Loss of Brap Results in Premature G1/S Phase Transition and Impeded Neural Progenitor Differentiation.

Cells initiate fate decisions during G1 phase by converting extracellular signals into distinctive cell cycle kinetics. The DNA replication timing is determined in G1 phase; lengthened G1 and hastened S phases correlate with increased neurogenic propensity of neural progenitor cells (NPCs), although the underlying molecular control remains elusive. Here, we report that proper G1 phase completion in NPCs requires Brap, a Ras-Erk signaling modulator with ubiquitin E3 ligase activity. We identified Skp2 and Skp2-associated SCF ubiquitin ligase as a key target of Brap-mediated polyubiquitination. Loss of Brap resulted in elevated Skp2, which increased p27Kip1 destruction, leading to G1 phase truncation and premature S phase entry. The aberrantly executed G1 in Brap-mutant NPCs, followed by hindered S phase progression and increased G2 phase arrest, which together prolonged the cell cycle, impeded neuronal differentiation and culminated in microcephaly. These findings demonstrate that neuronal differentiation is potentiated during G1 phase by Brap-directed cascade of events in cell signaling and protein turnover.

Upregulation of neurovascular communication through filamin abrogation promotes ectopic periventricular neurogenesis.

Neuronal fate-restricted intermediate progenitors (IPs) are derived from the multipotent radial glia (RGs) and serve as the direct precursors for cerebral cortical neurons, but factors that control their neurogenic plasticity remain elusive. Here we report that IPs' neuron production is enhanced by abrogating filamin function, leading to the generation of periventricular neurons independent of normal neocortical neurogenesis and neuronal migration. Loss of Flna in neural progenitor cells (NPCs) led RGs to undergo changes resembling epithelial-mesenchymal transition (EMT) along with exuberant angiogenesis that together changed the microenvironment and increased neurogenesis of IPs. We show that by collaborating with ß-arrestin, Flna maintains the homeostatic signaling between the vasculature and NPCs, and loss of this function results in escalated Vegfa and Igf2 signaling, which exacerbates both EMT and angiogenesis to further potentiate IPs' neurogenesis. These results suggest that the neurogenic potential of IPs may be boosted in vivo by manipulating Flna-mediated neurovascular communication.

Spatially dependent dynamic MAPK modulation by the Nde1-Lis1-Brap complex patterns mammalian CNS.

Regulating cell proliferation and differentiation in CNS development requires both extraordinary complexity and precision. Neural progenitors receive graded overlapping signals from midline signaling centers, yet each makes a unique cell fate decision in a spatiotemporally restricted pattern. The Nde1-Lis1 complex regulates individualized cell fate decisions based on the geographical location with respect to the midline. While cells distant from the midline fail to self-renew in the Nde1-Lis1 double-mutant CNS, cells embedded in the signaling centers showed marked overproliferation. A direct interaction between Lis1 and Brap, a mitogen-activated protein kinase (MAPK) signaling threshold modulator, mediates this differential response to mitogenic signal gradients. Nde1-Lis1 deficiency resulted in a spatially dependent alteration of MAPK scaffold Ksr and hyperactivation of MAPK. Epistasis analyses supported synergistic Brap and Lis1 functions. These results suggest that a molecular complex composed of Nde1, Lis1, and Brap regulates the dynamic MAPK signaling threshold in a spatially dependent fashion.