Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.17.3.2 (xanthine oxidase)
 8,383 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Myeloperoxidase (MPO), H2O2 and a halide form a powerful antimicrobial system effective against bacteria, fungi, viruses and mammalian cells. After phagocytosis, MPO is released into the phagosome from adjacent granules where it interacts with H2O2 generated either by leukocytic or microbial metabolism and a halide such as chloride or iodide to form agents toxic to the ingested organisms. Evidence for H2O2 and MPO participation in the microbicidal activity of polymorphonuclear leukocytes (PMNs) has been obtained from patients with neutrophil dysfunction. In chronic granulomatous disease, PMNs have a microbicidal defect associated with the absence of the respiratory burst. The importance of H2O2 deficiency in the PMN dysfunction is emphasized by its reversal by H2O2. PMNs which lack MPO also have a major fungicidal and bactericidal defect. Bactericidal activity is particularly low during the early postphagocytic period, after which the organisms are killed. Although emphasizing the importance of MPO-mediated antimicrobial systems particularly during the early postphagocytic period, these findings also indicate the presence of MPO-independent systems which develop slowly but are ultimately effective. The MPO-independent antimicrobial systems may be oxygen-dependent or oxygen-independent. The acetaldehyde-xanthine oxidase system has been used as a model of the MPO-independent, oxygen-dependent antimicrobial systems of the PMN. A microbicidal effect by this system was observed which was inhibited by superoxide dismutase, catalase and scavengers of hydroxyl radicals (OH') and singlet oxygen (1O2). The microbicidal activity of acetaldehyde and xanthine oxidase is increased considerably by MPO and chloride. The formation of ethylene from methional or 2-oxo-4-methylthiobutyric acid by PMNs has been regarded as evidence for OH' formation. We have found ethylene formation to be largely dependent on MPO and evidence for the initiation of ethylene formation by 1O2 has been obtained. Both the xanthine oxidase system and the MPO-H2O2-halide system convert diphenylfuran into cis-dibenzoylethylene, an effect which is compatible with, although not proof of, the formation of 1O2 by these systems.
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PMID:The role of myeloperoxidase in the microbicidal activity of polymorphonuclear leukocytes. 22 42

Erythrocytes are hemolyzed by myeloperoxidase, an H2O2-generating system (glucose + glucose oxidase; hypoxanthine + xanthine oxidase) and an oxidizable cofactor (chloride, iodide, thyroxine, triiodothyronine). The combined effect of chloride and either iodide or the thyroid hormones is greater than additive. Myeloperoxidase can be replaced by lactoperoxidase in the iodide-, thyroxine and triiodothyronine-dependent, but not in the chloride-dependent, systems. Hemolysis is is inhibited by the peroxidase inhibitors, azide and cyanide, and by catalase and is stimulated by superoxide dismutase when the xanthine oxidase system is employed as the source of H2O2. Hemolysis by the iodide-dependent system is associated with the iodination of erythrocyte components.
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PMID:Hemolysis and iodination of erythrocyte components by a myeloperoxidase-mediated system. 117 52

In the present study, the ocular inflammatory response to intravitreally injected endotoxin and xanthine oxidase was studied and the cellular response of the anterior and posterior segments was contrasted. There was a clear dose response relationship to both compounds in aqueous humor protein concentration and aqueous and vitreous humor white cell number. Xanthine oxidase and low doses of endotoxin (0.25 and 1.0 ng) produce a mainly mononuclear response in the anterior segment. Higher doses of endotoxin (10 and 100 ng) produced a predominantly neutrophilic response. Cellular infiltration into the posterior segment differed qualitatively and quantitatively from the anterior segment in response to the same stimuli. Myeloperoxidase (MPO) activity (a marker for neutrophils) of the iris-ciliary body was increased only in those eyes with a large neutrophilic response and thus is not recommended for use as a definitive index of the ocular inflammatory response, but may be a useful adjunct for such studies.
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PMID:Cellular response to intravitreal injection of endotoxin and xanthine oxidase in rabbits. 152 15

Ischemia induced oxygen free radical damage was formerly attributed only to xanthine oxidase in intestine, liver, kidney and heart. A reevaluation indicated neutrophils as one of the major sources of postischemic oxidative tissue damage, chiefly in the intestine. Our data, obtained from the same occlusion time period for intestine, liver and kidney, showed a certain oxidative damage in intestine and kidney already during ischemia, expressed by an increase of thiobarbituric acid reactive substances (TBARS), whereas the liver sustained damage of this kind only during reperfusion. Oxidative stress was expressed by a comparison of the increase of TBARS, though this test is not a measure of a specific product of lipid peroxidation, but rather comprises several breakdown products of free radical damage. Myeloperoxidase as measure of neutrophil stimulation increased in the intestine and liver. The kidney sustained damage without an increase of myeloperoxidase activity, but showed a similar pattern of increase of TBARS as in the intestine. Our data suggest a major role of neutrophils in intestinal ischemia induced damage, where neutrophils can effect initiation and propagation. In the liver neutrophils may play a minor role concerning propagation, but they may act as an important initiating mechanism. Hepatic tissue shows a high ischemic tolerance, which is demonstrated by a missing increase of TBARS in spite of a certain increase of myeloperoxidase activity during ischemia. This can be interpreted by the high capacity of antioxidative mechanisms of liver tissue and the ability of a higher oxygen extraction ratio under nearly ischemic conditions. In the kidney there appears a smaller contribution of neutrophils. The similar pattern of increase of TBARS in kidney and intestine demonstrates a comparable low ischemic tolerance of these two tissues, whereas different initiating and propagating systems may occur.
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PMID:Intestinal, hepatic and renal production of thiobarbituric acid reactive substances and myeloperoxidase activity after temporary aortic occlusion and reperfusion. 165 85

Myeloperoxidase catalyses the conversion of H2O2 and Cl- to hypochlorous acid (HOCl). It also reacts with O2- to form the oxy adduct (compound III). To determine how O2- affects the formation of HOCl, chlorination of monochlorodimedon by myeloperoxidase was investigated using xanthine oxidase and hypoxanthine as a source of O2- and H2O2. Myeloperoxidase was mostly converted to compound III, and H2O2 was essential for chlorination. At pH 5.4, superoxide dismutase (SOD) enhanced chlorination and prevented formation of compound III. However, at pH 7.8, SOD inhibited chlorination and promoted formation of the ferrous peroxide adduct (compound II) instead of compound III. We present spectral evidence for a direct reaction between compound III and H2O2 to form compound II, and for the reduction of compound II by O2- to regenerate native myeloperoxidase. These reactions enable compound III and compound II to participate in the chlorination reaction. Myeloperoxidase catalytically inhibited O2- -dependent reduction of Nitro Blue Tetrazolium. This inhibition is explained by myeloperoxidase undergoing a cycle of reactions with O2-, H2O2 and O2-, with compounds III and II as intermediates, i.e., by myeloperoxidase acting as a combined SOD/catalase enzyme. By preventing the accumulation of inactive compound II, O2- enhances the activity of myeloperoxidase. We propose that, under physiological conditions, this optimizes the production of HOCl and may potentiate oxidant damage by stimulated neutrophils.
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PMID:Superoxide modulates the activity of myeloperoxidase and optimizes the production of hypochlorous acid. 284 72

In previous studies, we noted that Candida hyphae and pseudohyphae could be damaged and probably killed by neutrophils, primarily by oxygen-dependent nonphagocytic mechanisms. In extending these studies, amount of damage to hyphae again was measured by inhibition of [(14)C]cytosine uptake. Neutrophils from only one of four patients with chronic granulomatous disease damaged hyphae at all, and neutrophils from this single patient damaged hyphae far less efficiently than simultaneously tested neutrophils from normal control subjects. Neutrophils from neither of two subjects with hereditary myeloperoxidase deficiency damaged the hyphae. This confirmed the importance of oxidative mechanisms in general and myeloperoxidase-mediated systems in particular in damaging Candida hyphae. Several potentially fungicidal oxidative intermediates are produced by metabolic pathways of normal neutrophils, but their relative toxicity for Candida hyphae was previously unknown. To help determine this, cell-free in vitro systems were used to generate these potentially microbicidal products. Myeloperoxidase with hydrogen peroxide, iodide, and chloride resulted in 91.2% damage to hyphal inocula in 11 experiments. There was less damage when either chloride or iodide was omitted, and no damage when myeloperoxidase was omitted or inactivated by heating. Azide, cyanide, and catalase (but not heated catalase) inhibited the damage. Systems for generation of hydrogen peroxide could replace reagent hydrogen peroxide in the myeloperoxidase system. These included glucose oxidase, in the presence of glucose, and xanthine oxidase, in the presence of either hypoxanthine or acetaldehyde. In the presence of myeloperoxidase and a halide, the toxicity of the xanthine oxidase system was not inhibited by superoxide dismutase and, under some conditions, was marginally increased by this enzyme. This suggested that superoxide radical did not damage hyphae directly but served primarily as an intermediate in the production of hydrogen peroxide. The possible damage to hyphae by singlet oxygen was examined using photoactivation of rose bengal. This dye damaged hyphae in the presence of light and oxygen. The effect was almost completely inhibited by putative quenchers of singlet oxygen: histidine, tryptophan, and 1,4-diazobicyclo[2.2.2]octane. These agents also inhibited damage to hyphae by myeloperoxidase, halide, and either hydrogen peroxide or a peroxide source (xanthine oxidase plus acetaldehyde). Myeloperoxidase-mediated damage to hyphae was also inhibited by dimethyl sulfoxide, an antioxidant and scavenger of the hydroxyl radical. These data support the involvement of oxidative mechanisms and the myeloperoxidase-H(2)O(2)-halide system, in particular in damaging hyphae in vitro and perhaps in vivo as well.
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PMID:Damage to Candida albicans hyphae and pseudohyphae by the myeloperoxidase system and oxidative products of neutrophil metabolism in vitro. 625 27

Natural killer cells spontaneously lyse certain tumor cells and may defend against malignancy. We have previously shown that natural killing (NK) by human peripheral blood mononuclear cells (PBMC) is suppressed in vitro by phorbol diester tumor promoters, including 12-O-tetradecanoylphorbol-13-acetate (TPA). We here demonstrate that suppression of NK is mediated by monocytes or polymorphonuclear leukocytes (PMN) and that suppression is dependent on the generation of reactive forms of molecular oxygen (RO), particularly hydrogen peroxide (H2O2). NK was suppressed not only by TPA but also by opsonized zymosan (yeast cell walls), which, like TPA, was not toxic to PBMC. Both TPA and zymosan stimulated the production of superoxide anion (O2-) and H2O2 by PBMC. Production of RO correlated with suppression of NK. When PBMC were depleted of monocytes, the production of RO and the suppression of NK were both markedly reduced. Suppression could be restored by monocytes or PMN, both of which produced RO in response to TPA or zymosan. Suppression of NK was dependent on RO. Monocytes or PMN from a patient with chronic granulomatous disease, whose cells cannot generate RO, did not mediate suppression of NK. Suppression was also reduced in glucose-free medium, which did not support the generation of RO. Suppression of NK by TPA was inhibited by catalase. Bovine superoxide dismutase had a limited effect on suppression, even in high concentration, and tyrosine-copper (II) complex, which also enhances dismutation of O2- to H2O2, had almost no effect on suppression. When H2O2 was directly generated enzymatically from glucose oxidase and glucose, NK was suppressed and suppression was reversed by catalase. NK was also suppressed by the enzymatic generation of O2- from xanthine oxidase and xanthine, but suppression under these conditions was again inhibited by catalase and not by superoxide dismutase, indicating that suppression was due to the secondary formation of H2O2 from O2-. These results indicate that H2O2 is important in suppression of NK. Myeloperoxidase did not appear to play a role in suppression because inhibition of this enzyme by sodium azide, cyanide, or aminotriazole did not prevent suppression of NK. Suppression of NK was reversible; after exposure to zymosan, NK could be partially restored by the addition of catalase and superoxide dismutase or by the removal of zymosan. These studies demonstrate cellular regulation of NK by monocytes or polymorphonuclear leukocytes and indicate a role for RO in immunoregulation.
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PMID:Suppression of natural killing in vitro by monocytes and polymorphonuclear leukocytes: requirement for reactive metabolites of oxygen. 707 51

This study looks at the role of xanthine oxidase (XO) in ischemia/reperfusion (I/R) induced intestinal mucosal damage using normal and xanthine oxidase deficient rats. Tungstate feeding for 3 days depleted the intestinal mucosal XO by 80%. A ligated loop of the rat small intestine (both normal and XO-deficient) was subjected to 1 h of total ischemia followed by 5 min revascularisation. The ensuing mucosal damage was assessed by biochemical and histological studies. Ischemia or I/R increased the XO levels in normal rats without any change in XO-deficient rats. Myeloperoxidase (a neutrophil marker) level was increased in both group of rats but it was comparatively higher in the XO-deficient rats. Accumulation of peroxidation products such as malondialdehyde, conjugated diene and increased production of hydroxyl radicals by microsomes were seen after ischemia and I/R and were similar in normal and XO-deficient rats. Studies on other parameters of peroxidation showed a decrease in polyunsaturated fatty acids and alpha-tocopherol, an increase in cysteine and cystine levels after I/R and were similar in both normal and XO-deficient rats. Histological results indicated gross morphological changes in the intestinal mucosa due to ischemia and I/R, and the damage was more severe in XO-deficient rats. These observations suggest that oxygen-derived free radicals are involved in the intestinal mucosal damage during I/R and infiltrated neutrophils rather than XO may be the primary source of free radicals under these conditions.
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PMID:Oxygen free radical induced damage during intestinal ischemia/reperfusion in normal and xanthine oxidase deficient rats. 823 77

This study was conducted with rats to assess the involvement of leukocytes in a model of CO-mediated brain injury. Myeloperoxidase activity, measured as an index of leukocyte sequestration, was found to be increased 10-fold in brain microvessel segments prepared from rats immediately or 90 min after exposure to CO. Fluorescence and light microscopic examinations revealed leukocytes in microvessels taken from CO-poisoned rats, but not in that from control rats. Studies were then conducted with rats that had been made leukopenic or treated with monoclonal anti-CD-18 F(ab')2 fragments to inhibit leukocyte adherence to the vasculature. Neither of these groups of animals exhibited the biochemical changes observed in the brains of sham-treated rats: conversion of xanthine dehydrogenase (XD) to sulfhydryl-irreversible xanthine oxidase (XO), and lipid peroxidation, at 90 min following CO poisoning. Treatment with a synthetic serine protease inhibitor, gabexate mesylate, also prevented these biochemical changes if administered immediately after CO poisoning, but the agent did not inhibit leukocyte sequestration. Rats depleted of XD and XO by a tungsten diet, and those treated with allopurinol to inhibit XD and XO, also exhibited at least a 10-fold increase in myeloperoxidase activity in microvessels immediately after CO poisoning, but only a 5-fold increase at 90 min. In vitro studies demonstrated that B2 integrin-dependent polymorphonuclear leukocyte adherence was impaired immediately following CO poisoning although the adherence molecules were expressed on the membrane surface. Adherence function normalized by 45 min. The results suggest that leukocytes are responsible for the development of biochemical changes in brain following CO poisoning, and the sequence of events is as follows: leukocyte sequestration in the microvasculature, B2 integrin-dependent adherence, protease-mediated conversion of XD to XO, O2 radical-dependent lipid peroxidation.
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PMID:Leukocytes in carbon monoxide-mediated brain oxidative injury. 824 31

Myeloperoxidase, the most abundant enzyme in neutrophils, catalyses the conversion of hydrogen peroxide and chloride to hypochlorous acid. This potent oxidant has the potential to cause considerable tissue damage in many inflammatory diseases. We have investigated the ability of dapsone, diclofenac, primaquine, sulfapyridine and benzocaine to inhibit hypochlorous acid production by stimulated human neutrophils. The drugs were also tested against purified myeloperoxidase using xanthine oxidase to generate hydrogen peroxide and superoxide. The inhibitory effects of the drugs on hypochlorous acid production, either by cells stimulated with phorbol myristate acetate or by myeloperoxidase and xanthine oxidase, were significantly less than those determined with myeloperoxidase and reagent hydrogen peroxide. Comparable potency was observed only when superoxide dismutase was present to remove superoxide. We also observed that with the xanthine oxidase system, inhibition of hypochlorous acid production by dapsone decreased markedly as the concentration of myeloperoxidase increased. Dapsone was a poor inhibitor of hypochlorous acid production by neutrophils stimulated with opsonized zymosan, regardless of the presence of superoxide dismutase. With this phagocytic stimulus, catalase inhibited hypochlorous acid formation by only 60%, which indicates that a substantial amount of the hypochlorous acid detected originated from within phagosomes. Thus, it is apparent that dapsone is unable to affect intraphagosomal conversion of hydrogen peroxide to hypochlorous acid. All the drugs inhibit myeloperoxidase reversibly by trapping it as its inactive redox intermediate, compound II. We propose that superoxide limits the potency of the drugs by reducing compound II back to the active enzyme. Furthermore, under conditions where the activity of myeloperoxidase exceeds that of the hydrogen peroxide-generating system, which is most likely to occur in phagosomes, partial inhibition of myeloperoxidase need not affect hypochlorous acid production. We conclude that drugs that inhibit myeloperoxidase by converting it to compound II are unlikely to be effective against hypochlorous acid-mediating tissue damage.
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PMID:Superoxide is an antagonist of antiinflammatory drugs that inhibit hypochlorous acid production by myeloperoxidase. 839 Feb 58


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