Whole-animal connectome and cell-type complement of the three-segmented 
Platynereis dumerilii larva

Verasztó, C; Jasek, S; Gühmann, M; Shahidi, R; Ueda, N; Beard, JD; Mendes, S; Heinz, K; Bezares-Calderón, LA; Williams, E; Jékely, G

doi:10.1101/2020.08.21.260984

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Whole-animal connectome and cell-type complement of the three-segmented Platynereis dumerilii larva

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Gühmann, M
Research Group Neurobiology of Marine Zooplankton, Max Planck Institute for Developmental Biology, Max Planck Society;

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Ueda, N
Research Group Neurobiology of Marine Zooplankton, Max Planck Institute for Developmental Biology, Max Planck Society;

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Mendes, S
Research Group Neurobiology of Marine Zooplankton, Max Planck Institute for Developmental Biology, Max Planck Society;

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引用

Verasztó, C., Jasek, S., Gühmann, M., Shahidi, R., Ueda, N., Beard, J., Mendes, S., Heinz, K., Bezares-Calderón, L., Williams, E., & Jékely, G. (submitted). Whole-animal connectome and cell-type complement of the three-segmented Platynereis dumerilii larva.

引用: https://hdl.handle.net/21.11116/0000-000E-35E2-7

要旨

Nervous systems coordinate effectors across the body during movements. We know little about the cellular-level structure of synaptic circuits for such body-wide control. Here we describe the whole-body synaptic connectome and cell-type complement of a three-segmented larva of the marine annelid Platynereis dumerilii. We reconstructed and annotated over 1,500 neurons and 6,500 non-neuronal cells in a whole-body serial electron microscopy dataset. The differentiated cells fall into 180 neuronal and 90 non-neuronal cell types. We analyse the modular network architecture of the entire nervous system and describe polysynaptic pathways from 428 sensory neurons to four effector systems – ciliated cells, glands, pigment cells and muscles. The complete somatic musculature and its innervation will be described in a companion paper. We also investigated intersegmental differences in cell-type complement, descending and ascending pathways, and mechanosensory and peptidergic circuits. Our work provides the basis for understanding whole-body coordination in annelids.