氨基醇的微生物代谢。辅酶B12依赖性乙醇胺氨裂解酶的形成及其在大肠杆菌中的协同诱导。
Microbial metabolism of amino alcohols. Formation of coenzyme B12-dependent ethanolamine ammonia-lyase and its concerted induction in Escherichia coli.
作者信息
Blackwell C M, Turner J M
出版信息
Biochem J. 1978 Dec 15;176(3):751-7. doi: 10.1042/bj1760751.
Abstract
- Kinetic studies of ethanolamine ammonia-lyase formation by Escherichia coli suggested that coenzyme B12 (5'-deoxyadenosylcobalamin), with ethanolamine, is a co-inducer. 2. Enzymic and immunological tests failed to show the formation of complementary enzyme components induced separately by ethanolamine and cobalamin respectively. 3. Although specific for ethanolamine as the substrate, enzyme formation was induced by certain analogues, e.g. 2-aminopropan-1-ol. 4. Experiments with cyano[57Co]-cobalamin suggested that neither coenzyme B12 nor some more tightly bound coenzymically inactive cobamide was necessary for enzyme stability in vitro. 5. Mutants of E. coli were obtained which formed ethanolamine ammonia-lyase apoenzyme constitutively, showing that neither ethanolamine nor cobalamin was required for assembly or post-transcriptional stability of the enzyme in vivo. Constitutive enzyme formation was subject to catabolite repression, particularly by glucose. 6. It appears likely that ethanolamine and coenzyme B12, acting in concert, induce ethanolamine ammonia-lyase formation. The term 'concerted' induction is proposed for this phenomenon.
摘要
- 大肠杆菌形成乙醇胺氨裂解酶的动力学研究表明,辅酶B12(5'-脱氧腺苷钴胺素)与乙醇胺一起是一种共诱导剂。2. 酶学和免疫学测试未能显示分别由乙醇胺和钴胺素单独诱导形成的互补酶成分。3. 尽管该酶对乙醇胺作为底物具有特异性,但某些类似物,如2-氨基丙醇,可诱导酶的形成。4. 用氰基[57Co]钴胺素进行的实验表明,在体外,辅酶B12或一些结合更紧密的无辅酶活性的钴胺酰胺对酶的稳定性都不是必需的。5. 获得了大肠杆菌突变体,其组成型地形成乙醇胺氨裂解酶脱辅酶,表明在体内,乙醇胺和钴胺素对该酶的组装或转录后稳定性都不是必需的。组成型酶的形成受到分解代谢物阻遏,尤其是葡萄糖的阻遏。6. 乙醇胺和辅酶B12协同作用似乎诱导了乙醇胺氨裂解酶的形成。为此现象提出了“协同”诱导这一术语。
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