Exploration of the Plasmodium falciparum Resistome and Druggable Genome Reveals New Mechanisms of Drug Resistance and Antimalarial Targets.

Microbiology insights Pub Date : 2018-11-27 eCollection Date: 2018-01-01 DOI:10.1177/1178636118808529
Annie Cowell, Elizabeth Winzeler
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引用次数: 12

Abstract

Plasmodium parasites, the causative agent of malaria infections, rapidly evolve drug resistance and escape detection by the human immune response via the incredible mutability of its genome. Understanding the genetic mechanisms by which Plasmodium parasites develop antimalarial resistance is essential to understanding why most drugs fail in the clinic and designing the next generation of therapies. A systematic genomic analysis of 262 Plasmodium falciparum clones with stable in vitro resistance to 37 diverse compounds with potent antimalarial activity was undertaken with the main goal of identifying new drug targets. Despite several challenges inherent to this method of in vitro drug resistance generation followed by whole genome sequencing, the study was able to identify a likely drug target or resistance gene for every compound for which resistant parasites could be generated. Known and novel P falciparum resistance mediators were discovered along with several new promising antimalarial drug targets. Surprisingly, gene amplification events contributed to one-third of the drug resistance acquisition events. The study can serve as a model for drug discovery and resistance analyses in other similar microbial pathogens amenable to in vitro culture.

Abstract Image

Abstract Image

恶性疟原虫耐药组和可药物基因组的探索揭示了新的耐药机制和抗疟靶点。
疟原虫是疟疾感染的病原体,它迅速进化出耐药性,并通过其基因组令人难以置信的变异逃脱了人类免疫反应的检测。了解疟原虫产生抗疟疾耐药性的遗传机制对于理解为什么大多数药物在临床上失败和设计下一代疗法至关重要。对262个恶性疟原虫克隆进行了系统的基因组分析,这些克隆对37种具有强抗疟活性的化合物具有稳定的体外抗性,主要目的是确定新的药物靶点。尽管这种体外产生耐药性然后进行全基因组测序的方法存在一些固有的挑战,但该研究能够为每种可能产生耐药寄生虫的化合物确定可能的药物靶点或耐药基因。已知的和新型的恶性疟原虫耐药介质以及一些新的有希望的抗疟药物靶点被发现。令人惊讶的是,基因扩增事件促成了三分之一的耐药性获得事件。该研究可为其他类似微生物病原体的体外培养药物发现和耐药性分析提供模型。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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