Protein thiyl radical mediates S-glutathionylation of complex I

Complex I is a critical site of O(2)(?-) production and the major host of reactive protein thiols in mitochondria. In response to oxidative stress, complex I protein thiols at the 51- and 75-kDa subunits are reversibly S-glutathionylated. The mechanism of complex I S-glutathionylation is mainly obtained from insight into GSSG-mediated thiol-disulfide exchange, which would require a dramatic decline in the GSH/GSSG ratio. Intrinsic complex I S-glutathionylation can be detected in the rat heart at a relatively high GSH/GSSG ratio (J. Chen et al., J. Biol. Chem. 285:3168-3180, 2010). Thus, we hypothesized that reactive thiyl radical is more likely to mediate protein S-glutathionylation of complex I. Here we employed immuno-spin trapping and tandem mass spectrometry (LC/MS/MS) to test the hypothesis in the 75-kDa subunit from S-glutathionylated complex I. Under the conditions of O(2)(?-) production in the presence of GSH, we detected complex I S-glutathionylation at Cys-226, Cys-367, and Cys-727 of the 75-kDa subunit. Addition of a radical trap, 5,5-dimethyl-1-pyrroline N-oxide (DMPO), significantly decreased complex I S-glutathionylation and subsequently increased the protein radical adduct of complex I-DMPO as detected by immunoblotting using an anti-DMPO antibody. LC/MS/MS analysis indicated that Cys-226, Cys-554, and Cys-727 were involved in DMPO binding, confirming that formation of the complex I thiyl radical mediates S-glutathionylation. LC/MS/MS analysis also showed that Cys-554 and Cys-727 were S-sulfonated under conditions of O(2)(?-) generation in the absence of DMPO. In myocytes (HL-1 cell line) treated with menadione to trigger mitochondrial O(2)(?-) generation, complex I protein radical and S-glutathionylation were increased. Thus mediation of complex I S-glutathionylation by the protein thiyl radical provides a unique pathway for the redox regulation of mitochondrial function.     

Regulation of mitochondrial glutathione redox status and protein glutathionylation by respiratory substrates

Brain and liver mitochondria isolated by a discontinuous Percoll gradient show an oxidized redox environment, which is reflected by low GSH levels and high GSSG levels and significant glutathionylation of mitochondrial proteins as well as by low NAD(P)H/NAD(P) values. The redox potential of brain mitochondria isolated by a discontinuous Percoll gradient method was calculated to be -171 mV based on GSH and GSSG concentrations. Immunoblotting and LC/MS/MS analysis revealed that succinyl-CoA transferase and ATP synthase (F(1) complex, α-subunit) were extensively glutathionylated; S-glutathionylation of these proteins resulted in a substantial decrease of activity. Supplementation of mitochondria with complex I or complex II respiratory substrates (malate/glutamate or succinate, respectively) increased NADH and NADPH levels, resulting in the restoration of GSH levels through reduction of GSSG and deglutathionylation of mitochondrial proteins. Under these conditions, the redox potential of brain mitochondria was calculated to be -291 mV. Supplementation of mitochondria with respiratory substrates prevented GSSG formation and, consequently, ATP synthase glutathionylation in response to H(2)O(2) challenges. ATP synthase appears to be the major mitochondrial protein that becomes glutathionylated under oxidative stress conditions. Glutathionylation of mitochondrial proteins is a major consequence of oxidative stress, and respiratory substrates are key regulators of mitochondrial redox status (as reflected by thiol/disulfide exchange) by maintaining mitochondrial NADPH levels.     

Redox properties of the [2Fe-2S] center in the 24 kDa (NQO2) subunit of NADH:ubiquinone oxidoreductase (complex I)

The redox properties of the [2Fe-2S] cluster in the 24 kDa subunit of bovine heart mitochondrial NADH:ubiquinone oxidoreductase (complex I) and three of its homologues have been defined using protein-film voltammetry. The clusters in all four examples display characteristic, pH-dependent redox transitions, which, unusually, can be masked by high ionic strength conditions. At low ionic strength (10 mM NaCl) the reduction potential varies by approximately 100 mV between high and low pH limits (pH 5 and 9); thus the redox process is not strongly coupled and is unlikely to form part of the mechanism of energy transduction in complex I. The pH dependence was shown to result from pH-linked changes in protein charge, due to nonspecific protonation events, rather than from the coupling of a specific ionizable residue, and the ionic strength dependence at high and low pH was modeled using extended Debye-Hückel theory. The low potential of the 24 kDa subunit [2Fe-2S] cluster, out of line with the potentials of the other iron-sulfur clusters in complex I, is suggested to play a role in coupling reducing equivalents at the catalytic active site. Finally, the validity of using the [2Fe-2S] cluster in an isolated subunit, as a mechanistic basis for coupled proton-electron transfer in intact complex I, is evaluated.     

Glutaredoxin 2 catalyzes the reversible oxidation and glutathionylation of mitochondrial membrane thiol proteins: implications for mitochondrial redox regulation and antioxidant DEFENSE

The redox poise of the mitochondrial glutathione pool is central in the response of mitochondria to oxidative damage and redox signaling, but the mechanisms are uncertain. One possibility is that the oxidation of glutathione (GSH) to glutathione disulfide (GSSG) and the consequent change in the GSH/GSSG ratio causes protein thiols to change their redox state, enabling protein function to respond reversibly to redox signals and oxidative damage. However, little is known about the interplay between the mitochondrial glutathione pool and protein thiols. Therefore we investigated how physiological GSH/GSSG ratios affected the redox state of mitochondrial membrane protein thiols. Exposure to oxidized GSH/GSSG ratios led to the reversible oxidation of reactive protein thiols by thiol-disulfide exchange, the extent of which was dependent on the GSH/GSSG ratio. There was an initial rapid phase of protein thiol oxidation, followed by gradual oxidation over 30 min. A large number of mitochondrial proteins contain reactive thiols and most of these formed intraprotein disulfides upon oxidation by GSSG; however, a small number formed persistent mixed disulfides with glutathione. Both protein disulfide formation and glutathionylation were catalyzed by the mitochondrial thiol transferase glutaredoxin 2 (Grx2), as were protein deglutathionylation and the reduction of protein disulfides by GSH. Complex I was the most prominent protein that was persistently glutathionylated by GSSG in the presence of Grx2. Maintenance of complex I with an oxidized GSH/GSSG ratio led to a dramatic loss of activity, suggesting that oxidation of the mitochondrial glutathione pool may contribute to the selective complex I inactivation seen in Parkinson's disease. Most significantly, Grx2 catalyzed reversible protein glutathionylation/deglutathionylation over a wide range of GSH/GSSG ratios, from the reduced levels accessible under redox signaling to oxidized ratios only found under severe oxidative stress. Our findings indicate that Grx2 plays a central role in the response of mitochondria to both redox signals and oxidative stress by facilitating the interplay between the mitochondrial glutathione pool and protein thiols.     

Reduction of the iron-sulfur clusters in mitochondrial NADH:ubiquinone oxidoreductase (complex I) by EuII-DTPA, a very low potential reductant

NADH:ubiquinone oxidoreductase (complex I) is the first enzyme of the mitochondrial electron transport chain. It contains a flavin mononucleotide to oxidize NADH, and eight iron-sulfur clusters. Seven of them transfer electrons between the flavin and the quinone-binding site, and one is on the opposite side of the flavin. Although most information about their properties is from EPR, the spectra from only five clusters have been observed, and it is difficult to match them to the structurally defined clusters. Here, we analyze complex I from bovine mitochondria reacted with a very low potential reductant, to impose a potential approaching -1 V. We compare the spectra with those from higher potentials and from the 24 kDa subunit and flavoprotein subcomplex, and model the spectra by starting from those with fewer components and building the complexity gradually. Spectrum N1a, from the 24 kDa subunit [2Fe-2S] cluster, is not observed in bovine complex I at any potential. Spectrum N1b, from the 75 kDa subunit [2Fe-2S] cluster, exhibits a lower potential than the N3, N4 and N5 spectra of three [4Fe-4S] clusters. In the lowest potential spectra an N5-type spectrum is observed at unusually high temperature (indicating a significant change to the cluster, or that two clusters have very similar g values), the relaxation rate of N1b increases (indicating that a nearby cluster has become reduced) and a new feature with an apparent g value of 2.16 suggests an interaction between two reduced clusters. The consequences of these observations for electron transfer in complex I are discussed.     

Relationship between mitochondrial NADH-ubiquinone reductase and a bacterial NAD-reducing hydrogenase

Bovine mitochondrial NADH-ubiquinone reductase (complex I), the first enzyme in the electron-transport chain, is a membrane-bound assembly of more than 30 different proteins, and the flavoprotein (FP) fraction, a water-soluble assembly of the 51-, 24-, and 10-kDa subunits, retains some of the catalytic properties of the enzyme. The 51-kDa subunit binds the substrate NAD(H) and probably contains both the cofactor, FMN, and also a tetranuclear iron-sulfur center, while a binuclear iron-sulfur center is located in the 24- or 10-kDa proteins. The 75-kDa subunit is the largest of the six proteins in the iron-sulfur protein (IP) fraction, and its sequence indicates that it too contains iron-sulfur clusters. Partial protein sequences have been determined at the N-terminus and at internal sites in the 51-kDa subunit, and the corresponding cDNA encoding a precursor of the protein has been isolated by using a novel strategy based on the polymerase chain reaction. The mature protein is 444 amino acids long. Its sequence, and those of the 24- and 75-kDa subunits, shows that mitochondrial complex I is related to a soluble NAD-reducing hydrogenase from the facultative chemolithotroph Alcaligenes eutrophus H16. This enzyme has four subunits, alpha, beta, gamma, and delta, and the alpha gamma dimer is an NADH oxidoreductase that contains FMN. The gamma-subunit is related to residues 1-240 of the 75-kDa subunit of complex I, and the alpha-subunit sequence is a fusion of homologues of the 24- and 51-kDa subunits, in the order N- to C-terminal. The most highly conserved regions are in the 51-kDa subunit and probably form parts of nucleotide binding sites for NAD(H) and FMN. Another conserved region surrounds the sequence motif CysXXCysXXCys, which is likely to provide three of the four ligands of a 4Fe-4S center, possibly that known as N-3. Characteristic ligands for a second 4Fe-4S center are conserved in the 75-kDa and gamma-subunits. This relationship with the bacterial enzyme implies that the 24- and 51-kDa subunits, together with part of the 75-kDa subunit, constitute a structural unit in mitochondrial complex I that is concerned with the first steps of electron transport.     

The utility of N,N-biotinyl glutathione disulfide in the study of protein S-glutathiolation

Glutathione disulfide (GSSG) accumulates in cells under an increased oxidant load, which occurs during neurohormonal or metabolic stimulation as well as in many disease states. Elevated GSSG promotes protein S-glutathiolation, a reversible post-translational modification, which can directly alter or regulate protein function. We developed novel strategies for the study of protein S-glutathiolation that involved the simple synthesis of N,N-biotinyl glutathione disulfide (biotin-GSSG). Biotin-GSSG treatment of cells mimics a defined component of oxidative stress, namely a shift in the glutathione redox couple to the oxidized disulfide state. This induces widespread protein S-glutathiolation, which was detected on non-reducing Western blots probed with streptavidin-horseradish peroxidase and imaged using confocal fluorescence microscopy and ExtrAvidin-FITC. S-Glutathiolated proteins were purified using streptavidin-agarose and identified using proteomic methods. We conclude that biotin-GSSG is a useful tool in the investigation of protein S-glutathiolation and offers significant advantages over conventional methods or antibody-based strategies. These novel approaches may find widespread utility in the study of disease or redox signaling models where GSSG accumulation occurs.     

Effect of 1-methyl-4-phenylpyridinium on glutathione in rat pheochromocytoma PC 12 cells

We investigated the effect of the selective dopaminergic neurotoxin 1-methyl-4-phenylpyridinium (MPP+) on glutathione redox status and the generation of reactive oxygen intermediates (ROI) in rat pheochromocytoma PC 12 cells in vitro. Treatment with MPP+ (250 microM) led to a 63% increase of reduced glutathione (GSH) after 24 h, while a 10-fold higher concentration of MPP+ (2.5 mM) depleted cellular GSH to 12.5% of control levels within that time. Similarly, the complex I-inhibitor rotenone induced a time-dependent loss of GSH at 1 and 10 microM, whereas treatment with lower concentrations of rotenone (0.1, 0.01 microM) increased cellular GSH. Both MPP+ and rotenone increased cellular levels of oxidised glutathione (GSSG) and the higher concentrations of both compounds led to an elevated ratio of oxidised glutathione (GSSG) vs total glutathione (GSH + GSSG) indicating a shift in cellular redox balance. MPP+ or rotenone did not induce the generation of ROI or significant elevation of intracellular levels of thiobabituric acid reactive substances (TBARS) for up to 48 h. Our data suggest that MPP+ has differential effects on glutathione homeostasis depending on the degree of complex I-inhibition and that inhibition of complex I is not sufficient to generate ROI in this paradigm.     

Reversible inactivation of Saccharomyces cerevisiae glutathione reductase under reducing conditions

Glutathione reductase from Saccharomyces cerevisiae was rapidly inactivated following aerobic incubation with NADPH, NADH, and several other reductants, in a time- and temperature-dependent process. The inactivation had already reached 50% when the NADPH concentration reached that of the glutathione reductase subunit. The inactivation was very marked at pH values below 5.5 and over 7, while only a slight activity decrease was noticed at pH values between these two values. After elimination of excess NADPH the enzyme remained inactive for at least 4 h. The enzyme was protected against redox inactivation by low concentrations of GSSG, ferricyanide, GSH, or dithiothreitol, and high concentrations of NAD(P)+; oxidized glutathione effectively protected the enzyme at concentrations even lower than GSH. The inactive enzyme was efficiently reactivated after incubation with GSSG, ferricyanide, GSH, or dithiothreitol, whether NADPH was present or not. The reactivation with GSH was rapid even at 0 degree C, whereas the optimum temperature for reactivation with GSSG was 30 degrees C. A tentative model for the redox interconversion, involving an erroneous intramolecular disulfide bridge, is put forward.     

Determination of the midpoint potential of the FAD and FMN flavin cofactors and of the 3Fe-4S cluster of glutamate synthase

Glutamate synthase is a complex iron-sulfur flavoprotein that catalyzes the reductive transfer of the L-glutamine amide group to C(2) of 2-oxoglutarate, forming two molecules of L-glutamate. The bacterial enzyme is an alphabeta protomer, which contains one FAD (on the beta subunit, approximately 50 kDa), one FMN (on the alpha subunit, approximately 150 kDa), and three different Fe-S clusters (one 3Fe-4S center on the alpha subunit and two 4Fe-4S clusters at an unknown location). To address the problem of the intramolecular electron pathway, we have measured the midpoint potential values of the flavin cofactors and of the 3Fe-4S cluster of glutamate synthase in the isolated alpha and beta subunits and in the alphabeta holoenzyme. No detectable amounts of flavin semiquinones were observed during reductive titrations of the enzyme, indicating that the midpoint potential value of each flavin(ox)/flavin(sq) couple is, in all cases, significantly more negative than that of the corresponding flavin(sq)/flavin(hq) couple. Association of the two subunits to form the alphabeta protomer does not alter significantly the midpoint potential value of the FMN cofactor and of the 3Fe-4S cluster (approximately -240 and -270 mV, respectively), but it makes that of FAD some 40 mV less negative (approximately -340 mV for the beta subunit and -300 mV for FAD bound to the holoenzyme). Binding of the nonreducible NADP(+) analogue, 3-aminopyridine adenine dinucleotide phosphate, made the measured midpoint potential value of the FAD cofactor approximately 30-40 mV less negative in the isolated beta subunit, but had no effect on the redox properties of the alphabeta holoenzyme. This result correlates with the formation of a stable charge-transfer complex between the reduced flavin and the oxidized pyridine nucleotide in the isolated beta subunit, but not in the alphabeta holoenzyme. Binding of L-methionine sulfone, a glutamine analogue, had no significant effect on the redox properties of the enzyme cofactors. On the contrary, 2-oxoglutarate made the measured midpoint potential value of the 3Fe-4S cluster approximately 20 mV more negative in the isolated alpha subunit, but up to 100 mV less negative in the alphabeta holoenzyme as compared to the values of the corresponding free enzyme forms. These findings are consistent with electron transfer from the entry site (FAD) to the exit site (FMN) through the 3Fe-4S center of the enzyme and the involvement of at least one of the two low-potential 4Fe-4S centers, which are present in the glutamate synthase holoenzyme, but not in the isolated subunits. Furthermore, the data demonstrate a specific role of 2-oxoglutarate in promoting electron transfer from FAD to the 3Fe-4S cluster of the glutamate synthase holoenzyme. The modulatory role of 2-oxoglutarate is indeed consistent with the recently determined three-dimensional structure of the glutamate synthase alpha subunit, in which several polypeptide stretches are suitably positioned to mediate communication between substrate binding sites and the enzyme redox centers (FMN and the 3Fe-4S cluster) to tightly control and coordinate the individual reaction steps [Binda, C., et al. (2000) Structure 8, 1299-1308].     

Quantification of oxidative posttranslational modifications of cysteine thiols of p21ras associated with redox modulation of activity using isotope-coded affinity tags and mass spectrometry

p21ras GTPase is the protein product of the most commonly mutated human oncogene and has been identified as a target for reactive oxygen and nitrogen species. Posttranslational modification of reactive thiols, by reversible S-glutathiolation and S-nitrosation, and potentially also by irreversible oxidation, may have significant effects on p21ras activity. Here we used an isotope-coded affinity tag (ICAT) and mass spectrometry to quantitate the reversible and irreversible oxidative posttranslational thiol modifications of p21ras caused by peroxynitrite (ONOO(-)) or glutathione disulfide (GSSG). The activity of p21ras was significantly increased after exposure to GSSG, but not to ONOO(-). The results of LC-MS/MS analysis of tryptic peptides of p21ras treated with ONOO(-) showed that ICAT labeling of Cys(118) was decreased by 47%, whereas Cys(80) was not significantly affected and was thereby shown to be less reactive. The extent of S-glutathiolation of Cys(118) by GSSG was 53%, and that of the terminal cysteines was 85%, as estimated by the decrease in ICAT labeling. The changes in ICAT labeling caused by GSSG were reversible by chemical reduction, but those caused by peroxynitrite were irreversible. The quantitative changes in thiol modification caused by GSSG associated with increased activity demonstrate the potential importance of redox modulation of p21ras.     

The amino acid sequence of the 9 kDa polypeptide and partial amino acid sequence of the 20 kDa polypeptide of mitochondrial NADH:ubiquinone oxidoreductase.

Mitochondrial NADH:ubiquinone oxidoreductase (complex I) is the most complicated enzyme in the respiratory chain and is composed of at least 26 distinct polypeptides. Two hydrophilic subfractions of bovine heart complex I were systematically resolved into individual polypeptides by chromatography. Three polypeptides (51, 24, and 9 kDa) were isolated from the flavoprotein fraction (FP) of complex I, and the complete amino acid sequence of the 9 kDa polypeptide was determined. The 9 kDa polypeptide is composed of 75 amino acids with a molecular weight of 8,437. This protein exhibits no obvious sequence similarity to other proteins. The iron-sulfur protein fraction (IP) of complex I was separated into eight polypeptides, 75, 49, 30, 20, 18, 15, 13 kDa-A, and 13 kDa-B. The 20 kDa polypeptide was recognized as a novel component of IP for the first time. The N-terminal and several peptide sequences of the 20 kDa polypeptide were determined. Comparison of the sequences revealed significant sequence similarities of the 20 kDa polypeptide to the psbG gene products encoded in the chloroplast genome. The conserved sequence in these proteins was also found in the small subunit of the nickel-containing hydrogenases. These results suggest that complex I is related to other redox enzyme complexes.     

Redox control of platelet aggregation

Sulfhydryl and disulfide metabolism in platelet function has recently reemerged as a focus of platelet research. In this study we tested the effect of redox buffer on platelet aggregation and the effect of reduced glutathione (GSH) and platelet activation on sulfhydryl exposure in the platelet fibrinogen receptor, alpha IIb beta 3. In the presence of subthreshold concentrations of agonist, physiologic concentrations of GSH (10 microM) stimulated platelet aggregation and secretion. These effects were found with more than one platelet agonist and with different low molecular weight thiols, including homocysteine. The effect of low molecular weight thiols was reproduced with the peptide LSARLAF which directly activates platelets through alpha IIb beta 3, suggesting that the mechanism is at the level of this integrin. After determining optimal sulfhydryl labeling conditions for alpha IIb beta 3 (5 mM EDTA, 37 degrees C, 60 min), we found that GSH (10 microM) generated sulfhydryls in the beta 3 subunit. To determine if the requirement was for reducing equivalents or for a redox potential (ratio of GSH to GSSG), aggregation was further studied with the addition of low concentrations of GSSG to the GSH. With a ratio of GSH/GSSG of 5/1, similar to that of blood, the addition of GSSG potentiated the stimulatory effect as compared to GSH alone. This indicates that, for potentiation of aggregation, GSH is not simply reducing disulfide bonds; there is rather a requirement for a certain redox potential. Additional studies performed in the absence of added glutathione showed an increase in sulfhydryl labeling in the beta 3 subunit during platelet activation. Finally, we show that vicinal dithiols of platelet surface proteins are involved in the sulfhydryl-dependent pathways of platelet activation. In summary, these data imply that the redox potential of blood regulates activation of the alpha IIb beta 3 integrin and together with other reports in the literature suggest that disulfide bond cleavage with sulfhydryl generation in beta 3 is involved in activation of this receptor.     

Ageing of tomato seeds involves glutathione oxidation

The effect of seed ageing on the oxidation of reduced glutathione (GSH) and the role of GSH oxidation in ageing-induced deterioration were studied in seeds of tomato ( Lycopersicon esculentum Mill. cv. Lerica, Moneymaker and Cromco). Both long-term storage at 15°C/30% relative humidity (RH) and artificial ageing at 20°C/75% RH, 30°C/45% RH and 60°C/45% RH resulted in a marked loss of GSH and a simultaneous, though not proportional, increase in its oxidized form GSSG. The glutathione thiol-disulfide status shifted towards a highly oxidized form, while the total glutathione pool decreased. The extent of GSH oxidation differed between ageing conditions and was not directly related to the extent of seed deterioration. Thiobarbituric acid-reactive substances did not increase in ageing tomato seeds, suggesting that lipid peroxidation did not take place. Hydration of seeds, either upon imbibition in water or by priming in an osmotic solution, resulted in a rapid decrease in GSSG, a shift of the glutathione redox couple to a mainly reduced status and an increase in the glutathione pool, in both control and aged seeds. The results indicate that, in tomato seeds, (1) seed ageing involves GSH oxidation into GSSG, which is indicative of oxidative stress, (2) ageing does not affect the GSSG reduction capacity upon subsequent imbibition, and (3) the lowered viability of aged seeds cannot directly be ascribed to the decreased GSH pool or To the highly oxidized glutathione redox status.     

The multiple nicotinamide nucleotide-binding subunits of bovine heart mitochondrial NADH:ubiquinone oxidoreductase (complex I).

Direct photoaffinity labeling of purified bovine heart NADH:ubiquinone oxidoreductase (complex I) with 32P-labeled NAD(H), NADP(H) and ADP has shown that five polypeptides become labeled, with molecular masses of 51, 42, 39, 30, and 18-20 kDa. The 51 and the 30-kDa polypeptides were labeled with either [32P]NAD(H), [32P]NADP(H) or [beta-32P]ADP. The 42-kDa polypeptide was labeled with [32P]NAD(H) and to a small extent with [beta-32P]ADP. It was not labeled with [32P]NADP(H). The 39-kDa polypeptide was labeled with [32P]NADPH and to a small extent with [beta-32P]ADP. Our previous studies had shown that this subunit also binds NADP, but not NAD(H) [Yamaguchi, M., Belogrudov, G.I. & Hatefi, Y. (1998) J. Biol. Chem. 273, 8094-8098]. The 18-20-kDa polypeptide was labeled only with [32P]NADPH. Among these polypeptides, the 51-kDa subunit is known to contain FMN and a [4Fe-4S] cluster, and is the NAD(P)H-binding subunit of the primary dehydrogenase domain of complex I. The possible roles of the other nucleotide-binding subunits of complex I have been discussed.     

Redox-changes associated with the glutathione-dependent ability of the Cu(II)-GSSG complex to generate superoxide

The intracellularly-occurring Cu(I)-glutathione complex (Cu(I)-[GSH](2)) has the ability to reduce molecular oxygen into superoxide. Removal of such radicals leads to the irreversible conversion of Cu(I)-[GSH](2) into the redox-inactive Cu(II)-GSSG complex. The present study addressed the potential of reduced glutathione, ascorbate and superoxide to reductively regenerate Cu(I)-[GSH](2) from Cu(II)-GSSG, and investigated the redox changes involved in such process. Results show that: (i) among the three tested reductants, only GSH is able to reduce the Cu(II) bound to GSSG; (ii) during the reduction of Cu(II)-GSSG, a Cu(I)-GSSG intermediate would be formed (supported here by Cu(I) and GSSG recovery data and by NMR studies); (iii) when GSH is present in a molar excess equal or greater than 1:3, the reduction of Cu(II)-GSSG into Cu(I)-[GSH](2) is quantitative and complete. Under such conditions, the Cu(II)-GSSG complex acquires a superoxide-generating capacity which is identical to that seen with the Cu(I)-[GSH](2) complex. Within cells, the concentrations of GSH are at least 2- to 3-fold order of magnitude higher than those expected for the Cu(II)-GSSG complex. Thus, we postulate that the interaction between GSH and Cu(II)-GSSG could be seen as a potential mechanism to regenerate continuously the Cu(I)-[GSH](2) complex and thereby affect the ability of the latter to generate superoxide.     

Three novel subunits of Arabidopsis chloroplastic NAD(P)H dehydrogenase identified by bioinformatic and reverse genetic approaches

Chloroplastic NAD(P)H dehydrogenase (NDH) plays a role in cyclic electron flow around photosystem I to produce ATP, especially in adaptation to environmental changes. Although the NDH complex contains 11 subunits that are homologous to NADH:ubiquinone oxidoreductase (complex I; EC 1.6.5.3), recent genetic and biological studies have indicated that NDH also comprises unique subunits. We describe here an in silico approach based on co-expression analysis and phylogenetic profiling that was used to identify 65 genes as potential candidates for NDH subunits. Characterization of 21 Arabidopsis T-DNA insertion mutants among these ndh gene candidates indicated that three novel ndf (NDH-dependent cyclic electron flow) mutants ( ndf1 , ndf2 and ndf4 ) had impaired NDH activity as determined by measurement of chlorophyll fluorescence. The amount of NdhH subunit was greatly decreased in these mutants, suggesting that the loss of NDH activity was caused by a defect in accumulation of the NDH complex. In addition, NDF1, NDF2 and NDF4 proteins co-migrated with the NdhH subunit, as shown by blue native electrophoresis. These results strongly suggest that NDF proteins are novel subunits of the NDH complex. Further analysis revealed that the NDF1 and NDF2 proteins were unstable in the mutants lacking hydrophobic subunits of the NDH complex, but were stable in mutants lacking the hydrophilic subunits, suggesting that NDF1 and NDF2 interact with a hydrophobic sub-complex. NDF4 protein was predicted to possess a redox-active iron–sulfur cluster domain that may be involved in the electron transfer.     

Glutathione controls the redox state of the mitochondrial carnitine/acylcarnitine carrier Cys residues by glutathionylation

Background

The mitochondrial carnitine/acylcarnitine carrier (CAC) is essential for cell metabolism since it catalyzes the transport of acylcarnitines into mitochondria allowing the β-oxidation of fatty acids. CAC functional and structural properties have been characterized. Cys residues which could form disulfides suggest the involvement of CAC in redox switches.

Methods

The effect of GSH and GSSG on the [³H]-carnitine/carnitine antiport catalyzed by the CAC in proteoliposomes has been studied. The Cys residues involved in the redox switch have been identified by site-directed mutagenesis. Glutathionylated CAC has been assessed by glutathionyl-protein specific antibody.

Results

GSH led to increase of transport activity of the CAC extracted from liver mitochondria. A similar effect was observed on the recombinant CAC. The presence of glutaredoxin-1 (Grx1) accelerated the GSH activation of the recombinant CAC. The effect was more evident at 37 °C. GSSG led to transport inhibition which was reversed by dithioerythritol (DTE). The effects of GSH and GSSG were studied on CAC Cys-mutants. CAC lacking C136 and C155 was insensitive to both reagents. Mutants containing these two Cys responded as the wild-type. Anti-glutathionyl antibody revealed the formation of glutathionylated CAC.

Conclusions

CAC is redox-sensitive and it is regulated by the GSH/GSSG couple. C136 and C155 are responsible for the regulation which occurs through glutathionylation.

General significance

CAC is sensitive to the redox state of the cell switching between oxidized and reduced forms in response to variation of GSSG and GSH concentrations.     

Human jejunal glutathione reductase: purification and evaluation of the NADPH- and glutathione-induced changes in redox state

Human proximal jejunal glutathione reductase (EC 1.6.4.2) was purified to homogeneity by affinity chromatography on 2', 5'-ADP-Sepharose 4B. In most of its molecular and kinetic properties, the enzyme resembled glutathione reductase from other sources: The subunit mass was 56 kDa; the isoelectric point and pH optimum were 6.75 and 7.25, respectively; Michaelis constants, determined at pH 7.4, 37 degrees C, fell within the range of previously reported values [Km(NADPH) = 20 microM, Km(GSSG) = 80 microM]. The response of the enzyme to reducing conditions, on the other hand, had unique features: Preincubation with 1 mM NADPH resulted in 90% loss of activity which could be partially reversed by 2 mM GSSG, but not GSH. (Treatment with GSSG regenerated 68% of the original activity.) Reduction by GSH also caused inactivation which potentially amounted to greater than 80%. This inactivation could not be reversed by GSSG. The protective effect of GSSG against inactivation by GSH was studied. Except where [GSSG] far exceeded [GSH], the presence of GSSG in the preincubation medium decreased the extent of inhibition without affecting the rate constant for approach to equilibrium activity. At [GSSG] greater than [GSH] a decrease in the rate constant for inactivation was also observed. The results were interpreted in terms of a three-step mechanism: (1) preequilibrium reduction of Eox to Ered; (2) rate-limiting change in conformation from Ered to E'red, and (3) irreversible conversion to catalytically inferior products.     

Effect of antioxidant-enriched diets on glutathione redox status in tissue homogenates and mitochondria of the senescence-accelerated mouse

The main purpose of this study was to investigate whether consumption of diets enriched in antioxidants attenuates the level of oxidative stress in the senescence-accelerated mouse (SAM). In separate and independent studies, two different dietary mixtures, one enriched with vitamin E, vitamin C, L-carnitine, and lipoic acid (Diet I) and another diet including vitamins E and C and 13 additional ingredients containing micronutrients with bioflavonoids, polyphenols, and carotenoids (Diet II), were fed for 8 and 10 months, respectively. The amounts of glutathione (GSH) and glutathione disulfides (GSSG) and GSH:GSSG ratios were determined in plasma, tissue homogenates, and mitochondria isolated from five different tissues of SAM (P8) mice. Both diets had a reductive effect in plasma; however Diet I had relatively little effect on the glutathione redox status in tissue homogenates or mitochondria. Remarkably, Diet II caused a large increase in the amount of glutathione and a marked reductive shift in glutathione redox state in mitochondria. Overall, the effects of Diet II were tissue and gender specific. Results indicated that the glutathione redox state in mitochondria and tissues can be altered by supplemental intake of a relatively complex mixture of dietary antioxidants that contains substances known to induce phase 2 enzymes, glutathione, and antioxidant defenses. Whether corresponding attenuations occur in age-associated deleterious changes in physiological functions or life span remains unknown.