Laboratory of Molecular Genetics, Cancer Research Institute, Vlárska 7, 833 91 Bratislava, Slovak Republic.
Chem Res Toxicol. 2012 Aug 20;25(8):1598-608. doi: 10.1021/tx300061n. Epub 2012 Jul 17.
Selenium (Se) is a trace element that is essential for human health as it takes part in many cellular processes. The cellular response to this compound elicits very diverse processes including DNA damage response and repair. Because an inorganic form of Se, sodium selenite (SeL), has often been a part of numerous studies and because this form of Se is used as a dietary supplement by the public, here, we elucidated mechanisms of SeL-induced toxicity in yeast Saccharomyces cerevisiae using a combination of systematic genetic and transcriptome analysis. First, we screened the yeast haploid deletion mutant library for growth in the presence of this Se compound. We identified 39 highly SeL sensitive mutants. The corresponding deleted genes encoded mostly proteins involved in DNA damage response and repair, vacuole function, glutathione (GSH) metabolism, transcription, and chromatin metabolism. DNA damage response and repair mutants were examined in more detail: a synergistic interaction between postreplication (PRR) and homologous recombination (HRR) repair pathways was revealed. In addition, the effect of combined defects in HRR and GSH metabolism was analyzed, and again, the synergistic interaction was found. Second, microarray analysis was used to reveal expression profile changes after SeL exposure. The gene process categories "amino acid metabolism" and "generation of precursor metabolites and energy" comprised the greatest number of induced and repressed genes, respectively. We propose that SeL-induced toxicity markedly results from DNA injury, thereby highlighting the importance of DNA damage response and repair pathways in protecting cells against toxic effects of this Se compound. In addition, we suggest that SeL toxicity also originates from damage to cellular proteins, including those acting in DNA damage response and repair.
硒(Se)是一种必需的微量元素,对人类健康至关重要,因为它参与了许多细胞过程。细胞对这种化合物的反应引发了非常多样化的过程,包括 DNA 损伤反应和修复。由于无机形式的硒,亚硒酸钠(SeL),经常是许多研究的一部分,并且这种形式的硒被公众用作膳食补充剂,因此,我们使用系统的遗传和转录组分析相结合的方法,阐明了 SeL 在酵母酿酒酵母中的诱导毒性机制。首先,我们在含有这种 Se 化合物的情况下筛选了酵母单倍体缺失突变体文库的生长情况。我们鉴定出 39 种对 SeL 非常敏感的突变体。相应缺失的基因编码的大多数蛋白质都参与 DNA 损伤反应和修复、液泡功能、谷胱甘肽(GSH)代谢、转录和染色质代谢。进一步研究了 DNA 损伤反应和修复突变体:揭示了复制后(PRR)和同源重组(HRR)修复途径之间的协同相互作用。此外,还分析了 HRR 和 GSH 代谢联合缺陷的影响,再次发现了协同相互作用。其次,使用微阵列分析揭示了 SeL 暴露后的表达谱变化。基因过程类别“氨基酸代谢”和“前体代谢物和能量的产生”分别包含最多的诱导和抑制基因。我们提出,SeL 诱导的毒性主要源于 DNA 损伤,从而突出了 DNA 损伤反应和修复途径在保护细胞免受这种 Se 化合物的毒性作用方面的重要性。此外,我们还认为 SeL 毒性也源于对细胞蛋白的损伤,包括那些在 DNA 损伤反应和修复中起作用的蛋白。
