Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.17.1.4 (xanthine dehydrogenase)
 1,236 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

We report the identification of a number of mutations that result in amino acid replacements (and their phenotypic characterization) in either the MogA-like domain or domains 2 and 3 of the MoeA-like region of the Aspergillus nidulans cnxE gene. These domains are functionally required since mutations that result in amino acid substitutions in any one domain lead to the loss or to a substantial reduction in all three identified molybdoenzyme activities (i.e., nitrate reductase, xanthine dehydrogenase, and nicotinate hydroxylase). Certain cnxE mutants that show partial growth with nitrate as the nitrogen source in contrast do not grow on hypoxanthine or nicotinate. Complementation between mutants carrying lesions in the MogA-like domain or the MoeA-like region, respectively, most likely occurs at the protein level. A homology model of CnxE based on the dimeric structure of E. coli MoeA is presented and the position of inactivating mutations (due to amino acid replacements) in the MoeA-like functional region of the CnxE protein is mapped to this model. Finally, the activity of nicotinate hydroxylase, unlike that of nitrate reductase and xanthine dehydrogenase, is not restored in cnxE mutants grown in the presence of excess molybdate.
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PMID:Mutational analysis of the gephyrin-related molybdenum cofactor biosynthetic gene cnxE from the lower eukaryote Aspergillus nidulans. 1207 59

Tyrosine nitration is a common modification to proteins in vivo, but the reactive nitrogen species responsible for nitration are often studied in vitro using just the amino acid tyrosine in simple phosphate solutions. To investigate which reactive nitrogen species could nitrate proteins in a complex biological system, we exposed rat heart and brain homogenates to peroxynitrite, nitric oxide under aerobic conditions, and other putative nitrating agents. Peroxynitrite was by far the most efficient nitrating agent when alternative targets were available to compete with tyrosine. Curiously, proteins in heart homogenates were substantially more resistant to nitration than brain homogenates. Ultrafiltration to remove low molecular weight compounds made the heart proteins equally susceptible as the brain proteins to nitration. Endogenous ascorbate and free thiols had little effect on nitration by peroxynitrite in either heart or brain. However, accumulation of urate formed by the oxidation of hypoxanthine by xanthine dehydrogenase and oxidase in heart appeared to be the major inhibitor of nitration. Heart homogenates treated with uricase, which converts urate to allantoin, showed equivalent nitration as in brain homogenates. Urate, as assayed by HPLC, was 58 +/- 8 microM in heart but only 4 +/- 2 microM in brain homogenates. Although xanthine dehydrogenase conversion to a free radical-producing oxidase can serve as an important source of superoxide and hydrogen peroxide during ischemia/reperfusion, our results suggest that urate formation by xanthine dehydrogenase may provide a significant antioxidant defense against peroxynitrite and related nitric oxide-derived oxidants.
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PMID:Urate produced during hypoxia protects heart proteins from peroxynitrite-mediated protein nitration. 1239 32

In addition to nitric oxide (NO) generation from specific NO synthases, NO is also formed during anoxia from nitrite reduction, and xanthine oxidase (XO) catalyzes this process. While in tissues and blood high nitrate levels are present, questions remain regarding whether nitrate is also a source of NO and if XO-mediated nitrate reduction can be an important source of NO in biological systems. To characterize the kinetics, magnitude, and mechanism of XO-mediated nitrate reduction under anaerobic conditions, EPR, chemiluminescence NO-analyzer, and NO-electrode studies were performed. Typical XO reducing substrates, xanthine, NADH, and 2,3-dihydroxybenz-aldehyde, triggered nitrate reduction to nitrite and NO. The rate of nitrite production followed Michaelis-Menten kinetics, while NO generation rates increased linearly following the accumulation of nitrite, suggesting stepwise-reduction of nitrate to nitrite then to NO. The molybdenum-binding XO inhibitor, oxypurinol, inhibited both nitrite and NO production, indicating that nitrate reduction occurs at the molybdenum site. At higher xanthine concentrations, partial inhibition was seen, suggesting formation of a substrate-bound reduced enzyme complex with xanthine blocking the molybdenum site. The pH dependence of nitrite and NO formation indicate that XO-mediated nitrate reduction occurs via an acid-catalyzed mechanism. With conditions occurring during ischemia, myocardial xanthine oxidoreductase and nitrate levels were determined to generate up to 20 microM nitrite within 10-20 min that can be further reduced to NO with rates comparable to those of maximally activated NOS. Thus, XOR catalyzed nitrate reduction to nitrite and NO occurs and can be an important source of NO production in ischemic tissues.
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PMID:Characterization of the magnitude and kinetics of xanthine oxidase-catalyzed nitrate reduction: evaluation of its role in nitrite and nitric oxide generation in anoxic tissues. 1254 37

To date, dozens of genes have been reported to be up-regulated with senescence in higher plants. Radish din1 and its ortholog sen1 of Arabidopsis are known as such, but their function is not clear yet. Here we have isolated their counterpart cDNA from tobacco and designated it as NTDIN: Its product, Ntdin, a 185 amino acid polypeptide with 56.8% and 54.2% identity to Atsen1 and Rsdin1, respectively, is localized in chloroplasts. Transcripts of Ntdin are induced by sulfate or nitrate but not by phosphate, suggesting its involvement in sulfur and nitrogen metabolism. A database search revealed that Ntdin shows similarity with the C-terminal region of Nicotiana plumbaginifolia Cnx5, which functions in molybdenum cofactor (Moco) biosynthesis. Transgenic tobacco plants with suppressed Ntdin are more tolerant to chlorate, a substrate analog of nitrate reductase, than controls, implying low nitrate reductase activity in the transgenic plants due to a deficiency of Moco. Indeed, enzymatic activities of two molybdoenzymes, nitrate reductase and xanthine dehydrogenase, in transgenic plants are found to be significantly lower than in control plants. Direct measurement of Moco contents reveals that those transgenic plants contain about 5% Moco of those of the control plants. Abscisic acid and indole-3-acidic acid, whose biosynthetic pathways require Moco, up-regulated Ntdin expression. Taken together, it is concluded that Ntdin functions in a certain step in Moco biosynthesis.
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PMID:Ntdin, a tobacco senescence-associated gene, is involved in molybdenum cofactor biosynthesis. 1458 28

There is substantial evidence that oxidative stress participates in the pathophysiology of cardiovascular disease. Biochemical, molecular and pharmacological studies further implicate xanthine oxidoreductase (XOR) as a source of reactive oxygen species in the cardiovascular system. XOR is a member of the molybdoenzyme family and is best known for its catalytic role in purine degradation, metabolizing hypoxanthine and xanthine to uric acid with concomitant generation of superoxide. Gene expression of XOR is regulated by oxygen tension, cytokines and glucocorticoids. XOR requires molybdopterin, iron-sulphur centres, and FAD as cofactors and has two interconvertible forms, xanthine oxidase and xanthine dehydrogenase, which transfer electrons from xanthine to oxygen and NAD(+), respectively, yielding superoxide, hydrogen peroxide and NADH. Additionally, XOR can generate superoxide via NADH oxidase activity and can produce nitric oxide via nitrate and nitrite reductase activities. While a role for XOR beyond purine metabolism was first suggested in ischaemia-reperfusion injury, there is growing awareness that it also participates in endothelial dysfunction, hypertension and heart failure. Importantly, the XOR inhibitors allopurinol and oxypurinol attenuate dysfunction caused by XOR in these disease states. Attention to the broader range of XOR bioactivity in the cardiovascular system has prompted initiation of several randomised clinical outcome trials, particularly for congestive heart failure. Here we review XOR gene structure and regulation, protein structure, enzymology, tissue distribution and pathophysiological role in cardiovascular disease with an emphasis on heart failure.
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PMID:Xanthine oxidoreductase and cardiovascular disease: molecular mechanisms and pathophysiological implications. 1469 47

In addition to its basic role in the metabolism of purine nucleotides, xanthine oxidoreductase (XOR) is involved in the generation of oxygen-derived free radicals and production and metabolic fate of nitric oxide (NO). Growth hormone (GH) and Vitamin E (E) have been shown previously to modify immune response to infection. Our objective was to determine in heifers the effect of endotoxin challenge (LPS; 3.0 microg/kg BW, i.v. bolus, Escherichia coli 055:B5) on xanthine oxidase (XO) activity in plasma and liver and the modification of this response by daily treatment with recombinant GH (0.1 mg/kg BW, i.m., for 12 days) or GH+E (E: mixed tocopherol, 1000 IU/heifer, i.m., for 5 days). In experiment 1, 16 heifers ( 348.7 +/- 6.1 kg) were assigned to control (C, daily placebo injections), GH, or GH+E treatments and were challenged with two consecutive LPS injections (LPS1 and LPS2, 48 h apart). After LPS1, plasma XO activity increased 290% (P < 0.001) at 3 h, reached peak (430%) at 24 h and returned to basal level by 48 h after LPS2. XO responses (area under the time x activity curve, AUC) were greater after LPS1 than LPS2 (P< 0.001). Total plasma XO responses to LPS (AUC, LPS1+LPS2) were augmented 55% (P < 0.05) over C with GH treatment but diminished to C responses in GH+E. There was a linear relationship (r2 = 0.605, P < 0.001) between total response in plasma XO activity and plasma nitrate + nitrate concentration. In experiment 2, 24 heifers ( 346 +/- 6 kg) were assigned to C or GH treatments and liver biopsy samples were obtained at 0, 3, 6, and 24h after a single LPS challenge. Hepatic XO activities increased 63.3% (P < 0.05) 6 h after single LPS challenge and remained elevated at 24 h (100.1%, P < 0.01) but were not affected by GH treatment. Results indicate that LPS-induced increases in plasma XO activity could be amplified by previous GH treatment but attenuated by E administration. The data also suggest that E may be effective in controlling some mediators of immune response associated with increased production of NO via the effect on XO activity and its production of superoxide anion as well as uric acid.
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PMID:Endotoxin challenge increases xanthine oxidase activity in cattle: effect of growth hormone and vitamin E treatment. 1506 24

The requirement for the mobA gene in key assimilatory and respiratory nitrogen metabolism of Pseudomonas aeruginosa PAO1 was investigated by mutational analysis of PA3030 (mobA; MoCo guanylating enzyme), PA1779 (nasA; assimilatory nitrate reductase), and PA3875 (narG; respiratory nitrate reductase). The mobA mutant was deficient in both assimilatory and respiratory nitrate reductase activities, whereas xanthine dehydrogenase activity remained unaffected. Thus, P. aeruginosa requires both the molybdopterin (MPT) and molybdopterin guanine dinucleotide (MGD) forms of the molybdenum cofactor for a complete spectrum of nitrogen metabolism, and one form cannot substitute for the other. Regulation studies using a Phi(PA3030-lacZGm) reporter strain suggest that expression of mobA is not influenced by the type of nitrogen source or by anaerobiosis, whereas assimilatory nitrate reductase activity was detected only in the presence of nitrate.
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PMID:The mobA gene is required for assimilatory and respiratory nitrate reduction but not xanthine dehydrogenase activity in Pseudomonas aeruginosa. 1623 22

Nitrate reductase-deficient barley (Hordeum vulgare L.) mutants were assayed for the presence of a functional molybdenum cofactor determined from the activity of the molybdoenzyme, xanthine dehydrogenase, and for nitrate reductase-associated activities. Rocket immunoelectrophoresis was used to detect nitrate reductase cross-reacting material in the mutants. The cross-reacting material levels of the mutants ranged from 8 to 136% of the wild type and were correlated with their nitrate reductase-associated activities, except for nar 1c, which lacked all associated nitrate reductase activities but had 38% of the wild-type cross-reacting material. The cross-reacting material of two nar 1 mutants, as well as nar 2a, Xno 18, Xno 19, and Xno 29, exhibited rocket immunoprecipitates that were similar to the wild-type enzyme indicating structural homology between the mutant and wild-type nitrate reductase proteins. The cross-reacting materials of the seven remaining nar 1 alleles formed rockets only in the presence of purified wild-type nitrate reductase, suggesting structural modifications of the mutant cross-reacting materials. All nar 1 alleles and Xno 29 had xanthine dehydrogenase activity indicating the presence of functional molybdenum cofactors. These results suggest that nar 1 is the structural gene for nitrate reductase. Mutants nar 2a, Xno 18, and Xno 19 lacked xanthine dehydrogenase activity and are considered to be molybdenum cofactor deficient mutants. Cross-reacting material was not detected in uninduced wild-type or mutant extracts, suggesting that nitrate reductase is synthesized de novo in response to nitrate.
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PMID:Nitrate reductase-deficient mutants in barley : immunoelectrophoretic characterization. 1666 74

The effect of nitrate on N(2) fixation and the assimilation of fixed N(2) in legume nodules was investigated by supplying nitrate to well established soybean (Glycine max L. Merr. cv Bragg)-Rhizobium japonicum (strain 3I1b110) symbioses. Three different techniques, acetylene reduction, (15)N(2) fixation and relative abundance of ureides ([ureides/(ureides + nitrate + alpha-amino nitrogen)] x 100) in xylem exudate, gave similar results for the effect of nitrate on N(2) fixation by nodulated roots. After 2 days of treatment with 10 millimolar nitrate, acetylene reduction by nodulated roots was inhibited by 48% but there was no effect on either acetylene reduction by isolated bacteroids or in vitro activity of nodule cytoplasmic glutamine synthetase, glutamine oxoglutarate aminotransferase, xanthine dehydrogenase, uricase, or allantoinase. After 7 days, acetylene reduction by isolated bacteroids was almost completely inhibited but, except for glutamine oxoglutarate aminotransferase, there was still no effect on the nodule cytoplasmic enzymes. It was concluded that, when nitrate is supplied to an established symbiosis, inhibition of nodulated root N(2) fixation precedes the loss of the potential of bacteroids to fix N(2). This in turn precedes the loss of the potential of nodules to assimilate fixed N(2).
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PMID:Enzymes of ammonia assimilation and ureide biosynthesis in soybean nodules: effect of nitrate. 1666 78

Two methods were developed for the detection of altered ureide metabolism in legume nodules. Both techniques are based on the positive correlation between the presence of high xanthine dehydrogenase (EC 1.2.1.37) specific activity in nodules and the ability of those nodules to produce the ureides, allantoin and allantoic acid. In the first method, nodulated legumes are treated for 2 weeks with a soil drench of allopurinol. After allopurinol treatment, leaves of N(2)-fed, ureide-producing legumes, soybean, cowpea, and lima bean, became very chlorotic. Leaves of KNO(3) (-) or NH(4)Cl-fed ureide-producing legumes were unaffected by the allopurinol treatment. Leaves of the amide-producing legumes, alfalfa, clover, peak, and lupin, were unaffected by the allopurinol treatment with N(2), KNO(3), or NH(4)Cl as nitrogen source. These experiments showed that long-term allopurinol treatments are useful in differentiating between ureide- and amide-producing legumes when effectively nodulated. A second method was developed for the rapid, qualitative estimation of xanthine dehydrogenase activity in legume nodules. This method utilizes pterin, an alternate substrate for xanthine dehydrogenase. Xanthine dehydrogenase hydroxylates pterin in the presence of NAD(+) to produce isoxanthopterin. When exposed to long wave ultraviolet light (365 nanometers), isoxanthopterin emits blue fluorescence. When nodules of ureide-producing legumes were sliced in half and placed in microtiter plate wells containing NAD(+) and pterin, isoxanthopterin was observed after 6 hours of incubation at room temperature. Allopurinol prevented isoxanthopterin production. When slices of amide-producing legume nodules were placed in wells with pterin and NAD(+), no blue fluorescence was observed. The production of NADH by xanthine dehydrogenase does not interfere with the fluorescence of isoxanthopterin. These observations agree with the high specific activity of xanthine dehydrogenase in nodules of ureide-producing legumes and the low activity measured in amide-producing nodules. The wild soybean, Glycine soja Sieb. and Zucc., was examined for ureide synthesis. Stems of wild soybean plants had a high ureide abundance with N(2) as sole nitrogen source when nodulated with either Rhizobium fredii or Bradyrhizobium japonicum. Ureide abundance declined when nitrate or ammonium was added to the nutrient solution. Nodule slices of these plants produced isoxanthopterin when incubated with pterin. Nodule crude extracts of G. soja had high levels of xanthine dehydrogenase activity. Both Glycine max and G. soja plants were found to produce ureides when plants were inoculated with fast-growing R. fredii. The two methods described here can be used to discriminate ureide producers from amide producers as well as detect nitrogen-fixing legumes which have altered ureide metabolism. A nodulated legume that lacks xanthine dehydrogenase activity as demonstrated by the pterin assay cannot produce ureides since ureide synthesis has been shown to require xanthine dehydrogenase activity both in vivo and in vitro. A nodulated legume that remains green during allopurinol treatment also lacks ureide synthesis since the leaves of ureide-producing legumes are very chlorotic following allopurinol treatment.
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PMID:Two indirect methods for detecting ureide synthesis by nodulated legumes. 1666 57


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