细菌应答调节蛋白:来自共同结构域的多样调控策略
Bacterial response regulators: versatile regulatory strategies from common domains.
作者信息
Gao Rong, Mack Timothy R, Stock Ann M
机构信息
Center for Advanced Biotechnology and Medicine, Howard Hughes Medical Institute, Piscataway, NJ 08854, USA.
出版信息
Trends Biochem Sci. 2007 May;32(5):225-34. doi: 10.1016/j.tibs.2007.03.002. Epub 2007 Apr 12.
Abstract
Response regulators (RRs) comprise a major family of signaling proteins in prokaryotes. A modular architecture that consists of a conserved receiver domain and a variable effector domain enables RRs to function as phosphorylation-regulated switches that couple a wide variety of cellular behaviors to environmental cues. Recently, advances have been made in understanding RR functions both at genome-wide and molecular levels. Global techniques have been developed to analyze RR input and output, expanding the scope of characterization of these versatile components. Meanwhile, structural studies have revealed that, despite common structures and mechanisms of function within individual domains, a range of interactions between receiver and effector domains confer great diversity in regulatory strategies, optimizing individual RRs for the specific regulatory needs of different signaling systems.
摘要
应答调节蛋白(RRs)是原核生物中一类主要的信号蛋白家族。由保守的接收结构域和可变的效应结构域组成的模块化结构,使RRs能够作为磷酸化调节开关发挥作用,将多种细胞行为与环境信号联系起来。最近,在全基因组和分子水平上理解RR功能方面取得了进展。已经开发出全局技术来分析RR的输入和输出,扩大了对这些多功能组件的表征范围。同时,结构研究表明,尽管各个结构域内有共同的结构和功能机制,但接收结构域和效应结构域之间的一系列相互作用赋予了调节策略极大的多样性,使单个RRs能够针对不同信号系统的特定调节需求进行优化。
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3
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