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发现细菌的环状蛋白:细菌素、蓝细菌素和菌毛蛋白。

Discovering the bacterial circular proteins: bacteriocins, cyanobactins, and pilins.

机构信息

Department of Molecular Genetics, University of Groningen, 9747 AG Groningen, The Netherlands.

出版信息

J Biol Chem. 2012 Aug 3;287(32):27007-13. doi: 10.1074/jbc.R112.354688. Epub 2012 Jun 14.

DOI:10.1074/jbc.R112.354688
PMID:22700986
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3411037/
Abstract

Over recent years, several examples of natural ribosomally synthesized circular proteins and peptides from diverse organisms have been described. They are a group of proteins for which the precursors must be post-translationally modified to join the N and C termini with a peptide bond. This feature appears to confer a range of potential advantages because these proteins show increased resistance to proteases and higher thermodynamic stability, both of which improve their biological activity. They are produced by prokaryotic and eukaryotic organisms and show diverse biological activities, related mostly to a self-defense or competition mechanism of the producer organisms, with the only exception being the circular pilins. This minireview highlights ribosomally synthesized circular proteins produced by members of the domain Bacteria: circular bacteriocins, cyanobactins, and circular pilins. We pay special attention to the genetic organization of the biosynthetic machinery of these molecules, the role of circularization, and the differences in the possible circularization mechanisms.

摘要

近年来,已经描述了来自不同生物体的几种天然核糖体合成的环状蛋白质和肽的例子。它们是一组蛋白质,其前体必须经过翻译后修饰,才能通过肽键连接 N 和 C 末端。这一特征似乎赋予了它们一系列潜在的优势,因为这些蛋白质对蛋白酶的抗性增强,热力学稳定性提高,这两者都提高了它们的生物活性。它们由原核生物和真核生物产生,并表现出多种生物活性,主要与产生这些蛋白质的生物体的自我防御或竞争机制有关,唯一的例外是环状菌毛。这篇小型综述强调了域细菌成员产生的核糖体合成的环状蛋白质:环状细菌素、蓝细菌素和环状菌毛。我们特别关注这些分子生物合成机制的遗传组织、环状化的作用以及可能的环状化机制的差异。

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