大规模细胞内流动的几何效应

Olenka Jain, Brato Chakrabarti, Reza Farhadifar, Elizabeth R. Gavis, Michael J. Shelley, Stanislav Y. Shvartsman
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摘要

这项研究探索了细胞几何在果蝇卵母细胞晚期自组织流体定向中的作用。最近的理论工作表明,一个仅依赖于柔性、皮质锚定微管(MTs)的流体动力学相互作用以及在其上运动的分子马达的机械负荷的模型,足以产生观察到的流体。虽然已经在球形细胞中对流动的产生进行了研究,但卵母细胞在流动过程中会改变形状,因此尚不清楚这些流动对细胞几何形状的影响有多大。在这里,我们使用生物物理理论和计算分析来研究几何形状的作用,并发现旋转轴是由域的形状设定的,而且流动对域形状的生物相关扰动具有鲁棒性。利用实时成像和三维流动重建,我们检验了理论/模拟的预测结果,发现模型与实时实验之间存在一致性,进一步证明了果蝇晚期卵母细胞的流动方向与几何形状有关。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Geometric Effects in Large Scale Intracellular Flows
This work probes the role of cell geometry in orienting self-organized fluid flows in the late stage Drosophila oocyte. Recent theoretical work has shown that a model, which relies only on hydrodynamic interactions of flexible, cortically anchored microtubules (MTs) and the mechanical loads from molecular motors moving upon them, is sufficient to generate observed flows. While the emergence of flows has been studied in spheres, oocytes change shape during streaming and it was unclear how robust these flows are to the geometry of the cell. Here we use biophysical theory and computational analysis to investigate the role of geometry and find that the axis of rotation is set by the shape of the domain and that the flow is robust to biologically relevant perturbations of the domain shape. Using live imaging and 3D flow reconstruction, we test the predictions of the theory/simulation, finding consistency between the model and live experiments, further demonstrating a geometric dependence on flow direction in late-stage Drosophila oocytes.
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