The Notch signal transduction pathway regulates the decision to proliferate versus differentiate. Although there are a myriad of mouse models for the Notch pathway, surprisingly little is known about how these genes regulate early eye development, particularly in the anterior lens. We employed both gain-of-function and loss-of-function approaches to determine the role of Notch signaling in lens development. Here we analyzed mice containing conditional deletion of the Notch effector Rbpj or overexpression of the activated Notch1 intracellular domain during lens formation. We demonstrate distinct functions for Notch signaling in progenitor cell growth, fiber cell differentiation and maintenance of the transition zone. In particular, Notch signaling controls the timing of primary fiber cell differentiation and is essential for secondary fiber cell differentiation. Either gain or loss of Notch signaling leads to formation of a dysgenic lens, which in loss-of-function mice undergoes a profound postnatal degeneration. Our data suggest both Cyclin D1 and Cyclin D2, and the p27(Kip1) cyclin-dependent kinase inhibitor act downstream of Notch signaling, and define multiple critical functions for this pathway during lens development.
CNS progenitors choose a fate, exit mitosis and differentiate. Basic helix-loop-helix (bHLH) transcription factors are key regulators of neurogenesis, but their molecular mechanisms remain unclear. In the mouse retina, removal of the bHLH factor Math5 (Atoh7) causes the loss of retinal ganglion cells (RGCs) and appearance of excess cone photoreceptors. Here, we show a simultaneous requirement for Math5 in retinal neuron formation and cell cycle progression. At embryonic day E11.5, Math5-/- cells are unable to assume the earliest fates, particularly that of an RGC, and instead adopt the last fate as Müller glia. Concurrently, the loss of Math5 causes mitotically active retinal progenitors to undergo aberrant cell cycles. The drastic fate shift of Math5-/- cells correlates with age-specific alterations in p27/Kip1 expression and an inability to become fully postmitotic. Finally, Math5 normally suppresses NeuroD1 within Math5-expressing cells and inhibits Ngn2 expression and cone photoreceptor genesis within separate cell populations. Thus, Math5 orchestrates neurogenesis in multiple ways, regulating both intrinsic and extrinsic processes.
In the mammalian retina, neuronal differentiation begins in the dorso-central optic cup and sweeps peripherally and ventrally. While certain extrinsic factors have been implicated, little is known about the intrinsic factors that direct this process. In this study, we evaluate the expression and function of proneural bHLH transcription factors during the onset of mouse retinal neurogenesis. Dorso-central retinal progenitor cells that give rise to the first postmitotic neurons express Neurog2/Ngn2 and Atoh7/Math5. In the absence of Neurog2, the spread of neurogenesis stalls, along with Atoh7 expression and RGC differentiation. However, neurogenesis is eventually restored, and at birth Neurog2 mutant retinas are reduced in size, with only a slight increase in the retinal ganglion cell population. We find that the re-establishment of neurogenesis coincides with the onset of Ascl1 expression, and that Ascl1 can rescue the early arrest of neural development in the absence of Neurog2. Together, this study supports the hypothesis that the intrinsic factors Neurog2 and Ascl1 regulate the temporal progression of retinal neurogenesis by directing overlapping waves of neuron formation.
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