Abstract
SummaryIdentifying distinct anatomical structures within the brain and developing genetic tools to target them are fundamental steps for understanding brain function. We hypothesize that enhancer expression patterns can be used to automatically identify functional units such as neuropils and fiber tracts. We used two recent, genome-scale Drosophila GAL4 libraries and associated confocal image datasets to segment large brain regions into smaller subvolumes. Our results (available at https://strawlab.org/braincode) support this hypothesis because regions with well-known anatomy, namely the antennal lobes and central complex, were automatically segmented into familiar compartments. The basis for the structural assignment is clustering of voxels based on patterns of enhancer expression. These initial clusters are agglomerated to make hierarchical predictions of structure. We applied the algorithm to central brain regions receiving input from the optic lobes. Based on the automated segmentation and manual validation, we can identify and provide promising driver lines for 11 previously identified and 14 novel types of visual projection neurons and their associated optic glomeruli. The same strategy can be used in other brain regions and likely other species, including vertebrates.
Highlights
A key goal of neuroscientists is to understand brain structure and function and their relation to behavior
We applied the algorithm to central brain regions receiving input from the optic lobes
Whereas local interneurons might be confined to particular clusters, other cell types extend through multiple clusters and into more distant brain regions
Summary
A key goal of neuroscientists is to understand brain structure and function and their relation to behavior. The VPNs are incompletely cataloged and no systematic map of the optic glomeruli is available This region is interesting because the VPNs are an information bottleneck; visual information from the cell-rich optic lobes must pass through the VPNs—with small numbers of cell types and absolute cell counts—before reaching the central brain, where it can influence behavior. Each VPN type and corresponding glomerulus may carry information about a specific visual feature, and the array of glomeruli process information so the animal can respond appropriately [11, 13, 16, 19, 20] As it has been with the Drosophila olfactory system, genetic access to VPN cell types and other cell types innervating the optic glomeruli will be useful in elucidating visual circuit function
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