UNIPROT:P47989 - FACTA Search

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

The influence of endogenous nitric oxide (NO) and NO-releasing compounds on free radical release from porcine leukocytes was investigated by luminol-enhanced chemiluminescence (CL). The direct free radical-scavenging activity of the compounds was determined by a cell-free system using xanthine plus xanthine oxidase (X + XO). The NO donor, N-(2-hydroxyethyl)nicotinumide nitrate (nicorandil), markedly inhibited CL generated by phorbol myristate acetate (PMA)-stimulated leukocytes. In addition, nicorandil and S-nitrozo-N-acetylpenicillamine (SNAP) both decreased CL generated by X + XO. Conversely, C87 3754, a NO-releasing sydnonimine, decreased free radical release from leukocytes only when preincubated with the cells and had no effects on the X + XO system. None of the NO donors inhibited peroxynitrite-generated CL. L-, but not D-, arginine inhibited PMA-activated free radical generation without affecting X + XO-induced CL. L-Canavanine, N omega-nitro-L-arginine (L-NNA), and L-nitro-arginine methyl ester (L-NAME), inhibitors of the NO pathway, augmented PMA-induced CL. However, L-canavanine, but not L-NNA and L-NAME, produced a significant inhibition of X + XO-induced CL. It is concluded that endogenous NO may play an important role in the measurement of free radicals released from porcine leukocytes, assessed by luminol-enhanced CL, and that compounds with NO-releasing properties decrease CL, possibly by interfering with free radical generation.
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PMID:Influence of nitric oxide on luminol-enhanced chemiluminescence measured from porcine-stimulated leukocytes. 930 Mar 17

Multiorgan failure is often the lethal outcome of intratracheal aspiration of acidic gastric juice. The pathogenesis of multiorgan failure may involve a systemic imbalance between pro-inflammatory and anti-inflammatory factors. In an anesthetized rat model, intratracheal instillation of HCl elicited intestinal inflammation which was exaggerated by xanthine oxidase (XO) and attenuated by nitric oxide (NO). We hypothesized that XO may mediate injury in part by suppression of NO formation. Therefore, we measured intestinal tissue concentrations of the stable NO oxidative metabolites (NO2- and NO3-) following intratracheal (IT) instillation of NaCl or HCl alone or in combination with interventions aimed at increasing or decreasing XO activity. Compared with IT NaCl (control treatment) jejunal tissue NO2- and NO2- + NO3- concentrations were increased by allopurinol pretreatment, which inhibits XO, and were decreased by systemically administered XO, as well as by IT HCl. The decreased NO2- and NO2- + NO3- concentrations found following IT HCl were completely reversed by either allopurinol or by systemically administered L-arginine (the precursor of NO). We conclude that manipulation of the pro-inflammatory XO system has a reciprocal effect on the intestinal anti-inflammatory NO system in either the undamaged or the endobronchially acidified lung model.
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PMID:Xanthine oxidase decreases production of gut wall nitric oxide. 940 47

The superoxide scavenging activities of copper(II) complexes with the ligands, 6,6'-methylene- bis(5'-amino-3',4'-benzo-2'-thiapentyl)-1,11-diamino- 2,3:9,10-dibenzo-4,8-dithiaundecane (H4L), and 6,6'- bis(5'-amino-3'4'-benzo-2'-thiapentyl)-1,11-diamino- 2,3:9,10-dibenzo-4,8-dithiaundecane (H4L"), were investigated by xanthine-xanthine oxidase (X/XO) assays using nitroblue tetrazolium (NBT) as indicator molecule, and the results were compared with respect to the particular type of anion (ClO4, Cl, NO3) on the apical site of the copper(II) complexes. All of the complexes inhibited the reduction of NBT by superoxide radicals, with the [Cu2(L')](ClO4)2 complex exhibiting the highest scavenging activity against superoxide radicals among the complexes examined. The catalytic efficiency of the complexes for dismutation of superoxide radicals depends on the particular anion liganded to Cu(II) ion in the complexes, and the order of potency was observed to be ClO4 > Cl > NO3 in phosphate buffer at pH 7.40. The Cu(II)-H4L' complexes had the lowest IC50 and catalytic rate constant values indicating that the distorted geometry of the Cu(II)-H4L' complexes influence their catalytic activities for dismutation of superoxide radicals more efficiently. The difference in the activities of the complexes toward superoxide radicals can also be attributed to the nature of the anions on the apical site of the copper(II) complexes and the superoxide dismutase-like activity.
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PMID:Superoxide dismutase-mimicking activities of dinuclear Cu(II) complexes with ligands containing a tetrathioether-tetraamino moiety. 941 87

Incubation of S-nitrosocysteine or S-nitrosoglutathione (5-100 M) in the presence of a generator of superoxide (xanthine/xanthine oxidase) resulted in a time-dependent decomposition of S-nitrosothiols and accumulation of nitrite/nitrate in reaction mixtures. Quantitatively, the amounts of nitrite/nitrate represented >90% of nitrosonium equivalent of S-nitrosothiols degraded during the incubation. The reaction rates were unaffected by the presence catalase (1 unit/ml). Kinetic analysis showed that the degradation of S-nitrosothiols in the presence of superoxide proceeded at second order rate constants of 76,900 M-1 s-1 (S-nitrosocysteine) and 12,800 M-1 s-1 (S-nitrosoglutathione), respectively, with a stoichiometric ratio of 1 mol of S-nitrosothiol per 2 mol of superoxide. The findings provide the evidence for the involvement of superoxide in the metabolism of S-nitrosothiols. Furthermore, substantially slower reaction rates of superoxide with S-nitrosothiols relative to the reaction rate with NO are consistent with the contention that the transient formation of S-nitrosothiols in biological systems may protect NO from its rapid destruction by superoxide, thus enabling these compounds to serve as carriers or buffers of NO.
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PMID:Superoxide-mediated decomposition of biological S-nitrosothiols. 949 19

Nitric oxide (NO) synthesis is well-known to result from the oxidation of L-arginine by a family of NO synthases (NOS). However, under hypoxic conditions this mechanism of NO synthesis may be impaired and NO is formed by a NOS independent mechanism. This study was designed to examine the reduction of nitrite to NO by xanthine oxidase (XO) under hypoxia, because the bacterial nitrate/nitrite reductases have structural similarity to XO. We found that both purified and tissue containing XO catalyze the reduction of nitrite to NO, as demonstrated using a chemiluminescent NO meter. This redox reaction requires NADH as an electron donor, and is oxygen independent. The inhibitory profiles suggest that reduction of nitrite takes place at the molybdenum center of XO whilst NADH is oxidized at the FAD center. Heparin binding of XO caused an increase in the catalysis of nitrite reduction. The XO-catalyzed generation of NO may be important in redistribution of blood flow to ischaemic tissue as a supplement to NOS, since both nitrite and NADH have been shown to be elevated in hypoxic tissue.
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PMID:Generation of nitric oxide by a nitrite reductase activity of xanthine oxidase: a potential pathway for nitric oxide formation in the absence of nitric oxide synthase activity. 973 Dec 11

Nitric oxide (NO) has cytotoxic effects but NO producing neurons are resistant to NO toxicity. These results suggest the presence of self-protecting factors for NO toxicity. Recently, 6R-tetrahydrobiopterin (6R-BH4), a cofactor for NO synthase (NOS), has been reported to degrade NO raising the possibility that 6R-BH4 acts as a self-protecting factor for NO toxicity. In PC12 cells which have NOS, three-day culture with sodium nitroprusside (SNP) or NOC-12, NO generators, at 10-100 microM increased nitrite and nitrate concentrations in the culture medium and induced death of PC12 cells. Coadministration of 6R-BH4 (10 or 30 microM) with SNP or NOC-12 prevented cell death with reduction of nitrite and nitrate in the medium. Inhibition of 6R-BH4 synthesis by 2,4-diamino-6-hydroxypyrimidine (DAHP), an inhibitor for GTP cyclohydrolase I, decreased cellular 6R-BH4 content and viable cell number. The inhibiting effects of DAHP were restored by exogenous 6R-BH4. NOS activity, as estimated by nitrite concentrations in the medium, was unchanged by DAHP. Hypoxanthine and xanthine oxidase, which produce superoxide, mimicked the cell-protecting effect of 6R-BH4 which is reported to generate superoxide during its autoxidation. These results suggest that 6R-BH4 acts as a self-protecting factor for NO toxicity with generation of superoxide in NO-producing neurons.
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PMID:Self-protection of PC12 cells by 6R-tetrahydrobiopterin from nitric oxide toxicity. 984 57

Exhaled nitric oxide (NO) is increased in some inflammatory airway disorders but not in others such as cystic fibrosis and acute respiratory distress syndrome. NO can combine with superoxide (O-2) to form peroxynitrite, which can decompose into nitrate. Activated polymorphonuclear neutrophils (PMNs) releasing O-2 could account for a reduction in exhaled NO in disorders such as cystic fibrosis. To test this hypothesis in vitro, we stimulated confluent cultures of LA-4 cells, a murine lung epithelial cell line, to produce NO. Subsequently, human PMNs stimulated to produce O-2 were added to the LA-4 cells. A gradual increase in NO in the headspace above the cultures was observed and was markedly reduced by the addition of PMNs. An increase in nitrate in the culture supernatant fluids was measured, but no increase in nitrite was detected. Superoxide dismutase attenuated the PMN effect, and xanthine/xanthine oxidase reproduced the effect. No changes in epithelial cell inducible NO synthase protein or mRNA were observed. These data demonstrate that O-2 released from PMNs can decrease NO by conversion to nitrate and suggest a potential mechanism for modulation of NO levels in vivo.
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PMID:Superoxide released from neutrophils causes a reduction in nitric oxide gas. 984 49

Oxidation by rat liver microsomes of 13 compounds involving a C=N(OH) function (including N-hydroxyguanidines, amidoximes, ketoximes, and aldoximes) was found to occur with the release of nitrogen oxides such as NO, NO2-, and NO3-. The greatest activities were observed with liver microsomes from dexamethasone-treated rats (up to 8 nmol of NO2- nmol of P450(-)1 min-1). A detailed study of the microsomal oxidation of some of these compounds was performed. Oxidation of N-(4-chlorophenyl)-N'-hydroxy-guanidine led to the formation of the corresponding urea and cyanamide in addition to NO, NO2-, and NO3-. Formation of all these products was dependent on NADPH, O2, and cytochromes P450. Oxidation of two arylamidoximes was found to occur with formation of the corresponding amides and nitriles in addition to nitrogen oxides. Oxidation of 4-(chlorophenyl)methyl ketone oxime gave the corresponding ketone and nitroalkane as well as NO, NO2-, and NO3-. These reactions were also dependent on cytochromes P450 and required NADPH and O2. Mechanistic experiments showed that microsomal oxidations of amidoximes to the corresponding nitriles and of ketoximes to the corresponding nitroalkanes are not inhibited by superoxide dismutase (SOD) and are performed by a cytochrome P450 active species, presumably the high-valent P450-iron-oxo complex. On the contrary, microsomal oxidation of N-hydroxyguanidines to the corresponding cyanamides was greatly inhibited by SOD and appeared to be mainly due to O2*- derived from the oxidase function of cytochromes P450. Similarly, microsomal oxidations of N-hydroxyguanidines and amidoximes to the corresponding ureas and amides were also found to be mainly performed by O2*-, as shown by the great inhibitory effect of SOD (70-100%) and the ability of the xanthine-xanthine oxidase system to give similar oxidation products. However, it is noteworthy that other species, such as the P450 Fe(II)-O2 complex, are also involved, to a minor extent, in the SOD-insensitive microsomal oxidative cleavages of compounds containing a C=N(OH) bond. Our results suggest a general mechanism for such oxidative cleavages of C=N(OH) bonds with formation of nitrogen oxides by cytochromes P450 and NO-synthases, with the involvement of O2*- and its Fe(III) complex [(FeIII-O2-) or (FeII-O2)] as main active species.
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PMID:Microsomal cytochrome P450 dependent oxidation of N-hydroxyguanidines, amidoximes, and ketoximes: mechanism of the oxidative cleavage of their C=N(OH) bond with formation of nitrogen oxides. 986 Aug 31

The relevance of lucigenin (bis-N-methylacridinium nitrate)-amplified chemiluminescence (CL) as a specific assay for superoxide ion has recently been disputed (S. I. Liochev and I. Fridovich, Arch. Biochem. Biophys. 337, 115-120, 1997). These authors suggested that the redox cycling of lucigenin can lead to the formation of additional amount of superoxide ion. However, thermodynamic consideration shows that the equilibrium for the reaction O*-2 + Luc2+ if O2 + Luc*+ is completely shifted to the right (Keq = 10(6)); therefore, the redox cycling of lucigenin is of no importance. This conclusion is supported by the study of the effects of lucigenin on cytochrome c reduction by xanthine oxidase. It was found that lucigenin did enhance the rate of cytochrome c reduction with xanthine as a substrate, but it did not increase the rate of xanthine oxidation. When NADH was used as a substrate, lucigenin inhibited the SOD-dependent component of cytochrome c reduction and enhanced both the SOD-independent cytochrome c reduction and NADH oxidation, being a sole acceptor of an electron from the enzyme. All these findings indicate the extremely low probability of lucigenin redox cycling. In our opinion, lucigenin-amplified CL remains the most sensitive and highly specific test for superoxide formation in biological systems.
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PMID:Lucigenin is a mediator of cytochrome C reduction but not of superoxide production. 1035 92

The periplasmic nitrate reductase from Paracoccus denitrificans is a soluble two-subunit enzyme which binds two hemes (c-type), a [4Fe-4S] center, and a bis molybdopterin guanine dinucleotide cofactor (bis-MGD). A catalytic cycle for this enzyme is presented based on a study of these redox centers using electron paramagnetic resonance (EPR) and extended X-ray absorption fine structure (EXAFS) spectroscopies. The Mo(V) EPR signal of resting NAP (High g [resting]) has g(av) = 1.9898 is rhombic, exhibits low anisotropy, and is split by two weakly interacting protons which are not solvent-exchangeable. Addition of exogenous ligands to this resting state (e.g., nitrate, nitrite, azide) did not change the form of the signal. A distinct form of the High g Mo(V) signal, which has slightly lower anisotropy and higher rhombicity, was trapped during turnover of nitrate and may represent a catalytically relevant Mo(V) intermediate (High g [nitrate]). Mo K-edge EXAFS analysis was undertaken on the ferricyanide oxidized enzyme, a reduced sample frozen within 10 min of dithionite addition, and a nitrate-reoxidized form of the enzyme. The oxidized enzyme was fitted best as a di-oxo Mo(VI) species with 5 sulfur ligands (4 at 2. 43 A and 1 at 2.82 A), and the reduced form was fitted best as a mono-oxo Mo(IV) species with 3 sulfur ligands at 2.35 A. The addition of nitrate to the reduced enzyme resulted in reoxidation to a di-oxo Mo(VI) species similar to the resting enzyme. Prolonged incubation of NAP with dithionite in the absence of nitrate (i.e., nonturnover conditions) resulted in the formation of a species with a Mo(V) EPR signal that is quite distinct from the High g family and which has a g(av) = 1.973 (Low g [unsplit]). This signal resembles those of the mono-MGD xanthine oxidase family and is proposed to arise from an inactive form of the nitrate reductase in which the Mo(V) form is only coordinated by the dithiolene of one MGD. In samples of NAP that had been reduced with dithionite, treated with azide or cyanide, and then reoxidized with ferricyanide, two Mo(V) signals were detected with g(av) elevated compared to the High g signals. Kinetic analysis demonstrated that azide and cyanide displayed competitive and noncompetitive inhibition, respectively. EXAFS analysis of azide-treated samples show improvement to the fit when two nitrogens are included in the molybdenum coordination sphere at 2.52 A, suggesting that azide binds directly to Mo(IV). Based on these spectroscopic and kinetic data, models for Mo coordination during turnover have been proposed.
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PMID:Models for molybdenum coordination during the catalytic cycle of periplasmic nitrate reductase from Paracoccus denitrificans derived from EPR and EXAFS spectroscopy. 1041 73

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