The yeast Saccharomyces cerevisiae contains two glutaredoxins, encoded by GRX1 and GRX2, which are active as glutathione-dependent oxidoreductases. Our studies show that changes in the levels of glutaredoxins affect the resistance of yeast cells to oxidative stress induced by hydroperoxides. Elevating the gene dosage of GRX1 or GRX2 increases resistance to hydroperoxides including hydrogen peroxide, tert-butyl hydroperoxide and cumene hydroperoxide. The glutaredoxin-mediated resistance to hydroperoxides is dependent on the presence of an intact glutathione system, but does not require the activity of phospholipid hydroperoxide glutathione peroxidases (GPX1-3). Rather, the mechanism appears to be mediated via glutathione conjugation and removal from the cell because it is absent in strains lacking glutathione-S-transferases (GTT1, GTT2) or the GS-X pump (YCF1). We show that the yeast glutaredoxins can directly reduce hydroperoxides in a catalytic manner, using reducing power provided by NADPH, GSH, and glutathione reductase. With cumene hydroperoxide, high pressure liquid chromatography analysis confirmed the formation of the corresponding cumyl alcohol. We propose a model in which the glutathione peroxidase activity of glutaredoxins converts hydroperoxides to their corresponding alcohols; these can then be conjugated to GSH by glutathione-S-transferases and transported into the vacuole by Ycf1.All aerobic organisms are exposed to reactive oxygen species (ROS), 1 such as H 2 O 2 , the superoxide anion, and the hydroxyl radical during the course of normal aerobic metabolism or following exposure to radical-generating compounds. These ROS can cause wide-ranging damage to cells, and an oxidative stress is said to occur when the cellular survival mechanisms are unable to cope with the ROS or the damage they cause (1). Oxidative damage is associated with various diseases such as cancer, vascular, and neurodegenerative disorders, as well as with aging processes (2-4). To protect against damage, cells contain a number of defense mechanisms including enzymes, such as catalase, superoxide dismutase, glutathione peroxidase, and low molecular weight antioxidants such as glutathione (GSH) and vitamins C and E (5, 6). Recent studies have highlighted the key role played by sulfhydryl groups (-SH) in the response to oxidative stress, and in particular, the roles of the GSH/glutaredoxin and thioredoxin systems, which maintain the redox homeostasis of the cell (7-10). In this present study, we examine the role of yeast glutaredoxins in protection against hydroperoxides.Glutaredoxins are small heat-stable oxidoreductases, first discovered in Escherichia coli as GSH-dependent hydrogen donors for ribonucleotide reductase (11). They form part of the glutaredoxin system, comprising NADPH, GSH, and glutathione reductase, which transfers electrons from NADPH to glutaredoxins via GSH (12). The yeast Saccharomyces cerevisiae contains two glutaredoxins, designated Grx1 and Grx2, which share 40 -52% identity and 61-76% similarity with those...
The yeast Saccharomyces cerevisiae contains two glutaredoxins, encoded by GRX1 and GRX2, that are required for resistance to reactive oxygen species. We recently reported that Grx1 is active as a glutathione peroxidase and can directly reduce hydroperoxides (Collinson, E. J., Wheeler, G. L., Garrido, E. O., Avery, A. M., Avery, S. V., and Grant, C. M. (2002) J. Biol. Chem. 277, 16712-16717). We now show that Grx2 is also a general hydroperoxidase, and kinetic data indicate that both enzymes have a similar pattern of activity, which is highest with hydrogen peroxide, followed by cumene hydroperoxide and tert-butyl hydroperoxide. Furthermore, both Grx1 and Grx2 are shown be active as glutathione S-transferases (GSTs), and their activity with model substrates such as 1-chloro-2,4-dinitrobenzene is similar to their activity with hydroperoxides. Analysis of the Grx1 active site residues shows that Cys-27, but not Cys-30, is required for both the peroxidase and transferase activities, indicating that these reactions proceed via a monothiol mechanism. Deletion analysis shows that Grx1 and Grx2 have an overlapping function with yeast GSTs, encoded by GTT1 and GTT2, and are responsible for the majority of cellular GST activity. In addition, multiple mutants lacking GRX1, GRX2, GTT1, and GTT2 show increased sensitivity to stress conditions, including exposure to xenobiotics, heat, and oxidants. In summary, glutaredoxins are multifunctional enzymes with oxidoreductase, peroxidase, and GST activity, and are therefore ideally suited to detoxify the wide range of xenobiotics and oxidants that can be generated during diverse stress conditions.
Acrolein is a ubiquitous reactive aldehyde which is formed as a product of lipid peroxidation in biological systems. In this present study, we screened the complete set of viable deletion strains in Saccharomyces cerevisiae for sensitivity to acrolein to identify cell functions involved in resistance to reactive aldehydes. We identified 128 mutants whose gene products are localized throughout the cell. Acrolein-sensitive mutants were distributed among most major biological processes but particularly affected gene expression, metabolism, and cellular signaling. Surprisingly, the screen did not identify any antioxidants or similar stress-protective molecules, indicating that acrolein toxicity may not be mediated via reactive oxygen species. Most strikingly, a mutant lacking an old yellow enzyme (OYE2) was identified as being acrolein sensitive. Old yellow enzymes are known to reduce ␣,-unsaturated carbonyl compounds in vitro, but their physiological roles have remained uncertain. We show that mutants lacking OYE2, but not OYE3, are sensitive to acrolein, and overexpression of both isoenzymes increases acrolein tolerance. Our data indicate that OYE2 is required for basal levels of tolerance, whereas OYE3 expression is particularly induced following acrolein stress. Despite the range of ␣,-unsaturated carbonyl compounds that have been identified as substrates of old yellow enzymes in vitro, we show that old yellow enzymes specifically mediate resistance to small ␣,-unsaturated carbonyl compounds, such as acrolein, in vivo.
In mammalian cells, heme is degraded by heme oxygenase to biliverdin, which is then reduced to bilirubin by biliverdin reductase (BVR). Both bile pigments have reducing properties, and bilirubin is now generally considered to be a potent antioxidant, yet it remains unclear how it protects cells against oxidative damage. A presently popular explanation for the antioxidant function of bilirubin is a redox cycle in which bilirubin is oxidized to biliverdin and then recycled by BVR. Here, we reexamined this putative BVR-mediated redox cycle. We observed that lipid peroxidation-mediated oxidation of bilirubin in chloroform, a model of cell membrane-bound bilirubin, did not yield biliverdin, a prerequisite for the putative redox cycle. Similarly, H 2 O 2 did not oxidize albumin-bound bilirubin to biliverdin, and in vitro oxidation of albumin or ligandin-bound bilirubin by peroxyl radicals gave modest yields of biliverdin. In addition, decreasing cellular BVR protein and activity in HeLa cells using RNA interference did not alter H 2 O 2 -mediated cell death, just as BVR overexpression failed to enhance protection of these cells against H 2 O 2 -mediated damage, irrespective of whether bilirubin or biliverdin were added to the cells as substrate for the putative redox cycle. Similarly, transformation of human BVR into hmx1 (heme oxygenase) mutant yeast did not provide protection against H 2 O 2 toxicity above that seen in hmx1 mutant yeast expressing human heme oxygenase-1. Together, these results argue against the BVR-mediated redox cycle playing a general or important role as cellular antioxidant defense mechanism.
Rom2p, the Rho1 GTP/GDP Exchange Factor of Saccharomyces cerevisiae, Can Mediate Stress Responses via the Ras-cAMP Pathway
The Ras-cyclic AMP pathway is connected to other nutrient-regulated signaling pathways and mediates the global stress responses of Saccharomyces cerevisiae. Here, we show that Rom2p, the Rho1 GTP/GDP exchange factor, can mediate stress responses and cell growth via the Ras-cAMP pathways. ROM2 was isolated as a suppresser of heat and NaCl sensitivity caused by the lack of the Ras-GTPase activator Ira2p or of cAMP phosphodiesterases. Subsequent analysis of strains with a rom2 deletion showed that Rom2p is essential for resistance to a variety of stresses caused by freeze-thawing, oxidants, cycloheximide, NaCl, or cobalt ions. Stress sensitivity and the growth defect caused by the rom2 deletion could be suppressed by depleting Ras or protein kinase A (PKA) activity or by overexpressing the high affinity cAMP phosphodiesterase Pde2p. In addition, overexpression of ROM2 could not rescue cells lacking the regulatory subunit of PKA, indicating that the Ras-adenylate, cyclase-PKA cascade is essential for Rom2p-mediated stress responses and cell growth. Deletion of IRA2 exacerbated the freeze-thaw sensitivity and growth defect of the rom2 mutant, indicating that Rom2p signaling may control Ras independently of IRA2. Increases in cAMP levels were detected in the rom2 deletion mutants, and these were comparable with the effects of an ira2 mutation. The effects of the deletion of ROM2 on sensitivity to hydrogen peroxide, paraquat, and cobalt ions, but not to caffeine, were reduced when a constitutive allele of RHO1 was introduced on a single copy plasmid. However, the effects of the deletion of ROM2 on sensitivity to diamide and NaCl were exacerbated. Taken together, our data indicate that Rom2p can regulate PKA activity by controlling cAMP levels via the Ras-cAMP pathway and that for those stresses related to oxidative stress, this cross-talk is probably mediated via the Rho1p-activated MAPK pathway.The ability of cells to appropriately respond to alterations in environment is essential for the survival of stress situations, and processes for stress sensing and the subsequent modulation of cell physiology require the involvement of signal transduction pathways. The Ras-cyclic AMP pathway is an essential nutrient-sensing pathway in yeast (1, 2) and is also important for stress tolerance of Saccharomyces cerevisiae. This pathway is involved in cellular responses to stresses mediated via genes with stress response elements in their promoters (3-7), Pos9/ Skn7-mediated oxidative stress (8), high-salt stress (9, 10), and freezing and thawing (11,12).Ras proteins in yeast (encoded by RAS1 and RAS2) are associated with adenylate cyclase (encoded by CYR1/CDC35) to control cAMP synthesis. cAMP functions exclusively through the cAMP-dependent protein kinase A (PKA) 1 (13,14), which can phosphorylate various target proteins involved in transcription, energy metabolism, cell cycle progression, and the accumulation of glycogen and trehalose (4,(15)(16)(17)(18)(19)(20)(21)(22). PKA is a heterotetramer of two regulatory subunits encoded ...
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