Nicolas Fierling, Patrick Billard, Pascale Bauda, Damien Blaudez
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引用次数: 0
Abstract
The increasing use of lithium (Li) in new technologies raises the question of its impact on living microorganisms. In the present study, we aimed to identify putative Li targets and resistance mechanisms in the yeast model Saccharomyces cerevisiae using a deletomic approach based on the screening of a collection of 4,733 knockout mutants under Li exposure. This screening highlighted 60 mutants resistant to Li and 124 mutants sensitive to Li. Through functional enrichment analyses, transport systems and catabolite repression were identified as playing a central role in cell resistance to toxic concentrations of Li. In contrast, the AKT/protein kinase B family, signal transduction or cell communication were identified as potential toxic targets of Li. The majority of the mutants with a Li-sensitive phenotype were also sensitive to other alkali and alkaline-earth metals, whereas the Li-resistance phenotype was mostly resistant to Na but poorly resistant to other metals. A comparison with the results of deletomics studies carried out in the presence of other metals highlighted Li-specific phenotypes. Three genes (NAM7, NMD2, UPF3) of the nonsense-mediated decay pathway were specifically involved in resistance to Li. In contrast, mutants with the NCA2, SPT20, GCN5, YOR376W, YPK3, and DCW1 genes deleted were specifically sensitive to Li. These genes encode various functions from putative mannosidase to constitution of the Spt-Ada-Gcn5 acetyltransferase complex. This work provides a better understanding of potential specific resistance mechanisms and cellular targets of Li in yeast.
锂(Li)在新技术中的使用日益增多,这就提出了锂对生物微生物的影响问题。在本研究中,我们通过对 4733 个锂暴露下的基因敲除突变体进行筛选,采用脱粒组学方法,旨在确定酵母模型酿酒酵母中潜在的锂靶标和抗性机制。这一筛选突出了 60 个对 Li 具有抗性的突变体和 124 个对 Li 敏感的突变体。通过功能富集分析,确定了运输系统和代谢抑制在细胞对有毒浓度的锂的抗性中起核心作用。相反,AKT/蛋白激酶 B 家族、信号转导或细胞通讯被确定为 Li 的潜在毒性靶标。大多数具有锂敏感表型的突变体也对其他碱金属和碱土金属敏感,而锂抗性表型大多对 Na 具有抗性,但对其他金属的抗性较差。与在其他金属存在的情况下进行的缺失组学研究结果进行比较后发现,锂的表型具有特异性。无义介导衰变途径的三个基因(NAM7、NMD2、UPF3)特别参与了对锂的抗性。相反,删除了 NCA2、SPT20、GCN5、YOR376W、YPK3 和 DCW1 基因的突变体对锂特别敏感。这些基因编码从推定甘露糖苷酶到 Spt-Ada-Gcn5 乙酰转移酶复合物组成的各种功能。这项工作让我们更好地了解了酵母对 Li 的潜在特异性抗性机制和细胞靶标。