Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UNIPROT:P47989 (xanthine oxidase)
 8,633 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The reactions of native bovine catalase with superoxide and solvated electrons have been investigated using three different methods for generation of these reducing substrates: gamma-radiolysis of oxygenated or deaerated buffer solutions in the presence of an OH radical scavenger; either xanthine or acetaldehyde with xanthine oxidase; and low-temperature (77 K) gamma-radiolysis of buffered ethylene glycol/water solutions with subsequent annealing of samples at 183 K. The first spectral evidence for catalase compound II formation from native catalase via reaction with superoxide was obtained. The results are compared with results for peroxidase compound II or III formation observed under the same experimental conditions. A scheme is proposed to explain these observations involving intermediate formation of catalase compounds I and III and the ferrous enzyme. The one-electron reduction of catalase and peroxidase by radiolytically-generated solvated electrons was compared. In the present study the first absorption spectrum of a high-spin ferrous catalase which has peaks at 561 and 594 nm is reported, in comparison with a hemochromogen low-spin ferrous peroxidase observed under the same experimental conditions (peaks at 527 and 556 nm). Both spectra were recorded at 77 K. Data presented in this work also provide the first spectral evidence indicating the low temperature (183 K) conversion of high-spin ferrous catalase into compound III (oxycatalase) in the presence of dioxygen. Under the same experimental conditions low-spin ferrous peroxidase was converted into the high-spin ferrous form without oxyperoxidase formation.
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PMID:Spectral studies of intermediate species formed in one-electron reactions of bovine liver catalase at room and low temperatures. A comparison with peroxidase reactions. 136 11

There are two types of collagenases, products of two distinct genes, called MMP-1 (matrix metalloproteinase 1 or "fibroblast-type collagenase") and MMP-8 ("neutrophil collagenase"). In synovial fluid, MMP-8 is stored as latent proenzyme in polymorphonuclear neutrophils. MMP-8 is activated by hypochlorous acid produced by myeloperoxidase from hydrogen peroxide and chloride ion and by the hydroxyl radical produced in Haber Weiss reaction fed by superoxide produced by, eg, NADPH (reduced nicotinamide adenine dinucleotide) oxidase and xanthine oxidase. In addition to activation upon secretion, oxidatively modified MMP-8 is susceptible to a subsequent proteolytic attack and activation by cathepsin G. The authors suggest that activation of neutrophil-derived MMP-8 involves oxidative, nonproteolytic activation upon secretion and a more slowly progressive proteolytic activation by cathepsin G (or chymases and tryptases), and that these oxidative and proteolytic activation mechanisms act in concert. In contrast to MMP-8, MMP-1 is synthesized de novo and secreted immediately after synthesis by fibroblasts, macrophages, and some epithelial cells. Human rheumatoid synovial tissue contains mainly fibroblast-type MMP-1 collagenase as assessed by collagenase extracted from synovial tissue and by MMP-1 and MMP-8 immunostaining. It is suggested that in vivo, MMP-1 in synovitis tissue is activated by a plasminogen activator/plasminogen/prostromelysin (alternatively tryptases)/proMMP-1 cascade. In conclusion, MMP-8 and MMP-1 show type-specific compartmentalization and modes of activation in rheumatoid synovial fluid and tissue.
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PMID:Collagenase in synovitis of rheumatoid arthritis. 141 81

The interaction between milk xanthine oxidase (XO) and lactoperoxidase (LP) in model system and antimicrobial action of these enzymes on Escherichia coli 0-111 were studied. It was shown, that bacterial superoxide dismutase (SOD), which transforms O2-. (XO-reaction product) into H2O2 (substrate of LP), is necessary for binding of the reaction sequence: XO-->LP-->antimicrobial products. It is suggested, that these enzymes unite in the protective system in intestinal infections of newborns. Bacterial SOD in this case acts as the key factor, creating the system.
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PMID:[Free-radical mechanism of antimicrobial action of xanthine oxidase and lactoperoxidase]. 147 55

The excessive generation of free radicals is thought to be one of the major mechanisms leading to tissue injury in various pathological conditions, including ischemia, inflammation, and trauma. Conversion of xanthine dehydrogenase (XDH) to xanthine oxidase (XO) contributes to the formation of superoxide, an oxygen radical. We measured XDH and XO activity using a newly developed fluorometric assay in an experimental spinal cord injury model in rats. XO activity increased by more than 100% 4 h after spinal cord trauma. Total (XDH + XO) activity also increased by 96% during the same period. Allopurinol, an inhibitor of XO (100 mg/kg/day x 2 days, i.p.), completely inhibited plasma and spinal cord XO activity but did not affect posttraumatic edema determined by water content or polymorphonuclear (PMN) cell infiltration reflected by myeloperoxidase (MPO) activity in traumatized spinal cord. These results indicate that XDH conversion to XO may not be the major mechanism of oxygen radical formation in the pathogenesis of vasogenic edema or inflammatory response in this experimental spinal cord injury model in rats.
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PMID:Xanthine oxidase in experimental spinal cord injury. 164 10

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

In vivo most extracellular iron is bound to transferrin or lactoferrin in such a way as to be unable to catalyze the formation of hydroxyl radical from superoxide (.O2-) and hydrogen peroxide (H2O2). At sites of Pseudomonas aeruginosa infection bacterial and neutrophil products could possibly modify transferrin and/or lactoferrin forming catalytic iron complexes. To examine this possibility, diferrictransferrin and diferriclactoferrin which had been incubated with pseudomonas elastase, pseudomonas alkaline protease, human neutrophil elastase, trypsin, or the myeloperoxidase product HOCl were added to a hypoxanthine/xanthine oxidase .O2-/H2O2 generating system. Hydroxyl radical formation was only detected with pseudomonas elastase treated diferrictransferrin and, to a much lesser extent, diferriclactoferrin. This effect was enhanced by the combination of pseudomonas elastase with other proteases, most prominently neutrophil elastase. Addition of pseudomonas elastase-treated diferrictransferrin to stimulated neutrophils also resulted in hydroxyl radical generation. Incubation of pseudomonas elastase with transferrin which had been selectively iron loaded at either the NH2- or COOH-terminal binding site yielded iron chelates with similar efficacy for hydroxyl radical catalysis. Pseudomonas elastase and HOCl treatment also decreased the ability of apotransferrin to inhibit hydroxyl radical formation by a Fe-NTA supplemented hypoxanthine/xanthine oxidase system. However, apotransferrin could be protected from the effects of HOCl if bicarbonate anion was present during the incubation. Apolactoferrin inhibition of hydroxyl radical generation was unaffected by any of the four proteases or HOCl. Alteration of transferrin by enzymes and oxidants present at sites of pseudomonas and other bacterial infections may increase the potential for local hydroxyl radical generation thereby contributing to tissue injury.
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PMID:Pseudomonas and neutrophil products modify transferrin and lactoferrin to create conditions that favor hydroxyl radical formation. 165 25

Our results suggest that xanthine oxidase (XO) contributes to lung neutrophil sequestration in hypovolemic shock. Catheterized rats subjected to shock by phlebotomy (approximately 30% blood loss) had decreased mean arterial blood pressures (P less than 0.05) and increased (P less than 0.05) lung myeloperoxidase (MPO) activities (indicative of lung neutrophil accumulation) compared with sham-treated normotensive rats. In contrast, rats depleted of lung and plasma XO activity by tungsten diet before phlebotomy had decreased (P less than 0.05) lung MPO activities compared with phlebotomized rats fed regular diets.
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PMID:Hypovolemic shock promotes neutrophil sequestration in lungs by a xanthine oxidase-related mechanism. 166 98

Mercuric ion, a well-known nephrotoxin, promotes oxidative tissue damage to kidney cells. One principal toxic action of Hg(II) is the disruption of mitochondrial functions, although the exact significance of this effect with regard to Hg(II) toxicity is poorly understood. In studies of the effects of Hg(II) on superoxide (O2-) and hydrogen peroxide (H2O2) production by rat kidney mitochondria, Hg(II) (1-6 microM), in the presence of antimycin A, caused a concentration-dependent increase (up to fivefold) in mitochondrial H2O2 production but an apparent decrease in mitochondrial O2- production. Hg(II) also inhibited O(2-)-dependent cytochrome c reduction (IC50 approximately 2-3 microM) when O2- was produced from xanthine oxidase. In contrast, Hg(I) did not react with O2- in either system, suggesting little involvement of Hg(I) in the apparent dismutation of O2- by Hg(II). Hg(II) also inhibited the reactions of KO2 (i.e., O2-) with hemin or horseradish peroxidase dissolved in dimethyl sulfoxide (DMSO). Finally, a combination of Hg(II) and KO2 in DMSO resulted in a stable UV absorbance spectrum [currently assigned Hg(II)-peroxide] distinct from either Hg(II) or KO2. These results suggest that Hg(II), despite possessing little redox activity, enhances the rate of O2- dismutation, leading to increased production of H2O2 by renal mitochondria. This property of Hg(II) may contribute to the oxidative tissue-damaging properties of mercury compounds.
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PMID:Reactivity of Hg(II) with superoxide: evidence for the catalytic dismutation of superoxide by Hg(II). 166 57

Benzene, a known human myelotoxin and leukemogen is metabolized by liver cytochrome P-450 monooxygenase to phenol. Further hydroxylation of phenol by cytochrome P-450 monooxygenase results in the formation of mainly hydroquinone, which accumulates in the bone marrow. Bone marrow contains high levels of myeloperoxidase. Here we report that phenol hydroxylation to hydroquinone is also catalyzed by human myeloperoxidase in the presence of a superoxide anion radical generating system, hypoxanthine and xanthine oxidase. No hydroquinone formation was detected in the absence of myeloperoxidase. At low concentrations superoxide dismutase stimulated, but at high concentrations inhibited, the conversion of phenol to hydroquinone. The inhibitory effect at high superoxide dismutase concentrations indicates that the active hydroxylating species of myeloperoxidase is not derived from its interaction with hydrogen peroxide. Furthermore, catalase a hydrogen peroxide scavenger, was found to have no significant effect on hydroxylation of phenol to hydroquinone, supporting the lack of hydrogen peroxide involvement. Mannitol (a hydroxyl radical scavenger) was found to have no inhibitory effect, but histidine (a singlet oxygen scavenger) inhibited hydroquinone formation. Based on these results we postulate that a myeloperoxidase-superoxide complex spontaneously rearranges to generate singlet oxygen and that this singlet oxygen is responsible for phenol hydroxylation to hydroquinone. These results also suggest that myeloperoxidase dependent hydroquinone formation could play a role in the production and accumulation of hydroquinone in bone marrow, the target organ of benzene-induced myelotoxicity.
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PMID:Hydroxylation of phenol to hydroquinone catalyzed by a human myeloperoxidase-superoxide complex: possible implications in benzene-induced myelotoxicity. 166 26

To determine the mechanisms whereby complement-activated granulocytes induce microvascular dysfunction in skeletal muscle, we examined the effect of antineutrophil serum (ANS), IB4 (a monoclonal antibody that inhibits CD18-dependent neutrophil adherence), xanthine oxidase inhibition or inactivation, deferoxamine, and catalase on the increase in canine gracilis muscle microvascular permeability induced by intravascular administration of zymosan-activated plasma (ZAP). Changes in vascular permeability were assessed by measurement of the solvent drag reflection coefficient (sigma) for total plasma proteins, and the extent of neutrophil infiltration was estimated by assessing muscle myeloperoxidase activity. ZAP infusion was associated with a marked increase in vascular permeability compared with control muscles that received no treatment or to muscles treated with zymosan heat-inactivated plasma (ZIP) (sigma = 0.51 +/- 0.04, 0.89 +/- 0.02, and 0.90 +/- 0.01, respectively). Estimates of sigma in animals rendered neutropenic with ANS, or treated with IB4, deferoxamine, or catalase before ZAP infusion were not significantly different from values obtained in control or ZIP-treated muscles (sigma = 0.96 +/- 0.02, 0.88 +/- 0.03, 0.85 +/- 0.02, and 0.79 +/- 0.01, respectively). However, xanthine oxidase inactivation or inhibition provided no protection from this ZAP-induced microvascular dysfunction (sigma = 0.58 +/- 0.02 and 0.58 +/- 0.01, respectively). In addition, neutropenia and inhibition of neutrophil adherence also prevented ZAP-induced increases in vascular resistance and tissue neutrophil infiltration.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Oxidant-mediated, CD18-dependent microvascular dysfunction induced by complement-activated granulocytes. 167 94


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