双组分信号传导在细菌运动性和生物膜形成中的作用
Involvement of Two-Component Signaling on Bacterial Motility and Biofilm Development.
作者信息
Prüß Birgit M
机构信息
Department of Microbiological Sciences, North Dakota State University, Fargo, North Dakota, USA
出版信息
J Bacteriol. 2017 Aug 22;199(18). doi: 10.1128/JB.00259-17. Print 2017 Sep 15.
Abstract
Two-component signaling is a specialized mechanism that bacteria use to respond to changes in their environment. Nonpathogenic strains of K-12 harbor 30 histidine kinases and 32 response regulators, which form a network of regulation that integrates many other global regulators that do not follow the two-component signaling mechanism, as well as signals from central metabolism. The output of this network is a multitude of phenotypic changes in response to changes in the environment. Among these phenotypic changes, many two-component systems control motility and/or the formation of biofilm, sessile communities of bacteria that form on surfaces. Motility is the first reversible attachment phase of biofilm development, followed by a so-called swim or stick switch toward surface organelles that aid in the subsequent phases. In the mature biofilm, motility heterogeneity is generated by a combination of evolutionary and gene regulatory events.
摘要
双组分信号传导是细菌用于响应其环境变化的一种特殊机制。K-12的非致病菌株含有30种组氨酸激酶和32种反应调节因子,它们形成一个调控网络,整合了许多不遵循双组分信号传导机制的其他全局调节因子以及来自中心代谢的信号。该网络的输出是响应环境变化的多种表型变化。在这些表型变化中,许多双组分系统控制运动性和/或生物膜的形成,生物膜是在表面形成的细菌固着群落。运动性是生物膜发育的第一个可逆附着阶段,随后是向有助于后续阶段的表面细胞器的所谓游动或黏附转换。在成熟的生物膜中,运动性异质性是由进化和基因调控事件共同产生的。
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