Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P06889 (Mol)
 630,302 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The role of various enzymes and biological molecules on the activation and deactivation of the metabolites of phenol was investigated in vitro. Phenol, the major metabolite of benzene, is metabolized to hydroquinone and catechol. Activation of these metabolites and deactivation of their oxidized forms was assessed by the amount of covalent binding to microsomal protein. [14C]Phenol and NADPH were incubated with hepatic microsomes isolated from phenobarbital-pretreated guinea pigs, and 2.33 nmoles of hydroquinone and 0.12 nmole of catechol were formed per minute per milligram of microsomal protein. Covalent binding of the metabolites to microsomal protein incubated with microsomes isolated from guinea pigs pretreated with phenobarbital was 252 pmoles bound/min/mg; with microsomes from untreated guinea pigs, covalent binding was 146 pmoles bound/min/mg. Covalent binding was inhibited greater than 90% with the addition of N-octylamine, ascorbate, or GSH. The addition of superoxide dismutase inhibited covalent binding with microsomes isolated from phenobarbital-pretreated guinea pigs 35% but did not inhibit it with microsomes isolated from untreated animals. Partially purified guinea pig hepatic DT-diaphorase [NAD(P)H (quinone acceptor) oxidoreductase, EC 1.6.99.2] inhibited covalent binding 70%. This effect was reversed in the presence of dicumarol, a specific inhibitor of DT-diaphorase. DT-diaphorase present in the 10(5) X g supernatant fraction was also active in inhibiting covalent binding but only after the removal of endogenous reduced glutathione. This effect could also be reversed by dicumarol. The addition of diaphorase (NADH:lipoamide oxidoreductase, EC 1.6.4.3) partially purified from Clostridium kluyveri inhibited covalent binding 86%. The addition of hydrogen peroxide and horseradish peroxidase (peroxidase, EC 1.11.17) or myeloperoxidase(s) increased covalent binding 30-fold and 6-fold, respectively. Ascorbate decreased this binding greater than 95%. These results indicate that hydroquinone, catechol, and phenol as well as their oxidized forms can be activated or deactivated by several of the above model systems. These systems may play a role in the myelotoxicity of benzene by modulating covalent binding.
Mol Pharmacol 1984 Jul
PMID:DT-diaphorase and peroxidase influence the covalent binding of the metabolites of phenol, the major metabolite of benzene. 674 27

Perturbation of brain protein synthesis by methyl mercury chloride (MeHg) was compared in vivo and in vitro. MeHg-stimulated and/or inhibited brain cell-free protein synthesis following in vivo or in vitro administration. Although pretreatment with GSH protected the postmitochondrial supernatant (PMS) from the in vitro inhibition, direct addition of -SH compounds did not reverse the in vivo or in vitro perturbations in synthesis induced by MeHg. Inhibition of synthesis induced by both in vivo and in vitro methyl mercury administration resulted in inactivation of component(s) in brain pH 5 enzymes. Stimulation of amino acid incorporation following in vivo administration of MeHg was apparently associated with the ribosome fraction, but in vitro preincubation of PMS with MeHg produced stimulation associated with the pH 5 enzyme fraction. A model of MeHg neurotoxicity was proposed providing a common molecular locus of interaction in vivo and in vitro.
Exp Mol Pathol 1983 Apr
PMID:Experimental methyl mercury neurotoxicity: similar in vivo and in vitro perturbation of brain cell-free protein synthesis. 683 46

Ligandin is an abundant soluble protein which has a t 1/2 of 2--3 days, is induced by many drugs and chemicals, and is stabilized in the absence of thyroid hormone. The protein is strategically concentrated in cells associated with transport and detoxification of many endogenous ligands, such as bilirubin, and exogenous ligands, such as drugs and chemicals. The protein is a dimer in rat liver. Whether the dimer is a primary gene product or at least two genes are involved is not known. The protein has broad, low affinity catalytic activity as a GSH-S-transferase for many ligands having electrophilic groups and hydrophobic domains. It catalyzes formation of GSH conjugates, non-covalently binds some ligands prior to their biotransformation or excretion in bile, and covalently binds other ligands, such as activated carcinogens. Recent studies include the possible role of ligandin in chemical carcinogenesis, diagnosis of inflammatory and neoplastic disease of the liver and kidney, and participation in intracellular transport. Although some of the roles that have been outlined are speculative, any single function is important. The GSH-S-transferases are primitive enzymes and non-specific binding proteins but "it is precisely their simplistic design that allows such protean serviceability". Ligandin illustrates a group of hepatic disposal mechanisms which involve bulk transport of ligands. Although specific uptake and transport mechanisms have been described for several hormones which enter the hepatocyte in small quantities and regulate intermediary metabolism and, possibly, cell maturation, bulk transport of ligands into, through and out of the liver involves mechanisms which accomodate many metabolites, drugs and chemicals of diverse structure. The liver is bathed in sewage which contains what we ingest or are injected with and potentially toxic products of intestinal microorganisms. The chemical formulas of the many substances which are metabolized by the liver provide a horror show of potentially reactive and toxic metabolites, mutagens and carcinogens. Despite this alimentary "Love Canal", we and our livers do remarkably well. These hepatic disposal mechanisms, as exemplified by ligandin, evolved in ancient times. They are present, albeit sluggishly, in insects and ancient elasmobranchs. Hepatic uptake and removal mechanisms of high capacity, modest affinity and broad substrate range permit us to live in what has probably always been a threatening world.
Mol Cell Biochem 1980 Feb 08
PMID:Ligandin: an adventure in liverland. 698 95

Mouse liver microsomes were prepared by repeated washing, homogenization, and centrifugation until almost no more soluble enzymes were found in the supernatant of the last centrifugation. About 0.09% of the total glutathione S-transferase activity and comparable amount of soluble enzymes were detected in microsomes solubilized with Emulgen 913. By double immunodiffusion, microsomal glutathione S-transferase were shown to have a complete immunological identity with cytosolic F2 and F3 transferase from mouse liver. By Sephadex gel filtration chromatography in 1% Emulgen 913, part of the microsomal transferase activity (20 to 50%) was shown to be associated with the microsomal membrane protein fraction and appeared in the void volume. Partially purified microsomal transferases were found to have molecular weights, isoelectric points and Km's for substrate and GSH which are comparable to those of soluble liver transferases. This study seems to suggest that the presence of glutathione S-transferases in microsomes is the result of specific and nonspecific association between the microsomal membrane and soluble liver transferases.
Mol Cell Biochem 1982 Oct 18
PMID:Identity of microsomal glutathione S-transferases. 714 47

Mitochondria are an important source of reactive oxygen intermediates because they are the major consumers of molecular oxygen in cells. Respiration is associated with toxicity, which is related to the activation of oxygen to reactive intermediates. The purpose of the present study was to examine the role of reduced glutathione (GSH) in the maintenance of mitochondrial functions during oxidative stress induced through selective inhibition of the complex III segment of the electron transport chain. Hydrogen peroxide monitored by the fluorescence of dichlorofluorescein increased in a time- and dose-dependent manner on incubation of mitochondria with antimycin A (AA), an inhibitor of complex III. However, blockade of complex I or II with rotenone or thenoyltrifluoroacetone, respectively, did not result in accumulation of hydrogen peroxide. Depletion of mitochondrial GSH to 10-20% of control by preincubation with diethylmaleate (0.8 mM) or ethacrynic acid (250 microM) also increased dichlorofluorescein and malondialdehyde levels and resulted in an additional (2-3-fold) increase after AA. Similar results were obtained when mitochondrial GSH depletion was produced by treatment with buthionine L-sulfoximine before mirochondria isolation. The endogenous oxidative stress induced by AA was accompanied by a moderate loss of activity of ATPase complex (77% of control) and complex IV of respiration (75% of control), which was accentuated after depletion of mitochondrial GSH (51% and 45% of control, respectively). Similar results were observed in isolated hepatocytes in which depletion of mitochondrial GSH and AA led to peroxidation and mitochondrial dysfunction. In addition, with electrophoretic mobility shift assay of the transcription factor nuclear factor-kappa B (NF-kappa B), we detected its activation in response to AA (2-3-fold). Depletion of mitochondrial GSH in hepatocytes (20% of control) led to further enhancement of NF-kappa B activation (2-4-fold), which correlated with generation of hydrogen peroxide. Thus, our results suggest that GSH protects mitochondria against the endogenous oxidative stress produced at the ubiquinone site of the electron transport chain. Mitochondrial GSH depletion potentiates oxidant-induced loss of mitochondrial functions. Oxidant stress in mitochondria can promote extramitochondrial activation of NF-kappa B and therefore may affect nuclear gene expression.
Mol Pharmacol 1995 Nov
PMID:Role of oxidative stress generated from the mitochondrial electron transport chain and mitochondrial glutathione status in loss of mitochondrial function and activation of transcription factor nuclear factor-kappa B: studies with isolated mitochondria and rat hepatocytes. 747 12

Nitric oxide (NO) has been demonstrated to play a protective role in cell injury. In this study, we have explored the effect of NO and two NO donors (sodium nitroprusside [SNP] and isosorbide dinitrate [ISDN]) on cellular glutathione (GSH) levels in a rat lung fibroblast cell line (RFL6 cells). SNP and ISDN significantly increased cellular GSH in RFL6 cells (5 x 10(-4) M SNP: 21.9 +/- 3.6 nmol/10(6) cells and 5 x 10(-3) M ISDN: 27.6 +/- 1.7 nmol/10(6) cells versus control: 13.2 +/- 0.4 nmol/10(6) cells; P < 0.05). The stimulatory effect of SNP and ISDN on GSH was first seen at 6 h and peaked at 12 to 24 h. A similar increase in GSH was observed in RFL6 cells exposed to 400 ppm NO for 7.5 h (NO: 20.5 +/- 3.4 nmol/10(6) cells versus control: 11.9 +/- 2.4; P < 0.05). SNP and ISDN also increased cellular GSH in bovine pulmonary artery smooth muscle cells (BPSMC) and bovine pulmonary artery endothelial cells (BPAEC). Buthionine sulfoximine (BSO) (0.01 mM), an inhibitor of the GSH synthetic enzyme gamma-glutamyl cysteine synthetase, blocked the increase in GSH in RFL6 cells seen with both SNP and ISDN. In BPAEC, exposure to NO donors for 24 h stimulated glutamate uptake (SNP: 441 +/- 19 pmol/10 min/10(6) cells and ISDN: 677 +/- 48 pmol/10 min/10(6) min/10(6) cells versus control: 222 +/- 9 pmol/10 min/10(6); P < 0.05). This effect paralleled the increase in GSH. In RFL6 cells, only SNP increased glutamate uptake after 24 h of incubation. In summary, NO and NO donors increase cellular GSH in RFL6 cells, BPAEC, and BPSMC. The mechanism of this effect is unclear but may involve upregulation of the normal GSH synthetic pathways. This observation may explain in part the protective effect of NO seen in some cell culture systems and may contribute to a protective effect against oxidant injury in vivo.
Am J Respir Cell Mol Biol 1995 Oct
PMID:Nitric oxide increases cellular glutathione levels in rat lung fibroblasts. 754 74

Long-Evans Cinnamon (LEC) rats, characterized by a gross accumulation of hepatic Cu and the spontaneous onset of hepatitis, have been established to be an animal model for Wilson disease. They were used to estimate the relationships among copper (Cu), metallothionein (MT), and reduced glutathione (GSH) in biliary excretion in this study. Even though a huge amount of MT existed in the LEC rat liver (5016 micrograms/g liver) compared to that (63 micrograms/g liver) of controls (Fischer rats), the biliary excretion of MT (65 ng/ml bile) did not reflect the accumulated MT level in LEC rats. It seems likely that MT does not excrete intrinsically into the bile. Biliary excretion of Cu (0.17 microgram/ml) in LEC rats was significantly lower than that (0.57 microgram/ml) in Fischer rats. The difference in biliary excretion of GSH between the two groups was significant but slight. The reduced excretion of GSH into bile in LEC rats may be due to increased hepatic gamma-glutamyltransferase but not to hepatic GSH levels. There were no differences in biliary potassium and inorganic phosphorous between the two groups. On the other hand, excretion of lysosomal enzymes such as beta-N-acetylglucosaminidase into bile was much lower in LEC rats (15.6 units/liter) than in controls (42.5 units/liter). The defective biliary excretion of Cu may be due to impaired lysosomal exocytosis, rather than canalicular membrane impairment. The LEC rat is very useful for research into the dynamics of metal excretion via the hepatobiliary system.
Biochem Mol Med 1995 Jun
PMID:Biliary excretion of copper, metallothionein, and glutathione into Long-Evans Cinnamon rats: a convincing animal model for Wilson disease. 755 24

The oxidant-antioxidant imbalance in the lower respiratory tract plays a major role in the pathogenesis in idiopathic pulmonary fibrosis (IPF). However, the systemic oxidant-antioxidant balance in the patients with IPF has not been extensively evaluated. In this study, the metabolism of glutathione (GSH) and superoxide anion production of whole blood were tested in 14 IPF patients and 12 normal subjects. While the total amount of GSH in the blood of IPF patients was not different from that of normal subjects (IPF; 22.9 +/- 4.9 micrograms/ml, control; 26.1 +/- 3.7 micrograms/ml), the amount of oxidized GSH (GSSG) and the ratio of GSSG to the total GSH in blood significantly increased in patients with IPF (IPF; 14.4 +/- 3.5%, control; 7.0 +/- 1.7%, P < 0.01), indicating that the glutathione redox cycle may be impaired in IPF. The production and generation of superoxide anions by blood were significantly greater in IPF than in normal subjects. The level of superoxide anion production was correlated with the GSSG/GSH ratio. These results indicate that IPF patients exhibit an impaired GSH metabolism with an increased oxidant formation of blood.
Biochem Mol Med 1995 Jun
PMID:Superoxide anion formation and glutathione metabolism of blood in patients with idiopathic pulmonary fibrosis. 755 28

Glutathione (GSH) regeneration was studied in rabbit erythrocytes which were loaded with calcium using ionophore A23187. Calcium-loading induced by A23187 and various concentrations of CaCl2 caused a dose-dependent depression in red cell GSH regeneration. The lowered GSH regeneration was mainly due to reduction of ATP level. In an experiment using haemolysate, the effect of calcium per se was negligible, while magnesium strongly affected GSH regeneration by controlling the rate of hexokinase reaction. These results indicate a possibility that cation perturbation, metabolic decay and oxidative damage are all interrelated in the erythrocyte aging process.
Comp Biochem Physiol B Biochem Mol Biol
PMID:Glutathione regeneration in calcium-loaded erythrocytes: a possible relationship among calcium accumulation, ATP decrement and oxidative damage. 755 47

Previous studies have shown that exogenous lactate impairs mechanical function of reperfused ischaemic hearts, while pyruvate improves post-ischaemic recovery. The aim of this study was to investigate whether the diverging influence of exogenous lactate and pyruvate on functional recovery can be explained by an effect of the exogenous substrates on endogenous protecting mechanisms against oxygen-derived free radicals. Isolated working rat hearts were perfused by a Krebs-Henseleit bicarbonate buffer containing glucose (5 mM) as basal substrate and either lactate (5 mM) or pyruvate (5 mM) as cosubstrate. In hearts perfused with glucose as sole substrate the activity of glutathione reductase was decreased by 32% during 30 min of ischaemia (p < 0.10 versus control value), while the activity of superoxide dismutase and catalase was reduced by 27 and 35%, respectively, during 5 min of reperfusion (p < 0.10 versus control value). The GSH level in the glucose group was reduced by 29% following 30 min of ischaemia and 35 min of reperfusion (p < 0.10). In lactate- and pyruvateperfused hearts there were no significant decreases of superoxide dismutase, catalase, glutathione peroxidase and glutathione reductase activity during 30 min of ischaemia, 5 min of reperfusion or 35 min of reperfusion. In pyruvate-perfused hearts the glutathione peroxidase activity was even increased by 43% during 30 min of ischaemia (p < 0.05). Glutathione levels (reduced and oxidized) did not markedly change in the lactate and pyruvate groups.(ABSTRACT TRUNCATED AT 250 WORDS)
Mol Cell Biochem 1995 May 24
PMID:The influence of lactate, pyruvate and glucose as exogenous substrates on free radical defense mechanisms in isolated rat hearts during ischaemia and reperfusion. 756 44


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