Myosin's powerstroke transitions define atomic scale movement of cardiac thin filament tropomyosin.

IF 3.3 2区 医学 Q1 PHYSIOLOGY
Journal of General Physiology Pub Date : 2024-05-06 Epub Date: 2024-04-12 DOI:10.1085/jgp.202413538
Michael J Rynkiewicz, Matthew C Childers, Olga E Karpicheva, Michael Regnier, Michael A Geeves, William Lehman
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引用次数: 0

Abstract

Dynamic interactions between the myosin motor head on thick filaments and the actin molecular track on thin filaments drive the myosin-crossbridge cycle that powers muscle contraction. The process is initiated by Ca2+ and the opening of troponin-tropomyosin-blocked myosin-binding sites on actin. The ensuing recruitment of myosin heads and their transformation from pre-powerstroke to post-powerstroke conformation on actin produce the force required for contraction. Cryo-EM-based atomic models confirm that during this process, tropomyosin occupies three different average positions on actin. Tropomyosin pivoting on actin away from a TnI-imposed myosin-blocking position accounts for part of the Ca2+ activation observed. However, the structure of tropomyosin on thin filaments that follows pre-powerstroke myosin binding and its translocation during myosin's pre-powerstroke to post-powerstroke transition remains unresolved. Here, we approach this transition computationally in silico. We used the myosin helix-loop-helix motif as an anchor to dock models of pre-powerstroke cardiac myosin to the cleft between neighboring actin subunits along cardiac thin filaments. We then performed targeted molecular dynamics simulations of the transition between pre- and post-powerstroke conformations on actin in the presence of cardiac troponin-tropomyosin. These simulations show Arg 369 and Glu 370 on the tip of myosin Loop-4 encountering identically charged residues on tropomyosin. The charge repulsion between residues causes tropomyosin translocation across actin, thus accounting for the final regulatory step in the activation of the thin filament, and, in turn, facilitating myosin movement along the filament. We suggest that during muscle activity, myosin-induced tropomyosin movement is likely to result in unencumbered myosin head interactions on actin at low-energy cost.

肌球蛋白的动力冲程转换确定了心脏细丝肌球蛋白的原子尺度运动。
粗丝上的肌球蛋白运动头与细丝上的肌动蛋白分子轨道之间的动态相互作用,推动了肌球蛋白-跨桥循环,从而为肌肉收缩提供动力。这一过程由 Ca2+ 和肌动蛋白上肌球蛋白-肌球蛋白阻断肌球蛋白结合位点的开放启动。随后肌球蛋白头的招募及其在肌动蛋白上从前冲力构象到后冲力构象的转变产生了收缩所需的力量。基于低温电子显微镜的原子模型证实,在这一过程中,肌球蛋白在肌动蛋白上占据三个不同的平均位置。肌球蛋白在肌动蛋白上远离 TnI 强加的肌球蛋白阻滞位置的枢转,是所观察到的 Ca2+ 激活的部分原因。然而,肌动蛋白在冲程前与肌球蛋白结合后在细丝上的结构,以及肌球蛋白在冲程前向冲程后转变过程中的转位,仍未得到解决。在此,我们通过计算对这一转变进行了硅学研究。我们利用肌球蛋白的螺旋-环-螺旋结构作为锚,将前冲程心肌肌球蛋白模型与心脏细丝上相邻肌动蛋白亚基之间的裂隙对接。然后,我们对心脏肌钙蛋白-肌球蛋白存在时肌动蛋白在冲力前和冲力后构象之间的转换进行了有针对性的分子动力学模拟。模拟结果显示,肌球蛋白 Loop-4 顶端的 Arg 369 和 Glu 370 遇到了肌动蛋白上带电的相同残基。残基之间的电荷排斥作用导致肌球蛋白在肌动蛋白上发生转移,从而完成了激活细丝的最后一个调节步骤,进而促进肌球蛋白沿细丝运动。我们认为,在肌肉活动过程中,肌球蛋白诱导的肌球蛋白运动很可能导致肌球蛋白头以低能量成本在肌动蛋白上进行无束缚的相互作用。
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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来源期刊
CiteScore
6.00
自引率
10.50%
发文量
88
审稿时长
6-12 weeks
期刊介绍: General physiology is the study of biological mechanisms through analytical investigations, which decipher the molecular and cellular mechanisms underlying biological function at all levels of organization. The mission of Journal of General Physiology (JGP) is to publish mechanistic and quantitative molecular and cellular physiology of the highest quality, to provide a best-in-class author experience, and to nurture future generations of independent researchers. The major emphasis is on physiological problems at the cellular and molecular level.
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