细菌铁硫调节蛋白作为生物传感器开关。

Bacterial iron-sulfur regulatory proteins as biological sensor-switches.

机构信息

Centre for Molecular and Structural Biochemistry, School of Chemistry, University of East Anglia, Norwich, United Kingdom.

出版信息

Antioxid Redox Signal. 2012 Nov 1;17(9):1215-31. doi: 10.1089/ars.2012.4511. Epub 2012 Mar 6.

DOI:10.1089/ars.2012.4511

PMID:22239203

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3430481/

Abstract

SIGNIFICANCE

In recent years, bacterial iron-sulfur cluster proteins that function as regulators of gene transcription have emerged as a major new group. In all cases, the cluster acts as a sensor of the environment and enables the organism to adapt to the prevailing conditions. This can range from mounting a response to oxidative or nitrosative stress to switching between anaerobic and aerobic respiratory pathways. The sensitivity of these ancient cofactors to small molecule reactive oxygen and nitrogen species, in particular, makes them ideally suited to function as sensors.

RECENT ADVANCES

An important challenge is to obtain mechanistic and structural information about how these regulators function and, in particular, how the chemistry occurring at the cluster drives the subsequent regulatory response. For several regulators, including FNR, SoxR, NsrR, IscR, and Wbl proteins, major advances in understanding have been gained recently and these are reviewed here.

CRITICAL ISSUES

A common theme emerging from these studies is that the sensitivity and specificity of the cluster of each regulatory protein must be exquisitely controlled by the protein environment of the cluster.

FUTURE DIRECTIONS

A major future challenge is to determine, for a range of regulators, the key factors for achieving control of sensitivity/specificity. Such information will lead, eventually, to a system understanding of stress response, which often involves more than one regulator.

摘要

意义

近年来，作为基因转录调控因子的细菌铁硫簇蛋白已经成为一个主要的新群体。在所有情况下，该簇作为环境的传感器，使生物体能够适应流行的条件。这可以从对氧化或硝化应激的反应，到在厌氧和需氧呼吸途径之间切换。这些古老辅因子对小分子活性氧和氮物种的敏感性，使它们非常适合作为传感器发挥作用。

关键问题

这些研究中出现的一个共同主题是，每个调节蛋白簇的敏感性和特异性必须由簇的蛋白质环境精细控制。

未来方向

未来的一个主要挑战是确定一系列调节剂实现敏感性/特异性控制的关键因素。这些信息最终将导致对压力反应的系统理解，而压力反应通常涉及多个调节剂。

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