4-N-羟基胞苷在大肠杆菌中的代谢

Metabolism of 4-N-hydroxy-cytidine in Escherichia coli.

作者信息

Trimble R B, Maley F

出版信息

J Bacteriol. 1971 Oct;108(1):145-53. doi: 10.1128/jb.108.1.145-153.1971.

DOI:10.1128/jb.108.1.145-153.1971

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC247043/

Abstract

4-N-hydroxy-cytidine was found to substitute for uridine as a pyrimidine supplement for the growth of Escherichia coli Bu(-). Measurement of the incorporation of 4-N-hydroxy-cytidine-2-(14)C into ribonucleic acid and deoxyribonucleic acid revealed that this compound was converted to cytidine or uridine before utilization. Two pathways for metabolism were considered: (i) the reduction of 4-N-hydroxy-cytidine to cytidine followed by deamination, (ii) the direct hydrolysis of hydroxylamine from 4-N-hydroxy-cytidine to yield uridine. A threefold increase in cytidine (deoxycytidine) deaminase (EC 3.5.4.5) activity, when the cells were grown on 4-N-hydroxy-cytidine, suggested the involvement of this enzyme. More direct proof was obtained by purifying the deaminase 185-fold and finding that it released hydroxylamine from 4-N-hydroxy-cytidine at one-fiftieth the rate at which ammonia was removed from cytidine. This result is consistent with the slower rate of growth of the Bu(-) cells on 4-N-hydroxy-cytidine than cytidine and suggests that the second pathway is the major route for utilization of this compound.

摘要

发现4-N-羟基胞苷可替代尿苷作为嘧啶补充剂，用于大肠杆菌Bu(-)的生长。对4-N-羟基胞苷-2-(14)C掺入核糖核酸和脱氧核糖核酸的测量表明，该化合物在利用前先转化为胞苷或尿苷。考虑了两条代谢途径：(i) 4-N-羟基胞苷还原为胞苷，随后脱氨；(ii) 4-N-羟基胞苷直接水解产生羟胺以生成尿苷。当细胞在4-N-羟基胞苷上生长时，胞苷（脱氧胞苷）脱氨酶（EC 3.5.4.5）活性增加了三倍，表明该酶参与其中。通过将脱氨酶纯化185倍，并发现其从4-N-羟基胞苷释放羟胺的速率是从胞苷去除氨的速率的五十分之一，从而获得了更直接的证据。这一结果与Bu(-)细胞在4-N-羟基胞苷上的生长速度比在胞苷上慢相一致，并表明第二条途径是该化合物利用的主要途径。

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