Queffeulou Marine, Leprohon Philippe, Fernandez-Prada Christopher, Ouellette Marc, Mejía-Jaramillo Ana María
Centre de Recherche en Infectiologie du Centre de Recherche du CHU Québec, Université Laval, Québec, Canada.
Département de Microbiologie, Infectiologie et Immunologie, Faculté de Médecine, Université Laval, Québec, Canada.
mBio. 2024 Jul 17;15(7):e0047724. doi: 10.1128/mbio.00477-24. Epub 2024 Jun 12.
Parasites of the genus pose a global health threat with limited treatment options. New drugs are urgently needed, and genomic screens have the potential to accelerate target discovery, mode of action, and resistance mechanisms against these new drugs. We describe here our effort in developing a genome-wide CRISPR-Cas9 screen in , an organism lacking a functional nonhomologous end joining system that must rely on microhomology-mediated end joining, single-strand annealing, or homologous recombination for repairing Cas9-induced double-stranded DNA breaks. A new vector for cloning and expressing single guide RNAs (sgRNAs) was designed and proven to be effective in a small pilot project while enriching specific sgRNAs during drug selection. We then developed a whole-genome library of 49,754 sgRNAs, targeting all the genes of . This library was transfected in expressing Cas9, and these cells were selected for resistance to two antileishmanials, miltefosine and amphotericin B. The sgRNAs the most enriched in the miltefosine screen targeted the miltefosine transporter gene, but sgRNAs targeting genes coding for a RING-variant protein and a transmembrane protein were also enriched. The sgRNAs the most enriched by amphotericin B targeted the sterol 24 C methyltransferase genes and a hypothetical gene. Through gene disruption experiments, we proved that loss of function of these genes was associated with resistance. This study describes the feasibility of carrying out whole-genome CRISPR-Cas9 screens in provided that a strong selective pressure is applied. Such a screen can be used for accelerating the development of urgently needed antileishmanial drugs.IMPORTANCELeishmaniasis, a global health threat, lacks adequate treatment options and drug resistance exacerbates the challenge. This study introduces a CRISPR-Cas9 screening approach in , unraveling mechanisms of drug resistance at a genome-wide scale. Our screen was applied against two main antileishmanial drugs, and guides were enriched upon drug selection. These guides targeted known and new targets, hence validating the use of this screen against . This strategy provides a powerful tool to expedite drug discovery as well as potential therapeutic targets against this neglected tropical disease.
属的寄生虫对全球健康构成威胁,且治疗选择有限。迫切需要新药,而基因组筛选有潜力加速针对这些新药的靶点发现、作用方式和耐药机制研究。我们在此描述了我们在开发全基因组CRISPR-Cas9筛选体系方面所做的努力,该筛选体系用于一种缺乏功能性非同源末端连接系统的生物体,这种生物体必须依靠微同源性介导的末端连接、单链退火或同源重组来修复Cas9诱导的双链DNA断裂。我们设计了一种用于克隆和表达单向导RNA(sgRNA)的新载体,并在一个小型试点项目中证明其有效,同时在药物筛选过程中富集特定的sgRNA。然后,我们开发了一个包含49754个sgRNA的全基因组文库,靶向该生物体的所有基因。将这个文库转染到表达Cas9的细胞中,并选择这些细胞使其对两种抗利什曼原虫药物米替福新和两性霉素B产生抗性。在米替福新筛选中富集程度最高的sgRNA靶向米替福新转运蛋白基因,但靶向编码一种RING变体蛋白和一种跨膜蛋白的基因的sgRNA也有富集。两性霉素B富集程度最高的sgRNA靶向固醇24 C甲基转移酶基因和一个假定基因。通过基因敲除实验,我们证明这些基因的功能丧失与抗性有关。本研究描述了在施加强大选择压力的情况下,在该生物体中进行全基因组CRISPR-Cas9筛选的可行性。这样的筛选可用于加速急需的抗利什曼原虫药物的开发。重要性利什曼病对全球健康构成威胁,缺乏足够的治疗选择,而耐药性加剧了这一挑战。本研究在该生物体中引入了CRISPR-Cas9筛选方法,在全基因组范围内揭示耐药机制。我们的筛选针对两种主要的抗利什曼原虫药物进行,在药物筛选后向导RNA被富集。这些向导RNA靶向已知和新的靶点,从而验证了该筛选方法在该生物体中的应用。这种策略为加速药物发现以及针对这种被忽视的热带疾病的潜在治疗靶点提供了一个强大的工具。
