A Connectome of the Male Drosophila Ventral Nerve Cord

  1. Shin-ya Takemura
  2. Kenneth J Hayworth
  3. Gary B Huang
  4. Michal Januszewski
  5. Zhiyuan Lu
  6. Elizabeth C Marin
  7. Stephan Preibisch
  8. C Shan Xu
  9. John Bogovic
  10. Andrew S Champion
  11. Han SJ Cheong
  12. Marta Costa
  13. Katharina Eichler
  14. William Katz
  15. Christopher Knecht
  16. Feng Li
  17. Billy J Morris
  18. Christopher Ordish
  19. Patricia K Rivlin
  20. Philipp Schlegel
  21. Kazunori Shinomiya
  22. Tomke Stürner
  23. Ting Zhao
  24. Griffin Badalamente
  25. Dennis Bailey
  26. Paul Brooks
  27. Brandon S Canino
  28. Jody Clements
  29. Michael Cook
  30. Octave Duclos
  31. Christopher R Dunne
  32. Kelli Fairbanks
  33. Siqi Fang
  34. Samantha Finley-May
  35. Audrey Francis
  36. Reed George
  37. Marina Gkantia
  38. Kyle Harrington
  39. Gary Patrick Hopkins
  40. Joseph Hsu
  41. Philip M Hubbard
  42. Alexandre Javier
  43. Dagmar Kainmueller
  44. Wyatt Korff
  45. Julie Kovalyak
  46. Dominik Krzemiński
  47. Shirley A Lauchie
  48. Alanna Lohff
  49. Charli Maldonado
  50. Emily A Manley
  51. Caroline Mooney
  52. Erika Neace
  53. Matthew Nichols
  54. Omotara Ogundeyi
  55. Nneoma Okeoma
  56. Tyler Paterson
  57. Elliott Phillips
  58. Emily M Phillips
  59. Caitlin Ribeiro
  60. Sean M Ryan
  61. Jon Thomson Rymer
  62. Anne K Scott
  63. Ashley L Scott
  64. David Shepherd
  65. Aya Shinomiya
  66. Claire Smith
  67. Natalie Smith
  68. Alia Suleiman
  69. Satoko Takemura
  70. Iris Talebi
  71. Imaan FM Tamimi
  72. Eric T Trautman
  73. Lowell Umayam
  74. John J Walsh
  75. Tansy Yang
  76. Gerald M Rubin
  77. Louis K Scheffer
  78. Jan Funke
  79. Stephan Saalfeld
  80. Harald F Hess
  81. Stephen M Plaza
  82. Gwyneth M Card
  83. Gregory SXE Jefferis
  84. Stuart Berg

  • Curated by eLife

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    eLife assessment

    This landmark paper introduces the generation and analysis of a connectome resource of the entire ventral nerve cord of a fruit fly which is one of the top model organisms to investigate how a nervous system forms and functions. The work introduces new and improved approaches - from tissue preparation to automated reconstruction - to generate a detailed connectome from a complex adult ventral nerve cord. This extensive new dataset provides cell type and lineage annotations, putative neurotransmitter expression information, and the potential to link to genetic driver lines, with compelling evidence to support the claims made.

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Abstract

Animal behavior is principally expressed through neural control of muscles. Therefore understanding how the brain controls behavior requires mapping neuronal circuits all the way to motor neurons. We have previously established technology to collect large-volume electron microscopy data sets of neural tissue and fully reconstruct the morphology of the neurons and their chemical synaptic connections throughout the volume. Using these tools we generated a dense wiring diagram, or connectome, for a large portion of the Drosophila central brain. However, in most animals, including the fly, the majority of motor neurons are located outside the brain in a neural center closer to the body, i.e. the mammalian spinal cord or insect ventral nerve cord (VNC). In this paper, we extend our effort to map full neural circuits for behavior by generating a connectome of the VNC of a male fly.

Article activity feed

  1. Version published to 10.7554/elife.97769.1 on eLife
  2. Version published to 10.7554/elife.97769 on eLife
  3. eLife

    eLife assessment

    This landmark paper introduces the generation and analysis of a connectome resource of the entire ventral nerve cord of a fruit fly which is one of the top model organisms to investigate how a nervous system forms and functions. The work introduces new and improved approaches - from tissue preparation to automated reconstruction - to generate a detailed connectome from a complex adult ventral nerve cord. This extensive new dataset provides cell type and lineage annotations, putative neurotransmitter expression information, and the potential to link to genetic driver lines, with compelling evidence to support the claims made.

  4. eLife

    Reviewer #1 (Public Review):

    Summary:

    Drosophila is one of the most studied model organisms to understand how neural circuits form and function to control intricate animal behaviors. The ventral nerve cord (VNC) part of the fly's CNS serves as a sensory processing and motor output center just like our spinal cord. Over the last decade, the VNC has become a fruitful platform to understand neural circuits responsible for motor behavior such as walking and flying. The missing resource was the complete connectome of the VNC neurons. This study provides this needed resource. The authors documented their approaches on how to generate the data from tissue preparation to computer-assisted reconstruction in a simple manner and left the in-depth analysis of the network features of the connecting neurons to two other well-written companion articles.

    Strengths:
    Unlike many other previously published EM datasets, the authors presented a ready-to-view connectome dataset of the adult fly VNC. Readers, without needing permission, can access the dataset to find their neurons of interest and determine their synaptic partners with a few clicks. The authors also share their novel approaches in a detailed manner for others to reproduce similar EM volumes for other tissues.

    Weaknesses:

    The reconstruction completion, around 50%, might be considered a weakness. However, the data appear to have ~ %50 completion across all different neuropils suggesting that sampling is homogenous and does not induce bias. Nevertheless, a higher percentage will give a more complete picture.

  5. eLife

    Reviewer #2 (Public Review):

    Summary:

    Takemura et al. achieved a milestone in connectomics with their dense reconstruction of the Male Adult Nerve Cord (MANC) in Drosophila, revealing the neural circuitry of the primary premotor and motor domains in the CNS of the fruit fly. The team meticulously reconstructed neuron morphologies and synaptic connections and registered these data with light microscopy datasets (of driver lines for example), made neuronal lineage annotations and neurotransmitter predictions, providing the basis for new hypotheses about motor control. A description of the dataset and methods are presented here, while cell type annotations and characterisation of connectivity between brain descending neurons and motor neurons are provided in two companion papers, Marin et al. and Cheong, Eichler, Stürner et al., respectively. This dataset and analysis will provide a rich resource for future neuroscientific exploration.

    Strengths:

    The authors fully utilise a wealth of tools and techniques developed over the course of over a decade to produce a new publicly available dataset with an impressive number of reconstructed neurons and synapses. The precision and recall of connections are as high or higher than past datasets (e.g. the Hemibrain), pointing to the reliability of any downstream analyses performed on this connectome. These data are augmented with neurotransmitter identities, providing essential information for modelling and computational analysis. The MANC connectome can also be linked to genetic tools through registration to pre-existing light microscopy datasets, allowing experimentalists to test hypotheses made based on the connectome.

    Weaknesses:

    This dataset presents the nerve cord connectome of just a single animal, so connectivity variability and validity will be hard to assess. However, it is bilaterally reconstructed, which does allow comparison between bilaterally symmetrical neurons on the left and right sides of the nerve cord, increasing confidence in connections observed on both sides. Damage occurred to the nerves during sample preparation, which will have to be considered when analysing sensory connectivity.

  6. Version published to 10.1101/2023.06.05.543757v1 on bioRxiv