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)

Evidence implicating reactive oxygen species (ROS) in reperfusion-induced arrhythmias is accumulating rapidly [1,2]. However, surprisingly little is known about the effects of ROS on cardiac electrophysiology. Such knowledge would improve our understanding of reperfusion-induced arrhythmias. Photosensitizers and light are known to produce a variety of ROS. They might, therefore, be useful for investigating oxygen-mediated cell injury. To our knowledge, such an approach has not been used to investigate ROS-induced alterations in the electrophysiological properties of cardiac muscle. The purpose of this paper is to demonstrate (1) the feasibility of using photosensitizers for such an investigation, and (2) some advantages photosensitizers offer when combined with single cell and patch pipette methodologies. A comparison of the electrophysiological alterations produced by photosensitizer-generated ROS to the reported effects of xanthine-xanthine oxidase or organic hydroperoxides suggests that the electrophysiological alterations produced by superoxide initiated reactions and/or lipid peroxidation are similar to those produced by photosensitizers and light.
J Mol Cell Cardiol 1989 Jun
PMID:Modification of cardiac action potential by photosensitizer-generated reactive oxygen. 277 6

Rat left atria or Langendorff hearts were kept at 37 degrees C and stimulated at a rate of 3.33 Hz. They were subjected to hypoxia (deprivation of oxygen) or ischemia (deprivation of oxygen and glucose + acidosis + increased extracellular potassium concentration) for 15 min or 1 h and subsequent reoxygenation for 5 or 15 min. Tissue concentrations of proteins, reduced and oxidized glutathione and conjugated dienes were measured at the end of the experiment. Hypoxia and ischemia decreased the excitability and contractility of the preparations and caused contracture. These effects were partly reversible during reoxygenation. However, in Langendorff hearts reoxygenation caused an increased release of CPK, LDH and glutathione into the perfusion fluid. Ischemia and reoxygenation in atria lowered the tissue concentration of reduced glutathione and increased its oxidized form. Similar changes were seen in atria and Langendorff hearts when oxygen radical production was accelerated by hypoxanthine and xanthine oxidase. No treatment raised significantly the concentration of conjugated dienes. These results seem to exclude an important role of an increased lipid peroxidation for reperfusion injury of isolated heart preparations.
J Mol Cell Cardiol 1989 Jul
PMID:No evidence for an increased lipid peroxidation during reoxygenation in Langendorff hearts and isolated atria of rats. 279 63

In the rabbit myocardium, ischemia (produced by ligation of the left circumflex coronary artery) is associated with a reduction in antioxidant capacity. This is reflected by an increased glutathione depletion and production of thiobarbituric acid reactive substances following in vitro oxidative challenge with t-butylhydroperoxide. This effect is greatly intensified by reperfusion following periods of ischemia longer than 20 mins, thereby paralleling the onset of irreversible injury. Chronic allopurinol pretreatment (1 mg/mL in drinking water or approximately 75 mg/kg/day for seven days prior to ligation) provides significant protection of the ischemic/reperfused myocardium to t-butylhydroperoxide induced glutathione depletion and production of thiobarbituric acid reactive substances. This protection was not associated with any significant alterations in levels of tissue ATP or in the activities of the myocardial antioxidant enzymes catalase, copper,zinc-superoxide dismutase or glutathione peroxidase, suggesting that allopurinol may exert its effects by direct radical scavenging or by some other mechanism unrelated to xanthine oxidase inhibition.
Can J Cardiol 1989 Oct
PMID:Altered antioxidant status in the ischemic/reperfused rabbit myocardium: effects of allopurinol. 281 60

The direct effect of oxygen metabolites was studied on isolated perfused rat hearts. Superoxide anion (O2-.) and hydrogen peroxide (H2O2) were generated by adding purine (2.3 mM) and purified xanthine oxidase (0.06 U/ml) to Krebs-Henseleit buffer (pH 7.4). Xanthine oxidase was added to the purine-containing perfusate either near the aorta (group A, which gave H2O2 less than 10 microM) or at a distant point from the aorta (group B, which gave 250 to 300 microM H2O2). The generation rate of O2-. was 31.7 +/- 1.0 nmol/ml/min in the experimental conditions. Contractile function, tissue adenosine triphosphate (ATP), and ultrastructure were not affected in group A. In contrast, hearts in group B showed marked decrease in contractility (+dP/dt) to 24.4 +/- 4.3% of control values. ATP levels were also markedly reduced from control values of 23.4 +/- 0.7 to 7.4 +/- 0.7 mumol/g dry tissue. Ultrastructure in group B hearts revealed "wavy" and disintegrated sarcolemma, depletion of glycogen deposits, and swelling and disruption of mitochondria. Release of the thiobarbituric acid reactive products including malondialdehyde was significant in the effluent (1.68 +/- 0.17 nmol/min/g wet tissue). These changes were almost completely prevented by catalase, but not by superoxide dismutase and deferoxamine. Moreover, exogenous H2O2 perfusion (300 microM) showed results similar to group B hearts. These observations suggest that H2O2 plays a major role in the injury. O2- does not appear to damage hearts directly, although it is important as a precursor of H2O2 and other radical species including hydroxyl radical.
J Mol Cell Cardiol 1988 Nov
PMID:Myocardial dysfunction and ultrastructural alterations mediated by oxygen metabolites. 285 30

If myocardial ischemia always results from an imbalance between the needs and supplies in oxygen of the myocardium cells, the physiopathology of this process seems today infinitely more complex than the mere diminution or interruption of the output in a coronary artery. The extension of atheromatous lesions, the platelets aggregation, thrombosis, the coronary spasm, the release of products from the arachidonic cascade, the reactivity of the vascular endothelium, the profibrinolytic activity of the tissues are many of the intricate factors inducing myocardial ischemia. Cellular alterations, of which some are triggered by the release of oxygenated free radicals, lead then to an irreversible necrosis. The medications used until now in the treatment of angina are oxygen scavengers and research goes on in this direction with vaso-dilators beta-blockers, prolonged action nitro-compounds (nicorandil) or nitro-compounds with an action reinforced by N-acetyl-cysteine, bradycardiac derivates of alinidine and the new calcium antagonists dihydropyridine. However, the new physiopathological concepts of ischemia have opened new directions for the research: products which modify the arachidonic cascade by increase of synthesis or release of PGI2 (nafazatrom, defibrotide), by inhibition of TXA2 synthesis or blocking of TXA2 receptors, and similar products of PGI2 (iloprost); thrombolytic agents more specific of thrombin (PTA) or fibrinolysis activators (defibrotide), and anticoagulants with extended action; chelating agents of oxygenated free radicals (peroxide dismutase, catalase, peroxidase) or xanthine oxidase inhibitors; platelets anti-aggregates like ticlopidine which blocks the platelets receptors to fibrinogen, or inhibitors of the synthesis of pro-aggregating agents.(ABSTRACT TRUNCATED AT 250 WORDS)
Ann Cardiol Angeiol (Paris) 1986 Oct 15
PMID:[Current therapeutic concepts in the treatment of myocardial ischemia. Current and future drugs]. 287 4

The oxygen paradox refers to the abrupt release of cytoplasmic enzymes and severe cellular disruption that occurs following reoxygenation of anoxic perfused hearts. In this study, the ability of a series of oxygen-derived free radical inhibitors and scavenging agents to protect isolated perfused rat hearts from the oxygen-induced enzyme release following 30 or 60 mins of anoxic perfusion (oxygen paradox) and cumene hydroperoxide-induced injury was evaluated. Malondialdehyde (MDA) release, an indicator of lipid peroxidation, and creatine kinase (CK) release, an indicator of cellular injury, were monitored. We evaluated five agents previously reported to scavenge or inhibit the formation of oxygen free radicals. The putative hydroxyl radical scavengers dimethylthiourea (DMTU) and mannitol; catalase, an agent protective against peroxide injury; allopurinol, an inhibitor of xanthine oxidase; and albumin, a non-specific protein control, were evaluated. Coronary flow rates and myocardial temperature were continuously monitored to ensure uniform perfusion conditions. The MDA assay was carefully monitored by constructing standard curves on each experimental day. Addition of 20 microM cumene hydroperoxide to oxygenated perfused hearts caused peroxidative cell injury as evidenced by significant MDA and CK release in the coronary effluent. DMTU and catalase provided near complete protection from cumene hydroperoxide-induced cell injury but did not reduce CK release from hearts subjected to either the mild (30-min) or the severe (60-min) oxygen paradox (reoxygenation-induced injury). Allopurinol caused a significant reduction in MDA release but not CK release from oxygen paradox-injured hearts. Allopurinol and albumin had no significant effect on MDA release from cumene-hydroperoxide-injured hearts. Catalase (300 U/ml) caused a mild but not statistically significant reduction in MDA release from cumene hydroperoxide injury but did not provide protection from the oxygen paradox at either injury level. Mannitol (120 mM), in contrast to DMTU, was ineffective in reducing cumene-induced injury but showed a significant protective effect against oxygen paradox-induced damage. It is concluded that the ability of mannitol to reduce reoxygenation-induced CK release in the oxygen paradox may be due to its osmotic activity and consequent ability to prevent cellular swelling rather than its activity as an oxygen-free radical scavenger.
J Mol Cell Cardiol 1987 Jun
PMID:Effects of the free radical scavenger DMTU and mannitol on the oxygen paradox in perfused rat hearts. 311 97

The activity and location of xanthine oxidase (EC.1.2.3.2.) and xanthine dehydrogenase (EC.1.2.1.37) have been measured using luminol-enhanced chemiluminescence in four types of cell from the cardiovascular system (neonatal and adult rat cardiac myocytes, rat aortic vascular smooth muscle cells, rat cardiac fibroblasts and human umbilical vein endothelial cells). The detection system developed was both rapid and reproducible and could be used on sub-milligram quantities of cells. Xanthine oxidase was located primarily in cells derived from the vasculature and especially in endothelial cells, as was xanthine dehydrogenase. Only neonatal myocytes had more dehydrogenase activity than oxidase. The significance of the location and activity of these enzymes is discussed in relation to the pathology of myocardial ischaemia, arrhythmogenesis and microvascular disorders.
Basic Res Cardiol
PMID:Chemiluminescence measurements of xanthine oxidase and xanthine dehydrogenase activity in four types of cardiovascular cell. 319 Jun 57

Cardioprotection by allopurinol during ischemia is thought to be due to inhibition of xanthine oxidase-derived reactive oxygen intermediates. Previous studies have reported that long pretreatment with allopurinol limits tissue necrosis during acute myocardial ischemia. This study investigated whether a prolonged pretreatment with allopurinol was necessary for cardioprotection. Tissue necrosis was measured in a closed chest canine model of permanent coronary occlusion when the drug was administered post coronary occlusion. In 20 dogs the coronary artery was occluded by an embolus injected into the left coronary artery. Three groups were studied: untreated controls (saline given intravenously post occlusion); allopurinol 1 min post occlusion (25 mg/kg given intravenously, 1 min post occlusion); and allopurinol 30 mins post occlusion (25 mg/kg given intravenously 30 mins post occlusion). Dogs in both drug treatment groups also received allopurinol (25 mg/kg intravenously) every 8 h post coronary occlusion. After 24 h of permanent coronary occlusion tissue necrosis was evaluated using triphenyl tetrazolium chloride staining and was related to major baseline predictors of infarct size, including anatomic risk zone and coronary collateral flow. In control dogs, infarct to risk zone ratio was inversely related to subepicardial collateral flow; analysis of covariance indicated that allopurinol administered post coronary occlusion did not shift this relationship. Treatment with allopurinol within the first minutes after coronary occlusion was ineffective in limiting tissue necrosis in this model of permanent coronary occlusion, therefore, long pretreatment with allopurinol is necessary for cardioprotection.
Can J Cardiol 1988 Oct
PMID:Myocardial salvage with allopurinol during 24 h of permanent coronary occlusion: importance of pretreatment. 322 62

Oxygen free radicals may participate in a variety of pathological cardiac conditions which are associated with an increased incidence of arrhythmias. However, evidence that free radicals per se can alter the electrical function of the myocardium is not convincing. Physiological solutions containing 3 mM dihydroxyfumaric acid (DHF), a compound known to generate free radicals, were superfused over calcium-tolerant cells isolated from the adult canine ventricle. The time course for changes in transmembrane action potentials was monitored using conventional microelectrode techniques. Changes were observed which could be conveniently segregated into three stages. Initially during superfusion with DHF, the voltage of the action potential plateau became more positive and the action potential duration increased (stage 1). Continued superfusion was associated with the development of both early and delayed afterdepolarizations (stage 2), which occasionally produced triggered beats. Subsequently, some cells failed to repolarize beyond -40 mV following an action potential upstroke. In cells which maintained normal levels of resting membrane potential, early and delayed afterdepolarizations ceased concomitant with the development of an increasingly more negative plateau voltage. Action potential duration decreased and plateau potential "collapsed", eventually merging with the resting level of the membrane potential. Resting membrane potential then gradually depolarized to less than -40 mV and all cells became inexcitable within 6 to 20 min (stages 3). Exposure of cells to xanthine (2 mM): xanthine oxidase (0.01 U/ml), another system known to generate free radicals, produced similar results. Superfusion with DHF solutions containing either superoxide dismutase or catalase delayed the appearance and attenuated the development of the changes in the cardiocyte action potential. The results demonstrate that isolated cardiocytes exposed to free radical generating solutions can undergo changes in their electrophysiological activity that resemble those said to underlie disturbances of cardiac rate and rhythm in the clinical setting.
J Mol Cell Cardiol 1988 Dec
PMID:Abnormal electrical activity induced by free radical generating systems in isolated cardiocytes. 324 6

Compelling evidence has been accumulated which indicates that myocardial tissue damage occurring during reperfusion after an ischaemic period may partly be due to the formation of oxygen free radicals and subsequent peroxidative processes. It has been well established that the actual toxicity of free radicals is dependent on the presence of free iron in the heart tissue. Based upon the hypothesis of McCord et al., proposing xanthine oxidase mediated formation of superoxide (O2-.) during the conversion of ATP-breakdown product(s) (hypo)xanthine to urate, we studied whether xanthine oxidase was able to mobilize free iron from the intra- and extracellular iron-binding proteins, ferritin and transferrin. It appeared that there was an O2-.-dependent and O2-.-independent mechanism by which xanthine oxidase could mobilize iron from ferritin while no iron mobilization from transferrin was detectable. The capacity of xanthine oxidase to mobilize iron from ferritin by an O2-.-independent mechanism implies that already during the anoxic/ischaemic period, iron may become available in the tissue which, upon the re-entrance of O2, catalyzes the formation of the very reactive OH radicals. The interaction between endothelial cells and cardiocytes in free radical homeostasis is discussed with the emphasis on the tissue localization of xanthine oxidase. The latter is located in endothelial cells implying an interaction between xanthine oxidase-induced endothelial cells initiated lipid peroxidation and the actual overall myocardial tissue damage.
Basic Res Cardiol 1987
PMID:Lipid peroxidation and myocardial ischaemic damage: cause or consequence? 331 Oct 8


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