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FtsZ 凝聚物:体外电子显微镜研究。

FtsZ condensates: an in vitro electron microscopy study.

机构信息

ERATO Actin Filament Dynamics Project, Japan Science and Technology Corporation, c/o RIKEN Harima Institute at Spring 8, 1-1-1 Kouto, Sayo, Hyogo 679-5148, Japan.

出版信息

Biopolymers. 2009 May;91(5):340-50. doi: 10.1002/bip.21136.

DOI:10.1002/bip.21136
PMID:19137575
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2731876/
Abstract

In vivo cell division protein FtsZ from E. coli forms rings and spirals which have only been observed by low resolution light microscopy. We show that these suprastructures are likely formed by molecular crowding which is a predominant factor in prokaryotic cells and enhances the weak lateral bonds between proto-filaments. Although FtsZ assembles into single proto-filaments in dilute aqueous buffer, with crowding agents above a critical concentration, it forms polymorphic supramolecular structures including rings and toroids (with multiple protofilaments) about 200 nm in diameter, similar in appearance to DNA toroids, and helices with pitches of several hundred nm as well as long, linear bundles. Helices resemble those observed in vivo, whereas the rings and toroids may represent a novel energy minimized state of FtsZ, at a later stage of Z-ring constriction. We shed light on the molecular arrangement of FtsZ filaments within these suprastructures using high resolution electron microscopy.

摘要

在活细胞中,来自大肠杆菌的细胞分裂蛋白 FtsZ 会形成环和螺旋,这些结构只能通过低分辨率的光学显微镜观察到。我们表明,这些超结构很可能是由分子拥挤形成的,分子拥挤是原核细胞中的一个主要因素,它增强了原丝之间的弱侧链相互作用。尽管 FtsZ 在稀水溶液缓冲液中会组装成单一线性原丝,但在拥挤剂超过临界浓度时,它会形成多形性超分子结构,包括直径约为 200nm 的环和环体(具有多个原丝),外观类似于 DNA 环体,以及具有几百纳米螺距的螺旋,以及长的线性束。螺旋类似于在体内观察到的螺旋,而环和环体可能代表 FtsZ 在 Z 环收缩的后期的一种新的能量最小化状态。我们使用高分辨率电子显微镜研究了这些超结构中 FtsZ 丝的分子排列。

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