Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts: Gene/Protein Disease Symptom Drug Enzyme Compound   Target Concepts: 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)

Among the mechanisms postulated to contribute to myocardial "stunning" is a depression of contractility by oxygen-derived free radicals. It has been suggested that these radicals might depress the calcium sensitivity of the contractile proteins. We have exposed the myofilaments (in chemically "skinned" rat cardiac muscle) to the superoxide anion and measured isometric force at controlled degrees of activation. Superoxide was generated by the xanthine/xanthine oxidase system: the effects to be described were shown to be specifically attributable to superoxide. Maximum calcium-activated force is reduced, or even completely abolished, in a dose-dependent fashion and without any alteration in calcium sensitivity. The myofilaments are highly sensitive to superoxide: significant force reduction has been shown to be caused by enzyme concentrations as low as 2 microunits/ml xanthine oxidase and with exposures of less than 1 minute to the generating system (at higher enzyme concentrations). Once force has been depressed, it cannot be recovered within the duration of the experiments described. When xanthine oxidase is applied during the calcium-induced contracture, tension falls steadily. However, a similar concentration is without immediate effect on the rigor contracture (evoked by applying ATP-free solutions). To account for the depression of maximum calcium-activated force, we conclude that some aspect of crossbridge behavior is particularly vulnerable to superoxide rather than that the radical has a nonspecific "proteolytic" effect. This action on the fundamental units of force production could contribute to myocardial stunning since the effects we report are consistent with many aspects of this phenomenon.
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PMID:Depression of peak force without altering calcium sensitivity by the superoxide anion in chemically skinned cardiac muscle of rat. 131 36

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.
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PMID:Modification of cardiac action potential by photosensitizer-generated reactive oxygen. 277 6

Reduced oxygen intermediates have been shown to directly depress cardiac muscle function at the subcellular, tissue, and whole animal levels. The exact species of reduced oxygen intermediate [superoxide anion radical (O2-.), H2O2, hydroxyl free radical (HO.)] and the concentrations necessary to depress cardiac muscle function have not been quantified. To better understand the role of O2-. and H2O2, we have studied rabbit right ventricular papillary muscle function in the presence of these reduced oxygen intermediates generated by a xanthine-xanthine oxidase system at 37 degrees C. In the presence of xanthine (0.1 mM) and xanthine oxidase (0.02 U/ml), 57.5 +/- 0.85 nmol.l-1.s-1 O2-. and 69.25 +/- 5.3 nmol.l-1.s-1 H2O2 were produced. In the presence of superoxide dismutase (SOD), O2-. was eliminated and H2O2 concentration increased. Catalase effectively eliminated the accumulation of H2O2 without significantly changing the rate of O2-. generation. When applied to isometrically contracting right ventricular papillary muscles, this system, with or without SOD and catalase, had no effect on peak developed tension or +/- dT/dt derived either from length-tension or force-frequency studies. However, when the xanthine oxidase concentration was increased to 0.112 U/ml, the rate of O2-. generation increased to 196.67 +/- 3.26 nmol.l-1.s-1 and H2O2 production increased to 142.19 +/- 9.3 nmol.l-1.s-1 with significant depression of papillary muscle tension development. SOD virtually eliminated O2-. production, whereas H2O2 production increased to 199.48 +/- 9.8 nmol.l-1.s-1 with no effect on papillary muscle tension development.(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Quantitative identification of superoxide anion as a negative inotropic species. 283 94

The role of reactive metabolites of oxygen, oxygen radicals (O-Rs), as mediators of potentially arrhythmogenic alterations in cellular electrical properties and contractile dysfunction of cardiac muscle during reperfusion after ischemia was investigated. Electrical and mechanical activities of arterially perfused guinea pig right ventricular walls were recorded simultaneously with intracellular microelectrodes and a force transducer. Preparations were maintained in Krebs-Henseleit solution (perfusion rate, 1.5 mL/min) and subjected to 30 minutes of no-flow ischemia followed by 60 minutes of reperfusion or pretreated with O-R scavengers (superoxide dismutase, 50 U/mL; catalase, 600 U/mL; and mannitol, 2 mmol/L) for 10 to 20 minutes, followed by 30 minutes of ischemia and 60 minutes of reperfusion. Reperfusion in untreated preparations caused (1) depolarization of resting membrane potential by 8 to 10 mV and slow recovery of action potential duration requiring 60 minutes to attain the preischemic duration, (2) tachyarrhythmias and premature action potentials, (3) postischemic contractile dysfunction, and (4) increased coronary perfusion pressure in untreated preparations. Pretreatment with scavenger cocktail affected neither electrical nor contractile activity before or during no-flow ischemia, but it (1) accelerated recovery of resting membrane potential and action potential duration, (2) reduced the incidence of tachyarrhythmia, (3) improved contractile function, and (4) inhibited the rise in perfusion pressure on reflow. Reperfusion with an exogenous O-R-generating system containing xanthine/xanthine oxidase (X/XO, 2 mmol/L:10 mU/mL) inhibited recovery of action potential duration and contractility. Treatment of normoxic arterially perfused right ventricular walls with X/XO caused a decline in action potential duration by approximately 20% within 30 minutes. In contrast, X/XO caused a 30% increase in the duration of action potentials in superfused papillary muscles or small strips of right ventricular walls over the same time period. Pretreatment with sodium nitroprusside (10 mumol/L) inhibited the decline in duration induced by X/XO in normoxic right ventricular walls but was without effect on prolongation due to X/XO in papillary muscles. Reperfusion with nitroprusside after no-flow ischemia caused (1) accelerated recovery of preischemic action potential configuration, (2) a significant decline in the incidence of reperfusion arrhythmias, (3) improved postischemic contractile performance, and (4) inhibition of the increase in perfusion pressure associated with reflow. The data indicate that slow recovery of the action potential duration caused by O-Rs in reperfusion cannot be explained by the direct effects of O-Rs on cardiac myocytes.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:Arrhythmia and delayed recovery of cardiac action potential during reperfusion after ischemia. Role of oxygen radical-induced no-reflow phenomenon. 778 73

Reactive free radical species appear to be involved in the ischemic injury of cardiac muscle, although the mechanisms by which oxygen-derived free radicals affect the heart cell function are not known. In the present study, cultured ventricular myocytes were exposed to an exogenous oxygen radical generating system. The myocyte-enriched, primary cultures were prepared from ventricles of new-born rat heart and exposed to a xanthine/xanthine oxidase (X+XO) system. The transmembrane potentials were recorded with glass microelectrodes. Cell contractions were monitored photometrically. The release of lactate dehydrogenase (LDH) in the medium was analysed. Quantitative measurement and the time course of the radical generation were performed by the electron paramagnetic resonance (EPR) spin trapping technique with the spin trap 5,5-dimethyl-1-pyroline-N-oxide (DMPO). We verified that X and XO alone had no significant functional and biochemical effects. The X+XO system produced a rapid decrease in the action potential amplitude. This effect was accompanied by a strong decrease in contractility and spontaneous rate. The time course of these functional defects were correlated with a progressive efflux of LDH from the cardiomyocytes. Prolonging the exposure to the X+XO system provoked the cessation of the spontaneous beatings and the progressive loss of the resting diastolic potential, together with a near total release of the cellular LDH. The LDH release and the functional depression were both efficiently prevented by catalase. On the contrary, superoxide dismutase (SOD) slowed down but did not protect against the functional and biochemical effects of the free radicals. In comparison, the EPR spectra obtained indicated that the X+XO system was associated with an important generation of superoxide anions but also with a small hydroxyl production. SOD scavenged the superoxide but a small .OH production persisted. Catalase (CAT) did not modify the superoxide generation but decreased the hydroxyl adduct formation. These results suggest that, although the generation of superoxide anions by the X+XO system was higher than the hydroxyl production, the functional injury and enzyme leakage seemed mainly mediated through a hydrogen peroxide-hydroxyl radical pathway. Cultured ventricular myocytes can be thus used as a valuable model to investigate the cellular mechanism of oxidant-induced damage in the heart.
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PMID:Correlation between direct ESR spectroscopic measurements and electromechanical and biochemical assessments of exogenous free radical injury in isolated rat cardiac myocytes. 943 21

The ryanodine receptor Ca2+ channel (RyRC) constitutes the Ca2+-release pathway in sarcoplasmic reticulum (SR) of cardiac muscle. A direct mechanical and a Ca2+-triggered mechanism (Ca2+-induced Ca2+ release) have been proposed to explain the in situ activation of Ca2+ release in cardiac muscle. A variety of chemical oxidants have been shown to activate RyRC; however, the role of modification induced by oxygen-derived free radicals in pathological states of the muscle remains to be elucidated. It has been hypothesized that oxygen-derived free radicals initiate Ca2+-mediated functional changes in or damage to cardiac muscle by acting on the SR and promoting an increase in Ca2+ release. We confirmed that superoxide anion radical (O2-) generated from hypoxanthine-xanthine oxidase reaction decreases calmodulin content and increases 45Ca2+ efflux from the heavy fraction of canine cardiac SR vesicles; hypoxanthine-xanthine oxidase also decreases Ca2+ free within the intravesicular space of the SR with no effect on Ca2+-ATPase activity. Current fluctuations through single Ca2+-release channels have been monitored after incorporation into planar phospholipid bilayers. We demonstrate that activation of the channel by O2- is dependent of the presence of calmodulin and identified calmodulin as a functional mediator of O2--triggered Ca2+ release through the RyRC. For the first time, we show that O2- stimulates Ca2+ release from heavy SR vesicles and suggest the importance of accessory proteins such as calmodulin in modulating the effect of O2-. The decreased calmodulin content induced by oxygen-derived free radicals, especially O2-, is a likely mechanism of accumulation of cytosolic Ca2+ (due to increased Ca2+ release from SR) after reperfusion of the ischemic heart.
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PMID:Superoxide anion radical-triggered Ca2+ release from cardiac sarcoplasmic reticulum through ryanodine receptor Ca2+ channel. 949 17

Because the net Ca2+ uptake in the sarcoplasmic reticulum (SR) of cardiac muscle is a result of the activity of Ca(2+)-ATPase and of the SR Ca(2+)-release channel, an abnormal Ca2+ uptake may be the result of the dysfunction of either or both structures. The site or sites of action for oxygen-derived free radicals (OFR) damage are unknown, although previous studies on the SR have focused on damage to the Ca2+ pump. Direct effects of OFR on SR Ca(2+)-release channels may be important in understanding their potential contribution to myocardial ischemia/reperfusion injury. We confirmed that superoxide anion radical (O2.-) generated from hypoxanthine-xanthine oxidase reaction decreases calmodulin content and increases 45Ca2+ efflux from the heavy fraction of canine cardiac SR vesicles. Electron spin resonance study showed that hydroxyl radicals are generated in addition to O2.- from hypoxanthine-xanthine oxidase reaction, and data indicate that O2.- is responsible for the observed effect. Current fluctuations through single Ca(2+)-release channels have been also monitored after incorporation into planar phospholipid bilayers. We directly demonstrate that activation of the channel by O2.- stimulates Ca2+ release from heavy SR vesicles and suggest the importance of accessory proteins such as calmodulin in modulating the effect of O2.-.
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PMID:[Superoxide anion radical selectively increases Ca2+ release from cardiac sarcoplasmic reticulum through ryanodine receptor Ca2+ channel]. 1019 Jan 35

Allopurinol, an inhibitor of xanthine oxidase, increases myofilament calcium responsiveness and blunts calcium cycling in isolated cardiac muscle. We sought to extend these observations to conscious dogs with and without pacing-induced heart failure and tested the prediction that allopurinol would have a positive inotropic effect without increasing energy expenditure, thereby increasing mechanical efficiency. In control dogs (n=10), allopurinol (200 mg IV) caused a small positive inotropic effect; (dP/dt)(max) increased from 3103+/-162 to 3373+/-225 mm Hg/s (+8.3+/-3.2%; P=0.01), but preload-recruitable stroke work and ventricular elastance did not change. In heart failure (n=5), this effect was larger; (dP/dt)(max) rose from 1602+/-190 to 1988+/-251 mm Hg/s (+24.4+/-8.7%; P=0.03), preload-recruitable stroke work increased from 55.8+/-9.1 to 84. 9+/-12.2 mm Hg (+28.1+/-5.3%; P=0.02), and ventricular elastance rose from 6.0+/-1.6 to 10.5+/-2.2 mm Hg/mm (P=0.03). Allopurinol did not affect myocardial lusitropic properties either in control or heart failure dogs. In heart failure dogs, but not controls, allopurinol decreased myocardial oxygen consumption (-49+/-4.6%; P=0. 002) and substantially increased mechanical efficiency (stroke work/myocardial oxygen consumption; +122+/-42%; P=0.04). Moreover, xanthine oxidase activity was approximately 4-fold increased in failing versus control dog hearts (387+/-125 versus 78+/-72 pmol/min. mg(-1); P=0.04) but was not detectable in plasma. These data indicate that allopurinol possesses unique inotropic properties, increasing myocardial contractility while simultaneously reducing cardiac energy requirements. The resultant boost in myocardial contractile efficiency may prove beneficial in the treatment of congestive heart failure.
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PMID:Intravenous allopurinol decreases myocardial oxygen consumption and increases mechanical efficiency in dogs with pacing-induced heart failure. 1047 73

Oxipurinol [alloxanthine, Oxyprim, oxypurinol] is the active metabolite of the only commercially available xanthine oxidase inhibitor, allopurinol. Oxipurinol is also a xanthine oxidase inhibitor. Oxipurinol is currently being developed by Cardiome Pharma. It is waiting for approval in the US for the treatment of allopurinol-intolerant hyperuricaemia (gout) and is in phase III trials for the treatment of congestive heart failure. Allopurinol is indicated for the treatment of symptomatic hyperuricaemia, or gout. Approximately 3-5% of patients receiving allopurinol develop intolerance to the drug. Oxipurinol was originally developed by Burroughs Wellcome (later GlaxoSmithKline), and has been available on a compassionate-use basis since 1967 for use in allopurinol-intolerant patients. The licensee company ILEX Oncology has stated that oxipurinol does not have patent protection. Oxipurinol's potential for treatment of congestive heart failure is based on the possibility that xanthine oxidase inhibitors may improve myocardial work efficiency by sensitising cardiac muscle cells to calcium ions, which are a key determinant of cardiac muscle function. This results in more efficient contraction of cardiac muscle cells, without the same increase in oxygen demand. At the second annual BioPartnering North America conference (BPN-2004) [February 2004, Vancouver, Canada], Cardiome Pharma stated that it was seeking a commercialisation partner to market and distribute oxipurinol in the US for the treatment of allopurinol-intolerant hyperuricaemia. In 1995, ILEX Oncology obtained an exclusive licence to oxipurinol from Burroughs Wellcome. Burroughs Wellcome later became part of Glaxo Wellcome, which merged with SmithKline Beecham in December 2000 to form GlaxoSmithKline. ILEX's licence agreement is now with GlaxoSmithKline and The Wellcome Foundation. In December 2001, ILEX granted Paralex, a privately held New York-based company, an exclusive sublicence to all of ILEX's rights to oxipurinol for the treatment of hyperuricaemia in allopurinol-intolerant patients. Paralex additionally gained the right to develop and commercialise oxipurinol in all fields, under data and technology owned by ILEX. Furthermore, Paralex had licensed certain intellectual property rights from The John Hopkins University relating to cardiovascular applications of xanthine oxidase inhibitors. Paralex was acquired by Cardiome Pharma in March 2002. Cardiome Pharma announced early in May 2002 that it had exercised its option to acquire from ILEX Oncology Inc. rights to clinical trial data for oxypurinol for the treatment of gout in allopurinol-intolerant patients. ILEX completed its open-label phase II clinical study of Oxyprim in allopurinol-intolerant gout patients, and the trial data were transferred to Cardiome. Cardiome stated in May 2002 that it intended to commence a further phase II trial of oxypurinol in gout. Phase III trials were in progress in 2003 in this indication. In 1995, ILEX Oncology continued the compassionate use distribution of oxipurinol while establishing a US FDA-approved registration plan for the agent. In November 1998, ILEX received Orphan Drug status for the use of oxipurinol in patients with symptomatic hyperuricaemia. ILEX Oncology's Development Pipeline for 1998 stated that oxipurinol had entered phase II clinical trials for the treatment of hyperuricaemia. In 2001, the clinical trials listing service CenterWatch stated that oxipurinol was in a phase II clinical trial with ILEX Oncology for the treatment of symptomatic hyperuricaemia in patients who are intolerant to allopurinol. The trial appeared to be taking place in the US, and was a multicentre, open-label, 14-week study in 90 patients. In February 2003, Cardiome confirmed beginning patient enrollment in three smaller phase II studies, with the first trial (EXOTIC) now completed. These three smaller proof-of-concept studies will observe surrogate endpoints such as cardiac output and exercise tolerance. The second proof-of-concept study in patients with CHF of ischemic aetiology (IV), known as EXOTIC-EF (Evaluation of XanThine Oxidase Inhibition on Cardiac Ejection Fraction), will assess the effects of oxypurinol on left ventricular performance. The EXOTIC-EF trial will start in the first quarter of 2004 and be completed by the second quarter of 2004. The third, LA PLATA, proof-of-concept study will explore the effects of 1 month of oral oxypurinol therapy on exercise capacity and left ventricular performance. It is projected that the LA PLATA study will start in the first quarter of 2004 and be completed by the third quarter of 2004. During the Heart Failure Society of America's meeting on 21 September 2003, Cardiome presented clinical data from its first proof-of-concept EXOTIC (European Xanthine Oxidase Inhibitors Trial In Cardiac Disease) study. Cardiome intends to conduct a second trial, at the Eppendorf Clinic at the University of Hamburg, to determine the effect of oxypurinol on left ventricular performance in patients with CHF of ischaemic aetiology. This study will be an extension of the original proof-of-concept study. According to the 1st Annual BioPartnering conference held in Vancouver, Canada, in February 2003, Cardiome is seeking co-development partners for oxipurinol in the treatment of congestive heart failure. In July 2003, the US Patent and Trademark Office issued a new patent providing additional protection to Cardiome's programme focused on treatment of congestive heart failure with oxypurinol. The patent, No. 6,569,862, was the second issued to the Johns Hopkins University (JHU) in this field. The key claims in the new patent cover use of the entire family of drugs known as xanthine oxidase inhibitors applied to contractile disorders of the heart, including congestive heart failure. An earlier patent issued to JHU contained provisions relating to a specific mechanism of action and to specific forms of heart disease. Both patents and related intellectual property are licensed exclusively to Cardiome.
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PMID:Oxipurinol: alloxanthine, Oxyprim, oxypurinol. 1513 81

Heart failure is a clinical syndrome associated with elevated levels of oxygen-derived free radicals. Xanthine oxidase activity is believed to be one source of reactive oxygen species in the failing heart. Interventions designed to reduce oxidative stress are believed to have significant therapeutic potential in heart failure. This study tested the hypothesis that xanthine oxidase activity would be elevated in a mouse model of dilated cardiomyopathy and evaluated the effect of chronic oral allopurinol, an inhibitor of xanthine oxidase, on contractility and progressive ventricular dilation in these mice. Nontransgenic and transgenic mice containing a troponin I truncation were treated with oral allopurinol from 2-4 mo of age. Myocardial xanthine oxidase activity was threefold higher in untreated transgenic mice compared with nontransgenic mice. Analyses of myofilament proteins for modification of carbonyl groups demonstrated myofibrillar protein damage in untreated transgenic mice. Treatment with allopurinol for 2 mo suppressed xanthine oxidase activity and myofibrillar protein oxidation. Allopurinol treatment also alleviated ventricular dilation and preserved shortening fraction in the transgenic animals. In addition, cardiac muscle twitch tension was preserved to 70% of nontransgenic levels in allopurinol-treated transgenic mice, a significant improvement over untreated transgenic mice. These findings indicate that chronic inhibition of xanthine oxidase can alter the progression of heart failure in dilated cardiomyopathy.
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PMID:Chronic xanthine oxidase inhibition prevents myofibrillar protein oxidation and preserves cardiac function in a transgenic mouse model of cardiomyopathy. 1586 59


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