亲核试剂对苄青霉素与链霉菌R61菌株的胞外DD-羧肽酶-转肽酶之间形成的苄青霉素酰基-酶复合物EI分解的影响。
Effects of nucleophiles on the breakdown of the benzylpenicilloyl-enzyme complex EI formed between benzylpenicillin and the exocellular DD-carboxypeptidase--transpeptiase of Streptomyces strain R61.
作者信息
Marquet A, Frère J M, Ghuysen J M, Loffet A
出版信息
Biochem J. 1979 Mar 1;177(3):909-16. doi: 10.1042/bj1770909.
Abstract
Serine is one of the enzyme residues with which benzylpenicillin collides as a result of its binding to the Streptomyces strain-R61 DD-carboxypeptidase-transpeptidase enzyme. Nucleophilic attack occurs on C(7) of the bound antibiotic molecule with formation of a benzylpenicilloyl-serine ester linkage, i.e. formation of the benzylpenicilloyl-enzyme EI complex. To reject the bound penicilloyl moiety and consequently to recover its initial activities, the strain-R61 enzyme has developed two possible mechanisms. Pathway A is a direct attack of the serine ester linkage by an exogenous nucleophile, resulting in the transfer of the benzylpenicilloyl moiety to this nucleophile. In pathway B, the benzylpenicilloyl moiety is first fragmented by C(5)-C(6) cleavage and the enzyme-bound phenylacetylglycyl residue thus produced is in turn transferred to the nucleophile. Pathway B occurs with water, glycylglycine and other amino compounds. Both pathways A and B occur with glycerol, other ROH nucleophiles and neutral hydroxylamine. The nucleophilic attacks are enzyme-catalysed.
摘要
丝氨酸是苄青霉素与链霉菌菌株-R61 D-羧肽酶-转肽酶结合时发生碰撞的酶残基之一。亲核攻击发生在结合的抗生素分子的C(7)上,形成苄青霉素酰-丝氨酸酯键,即形成苄青霉素酰-酶EI复合物。为了去除结合的青霉素酰部分并因此恢复其初始活性,菌株-R61酶发展出了两种可能的机制。途径A是外源亲核试剂对丝氨酸酯键的直接攻击,导致苄青霉素酰部分转移到该亲核试剂上。在途径B中,苄青霉素酰部分首先通过C(5)-C(6)裂解而断裂,由此产生的与酶结合的苯乙酰甘氨酰残基进而转移到亲核试剂上。途径B在水、甘氨酰甘氨酸和其他氨基化合物存在时发生。途径A和B在甘油、其他ROH亲核试剂和中性羟胺存在时均会发生。亲核攻击是由酶催化的。
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