Characterizing of robo downstream signalling to promote direct neurogenesis

Resumen

The size and degree of folding of the mammalian cortex are pivotal factors that affect species¿ cognitive abilities and sensorimotor skills. The cerebral cortex is the main region in the mammalian brain that governs complex cognitive behaviors. The development of the cortex depends on the amplification of neural stem cells (NSCs), neural progenitors (NPs) and the generation and differentiation of postmitotic neurons. There are two main types of NPs in the mouse neocortex (NCx): apical radial glia (aRGCs) and intermediate progenitor cells (IPCs). Robo receptors play an important role in regulating the amplification of cortical progenitors. The absence of Robo receptor signalling plus the alteration of the Notch signalling pathway in the mouse NCx leads to an overproduction of poorly functional IPCs. Ancient amniotic cortices exhibit a predominance of direct neurogenesis during development, where aRGCs produce neurons directly. Intriguingly, Robo receptors as well as Notch signalling play a major role in attenuating the mode of neurogenesis. This hypothesis was validated in several brain structures with phyletic antiquity, confirming that Robo receptors are essential in the shift towards indirect neurogenesis during the evolution and expansion of the cerebral cortex. However, little is known about the precise signalling cascade or interactors employed by Robo to initiate direct neurogenesis. In this thesis, we demonstrated the transcriptomic differences between the developing mouse NCx and OB (where direct neurogenesis is predominant in the OB vs NCx) using single cell RNA sequencing (scRNA). We showed aRGCs populations that are differently enriched between these regions. We traced lineage trajectories of indirect and direct neurogenesis, as well as validating the expression of several differentially expressed genes between the two regions. We used Robo intracellular domain (ICD)¿this region is considered a constitutively active form of Robo receptor¿and demonstrated the protein interactors that bind it. Following that, we demonstrated Robo ICD localization to the nucleus. We discovered that Robo conserved cytoplasmic domains play an important role in Robo ICD nucleocytoplasmic localization and direct neurogenesis induction in the mouse NCx. Next, we showed that Robo ICD localizes to chromatin, and causes transcriptional changes that occur upon the experimental gain of function of Robo ICD in the NCx and in vitro. Additionally, we showed that loss of function of Nup107, a nuclear pore complex (NPC) protein and one of Robo ICD protein interactors, induces direct neurogenesis in mouse NCx and chick lateral pallium. Taken together, our findings suggest the transcriptional role Robo ICD exerts by binding DNA and, consequently, its conserved role in moderating direct neurogenesis.