An extra-circadian function for human CLOCK in the neocortex

Abstract

AbstractCore circadian-related proteins such as the transcription factor CLOCK are ubiquitously expressed and important for regulating molecular pathways underlying circadian rhythms. Previous work has suggested that CLOCK has evolved human neocortex-specific gene regulation and therefore may have extra-circadian functions. To test this in vivo, we generated a mouse model that recapitulates human cortical expression of CLOCK. The CLOCK humanized (HU) mice show enhanced cognitive flexibility, which is associated with the alteration in spatiotemporal expression of CLOCK. Cell type specific genomic profiling of HU mice identified upregulated genes related to dendritic growth and spine formation in excitatory neurons. Consistent with this result, we found that excitatory neurons in HU mice have increased complexity of dendritic branching and spine density, as well as a greater frequency of excitatory postsynaptic currents, suggesting an increase in neural connectivity. In contrast, CLOCK knockout in human induced pluripotent stem cell-induced neurons showed reduced complexity of dendrites and lower density of presynaptic puncta. Together, our data demonstrate that CLOCK evolved extra-circadian gains of function via altered spatiotemporal gene expression and these functions may underlie human brain specializations.