in the recipient animals could then be tested phenotypically. One caveat is that any positive result may be due to the proliferation of the donor neoblasts in the recipient. This can be addressed by performing the same transplantation but using neoblasts isolated from camptothecin-treated worms, which would limit the proliferative contribution.
      3. In Figure 5E, the authors show that recipient ago-3 is required for systemic RNAi, and they suggest in the Discussion a plausible model in which recipient AGO-3 is required for nuclear RNAi for transcriptional target repression. However, this result appears inconsistent with the results in Figure 1C-D, where ago-3 KD did not abolish systemic RNAi. This contradiction should be acknowledged in text and further investigated. One possible interpretation is that the presence of the neoblast ago-3 from the donor lysate may have an antimorphic effect and interferes with the recipient AGO(s) (presumably ago-1 in this case) during target silencing , implying that homogeneity of AGO(s), or at least homogeneity of ago-1, is required for such systemic RNAi. Although the underlying mechanism remains difficult to interpret, such hypothesis could be tested by injecting lysate from ago-3 KD donor into ago-3 KD recipient. If AGO homogeneity is indeed required, such transfer treatment should no longer abolish systemic RNAi in the recipient in Figure 5D. Additionally, the target genes used for the systemic RNAi in Figure 1C/D and Figure 5E are different. To exclude the possibility that this discrepancy is target-specific, either six1/2 should be tested in the whole worm RNAi assay in Figure 1 or opsin should be used in the transfer assay in Figure 5.
      4. The authors claim in Figure 4 that the systemic RNAi is mediated by secreted RISC. This claim is not unexpected, because naked siRNA generally suffers poor half-life in vivo and therefore must be stabilized by bounding to AGO to evade the endogenous ribonucleases. Nevertheless, the alternative hypothesis that the transferred RNAi is mediated by the spread of naked RNA, though unlikely, should be experimentally excluded. Specifically, the isolated RNA and lysate with protease in Figure 4F (which failed to induce RNAi in the host worm) should be tested to confirm whether they contain siRNAs. This can be done by cloning and sequencing the sRNA in the lysate.
      5. The authors assigned ago-1 and ago-3 to the siRNA pathway and ago-2 to the miRNA pathway. This is an important conclusion for subsequent sRNA studies in planarians. However, the evidence provided in the current manuscript is insufficient to exclude ago-2 from the siRNA pathway, especially given that DDH catalytic triad is present in AGO-2. The observed redundancy between ago-1 and ago-3 to maintain functional RNAi can only support the involvement of these two AGO genes in the siRNA pathway but does not exclude AGO-2. To more rigorously test whether ago-2 should be excluded from the siRNA pathway, double RNAi of ago-2 and ago-1, as well as of ago-2 and ago-3, should be performed, and ago-2 should only be excluded from the siRNA-pathway if such double KD do not further reduce the RNAi efficacy compared with individual KD.
      6. The results shown in Figure 1F, where exposure to exogenous dsRNA can enhance the endogenous transcription of ago-1 and ago-3 in Sme, are particularly interesting. The authors should discuss whether this phenomenon is related to nuclear RNAi. In addition, it has been reported that exposure to exogenous dsRNA can increase the AGO/DICER protein levels without increasing the mRNA level (PMID32194567), and this should be compared with the present findings. Importantly, the result also suggests a potential strategy to improve the Sme RNAi efficiency. Accordingly, it would be valuable to test whether the increased ago-1/3 transcript levels caused by introducing exogenous dsRNA can lead to higher RNAi efficacy, both in terms of target silencing depth and the duration of RNAi effectiveness.
      7. Figure 2I-J provides remarkable evidence that the systemic RNAi in Sme is independent of RdRP. This result should be highlighted in the final paragraphs of the Introduction and mentioned in the Abstract.

      Minor Comments:

      1. The authors show that ago-1 + ago-3 KD only slightly perturbed the miRNA levels. However, this observation can be interpreted in at least two ways: (a) these two AGO genes are not involved in the miRNA pathway; or (b) these two genes are expressed at low abundance (which was mentioned later in the paper), such that their KD only mildly perturb their associated miRNAs, especially if these miRNAs are also associated with AGO-2. Scenario (a) seems less likely to be true because ago-2 is enriched in neoblasts (Figure 3C), whereas many conserved miRNAs have been reported to be enriched in Xins in Sme (Sasidharan et al 2013). This issue should be therefore discussed. In addition, the gene expression levels of the three ago genes from previously published bulk RNAseq datasets should be included in the figure.
      2. The illustration in Figure 1A is not fully accurate. In the miRNA pathway, target repression also includes mRNA degradation (which is conventionally referred to as mRNA decay or mRNA destabilization), which is in fact the dominant mode of miRNA-mediated repression. Therefore, "mRNA decay" should be added in addition to "translational inhibition". In the siRNA pathway, mRNA degradation is not directly mediated by RISC itself, but by the downstream exonucleases (i.e., XRN-1); therefore, the term "mRNA slicing" should be used instead for the siRNA part. Additionally, it has been shown that C. elegans RDE-1 is also associated with miRNAs (PMID 36790166), so the functional assignment in the model should be adjusted accordingly.
      3. In Figure S1C, the authors claimed that ago-1 and ago-3 exhibit more divergent PAZ and MID domains according to the AF modeling. However, this divergence may simply reflect the lower sequence conservation of AGO-1 and AGO-3 relative to AGO-2, which is shown in the phylogeny in Figure S1A. To address this caveat, Robetta modeling should be performed for both the full-length proteins in the comparative modeling mode due to the length of AGO proteins, or de novo modeling of the PAZ and MID domain. Structural the alignment in reference to solved AGO structures such as 4W5Q or 6N4O should be shown. If the MID/PAZ domains divergency remains evident, it should be quantified using backbone RMSD relative to known AGO structures.
      4. In Figure S1C, a second structural view should also be included to better illustrate the AGO architecture. The duplex channel within the PIWI-MID lobe should be clearly visible in one of the views. The L2 domain, or at least helix-7, should be labeled. If possible, the relative position of helix-7 to the guide RNA should also be shown. All the predicted structural models should be included in the supplemental files.
      5. The authors suggest that the spread of functional RISC from neoblasts depends on EVs. The evidence involving vha-16 is convincing, but to directly validate the presence of EVs that cargo RISC, CsCl ultracentrifugation would be informative. Although this experiment is beyond the scope of the current manuscript, the need for direct EV validation should be discussed.
      6. In Figure 2G, the authors show that although zfp-1 restores the homeostatic mRNA level at week 5, its downstream target prog-1 and agat-3 fail to recover. It remains unclear whether this is due to the delay of newly translated zfp-1 to activate the downstream targets, or due to translational suppression of zfp-1. Therefore, the mRNA levels of prog-1 and agat-3 should be further monitored beyond week 5.
      7. In Figure 3, the authors use co-expression by in situ hybridization to demonstrate the expression of ago in neoblasts. To provide the whole-animal context, co-expression of smedwi-1 and ago genes should also be confirmed using the current Sme scRNAseq datasets.
      8. The authors proposed in the Discussion that AGO-1 may sponge unwound RNA duplex and this facilitates the dsRNA transfer. This interpretation seems unlikely, because the ago-1 single KD, which would abolish such dsRNA transfer, did not show phenotypes in terms of systemic RNAi defect. Also, such scenario suggests that loss-of-function of ago-1 may be antimorphic since the sponged dsRNA were released, and thus co-KD of ago-1 and ago-3 should result in more efficient RNAi. These concern should be discussed.
      9. The Discussion states that AGO-1 is required in the donor, but this is inconsistent with the results in Figure 5D, where ago-1 KD in the donor did not abolish RNAi in the recipients. This inconsistency between results and text should be corrected.
      10. In Figure S5I, the authors show that short dsRNA generated by RNase III digestion failed to induce systemic RNAi in sid-1 loss-of-function condition. However, the alternative explanation is that RNase III digestion produced short dsRNAs that may result in siRNA with suboptimal length for AGO loading or functioning. This caveat should be mentioned, and the length profile of the RNase III digestion products should be shown by high density urea gel electrophoresis or HPLC.
      11. In all the transfer assays, one concern is the lysate may contain viable neoblasts, so that any observed results could be attributed to the proliferation of the donor-derived neoblasts rather than the transfer of RNAi materials. Therefore, a cell viability test using Calcein AM or other equivalent assay should be conducted to confirm the absence of live cells in the lysate preparation protocol.
      12. In the second paragraph of the introduction, when comparing the siRNA and miRNA pathways, the difference in base-pairing configuration with the target site should be introduced with appropriate reference.
      13. In the last paragraph of the introduction, the claim that the results may have implications for the design of effective RNAi-based therapies is too vague. Given that the current therapeutic siRNA delivery methods are already robust in clinical applications, the authors should more specifically explain how their findings in Sme might inform therapeutic development.
      14. In the last sentence of the second last paragraph of the introduction and Figure S5I, "RNAse" should be corrected to "RNase".
      15. In the first Results subsection, the second last paragraph, first sentence, one left parenthesis is missing.
      16. Throughout the Discussion, the term "AGO-RNA". If the authors intend to express a distinction from RISC, how this terminology differs from RISC should be justified. Otherwise, RISC would be more appropriate.
      17. Statistical significance should be shown in Figure 2E, 2G, 3A, 3C, S2A, S2D, S2G, S3D, S5D, S5G, S5J.
      18. Molecular weight should be labeled in Figure S5L.
      19. In Figure 2J, where the y-axis indicates % prevalence, the down-facing bars (antisense reads) should also be labeled as positive values on the y-axis. Displaying them as negative percentages (-20%) is incorrect.
      20. The small RNA cloning procedure should be described in the Methods. Basic information of sRNA sequencing, including read numbers, biotype distribution, proportion mapping to the triggering dsRNA, should be included too.
      21. The methods used to measure RNA and protein concentrations should be included in the Methods section.
      22. The irradiation protocol, including dosage, should be included in the Methods.
      23. In the Methods section, subscripts of chemical formulas are rendered as squares throughout the text. This formatting issue should be corrected.
      24. In the Results section, first subsection, second paragraph and first sentence. The cited data should be Suppl Figure S2D, not the current S2A-C.
      25. The manuscript uses inconsistent formatting for supplemental figures (for example, "Suppl Figure S1B,C" versus "Suppl Figure 2A-C"). The formatting should be standardized.

      Significance

      Planarians have long been appreciated as a robust model organisms for studying gene function in animal regeneration, and one major advantage of this system is its highly efficient systemic RNAi. However, the molecular basis of the RNAi machinery has not been thoroughly investigated, and detailed RNAi efficacy hasn't been evaluated. This study therefore provides important value by characterizing the molecular components underlying systemic RNAi in Sme, which contributes to both fundamental understanding and to potential optimization of RNAi-based experiments in Sme.

      In addition, the manuscript reports that stem cells are required for systemic RNAi in differentiated cells in Sme, a finding that has not been described in other organisms. Although the underlying mechanism remains unresolved, this observation offers potentially important implications for both RNA biology and stem cell biology.