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:P04040 (Catalase)
3,577 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The effect of oxygen derived free radicals (ODFR) upon the specific viscosity of equine synovial fluid was studied. ODFR were generated either by a mixture of ferrous iron and EDTA (Fe/EDTA) or by a mixture of hypoxanthine and xanthine oxidase (HX/XO). Incubation of the synovial fluid with both free radical generating systems decreased its specific viscosity. When the synovial fluid was incubated with Fe/EDTA the specific viscosity of the synovial fluid was reduced rapidly. By 2 mins, it was 53 +/- 3 per cent of the original specific viscosity and by 30 mins it was reduced to 39 +/- 5 per cent. In the HX/XO system, the specific viscosity was 75 +/- 4 per cent of the original specific viscosity at 10 mins and by 50 mins it was reduced to 55 +/- 3 per cent. Palosein (superoxide dismutase) was an effective inhibitor of the free radical induced reduction of the viscosity of the synovial fluid when the free radicals were generated with HX/XO but not with Fe/EDTA. Catalase was moderately effective as an inhibitor of reduction in specific viscosity of the synovial fluid when the free radicals were generated by either system. Only minor synergy resulted when mixtures of Palosein and catalase were tested for inhibition of Fe/EDTA induced reduction in the specific viscosity of equine synovial fluid. The results indicate that Palosein may protect equine synovial fluid from the effects of the superoxide radical (O2-) but not from the hydroxyl radical (OH.).(ABSTRACT TRUNCATED AT 250 WORDS)
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PMID:Effect of palosein (superoxide dismutase) and catalase upon oxygen derived free radical induced degradation of equine synovial fluid. 229 85

The effects of cell-free generated oxidants on migrating and developing stages of Schistosoma mansoni were investigated and the levels of antioxidant enzymes and of glutathione were determined for each stage. Schistosomula and 2-week-old parasites recovered from the livers of infected mice showed similar susceptibility to killing by added hydrogen peroxide and t-butylhydroperoxide. However, when glucose (0.5 mM)-glucose oxidase (2.5 mU ml-1) and xanthine (0.5 mM) or hypoxanthine (0.5 mM)-xanthine oxidase (5.0 mU ml-1) systems were used to generate hydrogen peroxide and oxygen free-radicals, schistosomula were more susceptible to oxidative killing than the 2-week-old parasites. The 4- and 8-week-old worms were more resistant to oxidants than all of the younger stages. High levels of superoxide dismutase (16.2-24.8 U mg-1 protein) were present in all stages. Catalase was not detected. Glutathione peroxidase activity with cumene hydroperoxide as substrate was not detectable in the schistosomula but the activity was present in the 2-week-old parasites. However, hydrogen peroxide-sensitive glutathione peroxidase activity was present in all the stages with a threefold difference in activity between schistosomula and the adult stages. Glutathione-s-transferase activity was significantly lower in the schistosomula, lung stages, and the 2-week-old parasites than in the older stages. Progressive increases in the levels of glutathione reductase and glutathione were also observed with development. The differences in the levels of antioxidants between different stages of development may partly explain the increase in resistance to oxidant-mediated damage as the parasite develops.
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PMID:Schistosoma mansoni: levels of antioxidants and resistance to oxidants increase during development. 232 92

Pulmonary hypoperfusion/ischemia-reperfusion (I/R) may initiate ARDS (nonhydrostatic pulmonary edema). Endothelial damage via xanthine oxidase (XO)-derived oxygen radicals (O2*) may mediate I/R injury. We previously documented Factor VIII antigen (F8) as a marker for endothelial injury. The purpose of this study was to (1) document I/R-induced nonhydrostatic pulmonary edema, (2) identify whether XO or O2* mediates nonhydrostatic edema, and (3) identify the site of injury (? endothelium). Rat lungs were isolated, ventilated, and perfused (100 min, control, or 40 min at 37 degrees C, I (static vent.), + 60 min, R). Effluent was analyzed for F8 release (ELISA: data relative to control). Tungsten-fed rats had negligible lung XO vs rats fed standard diet (3.6 vs 34.5 mU/g, (P less than 0.05). Catalase (CAT) 50 micrograms/ml) was added to perfusate prior to R. Sectioned lungs were fluorescein anti-F8 photographed (IF) and qualitatively assessed. (Table: see text). We conclude that (1) pulmonary hypoperfusion (I/R) leads to nonhydrostatic pulmonary edema, and (2) the edema results in part from XO-generated O2* directed at the capillary endothelium.
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PMID:Xanthine oxidase-derived oxygen radicals induce pulmonary edema via direct endothelial cell injury. 249 87

We previously found that the small cell fraction of isolated cells from canine gastric mucosa is a major producer of prostaglandin E2 (PGE2) and identified macrophages as the predominant cellular source. Prostaglandin-H synthase activity is dependent on the continuous presence of hydroperoxides. Because reactive oxygen metabolites may mediate mucosal injury in inflammatory or ischemic disease, we studied the release of PGE2 by isolated gastric cells during exposure to an oxygen metabolite-generating system, xanthine and xanthine oxidase. We found a concentration-dependent relationship between xanthine oxidase concentration and PGE2 production without cell lysis. The maximum PGE2 production stimulated by oxidants was equivalent to the maximum PGE2 response to bradykinin and A23187. The chief and parietal cell fractions produced very little PGE2 with xanthine oxidase concentrations that stimulated maximal PGE2 production in the small cell fraction. Uric acid did not stimulate PGE2 production. Catalase completely inhibited the response, while superoxide dismutase had a partial inhibitory effect. Hydrogen peroxide stimulated concentration-dependent PGE2 production with an ED50 of approximately 5 microM. We concluded that reactive oxygen metabolites stimulate PGE2 production by the small cell fraction of gastric mucosa.
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PMID:Oxygen metabolites modulate prostaglandin E2 production by isolated gastric mucosal cells. 249 50

Toxic oxygen metabolites (TOM) released from stimulated phagocytes and lung tissue have been shown to injure the pulmonary microcirculation. In the present study we evaluated microvascular injury caused by TOM in rat lungs perfused with plasma. The injury, as indicated by an increase in vascular permeability, was assessed by determining the fluid filtration rate (FFR) after paralysing the pulmonary vascular bed with papaverine (0.1 mg/ml). TOM were generated by adding xanthine oxidase (XO) (0.05-0.125 U/ml) and hypoxanthine (HX) (1 mmol/l) to the perfusate. FFR was measured before, 30 and 60 min after addition of XO and HX. The following interventions were done: 1. the H2O2-scavenger catalase, 2. substitution of the perfusate after 30 min, 3. BW 755 C, a combined lipoxygenase and cyclooxygenase inhibitor, and 4. indomethacin, a cyclooxygenase inhibitor. Addition of XO and HX caused FFR to increase from 14 +/- 4 mg/min (mean +/- s.e. mean) at the onset to 56 +/- 7 mg/min and 86 +/- 10 mg/min after 30 and 60 min, respectively. Replacing the perfusate with fresh plasma after 30 min caused a significant reduction in FFR at 60 min, from 86 +/- 11 mg/min to 58 +/- 10 mg/min. Catalase prevented the increase in FFR. Indomethacin and BW 755 C had no effect on the increase in FFR. We conclude that TOM induced a partly reversible increase in microvascular permeability of isolated rat lungs. From previous studies, the activity of XO was expected to cease after 30 min. Therefore it is suggested that secondary products of TOM propagate the lung injury. The increase in permeability was not mediated by arachidonic acid metabolites.
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PMID:Increased microvascular permeability caused by toxic oxygen metabolites is partly reversed by exchanging the perfusate in isolated rat lungs. 251 Apr 45

Vanadium compounds are known to stimulate the oxidation of NAD(P)H, but the mechanism remains unclear. This reaction was studied spectrophotometrically and by electron spin resonance spectroscopy (ESR) using vanadium in the reduced state (+4, vanadyl) and the oxidized state (+5, vanadate). In 25 mM sodium phosphate buffer at pH 7.4, vanadyl was slightly more effective in stimulating NADH oxidation than was vanadate. Addition of a superoxide generating system, xanthine/xanthine oxidase, resulted in a marked increase in NADH oxidation by vanadyl, and to a lesser extent, by vanadate. Decreasing the pH with superoxide present increased NADH oxidation for both vanadate and vanadyl. Addition of hydrogen peroxide to the reaction mixture did not change the NADH oxidation by vanadate, regardless of concentration or pH. With vanadyl however, addition of hydrogen peroxide greatly enhanced NADH oxidation which further increased with lower pH. Use of the spin trap DMPO in reaction mixtures containing vanadyl and hydrogen peroxide or a superoxide generating system resulted in the detection by ESR of hydroxyl. In each case, the hydroxyl radical signal intensity increased with vanadium concentration. Catalase was able to inhibit the formation of the DMPO--OH adduct formed by vanadate plus superoxide. These results show that the ability of vanadium to act in a Fenton-type reaction is an important process in the vanadium-stimulated oxidation of NADH.
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PMID:Importance of hydroxyl radical in the vanadium-stimulated oxidation of NADH. 253 40

The effect of oxidant stress on the active transport of serotonin (5-HT) into mouse platelets was examined. Oxidant stress was produced using either H2O2 or the xanthine-xanthine oxidase generating system that yields both superoxide anion and H2O2. H2O2 (6.25-100 microM) caused a rapid (2-4 min) stimulation of platelet 5-HT transport that returned to control levels after 15 min of incubation. Catalase (1500 U/ml) completely prevented the stimulation, and the hydroxyl radical trapping agents mannitol (1 nM) and thiourea (1 mM) failed to alter the stimulation. Fluoxetine (1 microM) totally blocked all 5-HT uptake into stimulated platelets. The xanthine-xanthine oxidase (3.12-25 mU/ml) generating system produced a response similar to that of H2O2. In this system, superoxide dismutase (250 U/ml) did not alter the stimulatory response, whereas catalase (1500 U/ml) totally prevented the stimulation. The kinetics of 5-HT transport showed that oxidant stress did not alter the Km of 5-HT transport (Km control = 8.0 +/- 1.0 x 10(-7) M versus Km H2O2 = 9.5 +/- 1.1 x 10(-7) M) but markedly increased the maximal rate of transport (Vmax control = 36.1 +/- 4.8 pmol/10(8) platelets/4 min versus Vmax H2O2 = 79.9 +/- 9.1 pmol/10(8) platelets/4 min). Washed platelets failed to be stimulated by H2O2; however, the addition of small amounts of plasma to the buffer medium fully restored the stimulating response to H2O2. These data suggest that a plasma factor regulates the active transport of 5-HT by platelets that are oxidatively stressed.
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PMID:Oxidant stress stimulates active transport of serotonin by platelets. 253 34

Superoxide radicals inactivate endoplasmic reticular (ER) Ca2+ pump in membranes isolated from smooth muscle of pig right coronary artery [Am. J. Physiol. 255 (Cell Physiol. 24): C297-C303, 1988]. We report on protective mechanisms against such inactivation. This tissue contained superoxide dismutase (SOD) and catalase. SOD was distributed primarily in cytosolic fraction, was cyanide sensitive, and was also present in mitochondrial fraction, and approximately 25% of this was cyanide insensitive. Catalase was distributed mainly in mitochondrial fraction and did not protect against inactivation of ER Ca2+ pump by superoxide radicals generated using xanthine plus xanthine oxidase. However, cytosolic fraction protected against this inactivation by two mechanisms: 1) DTT carried over from homogenization medium and 2) its intrinsic SOD content. Soluble fraction was concentrated, dialyzed to remove 1,4-dithiothreitol (DTT), lyophilized, and suspended in a small volume of DTT-free buffer. It still protected against superoxide inactivation of Ca2+ pump. On Sephacryl-300 gel chromatography, protecting activity comigrated with SOD. DTT protected against inactivation, but glutathione and cysteine protected only partially. Neither sulfhydryl agents nor SOD could reverse the inactivation process. Ca2+ pump activity was abolished by dithionitrobenzoate and p-chloromercuric benzoate. Superoxide may inactivate ER Ca2+ pump by irreversibly modifying key sulfhydryl group(s) on pump molecule and SOD in coronary artery smooth muscle may partially protect against this inactivation.
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PMID:Protection of Ca pump of coronary artery against inactivation by superoxide radical. 253 68

Xanthine oxidase has been hypothesized to be an important source of biological free radical generation. The enzyme generates the superoxide radical, .O2- and has been widely applied as a .O2- generating system; however, the enzyme may also generate other forms of reduced oxygen. We have applied electron paramagnetic resonance (EPR) spectroscopy using the spin trap 5,5'-dimethyl-1-pyrroline-N-oxide (DMPO) to characterize the different radical species generated by xanthine oxidase along with the mechanisms of their generation. Upon reaction of xanthine with xanthine oxidase equilibrated with air, both DMPO-OOH and DMPO-OH radicals are observed. In the presence of ethanol or dimethyl sulfoxide, alpha-hydroxyethyl or methyl radicals are generated, respectively, indicating that significant DMPO-OH generation occurred directly from OH rather than simply from the breakdown of DMPO-OOH. Superoxide dismutase totally scavenged the DMPO-OOH signal but not the DMPO-OH signal suggesting that .O2- was not required for .OH generation. Catalase markedly decreased the DMPO-OH signal, while superoxide dismutase + catalase totally scavenged all radical generation. Thus, xanthine oxidase generates .OH via the reduction of O2 to H2O2, which in turn is reduced to .OH. In anaerobic preparations, the enzyme reduces H2O2 to .OH as evidenced by the appearance of a pure DMPO-OH signal. The presence of the flavin in the enzyme is required for both .O2- and .OH generation confirming that the flavin is the site of O2 reduction. The ratio of .O2- and .OH generation was affected by the relative concentrations of dissolved O2 and H2O2. Thus, xanthine oxidase can generate the highly reactive .OH radical as well as the less reactive .O2- radical. The direct production of .OH by xanthine oxidase in cells and tissues containing this enzyme could explain the presence of oxidative cellular damage which is not prevented by superoxide dismutase.
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PMID:Characterization of free radical generation by xanthine oxidase. Evidence for hydroxyl radical generation. 254 34

The calcium ionophore A23187 causes endothelium-dependent contractions in canine basilar arteries. Removal of the endothelium, or treatment with indomethacin or superoxide dismutase (SOD), prevented the endothelium-dependent excitatory effect of the calcium ionophore. Catalase and deferoxamine were without effect. Superoxide anion generated by xanthine plus xanthine oxidase in the presence of catalase caused contractions of the vascular smooth muscle, which were abolished by SOD or heat inactivation of xanthine oxidase. The A23187-induced production of prostaglandins F2 alpha and E2 and thromboxane B2 was abolished by the removal of endothelium and by treatment with indomethacin but was not affected by the presence of SOD plus catalase. These observations are consistent with the hypothesis that superoxide anion, rather than prostaglandins generated by hydroperoxidase activity of cyclooxygenase, is an endothelium-derived contracting factor in canine cerebral arteries.
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PMID:Superoxide anion is an endothelium-derived contracting factor. 254 50


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