Differential contribution of P73 ⁺ Cajal-Retzius cells and Reelin to cortical morphogenesis

Cajal-Retzius cells (CRs) are a peculiar neuronal type within the developing mammalian cerebral cortex. One of their best documented feature is the robust secretion of Reln, a glycoprotein essential for the establishment of cortical layers through the control of radial migration of glutamatergic neurons. We previously identified Gmnc as a critical fate determinant for P73 ⁺ CRs subtypes from the hem, septum and thalamic eminence. In Gmnc ^-/- mutants, P73 ⁺ CRs are initially produced, cover the telencephalic vesicle but undergo massive apoptosis resulting in their complete depletion at mid-corticogenesis. Here we investigated the consequence of such a CRs depletion on dorsal cortex lamination and hippocampal morphogenesis. We found preplate splitting occurs normally in Gmnc ^-/- mutants but is followed by defective radial migration arrest in the dorsal cortex, altered cellular organization in the lateral cortex, aberrant hippocampal progenitor proliferation resulting in abnormal CA1 folding and lack of vasculature development in the hippocampal fissure. We then performed conditional Reln deletion in P73 ⁺ CRs to evaluate its relative contribution and found that only radial migration defects were recapitulated. We concluded that at mid-corticogenesis, CRs-derived Reln is required for radial migration arrest and additionally identified Reln-independent functions for CRs in the control of hippocampal progenitor proliferation and vessel remodelling.