肉毒梭菌对精氨酸和鸟氨酸的分解代谢

Arginine and ornithine catabolism by Clostridium botulinum.

作者信息

Mitruka B M, Costilow R N

出版信息

J Bacteriol. 1967 Jan;93(1):295-301. doi: 10.1128/jb.93.1.295-301.1967.

DOI:10.1128/jb.93.1.295-301.1967

PMID:5335895

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC315001/

Abstract

Clostridium botulinum 62-A was shown to catabolize l-arginine via citrulline to ornithine, NH(3), and CO(2). The individual enzymes of the dihydrolase system were all demonstrated in extracts of cells, spores, and germinated spores. There was no liberation of urea from l-arginine, so no functional arginase enzyme is present, but there was some transamidinase activity in cell extracts. l-Ornithine was degraded at a significant rate by cells grown in an l-ornithine-supplemented medium; it was partially decarboxylated to putrescine and partially fermented to NH(3), CO(2), volatile acids, and delta-aminovaleric acid. Results from the fermentation of l-ornithine-C(14), -1-C(14), and -2-C(14) demonstrated that essentially all of the CO(2) was derived from carbon 1, and volatile acids from carbons 2 to 5. Assays for the products of l-ornithine-C(14) fermentation revealed that the volatile acids consisted of acetate, propionate, valerate, and butyrate (in order of decreasing concentrations), and that delta-amino-valerate was the primary reduced product. A small amount of citrulline was formed during the fermentation. The carbon and redox balances indicated that l-ornithine is fermented as a single substrate. Preliminary experiments demonstrated that the fermentation of l-ornithine is carried out by cell extracts with the production of volatile acids.

摘要

肉毒梭菌62 - A被证明可通过瓜氨酸将L - 精氨酸分解为鸟氨酸、NH₃和CO₂。双水解酶系统的各个酶在细胞、孢子和发芽孢子的提取物中均得到证实。L - 精氨酸没有释放出尿素，因此不存在功能性的精氨酸酶，但细胞提取物中有一些转脒基酶活性。在添加L - 鸟氨酸的培养基中生长的细胞能以显著速率降解L - 鸟氨酸；它部分脱羧生成腐胺，部分发酵生成NH₃、CO₂、挥发性酸和δ - 氨基戊酸。L - 鸟氨酸 - C¹⁴、-1 - C¹⁴和 - 2 - C¹⁴的发酵结果表明，基本上所有的CO₂都来自碳1，挥发性酸来自碳2至碳5。对L - 鸟氨酸 - C¹⁴发酵产物的分析表明，挥发性酸由乙酸、丙酸、戊酸和丁酸组成（浓度依次降低），且δ - 氨基戊酸是主要的还原产物。发酵过程中形成了少量瓜氨酸。碳和氧化还原平衡表明L - 鸟氨酸作为单一底物进行发酵。初步实验表明，L - 鸟氨酸的发酵是由细胞提取物进行的，并产生挥发性酸。

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