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细胞色素P450 51作为真菌和原生动物寄生虫的药物靶点:过去、现在与未来

CYP51 as drug targets for fungi and protozoan parasites: past, present and future.

作者信息

Lepesheva Galina I, Friggeri Laura, Waterman Michael R

机构信息

Department of Biochemistry,Vanderbilt University School of Medicine,Nashville, Tennessee 37232,USA.

出版信息

Parasitology. 2018 Dec;145(14):1820-1836. doi: 10.1017/S0031182018000562. Epub 2018 Apr 12.

DOI:10.1017/S0031182018000562
PMID:29642960
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC6185833/
Abstract

The efficiency of treatment of human infections with the unicellular eukaryotic pathogens such as fungi and protozoa remains deeply unsatisfactory. For example, the mortality rates from nosocomial fungemia in critically ill, immunosuppressed or post-cancer patients often exceed 50%. A set of six systemic clinical azoles [sterol 14α-demethylase (CYP51) inhibitors] represents the first-line antifungal treatment. All these drugs were discovered empirically, by monitoring their effects on fungal cell growth, though it had been proven that they kill fungal cells by blocking the biosynthesis of ergosterol in fungi at the stage of 14α-demethylation of the sterol nucleus. This review briefs the history of antifungal azoles, outlines the situation with the current clinical azole-based drugs, describes the attempts of their repurposing for treatment of human infections with the protozoan parasites that, similar to fungi, also produce endogenous sterols, and discusses the most recently acquired knowledge on the CYP51 structure/function and inhibition. It is our belief that this information should be helpful in shifting from the traditional phenotypic screening to the actual target-driven drug discovery paradigm, which will rationalize and substantially accelerate the development of new, more efficient and pathogen-oriented CYP51 inhibitors.

摘要

对于治疗由真菌和原生动物等单细胞真核病原体引起的人类感染,其治疗效果仍非常不尽人意。例如,重症、免疫抑制或癌症后患者的医院获得性真菌血症死亡率常常超过50%。六种全身性临床唑类药物(甾醇14α-去甲基酶(CYP51)抑制剂)是一线抗真菌治疗药物。所有这些药物都是通过监测它们对真菌细胞生长的影响凭经验发现的,尽管已证实它们通过在甾醇核14α-去甲基化阶段阻断真菌中麦角甾醇的生物合成来杀死真菌细胞。本综述简要介绍了抗真菌唑类药物的历史,概述了当前基于唑类的临床药物的情况,描述了将它们重新用于治疗由原生动物寄生虫引起的人类感染的尝试,这些原生动物寄生虫与真菌类似,也产生内源性甾醇,并讨论了最近获得的关于CYP51结构/功能及抑制作用的知识。我们相信,这些信息将有助于从传统的表型筛选转向实际的靶点驱动药物发现模式,这将使新型、更高效且针对病原体的CYP51抑制剂的研发更加合理并大幅加速。

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