活细菌细胞中严谨反应机制的单分子研究。

Single-molecule investigations of the stringent response machinery in living bacterial cells.

机构信息

Department of Cell and Molecular Biology, Uppsala University, Uppsala, Sweden.

出版信息

Proc Natl Acad Sci U S A. 2011 Aug 2;108(31):E365-73. doi: 10.1073/pnas.1102255108. Epub 2011 Jul 5.

DOI:10.1073/pnas.1102255108

PMID:21730169

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3150888/

Abstract

The RelA-mediated stringent response is at the heart of bacterial adaptation to starvation and stress, playing a major role in the bacterial cell cycle and virulence. RelA integrates several environmental cues and synthesizes the alarmone ppGpp, which globally reprograms transcription, translation, and replication. We have developed and implemented novel single-molecule tracking methodology to characterize the intracellular catalytic cycle of RelA. Our single-molecule experiments show that RelA is on the ribosome under nonstarved conditions and that the individual enzyme molecule stays off the ribosome for an extended period of time after activation. This suggests that the catalytically active part of the RelA cycle is performed off, rather than on, the ribosome, and that rebinding to the ribosome is not necessary to trigger each ppGpp synthesis event. Furthermore, we find fast activation of RelA in response to heat stress followed by RelA rapidly being reset to its inactive state, which makes the system sensitive to new environmental cues and hints at an underlying excitable response mechanism.

摘要

RelA 介导的严格反应是细菌适应饥饿和压力的核心，在细菌细胞周期和毒力中发挥主要作用。RelA 整合了多种环境线索，并合成了预警子 ppGpp，该物质全局重编程转录、翻译和复制。我们开发并实施了新的单分子跟踪方法来描述 RelA 的细胞内催化循环。我们的单分子实验表明，在非饥饿条件下，RelA 位于核糖体上，并且在激活后，单个酶分子会在核糖体上停留很长一段时间。这表明 RelA 循环的催化活性部分是在核糖体之外进行的，而不是在核糖体上进行的，并且重新结合核糖体并不是触发每个 ppGpp 合成事件所必需的。此外，我们发现 RelA 对热应激的快速激活，随后 RelA 迅速恢复到非活跃状态，这使系统对新的环境线索敏感，并暗示存在潜在的兴奋反应机制。

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