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细胞防御氧化损伤在白色念珠菌对两性霉素B杀伤作用抗性中的作用。

Role of cell defense against oxidative damage in the resistance of Candida albicans to the killing effect of amphotericin B.

作者信息

Sokol-Anderson M, Sligh J E, Elberg S, Brajtburg J, Kobayashi G S, Medoff G

机构信息

Division of Infectious Diseases, Washington University School of Medicine, St. Louis, Missouri 63110.

出版信息

Antimicrob Agents Chemother. 1988 May;32(5):702-5. doi: 10.1128/AAC.32.5.702.

DOI:10.1128/AAC.32.5.702
PMID:3293525
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC172255/
Abstract

A laboratory-derived mutant of Candida albicans B311 (L) and a clinical isolate (C) of C. albicans, both lacking membrane ergosterol, were less susceptible to amphotericin B (AmB)-induced cell membrane permeability to K+ and lethality than was the wild-type laboratory strain (B311) which contained ergosterol. The resistance of L and C to AmB-induced killing was much greater than the level of resistance to AmB-induced cell membrane permeability. L and C were also less susceptible to killing by H2O2 than was B311, and when treated with menadione, they each produced less H2O2 than did B311. In addition, their levels of catalase activity were 3.8-fold (L) and 2-fold (C) higher than that of B311. The ergosterol deficiency in L and C probably impaired AmB binding to the cells, thereby lowering AmB effectiveness as measured by both cell membrane permeability and killing. Resistance of strains L and C to oxidation-dependent damage likely contributed to a diminished response to AmB-induced lethality.

摘要

白色念珠菌B311 (L) 的实验室衍生突变体和白色念珠菌的临床分离株 (C),两者均缺乏膜麦角固醇,与含有麦角固醇的野生型实验室菌株 (B311) 相比,它们对两性霉素B (AmB) 诱导的细胞膜对K+ 的通透性和致死性的敏感性较低。L和C对AmB诱导的杀伤的抗性远大于对AmB诱导的细胞膜通透性的抗性水平。L和C对H2O2 杀伤的敏感性也低于B311,并且在用甲萘醌处理时,它们各自产生的H2O2 比B311少。此外,它们的过氧化氢酶活性水平分别比B311高3.8倍 (L) 和2倍 (C)。L和C中麦角固醇的缺乏可能会损害AmB与细胞的结合,从而降低通过细胞膜通透性和杀伤作用衡量的AmB有效性。菌株L和C对氧化依赖性损伤的抗性可能导致对AmB诱导的致死性反应减弱。

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