通过分子动力学模拟研究深海鱼类α-肌动蛋白耐压机制。

Mechanism of deep-sea fish α-actin pressure tolerance investigated by molecular dynamics simulations.

作者信息

Wakai Nobuhiko, Takemura Kazuhiro, Morita Takami, Kitao Akio

机构信息

Department of Computational Biology, Graduate School of Frontier Sciences, The University of Tokyo, Tokyo, Japan.

Institute of Molecular and Cellular Biosciences, The University of Tokyo, Tokyo, Japan.

出版信息

PLoS One. 2014 Jan 20;9(1):e85852. doi: 10.1371/journal.pone.0085852. eCollection 2014.

DOI:10.1371/journal.pone.0085852

PMID:24465747

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3896411/

Abstract

The pressure tolerance of monomeric α-actin proteins from the deep-sea fish Coryphaenoides armatus and C. yaquinae was compared to that of non-deep-sea fish C. acrolepis, carp, and rabbit/human/chicken actins using molecular dynamics simulations at 0.1 and 60 MPa. The amino acid sequences of actins are highly conserved across a variety of species. The actins from C. armatus and C. yaquinae have the specific substitutions Q137K/V54A and Q137K/L67P, respectively, relative to C. acrolepis, and are pressure tolerant to depths of at least 6000 m. At high pressure, we observed significant changes in the salt bridge patterns in deep-sea fish actins, and these changes are expected to stabilize ATP binding and subdomain arrangement. Salt bridges between ATP and K137, formed in deep-sea fish actins, are expected to stabilize ATP binding even at high pressure. At high pressure, deep-sea fish actins also formed a greater total number of salt bridges than non-deep-sea fish actins owing to the formation of inter-helix/strand and inter-subdomain salt bridges. Free energy analysis suggests that deep-sea fish actins are stabilized to a greater degree by the conformational energy decrease associated with pressure effect.

摘要

利用分子动力学模拟，在0.1MPa和60MPa条件下，将深海鱼类长吻突吻鳕（Coryphaenoides armatus）和亚氏突吻鳕（C. yaquinae）的单体α-肌动蛋白的耐压性与非深海鱼类黑线鳕（C. acrolepis）、鲤鱼以及兔/人/鸡的肌动蛋白进行了比较。肌动蛋白的氨基酸序列在多种物种中高度保守。相对于黑线鳕，长吻突吻鳕和亚氏突吻鳕的肌动蛋白分别有特定的替换，即Q137K/V54A和Q137K/L67P，并且能够耐受至少6000米深度的压力。在高压下，我们观察到深海鱼类肌动蛋白的盐桥模式发生了显著变化，预计这些变化会稳定ATP结合和亚结构域排列。深海鱼类肌动蛋白中形成的ATP与K137之间的盐桥，即使在高压下也有望稳定ATP结合。在高压下，由于螺旋间/链间和亚结构域间盐桥的形成，深海鱼类肌动蛋白形成的盐桥总数也比非深海鱼类肌动蛋白更多。自由能分析表明，深海鱼类肌动蛋白因压力效应导致的构象能降低而在更大程度上得到稳定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/bc7d/3896411/2ad12cca49f6/pone.0085852.g001.jpg

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通过分子动力学模拟研究深海鱼类α-肌动蛋白耐压机制。

Mechanism of deep-sea fish α-actin pressure tolerance investigated by molecular dynamics simulations.

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