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)

Incubation of rat brain synaptosomes with xanthine and xanthine oxidase (X/XO) resulted in an inhibition of gamma-aminobutyric acid (GABA) uptake. The inhibitory effects of X/XO were temperature- and time-dependent, and were characterized by an increased Km for GABA and a decreased Vmax. Inhibition of GABA uptake by X/XO was associated with both the formation of malonyldialdehyde (MDA) and conjugated dienes, indicating that lipid peroxidation was involved. Studies with catalase, superoxide dismutase (SOD), mannitol, and chelated iron suggested that hydroxyl radical (OH X) was probably responsible for the initiation of lipid peroxidation. Both the peroxidation of synaptosomal membranes and the inhibition of GABA uptake by X/XO were enhanced by the addition of ADP and FeCl2. The X/XO-induced inhibition of GABA uptake by synaptosomes could be prevented by preincubation of synaptosomes with certain glucocorticoids prior to X/XO exposure. Methylprednisolone sodium succinate (MPSS), dexamethasone sodium phosphate (DMSP), and prednisolone sodium succinate (PSS) all prevented the inhibition of GABA uptake by X/XO. MPSS was most effective at concentrations around 100 microM, DMSP was slightly more potent, and PSS was optimal at around 300 microM. On the other hand, hydrocortisone sodium succinate (HCSS) was ineffective at preventing X/XO-induced inhibition of GABA uptake at concentrations up to 3 mM. The steroids are presumed to work through a mechanism that blocked the formation of lipid peroxides, as MPSS inhibited the formation of conjugated dienes in synaptosomes exposed to X/XO at a concentration that also protected GABA uptake.
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PMID:Lipid peroxidation-induced inhibition of gamma-aminobutyric acid uptake in rat brain synaptosomes: protection by glucocorticoids. 388 88

The morphological, biochemical and functional characterization of the vascular endothelium has become possible through the broad use of electron microscopic methods, the successful elaboration and application of techniques for the isolation and cultivation of endothelial cells in vitro and through sophisticated studies on vessel and organ preparations, both in vitro and in vivo. In this survey emphasis is placed on certain methodological aspects of endothelial cell culture as well as on biochemical, physiological and pathophysiological features of the vascular endothelium. Endothelial cells can be propagated in culture dishes, the most commonly applied method, on suspended microbeads (dextrane, polyacrylamide), a technique giving large yields, or on thin porous membranes, a procedure suited for the study of transport processes across the endothelial layer. Different structural, biochemical and functional properties of the luminal (apical) and abluminal (basal) cell membrane determine important polarity features of the endothelium. Endothelial cells exhibit a variety of biochemical pathways and are characterized by high metabolic activities. Of particular interest is the large content of ATP in endothelial cells of different vascular origin. The rapid intracellular degradation of adenine nucleotides to nucleosides and bases, which are constantly released, is balanced by synthesis, mainly via salvage pathways. In endothelial cells of microvascular origin uric acid predominates by far as the final purine degradative because of the presence of xanthine dehydrogenase in these cells; in the macrovascular endothelium purine breakdown proceeds only to hypoxanthine, since xanthine dehydrogenase is lacking. In this connection interrelations between nucleotide catabolism in myocardial tissue and in coronary endothelial cells are discussed, also with respect to the participation of endothelial xanthine oxidase in the formation of oxygen radicals during post-ischemic reperfusion of the heart. Vascular endothelial cells of different origin are also capable of a rapid extracellular degradation of ATP, ADP and AMP to adenosine by means of specific ecto-nucleotidases. The subsequent fate of extracellularly formed adenosine appears to be different for endothelial cells of microvascular (preferential adenosine uptake) and macrovascular origin (preferential extracellular adenosine accumulation), thus implying functional consequences for platelet aggregation.(ABSTRACT TRUNCATED AT 400 WORDS)
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PMID:The vascular endothelium: a survey of some newly evolving biochemical and physiological features. 393 1

Doxorubicin semiquinone, produced by reduction of doxorubicin with xanthine oxidase or ferredoxin reductase, reacted with H2O2 to cause deoxyribose oxidation that was catalysed by sub-micromolar concentrations of complexed iron. Both the mechanism of deoxyribose oxidation and the yield of oxidation products depended on the chelator. With EDTA or diethylenetriamine penta-acetic acid (DTPA), the reactive species behaved like free . OH. However, when ADP or no chelator was present, oxidation of deoxyribose was inhibited by mannitol but not benzoate or formate and was apparently not due to free . OH. Doxorubicin semiquinone and H2O2 caused peroxidation of phospholipid liposomes when ADP or no chelator was present, but not in the presence of EDTA or DTPA. Lipid peroxidation was iron dependent over a 0.1 to 1 microM range and was maximal with a pO2 of approximately 1.5 mm Hg, when the inhibitory effect of O2 on initiation is balanced by its stimulatory effects on propagation. The results imply that H2O2 and the doxorubicin semiquinone at low iron and O2 concentrations are very effective at initiating lipid peroxidation.
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PMID:Doxorubicin-dependent lipid peroxidation at low partial pressures of O2. 393 36

Hemeproteins promote lipid hydroperoxide-dependent lipid peroxidation in vitro. Only recently have studies demonstrated that certain hemeproteins peroxidize lipids in a lipid-hydroperoxide-independent manner. To understand fully the interaction between reactive oxygen metabolites, myoglobin and lipid, we investigate the possibility that myoglobin may use xanthine oxidase-generated superoxide and/or hydrogen peroxide to catalyze peroxidation of a polyunsaturated fatty acid. Our studies demonstrate that myoglobin, in the presence of hypoxanthine and xanthine oxidase, catalyze the peroxidation of arachidonic acid. Oxy (ferrous) myoglobin appears to be the most effective catalyst for arachidonic acid peroxidation when compared to metmyglobin, hemoglobin, or ADP-iron chelates. Inhibition studies reveal that myoglobin uses hydrogen peroxide, not superoxide to form either an oxo-heme-oxidant or caged radical that initiates arachidonate peroxidation. The reactivity of this oxidant is similar to that of ferryl iron or hydroxyl free radical. Our results suggest that this reaction may be important in myocardial reperfusion injury since reoxygenation of ischemic myocardium results in a burst of xanthine oxidase-generated superoxide and hydrogen peroxide in proximity to cellular myoglobin.
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PMID:Myoglobin-catalyzed hydrogen peroxide dependent arachidonic acid peroxidation. 393 40

Seminal plasma antioxidant inhibited ascorbate/iron-induced lipid peroxidation in spermatozoa, brain and liver mitochondria. The concentration required to produce inhibition in brain and liver mitochondria was high. Denaturation of spermatozoa resulted in complete loss of antioxidant action. Maintenance of native structure was essential for action of seminal plasma antioxidant in spermatozoal lipid peroxidation. The antioxidant inhibited NADPH, Fe3+-ADP induced lipid peroxidation in microsomes and consequences of lipid peroxidation such as glucose-6-phosphatase inactivation were prevented by presence of antioxidant. It did not inhibit microsomal lipid peroxidation induced by ascorbate and iron and xanthine-xanthine oxidase.
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PMID:Effect of seminal plasma antioxidant on lipid peroxidation in spermatozoa, mitochondria and microsomes. 406 52

Regional intestinal ischemia in cats resulted in an accumulation of hypoxanthine within 2 h, the concentration of which rose from 0.062 to 1.131 nmol/mg protein. A similar rise in AMP content (from 0.5 to 3.2 nmol/mg protein) was observed, but not in the ADP level. In parallel, ATP content decreased from 7.5 to 2.8 nmol/mg protein. Reperfusion of the ischemic tissue was followed by rapid metabolism of the purine metabolites; after 1 h of reperfusion the tissue level of hypoxanthine was 0.186 nmol/mg protein, of AMP 0.7 nmol/mg protein, and of ATP 4.3 nmol/mg protein. The oxidation of hypoxanthine, mediated by xanthine oxidase, is accompanied by the release of superoxide ions. Consequently, the concentration of oxidized glutathione was doubled upon reperfusion, while marked lipid peroxidation took place, as evidenced by the rise in conjugated diene content from 2.8 mumol/g tissue before reperfusion to 5.6 mumol/g tissue after 10 min of reoxygenation. In line with these findings is the fact that histologically observable damage occurred mainly in the presence of oxygen. These data indicate that, at least in our model, rapid reoxygenation is a major cause of "ischemic" tissue damage.
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PMID:Oxidative tissue damage following regional intestinal ischemia and reperfusion in the cat. 609 11

Rat liver microsomal NADPH-dependent lipid peroxidation and xanthine oxidase-promoted lipid peroxidation were reviewed and compared to see if a unified mechanism is involved in each system. These systems were also compared to hydroxyl radical-dependent lipid peroxidation in order to determine the physiological significance of the different mechanisms of lipid peroxidation. Fenton's reagent very readily promotes lipid peroxidation, which is inhibited by catalase and hydroxyl radical traps but not by superoxide dismutase. However, the addition of ADP to Fenton's reagent results in a type of lipid peroxidation that is not inhibited by hydroxyl radical traps and the amount of hydroxyl radical spin trap adducts formed is much less. Xanthine oxidase-promoted lipid peroxidation is not inhibited by catalase and is greatly stimulated by ADP. Microsomal NADPH-dependent lipid peroxidation is also dramatically stimulated by ADP in Tris buffer but not in phosphate buffer. Hydroxyl radical traps are without effect in both microsomes and xanthine oxidase-promoted lipid peroxidation. These results suggest several in vitro mechanisms for the initiation of lipid peroxidation but do not support the hydroxyl radical for a role in physiological lipid peroxidation.
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PMID:Superoxide dependent lipid peroxidation. 625 57

Superoxide (.O-2) is demonstrated to participate at the prostaglandin phase swelling (2-4 h) of carrageenan paw edema. Superoxide production is inhibited in vitro by typical anti-inflammatory drugs, but these drugs did not scavenge superoxide which was produced by xanthine oxidase. Phosphate, pyrophosphate, ATP, ADP and sulfate were essential for superoxide production by macrophages. These anions can induce paw swelling and are reported to increase in rheumatic patients. A mixture of macrophages and lymphocytes from BCG sensitized guinea-pigs was cultured for 2 days with SOD or D-mannitol. Nitroblue tetrazolium reduction (formazan formation) was inhibited by these agents, suggesting that the hydroxyl radical (.OH) is necessary for metabolic activation of macrophage. Lympholine-like factor of which production or release is enhanced by hydroxyl radical, activates macrophage. Production of oxygen radicals may increase rapidly by this chain cycle reaction. Possible relations of oxygen radicals to prostaglandin(s) biosyntheses, chemotaxis, lysosomal enzyme release protease participation, were discussed. Endogenous SOD, epinephrine, ceruloplasmin, blood plasma proteins, inflammatory fluid, may modulate the amount of superoxide by their superoxide scavenging capacities.
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PMID:Inflammation and superoxide production by macrophages. 626 69

Superoxide generation, assessed as the rate of acetylated cytochrome c reduction inhibited by superoxide dismutase, by purified NADPH cytochrome P-450 reductase or intact rat liver microsomes was found to account for only a small fraction of their respective NADPH oxidase activities. DTPA-Fe3+ and EDTA-FE3+ greatly stimulated NADPH oxidation, acetylated cytochrome c reduction, and O(2) production by the reductase and intact microsomes. In contrast, all ferric chelates tested caused modest inhibition of acetylated cytochrome c reduction and O(2) generation by xanthine oxidase. Although both EDTA-Fe3+ and DTPA-Fe3+ were directly reduced by the reductase under anaerobic conditions, ADP-Fe3+ was not reduced by the reductase under aerobic or anaerobic conditions. Desferrioxamine-Fe3+ was unique among the chelates tested in that it was a relatively inert iron chelate in these assays, having only minor effects on NADPH oxidation and/or O(2) generation by the purified reductase, intact microsomes, or xanthine oxidase. Desferrioxamine inhibited microsomal lipid peroxidation promoted by ADP-Fe3+ in a concentration-dependent fashion, with complete inhibition occurring at a concentration equal to that of exogenously added ferric iron. The participation of O(2) generated by the reductase in NADPH-dependent lipid peroxidation was also investigated and compared with results obtained with a xanthine oxidase-dependent lipid peroxidation system. NADPH-dependent peroxidation of either phospholipid liposomes or rat liver microsomes in the presence of ADP-Fe3+ was demonstrated to be independent of O(2) generation by the reductase.
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PMID:Superoxide generation by NADPH-cytochrome P-450 reductase: the effect of iron chelators and the role of superoxide in microsomal lipid peroxidation. 633 20

Uninduced rat liver microsomes and NADPH-Cytochrome P-450 reductase, purified from phenobarbital-treated rats, catalyzed an NADPH-dependent oxidation of hydroxyl radical scavenging agents. This oxidation was not stimulated by the addition of ferric ammonium sulfate, ferric citrate, or ferric-adenine nucleotide (AMP, ADP, ATP) chelates. Striking stimulation was observed when ferric-EDTA or ferric-diethylenetriamine pentaacetic acid (DTPA) was added. The iron-EDTA and iron-DTPA chelates, but not unchelated iron, iron-citrate or iron-nucleotide chelates, stimulated the oxidation of NADPH by the reductase in the absence as well as in the presence of phenobarbital-inducible cytochrome P-450. Thus, the iron chelates which promoted NADPH oxidation by the reductase were the only chelates which stimulated oxidation of hydroxyl radical scavengers by reductase and microsomes. The oxidation of aminopyrine, a typical drug substrate, was slightly stimulated by the addition of iron-EDTA or iron-DTPA to the microsomes. Catalase inhibited potently the oxidation of scavengers under all conditions, suggesting that H2O2 was the precursor of the hydroxyl radical in these systems. Very high amounts of superoxide dismutase had little effect on the iron-EDTA-stimulated rate of scavenger oxidation, whereas the iron-DTPA-stimulated rate was inhibited by 30 or 50% in microsomes or reductase, respectively. This suggests that the iron-EDTA and iron-DTPA chelates can be reduced directly by the reductase to the ferrous chelates, which subsequently interact with H2O2 in a Fenton-type reaction. Results with the reductase and microsomal systems should be contrasted with results found when the oxidation of hypoxanthine by xanthine oxidase was utilized to catalyze the production of hydroxyl radicals. In the xanthine oxidase system, ferric-ATP and -DTPA stimulated oxidation of scavengers by six- to eightfold, while ferric-EDTA stimulated 25-fold. Ferric-desferrioxamine consistently was inhibitory. Superoxide dismutase produced 79 to 86% inhibition in the absence or presence of iron, indicating an iron-catalyzed Haber-Weiss-type of reaction was responsible for oxidation of scavengers by the xanthine oxidase system. These results indicate that the ability of iron to promote hydroxyl radical production and the role that superoxide plays as a reductant of iron depends on the nature of the system as well as the chelating agent employed.
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PMID:The role of iron chelates in hydroxyl radical production by rat liver microsomes, NADPH-cytochrome P-450 reductase and xanthine oxidase. 633 21


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