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)

We have measured the activities of epoxide hydrase in microsomes and glutathione S-epoxidetransferase and glutathione S-aryltransferase in cytosol fractions of liver, lungs, kidneys, and small intestine from fetal and neonatal guinea pigs and rabbits. The rates at which adult values of these enzyme activities are reached in extrahepatic tissues differ from the rates of maturation of the hepatic enzyme activities for both species. In addition, the two pathways of epoxide metabolism studied here developed with age at different rates in any one organ. However, both cytosol glutathione S-transferases showed very similar developmental profiles in any one organ. It was especially interesting that the activities of both glutathione S-transferases were within the adult range in pulmonary cytosol fraction of guinea pig and rabbit before birth. Intestinal microsomes did not have adult values for epoxide hydrase activity until several weeks after birth. A feature common to both epoxide-metabolizing activities in hepatic and extrahepatic organs was a drop in mean specific activity, sometimes not statistically significant, around the time of birth. This decrease appeared to be due to dilution of the active enzyme with other protein, inasmuch as the total organ activity, in general, showed no such decline. We found that the pattern of development of hepatic microsomal epoxide hydrase activity was similar to developmental patterns published by others for hepatic microsomal mixed-function oxidases, and also that development of hepatic cytosol glutathione S-transferase was similar to hepatic development of glutathione S-transferase towards other substrates described in the literature.
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PMID:The perinatal development of epoxide-metabolizing enzyme activities in liver and extrahepatic organs of guinea pig and rabbit. 1 72

One of the main components in the waste products from vinyl chloride industries (EDC-tar), is ethylene dichloride (1,2-dichloroethane). This compound has been tested for mutagenicity on Salmonella typhimurium TA 1535. It is concluded that 1,2-dichloroethane gives a weak direct mutagenic effect, which is enhanced by addition of the postmitochondrial liver fraction (S-9). This activation is NADPH-independent and non microsomal. It is caused by a factor in the soluble fraction (115 000 g supernatant). This activation was further enhanced by the addition of glutathione but not by the addition of L-cysteine, N-acetyl-L-cysteine or 2-mercaptoethanol. No activation was observed when glutathione was added in the presence of a totally denaturated S-9 fraction or in the absence of this fraction. Activation of 1,2-dichloroethane was also found in the presence of glutathione and glutathione S-transferase A and C but not with glutathione S-tranferase B. A synthetic conjugate S-(2-chloroethyl)-L-cysteine gave a strong direct mutagenic effect at concentrations where no effects were seen with 1,2-dichloroethane. It is thus concluded that 1,2-dichloroethane is activated by conjugation to glutathione. Another main component in EDC-tar, 1,1,2-trichloroethane, was not mutagenic under any of our experimental conditions. For comparison 1,2-dibromoethane was also tested and gave a stronger direct mutagenic effect than 1,2-dichloroethane. Like the latter 1,2-dibromoethane was also activated by a NADPH-independent process.
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PMID:The mutagenic effect of 1,2-dichloroethane on Salmonella typhimurium I. Activation through conjugation with glutathion in vitro. 2 3

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

The prostaglandin D synthetase system was isolated from rat brain. Prostaglandin endoperoxide synthetase solubilized from a microsomal fraction catalyzed the conversion of arachidonic acid to prostaglandin H2 in the presence of heme and tryptophan. Prostaglandin D synthetase (prostaglandin endoperoxidase-D isomerase) catalyzing the isomerization of prostaglandin H2 to prostaglandin D2 was found predominantly in a cytosol fraction and was purified to apparent homogeneity with a specific activity of 1.7 mumol/min/mg of protein at 24 degrees C. The enzyme also acted upon prostaglandin G2 and produced a compound presumed to be 15-hydroperoxy-prostaglandin D2. Glutathione was not required for the enzyme reaction, but the enzyme was stabilized by thiol compounds including glutathione. The enzyme was inhibited by p-chloromercuribenzoic acid in a reversible manner. The purified enzyme was essentially free of the glutathione S-transferase activity which was found in the cytosol of brain.
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PMID:Purification and properties of prostaglandin D synthetase from rat brain. 10 31

Comparative studies of in vitro drug metabolism by hepatic and extrahepatic tissues have been complicated by the use of a single experimental tissue, few animal species, and variable experimental conditions. In an attempt to minimize these complications, liver, lung and kidney from rat, mouse, rabbit, hamster, and guinea pig were assayed for standard microsomal and soluble fraction enzymes involved in drug biotransformation. For all species, liver was the most active organ. Kidney and lung activities were usually 15%-40% of those found in liver, with kidney slightly more active than lung. No single species demonstrated total superiority in its drug-metabolizing ability, although hamster showed a large number of instances of greatest activity. The rat was a surprisingly poor representative of drug-metabolizing ability; it was superior to the other four species in less than 25% of the instances studied. All species appeared to N-demethylate aminopyrine equally except for high pulmonary and nearly absent renal activities in rabbit and high hepatic activity in hamster. Rat had the lowest level of cytochrome P-450 and low activity of NADPH-cytochrome c reductase. UDP-glucuronyltransferase activity toward the acceptors p-nitrophenol and o-aminophenol was higher in hamster and rabbit than other species. Guinea pig appeared to have the most active soluble fraction enzymes. Mouse lung and kidney had glutathione S-aryltransferase activities 10-fold greater than any other species and comparable to liver activity from rabbit and hamster.
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PMID:Comparison of in vitro drug metabolism by lung, liver, and kidney of several common laboratory species. 24 Jun 55

Methadone . HCl given in the drinking water for 4 weeks increased microsomal epoxide hydratase activity in the liver of adult male Wistar rats, with no change in aryl hydrocarbon hydroxylase activity. In contrast, in female rats it raised aryl hydrocarbon hydroxylase with no change in epoxide hydratase activity. Gonadectomy altered the effect of methadone on epoxide hydratase, but not on aryl hydrocarbon hydroxylase activity, in both sexes. In ovariectomized rats, but not in controls, methadone nearly doubled the epoxide hydratase activity, whereas in male rats castration decreased the inductive effect of methadone. Gonadectomy had a significant effect on the results of methadone treatment with respect to glutathione S-transferase activity in female rats. A sex difference was noted in the control levels of aryl hydrocarbon hydroxylase and glutathione S-transferase, but not of epoxide hydratase activity. The glutathione S-transferase and aryl hydrocarbon hydroxylase activities were decreased in castrated male rats, whereas epoxide hydratase activity was unaltered. It is concluded that sex hormones play an important role in the induction of epoxide hydratase and glutathione S-transferase by methadone, but not of aryl hydrocarbon hydroxylase, at this particular dosage regime.
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PMID:The effects of gonadectomy on the hepatic activities of aryl hydrocarbon hydroxylase, epoxide hydratase, and glutathione S-transferase in Wistar rats pretreated with oral methadone . HCl. 44 29

An in vitro assay for the determination of the activity of disopyramide-N-dealkylation was developed. This reaction was concluded to be catalyzed by the liver microsomal, cytochrome P-450 centered monooxygenase system. Phenobarbital enhanced the N-dealkylation of disopyramide four fold, and disopyramide itself 1.6 fold, whereas methylcholanthrene was without effect. Disopyramide also increased ethoxycoumarin deethylation 1.6 fold, and had a slight increasing effect on the activity of epoxide hydratase, but did not affect the activities of glutathione S-transferase or UDPglucuronosyltransferase.
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PMID:Induction of disopyramide N-dealkylation by phenobarbital and disopyramide in rat liver. 48 13

The administration of trans-stilbene oxide to rats resulted in increased hepatic microsomal and nuclear epoxide hydrase (with styrene oxide (SO), benzo[a]pyrene 4,5-oxide (4,5-BP) as substrates) and aryl hydrocarbon hydroxylase (AHH) activities. Hepatic microsomal aminopyrine N-demethylase, benzphetamine N-demethylase, and ethylmorphine N-demethylase activities were also increased. These increases in microsomal enzyme activity were dose- and time-dependent (about 100% at 200 mg/kg body weight, administered for 2 consecutive days). However, only marginal increases in hepatic microsomal NADPH-cytochrome c reductase activity and cytochrome P-450 content were observed. No apparent proliferation of hepatic endoplasmic reticulum occurred in trans-stilbene oxide pretreated rats. The administration of trans-stilbene oxide has no effect on hepatic glutathione S-transferase activities (with SO or 4,5-BPO as substrates). None of the parameters were affected in pulmonary microsomes from treated rats. The in vitro addition of trans-stilbene oxide (10(-6)--10(-2) M) did not affect hepatic epoxide hydrase or glutathione S-transferase activities.
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PMID:trans-Stilbene oxide: an inducer of rat hepatic microsomal and nuclear epoxide hydrase and mixed-function oxidase activities. 69 68

1. The alkenyl phosphate insecticide, dimethylvinphos, is rapidly metabolized and eliminated by rats and dogs. 2. Metabolism proceeds via demethylation followed by the hydrolysis of desmethyl dimethylvinphos to 2,4-dichlorophenacyl chloride which is further metabolized mainly to 2,4-dichloromandelic acid, 1-(2,4-dichlorophenyl)ethanol (glucuronide) and 2,4-dichlorphenylethanediol (glucuronide). 3. The dechlorination of 2,4-dichlorophenacyl chloride to 2,4-dichloroacetophenone proceeds via the spontaneous formation of S-(2,4-dichlorophenacyl) glutathione which is converted to the ketone by an enzyme-catalysed glutathione-dependent reaction. 4. Demethylation of dimethylvinphos occurs in liver fractions via the action of two enzymes: glutathione S-methyl transferase in the cytosol, and microsomal mono-oxygenase. The relatively high activities of both enzymes in dog liver (compared with rat liver) partly account for the observed differences in metabolism and toxicity of dimethylvinphos in the two species. 5. The glutathione transferase is enhanced twofold by pre-treatment of rats with 0-1% phenobarbital in their drinking water. This treatment also induces the microsomal demethylation 45-fold and results in a greater than 13-fold protective effect against the acute toxic effects of dimethylvinphos.
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PMID:Metabolic demethylation of the insecticide dimethylvinphos in rats, in dogs, and in vitro. 100 19

The effect of glutathione depletor diethylmaleate on rat hepatic glutathione S-transferase and glutathione peroxidase was studied in vivo and in vitro. When diethylmaleate (600 mg/kg) was given i.p. to rats, liver glutathione was depleted within 2 h and recovered to the control level 5 h after diethylmaleate treatment. Both glutathione S-transferase and peroxidase activities in microsomes, not in cytosol, were markedly increased during glutathione depletion and only glutathione S-transferase activity remained at high levels after recovery of the glutathione content. The increase in microsomal glutathione S-transferase and peroxidase activities with concomitant exhaustion of glutathione was also observed by perfusion of the isolated liver with diethylmaleate (10 mM). When liver microsomes were incubated with diethylmaleate in vitro at 37 degrees C, glutathione S-transferase, but not peroxidase, activity was increased; the increase was not reversed by dithiothreitol. These results indicate that diethylmaleate activates microsomal glutathione S-transferase by direct reaction to the enzyme during glutathione depletion and suggest that glutathione S-transferase activity and glutathione peroxidase activity in the microsomal enzyme may be differently regulated.
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PMID:Activation of hepatic microsomal glutathione S-transferase of rats by a glutathione depletor, diethylmaleate. 128 82


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