Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Dihalomethanes are metabolized to carbon monoxide both in vivo and in vitro. The reaction is catalyzed by a hepatic microsomal cytochrome P-450 dependent mixed function oxidase system. Bioorganic mechanism studies suggest an initial oxygen insertion reaction followed by rearrangement to a formyl halide intermediate which in turn decomposes to yield carbon monoxide. In vitro studies show that 14C-dichloromethane becomes covalently bound to both microsomal protein and lipid. The similar characteristics of metabolism to carbon monoxide and covalent binding suggests that a common intermediate, perhaps the formyl halide, may be involved. Dihalomethanes are also metabolized to formaldehyde, formic acid, and inorganic halide. A glutathione transferase, located in hepatic cytosol fractions, appears to be involved. Reaction mechanism studies suggest that a S-hydroxymethyl glutathione intermediate may yield formaldehyde or be diverted via formaldehyde dehydrogenase/S-formyl glutathione hydrolase to yield formic acid. Haloforms are also metabolized in vitro to carbon monoxide by a hepatic microsomal cytochrome P-450 dependent mixed function oxidase system. This reaction is a markedly stimulated by sulfhydryl compounds.
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PMID:Metabolism of halogenated methanes and macromolecular binding. 9 15

Malignant melanoma tumors are inherently resistant to anticancer drugs, yet the mechanism of this resistance is not understood. B16 melanoma, a spontaneous tumor which arose in the C57BL/6 mouse; BL6 melanoma, a highly invasive variant; and Mel-ab melanocytes, isolated from C57BL/6 mouse skin, were examined for intracellular glutathione (GSH) content. GSH was higher in BL6 and B16 cells than in Mel-ab cells, with the highest concentration in BL6 cells. Since GSH is thought to be involved in the resistance of many cells, including melanoma, to cytotoxic drugs, we determined whether intracellular GSH content was altered during transformation of Mel-ab cells. After transfection with pHO6T1 plasmid DNA, containing an activated c-H-ras oncogene flanked by transcriptional enhancers, 1.3% of successfully transfected Mel-ab melanocytes formed distinct colonies in soft agar, compared to 0.2% of cells transfected with control pHO6 plasmid without H-ras. Approximately 53% of the pHO6T1-transfected colonies isolated from soft agar grew in 5% CO2 in the absence of phorbol-12-myristate-13-acetate, a requirement for the extended growth of Mel-ab cells. Cells transfected with control pHO6 plasmid and non-transfected Mel-ab cells did not survive under these conditions. All of the isolated pHO6T1 transfected cells formed tumors when inoculated into C57BL/6 mice. Transformed cells had higher GSH content than non-transfected Mel-ab cells, whether expressed on a cellular or cell volume basis. Although the amount of oxidized glutathione was greater in the tumorigenic cells, this could not account for the overall increase in GSH. Neither glutathione S-transferase nor gamma-glutamyl transpeptidase activities were increased in the H-ras-transfected cells. Northern blot analysis confirmed H-ras-specific RNA in pHO6T1-transformed cells.
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PMID:Induction of glutathione content in murine melanocytes after transformation with c-H-ras oncogene. 171 78

Perfusion of the bovine eye with a buffer solution containing t-butyl hydroperoxide and the glutathione reductase inhibitor nitrofurantoin caused significant decreases in reduced glutathione level in ciliary body and iris. The result was interpreted to suggest that the organic hydroperoxide was decomposed by the glutathione peroxidase-reductase system. The glutathione reductase reaction requires NADPH. Since the level of NADPH is maintained by the hexose monophosphate shunt in many tissues, we investigated whether this is also the case with bovine uveal tissues. CO2 formation from [1-14C]glucose but not from [6-14C]glucose was markedly stimulated by t-butyl hydroperoxide and was inhibited by the glutathione reductase inhibitor 1,3-bis(2-chloroethyl)-1-nitrosourea, thus supporting the importance of the hexose monophosphate shunt for hydroperoxide decomposition through the glutathione peroxidase-reductase system. The peroxidase-reductase activity was found both in non-pigmented and pigmented ciliary epithelial cells in culture. Purification studies isolated two forms of glutathione reductase [GR I (140 kDa) with subunit Mr of 70 kDa and GR II (greater than 670 kDa) with subunit Mr of 45 kDa] and a novel glutathione peroxidase (112 kDa with subunit Mr of 29 kDa). The peroxidase is active both with H2O2 and organic hydroperoxides, does not contain selenium and shows no glutathione S-transferase activity.
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PMID:Glutathione-dependent detoxification of peroxide in bovine ciliary body. 237 73

Recent evidence supports the concept that Adriamycin cytotoxicity may be mediated by drug semiquinone free radical and oxyradical generation. We tested this hypothesis further by exposing drug-sensitive (WT) and 500-fold Adriamycin-resistant MCF-7 human breast tumor cells (ADRR) to exogenous superoxide- and hydrogen peroxide-generating systems and subsequently monitored cell proliferation as a measure of cytotoxicity. The ADRR tumor cells tolerated a 4-fold greater exposure than sensitive cells to superoxide generated by the xanthine/xanthine oxidase system. Likewise, exposure to hydrogen peroxide produced by the action of glucose oxidase on glucose revealed a 4-fold diminished susceptibility of the drug-resistant cells to this reduced form of oxygen. Similar results were obtained by the direct application of hydrogen peroxide to cells. For both cell lines, cytotoxicity was dependent upon the magnitude and the duration of reactive oxygen exposure. When WT and ADRR cells were cultured under hyperoxia (95% O2:5% CO2), in order to stimulate the intracellular production of oxyradicals, proliferation was inhibited to a greater extent in the drug-sensitive cell line. Additionally, hyperoxia potentiated the cytotoxicity of Adriamycin to both sensitive and drug-resistant cells, but the effect depended upon the concentration of the drug. Under hyperoxic conditions, Adriamycin caused oxygen radical-dependent cytotoxicity to the WT tumor cells at clinically relevant drug concentrations as low as 2 to 3 nM. With ADRR tumor cells, hyperoxia increased the cytotoxicity of Adriamycin at concentrations above 5 microM. Paradoxically, both the WT and the ADRR tumor cells were equally susceptible to the cytotoxic effects of gamma irradiation. It is known that the Adriamycin-resistant MCF-7 cells greatly overexpress glutathione peroxidase and glutathione transferase activities; however, other biochemical defenses against reactive drug intermediates and oxygen radicals have been reported to be similar in the two cell lines. We have reexamined those observations in this report. The resistance of ADRR breast tumor cells to Adriamycin appears to be associated with a developed tolerance to superoxide, most likely because of a twofold increase in superoxide dismutase activity, and a decreased susceptibility to hydrogen peroxide, most likely because of 12-fold augmented selenium-dependent glutathione peroxidase activity. Acting in concert, these two enzymes would decrease the formation of hydroxyl radical from reduced molecular oxygen intermediates.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Differential oxygen radical susceptibility of adriamycin-sensitive and -resistant MCF-7 human breast tumor cells. 253 95

The amount of urea synthesized in intact guinea pig hepatocytes in 60 min ([urea]t=60), was determined at 37 degrees C in Krebs-Henseleit buffer plus (in mM) 10 NH4Cl, 5 lactate, and 10 ornithine in 5% CO2-95% O2. The concentrations of sulfonamide carbonic anhydrase (CA) inhibitors required to reduce the rate of urea synthesis by 50% (I50) were (in mM): 0.07 ethoxzolamide, 0.5 methazolamide, 0.7 acetazolamide, and 5.0 p-aminomethylbenzenesulfonamide. At 37 degrees C acetazolamide and ethoxzolamide reduced citrulline synthesis by intact mitochondria in medium containing (in mM) 50 3-(N-morpholino)propanesulfonic acid, 35 KCl, 5 KH2PO4, 2 adenosine triphosphate, 10 ornithine, 10 NH4Cl, 1 [ethylene-bis(oxyethylenenitrile)]tetraacetic acid, 1 MgCl2, 20 pyruvate, and 25 KHCO3 (pH 7.4) in 5% CO2-95% O2; the inhibition by ethoxzolamide was not decreased greater than 50%; 25% inhibition was achieved by 0.65 microM ethoxzolamide. Inhibition constant (Ki) values for CA activity of disrupted mitochondria at 37 degrees C were 0.03 microM ethoxzolamide and 0.16 microM acetazolamide, and for disrupted hepatocytes were 150 microM ethoxzolamide and 50 microM acetazolamide. p-Aminomethylaminosulfonamide-affinity column purification yields one band of 29,000 mol wt for CA V purified from disrupted mitochondria; homogenized whole-liver supernatant yields an additional band of 20,000 mol wt (at greater than 100 times the concentration of CA V), which has some glutathione S-transferase activity. It is concluded that this 20,000-mol wt protein modifies the potency of ethoxzolamide in the liver cytosol.
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PMID:Inhibition of mitochondrial carbonic anhydrase and ureagenesis: a discrepancy examined. 312 80

Acrylonitrile caused thiobarbituric acid-positive reactants time- and concentration-dependently in isolated hepatocytes. This effect was markedly enhanced by gassing of the medium with 95% oxygen-5% CO2 gas mixture. Glycidonitrile, an acrylonitrile metabolite, proved more potent in this respect than the parent acrylonitrile or its end metabolite, cyanide anion. The latter decreased greatly the viability of isolated liver cells but caused thiobarbituric acid-positive reactants only in the presence of diethylmaleate. Acrylonitrile caused also a decrease in the concentration of nonprotein sulfhydryl groups but the oxidation of glutathione (GSH) to GSSG (oxidized glutathione) was not the major mechanism. This might indicate the consumption of GSH in the glutathione S-transferase catalyzed reactions. In contrast to cyanide anion-induced effects acrylonitrile did not affect markedly the viability of hepatocytes.
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PMID:Consequences of acrylonitrile metabolism in rat hepatocytes: effects on lipid peroxidation and viability of the cells. 313 12

The elimination and metabolism of [14-C]-tetrachloroethylene (Tetra) was studied in female rats and mice after the oral administration of 800 mg/kg [14-C]-Tetra. Elimination of unchanged Tetra was the main pathway of elimination in both species and amounted to 91.2% of the dose in rats and 85.1% in mice. [14-C]-Carbon dioxide (CO2) was found to be a trace metabolite of [14-C]-Tetra. Only a small part of the applied dose was transformed to urinary (rats = 2.3%, mice = 7.1%) and fecal (rats = 2.0%, mice = 0.5%) metabolites. The urinary metabolites were separated and quantified by high performance liquid chromatography (HPLC) and identified by gas liquid chromatography/mass spectrometry (GC/MS). The following metabolites could be identified: oxalic acid (8.0% of urinary radioactivity in rats, 2.9% in mice), dichloroacetic acid (5.1%, 4.4%), trichloroacetic acid (54.0%, 57.8%), N-trichloroacetyl-aminoethanol (5.4%, 5.7%), trichloroethanol, free and conjugated (8.7%, 8.0%), S-1,2,2-trichlorovinyl-N-acetylcysteine (N-acetyl TCVC) (1.6%, 0.5%), and another conjugate of trichloroacetic acid (1.8%, 1.3%). The structures of the identified metabolites indicate two different pathways operative in Tetra biotransformation: cytochrome P-450-mediated epoxidation forming reactive metabolites in the liver and conjugation of Tetra with glutathione (GSH) catalyzed by glutathione transferase(s). The formation of reactive intermediates by renal processing of the glutathione conjugates may provide a molecular mechanism for the nephrotoxicity and nephrocarcinogenicity of Tetra in male rats.
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PMID:Identification of S-1,2,2-trichlorovinyl-N-acetylcysteine as a urinary metabolite of tetrachloroethylene: bioactivation through glutathione conjugation as a possible explanation of its nephrocarcinogenicity. 327 76

The capacity of the human adrenal gland to metabolize various xenobiotics was investigated. Adrenal microsomal and mitochondrial preparations showed a maximal absorption at 450 nm for dithionite-reduced cytochromes in the presence of carbon monoxide. Occasionally, absorption maxima at 448 nm were observed with both microsomal and mitochondrial preparations. Microsomal and mitochondrial cytochrome P-450 (448) concentrations were found to be 0.34 and 0.23 nmol/mg protein, respectively. In spite of the high microsomal cytochrome P-450 levels neither the hydrocarbons, benz[a]pyrene (BP) and 7,12-dimethylbenz[a]anthracene (DMBA), nor a variety of other substrates were metabolized to any measurable extent. In contrast, microsomal epoxide hydrolase and soluble glutathione transferase activities were high. The results may explain the low incidence of adrenal cancer in man.
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PMID:Metabolism of xenobiotics in the human adrenal gland. 632 Oct 20

Dihalomethanes are metabolized to carbon monoxide (CO) both in vivo and in vitro. The reaction is catalyzed by the hepatic microsomal cytochrome P-450 dependent mixed function oxidase system. Reaction mechanism studies suggest an initial oxygen insertion reaction followed by rearrangement to a formyl halide intermediate, which in turn decomposes to yield CO. In vitro studies show that [14C]dichloromethane becomes covalently bound to both microsomal protein and lipid. The similar characteristics of metabolism to CO and covalent suggest that a common intermediate, perhaps the formyl halide, may be involved. Dihalomethanes are also metabolized for formaldehyde, formic acid, and inorganic halide. A glutathione transferase located in hepatic cytosol fractions appears to be involved. Reaction mechanism studies suggest that a S-hydroxymethyl glutathione intermediate may yield formaldehyde or be diverted via formaldehyde dehydrogenase/S-formyl glutathione hydrolase to yield formic acid. Haloforms are also metabolized to carbon monoxide both in vivo and in vitro by a hepatic microsomal cytochrome P-450 dependent mixed function oxidase system. In vitro, this reaction is markedly stimulated by sulfhydryl compounds. Reaction mechanism studies suggest an initial oxygen insertion reaction followed by rearrangement to a dihalocarbonyl intermediate, which in turn reacts with sulfhydryl reagents to yield a thiol-S-formyl halide. Subsequent attack by other sulfhydryl compounds would result in the formation of CO and a disulfide.
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PMID:Halogenated methanes: metabolism and toxicity. 677 82

1. The metabolism of a nitrate ester-substituted dihydropyridine derivative (NND) in vitro was characterized with rabbit hepatic microsomes and cytosol. 2. Denitration activity was located in both the microsomal and cytosolic fractions, whereas oxidation to the pyridine analogue was solely located in the microsomal fraction. 3. Oxidation to the pyridine analogue required NADPH and was inhibited by carbon monoxide, miconazole and SKF-525A, suggesting that oxidation was catalysed by P450. 4. Denitration activity in the microsomes required either NADPH or GSH. Together with these results, responses to various inhibitors indicate participation of both P450 and glutathione S-transferase (GST). 5. Denitration activity in cytosol was activated by glutathione (GSH), and by dithiothreitol (DTT) to a greater extent. GSH-dependent denitration was inhibited by S-hexyl GSH, an inhibitor of GST, but DTT-dependent denitration was not. Moreover, the formation patterns of the mono-denitrated metabolites, M1 and M2, were shown to be different in each incubation condition. 6. These results suggest that the denitration of NND in cytosol could be catalysed by a GSH-independent enzyme as well as the GSH-dependent enzyme, GST.
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PMID:Metabolism of a nitrate ester, dihydropyridine derivative in rabbit hepatic microsomes and cytosol. 761 54


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