细胞对超氧化物和过氧化氢的防御机制。
Cellular defenses against superoxide and hydrogen peroxide.
作者信息
Imlay James A
机构信息
Department of Microbiology, University of Illinois, Urbana, IL 61801, USA.
出版信息
Annu Rev Biochem. 2008;77:755-76. doi: 10.1146/annurev.biochem.77.061606.161055.
Abstract
Life evolved in an anaerobic world; therefore, fundamental enzymatic mechanisms and biochemical pathways were refined and integrated into metabolism in the absence of any selective pressure to avoid reactivity with oxygen. After photosystem II appeared, environmental oxygen levels rose very slowly. During this time, microorganisms acquired oxygen tolerance by jettisoning enzymes that use glycyl radicals and exposed low-potential iron-sulfur clusters, which can be directly poisoned by oxygen. They also developed mechanisms to defend themselves against superoxide (O(2)()) and hydrogen peroxide, partially reduced oxygen species that are generated as inadvertent by-products of aerobic metabolism. Contemporary organisms have inherited both the vulnerabilities and the defenses of these ancestral microbes. Current research seeks to identify these, and bacteria comprise an exceptionally accessible experimental system that has provided many of the answers. This manuscript reviews recent developments and identifies remaining puzzles.
摘要
生命在无氧环境中演化;因此,基本的酶促机制和生化途径在没有避免与氧气发生反应的选择压力的情况下得到完善并融入新陈代谢。在光系统II出现后,环境中的氧气水平上升非常缓慢。在此期间,微生物通过抛弃使用甘氨酰自由基的酶和暴露低电位铁硫簇来获得耐氧性,这些酶和铁硫簇会被氧气直接毒害。它们还开发了抵御超氧化物(O₂⁻)和过氧化氢的机制,这两种部分还原的氧物种是有氧代谢不经意产生的副产物。当代生物继承了这些远古微生物的脆弱性和防御机制。目前的研究试图识别这些,而细菌构成了一个特别容易研究的实验系统,已经提供了许多答案。本文综述了近期的进展并指出了仍存在的谜题。
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