细胞接触导向源于间隙回避。

Cellular Contact Guidance Emerges from Gap Avoidance.

作者信息

Buskermolen Antonetta B C, Ristori Tommaso, Mostert Dylan, van Turnhout Mark C, Shishvan Siamak S, Loerakker Sandra, Kurniawan Nicholas A, Deshpande Vikram S, Bouten Carlijn V C

机构信息

Department of Biomedical Engineering, Eindhoven University of Technology, Eindhoven, the Netherlands.

Institute for Complex Molecular Systems, Eindhoven University of Technology, Eindhoven, the Netherlands.

出版信息

Cell Rep Phys Sci. 2020 May 20;1(5):100055. doi: 10.1016/j.xcrp.2020.100055.

DOI:10.1016/j.xcrp.2020.100055

PMID:32685934

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7357833/

Abstract

In the presence of anisotropic biochemical or topographical patterns, cells tend to align in the direction of these cues-a widely reported phenomenon known as "contact guidance." To investigate the origins of contact guidance, here, we created substrates micropatterned with parallel lines of fibronectin with dimensions spanning multiple orders of magnitude. Quantitative morphometric analysis of our experimental data reveals two regimes of contact guidance governed by the length scale of the cues that cannot be explained by enforced alignment of focal adhesions. Adopting computational simulations of cell remodeling on inhomogeneous substrates based on a statistical mechanics framework for living cells, we show that contact guidance emerges from anisotropic cell shape fluctuation and "gap avoidance," i.e., the energetic penalty of cell adhesions on non-adhesive gaps. Our findings therefore point to general biophysical mechanisms underlying cellular contact guidance, without the necessity of invoking specific molecular pathways.

摘要

在存在各向异性生化或地形学模式的情况下，细胞倾向于沿着这些线索的方向排列——这是一种被广泛报道的现象，称为“接触导向”。为了研究接触导向的起源，在此我们创建了用纤连蛋白平行线微图案化的底物，其尺寸跨越多个数量级。对我们实验数据的定量形态测量分析揭示了接触导向的两种机制，它们由线索的长度尺度所控制，而这无法通过粘着斑的强制排列来解释。基于活细胞的统计力学框架，采用非均匀底物上细胞重塑的计算模拟，我们表明接触导向源于各向异性的细胞形状波动和“间隙规避”，即细胞粘着在非粘着间隙上的能量惩罚。因此，我们的发现指出了细胞接触导向背后的一般生物物理机制，而无需调用特定的分子途径。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/8c45/7357833/6516e657a725/fx1.jpg

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细胞接触导向源于间隙回避。

Cellular Contact Guidance Emerges from Gap Avoidance.

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