Animal nervous system organization is crucial for all body functions and its disruption can manifest in severe cognitive and behavioral impairment. This organization relies on features across scales, from nano-level localization of synapses, through multiplicities of neuronal morphologies and their contribution to circuit organization, to the high level stereotyped connections between different regions of the brain. The sheer complexity of this organ means that to date, we have yet to reconstruct and model the structure of a complete nervous system that is integrated across all these scales. Here, we present a complete structure-function model of the nematode C. elegans main neuropil, the nerve ring, which we derive by integrating the volumetric reconstruction from two animals with corresponding synaptic and gap junctional connectomes. Whereas previously the nerve ring was considered a densely packed tract of axons, we uncover internal organization into 5 functional bundles and show how they spatially constrain and support the synaptic connectome. We find that the C. elegans connectome is not invariant, but that a precisely wired core circuit is embedded in a background of variable connectivity, and propose a corresponding reference connectome for the core circuit. Using this reference, we show that the architecture of the C. elegans brain can be viewed as a modular Residual Network that supports sensory computation and integration, sensory-motor convergence, and brain-wide coordination. These findings point to scalable and robust features of brain organization that are likely universal across phyla. 2 Since the discovery of neurons and their connections through synapses and gap junctions, a major effort has focused on 3 characterizing these units and the micro-and macro-circuits that they comprise, culminating in a growing body of high 4 resolution nano-connectomic data across species 1-10 . Naturally, data, however rich, cannot, on their own provide explanatory 5 power to address the computation within circuits or to determine how these circuits communicate and coordinate information 6 flow to generate behavior. Indeed, constructing a comprehensive brain map will require a meaningful strategy for integrating 7 structure and function across scales. Achieving this feat in even a small animal can provide a useful model for postulating 8 principles of organization across scales 11 .
9The free-living nematode C. elegans has a small, compact nervous system 2 while exhibiting a range of complex, individual-10 ized behaviors, making it an ideal model system for studies of whole brain organization 11 . All 302 C. elegans neurons have been 11 anatomically characterized based on serial sectioned electron micrographs (EM) 2 to produce a whole animal connectome 2,5,12 .
12This animal's invariant cell-lineage 13 and anatomy 2 might suggest that its connectome too is invariant 14 . Unfortunately, the 13 small sample size of available reconstructions has precluded a reliable estimate of reproducibility and variability of th...
