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评估机械敏感离子通道对膜应变和张力的敏感性。

Estimating the sensitivity of mechanosensitive ion channels to membrane strain and tension.

作者信息

Charras Guillaume T, Williams Beatrice A, Sims Stephen M, Horton Mike A

机构信息

Bone and Mineral Centre, Department of Medicine, University College London, London, United Kingdom.

出版信息

Biophys J. 2004 Oct;87(4):2870-84. doi: 10.1529/biophysj.104.040436.

DOI:10.1529/biophysj.104.040436
PMID:15454477
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1304704/
Abstract

Bone adapts to its environment by a process in which osteoblasts and osteocytes sense applied mechanical strain. One possible pathway for the detection of strain involves mechanosensitive channels and we sought to determine their sensitivity to membrane strain and tension. We used a combination of experimental and computational modeling techniques to gain new insights into cell mechanics and the regulation of mechanosensitive channels. Using patch-clamp electrophysiology combined with video microscopy, we recorded simultaneously the evolution of membrane extensions into the micropipette, applied pressure, and membrane currents. Nonselective mechanosensitive cation channels with a conductance of 15 pS were observed. Bleb aspiration into the micropipette was simulated using finite element models incorporating the cytoplasm, the actin cortex, the plasma membrane, cellular stiffening in response to strain, and adhesion between the membrane and the micropipette. Using this model, we examine the relative importance of the different cellular components in resisting suction into the pipette and estimate the membrane strains and tensions needed to open mechanosensitive channels. Radial membrane strains of 800% and tensions of 5 10(-4) N.m(-1) were needed to open 50% of mechanosensitive channels. We discuss the relevance of these results in the understanding of cellular reactions to mechanical strain and bone physiology.

摘要

骨骼通过成骨细胞和骨细胞感知施加的机械应变的过程来适应其环境。检测应变的一种可能途径涉及机械敏感通道,我们试图确定它们对膜应变和张力的敏感性。我们使用实验和计算建模技术相结合的方法,以获得对细胞力学和机械敏感通道调节的新见解。通过将膜片钳电生理学与视频显微镜相结合,我们同时记录了膜向微吸管内延伸、施加压力和膜电流的变化。观察到了电导为15 pS的非选择性机械敏感阳离子通道。使用包含细胞质、肌动蛋白皮质、质膜、应变引起的细胞硬化以及膜与微吸管之间粘附的有限元模型模拟了向微吸管内的气泡抽吸。使用该模型,我们研究了不同细胞成分在抵抗吸管内抽吸中的相对重要性,并估计了打开机械敏感通道所需的膜应变和张力。打开50%的机械敏感通道需要800%的径向膜应变和5×10^(-4) N·m^(-1)的张力。我们讨论了这些结果在理解细胞对机械应变的反应和骨骼生理学方面的相关性。

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