A moving ParA gradient on the nucleoid directs subcellular cargo transport via a chemophoresis force.

Bioarchitecture Pub Date : 2014-01-01 DOI:10.4161/19490992.2014.987581

Anthony G Vecchiarelli, Yeonee Seol, Keir C Neuman, Kiyoshi Mizuuchi

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引用次数: 22

Abstract

DNA segregation is a critical process for all life, and although there is a relatively good understanding of eukaryotic mitosis, the mechanism in bacteria remains unclear. The small size of a bacterial cell and the number of factors involved in its subcellular organization make it difficult to study individual systems under controlled conditions in vivo. We developed a cell-free technique to reconstitute and visualize bacterial ParA-mediated segregation systems. Our studies provide direct evidence for a mode of transport that does not use a classical cytoskeletal filament or motor protein. Instead, we demonstrate that ParA-type DNA segregation systems can establish a propagating ParA ATPase gradient on the nucleoid surface, which generates the force required for the directed movement of spatially confined cargoes, such as plasmids or large organelles, and distributes multiple cargos equidistant to each other inside cells. Here we present the critical principles of our diffusion-ratchet model of ParA-mediated transport and expand on the mathematically derived chemophoresis force using experimentally-determined biochemical and cellular parameters.

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类核上移动的准梯度通过化学电泳力指导亚细胞货物运输。

DNA分离是所有生命的一个关键过程，尽管对真核生物有丝分裂有了相对较好的了解，但在细菌中的机制仍不清楚。细菌细胞的小尺寸和其亚细胞组织中涉及的因素的数量使得在体内受控条件下研究单个系统变得困难。我们开发了一种无细胞技术来重建和可视化细菌para介导的分离系统。我们的研究为一种不使用经典细胞骨架丝或运动蛋白的运输方式提供了直接证据。相反，我们证明了对a型DNA分离系统可以在类核表面建立一个繁殖的对ATPase梯度，这产生了空间受限货物(如质粒或大型细胞器)定向运动所需的力，并在细胞内等距分布多个货物。在这里，我们提出了我们的扩散棘轮模型的关键原理，并利用实验确定的生化和细胞参数对数学推导的化学电泳力进行了扩展。

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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Bioarchitecture

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