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通过过氧化氢、抗坏血酸和溶菌酶的协同作用杀灭革兰氏阴性菌并使其裂解。

Killing and lysis of gram-negative bacteria through the synergistic effect of hydrogen peroxide, ascorbic acid, and lysozyme.

作者信息

Miller T E

出版信息

J Bacteriol. 1969 Jun;98(3):949-55. doi: 10.1128/jb.98.3.949-955.1969.

DOI:10.1128/jb.98.3.949-955.1969
PMID:4892384
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC315280/
Abstract

A mixture of hydrogen peroxide and ascorbic acid has been found to generate an antibacterial mechanism which is active against gram-negative bacteria. It results in bacterial death and renders the organism sensitive to lysis by lysozyme. Under the conditions used, horseradish peroxidase did not augment the antibacterial effect. It is suggested that the effector mechanism involves the generation of short-lived free radicals which disturb the integrity of the cell wall. This effect alone might kill bacteria by interfering with selective permeability, but in the presence of lysozyme a further bactericidal activity is accomplished by complete disruption of the cell. It is proposed that a transient antibacterial system such as that described could exist within phagocytic cells. Free radicals would be formed through the interaction of certain oxidizable substances and hydrogen peroxide, which is produced during the enhanced metabolic activity that accompanies ingestion of bacteria. Such a system would help to explain why macrophages, which are apparently devoid of preformed bactericidins, are nonetheless very efficient in killing most phagocytosed bacteria.

摘要

已发现过氧化氢和抗坏血酸的混合物能产生一种对革兰氏阴性菌有活性的抗菌机制。它会导致细菌死亡,并使生物体对溶菌酶的裂解敏感。在所使用的条件下,辣根过氧化物酶不会增强抗菌效果。有人认为,效应机制涉及产生干扰细胞壁完整性的短寿命自由基。仅这种作用可能通过干扰选择性通透性来杀死细菌,但在溶菌酶存在的情况下,通过细胞的完全破坏可实现进一步的杀菌活性。有人提出,如所描述的这种短暂抗菌系统可能存在于吞噬细胞内。自由基将通过某些可氧化物质与过氧化氢的相互作用形成,而过氧化氢是在伴随细菌摄取的增强代谢活动期间产生的。这样的系统将有助于解释为什么显然没有预先形成的杀菌素的巨噬细胞在杀死大多数吞噬的细菌方面却非常有效。

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