EC:1.17.3.2 - FACTA Search

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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)

Purine nucleotide synthesis and interconversion were examined over a range of purine base and nucleoside concentrations in intact N4 and N4TG (hypoxanthine-guanine phosphoribosyltransferase (HGPRT) deficient) neuroblastoma cells. Adenosine was a better nucleotide precursor than adenine, hypoxanthine or guanine at concentrations greater than 100 micron. With hypoxanthine or guanine, N4TG cells had less than 2% the rate of nucleotide synthesis of N4 cells. At substrate concentrations greater than 100 micron the rates for deamination of adenosine and phosphorolysis of guanosine exceeded those for any reaction of nucleotide synthesis. Labelled inosine and guanosine accumulated from hypoxanthine and guanine, respectively, in HGPRT-deficient cells and the nucleosides accumulated to a greater extent in N4 cells indicating dephosphorylation of newly synthesized IMP and GMP to be quantitatively significant. A deficiency of xanthine oxidase, guanine deaminase and guanosine kinase activities was found in neuroblastoma cells. Hypoxanthine was a source for both adenine and guanine nucleotides, whereas adenine or guanine were principally sources for adenine (greater than 85%) or guanine (greater than 90%) nucleotides, respectively. The rate of [14C]formate incorporation into ATP, GTP and nucleic acid purines was essentially equivalent for both N4 and N4TG cells. Purine nucleotide pools were also comparable in both cell lines, but the concentration of UDP-sugars was 1.5 times greater in N4TG than N4 cells.
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PMID:A comparison of purine metabolism and nucleotide pools in normal and hypoxanthine-guanine phosphoribosyltransferase-deficient neuroblastoma cells. 71 89

This study was accomplished to examine the relative importance of different metabolic precursors of nucleic acid synthesis in the malarial parasite, P. berghei. Three possible pathways for incorporation of Adenine (type) compounds exist: 1) incorporation via hypoxanthine, 2) via adenine, or 3) via adenosine. The parasitized cell and erythrocyte-free malarial parasite were both examined because of possible metabolic differences that could be encountered. Hypoxanthine was clearly the best precursor at both levels with extra-incorporation in the presence of allopurinol (10(-4)M), which protects oxidative metabolism of hypoxanthine. Adenosine was less efficient in its incorporation into nucleic acids at both levels. Adenine was clearly the poorest precursor being extremely less efficient compared to hypoxanthine 1/50 at parasitized cell level and 1/100 at the free parasite level. At both levels adenine seemed to be slightly more efficient in the presence of allopurinol and this appeared to be a similar to the incorporation via adenosine with allopurinol. In both cases, part of the incorporation could be coming via conversion to hypoxanthine because allopurinol protects oxidation of hypoxanthine via inhibition of xanthine oxidase. With the prior observation of Manandhar and Van Dyke that adenosine is converted to hypoxanthine outside or on the surface of the malarial parasite one is lead to conclude that of the three pathways the hypoxanthine pathway is probably the major and possibly the almost totally important pathway making hypoxanthine's uptake and/or conversion to inosine monophosphate a key event of metabolic and chemotherapeutic importance.
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PMID:Comparison of tritiated hypoxanthine, adenine and adenosine for purine-salvage incorporation into nucleic acids of the malarial parasite, Plasmodium berghei. 109 47

Adenosine has been shown to protect the ischemic and reperfused myocardium. To examine whether the protective effect of the nucleoside is mediated by modulation of oxidative stress, isolated rat hearts were perfused for 30 minutes with 100 microM H2O2 or an exogenous free radical-generating system consisting of purine (3.06 mM) and xanthine oxidase (10 units/l) in the presence or absence of drugs acting on adenosine A1 or A2 receptors. H2O2 alone produced a greater than 90% loss in contractility concomitant with a threefold elevation in resting tension, although these effects occurred in the absence of ultrastructural damage. Two A1 receptor agonists N6-cyclopentyladenosine (CPA, 1 microM) and R(-)-N6-(2-phenylisopropyl)adenosine (R-PIA, 1 microM) significantly attenuated the cardiodepressant effects of H2O2 and depressed the elevation in resting tension; however, only the effect of CPA was found to be significant with regard to the latter parameter. A similar concentration of S(+)-N6-(2-phenylisopropyl)adenosine (S-PIA), a markedly less potent A1 receptor agonist, was found to be without beneficial effect. However, a significant protective effect against both the reduction in contractility and the elevation in resting tension was seen with a 10-fold elevation in the concentration of S-PIA (10 microM). The protective effects on functional parameters were associated with preservation of high-energy phosphate and adenine nucleotide contents after 30 minutes of H2O2 treatment. The salutary effects of all drugs were reversed in the presence of the A1 receptor antagonist 1,3-dipropyl-8-cyclopentylxanthine (0.5 microM). An A2 receptor agonist 2-[p-(carboxyethyl)phenethylamino]-5'-N-ethylcarboxamidoadenosine, termed CGS 21680 (1 microM), failed to alter the cardiac response to H2O2 with regard to all parameters studied. Neither a 50% reduction in external CaCl2 concentration nor treatment with 10 microM DL-propranolol exerted salutary effects against H2O2-induced dysfunction. None of the A1 receptor agonists modulated the response to purine plus xanthine oxidase. Our results demonstrate a selective protective effect of adenosine A1 receptor activation against the cardiac toxicity of H2O2 and provide, at least in part, a basis for the cardioprotective actions of adenosine and its analogues.
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PMID:Adenosine A1 receptor activation attenuates cardiac injury produced by hydrogen peroxide. 139 72

A pair of ribonuclease assays have been developed which offer improvements in specificity, simplicity, and/or sensitivity over current procedures. The assays measure the rate of adenosine release upon ribonuclease hydrolysis of 3'-adenosyl dinucleoside monophosphate substrates. Adenosine formation is spectrophotometrically determined by combining a coupled-enzyme system (adenosine deaminase or an adenosine deaminase/nucleoside phosphorylase/xanthine oxidase combination) to the ribonuclease cleavage. As demonstrated by a brief characterization of the ribonuclease activities in several mouse tissues, the methods demonstrate the advantage of being able to discriminate between ribonucleases of differing substrate specificities. An interesting guanosyl(3'-5')adenosine-specific ribonuclease in mouse brain has been identified using these assay methods.
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PMID:Spectrophotometric ribonuclease assays using dinucleoside monophosphate substrates. 152 17

Adenosine produced from 5'-AMP has been proposed as a mediator of intrinsic renal regulation. The rates of 5'-AMP and adenosine metabolism are dependent on the activities of enzyme involved in purine metabolism. The activities of adenosine kinase (AK), adenosine deaminase (ADA), 5'-nucleotidase (5'-NT), AMP deaminase, xanthine oxidase and purine nucleoside phosphorylase were measured in cytosolic and membrane fractions from glomeruli, cortical tubules, medullary thick ascending limb of Henle (MTAL) and collecting duct prepared from rat kidney by combinations of sieving and sucrose density gradient centrifugation techniques. In the cytoplasm of glomeruli cells, the activity ratios of ADA/AK and AMP deaminase/5'-NT were 70 and 2.4, respectively. The highest activity of 5'-NT was found in membrane fractions of cortical tubules where it was equally distributed between luminal and antiluminal membranes. Membrane fractions of MTAL did not contain detectable amounts of adenosine deaminase activity. The highest activity of xanthine oxidase and purine nucleoside phosphorylase was in the cytoplasm fraction of glomeruli. These results suggest that deamination of AMP and adenosine may be favored in the cytoplasm of glomeruli cells. In contrast, in the extracellular space of glomeruli and especially in the cortical tubule, AMP can be converted preferentially to adenosine by 5'-NT.
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PMID:The distribution of enzymes involved in purine metabolism in rat kidney. 161 Aug 88

Adenosine and adenine nucleotides shorten the action potential duration of atrial myocytes and activate a specific acetylcholine and adenosine receptor-operated potassium outward current referred to as IKACh,Ado. The objective of this study was to determine whether adenine nucleotides shorten the action potential duration and increase IKACh,Ado in guinea pig atrial myocytes by directly activating adenosine receptors. The potency and efficacy of AMP and adenosine in increasing IKACh,Ado and shortening atrial action potential duration were similar; the EC50 values for AMP and adenosine were 3.4 +/- 0.8 and 3.1 +/- 0.4 microM, respectively. Likewise, the maximum increases in IKACh,Ado caused by AMP and adenosine were similar (122 +/- 11% versus 123 +/- 9%). In comparison, ATP and the stable analogue of AMP, adenosine monophosphorothioate (AMPS), were significantly less potent and efficacious than adenosine and AMP, and adenosine receptor antagonist 8-(p-sulfophenyl)theophylline and abolished in the presence of adenosine deaminase and alpha, beta-methylene-ADP (APCP, an inhibitor of AMP degradation). Binding of the A1-adenosine antagonist [3H]8-cyclopentyl-1,3-dipropylxanthine (DPCPX) to guinea pig atrial membranes treated with adenosine deaminase and APCP was reduced up to 60% by 100 microM concentrations of AMP, AMPS, and adenosine. Inosine inhibited binding by 43 +/- 3% at 100 microM, whereas hypoxanthine and xanthine had little (5-10% inhibition) and uric acid had no effect. Only 3% of AMP and 35% of AMPS were recovered intact after a 90-minute incubation at 21 degrees C with preparations of guinea pig atrial membranes. Percent displacement of [3H]DPCPX binding to atrial membranes by 100 microM AMP was significantly less in the presence of nucleoside phosphorylase and xanthine oxidase (to degrade inosine, hypoxanthine, and xanthine to uric acid) than in their absence (12.4 +/- 3.1% versus 49.7 +/- 1.5%). The results suggest that the observed electrophysiological actions of adenine nucleotides in cardiomyocytes are mediated by adenosine and are consistent with activation of A1-adenosine receptors.
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PMID:Electrophysiological and receptor binding studies to assess activation of the cardiac adenosine receptor by adenine nucleotides. 200 6

1. Adenosine metabolizing enzymes in seminal plasma of man and bull have been investigated. 2. A different level of 5'-nucleotidase activity has been found in two seminal plasmas: in bull 5'-nucleotidase represents 80% of the total AMP dephosphorylating enzymes while in man 5'-nucleotidase represents only 1.3% of the total AMP dephosphorylating activities. 3. Apart from the different levels of 5'-nucleotidase activity, different kinetic parameters have been reported for 5'-nucleotidase, acid prostatic phosphatases, ADA and PNP. 4. Adenosine kinase, xanthine oxidase and AdoHcy-hydrolase have not been detected in the seminal plasma of man and bull.
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PMID:Adenosine metabolizing enzymes in seminal plasma of bull and man: a comparative study. 212 26

Acetylcholine and ATP are costored and coreleased during synaptic activity at the electric organ of Torpedo. It has been suggested that released ATP is converted to adenosine at the synaptic cleft, and in turn this nucleoside would depress the evoked release of acetylcholine. In the present communication we have used a chemiluminescent reaction that let us to monitor continuously the presence of adenosine in this preparation. The chemiluminescent reaction is based on the conversion of adenosine into uric acid and H2O2 by adenosine deaminase, nucleoside phosphorylase, and xanthine oxidase enzymes. The hydrogen peroxide has been detected by peroxidase-luminol mixture. The reaction has a sensitivity on the picomol range and discerned between Adenosine, AMP, ADP, and ATP. We have developed this technique in the hope of understanding whether adenosine is released during synaptic activity or it comes from the released ATP. We have studied the release or formation of adenosine in fragments of the electric organ and in isolated cholinergic nerve terminals obtained from it. In both conditions we have followed the effect of potassium stimulation upon the detection of adenosine. Potassium stimulation increased the extracellular adenosine either in slices or the synaptosomal fraction of Torpedo electric organ. The presence of alpha, beta-methylene ADP, an inhibitor of 5'-nucleotidase, inhibits the detection of adenosine, suggesting that extracellular adenosine is a consequence of ectocellular dephosphorylation of released ATP.
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PMID:The release of adenosine at the electric organ of Torpedo. A study using a continuous chemiluminescent method. 232 27

Studies on the mechanism of immunosuppression shown by adenine comprised two areas: (1) Toxicity studies on hepatic, muscle and renal tissues were undertaken to ascertain if immunosuppression was a result of a non specific toxicity. (2) Studies to determine whether immunosuppression is a function of the inhibitory effect on de novo and salvage pathways of purine nucleotide metabolism. Toxicity studies in mice indicated that adenine caused an acute, reversible renal tubular necrosis and that allopurinol, when combined with adenine, could abrogate both the renal toxicity and immunosuppressive activity of the purine base. This result indicated that the toxic and/or immunosuppressive compound may be a xanthine oxidase catalysed product of adenine. Further studies indicated that it was unlikely that a major part of the immunosuppressive activity of adenine was due to the renal toxicity exerted by this compound. Splenic PRPP levels were found to peak on day 4 after antigen administration (day 0) and this corresponded with the peak in antibody plaque response which occurred at day 4 to 5. Adenine given at an immunosuppressive dose of 25 mumoles/mouse on day 0, 1 resulted in a significant inhibition of splenic PRPP levels on day 2 of the response. This effect on splenic PRPP levels on day 2 was also found with hypoxanthine given at an immune enhancing dose and therefore would indicate that depression of splenic PRPP per se is not responsible for the immunosuppression. Adenosine given at immunosuppressive doses was found not to affect PRPP levels in the spleen and hepatic PRPP levels were unaffected by adenine, adenosine and hypoxanthine. The in vivo effects of adenine on hypoxanthine-guanine phosphoribosyltransferase showed that adenine could inhibit significantly this salvage pathway in spleen and liver and that this inhibition could be overcome with concomitant administration of allopurinol. A metabolite of adenine which could contribute to its immunosuppressive activity may be 2-hydroxyadenine since it is derived from the xanthine oxidase catalysed oxidation of adenine inhibited hypoxanthine-guanine phosphoribosyltransferase gave similar renal toxicity to adenine and was immunosuppressive.
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PMID:Studies on the mechanism of immunosuppression with adenine. 241 71

Effects of xanthine (2 mM) and xanthine oxidase (10 U/L) perfusion on myocardial function, lipid peroxide content, high-energy phosphates and their metabolites, and ultrastructure were examined in isolated perfused rat hearts to define the time course of myocardial injury due to exogenous supply of active oxygen species. Peak-developed force and dF/dt showed a decline within 5 min and complete contractile failure was seen at 20 min. Resting tension was higher at 10 min and reached a maximum value of 400% at 40 min. These changes in contractile parameters were reduced by superoxide dismutase (1.2 x 10(5) U/L), catalase (2 and 4 X 10(4) U/L), and mannitol (10 and 20 mM). Lipid peroxide content was significantly higher at 5 min and rose continuously with xanthine-xanthine oxidase (X-XO) perfusion. A close correlation was noted (r = 0.935) between increased lipid peroxide content and a decrease in peak-developed force. Creatine phosphate and adenosine triphosphate (ATP) showed a time-dependent decrease due to X-XO perfusion. Loss of ATP also correlated (r = 0.819) with the contractile failure. Adenosine diphosphate showed an increase at 5 min followed by a decrease at 20 and 40 min. Adenosine monophosphate, adenosine, and creatine content increased with X-XO perfusion. In a semiquantitative morphometric study, significant myocardial and vascular changes became apparent only after 10 min of X-XO perfusion. When a 5-min perfusion with X-XO was followed by a control perfusion, a recovery of developed force and normal structure was noted at 40 min. These data show that X-XO induced contractile failure involves partially reduced forms of oxygen such as superoxide, hydroxyl radicals, and hydrogen peroxide. The negative inotropic effect of a vascular supply of these active oxygen species may be related to increased lipid peroxidation as well as the loss of high-energy phosphates. Structural damage to myocytes and blood vessels and a rise in resting tension were delayed events requiring a continuous and longer exposure to radical species.
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PMID:Time course of structure, function, and metabolic changes due to an exogenous source of oxygen metabolites in rat heart. 262 93

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