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

Generation of radicals in vivo depends on metabolic activities. The reactions are usually influenced by (i) the presence and concentration of oxygen; (ii) the availability of transition metals (effects of binding and compartimentalization); (iii) the level of reductants and antioxidants (e.g. nutritional effects). The effects of radicals are thought to be due to (i) membrane damage (affecting passive or active transport through altered fluidity/function interrelationships, intercellular messenging through modifications in the synthesis of prostaglandins and leukotrienes); (ii) protein damage (e.g. affecting membrane transporters, channel proteins, receptor or regulatory proteins, immunomodulators); (iii) damage to DNA. Defense mechanisms consist of (i) prevention of the 'spreading' of primary damage by low molecular weight antioxidants (e.g. vitamin E, GSH, vitamin C, beta-carotene, uric acid); (ii) prevention or limitation of 'secondary' damage by enzymes (e.g. GSH-peroxidase, catalase, superoxide dismutase, DT-diaphorase) and/or chelators; (iii) repair processes, e.g. lipid degradation/membrane repair enzymes (phospholipases, peroxidases, some transferases and reductases), protein disposal or repair enzymes (proteases, GSSG-reductase), DNA degradation repair enzymes (exonuclease III, endonucleases III and IV, glycosylases, polymerases). Recent hypotheses on a messenging function of the superoxide anion O2- are discussed and possible implications of cross-reactions between O2- and nitric oxide (endothelium-derived relaxing factor EDRF) are shortly mentioned.
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PMID:Radical reactions in vivo--an overview. 228 Nov 32

Though various chemotherapy protocols lead to considerable response rates in squamous cell head and neck cancer (SCHNC), the overgrowth of a tumor cell phenotype which no longer responds to clinically achievable drug concentrations regularly impairs definite tumor control. In order to investigate mechanisms of drug resistance towards one of the most active agents in SCHNC we established four Cisplatin (CDDP)-resistant sublines (DDP1-DDP4) of the recloned human SCHNC cell line HLac 79. The 50% inhibitory drug concentration (IC50) of CDDP as determined by the colorimetric MTT-assay was increased by the factors 2.7 (DDP1), 3.3 (DDP2), 5.1 (DDP3), and 6.4 (DDP4) in the respective sublines. Three subpopulations contained significantly elevated glutathione (GSH) levels by the factors 1.4 (DDP3), 1.7 (DDP2), and 2.4 (DDP4) compared to the maternal line (50.2 nM/mg protein). DDP4 showed increased activity of gamma-glutamyl-transpeptidase (1.83 vs. 1.21 mU/mg protein), and DDP2 and DDP4 showed increased activity of GSH-S-transferase (35.6 and 51.9 vs. 25.1 mU/mg protein). Concerning both GSH-peroxidase and GSH-reductase no significant differences between the HLac 79 subpopulations were observed. Intracellular CDDP accumulation determined by neutron activation analysis revealed reduced drug uptake in DDP3 and DDP4 (60% and 76% of control value).
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PMID:Establishment and characterization of cisplatin-resistant sublines of the human squamous carcinoma cell line HLac 79. 228 22

Treatment of rats with cisplatin or with cisplatin after chronic pre-exposure to lead induced a decrease in cytochrome P-450, reduced glutathione (GSH), GSH-S-transferase, reductase and peroxidase activities, and an increase in N-glucuronyl transferase, lipid peroxidation and oxidized glutathione (GSSG). On histological examination, rats treated by lead or cisplatin and by lead + cisplatin revealed significant proximal tubular lesions which varied from minimal changes to severe necrosis. Lead toxicity was characterized by irregularity and thickening of glomerular basement membranes, and by tubular mitochondrial alterations associated with the presence of intranuclear inclusions. Cisplatin injury showed more extensive lesions with cellular disorganization. Except for an increase in N-glucuronyl transferase activity, lead did not exert any significant effect on these biochemical and histological parameters and did not significantly modify the deleterious effects of further therapy by cisplatin.
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PMID:Cisplatin nephrotoxicity in lead-pretreated rats: enzymatic and morphological studies. 230 43

Infusion of menadione at two different doses [2.7 mg and 5.5 mg in 100 microliters of dimethyl sulphoxide (DMSO)] into perfused rat livers for 30 min caused no or a 6-fold increase respectively in junctional permeability to horseradish peroxidase as compared with controls receiving 100 microliters of DMSO alone. The total glutathione (GSH) contents in these livers measured at the end of the experiments were 115% and 53%, compared with the controls. The free-radical scavenger butylated hydroxytoluene (BHT) (final concn. 5 microM) protected against the GSH depletion caused by the higher dose of menadione and partially decreased the menadione-induced increase in junctional permeability. Verapamil, a Ca2(+)-channel blocker which was added into the perfusion medium (final concn. 40 microM) 10 min before the infusion of 5.5 mg of menadione, completely abolished the effect of menadione on junctional permeability. Menadione exposure therefore increases tight-junctional permeability in the liver; this may involve a depletion of GSH and a subsequent increase in intracellular Ca2+.
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PMID:Menadione increases hepatic tight-junctional permeability. Its effect can be decreased by butylated hydroxytoluene and verapamil. 239 83

A simple and sensitive method for the simultaneous visualization of glutathione peroxidase and catalase on polyacrylamide gels is described. The procedure included: (1) running samples on a 7.5% polyacrylamide gel, (2) soaking the gel in a certain concentration of reduced glutathione (0.25-2.0 mM), (3) soaking the gel in GSH plus H2O2 or cumene hydroperoxide, (4) finally staining with a 1% ferric chloride 1% potassium ferricyanide solution. The best concentration of glutathione for simultaneous visualization of glutathione peroxidase in mouse liver homogenates and also it is specific for glutathione peroxidase since other peroxidases such as lactoperoxidase, horseradish peroxidase and glutathione S-transferase cannot be visualized. Using this method, it was found that unlike catalase, glutathione peroxidase is heat resistant (68 degrees C, 1 min), but sensitive to 10 mM sodium iodoacetate.
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PMID:A simultaneous visualization of the antioxidant enzymes glutathione peroxidase and catalase on polyacrylamide gels. 246 58

Nitrogen dioxide (NO2), a major oxidant constituent of vehicle emissions, is toxic to lung cells including endothelial cells. Since NO2 is a reactive free radical, one of the postulated mechanisms of NO2-induced pulmonary injury involves the peroxidation of membrane lipids. Therefore, this study evaluated the dose- and time-dependent effects of nitrogen dioxide exposure by measuring the biochemical and biophysical parameters, as well as the metabolic function, in porcine pulmonary artery and aortic endothelial cells in monolayer cultures. To evaluate the biochemical changes, the antioxidant enzyme GSH-reductase (GSH-red), GSH-peroxidase (GSH-per), and glucose-6-phosphate dehydrogenase (G6PDH) activities, as well as the lipid peroxide formation, glutathione (GSH) content, and lactate dehydrogenase (LDH) release were measured. Biophysical changes were measured by monitoring lipid fluidity in both the hydrophobic and hydrophilic regions of the plasma membrane. The uptake of 5-hydroxytryptamine (5-HT) was measured as a metabolic function of endothelial cells. Confluent porcine pulmonary artery and aortic endothelial cells were exposed to 3 or 5 ppm NO2 or air (control) for 3-24 hours. After 3-, 6-, or 12-hour exposures to 3 or 5 ppm NO2, the GSH-red and G6PDH activities, as well as the lipid peroxide formation and LDH release, were not different from those of controls in both pulmonary artery and aortic endothelial cells. Exposure of the cells to 3 or 5 ppm NO2 for 24 hours resulted in significant increases in GSH-red (p less than 0.05) and G6PDH (p less than 0.001) activities in both cell types. Exposure to 5 ppm NO2 for 24 hours significantly (p less than 0.05) increased lipid peroxide formation and increased (p less than 0.01) LDH release in both the pulmonary artery and aortic endothelial cells. GSH-per activity and GSH content in NO2-exposed pulmonary artery and aortic endothelial cells were not different from those of controls, irrespective of NO2 concentration and exposure time. Fluorescence spectroscopy was used to measure the membrane lipid fluidity. Membrane fluidity in the hydrophobic region was measured by 1,6-diphenyl-1, 3, 5-hexatriene (DPH), an aromatic hydrocarbon that partitions into the hydrophobic interior of the lipid bilayer.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Biochemical and metabolic response to nitrogen dioxide-induced endothelial injury. 247 62

Using two peroxidative systems (prostaglandin H synthase/arachidonic acid and horseradish peroxidase/H2O2) we observed GSH conjugate formation with a number of compounds including polycyclic aromatic hydrocarbon-diols (PAH-diols), insecticides, and steroids. Several of the conjugates were characterized by chromatography, uv-vis spectrophotometry, and FAB mass spectroscopy. Conjugate formation is dependent upon a functioning peroxidase, GSH, and is markedly enhanced (3- to 10-fold) by the inclusion of a number of reducing cosubstrates including phenol, uric acid, phenylbutazone, and acetaminophen. The mechanism of conjugate formation appears to involve addition of thiyl radical to alkene bonds conjugated to an electron releasing group probably by resonance stabilization of the carbon-centered radical intermediate. Thiyl radicals are formed either directly by GSH reduction of the peroxidase or indirectly by GSH reduction of radicals formed from reducing cosubstrates. The nitrone spin trap, 5,5-dimethyl-1-pyrroline N-oxide, which traps thiyl radicals, totally inhibits production of GSH conjugates in both peroxidative systems. Conjugation of PAH-diols, some of which are penultimate carcinogens, would prevent their metabolism to the diol-epoxides, an ultimate carcinogenic species of PAH. Conjugation by peroxidases appears to be a general pathway for glutathione conjugate formation that may lead to potential detoxification of chemicals.
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PMID:Peroxidase-mediated formation of glutathione conjugates from polycyclic aromatic dihydrodiols and insecticides. 249 94

Platelets administered 1-chloro-2,4-dinitrobenzene to deplete intracellular glutathione (GSH) and inhibit GSH-peroxidase responded with irreversible aggregation to low doses of arachidonic acid (AA) more rapidly than control cells. This increase in sensitivity was correlated to inhibition of GSH-peroxidase, and not with the depletion of GSH. Addition of hydrogen peroxide, 15-hydroperoxyeicosatetraenoic acid, or inhibition of the lipoxygenase metabolic pathway by 4,7,10,13-eicosatetraynoic acid also induced a hypersensitive aggregation response to AA. These results suggest that the three modes of treatment share a common mechanism of increasing AA metabolism to biologically active prostaglandins and thromboxane A2 through alterations in cyclooxygenase kinetics and available enzyme substrate.
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PMID:Platelet hypersensitivity induced by 1-chloro-2, 4-dinitrobenzene, hydroperoxides and inhibition of lipoxygenase. 249 41

Selective removal of intracellular glutathione (GSH) and inhibition of the GSH-dependent peroxidase (GSH-Px) by 1-chloro-2,4-dinitrobenzene (CDNB) was used to evaluate the role of GSH and GSH-Px in arachidonic acid (AA) metabolism in human platelets. Although total conversion of AA through the lipoxygenase pathway is lowered by GSH depletion, significant 12-HETE formation was observed suggesting that GSH and GSH-Px are not required for the generation of 12-HETE in human platelets. Prolonged treatment of platelets with CDNB (2 h) completely destroyed GSH-Px activity creating a model in which the effects of GSH alone could be determined. Platelet homogenates replenished with GSH, but lacking GSH-Px activity converted significantly higher amounts of AA to 12-HPETE and 12-HETE than control. Platelet cytosolic metabolism of 15-HPETE to 15-HETE decreased after CDNB, while the membrane metabolism remained similar to control due to high GSH-independent peroxidase activity associated with the membranes. These results indicate that GSH and GSH-Px function to enhance lipoxygenase activity, rather than catalyse the reduction of 12-HPETE to 12-HETE.
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PMID:Role of glutathione and glutathione peroxidase in human platelet arachidonic acid metabolism. 250 28

During the aerobic reaction of soybean lipoxygenase with polyunsaturated fatty acids (linoleic, linolenic, and arachidonic acid) oxygen uptake is followed by excited carbonyl photoemission. The chemiluminescence yield of phi cl = 10(-10) photons/O2 molecule consumed is enhanced 2-3 orders of magnitude by the carbonyl sensitizers 9,10-dibromo-anthracene-2-sulfonate (kET tau 0 = 10(4) M-1; phi cl = 10(-8) photons/O2) and chlorophyll-a (kET tau 0 = 10(6) M-1; phi cl = 10(-7) photons/O2), respectively. alpha,beta-Saturated triplet excited carbonyls as from 1,2-dioxetane cleavage are discussed to arise from a secondary peroxidase/oxidase reaction with aldehydes formed in the course of enzymic lipid peroxidation. When 1 mM glutathione is added to the aerobic lipoxygenase/arachidonate reaction, carbonyl emission (375-455 nm) is replaced by intense red bands (630-645 nm and 695-715 nm) resembling the characteristic spectrum of (1 delta g)O2-singlet oxygen dimol-emission. The quantum yield (phi cl = 10(-8) photons/O2) remains unaffected by chlorophyll indicating that the red emission is independent of excited carbonyls. The effect of GSH is attributed to dioxetane interception and subsequent glutathione peroxidation generating 1O2 by electron transfer from the superoxide anion radical to a peroxysulfenyl radical.
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PMID:The peroxidase/oxidase activity of soybean lipoxygenase--II. Triplet carbonyls and red photoemission during polyunsaturated fatty acid and glutathione oxidation. 250 79


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