UNIPROT:P47989 - FACTA Search

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Query: UNIPROT:P47989 (xanthine oxidase)
8,633 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Ischemia followed by reflow often results in tissue injury. Although reactive oxygens seem to play an important role in the pathogenesis of postischemic reflow-induced tissue injury, the mechanism and an efficient way to inhibit oxidative injury are not known. We studied the mechanism by which hepatic transport function was inhibited by a transient occlusion followed by reflow of the portal vein and hepatic artery by using a superoxide dismutase (SOD) derivative (SM-SOD) which circulates bound to albumin with a half-life of 6 h. Occlusion of the hepatic vessels for 20 min followed by reflow for 60 min significantly inhibited transhepatic transport of cholephilic ligands, such as bromosulfophthalein (BSP) and taurocholic acid. Intravenous administration of SM-SOD markedly inhibited the reflow-induced decrease in transhepatic transport of these ligands. Thiobarbituric acid - reactive metabolites (TBAR) in the liver and plasma remained unchanged during occlusion and reflow, while TBAR in the bile increased significantly. Intravenous injection of SM-SOD inhibited the reflow-induced increase in biliary TBAR. Xanthine oxidase activity in plasma also increased during occlusion and reflow by an SM-SOD-inhibitable mechanism. Polymorphonuclear leukocyte-dependent chemiluminescence of the peripheral blood remained unchanged during occlusion, but increased markedly with time after reflow. SM-SOD also inhibited the increase in chemiluminescence almost completely. These and other results suggested that the superoxide radical and/or its metabolite(s) might play an important role in the pathogenesis of the reflow-induced liver injury and that SM-SOD might be useful for studying the mechanism for tissue injury caused by oxygen toxicity.
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PMID:Inhibition of ischemia and reflow-induced liver injury by an SOD derivative that circulates bound to albumin. 230 17

Ischemia-reperfusion lung injury limits lung transplantation. Neutrophil activation and/or xanthine oxidase-mediated purine degradation may cause toxic oxygen metabolite production and lung injury. We investigated whether circulating blood elements are involved in the pathogenesis of ischemia-reperfusion lung injury. Isolated rat lungs were perfused with physiological salt solution (PSS) stabilized with Ficoll until circulating blood elements were not detected in the lung effluent. Lungs were then rendered ischemic by stopping ventilation and perfusion for 45 min at room temperature. Lung injury occurred and was quantitated by the accumulation of 125I-bovine serum albumin into lung parenchyma and alveolar lavage fluid during reperfusion. Lung injury occurred, in the absence of circulating blood elements, when ischemic lungs were reperfused with PSS-Ficoll solution alone. Reperfusion with whole blood or PSS-Ficoll supplemented with human or rat neutrophils did not increase lung injury. Furthermore, during lung ischemia, the presence of neutrophils did not enhance injury. Experiments using PSS-albumin perfusate and quantitating lung injury by permeability-surface area product yielded similar results. Microvascular pressures were not different and could not account for the results. Toxic O2 metabolites were involved in the injury because addition of erythrocytes or catalase to the perfusate attenuated the injury. Thus reperfusion after lung ischemia causes injury that is dependent on a nonneutrophil source of toxic O2 metabolites.
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PMID:Neutrophils are not necessary for induction of ischemia-reperfusion lung injury. 231 80

Two lines of investigation suggested that xanthine oxidase- (XO) derived O2 metabolites contribute to paraquat- (PQ) induced acute lung injury. First, PQ treatment increased lung XO activity and decreased lung xanthine dehydrogenase activity. Second, lung albumin uptake increased compared with control values in untreated XO-replete but not tungsten-treated XO-depleted lungs in rats treated with PQ.
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PMID:Xanthine oxidase is increased and contributes to paraquat-induced acute lung injury. 234 13

A method was developed to separate guanase by agarose gel electrophoresis and to detect its activity by staining of the bands with a mixture of the enzymes xanthine oxidase, catalase, and aldehyde dehydrogenase, the coenzyme NADP+, and a substrate of guanine, ethanol, phenazine methosulfate, nitrotetrazolium blue, and KCN in Tris-(hydroxymethyl)methylamine buffer (pH 8.0). Serum samples showed bands 1 (faster moving) and 2 corresponding to the positions of albumin and alpha 2-globulin, respectively, found by serum protein staining. The same bands were detected with guanase from human liver and kidney, although band 2 from the latter samples was not as distinct as that from the liver samples.
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PMID:Analysis of guanase by agarose gel electrophoresis and activity staining. 241 96

Inasmuch as xanthine oxidase (XO)-derived O2* metabolites may contribute to vascular endothelial injury and Factor VIII antigen (F8Ag) is a component of endothelial cells, we hypothesized that XO-derived O2* might damage and cause distant organ endothelial cells to release F8Ag in rats subjected to skin burn. We found that serum F8Ag (ELISA) increased in the blood of rats subjected to skin burn (70 degrees C water to shaved dorsal skin for 30 seconds) but not in sham control rats (30 degrees C water). Coincidentally, F8Ag levels also decreased in lung and kidney tissue sections (immunofluorescent staining) of burned rats but not sham rats. Increases in circulating F8Ag levels and decreases in tissue F8Ag levels appeared to result from XO-derived O2* metabolites: F8Ag levels did not increase in the blood and did not decrease in the tissues of rats pretreated with allopurinol (a specific XO inhibitor, 50 mg/kg) or dimethylthiourea (DMTU) (a permeable O2* metabolite scavenger, 250 mg/kg). Lung injury as assessed by permeability studies (I125-albumin leak) paralleled changes in blood F8Ag levels in sham, burn, allopurinol-, and DMTU-treated groups. We conclude that skin burn causes a systemic vascular injury that can be inhibited by allopurinol or DMTU and is reflected by increased circulating and tissue decreased Factor VIII antigen levels. Release of Factor VIII antigen may serve as a valuable marker of distant organ injury in patients with skin burn.
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PMID:Local skin burn causes systemic (lung and kidney) endothelial cell injury reflected by increased circulating and decreased tissue factor VIII-related antigen. 250 1

This study used chemiluminescence, an "on-line" photon-counting technique, to detect and characterize activated O2 species in vitro and in isolated rat lungs. The sensitivity and specificity of enhanced chemiluminescence for superoxide anion (O2-.) and hydrogen peroxide (H2O2) was evaluated in vitro. The effect of media conditions (such as O2 tension, albumin concentration, and sulfhydryl group availability) on luminescence was assessed in vitro. Xanthine-xanthine oxidase (X-XO) primarily produced superoxide anion in vitro. Enhanced chemiluminescence varied directly with the dose of luminescent probe used and the quantity of activated O2 species administered. The strength of the luminescent signal was also dependent on the concentration of albumin and O2 in the media. Lucigenin was more sensitive than luminol to the presence of O2-. and, unlike luminol, lucigenin did not alter radical production by XO. However, neither luminescent probe was specific for O2-., as both detected H2O2 and O2 in vitro. H2O2-induced chemiluminescence was inhibited by catalase but not superoxide dismutase (SOD), while X-XO-induced luminescence was inhibited by SOD but not catalase. SOD-inhibitable chemiluminescence was a sensitive and specific marker for O2-. production in vitro. Once the sensitivity-specificity of enhanced chemiluminescence was defined in vitro, this technique was used to explore the mechanism by which exogenous X-XO reduced hypoxic vasoconstriction in isolated rat lungs. The vascular paresis, caused by administration of X-XO to the rat lung, resulted from a brief burst of O2-. production rather than a sustained alteration of lung radical levels.
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PMID:Detection of activated O2 species in vitro and in rat lungs by chemiluminescence. 253 94

1. The effects of reactive oxygen metabolites on the rat gastric mucosa following close-arterial infusion into the left gastric artery have been determined by macroscopic and histological assessment. 2. Local intra-arterial infusion of hydrogen peroxide (0.6-1.3 mumol kg-1 min-1) induced mucosal injury, characterised by areas of pronounced disruption and haemorrhage, which was prevented by concurrent intravenous administration of catalase. 3. Local infusion of the superoxide generating system xanthine-oxidase and hypoxanthine likewise induced extensive haemorrhagic damage and necrosis of the mucosa. Prolonged incubation of this mixture (10 min) before administration, significantly reduced the degree of injury, indicating the lability of the products so formed. 4. The gastric mucosal injury induced by the superoxide generating system was inhibited by concurrent local infusion of superoxide dismutase (96 u kg-1 min-1), as was the associated increase in mucosal permeability to radiolabelled albumin. 5. Administration of catalase did not inhibit the gastric mucosal damage induced by infusion of xanthine oxidase-hypoxanthine, yet augmented the protective effects of a low dose of superoxide dismutase (46 u kg-1 min-1 i.a.). 6. These findings directly confirm that reactive oxygen metabolites can induce extensive gastric mucosal injury, supporting their role in the pathogenesis of gastric damage following ischaemia and hypotensive shock.
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PMID:Gastric damage following local intra-arterial administration of reactive oxygen metabolites in the rat. 255 38

Lipid peroxide and SOD were selected as free radical related substances and system for their elimination, and detection was evaluated. NADPH-Cytochrome c reductase-Neotetrazolium (NT) method (Mic-NT method) and Xanthine oxidase-Nitrotetrazolium Blue method (XOD-NTB method) are current detection methods of SOD activities. They are based on the O2-specific reaction. Minimum detectable amount of SOD by the Mic-NT method and XOD-NTB method was about 15 ng and 200 ng, respectively. On the other hand, an XOD-NH2OH method which detects SOD activities based on the O2-specific oxidation reaction showed the minimum detectable amount of 2.5 ng. Consequently, SOD-detecting sensitivity of these methods was found to be in the following order: XOD-NH2OH method greater than Mic-NT method greater than XOD-NTB method. In addition, albumin caused a positive error in all three methods. With a monoclonal antibody-aided SOD-analyzing method (EIA method), the minimum detectable amount of SOD was 0.2 ng. The isoenzymes of SOD (Cu, Zn-SOD and Mn-SOD) could be detected separately by 1. deactivating Cu, Zn-SOD with CN- or H2O2 and regarding the remaining activity as Mn-SOD and 2. by deactivating Mn-SOD selectively through pretreatment of the sample with SDS and regarding the remaining activity as Cu, Zn-SOD. TBA method (Yagi's method) has been used frequently for the measurement of serum lipid peroxide.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:[Detection methods of free radical related substances and the system for their elimination]. 260 53

O2 radicals are important in the pathogenesis of acute lung injury. The purpose of this investigation was to determine the role that microvascular pressure plays in edema induced by reactive O2 species generated by xanthine oxidase. In isolated rat lungs perfused with Krebs buffer plus 4% albumin, 5 mM glucose, and 2 mM xanthine at constant flow (13 ml/min), addition of xanthine oxidase (0.02 U/ml) caused a progressive increase in both pulmonary arterial and microvascular pressure (double occlusion method), which preceded the onset of edema. Both the pressure rise and edema formation were blocked by catalase, suggesting that vascular injury was related to H2O2 production. Lungs not exposed to free radicals that had microvascular pressure elevated to match that of the xanthine oxidase-perfused lungs showed only a small, reversible (nonedematous) weight gain. Lungs exposed to xanthine oxidase but perfused at constant microvascular pressure (5 Torr, similar to control lungs) showed a significant delay in protein-rich edema formation. These data indicate that reactive O2 metabolites induced lung injury, which is accompanied by increased microvascular pressure. Although the rise in microvascular pressure was shown not to be essential for edema formation, it does play a role in acceleration of the rate of transvascular fluid loss.
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PMID:Role of microvascular pressure in reactive oxygen-induced lung edema. 270 63

Platelet-activating factor (1-O-alkyl-2-acetyl-sn-glycero-3-phosphocholine [PAF]) is a vasoactive ether lipid produced by activated blood cells. To examine the molecular traffic and sites of metabolism of PAF released in the vascular wall, we used a coculture system in which endothelial cells are grown on micropore filters suspended over confluent cultures of vascular smooth muscle cells. The endothelial cells took up PAF 5-7 times more readily from the apical than from the basolateral surface, converting it to 1-O-alkyl-2-acyl-sn-glycero-3-phosphocholine (2-acyl-PAF) and other minor metabolites. Intact endothelial monolayers effectively shielded the underlying smooth muscle cells from PAF present in the apical fluid; after a 30-min incubation with [3H]-PAF, only 1% of the radioactivity was transferred to the interstitial fluid. By contrast, PAF readily entered the interstitial fluid when the endothelial monolayers were injured by exposure to xanthine and xanthine oxidase. PAF did not significantly increase the permeability of endothelial monolayers to albumin. Smooth muscle cells took up and metabolized interstitial PAF more quickly and more completely than did endothelial cells; 65% was converted to 2-acyl-PAF in 15 min by the smooth muscle cells. PAF enhanced the proliferative effect of PDGF on smooth muscle cells, as assessed by [3H]-thymidine incorporation. These findings suggest that endothelial cells form a barrier to PAF released at the luminal surface, but PAF released in the vascular intima interacts primarily with smooth muscle cells, possibly stimulating proliferation in these cells.
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PMID:Interaction of platelet-activating factor with endothelial and vascular smooth muscle cells in coculture. 271 86

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