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)

Tyrosinase (EC 1.14.18.1)/O2, ceruloplasmin (human type X)/O2, and peroxidase (EC 1.11.1.7)/H2O2 oxidized the endogenous central nervous system alkaloid salsolinol (SAL) at physiological pH. The proximate oxidation product was an electrophilic ortho-quinone (4) which at pH 7.0 rapidly tautomerized. Four major initial products were formed from 4: cis- and trans-1,2,3,4-tetrahydro-1-methyl-4,6,7-isoquinolinetriol (A and B, respectively), 2,3,4-trihydro-1-methyl-7-hydroxy-6-oxyisoquinoline (C), and 1-methyl-6,7-isoquinoline diol (D). Mechanisms describing the formation of these products have been presented. Ortho-quinone 4, formed in the enzyme-mediated reactions, was rapidly attacked by glutathione to yield the 5-S-, 8-S-, and 5,8-bi-S-glutathionyl conjugates of SAL. Preliminary experiments indicated that injection of A, B and C into the CNS of mice evoked profound behavioral effects. Quinone methide C was toxic. The potential role of the oxidation of salsolinol in the neurodegenerative and behavioral effects associated with chronic alcoholism is discussed.
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PMID:Interactions of salsolinol with oxidative enzymes. 165 22

Bone marrow stroma consists predominately of two cell types, macrophages and fibroblastoid stromal cells, which regulate the growth and differentiation of myelopoietic cells via the production of growth factors. We have previously shown that macrophages are more sensitive than fibroblastoid stromal cells (LTF cells) to the toxic effects of the benzene metabolite hydroquinone. In this study, the role of selective bioactivation and/or deactivation in the macrophage-selective effects of hydroquinone was examined. LTF and macrophage cultures were incubated with 10 microM [14C]hydroquinone to examine differential bioactivation. After 24 hr, the amount of 14C covalently bound to acid-insoluble macromolecules was determined. Macrophages had 16-fold higher levels of macromolecule-associated 14C than did LTF cells. Additional experiments revealed that hydroquinone bioactivation to covalent-binding species was hydrogen peroxide dependent in macrophage homogenates. Covalent binding in companion LTF homogenates was minimal, even in the presence of excess hydrogen peroxide. These data suggest that a peroxidative event was responsible for bioactivation in macrophages and, in agreement with this, macrophages contained detectable peroxidase activity whereas LTF cells did not. Bioactivation of [14C]hydroquinone to protein-binding species by peroxidase was confirmed utilizing purified human myeloperoxidase in the presence of hydrogen peroxide and ovalbumin as a protein source. High performance liquid chromatographic analysis of incubations containing purified myeloperoxidase, hydroquinone, and hydrogen peroxide showed that greater than 90% of hydroquinone was removed and could be detected stoichometrically as 1,4-benzoquinone. 1,4-Benzoquinone was confirmed as a reactive metabolite formed from hydroquinone in macrophage incubations using excess GSH and trapping the reactive quinone as its GSH conjugate, which was measured by high performance liquid chromatography with electrochemical detection. The activity of DT-diaphorase, a quinone reductase that has been invoked as a protective mechanism in quinone-induced toxicity, was 4-fold higher in LTF cells than macrophages. These data suggest that the macrophage-selective toxicity of hydroquinone results from higher levels of peroxidase-mediated bioactivation and/or lower levels of DT-diaphorase-mediated detoxification.
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PMID:Bone marrow stromal cell bioactivation and detoxification of the benzene metabolite hydroquinone: comparison of macrophages and fibroblastoid cells. 215 73

We have recently demonstrated that butylated hydroxyanisole (BHA) markedly stimulates the peroxidase-dependent oxidation of butylated hydroxytoluene (BHT) to the potentially toxic BHT-quinone methide. Using both horseradish peroxidase and prostaglandin H synthase we now report the ability of a wide variety of compounds to stimulate peroxidase-dependent activation of BHT. These compounds include several phenolic compounds commonly present in pharmacologic preparations or occurring naturally in foods. The ability of a given compound to stimulate BHT oxidation was found to depend on the type of radical it forms upon peroxidase oxidation. Compounds which have been shown to form phenoxy radicals or nitrogen-centered cation radicals were observed to enhance BHT oxidation. Conversely, compounds which are known to form peroxy radicals or semiquinone radicals either inhibited or had no effect on BHT oxidation. Compounds which enhanced BHT oxidation (monitored by covalent binding of [14C]BHT to protein) were also observed to stimulate the formation of BHT-quinone methide and stilbenequinone. This suggested a common mechanism of interaction of these compounds with BHT. The stimulation of BHT covalent binding by BHA was also seen in various human and animal tissues using either arachidonic acid or hydrogen peroxide as substrate. The possible toxicologic implications of the enhancement of peroxidase-catalyzed BHT oxidation to BHT-quinone methide are discussed.
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PMID:Enhancement of the peroxidase-mediated oxidation of butylated hydroxytoluene to a quinone methide by phenolic and amine compounds. 251 Sep 48

The metabolism of secondary phenolic metabolites of benzene, such as catechol, by peroxidases represents one possible mechanism underlying benzene-induced myelotoxicity. The oxidation of catechol by horseradish peroxidase and peroxidases present in human leukocytes was therefore examined. Peroxidatic oxidation resulted in o-benzoquinone production, which was characterized as its bromothiophenol adduct. o-Benzoquinone-glutathione conjugates were formed during peroxidatic oxidation of catechol in the presence of glutathione. Both mono- and diglutathione conjugates were detected. As much as 80% of catechol removed during peroxidatic oxidation could be recovered as glutathione conjugates of o-benzoquinone. Glutathione had no inhibitory effect on the removal of catechol during peroxidatic oxidation. In the presence of divalent cations (Mg2+, Zn2+), however, which slow the rate of o-semiquinone disproportionation, glutathione was found to inhibit catechol removal. This suggests that in the absence of stabilizing metal, reduction of the o-benzosemiquinone radical by glutathione cannot compete with other rapid reactions of the radical such as disproportionation. No interaction of the o-benzosemiquinone radical with oxygen could be detected even in the presence of stabilizing metals or superoxide dismutase which inhibits the reverse reaction of the SQ + O2 in equilibrium Q + O.2 equilibrium. Thus, under physiological conditions, glutathione and oxygen would not be expected to reduce or oxidize respectively the o-benzosemiquinone radical. These data show that the generation of thiol conjugates of o-benzoquinone can be used as probes of peroxidatic oxidation of catechol.
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PMID:Oxidation of catechol by horseradish peroxidase and human leukocyte peroxidase: reactions of o-benzoquinone and o-benzosemiquinone. 283 75

N,N-Dimethyl-p-anisidine (DMA) was used as a substrate to differentiate between the direct, or chloride-independent, and the indirect, or chloride-dependent, pathways characteristic of myeloperoxidase (donor: hydrogen-peroxide oxidoreductase, EC 1.11.1.7). The chemical oxidation by sodium hypochlorite and the horseradish peroxidase-catalyzed oxidation by H2O2 were also investigated for a comparison. The chemical oxidation of DMA by NaOCl (DMA/NaOCl = 1) gave the p-N,N-dimethylaminophenoxy radical at pH 5 and 7. p-Benzoquinone and formaldehyde were determined as stable end-products. On the other hand, the cation radical of DMA was detected and p-benzoquinone was not obtained in the horseradish peroxidase-H2O2-Cl- system. In the presence of Cl- the myeloperoxidase-catalyzed oxidation at pH 5 gave nearly the same result as did the oxidation by NaOCl, whereas in the absence of Cl- the result of the oxidation was similar to that of the horseradish peroxidase-catalyzed oxidation, except for a low yield of formaldehyde formation, which was ascribed to the decomposition of H2O2 by the catalase activity of myeloperoxidase. Although the myeloperoxidase-catalyzed oxidation of DMA at pH 7 in the presence of Cl- gave only the cation radical of DMA, a fairly large amount of p-benzoquinone was obtained as a product. This result indicates that the indirect chloride-dependent oxidation is also operating at pH 7. The reaction mechanism for the myeloperoxidase-catalyzed oxidation of DMA is proposed.
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PMID:ESR studies on the oxidation of N,N-dimethyl-p-anisidine and its analogues catalyzed by myeloperoxidase. 302 17

Membrane-bound and dodecyloctaoxyethyleneglycol monoether-solubilized Na,K-ATPases from pig kidney were covalently attached to microtiter plate wells pretreated with p-benzoquinone (plus collodion for some plates). The immobilized enzymes were detected with the mouse monoclonal antibody (named 38) specific to Na,K-ATPase and a perioxidase-conjugated rabbit IgG anti-mouse IgG. When the two Na,K-ATPase preparations were applied to each well at the same protein concentration, the color intensity of the peroxidase reaction for determination of antibody was two to three times stronger with the solubilized enzyme than with the membrane-bound enzyme. Similar titer values were obtained from the graphical analysis of titration curves of both enzymes. Red cell membrane proteins as well as Na,K-ATPase were covalently attached to the plastic. p-Benzoquinone should be generally useful for coupling membrane proteins, even in detergent solutions, to microtiter plate wells.
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PMID:Coupling of membrane-bound and detergent-solubilized sodium- and potassium-activated ATPase to p-benzoquinone-treated microtiter plates. 609 21

The ESR-spin stabilization approach has been employed to detect and characterize o-semiquinone radicals from the oxidation of epinephrine and related materials (norepinephrine, 3,4-dihydroxynorephedrine, isoproterenol, and adrenalone) in aqueous solutions. Semiquinones were generated by various oxidative procedures--enzymatic oxidation (with horseradish peroxidase/H2O2), chemical oxidation (with Ag2O) and photooxidation--and subsequently kinetically stabilized through complexation with Zn2+ ions. This "spin stabilization" affords high radical concentrations, which has allowed unambiguous identification of the radical intermediates. Where appropriate, spectral assignments have been supported by deuterium substitution experiments and computer simulations of spectra. Two types of free radical have been identified: primary "open chain" semiquinones, formed by one-electron oxidation of the parent catecholamines, and secondary semiquinones, formed subsequent to cyclization reactions. The mechanism of formation of the secondary radicals is discussed, and it is concluded that they are derived from product aminochromes. Thus, oxidation of adrenochrome gives a radical identical to the secondary species observed from oxidation of epinephrine.
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PMID:Electron spin resonance-spin stabilization of semiquinones produced during oxidation of epinephrine and its analogues. 632 6

Using spin stabilization, ESR measurements have been made of o-semiquinone production from the horseradish peroxidase-H2O2 oxidation of catecholamine substrates. The termination rate constant for semiquinones stabilized with Zn2+ at pH 5 is about 10(4) times smaller than for uncomplexed semiquinones at neutral pH. Stabilization allows steady state concentrations of semiquinones to be obtained. The duration of the steady state is dependent upon the concentrations of enzyme, hydrogen peroxide, and catecholamine substrate. The relative reactivity of the substrates 3,4-dihydroxyphenylalanine, norepinephrine, and dopamine at pH 5 is 1:8:40. The effects of phenol and ascorbate were studied and shown to be consistent with scavenging of phenoxyl radicals by catecholamine and semiquinone radicals by ascorbate, respectively.
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PMID:Peroxidatic oxidation of catecholamines. A kinetic electron spin resonance investigation using the spin stabilization approach. 633 64

Exposure to benzene, a human and animal carcinogen, results in the formation of structural chromosomal aberrations in the bone marrow and blood cells of animals and humans. The mechanisms underlying these clastogenic effects are unknown. Inhibition of enzymes involved in DNA replication and repair, such as topoisomerase enzymes, by the metabolites of benzene represents a potential mechanism for the formation of chromosomal aberrations. To test this hypothesis, the inhibitory effects of various phenolic and quinone metabolites of benzene on the activity of human topoisomerases I and II were studied in vitro. No inhibition of topoisomerase I was seen with any of the tested metabolites. Inhibitory effects on topoisomerase II were not observed for hydroquinone, phenol, 2,2'-biphenol, 4,4'-biphenol and catechol at concentrations as high as 500 microM. 1,4-Benzoquinone and 1,2,4-benzenetriol inhibited topoisomerase II at relatively high 500 and 250 microM concentrations, respectively. However following bioactivation using a peroxidase/H2O2 system, inhibitory effects were seen at concentrations as low as 50 microM for both phenol and 2,2'-biphenol and 10 microM for 4,4'-biphenol. The addition of reduced glutathione (GSH) to the 4,4'-biphenol and horseradish peroxidase reaction system protected topoisomerase II from inhibition suggesting that diphenoquinone or another oxidation product formed from 4,4'-biphenol might be the reactive species. These in vitro results indicate that inhibition of topoisomerase II may contribute to the clastogenic and carcinogenic effects of benzene. In addition, metabolites formed from these phenolic compounds appear to represent several new types of topoisomerase II-inhibiting compounds.
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PMID:Topoisomerase inhibition by phenolic metabolites: a potential mechanism for benzene's clastogenic effects. 758 26

A single intramuscular injection of 2 mg estradiol valerate (EV) results in neuronal degeneration and beta-endorphin depletion in the hypothalamic arcuate nucleus of adult female rats. We have hypothesized that peroxidase-positive astrocytes in this brain region oxidize estrogens and catecholestrogens to semiquinone radicals which mediate oxidative neuronal injury. In the present study, dietary administration of the potent antioxidant 21-aminosteroid, U-74389F, completely blocked EV-induced beta-endorphin depletion in the hypothalami of adult female rats. Neither EV nor 21-aminosteroid treatment had any effect on hypothalamic concentrations of neuropeptide Y and Met-enkephalin, confirming that the estradiol lesion is fairly selective for the beta-endorphin cell population. The present findings support the hypothesis that the toxic effect of estradiol on hypothalamic beta-endorphin neurons is mediated by free radicals.
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PMID:The 21-aminosteroid antioxidant, U74389F, prevents estradiol-induced depletion of hypothalamic beta-endorphin in adult female rats. 795 15


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