肌球蛋白VI在连续运动过程中如何协调其头部。

How myosin VI coordinates its heads during processive movement.

作者信息

Sweeney H Lee, Park Hyokeun, Zong Alan B, Yang Zhaohui, Selvin Paul R, Rosenfeld Steven S

机构信息

Department of Physiology, University of Pennsylvania School of Medicine, Philadelphia, PA, USA.

出版信息

EMBO J. 2007 Jun 6;26(11):2682-92. doi: 10.1038/sj.emboj.7601720. Epub 2007 May 17.

DOI:10.1038/sj.emboj.7601720

PMID:17510632

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1888679/

Abstract

A processive molecular motor must coordinate the enzymatic state of its two catalytic domains in order to prevent premature detachment from its track. For myosin V, internal strain produced when both heads of are attached to an actin track prevents completion of the lever arm swing of the lead head and blocks ADP release. However, this mechanism cannot work for myosin VI, since its lever arm positions are reversed. Here, we demonstrate that myosin VI gating is achieved instead by blocking ATP binding to the lead head once it has released its ADP. The structural basis for this unique gating mechanism involves an insert near the nucleotide binding pocket that is found only in class VI myosin. Reverse strain greatly favors binding of ADP to the lead head, which makes it possible for myosin VI to function as a processive transporter as well as an actin-based anchor. While this mechanism is unlike that of any other myosin superfamily member, it bears remarkable similarities to that of another processive motor from a different superfamily--kinesin I.

摘要

一个进行性分子马达必须协调其两个催化结构域的酶促状态，以防止过早地从其轨道上脱离。对于肌球蛋白V，当两个头部都附着在肌动蛋白轨道上时产生的内部应变会阻止领头头部的杠杆臂摆动完成并阻碍ADP释放。然而，这种机制不适用于肌球蛋白VI，因为其杠杆臂位置是相反的。在这里，我们证明肌球蛋白VI的门控是通过在领头头部释放ADP后阻止ATP与其结合来实现的。这种独特门控机制的结构基础涉及仅在VI类肌球蛋白中发现的核苷酸结合口袋附近的一个插入片段。反向应变极大地有利于ADP与领头头部的结合，这使得肌球蛋白VI能够作为一个进行性转运体以及基于肌动蛋白的锚发挥作用。虽然这种机制与任何其他肌球蛋白超家族成员都不同，但它与来自不同超家族的另一个进行性马达——驱动蛋白I具有显著相似性。

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A force-dependent state controls the coordination of processive myosin V.一种力依赖状态控制着持续性肌球蛋白V的协调性。

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Load-dependent kinetics of myosin-V can explain its high processivity.肌球蛋白-V的负载依赖性动力学可以解释其高持续性。

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