A Yeast Mutant Screen Identifies TORC and Lys63 Polyubiquitination Pathway Genes among Determinants of Sensitivity to the Cancer Stem Cell-Specific Drug Salinomycin

Donald Rozario
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Abstract

: The antibiotic salinomycin (SM) acts as a selective potassium ionophore. In budding yeast ( Saccharomyces cerevisiae ), we describe that the agent inhibits cell growth, elevates reactive oxygen species (ROS) levels and prominently causes mitochondrial damage, as revealed by the emergence of perpetually respiration-defective cells. The collection of systematic gene deletions in haploid yeast was screened to characterize genes whose deletion confers SM sensitivity or resistance if glycerol is provided as the only carbon source, thus requiring active respiration for growth. Mutants conferring the highest SM resistance were those of the Mms2-Ubi13 E2-ubiquitin conjugating enzyme (Lys63 polyubiquitination) and the TORC pathway, such as Sch9. Sch9 phosphorylation is reduced after SM treatment and, whereas initial SM-enhanced ROS levels are not diminished in the mutant, we suggest that a protective response is mounted in the absence of Sch9 that promotes mitochondrial stability under conditions of potassium ion loss. As indicated by other isolated mutants with altered SM sensitivity, levels and modifications of ribosomal proteins may also play a role in these responses. SM has attracted considerable attention due to its cancer stem-cell specific mode of action. Even if not all of its cancer stem cell targets may have an equivalent in yeast, these studies may suggest strategies for mitigating its side effects during treatment of cancer patients.
酵母突变体筛选发现肿瘤干细胞特异性药物盐霉素敏感性决定因素中的TORC和Lys63多泛素化途径基因
抗生素盐霉素(SM)是一种选择性钾离子载体。在出芽酵母(Saccharomyces cerevisiae)中,我们描述了该剂抑制细胞生长,提高活性氧(ROS)水平,并显著导致线粒体损伤,如永久性呼吸缺陷细胞的出现所揭示的那样。筛选了单倍体酵母中系统缺失的基因,以确定在甘油作为唯一碳源的情况下,哪些缺失基因赋予SM敏感性或抗性,从而需要主动呼吸来生长。具有最高SM抗性的突变体是Mms2-Ubi13 e2 -泛素结合酶(Lys63多泛素化)和TORC途径的突变体,如Sch9。SM处理后,Sch9磷酸化减少,而初始SM增强的ROS水平在突变体中并未减少,我们认为,在缺乏Sch9的情况下,保护性反应会促进钾离子损失条件下的线粒体稳定性。其他分离的SM敏感性改变的突变体表明,核糖体蛋白的水平和修饰也可能在这些反应中起作用。SM因其肿瘤干细胞特异性作用方式而备受关注。即使不是所有的癌症干细胞靶点在酵母菌中都有相同的靶点,这些研究也可能为减轻癌症患者治疗期间的副作用提供策略。
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