Changes in Wnt-Dependent Neuronal Morphology Underlie the Anatomical Diversification of Neocortical Homologs in Amniotes.

The six-layered neocortex is a shared characteristic of all mammals, but not of non-mammalian species, and its formation requires an inside-out pattern of neuronal migration. The extant reptilian dorsal cortex is thought to represent an ancestral form of the neocortex, although how the reptilian three-layered cortex is formed is poorly understood. Here, we show unique patterns of lamination and neuronal migration in the developing reptilian cortex. While the multipolar-to-bipolar transition of migrating neurons is essential for mammalian cortical development, the reptilian cortex lacks bipolar-shaped migrating neurons, resulting in an outside-in pattern of cortical development. Furthermore, dynamic regulation of Wnt signal strengths contributes to neuronal morphological changes, which is conserved across species. Our data preclude the idea that the six-layered mammalian neocortex emerged by simple addition to the reptilian dorsal cortex but suggest that the acquisition of a novel neuronal morphology based on conserved developmental programs contributed to neocortical evolution.