Hydrogen sulfide: a toxic gas produced by dissimilatory sulfate and sulfur reduction and consumed by microbial oxidation.

Metal ions in life sciences Pub Date : 2014-01-01 DOI:10.1007/978-94-017-9269-1_10

Larry L Barton, Marie-Laure Fardeau, Guy D Fauque

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引用次数: 71

Abstract

Sulfur is an essential element for the synthesis of cysteine, methionine, and other organo-sulfur compounds needed by living organisms. Additionally, some prokaryotes are capable of exploiting oxidation or reduction of inorganic sulfur compounds to energize cellular growth. Several anaerobic genera of Bacteria and Archaea produce hydrogen sulfide (H2S), as a result of using sulfate (SO(4)(2 -) ), elemental sulfur (S(0)), thiosulfate (S₂O(3)(2 -)), and tetrathionate (S(4)O(6)(2 -)) as terminal electron acceptors. Some phototrophic and aerobic sulfur bacteria are capable of using electrons from oxidation of sulfide to support chemolithotrophic growth. For the most part, biosulfur reduction or oxidation requires unique enzymatic activities with metal cofactors participating in electron transfer. This review provides an examination of cytochromes, iron-sulfur proteins, and sirohemes participating in electron movement in diverse groups of sulfate-reducing, sulfur-reducing, and sulfide-oxidizing Bacteria and Archaea.

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硫化氢:由异化硫酸盐和硫还原产生的有毒气体，由微生物氧化消耗。

硫是合成半胱氨酸、蛋氨酸和生物体所需的其他有机含硫化合物的必需元素。此外，一些原核生物能够利用无机硫化合物的氧化或还原来为细胞生长提供能量。细菌和古细菌的几个厌氧属产生硫化氢(H2S)，由于使用硫酸盐(SO(4)(2 -))，单质硫(S(0))，硫代硫酸盐(S₂O(3)(2 -))和四硫酸盐(S(4)O(6)(2 -))作为终端电子受体。一些光养和好氧硫细菌能够利用硫化物氧化产生的电子来支持化能营养生长。在大多数情况下，生物硫还原或氧化需要独特的酶活性与金属辅助因子参与电子转移。本文综述了细胞色素、铁硫蛋白和sirohemes在硫酸盐还原、硫还原和硫化物氧化细菌和古细菌中参与电子运动的研究进展。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Metal ions in life sciences

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