Meningeal-derived retinoic acid regulates neurogenesis via suppression of Notch and Sox2

Abstract

SummaryThe meninges act as a regulator of brain development by secreting ligands that act on neural cells to regulate neurogenesis and neuronal migration. Meningeal-derived retinoic acid (RA) promotes neocortical neural progenitor cell cycle exit; however, the underlying molecular mechanism is unknown. Here, we used spatial transcriptomics and profiling of retinoic-acid receptor-α (RARα) DNA binding inFoxc1-mutant embryos that lack meninges-derived ligands to identify the neurogenic transcriptional mechanisms of RA signaling in telencephalic neural progenitors. We determined that meningeal-derived RA controls neurogenesis by suppressing progenitor self-renewal pathways Notch signaling and the transcription factor Sox2. We show that RARα binds in theSox2otpromoter, a long non-coding RNA that regulatesSox2expression, and RA promotesSox2otexpression in neocortical progenitors. Our findings elucidate a previously unknown mechanism of how meningeal RA coordinates neocortical development and insight into how defects in meningeal development may cause neurodevelopmental disorders.