Foteinopoulos Panayiotis, Mulder Bela M
Department of Systems Biophysics, FOM Institute AMOLF, Science Park 104, 1098 XG, Amsterdam, The Netherlands.
Bull Math Biol. 2014 Nov;76(11):2907-22. doi: 10.1007/s11538-014-0039-3. Epub 2014 Oct 28.
The highly orientationally ordered cortical microtubule array in plant cells is a key component for cell growth and development. Recent experimental and computational work has shown that the anisotropic nucleation of new microtubules from pre-existing microtubules has a major effect on the alignment process. We formulate a theoretical model to investigate the role of the microtubule-bound nucleation on the self-organization of the dynamical cortical microtubules. A bifurcation analysis of the stability of the disordered phase of the model reveals that the effective degree of co-aligned nucleation is the main determinant of the location of the transition. Increased co-aligned nucleation creates a positive feedback effect on the ordering process that can significantly widen the ordered region. We validate these predictions by comparing to the results of particle-based simulations.
植物细胞中高度定向有序的皮层微管阵列是细胞生长和发育的关键组成部分。最近的实验和计算工作表明,新微管从预先存在的微管上的各向异性成核作用对微管排列过程有重大影响。我们建立了一个理论模型来研究微管结合成核在动态皮层微管自组织中的作用。对该模型无序相稳定性的分岔分析表明,共排列成核的有效程度是转变位置的主要决定因素。增加共排列成核会对排列过程产生正反馈效应,从而可显著拓宽有序区域。我们通过与基于粒子的模拟结果进行比较来验证这些预测。
