Abstract
The absence of Tsa1, a key peroxiredoxin that scavenges H2O2 in Saccharomyces cerevisiae, causes the accumulation of a broad spectrum of mutations. Deletion of TSA1 also causes synthetic lethality in combination with mutations in RAD51 or several key genes involved in DNA double-strand break repair. In the present study, we propose that the accumulation of reactive oxygen species (ROS) is the primary cause of genome instability of tsa1Δ cells. In searching for spontaneous suppressors of synthetic lethality of tsa1Δ rad51Δ double mutants, we identified that the loss of thioredoxin reductase Trr1 rescues their viability. The trr1Δ mutant displayed a CanR mutation rate 5-fold lower than wild-type cells. Additional deletion of TRR1 in tsa1Δ mutant reduced substantially the CanR mutation rate of tsa1Δ strain (33-fold), and to a lesser extent, of rad51Δ strain (4-fold). Loss of Trr1 induced Yap1 nuclear accumulation and over-expression of a set of Yap1-regulated oxido-reductases with antioxidant properties that ultimately re-equilibrate intracellular redox environment, reducing substantially ROS-associated DNA damages. This trr1Δ -induced effect was largely thioredoxin-dependent, probably mediated by oxidized forms of thioredoxins, the primary substrates of Trr1. Thioredoxin Trx1 and Trx2 were constitutively and strongly oxidized in the absence of Trr1. In trx1Δ trx2Δ cells, Yap1 was only moderately activated; consistently, the trx1Δ trx2Δ double deletion failed to efficiently rescue the viability of tsa1Δ rad51Δ. Finally, we showed that modulation of the dNTP pool size also influences the formation of spontaneous mutation in trr1Δ and trx1Δ trx2Δ strains. We present a tentative model that helps to estimate the respective impact of ROS level and dNTP concentration in the generation of spontaneous mutations.
Highlights
Reactive oxygen species (ROS) are formed in all oxygenconsuming organisms
It is generally accepted that the Canavanineresistant mutants (CanR) mutation rate in cells is indicative of the level of DNA damage, which itself follows the variations of ROS concentration
The CanR mutation rate of the tsa1D strain decreased substantially under anaerobiosis and was the same as the CanR mutation rate of the wild-type strain. This observation supports the view that scavenging intracellular H2O2 is one of the major cellular functions of Tsa1 that protects the nuclear genome from damage by ROS. These results suggest that ROS in tsa1D mutant grown under aerobic conditions is a major source of DNA damage underlying the formation of CanR mutations
Summary
Reactive oxygen species (ROS) are formed in all oxygenconsuming organisms. ROS can attack almost all cell components and can induce many types of DNA damage that can cause mutations and genome rearrangements. Yeasts like Saccharomyces cerevisiae, and other aerobic organisms, have acquired a wide array of mechanisms, including pathways that repair the ROSinduced DNA damage, to prevent the deleterious effects of ROS [1]. Two main redox systems are involved in reducing the level of ROS, the glutathione (GSH) and thioredoxin (Trx) pathways. The GSH pathway involving glutaredoxins is thought to provide a redox buffering function and GSH is the reductant of the glutaredoxins. Two transcription factors are mainly involved: Yap and Skn, which function in part cooperatively in the peroxide response [8]. Yap is the main regulator that controls the expression of S. cerevisiae genes encoding most antioxidants, components of glutathione and carbohydrate metabolism, and components of different metal and drug response pathways [8,9,10]
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