Transitions between cooperative and crowding-dominated collective motion in non-jammed MDCK monolayers.

IF 2.1 4区生物学 Q3 DEVELOPMENTAL BIOLOGY

Cells & Development Pub Date : 2024-12-19 DOI:10.1016/j.cdev.2024.203989

Steven J Chisolm, Emily Guo, Vignesh Subramaniam, Kyle D Schulze, Thomas E Angelini

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引用次数: 0

Abstract

Transitions between solid-like and fluid-like states in living tissues have been found in steps of embryonic development and in stages of disease progression. Our current understanding of these transitions has been guided by experimental and theoretical investigations focused on how motion becomes arrested with increased mechanical coupling between cells, typically as a function of packing density or cell cohesiveness. However, cells actively respond to externally applied forces by contracting after a time delay, so it is possible that at some packing densities or levels of cell cohesiveness, mechanical coupling stimulates cell motion instead of suppressing it. Here we report our findings that at low densities and within multiple ranges of cell cohesiveness, cell migration speeds increase with these measures of mechanical coupling. Our observations run counter to our intuition that cell motion will be suppressed by increasingly packing or sticking cells together and may provide new insight into biological processes involving motion in dense cell populations.

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非阻塞MDCK单层中合作运动与群体主导运动之间的过渡。

在胚胎发育的各个阶段和疾病发展的各个阶段，都发现了活体组织在固体和液体状态之间的转变。我们目前对这些转变的理解是由实验和理论研究指导的，这些研究集中在运动如何随着细胞之间机械耦合的增加而被阻止，通常是作为堆积密度或细胞内聚性的函数。然而，细胞通过在一段时间延迟后收缩来积极响应外部施加的力，因此在某些堆积密度或细胞内聚水平下，机械耦合可能刺激而不是抑制细胞运动。在这里，我们报告了我们的发现，在低密度和多个细胞内聚范围内，细胞迁移速度随着这些机械耦合措施的增加而增加。我们的观察结果与我们的直觉相反，即细胞的运动将被越来越多的细胞包装或粘在一起而抑制，这可能为涉及密集细胞群体运动的生物过程提供新的见解。

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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来源期刊

Cells & Development DEVELOPMENTAL BIOLOGY-

CiteScore

3.70

自引率

0.00%

发文量