Architectural control of mesenchymal stem cell phenotype through nuclear actin.

Nucleus (Austin, Tex.) Pub Date : 2022-12-01 DOI:10.1080/19491034.2022.2029297

Janet Rubin, Andre J van Wijnen, Gunes Uzer

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Abstract

There is growing appreciation that architectural components of the nucleus regulate gene accessibility by altering chromatin organization. While nuclear membrane connector proteins link the mechanosensitive actin cytoskeleton to the nucleoskeleton, actin's contribution to the inner architecture of the nucleus remains enigmatic. Control of actin transport into the nucleus, plus the presence of proteins that control actin structure (the actin tool-box) within the nucleus, suggests that nuclear actin may support biomechanical regulation of gene expression. Cellular actin structure is mechanoresponsive: actin cables generated through forces experienced at the plasma membrane transmit force into the nucleus. We posit that dynamic actin remodeling in response to such biomechanical cues provides a novel level of structural control over the epigenetic landscape. We here propose to bring awareness to the fact that mechanical forces can promote actin transfer into the nucleus and control structural arrangements as illustrated in mesenchymal stem cells, thereby modulating lineage commitment.

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通过核肌动蛋白对间充质干细胞表型进行结构控制。

人们越来越认识到，细胞核的结构成分通过改变染色质组织来调节基因的可及性。虽然核膜连接蛋白将机械敏感的肌动蛋白细胞骨架与核骨架连接起来，但肌动蛋白对细胞核内部结构的贡献仍然是个谜。控制肌动蛋白运输进入细胞核，再加上细胞核内存在控制肌动蛋白结构的蛋白质（肌动蛋白工具箱），表明核肌动蛋白可能支持基因表达的生物力学调控。细胞肌动蛋白结构具有机械传导性：质膜受力产生的肌动蛋白索将力传入细胞核。我们认为，根据这种生物力学线索进行的动态肌动蛋白重塑为表观遗传景观提供了一种新的结构控制水平。在此，我们建议让人们认识到，机械力可以促进肌动蛋白向细胞核传递，控制结构排列，如间充质干细胞所示，从而调节血统承诺。

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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Nucleus (Austin, Tex.)

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