Recent advances in understanding cell type transitions during dorsal neural tube development.

Faculty reviews Pub Date : 2022-09-27 eCollection Date: 2022-01-01 DOI:10.12703/r/11-27
Chaya Kalcheim, Dina Rekler
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Abstract

The vertebrate neural tube is a representative example of a morphogen-patterned tissue that generates different cell types with spatial and temporal precision. More specifically, the development of the dorsal region of the neural tube is of particular interest because of its highly dynamic behavior. First, early premigratory neural crest progenitors undergo an epithelial-to-mesenchymal transition, exit the neural primordium, and generate, among many derivatives, most of the peripheral nervous system. Subsequently, the dorsal neural tube becomes populated by definitive roof plate cells that constitute an organizing center for dorsal interneurons and guide axonal patterning. In turn, roof plate cells transform into dorsal radial glia that contributes to and shapes the formation of the dorsal ependyma of the central nervous system. To form a normal functional spinal cord, these extraordinary transitions should be tightly regulated in time and space. Thus far, the underlying cellular changes and molecular mechanisms are only beginning to be uncovered. In this review, we discuss recent results that shed light on the end of neural crest production and delamination, the early formation of the definitive roof plate, and its further maturation into radial glia. The last of these processes culminate in the formation of the dorsal ependyma, a component of the stem cell niche of the central nervous system. We highlight how similar mechanisms operate throughout these transitions, which may serve to reveal common design principles applicable to the ontogeny of epithelial tissues.

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了解背神经管发育过程中细胞类型转变的最新进展。
脊椎动物神经管是形态模式组织的一个典型例子,它产生具有空间和时间精度的不同细胞类型。更具体地说,神经管背侧区域的发育是特别有趣的,因为它的高度动态行为。首先,早期的前迁移神经嵴祖细胞经历上皮细胞到间质细胞的转变,退出神经原基,并在许多衍生物中产生大部分周围神经系统。随后,背神经管被确定的顶板细胞填充,这些顶板细胞构成背侧中间神经元的组织中心并引导轴突模式。接着,顶板细胞转化为脊背放射状胶质细胞,并参与中枢神经系统脊背室管膜的形成。为了形成一个正常的功能脊髓,这些异常的转变应该在时间和空间上受到严格的调节。到目前为止,潜在的细胞变化和分子机制才刚刚开始被发现。在这篇综述中,我们讨论了最近的研究结果,揭示了神经嵴产生和分层的结束,最终顶板的早期形成,以及它进一步成熟为放射状胶质细胞。这些过程中的最后一个最终形成背室管膜,这是中枢神经系统干细胞生态位的一个组成部分。我们强调了在这些转变过程中相似的机制是如何运作的,这可能有助于揭示适用于上皮组织个体发生的共同设计原则。
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