细胞运动中的形态与功能:从成纤维细胞到角膜细胞。
Form and function in cell motility: from fibroblasts to keratocytes.
机构信息
Biomedical Engineering Department, Boston University, Boston, Massachusetts, USA.
出版信息
Biophys J. 2010 Apr 21;98(8):1408-17. doi: 10.1016/j.bpj.2009.12.4303.
Abstract
It is plain enough that a horse is made for running, but similar statements about motile cells are not so obvious. Here the basis for structure-function relations in cell motility is explored by application of a new computational technique that allows realistic three-dimensional simulations of cells migrating on flat substrata. With this approach, some cyber cells spontaneously display the classic irregular protrusion cycles and handmirror morphology of a crawling fibroblast, and others the steady gliding motility and crescent morphology of a fish keratocyte. The keratocyte motif is caused by optimal recycling of the cytoskeleton from the back to the front so that more of the periphery can be devoted to protrusion. These calculations are a step toward bridging the gap between the integrated mechanics and biophysics of whole cells and the microscopic molecular biology of cytoskeletal components.
摘要
很明显,马是为奔跑而生的,但关于运动细胞的类似陈述并不那么明显。在这里,通过应用一种新的计算技术来探索细胞运动中的结构-功能关系,该技术允许对在平基底上迁移的细胞进行逼真的三维模拟。通过这种方法,一些计算细胞自发地表现出了爬行成纤维细胞的经典不规则突起循环和手镜形态,而另一些则表现出了鱼角膜细胞的稳定滑行运动和新月形形态。角膜细胞的这种形态是由于细胞骨架从后端到前端的最佳回收,从而可以将更多的周边部分用于突起。这些计算是朝着弥合整个细胞的综合力学和生物物理学与细胞骨架成分的微观分子生物学之间的差距迈出的一步。
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2
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Multiscale Model Simul. 2005;3(2):413-439. doi: 10.1137/04060370X.
3
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4
Filamentous network mechanics and active contractility determine cell and tissue shape.丝状网络力学和主动收缩性决定细胞和组织的形状。
Biophys J. 2008 Oct;95(7):3488-96. doi: 10.1529/biophysj.108.134296. Epub 2008 Jul 3.
5
Mechanism of shape determination in motile cells.运动细胞中形状确定的机制。
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