Mechanistic basis of lineage restriction

Bohou Wu, Jae Hyun Lee, Kara M. Foshay, Li Zhang, Croydon J. Fernandes, Boyang Gao, Xiaoyang Dou, Chris Z. Zhang, Guoping Fan, Becky X. Xiao, Bruce T. Lahn
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Abstract

Lineage restriction, the biological phenomenon whereby developing cells progressively lose fate potency for all but their adopted lineages, is foundational to multicellular lifeforms as it secures the functional identities of the myriad cell types in the body. The mechanisms of lineage restriction remain enigmatic. We previously defined occlusion as a mode of gene silencing wherein affected genes lack the transcriptional potency to be activated by their cognate transcription factors (TFs). Here, we present a comprehensive mechanistic basis of lineage restriction as driven by gene occlusion. Specifically, we show that genes can become occluded simply by the default action of chromatinization in the absence of TF binding, that naive pluripotent stem cells establish full developmental potency via their capacity to erase occlusion, that primed pluripotent cells shut down this deocclusion ability in preparation for differentiation, that differentiating cells become increasingly restricted in their fate potency by the irreversible occlusion of lineage-inappropriate genes, and that stem cells employ placeholder factors (PFs) to protect silent genes needed for later activation from premature occlusion. Collectively, these mechanisms drive lineage restriction whereby the transcriptionally potent portion of the genome shrinks progressively during differentiation, rendering the fate potency of developing cells to also dwindle progressively.
血统限制的机制基础
细胞系限制是一种生物现象,发育中的细胞会逐渐丧失除所采用的细胞系之外的所有细胞系的命运潜能,它是多细胞生命体的基础,因为它确保了体内无数细胞类型的功能特性。世系限制的机制仍然是个谜。我们之前将闭锁定义为一种基因沉默模式,在这种模式下,受影响的基因缺乏被其同源转录因子(TFs)激活的转录效力。在这里,我们提出了由基因闭锁驱动的世系限制的全面机理基础。具体来说,我们表明,在没有转录因子结合的情况下,基因可以仅仅通过染色质化的默认作用而闭锁,幼稚的多能干细胞通过其消除闭锁的能力而建立起完全的发育潜能,原始的多能细胞在准备分化的过程中关闭了这种消除闭锁的能力、分化细胞的命运潜能因不可逆的不适合品系基因闭锁而日益受限,干细胞利用占位因子(PFs)保护日后激活所需的沉默基因不过早闭锁。总之,这些机制驱动着系限制,基因组转录效力部分在分化过程中逐渐缩小,使发育中细胞的命运效力也逐渐减弱。
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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