National Institute of Neurological Disorders and Stroke and National Human Genome Research Institute NIH, Bethesda, MD 20892, USA.
Development. 2011 May;138(9):1839-49. doi: 10.1242/dev.062471. Epub 2011 Mar 29.
Development of the segmented central nerve cords of vertebrates and invertebrates requires connecting successive neuromeres. Here, we show both how a pathway is constructed to guide pioneer axons between segments of the Drosophila CNS, and how motility of the pioneers along that pathway is promoted. First, canonical Notch signaling in specialized glial cells causes nearby differentiating neurons to extrude a mesh of fine projections, and shapes that mesh into a continuous carpet that bridges from segment to segment, hugging the glial surface. This is the direct substratum that pioneer axons follow as they grow. Simultaneously, Notch uses an alternate, non-canonical signaling pathway in the pioneer growth cones themselves, promoting their motility by suppressing Abl signaling to stimulate filopodial growth while presumably reducing substratum adhesion. This propels the axons as they establish the connection between successive segments.
脊椎动物和无脊椎动物的分段中央神经索的发育需要连接连续的神经节。在这里,我们展示了如何构建一条通路来引导果蝇中枢神经系统节段之间的先驱轴突,以及如何促进先驱沿着该通路的运动。首先,专门的神经胶质细胞中的经典 Notch 信号导致附近正在分化的神经元伸出一个由细突组成的网格,并将该网格塑造成一个连续的地毯,从一个节段延伸到另一个节段,紧贴着神经胶质表面。这是先驱轴突在生长过程中遵循的直接基质。同时,Notch 在先驱生长锥本身中使用另一种非经典信号通路,通过抑制 Abl 信号来促进丝状伪足的生长,从而刺激其运动,同时可能减少基质粘附。这推动了轴突在连续节段之间建立连接。