卤素取代酚类的细菌O-甲基化作用。
Bacterial O-methylation of halogen-substituted phenols.
作者信息
Allard A S, Remberger M, Neilson A H
出版信息
Appl Environ Microbiol. 1987 Apr;53(4):839-45. doi: 10.1128/aem.53.4.839-845.1987.
Abstract
Two strains of bacteria capable of carrying out the O-methylation of phenolic compounds, one from the gram-positive genus Rhodococcus and one from the gram-negative genus Acinetobacter, were used to examine the O-methylation of phenols carrying fluoro-, chloro-, and bromo-substituents. Zero-order rates of O-methylation were calculated from data for the chloro- and bromophenols; there was no simple relationship between the rates of reaction and the structure of the substrates, and significant differences were observed in the responses of the two test organisms. For the gram-negative strain, the pattern of substitution was as important as the number of substituents. Hexachlorophene was resistant to O-methylation by both strains, and tetrabromobisphenol-A was O-methylated only by the gram-positive strain. It is suggested that in the natural environment, bacterial O-methylation of phenols carrying electron-attracting substituents might be a significant alternative to biodegradation.
摘要
两种能够对酚类化合物进行O-甲基化的细菌菌株,一种来自革兰氏阳性的红球菌属,另一种来自革兰氏阴性的不动杆菌属,被用于检测携带氟、氯和溴取代基的酚类的O-甲基化。根据氯酚和溴酚的数据计算出O-甲基化的零级反应速率;反应速率与底物结构之间没有简单的关系,并且在两种测试微生物的反应中观察到了显著差异。对于革兰氏阴性菌株,取代模式与取代基数量同样重要。六氯酚对两种菌株的O-甲基化均具有抗性,而四溴双酚-A仅被革兰氏阳性菌株进行O-甲基化。有人提出,在自然环境中,携带吸电子取代基的酚类的细菌O-甲基化可能是生物降解的一种重要替代方式。
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