吡啶环的微生物代谢。微生物降解吡啶化合物过程中作为中间体的吡啶二醇(二羟基吡啶)的形成。
Microbial metabolism of the pyridine ring. Formation of pyridinediols (dihydroxypyridines) as intermediates in the degradation of pyridine compounds by micro-organisms.
作者信息
Houghton C, Cain R B
出版信息
Biochem J. 1972 Dec;130(3):879-93. doi: 10.1042/bj1300879.
Abstract
- Several species of micro-organisms that were capable of utilizing pyridine compounds as carbon and energy source were isolated from soil and sewage. Compounds degraded included pyridine and the three isomeric hydroxypyridines. 2. Suitable modifications of the cultural conditions led to the accumulation of pyridinediols (dihydroxypyridines), which were isolated and characterized. 3. Three species of Achromobacter produced pyridine-2,5-diol from 2- or 3-hydroxypyridine whereas an uncommon Agrobacterium sp. (N.C.I.B. 10413) produced pyridine-3,4-diol from 4-hydroxypyridine. 4. On the basis of chemical isolation, induction of the necessary enzymes in washed suspensions and the substrate specificity exhibited by the isolated bacteria, the initial transformations proposed are: 2-hydroxypyridine --> pyridine-2,5-diol; 3-hydroxypyridine --> pyridine-2,5-diol and 4-hydroxypyridine --> pyridine-3,4-diol. 5. A selected pyridine-utilizer, Nocardia Z1, did not produce any detectable hydroxy derivative from pyridine, but carried out a slow oxidation of 3-hydroxypyridine to pyridine-2,3-diol and pyridine-3,4-diol. These diols were not further metabolized. 6. Addition of the isomeric hydroxypyridines to a model hydroxylating system resulted in the formation of those diols predicted by theory.
摘要
- 从土壤和污水中分离出了几种能够利用吡啶化合物作为碳源和能源的微生物。被降解的化合物包括吡啶和三种异构羟基吡啶。2. 对培养条件进行适当修改后,吡啶二醇(二羟基吡啶)得以积累,并对其进行了分离和表征。3. 三种无色杆菌属的菌株可从2-或3-羟基吡啶生成吡啶-2,5-二醇,而一种罕见的土壤杆菌属菌株(N.C.I.B. 10413)可从4-羟基吡啶生成吡啶-3,4-二醇。4. 根据化学分离、在洗涤后的悬浮液中诱导所需酶以及分离出的细菌所表现出的底物特异性,提出的初始转化过程为:2-羟基吡啶→吡啶-2,5-二醇;3-羟基吡啶→吡啶-2,5-二醇;4-羟基吡啶→吡啶-3,4-二醇。5. 一种选定的利用吡啶的诺卡氏菌Z1,不能从吡啶产生任何可检测到的羟基衍生物,但能将3-羟基吡啶缓慢氧化为吡啶-2,3-二醇和吡啶-3,4-二醇。这些二醇不再进一步代谢。6. 将异构羟基吡啶添加到模型羟化系统中,会生成理论上预测的那些二醇。
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