神经元规范利用细胞周期间隙期固有的灵活性。

Neurogenesis (Austin, Tex.) Pub Date : 2015-11-13 eCollection Date: 2015-01-01 DOI:10.1080/23262133.2015.1095694
Benjamin Pfeuty
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引用次数: 1

摘要

从几乎无限增殖的多能干细胞开始,在器官发生过程中有序出现的谱系受限细胞类型显示出增殖能力下降同时分化特征范围增加,这意味着细胞周期进程和细胞分化之间存在严格的时空耦合。最近的一项计算模型研究在神经发生的背景下探讨了前神经g2因子、Hes1 Notch效应因子和拮抗作用的g1期调节因子之间的特殊连接模式是否以及如何在这一事件中起作用。本研究强调,累积的Neurog2和CKI对G1/S转运的强烈反对使得G1期延长和终末分化伴随G1晚期退出而发生的敏感控制。相比之下,Hes1促进早期g1细胞周期阻滞,其细胞自主振荡结合侧抑制机制有助于维持不稳定的增殖状态,与不同的细胞命运输出保持动态平衡,从而为细胞提供保持自我更新或分化为不同细胞类型的选择。这些与ascl1依赖性神经分化相关的结果表明,发育命运决定利用细胞周期间隙期固有的灵活性,通过选择细胞周期机制和分化途径组成部分之间微妙不同的连接模式来产生多样性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Neuronal specification exploits the inherent flexibility of cell-cycle gap phases.

Neuronal specification exploits the inherent flexibility of cell-cycle gap phases.

Starting from pluripotent stem cells that virtually proliferate indefinitely, the orderly emergence during organogenesis of lineage-restricted cell types exhibiting a decreased proliferative capacity concurrently with an increasing range of differentiation traits implies the occurrence of a stringent spatiotemporal coupling between cell-cycle progression and cell differentiation. A recent computational modeling study has explored in the context of neurogenesis whether and how the peculiar pattern of connections among the proneural Neurog2 factor, the Hes1 Notch effector and antagonistically-acting G1-phase regulators would be instrumental in this event. This study highlighted that the strong opposition to G1/S transit imposed by accumulating Neurog2 and CKI enables a sensitive control of G1-phase lengthening and terminal differentiation to occur concomitantly with late-G1 exit. Contrastingly, Hes1 promotes early-G1 cell-cycle arrest and its cell-autonomous oscillations combined with a lateral inhibition mechanism help maintain a labile proliferation state in dynamic balance with diverse cell-fate outputs, thereby, offering cells the choice to either keep self-renewing or differentiate into distinct cell types. These results, discussed in connection with Ascl1-dependent neural differentiation, suggest that developmental fate decisions exploit the inherent flexibility of cell-cycle gap phases to generate diversity by selecting subtly-differing patterns of connections among components of the cell-cycle machinery and differentiation pathways.

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