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)

The mechanism of steroid hydroxylation in rat liver microsomes has been investigated by employing NaIO4, NaClO2, and various organic hydroperoxides as hydroxylating agents and comparing the reaction rates and steroid products formed with those of the NADPH-dependent reaction. Androstenedione, testosterone, progesterone, and 17beta-estradiol were found to act as good substrates. NaIO4 was by far the most effective hydroxylating agent followed by cumene hydroperoxide, NADPH, NaClO2, pregnenolone 17alpha-hydroperoxide, tert-butyl hydroperoxide, and linoleic acid hydroperoxide. Androstenedione was chosen as the model substrate for inducer and inhibitor studies. The steroid was converted to its respective 6beta-, 7alpha, 15-, and 16alpha-hydroxy derivatives when incubated with microsomal fractions fortified with hydroxylating agent. Evidence for cytochrome P-450 involvement in androstenedione hydroxylation included a marked inhibition by substrates and modifiers of cytochrome P-450 and by reagents which convert cytochrome P-450 to cytochrome P-420. The ratios of the steroid products varied according to the type of hydroxylating agent used and were also modified by in vivo phenobarbital pretreatment. It was suggested that multiple forms of cytochrome P-450 exhibiting different affinities for hydroxylating agent are responsible for these different ratios. Horse-radish peroxidase, catalase, and metmyoglobin could not catalyze androstenedione hydroxylation. Addition of NaIO4, NaClO2, cumene hydroperoxide and other organic hydroperoxides to microsomal suspensions resulted in the appearance of a transient spectral change in the difference spectrum characterized by a peak at about 440 nm and a trough at 420 nm. The efficiency of these oxidizing agents in promoting steroid hydroxylation in microsomes appeared to be related to their effectiveness in eliciting the spectral complex. Electron donors, substrates, and modifiers of cytochrome P-450 greatly diminished the magnitude of the spectral change. It is proposed that NaIO4, NaClO2, and organic hydroperoxides promote steroid hydroxylation by forming a transient ferryl ion (compound I) of cytochrome P-450 which may be the common intermediate hydroxylating species involved in hydroxylations catalyzed by cytochrome P-450.
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PMID:The involvement of cytochrome P-450 in hepatic microsomal steroid hydroxylation reactions supported by sodium periodate, sodium chlorite, and organic hydroperoxides. 17 55

1. Metabolism of added hydroperoxides was studied in hemoglobin-free perfused rat liver and in isolated rat hepatocytes as well as microsomal and mitochondrial fractions. 2. Perfused liver is capable of removing organic hydroperoxides [cumene and tert-butyl hydroperoxide] at rates up to 3--4 mumol X min-1 X gram liver-1. Concomitantly, there is a release of glutathione disulfide (GSSG) into the extracellular space in a relationship approx. linear with hydroperoxide infusion rates. About 30 nmol GSSG are released per mumol hydroperoxide added per min per gram liver. GSSG release is interpreted to indicate GSH peroxidase activity. 3. GSSG release is observed also with added H2O2. At rates of H2O2 infusion of about 1.5 mumol X min-1 X gram liver-1 a maximum of GSSG release is attained which, however, can be increased by inhibition of catalase with 3-amino-1,2,4-aminotriazole. 4. A contribution of the endoplasmic reticulum in addition to glutathione peroxidase in organic hydroperoxide removal is demonstrated (a) by comparison of perfused livers from untreated and phenobarbital-pretreated rats and (b) in isolated microsomal fractions, and a possible involvement of reactive iron species (e.g. cytochrome P-450-linked peroxidase activity) is discussed. 5. Hydroperoxide addition to microsomes leads to rapid and substantial lipid peroxidation as evidenced by formation of thiobarbituric-acid-reactive material (presumably malondialdehyde) and by O2 uptake. Like in other types of induction of lipid peroxidation, malondialdehyde/O2 ratios of 1/20 are observed. Cumene hydroperoxide (0.6 mM) gives rise to 4-fold higher rates of malondialdehyde formation than tert-butyl hydroperoxide (1 mM). Ethylenediamine tetraacetate does not inhibit this type of lipid peroxidation. 6. Lipid peroxidation in isolated hepatocytes upon hydroperoxide addition is much lower than in isolated microsomes or mitochondria, consistent with the presence of effective hydroperoxide-reducing systems. However, when NADPH is oxidized to the maximal extent as evidenced by dual-wavelength spectrophotometry, lipid peroxidation occurs at large amounts. 7. A dependence of hydroperoxide removal rates upon flux through the pentose phosphate pathway is suggested by a stimulatory effect of glucose in hepatocytes from fasted rats and by an increased rate of 14CO2 release from [1-14C]glucose during hydroperoxide metabolism in perfused liver.
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PMID:Hydroperoxide-metabolizing systems in rat liver. 117 55

Luminol chemiluminescence was used to evaluate the scavenging of superoxide, hydroxyl and alkoxy radicals by four antioxidants: dipyridamole, diethyldithiocarbamic acid, (+)catechin, and ascorbic acid. Different concentrations of these compounds were compared with well-known oxygen radical scavengers in their capacity to inhibit the chemiluminescence produced in the reaction between luminol and specific oxygen radicals. Hydroxyl radicals were generated using the Fenton reaction and these produced chemiluminescence which was inhibited by diethyldithiocarbamate. Alkoxy radicals were generated using the reaction of tert-butyl hydroperoxide and ferrous ion and produced chemiluminescence which was inhibited equally by all of the compounds tested. For the determination of superoxide scavengers we describe a new, simple, economic, and rapid chemiluminescence method consisting of the reaction between luminol and horseradish peroxidase (HRP). With this method it was found that 40 nmol/l dipyridamole, 0.18 mumol/l ascorbic acid, 0.23 mumol/l (+)catechin, and 3 mumol/l diethyldithiocarbamic acid are equivalent to 3.9 ng/ml superoxide dismutase (specific scavenger of superoxide) in causing the same degree of chemiluminescence inhibition. These results not only indicated that the antioxidative properties of these compounds showed different degrees of effectiveness against a particular radical but also that they may exert their action against more than one radical.
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PMID:Effect of antioxidants on chemiluminescence produced by reactive oxygen species. 131 90

We have demonstrated with electron paramagnetic resonance (EPR) that organic hydroperoxides are decomposed to free radicals by both human polymorphonuclear leukocytes (PMNs) and purified myeloperoxidase. When tert-butyl hydroperoxide was incubated with either PMNs or purified myeloperoxidase, peroxyl, alkoxyl, and alkyl radicals were trapped by the spin trap 5,5-dimethyl-1-pyrroline N-oxide (DMPO). In the case of ethyl hydroperoxide, DMPO radical adducts of peroxyl and alkyl (identified as alpha-hydroxyethyl when trapped by tert-nitrosobutane) radicals were detected. Radical adduct formation was inhibited when azide was added to the incubation mixture. Myeloperoxidase-deficient PMNs produced DMPO radical adduct intensities at only about 20-30% of that of normal PMNs. Our studies suggest that myeloperoxidase in PMNs is primarily responsible for the decomposition of organic hydroperoxides to free radicals. The finding of the free radical formation derived from organic hydroperoxides by PMNs may be related to the cytotoxicity of this class of compounds.
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PMID:Free radical formation from organic hydroperoxides in isolated human polymorphonuclear neutrophils. 166 60

The decomposition of organic hydroperoxides as catalyzed by chloroperoxidase was investigated with electron spin resonance (ESR) spectroscopy. Tertiary peroxyl radicals were directly detected by ESR from incubations of tert-butyl hydroperoxide or cumene hydroperoxide with chloroperoxidase at pH 6.4. Peroxyl, alkoxyl, and carbon-centered free radicals from tertiary hydroperoxide/chloroperoxidase systems were successfully trapped by the spin trap 5,5-dimethyl-1-pyrroline N-oxide, whereas alkoxyl radicals were not detected in the ethyl hydroperoxide/chloroperoxidase system. The carbon-centered free radicals were further characterized by spin-trapping studies with tert-nitrosobutane. Oxygen evolution measured by a Clark oxygen electrode was detected for all the hydroperoxide/chloroperoxidase systems. The classical peroxidase mechanism is proposed to describe the formation of peroxyl radicals. In the case of tertiary peroxyl radicals, their subsequent self-reactions result in the formation of alkoxyl free radicals and molecular oxygen. beta-Scission and internal hydrogen atom transfer reactions of the alkoxyl free radicals lead to the formation of various carbon-centered free radicals. In the case of the primary ethyl peroxyl radicals, decay through the Russell pathway forms molecular oxygen.
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PMID:Peroxyl, alkoxyl, and carbon-centered radical formation from organic hydroperoxides by chloroperoxidase. 254 50

Development of the mitochondrial antioxidant defense system was studied to assess its potential role in the newborn mammal's tolerance to oxidative challenge and to gain insight into the fetal adaptation to a relatively hyperoxic adult environment. Isolated heart, kidney, and liver mitochondria from fetal, newborn, and adult guinea pigs were used. In situ function of the antioxidant enzymes was estimated in mitochondrial suspensions after the addition to selenite or tert-butyl hydroperoxide by determining NAD(P)H oxidation rates spectrophotometrically at 340-375 nm. Kidney and liver mitochondria from newborn animals were less susceptible to selenite and tert-butyl hydroperoxide-induced NAD(P)H oxidation. The pattern of change, however, varied widely with tissue type. Kidney mitochondria displayed the largest change with a 3- to 4-fold increase in rate from the fetal to adult period. NAD(P)H oxidation rates in intact mitochondria did not correlate consistently with glutathione reductase and peroxidase activities in sonicated mitochondria suggesting in situ regulation by other endogenous factors. Immediately after birth, mitochondrial glutathione reductase and peroxidase activities dropped 38-50% and 50-70%, respectively, in all tissues studied. Total glutathione content of heart and liver mitochondria did not change with age. Adult kidney mitochondrial glutathione, however, declined to 24% of fetal values. Mitochondrial superoxide dismutase activity increased 150-300% from the fetal to the adult period in all tissues studied. Perinatal changes in the mitochondrial antioxidant system and their relationship to mitochondrial calcium metabolism are discussed in terms of the newborn's resistance to oxidative stress.
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PMID:Perinatal development of heart, kidney, and liver mitochondrial antioxidant defense. 258 24

Low-level chemiluminescence (C) is thought to be an index of oxidant stress. We measured the relationship between low-level C, pulmonary arterial pressure, and perfusate concentration of thromboxane B2 (TxB2) in isolated perfused rabbit lungs during challenge with tert-butyl hydroperoxide (t-bu-OOH). We also measured glutathione release as another index of oxidant stress. We found that C was correlated with each variable, suggesting that oxidant stress measured by C and by glutathione release stimulated TxB2 production and pulmonary vasoconstriction. We also investigated the contribution of active O2 metabolites produced by prostaglandin (PG) peroxidase to oxidant stress by studying the effects of t-bu-OOH before and after the use of cyclooxygenase and lipoxygenase inhibitors. We found that C was augmented after inhibition, perhaps due to metabolism of t-bu-OOH by peroxidases of both arachidonic acid (AA) metabolic pathways in the absence of their normal substrates. We studied phenylbutazone, thought to inhibit peroxidases, and AA. C during t-bu-OOH administration was not augmented after phenylbutazone and was markedly inhibited after AA administration perhaps because AA competes with t-bu-OOH. To further study the role of peroxidases we pretreated the lungs with the antioxidant dithiothreitol, which inhibits peroxidases involved in both the cyclooxygenase and lipoxygenase pathways. Dithiothreitol nearly abolished C produced by t-bu-OOH and also prevented the increased light caused by eicosatetrynoic acid. We directly tested the hypothesis that C occurred as a result of the interaction of t-bu-OOH and the cyclooxygenase and lipoxygenase enzymes; we measured C when t-bu-OOH was added to purified PGH2 synthase or soybean lipoxygenase. The combination of t-bu-OOH with PGH2 synthase or lipoxygenase led to C that was inhibited by dithiothreitol and by the antioxidant phenol. These results suggest that enzymes involved in AA metabolism can interact with t-bu-OOH and that the action of these enzymes on t-bu-OOH leads to C. The results may mean that lipid peroxides can indirectly contribute to tissue oxidant stress due to production of active O2 metabolites as by-products of their metabolism by AA peroxidases.
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PMID:Hydroperoxide-induced chemiluminescence in rabbit lungs: role of arachidonic acid enzymes. 314 52

Rutin (3',4',5,7-tetrahydroxyflavone-3-rutinoside) was oxidized by a horseradish peroxidase-H2O2 system to an ascorbate-reducible product which had an absorption maximum at about 290 nm and a shoulder at about 440 nm at pH 4. At pH 7.8, ascorbate-reducible compounds and sodium hydrosulfite-reducible and -nonreducible compounds were formed by the oxidation. The ascorbate-reducible compounds consisted of at least two components, the absorption bands of which were at 460-480 nm and about 620 nm. The sodium hydrosulfite-reducible compounds also consisted of two components, and one of the components which had an absorption maximum at about 480 nm seems to be formed from the ascorbate-reducible component of an absorption maximum at the blue region by a nonenzymatic reaction. A mixture of oxidized products of rutin formed by tert-butyl hydroperoxide-dependent oxidation was similar to that formed by the enzymatic reaction. It is discussed that the 3'- and 4'-OH groups of rutin were oxidized by the horseradish peroxidase-H2O2 system and that the oxidized product which could be reduced by ascorbate is an o-quinone derivative.
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PMID:Spectrophotometric study on the oxidation of rutin by horseradish peroxidase and characteristics of the oxidized products. 373 Apr 22

The effects of the xenobiotics, i.e. butylated hydroxytoluene, beta-naphthoflavone, isosafrole, pregnenolone-16 alpha-carbonitrile, trans-stilbene oxide, 3-methylcholanthrene, phenobarbital, 3,3',4,4'-tetrachlorobiphenyl, 2,2',4,4',5,5'-hexachlorobiphenyl, on rat liver cytosolic glutathione transferase and glutathione peroxidase activities have been investigated. Although the glutathione transferase isozymes (measured by the specific substrates ethacrynic acid and delta 5-androstene-3,17-dione) which have been shown to possess peroxidase activity were significantly increased, little or no increase in peroxidase activity (toward cumene hydroperoxide, tert-butyl hydroperoxide or hydrogen peroxide) was observed. Likewise during a 16-day time course following the administration of Aroclor 1254 or fireMaster BP-6 (each 500 mg/kg, i.p.), potent induction of glutathione transferase activities was seen without any significant increases in peroxidase activities. In fact during the second week of the time course, there were significant decreases in selenium-dependent glutathione peroxidase activity (toward hydrogen peroxide). The inverse regulation of these activities, i.e. the depression of selenium-dependent glutathione peroxidase activity following sustained induction of glutathione transferases, may have direct implications for the toxicity of the polyhalogenated aromatic hydrocarbons.
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PMID:Differential regulation of hepatic glutathione transferase and glutathione peroxidase activities in the rat. 405 12

As tert-butyl hydroperoxide is metabolized by the glutatione peroxidase--glutathione reductase enzyme system present in liver mitochondria, rapid and extensive oxidation of NADH and slow NADPH oxidation are observed. This NAD(P)H oxidation can be prevented, or reversed, more effectively by 2-hydroxybutyrate than by isocitrate, indicating an important role of mitochondrial NAD(P)+ transhydrogenase activity in maintaining a high NADPH/NADP+ ratio for glutathione reductase. In Ca2+-loaded mitochondria tert-butyl hydroperoxide-induced NAD(P)H oxidation is followed by Ca2+ release from the mitochondria. If either 2-hydroxybutyrate or isocitrate is present, no Ca2+ release can be induced by the hydroperoxide. Following Ca2+ efflux the NAD(P)H oxidation process becomes irreversible and membrane damage occurs. These late effects do not take place if ruthenium red is added to prevent re-uptake of released Ca2+ by the mitochondria. Thus, we conclude that the metabolism of tert-butyl hydroperoxide leads to a release of mitochondrial Ca2+ via oxidation of pyridine nucleotides, and that subsequent membrane damage is not directly associated with this Ca2+ efflux but results from continued cycling of released Ca2+.
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PMID:Pyridine-nucleotide oxidation, Ca2+ cycling and membrane damage during tert-butyl hydroperoxide metabolism by rat-liver mitochondria. 670 88

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