单分子成像技术研究 FtsK 易位揭示了 DNA 上蛋白-蛋白碰撞的机制特征。

Single-molecule imaging of FtsK translocation reveals mechanistic features of protein-protein collisions on DNA.

机构信息

Department of Biochemistry and Molecular Biophysics, Columbia University, New York, NY 10032, USA.

Institute for Cellular and Molecular Biology, University of Texas at Austin, Austin, TX 78712, USA.

出版信息

Mol Cell. 2014 Jun 5;54(5):832-43. doi: 10.1016/j.molcel.2014.03.033. Epub 2014 Apr 24.

DOI:10.1016/j.molcel.2014.03.033

PMID:24768536

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4048639/

Abstract

In physiological settings, DNA translocases will encounter DNA-bound proteins, which must be dislodged or bypassed to allow continued translocation. FtsK is a bacterial translocase that promotes chromosome dimer resolution and decatenation by activating XerCD-dif recombination. To better understand how translocases act in crowded environments, we used single-molecule imaging to visualize FtsK in real time as it collided with other proteins. We show that FtsK can push, evict, and even bypass DNA-bound proteins. The primary factor dictating the outcome of collisions was the relative affinity of the proteins for their specific binding sites. Importantly, protein-protein interactions between FtsK and XerD help prevent removal of XerCD from DNA by promoting rapid reversal of FtsK. Finally, we demonstrate that RecBCD always overwhelms FtsK when these two motor proteins collide while traveling along the same DNA molecule, indicating that RecBCD is capable of exerting a much greater force than FtsK when translocating along DNA.

摘要

在生理环境中，DNA 转位酶会遇到与 DNA 结合的蛋白质，为了允许继续转位，这些蛋白质必须被移开或绕过。FtsK 是一种细菌转位酶，通过激活 XerCD-dif 重组来促进染色体二聚体的解析和去连环化。为了更好地理解转位酶在拥挤环境中的作用，我们使用单分子成像技术实时可视化 FtsK，观察它与其他蛋白质的碰撞。我们表明 FtsK 可以推动、驱逐甚至绕过与 DNA 结合的蛋白质。决定碰撞结果的主要因素是蛋白质与其特定结合位点的相对亲和力。重要的是，FtsK 和 XerD 之间的蛋白-蛋白相互作用有助于防止 XerCD 从 DNA 上被移除，这是通过促进 FtsK 的快速逆转来实现的。最后，我们证明了当这两种运动蛋白沿着同一 DNA 分子运动时，RecBCD 总是会压倒 FtsK，这表明 RecBCD 在沿着 DNA 转运时能够施加比 FtsK 大得多的力。

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