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

Exposure of red blood cells to oxygen radicals can induce hemoglobin damage and stimulate protein degradation, lipid peroxidation, and hemolysis. To determine if these events are linked, rabbit erythrocytes were incubated at 37 degrees C with various oxygen radical-generating systems and antioxidants. Protein degradation, measured by the production of free alanine, increased more than 11-fold in response to xanthine (X) + xanthine oxidase (XO). A similar increase in proteolysis occurred when the cells were incubated with acetaldehyde plus XO, with ascorbic acid plus iron (Asc + Fe), or with hydrogen peroxide (H2O2) alone. Upon addition of XO, increased proteolysis was evident within 5 min and was linear for up to 5 h. In contrast, lipid peroxidation, as shown by the production of malonyldialdehyde, conjugated dienes, or lipid hydroperoxides was observed only after 2 h of incubation with X + XO, acetaldehyde + XO, or H2O2. Ascorbate plus Fe2+ induced both protein degradation and lipid peroxidation; however, the addition of various antioxidants (urate, xanthine, glucose, or butylated hydroxytoluene) decreased lipid peroxidation without affecting proteolysis. Thus, these processes seem to occur by distinct mechanisms. Furthermore, at low concentrations of XO, protein degradation was clearly increased in the absence of detectable lipid peroxidation products. Hemolysis occurred only in a small number of cells (9%) and followed the appearance of lipid peroxidation products. Thus, an important response of red cells to oxygen radicals is rapid degradation of damaged cell proteins. Increased proteolysis seems to occur independently of membrane damage and to be a more sensitive indicator of cell exposure to oxygen radicals than is lipid peroxidation.
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PMID:Oxygen radicals stimulate intracellular proteolysis and lipid peroxidation by independent mechanisms in erythrocytes. 359 72

We have suggested that red blood cell proteolytic systems can degrade oxidatively damaged proteins, and that both damage and degradation are independent of lipid peroxidation (Davies, K. J. A., and Goldberg, A. L. (1987) J. Biol. Chem. 262, 8220-8226. These ideas have now been tested in cell-free extracts of rabbit erythrocytes and reticulocytes. Exposure to oxygen radicals or H2O2 increases the degradation of endogenous proteins in cell-free extracts, as in intact cells. Various radical-generating systems (acetaldehyde or xanthine + xanthine oxidase, ascorbic acid + iron, H2O2 + iron) and H2O2 alone enhanced the rates of proteolysis severalfold. Since these extracts were free of membrane lipids, protein damage and degradation must be independent of lipid peroxidation. An antioxidant buffer consisting of HEPES, glycerol, and dithiothreitol inhibited the increased proteolysis by 60-100%. Mannitol caused a 50-80% reduction in proteolysis suggesting that the hydroxyl radical (.OH), or a species with similar reactivity, may be the initiator of protein damage. When casein or bovine serum albumin were exposed to .OH (generated by H2O2 + Fe2+, or COCo radiation) these proteins were degraded up to 50 times faster than untreated proteins during subsequent incubations with red cell extracts. Mannitol inhibited this increase in proteolysis only if present during .OH exposure; mannitol did not affect the degradative system. Although ATP increased the degradation of untreated proteins 4- to 6-fold in reticulocyte extracts, it had little or no effect on the degradation of proteins exposed to .OH. ATP also did not stimulate hydrolysis of .OH-treated proteins in erythrocyte extracts. Leupeptin did not affect the degradative processes in either extract; thus lysosomal or Ca2+-activated thiol proteases were not involved. We propose that red cells contain a soluble, ATP-independent proteolytic pathway which may protect against the accumulation of proteins damaged by .OH or other active oxygen species.
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PMID:Proteins damaged by oxygen radicals are rapidly degraded in extracts of red blood cells. 359 73

Using isolated hemoglobin-free perfused rat livers we investigated the hepatotoxic effects of hypoxia, ethanol or the combination of both. Hypoxia only (90 min) led to a weak toxicity as evidenced by the efflux of the enzymes glutamate-pyruvate-transaminase (GPT) and sorbitol dehydrogenase (SDH). This toxic effect was slightly higher in livers treated with ethanol (3 g/l) under normoxic conditions. Ethanol added under hypoxic conditions, however, showed a strong hepatotoxic effect. Under hypoxic conditions, lactate + pyruvate production was increased fivefold over control, indicating that glycolysis was more effectively undergone as main source of energy. Addition of ethanol suppressed this effect, indicating that ethanol inhibited glycolysis. These results indicate that ethanol potentiates hypoxic liver damage by inhibiting the main metabolic pathway yielding ATP under low oxygen tension resulting in a severe energy deficit. Allopurinol (100 mg/l) inhibited the toxic effects seen with ethanol + hypoxia. Also, the inhibitory action of ethanol on glycolysis was antagonized. Our results are consistent with the following model: hypoxia converts NAD-dependent xanthine dehydrogenase (XD) into the oxygen-dependent xanthine oxidase (XO). Due to hypoxia and ethanol, purine metabolites and acetaldehyde accumulate and are metabolized via XO. This process leads to the production of oxygen radicals which most probably mediate both the inhibition of glycolysis and the direct toxic effects towards liver cells.
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PMID:Enhancement of hypoxic liver damage by ethanol. Involvement of xanthine oxidase and the role of glycolysis. 363 22

Previous reports indicate that allopurinol, a xanthine oxidase inhibitor, largely prevents the injury produced by reperfusion of ischemic tissues. In order to further assess the role of xanthine oxidase in ischemia-reperfusion injury, we examined the influence of another inhibitor of the enzyme (pterin aldehyde) on the increased vascular permeability produced by intestinal ischemia. Vascular permeability estimates in autoperfused segments of cat ileum were derived from the relationship between lymph-to-plasma protein concentration ratio and lymph flow. One hour of intestinal ischemia increased vascular permeability to 0.43 +/- 0.02 from a control (nonischemic) value of 0.08 +/- 0.005. In ischemic ileal segments pretreated with purified pterin aldehyde, vascular permeability increased to only 0.15 +/- 0.02. Pretreatment with commercially prepared folic acid, which is contaminated with pterin aldehyde, also attenuated the ischemia-induced increase in vascular permeability (0.16 +/- 0.04). These findings support the hypothesis that xanthine oxidase is a major source of oxygen-free radicals produced during reperfusion of the ischemic small bowel.
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PMID:Xanthine oxidase inhibitors attenuate ischemia-induced vascular permeability changes in the cat intestine. 375 55

Single doses of ethanol (5 g/kg, intragastric) produce oxidative stress in the liver as well as in the heart. The metabolism of acetaldehyde through xanthine oxidase appears to play an important role in the production of oxidative stress in the heart, but it has only a contributory role in the liver. It is suggested that, as oxidative stress through lipid peroxidation may produce organ pathology, the metabolic pathway of acetaldehyde through xanthine oxidase may be one of the mechanisms which mediate cardiac pathology in alcoholism.
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PMID:Role of acetaldehyde and xanthine oxidase in ethanol-induced oxidative stress. 375 47

Isoelectric focusing (IEF) and cellulose acetate electrophoresis were used to examine the multiplicity and distribution of aldehyde dehydrogenases (ALDHs), aldehyde oxidase (AOX) and xanthine oxidase (XOX) from tissues of olive and yellow baboons. Five ALDHs were resolved and distinguished on the basis of their differential tissue and subcellular distribution or substrate specificity. Some ALDHs exhibited multiple activity zones. Baboon liver ALDHs were differentially distributed in cytosol (ALDHs II, III and V) and large granular (mitochondrial) fractions (ALDHs I and IV). The major liver ALDHs (I and II) were also broadly distributed in other tissues, as was the major stomach enzyme (ALDH-III). Three brain ALDHs were resolved, which were also differentially distributed between large granular (mitochondrial) (ALDHs I and IV) and cytosolic (ALDH-III) fractions. Electrophoretic variability between individuals was observed for the major liver mitochondrial isozyme (ALDH-I), the major stomach isozyme (ALDH-III) and the minor liver isozymes (ALDHs IV and V). Single forms of AOX and XOX were found in baboon tissue extracts, with the highest activities in liver (AOX) and intestine extracts (XOX). Both oxidases were predominantly localized in the liver soluble fraction.
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PMID:Aldehyde dehydrogenases, aldehyde oxidase and xanthine oxidase from baboon tissues: phenotypic variability and subcellular distribution in liver and brain. 375 5

The stabilized carbonium ion salt, tropylium tetrafluoroborate, was oxidized to tropone (cycloheptatrienone) by rabbit liver aldehyde oxidase but not by the closely related molybdenum hydroxylase, xanthine oxidase. The tropylium cation is an aromatic hydrocarbon which lacks the aldehyde, imine, or iminium functional groups present in other substrates of aldehyde oxidase. The unique structural features of the tropylium ion should make it a useful tool for mechanistic studies of aldehyde oxidase.
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PMID:Tropylium tetrafluoroborate, a novel substrate for aldehyde oxidase. 377 70

The parameters of enzyme electrodes based on organic metals are presented. Cytochrome b2 (E.C. 1.1.2.3), glucose oxidase (E.C. 1.1.3.4), xanthine oxidase (E.C. 1.2.3.2) and peroxidase (E.C. 1.11.1.7) were used in electrodes sensitive to L-lactate, glucose, hypoxanthine and hydrogen peroxide. Electrocatalytic oxidation of NADH on organic metals and ethanol and acetaldehyde sensitive electrodes containing alcohol dehydrogenase (E.C. 1.1.1.1) were studied. Biocatalytic charge accumulation, the mechanism of electron exchange between the enzyme active centres and organic metals, and the future application of organic metals are discussed.
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PMID:Enzyme electrodes based on organic metals. 379 Jan 76

The oxygen consumption of cerebral arterioles from anesthetized cats was measured using the Cartesian diver microrespirometer following in vitro incubation with 200 micrograms/ml of arachidonate or 50 micrograms/ml of 15-hydroperoxy-eicosatetraenoic acid (15-HPETE). Both agents depressed oxygen consumption severely. This effect was inhibited completely by a combination of superoxide dismutase (SOD) and catalase, indicating that it is mediated by oxygen radicals. Similar depression of oxygen consumption was observed during incubation of the vessels with xanthine oxidase and acetaldehyde as substrate. This enzymic system is known to generate superoxide and hydrogen peroxide. The effect of xanthine oxidase was also partially inhibited by SOD and catalase. The effect of arachidonate was partially inhibited by cyclooxygenase inhibitors. The effect of lipoxygenase inhibitors could not be adequately tested because they depressed oxygen consumption by themselves. Prostaglandins H2 and E2 had no effect on arteriolar oxygen consumption. The results show that arachidonate and 15-HPETE in high concentration depress cerebral arteriolar oxygen consumption via an oxygen radical-mediated mechanism. Furthermore, the radical is generated in the vessel wall and does not require either the brain parenchyma or the formed elements of the blood or the meninges for its production.
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PMID:Reduction in cerebral arteriolar oxygen consumption by arachidonate. 392 Sep 21

Isoelectric focusing techniques (IEF) were used to examine the tissue distribution and genetic variability of aldehyde dehydrogenases (AHDs) from inbred strains of mice. Twelve zones of AHD activity were resolved which were differentially distributed between tissues. Liver extracts exhibited highest activity for most enzymes, with the exception of isozymes found in stomach (AHD-4) and testis (AHD-4 and AHD-6). Genetic variants for AHD-1 (liver mitochondrial isozyme) and AHD-4 (stomach isozyme) were examined from inbred strains and F1 hybrid animals. The results were consistent with dimeric subunit structures (designated as A2 and D2 isozymes respectively). IEF patterns for activity variants of testis-specific AHD-6 were identical, with 3-banded phenotypes being observed. pI values for the AHD forms as well as for aldehyde oxidase and xanthine oxidase isozymes, which stain in the absence of coenzyme, were reported.
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PMID:Isoelectric focusing studies of aldehyde dehydrogenases from mouse tissues: variant phenotypes of liver, stomach and testis isozymes. 404 Aug 41


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