On becoming neural: what the embryo can tell us about differentiating neural stem cells.

IF 1.5 Q4 CELL BIOLOGY
American journal of stem cells Pub Date : 2013-06-30 Print Date: 2013-01-01
Sally A Moody, Steven L Klein, Beverley A Karpinski, Thomas M Maynard, Anthony-Samuel Lamantia
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引用次数: 0

Abstract

THE EARLIEST STEPS OF EMBRYONIC NEURAL DEVELOPMENT ARE ORCHESTRATED BY SETS OF TRANSCRIPTION FACTORS THAT CONTROL AT LEAST THREE PROCESSES: the maintenance of proliferative, pluripotent precursors that expand the neural ectoderm; their transition to neurally committed stem cells comprising the neural plate; and the onset of differentiation of neural progenitors. The transition from one step to the next requires the sequential activation of each gene set and then its down-regulation at the correct developmental times. Herein, we review how these gene sets interact in a transcriptional network to regulate these early steps in neural development. A key gene in this regulatory network is FoxD4L1, a member of the forkhead box (Fox) family of transcription factors. Knock-down experiments in Xenopus embryos show that FoxD4L1 is required for the expression of the other neural transcription factors, whereas increased FoxD4L1 levels have three different effects on these genes: up-regulation of neural ectoderm precursor genes; transient down-regulation of neural plate stem cell genes; and down-regulation of neural progenitor differentiation genes. These different effects indicate that FoxD4L1 maintains neural ectodermal precursors in an immature, proliferative state, and counteracts premature neural stem cell and neural progenitor differentiation. Because it both up-regulates and down-regulates genes, we characterized the regions of the FoxD4L1 protein that are specifically involved in these transcriptional functions. We identified a transcriptional activation domain in the N-terminus and at least two domains in the C-terminus that are required for transcriptional repression. These functional domains are highly conserved in the mouse and human homologues. Preliminary studies of the related FoxD4 gene in cultured mouse embryonic stem cells indicate that it has a similar role in promoting immature neural ectodermal precursors and delaying neural progenitor differentiation. These studies in Xenopus embryos and mouse embryonic stem cells indicate that FoxD4L1/FoxD4 has the important function of regulating the balance between the genes that expand neural ectodermal precursors and those that promote neural stem/progenitor differentiation. Thus, regulating the level of expression of FoxD4 may be important in stem cell protocols designed to create immature neural cells for therapeutic uses.

关于神经分化:胚胎能告诉我们的关于神经干细胞分化的信息。
胚胎神经发育的最早步骤是由一组转录因子精心安排的,这些转录因子至少控制着三个过程:维持增殖的多能性前体,使神经外胚层扩张;它们向构成神经板的神经干细胞转变;神经祖细胞开始分化。从一个步骤过渡到下一个步骤需要每个基因组的顺序激活,然后在正确的发育时间下调。在此,我们回顾了这些基因集如何在转录网络中相互作用,以调节神经发育的这些早期步骤。这个调控网络中的一个关键基因是FoxD4L1,它是叉头盒(Fox)转录因子家族的成员。爪蟾胚胎敲除实验表明FoxD4L1是其他神经转录因子表达所必需的,而FoxD4L1水平的升高对这些基因有三种不同的影响:上调神经外胚层前体基因;神经板干细胞基因的瞬时下调神经祖细胞分化基因的下调。这些不同的作用表明FoxD4L1维持神经外胚层前体细胞处于未成熟的增殖状态,并抵消神经干细胞和神经前体细胞的过早分化。由于它同时上调和下调基因,我们对FoxD4L1蛋白中特异性参与这些转录功能的区域进行了表征。我们在n端发现了一个转录激活域,在c端发现了至少两个转录抑制域。这些功能域在小鼠和人类同源物中高度保守。对培养小鼠胚胎干细胞中FoxD4相关基因的初步研究表明,FoxD4在促进未成熟的神经外胚层前体和延缓神经祖细胞分化方面具有类似的作用。这些对爪蟾胚胎和小鼠胚胎干细胞的研究表明,FoxD4L1/FoxD4在调节神经外胚层前体细胞扩展基因和神经干/祖细胞分化基因之间的平衡方面具有重要功能。因此,调节FoxD4的表达水平在干细胞方案中可能是重要的,旨在创造用于治疗用途的未成熟神经细胞。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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