肌动蛋白对肌动球蛋白界面的看法。

Actin's view of actomyosin interface.

作者信息

Miller C J, Cheung P, White P, Reisler E

机构信息

Department of Chemistry and Biochemistry, University of California, Los Angeles 90024, USA.

出版信息

Biophys J. 1995 Apr;68(4 Suppl):50S-54S.

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1281863/

Abstract

Actomyosin interactions were examined by using yeast actin mutants with alanines replacing charged amino acid pairs D24/D25, E99/E100, D80/D81, and E83/K84. In the in vitro motility experiments, actin filaments of D24A/D25A or E99A/E100A mutants moved in the presence of 0.7% methylcellulose at the velocities of wild-type actin. Without methylcellulose, these mutant filaments, but not the D80/D81 or E83/K84 filaments, dissociated from the assay surface upon addition of ATP. Measurements of myosin subfragment-1 (S1) binding to D24A/D25A- and E99A/E100A-polymerized actins in the presence of ATP revealed a three- and twofold decrease in their binding constant, respectively, compared with wild-type actin. In contrast to this, all monomeric actins had the same binding affinity for S1. The rates and extents of polymerization of D24A/D25A and E99A/E100A actins by S1 were reduced in comparison to wild-type actin. The local structure of subdomain-2 on actin, as probed by subtilisin cleavage, was not altered for either mutant. A twofold decrease in nucleotide exchange was detected for the D24A/D25A mutant actin. These results demonstrate the involvement of the D24/D25 and E99/E100 residues in the weak binding of myosin to actin and reveal that residues D80/D81 and E83/K84 do not modulate actomyosin interactions.

摘要

通过使用丙氨酸取代带电荷氨基酸对D24/D25、E99/E100、D80/D81和E83/K84的酵母肌动蛋白突变体来研究肌动球蛋白相互作用。在体外运动实验中，D24A/D25A或E99A/E100A突变体的肌动蛋白丝在0.7%甲基纤维素存在下以野生型肌动蛋白的速度移动。没有甲基纤维素时，这些突变丝，而不是D80/D81或E83/K84丝，在添加ATP后从检测表面解离。在ATP存在下，测量肌球蛋白亚片段-1（S1）与D24A/D25A和E99A/E100A聚合肌动蛋白的结合，发现与野生型肌动蛋白相比，它们的结合常数分别降低了三倍和两倍。与此相反，所有单体肌动蛋白对S1具有相同的结合亲和力。与野生型肌动蛋白相比，S1对D24A/D25A和E99A/E100A肌动蛋白的聚合速率和程度降低。用枯草杆菌蛋白酶切割探测时，肌动蛋白上亚结构域-2的局部结构对任何一种突变体都没有改变。检测到D24A/D25A突变体肌动蛋白的核苷酸交换减少了两倍。这些结果证明了D24/D25和E99/E100残基参与肌球蛋白与肌动蛋白的弱结合，并揭示D80/D81和E83/K84残基不调节肌动球蛋白相互作用。

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Actin molecular structure and function.肌动蛋白的分子结构与功能。

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Enhanced stimulation of myosin subfragment 1 ATPase activity by addition of negatively charged residues to the yeast actin NH2 terminus.通过向酵母肌动蛋白氨基末端添加带负电荷的残基来增强肌球蛋白亚片段1的ATP酶活性刺激。

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