The mammalian auditory sensory epithelium, the organ of Corti, contains sensory hair cells and nonsensory supporting cells arranged in a highly patterned mosaic. Notch-mediated lateral inhibition is the proposed mechanism for creating this sensory mosaic. Previous work has shown that mice lacking the Notch ligand JAG2 differentiate supernumerary hair cells in the cochlea,consistent with the lateral inhibitory model. However, it was not clear why only relatively modest increases in hair cell production were observed in Jag2 mutant mice. Here, we show that another Notch ligand, DLL1,functions synergistically with JAG2 in regulating hair cell differentiation in the cochlea. We also show by conditional inactivation that these ligands probably signal through the NOTCH1 receptor. Supernumerary hair cells in Dll1/Jag2 double mutants arise primarily through a switch in cell fate, rather than through excess proliferation. Although these results demonstrate an important role for Notch-mediated lateral inhibition during cochlear hair cell patterning, we also detected abnormally prolonged cellular proliferation that preferentially affected supporting cells in the organ of Corti. Our results demonstrate that the Notch pathway plays a dual role in regulating cellular differentiation and patterning in the cochlea, acting both through lateral inhibition and the control of cellular proliferation.
Sensory information from the periphery is integrated and transduced by excitatory and inhibitory interneurons in the dorsal spinal cord. Recent studies have identified a number of postmitotic factors that control the generation of these sensory interneurons. We show that Gsh1/2 and Ascl1 (Mash1), which are expressed in sensory interneuron progenitors, control the choice between excitatory and inhibitory cell fates in the developing mouse spinal cord. During the early phase of neurogenesis, Gsh1/2 and Ascl1 coordinately regulate the expression of Tlx3, which is a critical postmitotic determinant for dorsal glutamatergic sensory interneurons. However, at later developmental times, Ascl1 controls the expression of Ptf1a in dIL(A) progenitors to promote inhibitory neuron differentiation while at the same time upregulating Notch signaling to ensure the proper generation of dIL(B) excitatory neurons. We propose that this switch in Ascl1 function enables the cogeneration of inhibitory and excitatory sensory interneurons from a common pool of dorsal progenitors.
In vertebrates, skeletal myogenesis is initiated by the generation of myoblasts followed by their differentiation to myocytes and the formation of myofibers. The determination of myoblasts and their differentiation are controlled by muscle regulatory factors that are activated at specific stages during myogenesis. During late embryonic and fetal stages a distinct population of resident proliferating progenitor cells is the major source of myogenic cells. How the differentiation of myoblasts and progenitor cells is regulated is not clear. We show that in mouse embryos the Notch ligand Delta1 (Dll1) controls both differentiation of early myoblasts and maintenance of myogenic progenitor cells. Early dermomyotomederived myoblasts are determined normally in Dll1 mutant embryos, but their differentiation is accelerated, leading to a transient excess of myotomal muscle fibers. Similarly, migratory hypaxial myogenic cells colonize the limb buds and activate muscle regulatory factor expression normally, but muscle differentiation progresses more rapidly. Resident progenitor cells defined by Pax3/Pax7 expression are formed initially, but they are progressively lost and virtually absent at embryonic day 14.5. Muscle growth declines beginning around embryonic day 12, leading to subsequent severe muscle hypotrophy in hypomorphic Dll1 fetuses. We suggest that premature and excessive differentiation leads to depletion of progenitor cells and cessation of muscle growth, and we conclude that Dll1 provides essential signals that are required to prevent uncontrolled differentiation early and ensure sustained muscle differentiation during development. myogenesis ͉ Notch signaling ͉ skeletal muscle
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