A consensus cell type atlas from multiple connectomes reveals principles of circuit stereotypy and variation.
Philipp SchlegelYijie YinAlexander Shakeel BatesSven DorkenwaldKatharina EichlerPaul BrooksDaniel S HanMarina GkantiaMarcia Dos SantosEva J MunnellyGriffin BadalamenteLaia Serratosa CapdevilaVarun A SaneMarkus William PleijzierImaan F M TamimiChristopher R DunneIrene SalgarellaAlexandre JavierSiqi FangEric PerlmanTom KazimiersSridhar R JagannathanArie MatsliahAmy R SterlingSzi-Chieh YuClaire E McKellarFlyWire ConsortiumMarta CostaH Sebastian SeungMala MurthyVolker HartensteinDavi D BockGregory S X E JefferisPublished in: bioRxiv : the preprint server for biology (2023)
The fruit fly Drosophila melanogaster combines surprisingly sophisticated behaviour with a highly tractable nervous system. A large part of the fly's success as a model organism in modern neuroscience stems from the concentration of collaboratively generated molecular genetic and digital resources. As presented in our FlyWire companion paper 1 , this now includes the first full brain connectome of an adult animal. Here we report the systematic and hierarchical annotation of this ∼130,000-neuron connectome including neuronal classes, cell types and developmental units (hemilineages). This enables any researcher to navigate this huge dataset and find systems and neurons of interest, linked to the literature through the Virtual Fly Brain database 2 . Crucially, this resource includes 4,179 cell types of which 3,166 consensus cell types are robustly defined by comparison with a second dataset, the "hemibrain" connectome 3 . Comparative analysis showed that cell type counts and strong connections were largely stable, but connection weights were surprisingly variable within and across animals. Further analysis defined simple heuristics for connectome interpretation: connections stronger than 10 unitary synapses or providing >1% of the input to a target cell are highly conserved. Some cell types showed increased variability across connectomes: the most common cell type in the mushroom body, required for learning and memory, is almost twice as numerous in FlyWire than in the hemibrain. We find evidence for functional homeostasis through adjustments of the absolute amount of excitatory input while maintaining the excitation-inhibition ratio. Finally, and surprisingly, about one third of the cell types recorded in the hemibrain connectome could not be robustly identified in the FlyWire connectome, cautioning against defining cell types based on single connectomes. We propose that a cell type should be robust to inter-individual variation, and therefore defined as a group of cells that are more similar to cells in a different brain than to any other cell in the same brain. We show that this new definition can be consistently applied to whole connectome datasets. Our work defines a consensus cell type atlas for the fly brain and provides both an intellectual framework and open source toolchain for brain-scale comparative connectomics.