DTX4 regulates neural progenitor transitions during cortical development

Neural progenitors drive cellular diversification in the neocortex. Prolongation of their proliferative capacity and increased diversity underpins the evolutionary expansion and morphological complexity of the human neocortex. Here, we investigate the mechanisms that regulate maintenance of the highly proliferative early neural progenitor subtypes and transition to subsequent progenitors of limited proliferative capacity during human and murine neocortical development. We identify DTX4, a Deltex family member, as an evolutionarily conserved molecular determinant of neural progenitor identity in the mammalian neocortex. DTX4 sustains the identity of radial glia, a highly proliferative progenitor subtype. Loss of DTX4, on the other hand, is a prerequisite for the generation of intermediate progenitors which possess low proliferative capacity. Perturbing DTX4 expression in human cerebral organoids and in the murine neocortex, alters progenitor composition, thereby inducing changes in neuronal diversity and cortical morphology. Mechanistically, we reveal that DTX4 controls progenitor identity by regulating the length of the cell cycle. Our findings underscore the critical role of cell cycle dynamics and of DTX4 in determining progenitor identity and thereby defining neuronal outcome during mammalian development.