生物聚合物壳与细胞核的力学及屈曲
Mechanics and Buckling of Biopolymeric Shells and Cell Nuclei.
作者信息
Banigan Edward J, Stephens Andrew D, Marko John F
机构信息
Department of Physics and Astronomy, Northwestern University, Evanston, Illinois.
Department of Molecular Biosciences, Northwestern University, Evanston, Illinois.
出版信息
Biophys J. 2017 Oct 17;113(8):1654-1663. doi: 10.1016/j.bpj.2017.08.034.
Abstract
We study a Brownian dynamics simulation model of a biopolymeric shell deformed by axial forces exerted at opposing poles. The model exhibits two distinct, linear force-extension regimes, with the response to small tensions governed by linear elasticity and the response to large tensions governed by an effective spring constant that scales with radius as R. When extended beyond the initial linear elastic regime, the shell undergoes a hysteretic, temperature-dependent buckling transition. We experimentally observe this buckling transition by stretching and imaging the lamina of isolated cell nuclei. Furthermore, the interior contents of the shell can alter mechanical response and buckling, which we show by simulating a model for the nucleus that quantitatively agrees with our micromanipulation experiments stretching individual nuclei.
摘要
我们研究了一个生物聚合物壳的布朗动力学模拟模型,该壳受到施加在相对两极的轴向力而发生变形。该模型呈现出两种不同的线性力-伸长状态,对小张力的响应由线性弹性控制,对大张力的响应由一个有效弹簧常数控制,该常数随半径按R缩放。当延伸超过初始线性弹性状态时,壳会经历一个滞后的、与温度相关的屈曲转变。我们通过拉伸和成像分离细胞核的薄片,从实验上观察到了这种屈曲转变。此外,壳的内部物质可以改变力学响应和屈曲,我们通过模拟一个细胞核模型来证明这一点,该模型在定量上与我们拉伸单个细胞核的微操纵实验相符。
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