Characterization of a glutathione metabolic mutant of Mycobacterium tuberculosis and its resistance to glutathione and nitrosoglutathione

Glutathione is a tripeptide and antioxidant, synthesized at high levels by cells during the production of reactive oxygen and nitrogen intermediates. Glutathione also serves as a carrier molecule for nitric oxide in the form of S-nitrosoglutathione. Previous studies from this laboratory have shown that glutathione and S-nitrosoglutathione are directly toxic to mycobacteria. Glutathione is not transported into the cells as a tripeptide. Extracellular glutathione is converted to a dipeptide due to the action of transpeptidase, and the dipeptide is then transported into the bacterial cells. The processing of glutathione and S-nitrosoglutathione is brought about by the action of the enzyme gamma-glutamyl transpeptidase. The function of gamma-glutamyl transpeptidase is to cleave glutathione and S-nitrosoglutathione to the dipeptide (Cys-Gly), which is then transported into the bacterium by the multicomponent ABC transporter dipeptide permease. We have created a mutant strain of Mycobacterium tuberculosis lacking this metabolic enzyme. We investigated the sensitivity of this strain to glutathione and S-nitrosoglutathione compared to that of the wild-type bacteria. In addition, we examined the role of glutathione and/or S-nitrosoglutathione in controlling the growth of intracellular M. tuberculosis inside mouse macrophages.     

Glutathione monoethyl ester: preparation, uptake by tissues, and conversion to glutathione

Glutathione monoethyl ester (L-gamma-glutamyl-L-cysteinylglycyl ethyl ester), in contrast to glutathione itself, is effectively transported into many types of cells. The ester is converted intracellularly into glutathione. Intraperitoneal injection of 35S-labeled ester into mice was followed by rapid appearance of isotope in the glutathione of liver, kidney, spleen, pancreas, and heart; the glutathione levels of these tissues also increased. Oral administration of the ester to mice also increased cellular glutathione levels. Relatively little extracellular deesterification was found. Transport of glutathione ester into human erythrocytes and intracellular conversion to glutathione was observed. The findings suggest that the glutathione ester will be useful as a radioprotecting agent and in the prevention and treatment of toxicity due to certain foreign compounds and oxygen. The ester may be useful in experimental work on glutathione transport, metabolism, and function, and in related studies on oxygen toxicity, radiation, mutagenesis, and ageing. Methods for the preparation of glutathione monoethyl ester and several related compounds are given.     

Export pumps for glutathione S-conjugates

The release of glutathione S-conjugates from cells is an ATP-dependent process mediated by integral membrane glycoproteins belonging to the recently discovered multidrug-resistance protein (MRP) family. Many lipophilic compounds conjugated with glutathione, glucuronate, or sulfate are substrates for export pumps of the MRP family. In humans six MRP isoforms encoded by different genes have been cloned. Orthologs of MRP have been identified in many species including yeast, plants, and nematodes. Human MRP1 and MRP2 are currently best characterized with respect to substrate specificity by measurements of ATP-dependent transport into inside-out membrane vesicles. High-affinity substrates include the glutathione S-conjugate leukotriene C4, S-(2,4dinitrophenyl)glutathione, bilirubin glucuronosides, and 17beta-glucuronosyl estradiol. In addition, glutathione disulfide is transported by MRP1 and MRP2. Reduced glutathione may be released from cells in a process directly or indirectly mediated by members of the MRP family. Proteins of the MRP family are indispensable for transport of glutathione S-conjugates and glutathione disulfide into the extracellular space and play, therefore, a decisive role in detoxification and defense against oxidative stress.     

Metabolism of glutamine and glutathione via gamma-glutamyltranspeptidase and glutamate transport in Helicobacter pylori: possible significance in the pathophysiology of the organism

gamma-Glutamyltranspeptidase (GGT) is a periplasmic enzyme of Helicobacter pylori implicated in its pathogenesis towards mammalian cells. We have cloned and expressed the H. pylori strain 26695 recombinant GGT protein in Escherichia coli and purified it to homogeneity. The purified protein exhibited hydrolysis activity with very high affinities for glutamine and glutathione shown by apparent K(m) values lower than 1 muM. H. pylori cells were unable to take up extracellular glutamine and glutathione directly. Instead, these substances were hydrolysed to glutamate by the action of GGT outside the cells. The glutamate produced was then transported by a Na(+)-dependent reaction into H. pylori cells, where it was mainly incorporated into the TCA cycle and partially utilized as a substrate for glutamine synthesis. These observations show that one of the principle physiological functions of H. pylori GGT is to enable H. pylori cells to utilize extracellular glutamine and glutathione as a source of glutamate. As glutamine and glutathione are important nutrients for maintenance of healthy gastrointestinal tissue, their depletion by the GGT enzyme is hypothesized to account for the damaging of mammalian cells and the pathophysiology of H. pylori.     

Glutathione, a first line of defense against cadmium toxicity

Experimental modulation of cellular glutathione levels has been used to explore the role of glutathione in cadmium toxicity. Mice treated with buthionine sulfoximine [an effective irreversible inhibitor of gamma-glutamylcysteine synthetase (EC 6.3.2.2) that decreases cellular levels of glutathione markedly] were sensitized to the toxic effects of CdCl2. Mice pretreated with a sublethal dose of Cd2+ to induce metallothionein synthesis were not sensitized to Cd2+ by buthionine sulfoximine. Mice sensitized to Cd2+ by buthionine sulfoximine were protected against a lethal dose of Cd2+ by glutathione mono isopropyl ester (L-gamma-glutamyl-L-cysteinylglycylisopropyl ester), but not by glutathione. These results are in accord with studies that showed that glutathione mono esters (in contrast to glutathione) are efficiently transported into cells and converted intracellularly to glutathione. The findings indicate that intracellular glutathione functions in protection against Cd2+ toxicity, and that this tripeptide provides a first line of defense against Cd2+ before induction of metallothionein synthesis occurs. The experimental approach used here in which cellular levels of glutathione are decreased or increased seems applicable to investigation of other types of metal toxicity and of other glutathione-dependent biological phenomena.     

Protection against cisplatin toxicity by administration of glutathione ester

The role of cellular glutathione in the prevention of toxicity due to the anti-cancer drug cisplatin (cis-diamminedichloroplatinum) was explored in mice treated with buthionine sulfoximine (BSO), a selective inhibitor of gamma-glutamylcysteine synthetase (and therefore of glutathione synthesis), and with glutathione and glutathione monoisopropyl ester. Pretreatment of mice with BSO enhanced the lethal toxicity of cisplatin by about twofold. Administration of glutathione ester (dose, 2.5-7.5 mmol/kg) protected against lethal cisplatin toxicity; glutathione was also effective, but much less so. Glutathione ester, in contrast to glutathione, is effectively transported into cells and split to glutathione intracellularly. The previous findings that administered glutathione does not protect against lethal toxicity due to cadmium ions and mercuric ions, whereas glutathione ester does, suggest that intracellular glutathione is required for protection against these heavy metal ions. That administration of glutathione has a protective effect on cisplatin toxicity suggests that the toxic effects of cisplatin may be exerted both intracellularly and extracellularly, and that extracellular glutathione (or its degradation products) may form a complex with cisplatin extracellularly. The finding that glutathione ester is more effective than glutathione in protecting against the toxicity of cisplatin suggests that use of glutathione ester may be therapeutically advantageous.     

Oxidative stresses induced the cystine transport activity in human erythrocytes

Cystine was transported into human erythrocytes in the presence of tertiary-butyl hydroperoxide (t-BH) or 1-chloro-2,4-dinitrobenzene (CDNB). The transport rate of cystine was dependent on the extracellular concentration of t-BH or CDNB, and on the incubation time. According to Dowex-1 column chromatography, the transported cystine was incorporated into fractions of glutathione disulfide (GSSG) and glutathione-S (GSH-S) conjugate. The transport of cystine was competitively inhibited by DL-homocystine and alanine. The inhibition rates by DL-homocystine and alanine were 75% and 68%, with similar Ki values of 0.7 mM and 0.6 mM, respectively. It is suggested that cystine transport is induced for glutathione synthesis when human erythrocytes are exposed to oxidative stresses. This transport system of cystine may serve as an emergency function in human erythrocytes.     

Gliotoxins disrupt alanine metabolism and glutathione production in C6 glioma cells: a 13C NMR spectroscopic study

Gliotoxins are a group of amino acids that are toxic to astrocytes, and are substrates of high-affinity sodium-dependent glutamate transporters. In the present study, C6 glioma cells were preincubated for 20 h in the presence of 400 μM L--aminoadipate, L-serine-O-sulphate, D-aspartate or L-cysteate, as well as in the presence of the poorly transported L-glutamate uptake inhibitor, L-anti-endo-methanopyrrolidine dicarboxylate. In experiments following [3-¹³C]alanine metabolism, all toxins caused a decreased incorporation of label into glutamate. Production of labelled lactate changed only when cells were incubated in the presence of L--aminoadipate or L-serine-O-sulphate. Incubation with L-anti-endo-methanopyrrolidine dicarboxylate caused no change in the amount of label incorporated into either glutamate or lactate. When glutathione production was followed using 1 mM [2-¹³C]glycine, differential effects of the gliotoxins were revealed. Most notably, both L-serine-O-sulphate and L--aminoadipate caused significant increases in labelling of glutathione. Once again, L-anti-endo-methanopyrrolidine dicarboxylate was without effect. Overall, we have shown that the gliotoxins cause disruption to alanine metabolism and glutathione production in C6 glioma cells, but that there are notable differences in their mechanisms of action. In the absence of any disruption to metabolism by L-anti-endo-methanopyrrolidine dicarboxylate, it is concluded that their mode of action involves more than inhibition of glutamate transport.     

Biochemical mechanisms of cephaloridine nephrotoxicity

Large doses of the cephalosporin antibiotic, cephaloridine, produce acute proximal tubular necrosis in humans and in laboratory animals. Cephaloridine is actively transported into the proximal tubular cell by an organic anion transport system while transport across the lumenal membrane into tubular fluid appears restricted. High intracellular concentrations of cephaloridine are attained in the proximal tubular cell which are critical to the development of nephrotoxicity. There is substantial evidence indicating that oxidative stress plays a major role in cephaloridine nephrotoxicity. Cephaloridine depletes reduced glutathione, increases oxidized glutathione and induces lipid peroxidation in renal cortical tissue. The molecular mechanisms mediating cephaloridine-induced oxidative stress are not well understood. Inhibition in gluconeogenesis is a relatively early biochemical effect of cephaloridine and is independent of lipid peroxidation. Furthermore, cephaloridine inhibits gluconeogenesis in both target (kidney) and non-target (liver) organs of cephaloridine toxicity. Since glucose is not a major fuel of proximal tubular cells, it is unlikely that cephaloridine-induced tubular necrosis is mediated by the effects of this drug on glucose synthesis.     

Apd1(+), a Gene Required for Red Pigment Formation in Ade6 Mutants of Schizosaccharomyces Pombe, Encodes an Enzyme Required for Glutathione Biosynthesis: A Role for Glutathione and a Glutathione-Conjugate Pump

Mutants in the adenine biosynthetic pathway of yeasts (ade1 and ade2 of Saccharomyces cerevisiae, ade6 and ade7 of Schizosaccharomyces pombe) accumulate an intense red pigment in their vacuoles when grown under adenine-limiting conditions. The precise events that determine the formation of the pigment are however, still unknown. We have begun a genetic investigation into the nature and cause of pigmentation of ade6 mutants of S. pombe and have discovered that one of these pigmentation defective mutants, apd1 (adenine pigmentation defective), is a strict glutathione auxotroph. The gene apd1(+) was found to encode the first enzyme in glutathione biosynthesis, γ-glutamylcysteine synthetase, gcs1(+). This gene when expressed in the mutant could confer both glutathione prototrophy and the characteristic red pigmentation, and disruption of the gene led to a loss in both phenotypes. Supplementation of glutathione in the medium, however, could only restore growth but not the pigmentation because the cells were unable to achieve sufficient intracellular levels of glutathione. Disruption of the second enzyme in glutathione biosynthesis, glutathione synthetase, gsh2(+), also led to glutathione auxotrophy, but only a partial defect in pigment formation. A reevaluation of the major amino acids previously reported to be present in the pigment indicated that the pigment is probably a glutathione conjugate. The ability of vanadate to inhibit pigment formation indicated that the conjugate was transported into the vacuole through a glutathione-conjugate pump. This was further confirmed using strains of S. cerevisiae bearing disruptions in the recently identified glutathione-conjugate pump, YCF1, where a significant reduction in pigment formation was observed. The pump of S. pombe is distinct from the previously identified vacuolar pump, hmt1p, for transporting cadystin peptides into vacuoles of S. pombe.     

Production of SH compounds in higher plants of different tolerance to Cd

The roots of six plant species, in three families, were exposed to 0, 3 and 9 M CdCl₂ for three days. The tops and roots were analyzed for total Cd. The roots were extracted with tris buffer at pH 7.2 and the extracts were analyzed for Cd and were also extracted with HAc-EDTA buffer and the extracts were analyzed for Cd, glutathione and SH compounds other than glutathione (SH-G). After exposure to Cd, the concentration of SH-G was highest in cucurbits, medium in grasses and lowest in legumes. Cd extracted from the roots at pH 7.2 increased with Cd treatment and correlated with SH-G in all families. This suggests that the Cd incorporated into the cells was detoxified by SH compounds produced in proportion to the degree of Cd incorporation. This may be one mechanism for tolerance in plants which accumulate Cd.The percentages of Cd transported from roots to tops were highest in cucurbits and lower in grasses and legumes. Cd incorporated into the root cells (symplast), was transported to top through apoplast.     

Investigations of S-transnitrosylation reactions between low- and high-molecular-weight S-nitroso compounds and their thiols by high-performance liquid chromatography and gas chromatography-mass spectrometry.

S-Transnitrosylation reactions are supposed to be the basic principle by which nitric oxide-related biological activities are regulated in vivo. Mechanisms of S-transnitrosylation reactions are poorly understood and equilibria constants for physiological S-nitroso compounds and thiols are rare. In the present study we investigated S-transnitrosylation reactions of the thiols homocysteine, cysteine, glutathione, N-acetylcysteine, N-acetylpenicillamine, and human plasma albumin and their corresponding S-nitroso compounds SNhC, SNC, GSNO, SNAC, SNAP, and SNALB utilizing high-performance liquid chromatographic and gas chromatographic-mass spectrometric techniques. These methods allowed to study S-transnitrosylation reactions in mixtures of several S-nitroso compound/thiol pairs, to determine equilibria constants, and to elucidate the mechanism of S-transnitrosylation reactions. We obtained the following order for the equilibria constants in aqueous buffered solution at pH 7.4: SNhC approximately SNAC > GSNO approximately SNALB > SNAP > SNC. Our results suggest that the mechanism of S-transnitrosylation reactions of these S-nitroso compounds and their thiols involve heterolytic cleavage of the S&sbond;N bond. Incubation of SNC with human red blood cells resulted in a dose-dependent formation of GSNO in the cytosol through S-transnitrosylation of intracellular GSH by the SNC transported into the cells. This reaction was accompanied with an almost complete disappearance of the SNC fraction transported into the cells. This finding is in full agreement with the equilibrium constant Keq of 1.9 for the reaction SNC + GSH <--> Cys + GSNO in aqueous buffer.     

The yeast glutaredoxins are active as glutathione peroxidases

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.     

Bcl-2 is a novel interacting partner for the 2-oxoglutarate carrier and a key regulator of mitochondrial glutathione

Despite making up only a minor fraction of the total cellular glutathione, recent studies indicate that the mitochondrial glutathione pool is essential for cell survival. Selective depletion of mitochondrial glutathione is sufficient to sensitize cells to mitochondrial oxidative stress (MOS) and intrinsic apoptosis. Glutathione is synthesized exclusively in the cytoplasm and must be actively transported into mitochondria. Therefore, regulation of mitochondrial glutathione transport is a key factor in maintaining the antioxidant status of mitochondria. Bcl-2 resides in the outer mitochondrial membrane where it acts as a central regulator of the intrinsic apoptotic cascade. In addition, Bcl-2 displays an antioxidant-like function that has been linked experimentally to the regulation of cellular glutathione content. We have previously demonstrated a novel interaction between recombinant Bcl-2 and reduced glutathione (GSH), which was antagonized by either Bcl-2 homology-3 domain (BH3) mimetics or a BH3-only protein, recombinant Bim. These previous findings prompted us to investigate if this novel Bcl-2/GSH interaction might play a role in regulating mitochondrial glutathione transport. Incubation of primary cultures of cerebellar granule neurons (CGNs) with the BH3 mimetic HA14-1 induced MOS and caused specific depletion of the mitochondrial glutathione pool. Bcl-2 was coimmunoprecipitated with GSH after chemical cross-linking in CGNs and this Bcl-2/GSH interaction was antagonized by preincubation with HA14-1. Moreover, both HA14-1 and recombinant Bim inhibited GSH transport into isolated rat brain mitochondria. To further investigate a possible link between Bcl-2 function and mitochondrial glutathione transport, we next examined if Bcl-2 associated with the 2-oxoglutarate carrier (OGC), an inner mitochondrial membrane protein known to transport glutathione in liver and kidney. After cotransfection of CHO cells, Bcl-2 was coimmunoprecipitated with OGC and this novel interaction was significantly enhanced by glutathione monoethyl ester. Similarly, recombinant Bcl-2 interacted with recombinant OGC in the presence of GSH. Bcl-2 and OGC cotransfection in CHO cells significantly increased the mitochondrial glutathione pool. Finally, the ability of Bcl-2 to protect CHO cells from apoptosis induced by hydrogen peroxide was significantly attenuated by the OGC inhibitor phenylsuccinate. These data suggest that GSH binding by Bcl-2 enhances its affinity for the OGC. Bcl-2 and OGC appear to act in a coordinated manner to increase the mitochondrial glutathione pool and enhance resistance of cells to oxidative stress. We conclude that regulation of mitochondrial glutathione transport is a principal mechanism by which Bcl-2 suppresses MOS.     

Glutathione metabolism at the blood-cerebrospinal fluid barrier

Glutathione metabolism and transport in the choroid plexus were probed by determining the effects of administration to rats of several compounds (buthionine sulfoximine, L-2-oxothiazolidine-4-carboxylate, L-(alpha 5,5S)-alpha-amino-3-chloro-4,5-dihydro-5-isoxazole acetic acid, gamma-glutamyl alanine, and glutathione monoethyl ester) on the levels of glutathione and cysteine in the cerebrospinal fluid. The findings indicate that glutathione is actively metabolized in the choroid plexus by pathways similar to those in kidney and other tissues. The level of glutathione in the cerebrospinal fluid can be decreased or increased by giving compounds that do not, under similar conditions, appreciably alter total brain levels of glutathione. Glutathione monoethyl ester is effectively transported into the cerebrospinal fluid.     

gamma-Glutamyl transpeptidase in rat ascites tumor cell LY-5. Lack of functional correlation of its catalytic activity with the amino acid transport.

gamma-Glutamyl transpeptidase activity was detected in rat ascites tumor cells (LY-5) suspended in Hanks' balanced saline solution using L-gamma-glutamyl-p-nitroanilide as a substrate. Whole-cell suspension of the tumor cells exhibited full activity of the enzyme without detectable cell disruption under the conditions examined. Various amino acids, transported through specific membrane carriers, did not affect the accessibility of substrate for the enzyme. An inhibitor of sodium-dependent transport systems of amino acids caused no significant change in the rate of enzyme catalysis. Like glutathione or S-methylglutathione, S-acetyldextran (mol. wt 215000) derivative of glutathione, which is believed to be unable to penetrate into intact cells, caused marked inhibition of the rate of p-nitroaniline release from the synthetic substrate by the tumor cells. These data indicated that the active site of the enzyme faced to the outer surface of the cells. gamma-Glutamyl transpeptidase of the tumor cells was successfully affinity-labeled by 6-diazo-5-oxo-L-norleucine, a glutamine analog, without causing detectable change in the viability of the cells under the conditions examined. The rate of transport of alanine, leucine, glycine and glutamine into cells was not affected by the inactivation of this enzyme with the affinity label. Thus, the activity of gamma-glutamyl transpeptidase located on the outer surface of tumor cell membrane does not seem to be requisite for the transport process of amino acids.     

Detoxification of xenobiotics in plant cells by glutathione conjugation and vacuolar compartmentalization: a fluorescent assay using monochlorobimane

Monochlorobimane (BmCl), a non-fluorescent cell-per-meant compound that reacts with glutathione to yield a strong blue fluorescent conjugate bimane-glutathione (Bm-SG), was used to trace the glutathione-dependent detoxification of xenobiotics in plant cells and protoplasts. In BmCl-labelled cells and protoplasts, fluorescence developed rapidly and was quickly concentrated in the vacuole. The rate of fluorescence development was dependent on the concentration of BmCl and the only metabolite formed was the conjugate Bm-SG. The formation of Bm-SG was correlated with a decrease in the amount of intracellular GSH. Compounds which reduced the intracellular levels of GSH severely reduced the formation of Bm-SG. Bm-SG was shown to be transported into isolated vacuoles by an ATP-dependent vana-date-sensitive mechanism. Kinetic analysis of cellular Bm-SG formation implicated both spontaneous conjugation and enzyme catalysis. Our results demonstrate a cellular pathway for xenobiotic detoxification in plants, starting with conjugation to glutathione in the cytoplasm, followed by the transport of the conjugates into the vacuole. This pathway is used to counter the toxic effects of some herbicides and environmental pollutants and overlaps with or parallels the pathway used for the biosynthesis of anthocyanins.     

A Conserved Mitochondrial ATP-binding Cassette Transporter Exports Glutathione Polysulfide for Cytosolic Metal Cofactor Assembly

An ATP-binding cassette transporter located in the inner mitochondrial membrane is involved in iron-sulfur cluster and molybdenum cofactor assembly in the cytosol, but the transported substrate is unknown. ATM3 (ABCB25) from Arabidopsis thaliana and its functional orthologue Atm1 from Saccharomyces cerevisiae were expressed in Lactococcus lactis and studied in inside-out membrane vesicles and in purified form. Both proteins selectively transported glutathione disulfide (GSSG) but not reduced glutathione in agreement with a 3-fold stimulation of ATPase activity by GSSG. By contrast, Fe²⁺ alone or in combination with glutathione did not stimulate ATPase activity. Arabidopsis atm3 mutants were hypersensitive to an inhibitor of glutathione biosynthesis and accumulated GSSG in the mitochondria. The growth phenotype of atm3-1 was strongly enhanced by depletion of the mitochondrion-localized, GSH-dependent persulfide oxygenase ETHE1, suggesting that the physiological substrate of ATM3 contains persulfide in addition to glutathione. Consistent with this idea, a transportomics approach using mass spectrometry showed that glutathione trisulfide (GS-S-SG) was transported by Atm1. We propose that mitochondria export glutathione polysulfide, containing glutathione and persulfide, for iron-sulfur cluster assembly in the cytosol.     

Toward a new role for plasma membrane sodium-dependent glutamate transporters of astrocytes: maintenance of antioxidant defenses beyond extracellular glutamate clearance

The primary function assigned to the sodium-dependent glutamate transporters, also known as excitatory amino acid transporters (EAATs), is to maintain the extracellular glutamate concentration in the low micromolar range, allowing glutamate to be used as a signaling molecule in the brain and preventing its cytotoxic effects. However, glutamate and cyst(e)ine, that is also a substrate of EAATs, are also important metabolites used for instance in the synthesis of the main antioxidant glutathione. This review describes the evidence suggesting that EAATs, by providing glutathione precursors, are crucial to prevent oxidative death in particular cells of the nervous system while being dispensable in others. This differential importance may depend on the way antioxidant defenses are maintained in each cell type and on the metabolic fate of transported substrates, both being probably controlled by EAAT interacting proteins. As oxidative stress invariably contributes to various forms of cell death, a better understanding of how antioxidant defenses are maintained in particular brain cells will probably help to develop protective strategies in degenerative insults specifically affecting these cells.     

Selenodiglutathione uptake by the Saccharomyces cerevisiae vacuolar ATP-binding cassette transporter Ycf1p

The Saccharomyces cerevisiae vacuolar ATP-binding cassette transporter Ycf1p is involved in heavy metal detoxification by mediating the ATP-dependent transport of glutathione-metal conjugates to the vacuole. In the case of selenite toxicity, deletion of YCF1 was shown to confer increased resistance, rather than sensitivity, to selenite exposure [Pinson B, Sagot I & Daignan-Fornier B (2000) Mol Microbiol36, 679-687]. Here, we show that when Ycf1p is expressed from a multicopy plasmid, the toxicity of selenite is exacerbated. Using secretory vesicles isolated from a sec6-4 mutant transformed either with the plasmid harbouring YCF1 or the control plasmid, we establish that the glutathione-conjugate selenodigluthatione is a high-affinity substrate of this ATP-binding cassette transporter and that oxidized glutathione is also efficiently transported. Finally, we show that the presence of Ycf1p impairs the glutathione/oxidized glutathione ratio of cells subjected to a selenite stress. Possible mechanisms by which Ycf1p-mediated vacuolar uptake of selenodiglutathione and oxidized glutathione enhances selenite toxicity are discussed.