模拟细胞运动,再现力-速度关系。
Simulation of cell motility that reproduces the force-velocity relationship.
机构信息
Cavendish Laboratory, University of Cambridge, 19 J J Thomson Avenue, Cambridge CB3 0HE, England.
出版信息
Proc Natl Acad Sci U S A. 2010 May 18;107(20):9141-6. doi: 10.1073/pnas.1002538107. Epub 2010 May 3.
Abstract
Many cells crawl by extending an actin-rich pseudopod. We have devised a simulation that describes how the polymerization kinetics of a branched actin filament network, coupled with excluded volume effects, powers the motility of crawling cells such as amoebae and fish keratocytes. Our stochastic simulation is based on the key fundamental properties of actin polymerization, namely growth, shrinkage, capping, branching, and nucleation, and also includes contributions from the creation and breaking of adhesive contacts with the substrate together with excluded volume effects related to filament packing. When reasonable values for appropriate constants were employed, this simulation generated a force-velocity relationship that resembled closely that observed experimentally. Our simulations indicated that excluded volume effects associated with actin filament branching lead to a decreased packing efficiency and resultant swelling of the cytoskeleton gel that contributes substantially to lamellipod protrusion.
摘要
许多细胞通过伸出富含肌动蛋白的伪足来爬行。我们设计了一个模拟,描述了分支肌动蛋白丝网络的聚合动力学如何与排除体积效应相结合,为变形虫和鱼类角膜细胞等爬行细胞提供动力。我们的随机模拟基于肌动蛋白聚合的关键基本特性,即生长、收缩、加帽、分支和核化,还包括与基质的粘附接触的形成和破坏以及与丝蛋白包装有关的排除体积效应的贡献。当使用合理的适当常数值时,这种模拟产生的力-速度关系与实验观察到的非常相似。我们的模拟表明,与肌动蛋白丝分支相关的排除体积效应会导致细胞骨架凝胶的包装效率降低和肿胀,这对片状伪足的突出有很大贡献。
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