大肠杆菌的形态发生
Morphogenesis of Escherichia coli.
作者信息
Nanninga N
机构信息
Institute for Molecular Cell Biology, BioCentrum Amsterdam, University of Amsterdam, The Netherlands.
出版信息
Microbiol Mol Biol Rev. 1998 Mar;62(1):110-29. doi: 10.1128/MMBR.62.1.110-129.1998.
Abstract
The shape of Escherichia coli is strikingly simple compared to those of higher eukaryotes. In fact, the end result of E. coli morphogenesis is a cylindrical tube with hemispherical caps. It is argued that physical principles affect biological forms. In this view, genes code for products that contribute to the production of suitable structures for physical factors to act upon. After introduction of a physical model, the discussion is focused on the shape-maintaining (peptidoglycan) layer of E. coli. This is followed by a detailed analysis of the structural relationship of the cellular interior to the cytoplasmic membrane. A basic theme of this review is that the transcriptionally active nucleoid and the cytoplasmic translation machinery form a structural continuity with the growing cellular envelope. An attempt has been made to show how this dynamic relationship during the cell cycle affects cell polarity and how it leads to cell division.
摘要
与高等真核生物相比,大肠杆菌的形状极其简单。事实上,大肠杆菌形态发生的最终结果是一个带有半球形帽的圆柱形管。有人认为物理原理会影响生物形态。按照这种观点,基因编码的产物有助于形成适合物理因素作用的结构。在引入一个物理模型后,讨论聚焦于大肠杆菌的形状维持(肽聚糖)层。接下来是对细胞内部与细胞质膜结构关系的详细分析。本综述的一个基本主题是,转录活跃的类核和细胞质翻译机制与不断生长的细胞包膜形成结构上的连续性。已尝试展示细胞周期中的这种动态关系如何影响细胞极性以及如何导致细胞分裂。
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