Cell migration in dense microenvironments.

Pub Date : 2023-09-21 DOI:10.5802/crbiol.124
Guilherme Pedreira de Freitas Nader, Juan Manuel García-Arcos
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Abstract

The nucleus has been viewed as a passenger during cell migration that functions merely to protect the genome. However, increasing evidence shows that the nucleus is an active organelle, constantly sensing the surrounding environment and translating extracellular mechanical inputs into intracellular signaling. The nuclear envelope has a large membrane reservoir which serves as a buffer for mechanical inputs as it unfolds without increasing its tension. In contrast, when cells cope with mechanical strain, such as migration through solid tumors or dense interstitial spaces, the nuclear envelope folds stretch, increasing nuclear envelope tension and sometimes causing rupture. Different degrees of nuclear envelope tension regulate cellular behaviors and functions, especially in cells that move and grow within dense matrices. The crosstalk between extracellular mechanical inputs and the cell nucleus is a critical component in the modulation of cell function of cells that navigate within packed microenvironments. Moreover, there is a link between regimes of nuclear envelope unfolding and different cellular behaviors, from orchestrated signaling cascades to cellular perturbations and damage.

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密集微环境中的细胞迁移。
细胞核被视为细胞迁移过程中的乘客,其功能仅为保护基因组。然而,越来越多的证据表明,细胞核是一种活跃的细胞器,不断感知周围环境,并将细胞外机械输入转化为细胞内信号。核外壳有一个大的膜储器,在不增加张力的情况下展开时,它可以作为机械输入的缓冲。相反,当细胞应对机械应变时,如通过实体瘤或致密间隙迁移时,核膜折叠会拉伸,增加核膜张力,有时会导致破裂。不同程度的核膜张力调节细胞的行为和功能,尤其是在致密基质中移动和生长的细胞中。细胞外机械输入和细胞核之间的串扰是在拥挤的微环境中导航的细胞的细胞功能调节的关键组成部分。此外,核膜展开机制和不同的细胞行为之间存在联系,从精心策划的信号级联到细胞扰动和损伤。
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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