Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.5.1.18 (glutathione S-transferase)
 22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Glutathione peroxidase (glutathione: hydrogen-peroxide oxidoreductase, EC 1.11.1.9) was purified approximately 600-fold from rainbow trout liver soluble fraction and its activity in the NADPH microsomal lipid peroxidation system tested. The enzyme has an approximate molecular weight of 100 000, contains four subunits and four atoms of selenium per mol protein. No selenium-independent glutathione peroxidase activity could be attributed to glutathione S-transferase (EC 2.5.1.18) in trout liver. Glutathione peroxidase together with glutathione (GSH) did not provide any additional protection in the in vitro liver microsomal lipid peroxidation system over and above that provided by GSH alone. Microsomal lipid peroxidation was, however, reduced by a partially purified glutathione S-transferase together with GSH. The protection provided by dialysed liver cytosol in this system was not GSH-dependent, showing that other factors in addition to glutathione S-transferase are involved. Of other possible factors, vitamin E reduced lipid peroxidation in this system. Concentrations of vitamin E in microsomes before and after peroxidation in vitro indicated that protective cytosolic factor(s) act prior to the termination of the free radical chain reactions effected by vitamin E. A GSH-dependent protective factor was present in microsomal protein, malondialdehyde formation in the in vitro microsomal system being markedly reduced in the presence of 5 mM GSH but not significantly lowered by 1 mM GSH.
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PMID:Rainbow trout liver microsomal lipid peroxidation. The effect of purified glutathione peroxidase, glutathione S-transferase and other factors. 646 1

To determine if non-selenium-dependent glutathione peroxidase (Non-Se GSH-Px) activity is present in rat lung, we fractionated rat lung soluble fractions from rats fed a selenium-deficient or control diet and measured glutathione peroxidase activity with both cumene hydroperoxide and hydrogen peroxide as substrates. We also measured glutathione S-transferase (GSH S-transferase) activity in the fractions with 1-chloro-2,4-dinitrobenzene as substrate. Non-Se GSH-Px activity was present (about 34% of total GSH-Px activity), and the peak present in the gel filtration chromatogram coeluted with the GSH S-transferase peak. We then measured GSH S-transferase activity in lung-soluble fractions from rats exposed to room air or 85% O2 for 5 days. Lung GSH S-transferase activity was increased in the oxygen-exposed animals when compared to the air-exposed controls. The increase in GSH S-transferase activity could represent the induction of lung non-Se GSH-Px activity.
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PMID:Non-selenium-dependent glutathione peroxidase activity in rat lung: association with lung glutathione S-transferase activity and the effects of hyperoxia. 685 74

Glutatione transferases (RX:glutathione R-transferases, EC 2.5.1.18) B and AA were purified from rat liver to investigate the mechanism for their apparent GSH peroxidase activity (GSSG formation). Both transferases catalyze an overall reaction in which loss of cumene hydroperoxide is accompanied by a stoichiometric increase in GSSG. Inclusion of cysteamine, a thiol, results in a reduction of GSSG formation but has no effect on hydroperoxide loss. Cysteamine does not inhibit the transferase-catalyzed conjugation of GSH and 1-chloro-2,4-dinitrobenzene. Peroxidase reactions carried out in the presence of cyanide, another nucleophile, also result in a reduction of GSSG formation without altering the rate of cumene hydroperoxide loss; cyanide does not inhibit transferase activity with 1-chloro-2,4-dinitrobenzene. Both cysteamine and cyanide are capable of blocking GSSG formation in the non-enzymic oxidation of GSH by hydrogen peroxide without blocking H2O2 loss. These results are consistent with a mechanism for GSH transferases in which nucleophilic attack by GS- on hydroperoxide results in a reactive intermediate, presumably the sulfenic acid of glutathione, GSOH. GSH + ROOH in equilibrium GSHO + ROH (1) This sulfenic acid then reacts non-enzymically with GSH to produce GSSG. GSOH + GSH in equilibrium GSSG + H2O (2) The summing of Reactions 1 and 2 explains the observed stoichiometry. Cysteamine and cyanide can compete with GSH for the sulfenic acid in Reaction 2, thus reducing GSSG formation. Thios.
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PMID:The glutathione peroxidase activity of glutathione S-transferases. 735 Sep 21

A consistent feature of the Alpha-, Mu- and Pi-class glutathione transferases (GSTs) is the presence near the N-terminus of a tyrosine residue that contributes to the activation of glutathione. While this residue appears to be conserved in many Theta-class GSTs, its absence in some suggested that the Theta-class GSTs may have a significantly different structure or catalytic mechanism. The elucidation of the crystal structure of the Theta-class GST from the Australian sheep blowfly, Lucilia cuprina, has indicated that a serine residue rather than a tyrosine residue can form a hydrogen bond with the glutathionyl sulphur atom. The present studies show that mutation of Ser-9 to alanine substantially inactivates the L. cuprina GST, confirming its importance in the reaction mechanism. As this serine is conserved in all Theta-class enzymes reported so far, it seems that an active-site serine is a significant factor that distinguishes the Theta-class GSTs from members of the Alpha-, Mu- and Pi-class isoenzymes.
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PMID:Evidence for an essential serine residue in the active site of the Theta class glutathione transferases. 757 61

An H2O2-resistant variant (OC14) of the HA1 Chinese hamster fibroblast cell line, which demonstrates cross resistance to 95% O2 and a 2-fold increase in total glutathione content, was utilized to investigate mechanisms responsible for cellular resistance to H2O2- and O2-toxicity. OC14 and HA1 cells were pretreated with buthionine sulfoximine (BSO) to deplete total cellular glutathione. Following BSO pretreatment, cells were either placed in 250 microM BSO to maintain the glutathione depleted condition and challenged with 95% O2, or challenged with hydrogen peroxide in the absence of BSO. Total glutathione and the activities of CuZn superoxide dismutase, Mn superoxide dismutase, catalase, glutathione peroxidase, and glutathione transferase were evaluated immediately following the BSO pretreatment as well as following 39 to 42 hr of exposure to 250 microM BSO. BSO treatment did not cause significant decreases in any cellular antioxidant tested, except total glutathione. Glutathione depletion resulted in significant (P < 0.05) sensitization to O2-toxicity and H2O2-toxicity in both cell lines at every time point tested. However, glutathione depletion did not completely abolish the resistance to either O2- or H2O2-toxicity demonstrated by OC14 cells, relative to HA1 cells. Also, glutathione depletion did not effect the ability of OC14 cells to metabolize extracellular H2O2. These data indicate that glutathione dependent processes significantly contribute to cellular resistance to acute H2O2- and O2-toxicity, but are not the only determinants of resistance in cell lines. The contribution of aldehydes formed by lipid peroxidation in mechanisms involved with the sensitization to O2-toxicity in glutathione depleted cells was tested by measuring the lipid peroxidation byproduct, 4-hydroxy-2-nonenal (4HNE), bound in Schiff-base linkages or in its free form in cell homogenates at 49 hr of 95% O2-exposure. No significant increase in 4HNE was detected in glutathione depleted cells relative to glutathione competent cells, indicating that glutathione depletion does not sensitize these cells to O2-toxicity by altering the intracellular accumulation of free or Schiff-base bound 4HNE.
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PMID:Contribution of increased glutathione content to mechanisms of oxidative stress resistance in hydrogen peroxide resistant hamster fibroblasts. 759 39

Chromium(VI) resistant Chinese hamster ovary (CHO) cell lines were established in this study by exposing parental CHO-K1 cells to sequential increases in CrO3 concentration. The final concentration of CrO3 used for selection was 7 microM for Cr7 and 16 microM for Cr16 cells. Cr16-1 was a subclone derived from Cr16 cells. Next, these resistant cells were cultured in media without CrO3 for more than 6 months. The resistance of these cells to CrO3 was determined by colony-forming ability following a 24-h treatment. The LD50 of CrO3 for chromium(VI) resistant cells was at least 25-fold higher than that of the parental cells. The cellular growth rate, chromosome number, and the hprt mutation frequency of these chromium(VI) resistant cells were quite similar to their parental cells. The glutathione level, glutathione S-transferase, catalase activity, and metallothionine mRNA level in Cr7 and Cr16-1 cells were not significantly different from their parental cells. Furthermore, Cr16-1 cells were as sensitive as CHO-K1 cells to free-radical generating agents, including hydrogen peroxide, nickel chloride, and methanesulfonate methyl ester, and emetine, i.e., a protein synthesis inhibitor. The uptake of chromium(VI) and the remaining amount of this metal in these resistant and the parental cell lines were assayed by atomic absorption spectrophotometry. Experimental results indicated that a vastly smaller amount of CrO3 entered the resistant cell lines than their parental cells did. A comparison was made of the sulfate uptake abilities of CHO-K1 and chromium(VI) resistant cell lines. These results revealed that the uptake of sulfate anion was substantially reduced in Cr7 and Cr16-1 cells. Extracellular chloride reduced sulfate uptake in CHO-K1 but not in Cr16-1 cells. Therefore, the major causative for chromium(VI) resistance in these resistant cells could possibly be due to the defects in SO4(2-)/C1- transport system for uptake chromium(VI).
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PMID:Long-term exposure to chromium(VI) oxide leads to defects in sulfate transport system in Chinese hamster ovary cells. 761 50

The kinetic mechanism of glutathione S-transferase (GST) from Octopus vulgaris hepatopancreas was investigated by steady-state analysis. Initial-velocity studies showed an intersecting pattern, which suggests a sequential kinetic mechanism for the enzyme. Product-inhibition patterns by chloride and the conjugate product were all non-competitive with respect to glutathione or 1-chloro-2,4-dinitrobenzene (CDNB), which indicates that the octopus digestive gland GST conforms to a steady-state sequential random Bi Bi kinetic mechanism. Dead-end inhibition patterns indicate that ethacrynic acid ([2,3-dichloro-4-(2-methyl-enebutyryl) phenoxy]acetic acid) binds at the hydrophobic H-site, norophthalmic acid (gamma-glutamylalanylglycine) binds at the glutathione G-site, and glutathione-ethacrynate conjugate occupied both H- and G-sites of the enzyme. The chemical mechanism of the enzyme was examined by pH and kinetic solvent-isotope effects. At pH (and p2H) = 8.011, in which kcat. was independent of pH or p2H, the solvent isotope effects on V and V/KmGSH were near unity, in the range 1.069-1.175. An inverse isotope effect was observed for V/KmCDNB (0.597), presumably resulting from the hydrogen-bonding of enzyme-bound glutathione, which has pKa of 6.83 +/- 0.04, a value lower by 2.34 pH units than the pKa of glutathione in aqueous solution. This lowering of the pKa value for the sulphydryl group of the bound glutathione was presumably due to interaction with the active site Tyr7, which had a pKa value of 8.46 +/- 0.09 that was raised to 9.63 +/- 0.08 in the presence of glutathione thiolate. Subsequent chemical reaction involves attacking of thiolate anion at the electrophilic substrate with the formation of a negatively charged Meisenheimer complex, which is the rate-limiting step of the reaction.
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PMID:Steady-state kinetics and chemical mechanism of octopus hepatopancreatic glutathione transferase. 761 78

Both radiation and anthracycline antibiotics may produce reactive oxygen species to cause cytotoxicity, and it has been suggested that some cellular antioxidant enzymes may be important for resistance to these agents. The human breast adenocarcinoma cell line MCF-7WT has a low level of glutathione peroxidase (GPX) activity. We have transfected MCF-7WT cells with a plasmid that contains the cDNA for human GPX under the transcriptional control of the human metallothionein IIA promoter. One transfected clone, MCF-GPX-6, contained multiple copies of GPX cDNA/cell and, after exposure to heavy metals, expressed a level of GPX enzyme activity that was 40-fold higher than that present in MCF-7WT cells and comparable to the GPX activity contained in the doxorubicin-resistant MCF-7DOX cell line. No differences in levels of glutathione, catalase, superoxide dismutase, glutathione S-transferase, or glutathione reductase were noted in MCF-GPX-6 cells compared to MCF-7WT cells. MCF-GPX-6 cells were relatively resistant to hydrogen peroxide and tert-butylhydroperoxide compared to MCF-7WT cells, e.g., exposure of both cell lines to 750 microM H2O2 for 1 h resulted in a relative surviving fraction of 0.07 for MCF-7WT and 0.35 for MCF-GPX-6 cells. However, no difference in sensitivity to either radiation or doxorubicin was noted between MCF-7WT and MCF-GPX-6 cells. These results suggest that GPX is not important for the development of cellular resistance to either radiation or doxorubicin.
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PMID:Enhanced glutathione peroxidase expression protects cells from hydroperoxides but not from radiation or doxorubicin. 767 Dec 61

Arg15 is a conserved active-site residue in class Alpha glutathione transferases. X-ray diffraction studies of human glutathione transferase A1-1 have shown that N epsilon of this amino acid residue is adjacent to the sulfur atom of a glutathione derivative bound to the active site, suggesting the presence of a hydrogen bond. The phenolic hydroxyl group of Tyr9 also forms a hydrogen bond to the sulfur atom of glutathione, and removal of this hydroxyl group causes partial inactivation of the enzyme. The present study demonstrates by use of site-directed mutagenesis the functional significance of Arg15 for catalysis. Mutation of Arg15 into Leu reduced the catalytic activity by 25-fold, whereas substitution by Lys caused only a threefold decrease, indicating the significance of a positively charged residue at position 15. Mutation of Arg15 into Ala or His caused a substantial reduction of the specific activity (200 or 400-fold, respectively), one order of magnitude more pronounced than the effect of the Tyr9-->Phe mutation. Double mutations involving residues 9 and 15 demonstrated that the effects of mutations at the two positions were additive except for the substitution of His for Arg15, which appeared to cause secondary structural effects. The pKa value of the phenolic hydroxyl of Tyr9 was determined by UV absorption difference spectroscopy and was found to be 8.1 in the wild-type enzyme. The corresponding pKa values of mutants R15K, R15H and R15L were 8.5, 8.7 and 8.8, respectively, demonstrating the contribution of the guanidinium group of Arg15 to the electrostatic field in the active site. Addition of glutathione caused an increased pKa value of Tyr9; this effect was not obtained with S-methylglutathione. These results show that Tyr9 is protonated when glutathione is bound to the enzyme at physiological pH values. The involvement of an Arg residue in the binding and activation of glutathione is a feature that distinguishes class Alpha glutathione transferases from members in other glutathione transferase classes.
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PMID:Functional significance of arginine 15 in the active site of human class alpha glutathione transferase A1-1. 772 30

Spectroscopy at a biochemical active site is influenced by local fields and hydrogen-bonds. Quantum calculations of the electronic structure of the entire biomolecule is, of course, impossible, but the chemical system can be modeled by dividing it into an active region (A) described quantum mechanically, and a spectator region (S) that influences A with strong fields and hydrogen-bonds. The all-electron interaction between A and S is replaced by an effective fragment potential (EFP) which represents the interaction as electrostatic, polarization and exchange repulsion terms. The EFP are derived entirely by ab initio model calculations of the S electronic properties and interactions and have been implemented in the quantum chemistry code, GAMESS. Spectroscopic analysis of enzyme active sites using the EFP will examine rhodanese and glutathione bound to glutathione S-transferase. The effect of specific hydrogen-bonds and local helices on spectral shifts is determined.
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PMID:Effective fragment potentials and spectroscopy at enzyme active sites. 773 1


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