丝状体
离合器
肌球蛋白
牵引(地质)
刚度
滑脱
牵引力
动力学(音乐)
机械
分子马达
肌动蛋白
生物物理学
材料科学
物理
化学
纳米技术
生物
工程类
复合材料
机械工程
生物化学
声学
热力学
作者
Clarence E. Chan,David J. Odde
出处
期刊:Science
[American Association for the Advancement of Science]
日期:2008-12-12
卷期号:322 (5908): 1687-1691
被引量:970
标识
DOI:10.1126/science.1163595
摘要
Cells sense the environment's mechanical stiffness to control their own shape, migration, and fate. To better understand stiffness sensing, we constructed a stochastic model of the "motor-clutch" force transmission system, where molecular clutches link F-actin to the substrate and mechanically resist myosin-driven F-actin retrograde flow. The model predicts two distinct regimes: (i) "frictional slippage," with fast retrograde flow and low traction forces on stiff substrates and (ii) oscillatory "load-and-fail" dynamics, with slower retrograde flow and higher traction forces on soft substrates. We experimentally confirmed these model predictions in embryonic chick forebrain neurons by measuring the nanoscale dynamics of single-growth-cone filopodia. Furthermore, we experimentally observed a model-predicted switch in F-actin dynamics around an elastic modulus of 1 kilopascal. Thus, a motor-clutch system inherently senses and responds to the mechanical stiffness of the local environment.
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