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平滑肌肌球蛋白组装:从带状和侧向极性到排极螺旋模型。

Myosin assembly of smooth muscle: from ribbons and side polarity to a row polar helical model.

机构信息

Austrian Academy of Sciences, Dr.-Ignaz-Seipel-Platz 2, 1010, Vienna, Austria.

Austrian Academy of Sciences, Vienna, Austria.

出版信息

J Muscle Res Cell Motil. 2022 Sep;43(3):113-133. doi: 10.1007/s10974-022-09622-4. Epub 2022 Jul 16.

DOI:10.1007/s10974-022-09622-4
PMID:35841444
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9420085/
Abstract

After decades of debate over the structure of smooth muscle myosin filaments, it is still unclear whether they are helical, as in all other muscle types, or square in shape. In both cases bipolar building units are proposed, but the deduced cross-bridge arrangements are fundamentally different. The opposite polarity of the adjusting longitudinal rows is proposed for the helical structure, while in the case of square filaments, or myosin ribbons, only their two faces are appositively polarized. Analysis of our unpublished archival data on light meromyosin (LMM) paracrystals and myosin rod assemblies as well as the filaments themselves indicated that the rods were assembled with a 6°-7° tilt angle from the rods' longitudinal axis, in contrast to the lack of tilt in LMM, both exhibiting a 14.3 nm myosin periodicity. Optical diffraction analysis of EM images of the rod assemblies and those of intact myosin confirmed their helical architecture characterized by 28 nm residue translations, 172 nm repeats and 516 nm pitch. A detailed helical model of these filaments was elucidated with bipolar tetramer building units made of two polar trimers. The filaments elongate at their two ends in a head-to-head manner, enabling targeted cross-bridge polarity of the adjacent rows, in the form of a unique Boerdijk-Coxeter type helix, similar to that of collagen or desmin fibers, with the covalent links replaced by a head-to-head clasp.

摘要

经过几十年关于平滑肌肌球蛋白丝结构的争论,它们究竟是螺旋状的,就像所有其他肌肉类型一样,还是方形的,仍然不清楚。在这两种情况下,都提出了双极构建单元,但推断出的横桥排列有根本的不同。对于螺旋结构,提出了调节纵列的相反极性,而对于方形丝或肌球蛋白带,只有它们的两个面被正性极化。对我们未发表的关于轻酶解肌球蛋白(LMM)副晶和肌球蛋白杆组装体以及纤维本身的档案数据的分析表明,杆以 6°-7°的倾斜角从杆的纵轴组装,而 LMM 则没有倾斜,两者都表现出 14.3nm 的肌球蛋白周期性。对杆组装体和完整肌球蛋白的 EM 图像的光学衍射分析证实了它们的螺旋结构,其特征是 28nm 的残基平移、172nm 的重复和 516nm 的螺距。用由两个极性三聚体组成的双极四聚体构建单元阐明了这些纤维的详细螺旋模型。纤维在其两端以头对头的方式伸长,能够以相邻行的独特博尔德吉克-考克斯特型螺旋的形式靶向横桥极性,类似于胶原或结蛋白纤维,用头对头的扣环代替共价键。

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