PROJECT SUMMARY Neural self-avoidance is a fundamental yet poorly understood process that is essential for proper brain wiring. Self-avoidance describes the tendency of neurites originating from the same cell to avoid each other while innervating target brain regions and finding synaptic targets. This process is mediated by the clustered Protocadherin (Pcdh) genes, which are differentially expressed between neurons and act as cell-surface molecular barcodes: neurites presenting the same combination of Pcdh isoforms repel each other, while those presenting different combinations can interact. Despite their central role in brain wiring, the regulation of Pcdh genes remains an unsolved problem in neuroscience. Specifically, the mechanism by which neurons choose specific Pcdh isoforms to express during development, and how this choice is maintained across the lifespan of a neuron, are unclear. Recent work has demonstrated a role for cohesin-mediated DNA loop extrusion in tuning Pcdh expression across cell types, suggesting that 3D genome architecture is a critical determinant of Pcdh gene choice. This proposal aims to test this model in vivo by using optical reconstruction of chromatin architecture (ORCA), a method for imaging single-allele genome structure in thousands of single cells, to study Pcdh locus topology in neurons of the olfactory epithelium (OE) and their precursors. By combining ORCA with RNA labelling of OE cell types and Pcdh isoforms, the first aim will establish a developmental clock of Pcdh gene choice that links 3D genome folding to the onset of Pcdh expression during development. Genetic mouse lines will be used to abolish cohesin activity in each cell type to determine how cohesin controls Pcdh choice across development. The second aim will address how cells achieve transcriptional stability of Pcdh genes across their lifetimes by considering a role for heterochromatin in the continued silencing of non-chosen Pcdh genes. Through single-cell sequencing and ORCA experiments, the ability of heterochromatin to stabilize Pcdh gene expression by sequestering non-chosen promoters away from Pcdh enhancers will be tested. Overall, these studies will have implications across multiple fields, including brain wiring, translational neuroscience, and gene regulation. First, they will reveal strategies by which neurons establish proper morphologies, an essential step in circuit formation across the brain, as seen here through the formation of olfactory maps. Second, Pcdh dysregulation is associated with multiple neuropsychiatric and neurodegenerative disorders, including schizophrenia and autism. The principles of Pcdh gene regulation shown here will advance our understanding of these disorder mechanisms and identify potential avenues for therapeutic intervention. And lastly, the functions of cohesin in gene regulation have been difficult to determine. The protein complex has primarily been studied in dividing cells in vitro, where it also pla...