A cellular and regulatory map of the cholinergic nervous system of C. elegans

  1. Laura Pereira  Is a corresponding author
  2. Paschalis Kratsios
  3. Esther Serrano-Saiz
  4. Hila Sheftel
  5. Avi E Mayo
  6. David H Hall
  7. John G White
  8. Brigitte LeBoeuf
  9. L Rene Garcia
  10. Uri Alon
  11. Oliver Hobert  Is a corresponding author
  1. Columbia University, United States
  2. Howard Hughes Medical Institute, Columbia University, United States
  3. Weizmann Institute of Science, Israel
  4. Albert Einstein College of Medicine, United States
  5. MRC Laboratory of Molecular Biology, United Kingdom
  6. Texas A&M University, United States
  7. Howard Hughes Medical Institute, Texas A&M University, United States

Decision letter

  1. Kang Shen
    Reviewing Editor; Howard Hughes Medical Institute, Stanford University, United States

In the interests of transparency, eLife includes the editorial decision letter and accompanying author responses. A lightly edited version of the letter sent to the authors after peer review is shown, indicating the most substantive concerns; minor comments are not usually included.

Thank you for submitting your work entitled "A cellular and regulatory map of the cholinergic nervous system of C. elegans" for consideration by eLife. Your article has been reviewed by a Senior Editor, Kang Shen (Reviewing Editor) and two peer reviewers. The following individuals involved in review of your submission have agreed to reveal their identity: Gerald Rubin and Shawn Xu (peer reviewers).

The reviewers have discussed the reviews with one another and the Reviewing Editor has drafted this decision to help you prepare a revised submission.

Summary:

Pereira et al., have written a very interesting and highly informative article which will be extremely beneficial for the C. elegans community. This article sets a broad foundation for cholinergic signaling in the C. elegans nervous system. They use an array of imaging techniques to identify potential sites of release, reception and cholinergic neuron identities, as well as acute observation and discussion of the role of acetylcholine in circuit motifs.

Both reviewers thought that the manuscript is suitable for publication in eLife after the following questions are addressed.

Essential revisions:

1) It would be helpful to readers to expand on the generality of the statement that "Invertebrate genomes encode not only conventional excitatory Ach-gated cation ion channels, but also inhibitory Ach-gated anion ion channels". For example, is there evidence that the widely studied invertebrate Drosophila has inhibitory nAChRs? In particular, Wormbase lists the closest fly homolog of ACC-4 as the GABA receptor Rdl. If evidence for the existence of Ach-gated anion ion channels is limited to C. elegans, then perhaps the wording should be changed to say "the C. elegans genome encodes" to be consistent with the available facts. I note that the two cited references do not contain information to support the broader statement made, as they describe work with C. elegans only.

2) I think the statement in paragraph seven subsection “unc-3 is a circuit-associated transcription factor” that unc-3 activity is required to "specify" synaptic connectivity is too strong and misleading. The data just show that unc-3 activity is required for normal synaptic connectivity to occur. That means something very different, at least to me, than "specify". Likewise the statement that unc-3 "defines the function and assembly of an entire circuit" goes way beyond what can be concluded from the results presented. The circuit is indeed abnormal in unc-3 mutants, but to use the word "define" here would require, in my opinion, evidence that in unc-3 mutants the circuit became a different type of functional circuit, not that it is just abnormal. I think one can say that unc-3 is "required", but "define" implies a specific role for unc-3 that has not been demonstrated. Similarly "circuit-associated" is appropriate, but "circuit-defining" is not.

3) This present study sets a foundation for investigating the role of ACC-4 in cholinergic signaling. ACC-4 however does not elicit strong Ach-gated chloride currents when expressed alone (Putrenko et al., 2005), does this suggest that it is an auxiliary subunit in a heteropentameric receptor? Therefore, does acc-4 co-express with at least one other Ach-gated chloride channel in each cell?

https://doi.org/10.7554/eLife.12432.028

Author response

1) It would be helpful to readers to expand on the generality of the statement that "Invertebrate genomes encode not only conventional excitatory Ach-gated cation ion channels, but also inhibitory Ach-gated anion ion channels". For example, is there evidence that the widely studied invertebrate Drosophila has inhibitory nAChRs? In particular, Wormbase lists the closest fly homolog of ACC-4 as the GABA receptor Rdl. If evidence for the existence of Ach-gated anion ion channels is limited to C. elegans, then perhaps the wording should be changed to say "the C. elegans genome encodes" to be consistent with the available facts. I note that the two cited references do not contain information to support the broader statement made, as they describe work with C. elegans only.

We apologize for this misstatement. While Drosophila does have anion-gated LGICs, it’s not clear whether these are ACh channels; in fact, the specific clade of ACC genes in worms is NOT conserved in Drosophila. So, while we can’t rule out that they exist in flies, there is currently no evidence for this. We followed the reviewer’s suggestion and changed the sentence to "the C. elegans genome encodes…"

2) I think the statement in paragraph seven subsection “unc-3 is a circuit-associated transcription factor” that unc-3 activity is required to "specify" synaptic connectivity is too strong and misleading. The data just show that unc-3 activity is required for normal synaptic connectivity to occur. That means something very different, at least to me, than "specify". Likewise the statement that unc-3 "defines the function and assembly of an entire circuit" goes way beyond what can be concluded from the results presented. The circuit is indeed abnormal in unc-3 mutants, but to use the word "define" here would require, in my opinion, evidence that in unc-3 mutants the circuit became a different type of functional circuit, not that it is just abnormal. I think one can say that unc-3 is "required", but "define" implies a specific role for unc-3 that has not been demonstrated. Similarly "circuit-associated" is appropriate, but "circuit-defining" is not.

Agree with all, fixed as requested (i.e. eliminated “specify” and “defining”).

3) This present study sets a foundation for investigating the role of ACC-4 in cholinergic signaling. ACC-4 however does not elicit strong Ach-gated chloride currents when expressed alone (Putrenko et al., 2005), does this suggest that it is an auxiliary subunit in a heteropentameric receptor? Therefore, does acc-4 co-express with at least one other Ach-gated chloride channel in each cell?

Yes, that’s correct. Unpublished worked from another C. elegans lab has indeed found such a subunit (an lgc gene). Since this is unpublished data, we have not mentioned this in the manuscript.

https://doi.org/10.7554/eLife.12432.029

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  1. Laura Pereira
  2. Paschalis Kratsios
  3. Esther Serrano-Saiz
  4. Hila Sheftel
  5. Avi E Mayo
  6. David H Hall
  7. John G White
  8. Brigitte LeBoeuf
  9. L Rene Garcia
  10. Uri Alon
  11. Oliver Hobert
(2015)
A cellular and regulatory map of the cholinergic nervous system of C. elegans
eLife 4:e12432.
https://doi.org/10.7554/eLife.12432

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https://doi.org/10.7554/eLife.12432