INSIGHTS INTO THE MECHANICS OF CYTOKINETIC RING ASSEMBLY USING 3D MODELING.

Tamara Carla Bidone, Haosu Tang, Dimitrios Vavylonis
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Abstract

During fission yeast cytokinesis, actin filaments nucleated by cortical formin Cdc12 are captured by myosin motors bound to a band of cortical nodes. The myosin motors exert forces that pull nodes together into a contractile ring. Cross-linking interactions help align actin filaments and nodes into a single bundle. Mutations in the myosin motor domain and changes in the concentration of cross-linkers alpha-actinin and fimbrin alter the morphology of the condensing network, leading to clumps, rings or extended meshworks. How the contractile tension developing during ring formation depends on the interplay between network morphology, myosin motor activity, cross-linking and actin filament turnover remains to be elucidated. We addressed this question using a 3D computational model in which semiflexible actin filaments (represented as beads connected by springs) grow from formins, can be captured by myosin in neighboring nodes, and get cross-linked with one another through an attractive interaction. We identify regimes of tension generation between connected nodes under a wide set of conditions regarding myosin dynamics and strength of cross-linking between actin filaments. We find conditions that maximize circumferential tension, correlate them with network morphology and propose experiments to test these predictions. This work addresses "Morphogenesis of soft and living matter" using computational modeling to simulate cytokinetic ring assembly from the key molecular mechanisms of viscoelastic cross-linked actin networks that include active molecular motors.

Abstract Image

Abstract Image

洞察使用3d建模的细胞动力学环组装的力学。
在分裂酵母细胞分裂过程中,由皮质双甲蛋白Cdc12成核的肌动蛋白丝被绑定在皮质节点带上的肌凝蛋白马达捕获。肌凝蛋白马达施加力量,将节点拉到一起形成一个收缩环。交联相互作用有助于将肌动蛋白丝和节点排列成一个束。肌凝蛋白运动结构域的突变和交联剂α -肌动蛋白和纤维蛋白浓度的变化会改变凝聚网络的形态,导致团块、环状或延伸的网状结构。在环形成过程中,收缩张力的发展如何取决于网络形态、肌球蛋白运动活性、交联和肌动蛋白丝周转之间的相互作用仍有待阐明。我们使用一个3D计算模型来解决这个问题,在这个模型中,半柔性肌动蛋白细丝(用弹簧连接的珠子表示)从形成蛋白中生长出来,可以被邻近节点的肌凝蛋白捕获,并通过有吸引力的相互作用相互交联。我们确定了在肌凝蛋白动力学和肌动蛋白丝之间交联强度的广泛条件下连接节点之间张力产生的机制。我们找到了最大化周向张力的条件,将它们与网络形态联系起来,并提出了实验来测试这些预测。这项工作解决了“软物质和活物质的形态发生”,使用计算模型来模拟包括活性分子马达在内的粘弹性交联肌动蛋白网络的关键分子机制的细胞动力学环组装。
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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