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)

Thyroid hormone formation requires the coincident presence of peroxidase, H2O2, iodide, and acceptor protein at one anatomic locus in the cell. The peroxidase enzyme appears to be a protoporphyrin lX containing heme protein, with binding sites for both iodide and tyrosine. It is probable that both iodide and tyrosine are oxidized to free radical forms which unite to form iodotyrosine. The peroxidase is also involved through an uncertain mechanism in iodotyrosine coupling and probably in oxidation of sulfhydryl bonds in thyroglobulin. H2O2 may be supplied by microsomal NADPH-cytochrome c reductase or NADH-cytochrome b5 reductase. Other possible intracellular H2OI generating systems include monoamine oxidase and xanthine oxidase. The usual acceptor for iodide is thyroglobulin, which is currently believed to be iodinated within apical secretory vesicles at the cell border just prior to liberation into the colloid, or possibly after liberation into the colloid. Other soluble an insoluble proteins are also iodinated within the gland. The peroxidase is present in numerous cellular structures, but iodination activity occurs primarily, if not only, at the apical cell border. The controls of iodination are imperfectly known. Thyrotrophin modulation of iodide uptake, H2O2 generation, thyroglobulin synthesis, and peroxidase enzyme level obviously are the main regulations. Many of these actions are thought to involve mediation of adenyl cyclase and subsequent activation of intracellular phosphokinases. Antithyroid drugs of the thiocarbamide group are competitive inhibitors of iodination under some circumstances, but if much iodide is present, they react with the oxidized iodine intermediate and are irreversibly inactivated themselves. Clinical problems involving defective peroxidase function are among the most frequent hereditary defects of thyroid hormone formation. Recognized abnormalities include deficient peroxidase, abnormality in binding of the peroxidase apoprotein to its prosthetic group, and other less well-identified abnormalities in peroxidase structure and function. Peroxidase is typically elevated in thyroid tissue from patients with hyperthyroidism sometimes deficient in cold thyroid nodules, and frequently diminished in tissue from patients with Hashimoto's thyroiditis.
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PMID:Biosynthesis of thyroid hormone: basic and clinical aspects. 6 47

Azelaic acid is an aliphatic dicarboxylic acid (HOOC-(CH2)7-COOH) which has recently been shown to have some practical therapeutic applications in skin diseases of different etiologies. It possesses diverse biological activities and its mechanisms of action are still under investigation. Azelaic acid, as disodium salt (C(9)2Na), at concentrations from 0.05 mM to 1.0 mM is capable of inhibiting significantly the hydroxylation of 1-tyrosine to 1-DOPA due to hydroxylradicals (HO.) produced by Fenton reaction. Similarly C(9)2Na significantly inhibits the heterogeneous photocatalytic oxidation of toluene to cresols, and the peroxidation of arachidonic acid (C20:4,n6), due to HO. formed by dissolved oxygen in the presence of UV-irradiated semiconductor TiO2 (photo-Fenton type reaction). C(9)2Na decomposition and its by-products formation are quantifiable only at high HO. concentrations. On the contrary, C(9)2Na is not a scavenger of O2-. generated by xanthine-xanthine oxidase system. Under the same experimental conditions, mannitol behaves like C(9)2Na. These data indicate that HO. scavenging capacity of C(9)2Na in vitro, and represent a useful tool for further investigations on the mechanisms of action of azelaic acid in biological systems.
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PMID:Scavenging activity of azelaic acid on hydroxyl radicals "in vitro". 164 75

The ability of two low-molecular-weight copper complexes to influence the hemolysis of human erythrocytes caused by active oxygen species-generating systems was studied. Cu(II) (glycine)2 and Cu(II) (tyrosine)2 did not inhibit hemolysis due to O-2 and H2O2 generated by xanthine oxidase plus acetaldehyde but rather has a prooxidant effect. The same copper complexes as well as Cu(II) strongly inhibited the hemolysis caused by the 1O2-generating system (Rose Bengal + light). It was found that except for 1O2 the other active oxygen species (O-2, H2O2 and OH.) did not participate in the Rose Bengal + light-induced hemolysis. Thus we examined whether the inhibitory effect of copper complexes was due to 1O2 quenching. Cu(II) (glycine)2 inhibited the Rose Bengal + light-induced oxidation of compounds known to react chemically with 1O2 and its effects were analogous to the effects of physical 1O2 quenchers, e. g. NaN3 and NiCl2. The oxygen consumption upon NADH-photooxidation in the presence of Rose Bengal was inhibited competitively by Cu(II) (glycine)2 but when concentration of Rose Bengal or light intensity were varied the extent of Cu(II) (glycine)2-caused inhibition was not changed. It is concluded that the effects of Cu(II) (glycine)2 and possibly of Cu(II) (tyrosine)2 are due to quenching of 1O2 but quenching of the excited state of the dye could not be excluded.
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PMID:A study on the ability of copper complexes to act as active oxygen species scavengers. 282 28

A 4-year-old patient is described with hyperphenylalaninemia, severe retardation in development, severe muscular hypotonia of the trunk and hypertonia of the extremities, convulsions, and frequent episodes of hyperthermia without infections. Urinary excretion of neopterin, biopterin, pterin, isoxanthopterin, dopamine, and serotonin was very low, although the relative proportions of pterins were normal. In lumbar cerebrospinal fluid, homovanillic acid, 5-hydroxyindoleacetic acid, neopterin and biopterin were low. Oral administration of L-erythro tetrahydrobiopterin normalized the elevated serum phenylalanine within 4 h, serum tyrosine was increased briefly and serum alanine and glutamic acid for a longer time. Urinary dopamine and serotonin excretion were also increased. Administration of an equivalent dose of D-erythro tetrahydroneopterin was ineffective and demonstrated that this compound is not a cofactor in vivo and cannot be transformed into an active cofactor. GTP cyclohydrolase I activity was not detectable in liver biopsies from the patient. The presence of an endogenous inhibitor in the patient's liver was excluded. This is the first case of a new variant of hyperphenylalaninemia in which the formation of dihydroneopterin triphosphate and its pterin metabolites in liver is markedly diminished. Normal activities of xanthine oxidase and sulfite oxidase were apparent since uric acid levels were normal and no increase in hypoxanthine, xanthine, and S-sulfocysteine concentrations could be observed in urine. It is concluded that the molybdenum cofactor of these enzymes may not be derived from dihydroneopterin triphosphate in man. Also, since no gross abnormalities in the patient's immune system could be found, it seems unlikely that dihydroneopterin triphosphate metabolites, such as neopterin, participate actively in immunological processes, as postulated by others. See Note added in proof.
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PMID:GTP cyclohydrolase I deficiency, a new enzyme defect causing hyperphenylalaninemia with neopterin, biopterin, dopamine, and serotonin deficiencies and muscular hypotonia. 673 69

Natural killer cells spontaneously lyse certain tumor cells and may defend against malignancy. We have previously shown that natural killing (NK) by human peripheral blood mononuclear cells (PBMC) is suppressed in vitro by phorbol diester tumor promoters, including 12-O-tetradecanoylphorbol-13-acetate (TPA). We here demonstrate that suppression of NK is mediated by monocytes or polymorphonuclear leukocytes (PMN) and that suppression is dependent on the generation of reactive forms of molecular oxygen (RO), particularly hydrogen peroxide (H2O2). NK was suppressed not only by TPA but also by opsonized zymosan (yeast cell walls), which, like TPA, was not toxic to PBMC. Both TPA and zymosan stimulated the production of superoxide anion (O2-) and H2O2 by PBMC. Production of RO correlated with suppression of NK. When PBMC were depleted of monocytes, the production of RO and the suppression of NK were both markedly reduced. Suppression could be restored by monocytes or PMN, both of which produced RO in response to TPA or zymosan. Suppression of NK was dependent on RO. Monocytes or PMN from a patient with chronic granulomatous disease, whose cells cannot generate RO, did not mediate suppression of NK. Suppression was also reduced in glucose-free medium, which did not support the generation of RO. Suppression of NK by TPA was inhibited by catalase. Bovine superoxide dismutase had a limited effect on suppression, even in high concentration, and tyrosine-copper (II) complex, which also enhances dismutation of O2- to H2O2, had almost no effect on suppression. When H2O2 was directly generated enzymatically from glucose oxidase and glucose, NK was suppressed and suppression was reversed by catalase. NK was also suppressed by the enzymatic generation of O2- from xanthine oxidase and xanthine, but suppression under these conditions was again inhibited by catalase and not by superoxide dismutase, indicating that suppression was due to the secondary formation of H2O2 from O2-. These results indicate that H2O2 is important in suppression of NK. Myeloperoxidase did not appear to play a role in suppression because inhibition of this enzyme by sodium azide, cyanide, or aminotriazole did not prevent suppression of NK. Suppression of NK was reversible; after exposure to zymosan, NK could be partially restored by the addition of catalase and superoxide dismutase or by the removal of zymosan. These studies demonstrate cellular regulation of NK by monocytes or polymorphonuclear leukocytes and indicate a role for RO in immunoregulation.
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PMID:Suppression of natural killing in vitro by monocytes and polymorphonuclear leukocytes: requirement for reactive metabolites of oxygen. 707 51

Steady-state radiolysis, pulse radiolysis and epr studies, combined with enzyme activity measurements, were carried out on the mechanism by which radical attack, through one-electron oxidation, inactivates xanthine oxidase. Electron transfer to both the N3 and Br2- radical species was used to initiate oxidative damage on the enzyme. Inactivation was found to occur to a greater extent at low than at high pH and is associated with the initial formation of a tryptophanyl radical which converts by a known intramolecular pathway to a tyrosyl radical with a rate constant of 5 x 10(3) S-1. The tyrosyl radical in turn slowly loses around half of its absorbance at an intramolecular rate constant of 350S-1 and is consistent with the establishment of a radical equilibrium with cysteine residue(s). The sequence of reactions could be repeated several times on the same irradiated sample implying that restitution of the implied cysteinyl radical occurs leading to other damage in the protein. N3+Trp/N-->Trp/N-->Tyr/O<-->Cys/S-->?. Epr evidence implies that inactivation of the enzyme from the above sequence of reactions arises in part from alternations to Fe/S center I in the enzyme.
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PMID:Inactivation of xanthine oxidase by oxidative radical attack. 749 May 3

The conditions under which nitric oxide (.NO) may modulate or promote lung injury have not been identified. We hypothesized that .NO-induced injury results from peroxynitrite, formed by the reaction of .NO with superoxide. The simultaneous generation of .NO and superoxide by 3-morpholinosydnonimine (SIN-1, 0.1-2 mM) resulted in oxidation of dihydrorhodamine, a marker of peroxynitrite production, and a dose-dependent decrease in the ability of SP-A to enhance lipid aggregation. Western blot analysis of SIN-1 exposed SP-A samples, overlaid with a polyclonal antibody against nitrotyrosine, were consistent with nitration of SP-A tyrosine residues. Superoxide dismutase (100 U/ml), L-cysteine (5 mM), xanthine oxidase (10 mU/ml) and xanthine (500 microM), or urate (100 microM) prevented the SIN-1-induced dihydrorhodamine oxidation and injury to SP-A. .NO alone, generated by S-nitroso-N-acetylpenicillamine plus 100 microM L-cysteine, or superoxide and hydrogen peroxide, generated by pterin and xanthine oxidase in the absence of iron, did not damage SP-A or oxidize dihydrorhodamine. We concluded that peroxynitrite, but not .NO or superoxide and hydrogen peroxide, in concentrations likely to be encountered in vivo, caused nitrotyrosine formation and decreased the ability of SP-A to aggregate lipids.
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PMID:Concurrent generation of nitric oxide and superoxide damages surfactant protein A. 794 50

Without the addition of any exogenous stimuli, neutrophils generated O2- and then ceased in a reversible manner that correlated with cellular swelling and contraction. The nature of the possible mechanism responsible for this O2- generation was studied and compared with that observed in the triggering of stimulant-dependent O2- generation (respiratory burst). The swelling-induced O2- generation was inhibited by diphenyliodonium, and was independent of the functional distortion of mitochondrial and/or microsomal electron transport and xanthine oxidase. This suggested that such generation was involved in respiratory-burst oxidase activation; however, this generation was not accompanied by any new phosphorylation of the 47-kDa protein or of tyrosine proteins. Dihydrocytochalasin B potentiated the O2- generation. The cellular swelling produced a priming effect on the triggering of respiratory burst with different stimuli. Cellular contraction, conversely, suppressed the respiratory burst. The structural specificity of the swelling-induced plasma membrane modulation for the O2- generation was suggested by the finding that modulation of plasma membrane structures by various non-ionic detergents per se inhibited O2- generation. Lipophilic and positively-charged agents inhibited the generation and this inhibition was abrogated by negatively-charged, but not by non-ionic agents. Negatively-charged agents potentiated the O2- generation. These results suggest that both the interaction of the plasma membrane with the cytoskeleton and an increase in net negative charges at the plasma membrane play important role in evoking O2- generation; this is discussed and compared with the signal transduction reported previously for respiratory burst.
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PMID:Swelling-induced O2- generation in guinea-pig neutrophils. 838 42

Nitric oxide (.NO) is a signal transducing free radical which can modify oxidant stress by limiting superoxide (O2.-)-mediated injury. However, the product of .NO reaction with O2.-, peroxynitrite (ONOO-), is a potent oxidizing and nitrating agent. Exposure of a mixture containing phosphatidylcholine liposomes and surfactant apoprotein A (SP-A; 10% by weight) to increasing concentrations of .NO, generated by spermine NONOate, and constant O2.- levels, produced by the action of xanthine oxidase on lumazine, suppressed O2.(-)-induced lipid peroxidation in the presence of Fe3(+)- EDTA. On the other hand, an increase in the .NO/O2.- value resulted in nitration of SP-A tyrosine residues, located in the carbohydrate recognition domain (CRD), and decreased the ability of SP-A to aggregate lipids and bind mannose, two functions that require an intact CRD. SP-A was also nitrated to a large extent following exposure to 3-morpholinosydnonimine (SIN-1) or tetranitromethane at pH 8. In each case, increased nitrotyrosine content correlated in a monotonic fashion with inhibition of lipid aggregation and mannose binding, correlated with the extent of functional inhibition. Superoxide dismutase (2400 U/ml) and urate (100 microM; nonspecific scavenger of both ONOO- and hydroxyl radical), but not mannitol (50 mM; hydroxyl radical scavenger), prevented the SIN-1-induced injury to SP-A. In contrast, spermine NON-Oate or xanthine oxidase plus lumazine alone neither inhibited SP-A function nor nitrated the protein. These results indicate that at high concentrations, .NO inhibit O2.-induced lipid peroxidation. However, ONOO., formed by the reaction of .NO and O2.-, nitrates SP-A leading to decreased ability to aggregate lipids and bind mannose.
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PMID:Nitration of surfactant protein A (SP-A) tyrosine residues results in decreased mannose binding ability. 880 82

Tyrosinase isolated from cultured human melanoma cells was studied for tyrosine oxygenation activity. L-Tyrosine and D-tyrosine were used as substrates and dopa was measured with HPLC and electrochemical detection as the product of oxygenation. Incubations were performed in the presence or absence of dopamine as co-substrate. Oxygenation of L-tyrosine occurred only in the presence of dopamine as co-substrate. No oxygenation of D-tyrosine was found, and we conclude that human tyrosinase is characterised by exclusive specificity for the L-isomer of tyrosine in its oxygenase function. It has recently been suggested that superoxide anion is a preferential oxygen substrate for human tyrosinase. Incubations were therefore performed with L- and D-tyrosine, human tyrosine, and xanthine/xanthine oxidase in the system, generating superoxide anion and hydrogen peroxide. Considerable formation of dopa was observed, but the quantity was the same irrespective of whether D-tyrosine or L-tyrosine was used as the substrate. Furthermore, formation of dopa occurred in a xanthine/xanthine oxidase system when bovine serum albumin (BSA) was substituted for tyrosinase. Our results provide no evidence that superoxide anion is an oxygen substrate for human tyrosinase. In the incubate containing xanthine/xanthine oxidase, catalase completely inhibited dopa formation, and superoxide dismutase and mannitol each strongly inhibited dopa formation. The results are compatible with hydroxyl radicals being responsible for the formation of dopa, since such radicals may be secondarily formed in the presence of superoxide anion and hydrogen peroxide.
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PMID:Enzymatic and non-enzymatic oxygenation of tyrosine. 885 72


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