细菌细胞骨架的分子。

Jan Löwe, Fusinita van den Ent, Linda A Amos
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引用次数: 139

摘要

细菌中肌动蛋白和微管蛋白的清晰而遥远的同源物的结构阐明以及这些蛋白的GFP标记有望重振原核细胞生物学领域。FtsZ(微管蛋白同源物)和MreB/ParM(肌动蛋白同源物)对于需要细胞精确定位分子的细胞任务是必不可少的,类似于真核细胞骨架的功能。FtsZ是细菌细胞分裂的组织分子,在细胞中间形成丝状环。许多分子,包括MinCDE, SulA, ZipA和FtsA,直接协助这一过程。最近,在Verrucomicrobia中发现了与微管蛋白更相似的基因,而不是与FtsZ相似的基因。MreB在细胞膜下形成螺旋状,并可能通过定位跨膜和质周细胞壁合成酶来确定细胞的形状。目前,还没有已知的与MreB及其相关蛋白相互作用的蛋白质在细胞内的特定时间和地点帮助这些蛋白质聚合或解聚。预计mreb相互作用蛋白的存在与真核生物中大量的肌动蛋白结合蛋白类似。ParM(一种质粒携带的肌动蛋白同源物)直接参与通过ParR/ parc辅助聚合将某些单拷贝质粒推向相反的极点,形成双螺旋细丝,很像肌动蛋白f -肌动蛋白形成的细丝。Mollicutes似乎已经发展出特殊的系统来决定细胞的形状和运动,如螺原体中的纤维蛋白。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Molecules of the bacterial cytoskeleton.

The structural elucidation of clear but distant homologs of actin and tubulin in bacteria and GFP labeling of these proteins promises to reinvigorate the field of prokaryotic cell biology. FtsZ (the tubulin homolog) and MreB/ParM (the actin homologs) are indispensable for cellular tasks that require the cell to accurately position molecules, similar to the function of the eukaryotic cytoskeleton. FtsZ is the organizing molecule of bacterial cell division and forms a filamentous ring around the middle of the cell. Many molecules, including MinCDE, SulA, ZipA, and FtsA, assist with this process directly. Recently, genes much more similar to tubulin than to FtsZ have been identified in Verrucomicrobia. MreB forms helices underneath the inner membrane and probably defines the shape of the cell by positioning transmembrane and periplasmic cell wall-synthesizing enzymes. Currently, no interacting proteins are known for MreB and its relatives that help these proteins polymerize or depolymerize at certain times and places inside the cell. It is anticipated that MreB-interacting proteins exist in analogy to the large number of actin binding proteins in eukaryotes. ParM (a plasmid-borne actin homolog) is directly involved in pushing certain single-copy plasmids to the opposite poles by ParR/parC-assisted polymerization into double-helical filaments, much like the filaments formed by actin, F-actin. Mollicutes seem to have developed special systems for cell shape determination and motility, such as the fibril protein in Spiroplasma.

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