Understanding actin organization in cell structure through lattice based Monte Carlo simulations.

Kathleen Puskar, Leonard Apeltsin, Shlomo Ta'asan, Russell Schwartz, Philip R LeDuc
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Abstract

Understanding the connection between mechanics and cell structure requires the exploration of the key molecular constituents responsible for cell shape and motility. One of these molecular bridges is the cytoskeleton, which is involved with intracellular organization and mechanotransduction. In order to examine the structure in cells, we have developed a computational technique that is able to probe the self-assembly of actin filaments through a lattice based Monte Carlo method. We have modeled the polymerization of these filaments based upon the interactions of globular actin through a probabilistic model encompassing both inert and active proteins. The results show similar response to classic ordinary differential equations at low molecular concentrations, but a bi-phasic divergence at realistic concentrations for living mammalian cells. Further, by introducing localized mobility parameters, we are able to simulate molecular gradients that are observed in nonhomogeneous protein distributions in vivo. The method and results have potential applications in cell and molecular biology as well as self-assembly for organic and inorganic systems.

通过基于晶格的蒙特卡罗模拟了解细胞结构中的肌动蛋白组织。
理解力学和细胞结构之间的联系需要探索负责细胞形状和运动的关键分子成分。其中一个分子桥是细胞骨架,它参与细胞内组织和机械转导。为了检查细胞中的结构,我们开发了一种计算技术,能够通过基于晶格的蒙特卡罗方法探测肌动蛋白丝的自组装。我们通过一个包含惰性和活性蛋白质的概率模型,基于球状肌动蛋白的相互作用,模拟了这些细丝的聚合。结果显示在低分子浓度下与经典常微分方程的响应相似,但在哺乳动物细胞的实际浓度下存在双相发散。此外,通过引入局部迁移参数,我们能够模拟在体内非均匀蛋白质分布中观察到的分子梯度。该方法和结果在细胞和分子生物学以及有机和无机系统的自组装方面具有潜在的应用前景。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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