EC:1.11.1.7 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.11.1.7 (peroxidase)
65,474 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Glutathione (GSH) was oxidized to GSSG in the presence of H2O2, tyrosine, and peroxidase. During the GSH oxidation catalyzed by lactoperoxidase, O2 was consumed and the formation of glutathione free radical was confirmed by ESR of its 5,5'-dimethyl-1-pyrroline-N-oxide adduct. When lactoperoxidase was replaced by thyroid peroxidase in the reaction system, the consumption of O2 and the formation of the free radical became negligibly small. These results led us to conclude that, in the presence of H2O2 and tyrosine, lactoperoxidase and thyroid peroxidase caused the one-electron and two-electron oxidations of GSH, respectively. It was assumed that GSH is oxidized by primary oxidation products of tyrosine, which are phenoxyl free radicals in lactoperoxidase reactions and phenoxyl cations in thyroid peroxidase reactions. When tyrosine was replaced by diiodotyrosine or 2,6-dichlorophenol, the difference in the mechanism between lactoperoxidase and thyroid peroxidase disappeared and both caused the one-electron oxidation of GSH. Iodides also served as an effective mediator of GSH oxidation coupled with the peroxidase reactions. In this case the two peroxidases both caused the two-electron oxidation of GSH.
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PMID:Characterization of one- and two-electron oxidations of glutathione coupled with lactoperoxidase and thyroid peroxidase reactions. 302 21

The mechanism of peroxidative N-dealkylation of alkylamines proceeds via one-electron oxidation to the iminium cation which reacts with water to give the N-hydroxymethyl derivative which decomposes to formaldehyde and the N-demethylated product. This reaction is normally inhibited by glutathione by reduction of the cation radical with subsequent formation of oxidized glutathione (GSSG) with oxygen uptake. It was found that the horseradish peroxidase catalyzed N-demthylation of N,N,N',N'-tetramethylbenzidine (N4-TMB) in the presence of glutathione leads to the formation of water-soluble metabolites identified by high field nuclear magnetic resonance (NMR) and fast atom bombardment (FAB) mass spectrometry as 3,3'-(diglutathion-S-yl) and 2,2'-(diglutathion-S-yl)-N4-TMB. Smaller amounts of (monoglutathion-S-yl)-N4-TMB were also found. Only trace amounts of GSSG were formed and no oxygen uptake was observed. Electron spin resonance (ESR) spectrometry in the presence of 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) did not indicate the presence of a DMPO-glutathionyl adduct. These results indicate that glutathione inhibited the N-demethylation of N4-TMB under the described reaction conditions not by reduction of the cation radical but by conjugate formation. The mechanism of N-demethylation must involve removal of two successive electrons to give the benzoquinone-diimine which undergoes rearrangement to the iminium cation followed by reaction with water.
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PMID:Glutathione conjugate formation without N-demethylation during the peroxidase catalysed N-oxidation of N,N',N,N'-tetramethylbenzidine. 302 52

The peroxidase-H2O2 catalyzed oxidation of certain drugs in the presence of GSH resulted in extensive oxidation to thiyl radicals and GSSG. NADH or arachidonate in place of GSH was also readily oxidized. Extensive oxygen uptake ensued resulting in the formation of superoxide radicals and H2O2. Only catalytic amounts of drugs and low peroxide levels were required, indicating a radox cycling mechanism. Active drugs included morphine, phenothiazines, aminopyrine, p-phenetidine, acetaminophen and 4-N,N-(CH3)2-aminophenol. Other drugs, including dopamine and methyl-alpha-dopa, did not catalyze oxygen uptake, nor was GSH oxidized to GSSG. Instead, GSH was depleted by GSH conjugate formation. Drugs of the former group, e.g. acetaminophen, aminopyrine or N,N-(CH3)2-aniline, have also been found by other investigators to form GSSG and hydrogen peroxide when added to hepatocytes or when perfused through an isolated liver. Although cytochrome P-450 normally catalyzes a two-electron oxidation of drugs, serious consideration should be given to some one-electron oxidation occurring as well and resulting in radical formation, oxygen activation and GSSG formation.
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PMID:Oxygen activation during drug metabolism. 311 75

The present study investigated the inflammatory responses and enzyme levels in lungs isolated from male Wistar rats after 3 d of continuous exposure to 0.75 ppm ozone and following 4 d of recovery in air. These times are associated with maximal proliferation of the alveolar type II epithelium and their subsequent transformation to new type I cells. Immediately following ozone exposure, bronchoalveolar lavage demonstrated neutrophil accumulation that was no longer present 4 d later. The number of lavaged macrophages was also found to be increased immediately following ozone exposure, and remained elevated at 4 d postexposure. Whole-lung determinations of key enzymes involved in energy generation (succinate oxidase) and maintenance of lung NADPH and reduced glutathione were corrected for changes in cell number, by use of lung DNA measurements. Immediately following ozone exposure succinate oxidase (SOX), glucose-6-phosphate (G6PD), and 6-phosphogluconate (6PGD) dehydrogenase activities per milligram DNA were significantly enhanced by 76%, 48%, and 21%, respectively. These data suggested that ozone-exposed lungs had cells with increased mitochondria and NADPH-generating capability consistent with the increased metabolic needs of a proliferating epithelium. At 4 d postexposure, only G6PD activity per milligram DNA remained higher by 22% than air-exposed controls. Although both glutathione reductase (GSSG-R) and peroxidase (GSH-Px) activities per lung were elevated in lungs immediately following exposure and 4 d later, when corrected for DNA only GSH-Px activity was significantly increased by 29% in lungs after the postexposure period. Lungs 4 d postexposure therefore had cells relatively enriched in G6PD and GSH-Px that might account for the increased ozone tolerance that has previously been associated with the formation of new type I epithelium.
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PMID:Rat lung recovery from 3 days of continuous exposure to 0.75 ppm ozone. 318 1

In perfused rat liver menadione elicits substantial oxidation in both the NADPH and GSH redox systems. Biliary excretion of GSSG is increased several-fold. Menadione derivatives appear in the bile predominantly as the menadione-S-glutathione conjugate, thiodione (60%), or as conjugates derived therefrom (17%). About 10% appear as menadione glucuronides. The excretion of taurocholate into bile is strongly inhibited upon menadione infusion. The inhibition of taurocholate excretion is small in livers with a low content of Se-GSH-peroxidase and in glutathione-depleted livers. In these livers intracellular GSSG and biliary GSSG release remain at low values, although menadione still imposes oxidative stress as indicated by an oxidation of intracellular NADPH. Under anoxic conditions menadione has little influence on both the NADPH and GSH redox systems and also on biliary taurocholate excretion. The amount of thiodione released into bile is similar to that found under normoxia, whereas the amount of glucuronidated products almost doubled. We conclude (a) that intracellular formation of GSSG by menadione occurs via the generation of hydrogen peroxide; (b) that the inhibition of biliary taurocholate excretion by menadione is related to the increased formation of glutathione disulfide; and (c) that menadione derivatives show little, if any, contribution to the inhibition of taurocholate excretion.
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PMID:Inhibition of biliary taurocholate excretion during menadione metabolism in perfused rat liver. 336 54

In the testes of rats treated with cadmium acetate (7 or 20 mumoles/kg, 24 hr, s.c.), the activity of glutathione (GSH)-peroxidase was increased. At the same time, the activity of glutathione disulfide (GSSG)-reductase and the cellular GSH concentration were decreased significantly. The basal activity of peroxidase in the Leydig and the Sertoli cell populations was comparable. However, the magnitude of increases in the activities markedly differed in the two cell populations, with that of the Sertoli cells increasing to nearly 450% of the control value in response to treatment with 20 mumoles/kg Cd2+. In the Leydig cells, the enzyme activity in response to the same treatment increased to only about 170% of the control value. Cd2+ treatment increased the concentration of heme in the microsomal and the smooth and rough endoplasmic reticulum fractions of the whole testis, as well as in the microsomal fractions of the Leydig and the Sertoli cells. As with the peroxidase activity, the two cell populations vastly differed in their susceptibilities to Cd2+ treatment, with the Sertoli cells being more severely affected by the metal. In the Sertoli cells the microsomal heme concentration was increased by approximately 11-fold, whereas only a 2-fold increase in the Leydig cells was noted. The increase in GSH-peroxidase activity was not due to the peroxidase activity of GSH-S-transferases, insofar as an increase in transferase activity was not observed in the Leydig and the Sertoli cells. Treatment of rats with sodium selenite (10 mumoles/kg, s.c.) 30 min before Cd2+ treatment (20 mumoles/kg) fully suppressed the above-described spectrum of effects of Cd2+ in the testis. Also, sodium selenite at a lower dose of 5 mumoles/kg prevented an increase in GSH-peroxidase activity. It is hypothesized that increased GSH-peroxidase activity in the Leydig and the Sertoli cells constitutes an adaptive response to increased cellular levels of heme and to the free radicals generated by the heme molecule. Selenium prevents the increase in GSH-peroxidase activity by circumventing the increase in cellular heme concentration. The protection is believed to be related, at least in part, to increased production of cellular GSH.
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PMID:Differential effect of cadmium on GSH-peroxidase activity in the Leydig and the Sertoli cells of rat testis. Suppression by selenium and the possible relationship to heme concentration. 359 23

1. Duplicate groups of rainbow trout (Salmo gairdneri) were each given partially purified diets which were either adequate or depleted in selenium for 40 weeks. 2. Although there was no significant difference in weight gain, liver Se concentration was significantly lower in fish given the deficient diet. 3. Glutathione (GSH) peroxidase (EC 1.11.1.9) activity was significantly reduced in liver of Se-deficient fish but a differential assay did not indicate the presence of a non-Se-dependent GSH peroxidase activity, although liver GSH S-transferase (EC 2.5.1.18) was significantly increased. 4. Perfusion of livers from trout given Se-adequate diets with t-butyl hydroperoxide (BuOOH) or hydrogen peroxide caused an increase in the rate of release of glutathione disulphide (GSSG) into the perfusate. 5. Perfusion of livers from Se-deficient trout with BuOOH or H2O2 did not result in any change in rate of release of GSSG into the perfusate. 6. These findings confirm the absence of any compensatory non-Se-dependent peroxidase activity in Se-depleted trout.
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PMID:Effect of selenium deficiency on hydroperoxide-stimulated release of glutathione from isolated perfused liver of rainbow trout (Salmo gairdneri). 367 22

Metabolism of menadione (2-methyl-1,4-naphthoquinone) results in the rapid oxidation of NADPH within isolated rat hepatocytes. The glutathione redox cycle is thought to play a major role in the consumption of NADPH during menadione metabolism, chiefly through glutathione reductase (GSSG-reductase). This enzyme reduces oxidized glutathione (GSSG), formed via the glutathione-peroxidase reaction, with the concomitant oxidation of NADPH. To explore the relationship between GSSG-reductase and the consumption of NADPH during menadione metabolism, isolated rat hepatocyte suspensions were exposed to non-lethal and lethal menadione concentrations (100 and 300 microM respectively) following the inhibition of GSSG-reductase with 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). Menadione produced a concentration-related depletion of GSH (measured as non-protein sulfhydryl content) which was potentiated markedly by BCNU. Menadione toxicity was potentiated at either concentration by BCNU based on lactate dehydrogenase leakage at 2 hr. In addition, the NADPH content of isolated hepatocytes rapidly declined following exposure to either concentration of menadione. However, at the lower menadione concentration (100 microM), the NADPH content returned to control values or above by 60 min, whereas the NADPH content of cells exposed to 300 microM menadione with or without BCNU remained depressed for the duration of the incubation. These data suggest that, although NADPH is required by GSSG-reductase for the reduction of GSSG to GSH during quinone-induced oxidative stress, this pathway does not appear to be the major route by which NADPH is consumed during the metabolism of menadione in isolated hepatocytes.
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PMID:Role of glutathione reductase during menadione-induced NADPH oxidation in isolated rat hepatocytes. 368 27

The interaction of N-(4-ethoxyphenyl)p-benzoquinone imine (NEPBQI), a metabolite formed during peroxidase catalyzed metabolism of p-phenetidine, with GSH and its effects in isolated rat hepatocytes were investigated. When reacted with GSH NEPBQI formed both a mono- and a diglutathione conjugate as well as GSSG. Formation of glutathione conjugates and GSSG also occurred when NEPBQI was added to isolated hepatocytes. The formation of GSSG was, however, only detectable if the hepatocytes had been pretreated with the GSSG reductase inhibitor BCNU (1,3-bis-(2-chloroethyl-1-nitrosourea). Similarly, NEPBQI caused a rapid decrease in cellular free protein thiols when added to hepatocytes, however this was expressed at higher concentrations than for effects on GSH. The protein thiol decrease was correlated with protein binding of NEPBQI. NEPBQI was also shown to be toxic to isolated hepatocytes. At a concentration of 400 microM extensive bleb formation was followed by loss of cell membrane integrity and cell death. To assess further the subcellular metabolism of NEPBQI microsomes and cytosol was used. NEPBQI was found to be preferentially reduced by cytochrome P-450 reductase in the microsomes whereas DT-diaphorase catalyzed its reduction in cytosol. NEPBQI did not undergo significant redox cycling since no formation of O2 was observed. Thus, the cytotoxic effect of NEPBQI appears to be due to protein arylation rather than redox cycling.
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PMID:Cellular effects of N(4-ethoxyphenyl)p-benzoquinone imine, a p-phenetidine metabolite formed during peroxidase reactions. 379 94

Garlic oil, onion oil and one of its constituents, dipropenyl sulfide, all increase, to diverse degrees, glutathione (GSH) peroxidase (GSH:H2O2 oxidoreductase, EC 1.11.1.9) activity in isolated epidermal cells incubated in the presence or absence of the potent tumor promoter 12-0-tetradecanoylphorbol-13-acetate (TPA). The stimulatory effects of these oils on epidermal GSH peroxidase activity are concentration-dependent and long-lasting, and thus, abolish totally the prolonged inhibitory effect of TPA on this enzyme. Moreover, garlic oil (5 micrograms/ml) inhibits by about 50% TPA-induced ornithine decarboxylase (ODC, L-ornithine carboxy-lyase, EC 4.1.1.17) activity in the same epidermal cell system. This concentration of garlic oil also increases remarkably GSH peroxidase activity and inhibits ODC induction in the presence of various nonphorbol ester tumor promoters. Since the same oil treatments inhibit dramatically the sharp decline in the intracellular ratio of reduced (GSH)/oxidized (GSSG) glutathione caused by TPA, it is suggested that some of the inhibitory effects of garlic and onion oils on skin tumor promotion may result from their enhancement of the natural GSH-dependent antioxidant protective system of the epidermal cells.
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PMID:Effects of garlic and onion oils on glutathione peroxidase activity, the ratio of reduced/oxidized glutathione and ornithine decarboxylase induction in isolated mouse epidermal cells treated with tumor promoters. 380 49

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