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黄素杆菌属转化甲基对硫磷的多相动力学。

Multiphasic kinetics for transformation of methyl parathion by flavobacterium species.

机构信息

Environmental Research Laboratory, U.S. Environmental Protection Agency, Athens, Georgia 30613, and Department of Microbiology and Institute of Ecology, University of Georgia, Athens, Georgia 30602.

出版信息

Appl Environ Microbiol. 1985 Sep;50(3):553-7. doi: 10.1128/aem.50.3.553-557.1985.

DOI:10.1128/aem.50.3.553-557.1985
PMID:16346874
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC238667/
Abstract

Transformation rates of an insecticide, methyl parathion, in pure cultures of Flavobacterium sp. followed multiphasic kinetics involving at least two systems (I and II). System I was a high-affinity, low-capacity system, and system II was a low-affinity, high-capacity system. Data from rate experiments suggested that metabolites formed via system II inhibited system I such that only one system operated at a time. System I operated at approximately 20 mug liter and less; system II operated at approximately 4 mg liter and less. These results show that xenobiotic chemicals, like naturally occurring substrates, can be transformed via multiple uptake and transformation systems even by a pure culture. Furthermore, computer simulation models of pollutant transformation rates based on kinetic constants determined in this study show that large errors can occur in predicted rates when the multiphasicity of kinetics is neglected.

摘要

杀虫剂甲基对硫磷在黄杆菌纯培养物中的转化速率遵循多相动力学,至少涉及两个系统(I 和 II)。系统 I 是一个高亲和力、低容量系统,系统 II 是一个低亲和力、高容量系统。速率实验数据表明,通过系统 II 形成的代谢物抑制了系统 I,使得一次只能运行一个系统。系统 I 的作用范围约为 20 微克/升及以下;系统 II 的作用范围约为 4 毫克/升及以下。这些结果表明,即使是纯培养物,也可以通过多种摄取和转化系统来转化外来化学物质,就像天然存在的底物一样。此外,基于本研究中确定的动力学常数的污染物转化速率的计算机模拟模型表明,当动力学的多相性被忽略时,预测速率可能会出现较大误差。

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