Forkhead box protein P1 (FOXP1), a transcription factor enriched in the neocortex, is associated with autism spectrum disorders (ASDs) and FOXP1 syndrome. Emx1;Foxp1 conditional deletion (Foxp1 conditional knockout [cKO]) in the mouse cortex leads to overall reduced cortex thickness, alterations in cortical lamination, and changes in the relative thickness of cortical layers. However, the developmental and cell-type-specific mechanisms underlying these changes remained unclear. We find that Foxp1 deletion results in accelerated pseudo-age during early neurogenesis, increased cell cycle exit during late neurogenesis, altered gene expression and chromatin accessibility, and selective migration deficits in a subset of upper-layer neurons. These data explain the postnatal differences observed in cortical layers and relative cortical thickness. We also highlight genes regulated by FOXP1 and their enrichment with high-confidence ASD or synaptic genes. Together, these results underscore a network of neurodevelopmental-disorder-related genes that may serve as potential modulatory targets for postnatal modification relevant to ASDs and FOXP1 syndrome.
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