The positioning of stress fibers in contractile cells minimizes internal mechanical stress

arXiv - QuanBio - Subcellular Processes Pub Date : 2024-07-10 DOI:arxiv-2407.07797

Lukas RiedelHeidelberg University, Valentin WössnerHeidelberg University, Dominic KempfHeidelberg University, Falko ZiebertHeidelberg University, Peter BastianHeidelberg University, Ulrich S. SchwarzHeidelberg University

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Abstract

The mechanics of animal cells is strongly determined by stress fibers, which are contractile filament bundles that form dynamically in response to extracellular cues. Stress fibers allow the cell to adapt its mechanics to environmental conditions and to protect it from structural damage. While the physical description of single stress fibers is well-developed, much less is known about their spatial distribution on the level of whole cells. Here, we combine a finite element method for one-dimensional fibers embedded in an elastic bulk medium with dynamical rules for stress fiber formation based on genetic algorithms. We postulate that their main goal is to achieve minimal mechanical stress in the bulk material with as few fibers as possible. The fiber positions and configurations resulting from this optimization task alone are in good agreement with those found in experiments where cells in 3D-scaffolds were mechanically strained at one attachment point. For optimized configurations, we find that stress fibers typically run through the cell in a diagonal fashion, similar to reinforcement strategies used for composite material.

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收缩细胞中应力纤维的定位可最大限度地减少内部机械应力

动物细胞的机械结构在很大程度上由应力纤维决定，应力纤维是一种收缩丝束，它是根据细胞外线索动态形成的。应力纤维使细胞的力学结构适应环境条件，并保护细胞免受结构损伤。虽然对单根应力纤维的物理描述已经非常成熟，但对它们在整个细胞水平上的空间分布却知之甚少。在此，我们将嵌入弹性体介质中的一维纤维的有限元方法与基于遗传算法的应力纤维形成动力学规则相结合。我们推测，它们的主要目标是以尽可能少的纤维实现散体材料中最小的机械应力。通过这项优化任务得出的纤维位置和配置与在实验中发现的纤维位置和配置非常吻合，在实验中，3D 模架中的细胞在一个附着点上受到机械应力。对于优化配置，我们发现应力纤维通常以对角线方式穿过细胞，这与复合材料的加固策略类似。

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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arXiv - QuanBio - Subcellular Processes

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