Distributed control circuits across a brain-and-cord connectome

  1. Alexander Shakeel Bates
  2. Jasper S Phelps
  3. Minsu Kim
  4. Helen H Yang
  5. Arie Matsliah
  6. Zaki Ajabi
  7. Eric Perlman
  8. Kevin M Delgado
  9. Mohammed Abdal Monium Osman
  10. Christopher K Salmon
  11. Jay Gager
  12. Benjamin Silverman
  13. Sophia Renauld
  14. Matthew F Collie
  15. Jingxuan Fan
  16. Diego A Pacheco
  17. Yunzhi Zhao
  18. Janki Patel
  19. Wenyi Zhang
  20. Laia Serratosa Capdevilla
  21. Ruairi JV Roberts
  22. Eva J Munnelly
  23. Nina Griggs
  24. Helen Langley
  25. Borja Moya-Llamas
  26. Ryan T Maloney
  27. Szi-chieh Yu
  28. Amy R Sterling
  29. Marissa Sorek
  30. Krzysztof Kruk
  31. Nikitas Serafetinidis
  32. Serene Dhawan
  33. Tomke Stuerner
  34. Finja Klemm
  35. Paul Brooks
  36. Ellen Lesser
  37. Jessica M Jones
  38. Sara E Pierce-Lundgren
  39. Su-Yee Lee
  40. Yichen Luo
  41. Andrew P Cook
  42. Theresa H McKim
  43. Emily C Kophs
  44. Tjalda Falt
  45. Alexa M Negron Morales
  46. Austin Burke
  47. James Hebditch
  48. Kyle P Willie
  49. Ryan Willie
  50. Sergiy Popovych
  51. Nico Kemnitz
  52. Dodam Ih
  53. Kisuk Lee
  54. Ran Lu
  55. Akhilesh Halageri
  56. J. Alexander Bae
  57. Ben Jourdan
  58. Gregory Schwartzman
  59. Damian D Demarest
  60. Emily Behnke
  61. Doug Bland
  62. Anne Kristiansen
  63. Jaime Skelton
  64. Tom Stocks
  65. Dustin Garner
  66. Farzaan Salman
  67. Kevin C Daly
  68. Anthony Hernandez
  69. Sandeep Kumar
  70. The BANC-FlyWire Consortium
  71. Sven Dorkenwald
  72. Forrest Collman
  73. Marie P Suver
  74. Lisa M Fenk
  75. Michael J Pankratz
  76. Gregory SXE Jefferis
  77. Katharina Eichler
  78. Andrew M Seeds
  79. Stefanie Hampel
  80. Sweta Agrawal
  81. Meet Zandawala
  82. Thomas Macrina
  83. Diane-Yayra Adjavon
  84. Jan Funke
  85. John C Tuthill
  86. Anthony Azevedo
  87. H. Sebastian Seung
  88. Benjamin L de Bivort
  89. Mala Murthy
  90. Jan Drugowitsch
  91. Rachel I Wilson
  92. Wei-Chung Allen Lee
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Abstract

Just as genomes revolutionized molecular genetics, connectomes (maps of neurons and synapses) are transforming neuroscience. To date, the only species with complete connectomes are worms1-3 and sea squirts4 (103-104 synapses). By contrast, the fruit fly is more complex (108 synaptic connections), with a brain that supports learning and spatial memory5,6 and an intricate ventral nerve cord analogous to the vertebrate spinal cord7-11. Here we report the first adult fly connectome that unites the brain and ventral nerve cord, and we leverage this resource to investigate principles of neural control. We show that effector cells (motor neurons, endocrine cells and efferent neurons targeting the viscera) are primarily influenced by local sensory cells in the same body part, forming local feedback loops. These local loops are linked by long-range circuits involving ascending and descending neurons organized into behavior-centric modules. Single ascending and descending neurons are often positioned to influence the voluntary movement of multiple body parts, together with endocrine cells or visceral organs that support those movements. Brain regions involved in learning and navigation supervise these circuits. These results reveal an architecture that is distributed, parallelized and embodied (tightly connected to effectors), reminiscent of distributed control architectures in engineered systems12,13.

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