Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:1.10.3.1 (tyrosinase)
 9,065 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Evidence for the generation of superoxide anion in an enzymatic action of tyrosinase is reported. In the dopatyrosinase reaction, 1 mol of O2 is required for the production of 2 mol of dopaquinone, 1 mol of dopachrome, and 1/4 mol of O2-. Superoxide dismutase and 2-methyl-6-phenyl-3,7-dihydroimidazo[1,2-a]pyrazin-3-one (a chemiluminescence probe and O2 trap) do not inhibit the rate of dopachrome formation from dopa in the presence of tyrosinase, indicating that free O2- is not utilized for metabolizing dopa. ESR studies for the accumulation of semiquinone radicals generated from tyrosine and N-acetyltyrosine in the presence of tyrosinase imply that O2- is not generated by the semiquinone + O2 reaction. Since the addition of H2O2 and dopa to tyrosinase promotes the release of O2- and formation of dopachrome, the Cu(II)O2-Cu(I) complex could be formed as a intermediate (an active form of tyrosinase); [Cu(II)]2 + H2O2 in equilibrium Cu(I)O2-Cu(II) + 2H+.
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PMID:Generation of superoxide during the enzymatic action of tyrosinase. 130 77

The enzyme system causing the side chain desaturation of the sclerotizing precursor, N-acetyldopamine (NADA), was solubilized from the larval cuticle of Sarcophaga bullata and resolved into three components. The first enzyme, phenoloxidase, catalyzed conversion of NADA to NADA quinone and provided it for the second enzyme (NADA quinone isomerase), which makes the highly unstable NADA quinone methide. Quinone methide was hydrated rapidly and nonenzymatically to form N-acetylnorepinephrine. In addition, it also served as the substrate for the last enzyme, quinone methide tautomerase, which converted it to 1,2-dehydro-NADA. Reconstitution of NADA side chain desaturase activity was achieved by mixing the last enzyme fraction with NADA quinone isomerase, obtained from the hemolymph of the same organism, and mushroom tyrosinase. Therefore, NADA side chain desaturation observed in insects is caused by the combined action of three enzymes rather than the action of a single specific NADA desaturase, as previously thought.
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PMID:N-acetyldopamine quinone methide/1,2-dehydro-N-acetyl dopamine tautomerase. A new enzyme involved in sclerotization of insect cuticle. 250 58

The synthesis of melanin involves the oxidation of phenolic substrates by the enzyme tyrosinase. In vertebrates tyrosinase is present only in specialized cells (melanocytes), where it catalyses the oxidation of tyrosine and certain diphenolic intermediate products to quinones which polymerize to give rise to melanin. This specialized metabolic pathway provides a possible approach to the specific chemotherapy of malignant tumours of pigment cells (malignant melanoma). Certain analogues of tyrosine are oxidized by tyrosinase generating reactive orthoquinones with cytotoxic potential. One such analogue, 4-hydroxyanisole, has been investigated as a possible specific melanocytotoxic precursor. The parent compound inhibits DNA synthesis but exhibits little general toxicity, while the tyrosinase oxidation products are highly toxic to cells. The mechanism of this toxicity may involve semiquinone radicals. Encouraging initial results have been obtained from clinical pilot studies using intra-arterial infusion of hydroxyanisole in patients with localized recurrences of malignant melanoma.
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PMID:Radicals and melanomas. 286 25

The cytotoxicity of catechols has been ascribed to covalent binding of the o-quinone oxidation products to proteins through the sulphydryl group. We have previously shown that dopaquinone can bind covalently to proteins through cysteine residues to form protein-bound cysteinyldopas. In this study, we have compared the reactivities of o-quinones, derived from tyrosinase oxidation of various catechols, with the cysteine residue in bovine serum albumin. o-Quinone forms of dopamine, norepinephrine, N-acetyldopa, N-acetyldopamine, 3,4-dihydroxyphenylacetic acid, pyrocatechol and 4-methylcatechols were much more reactive than dopaquinone, while o-quinone forms of 5-S-cysteinyldopa and epinephrine were much less reactive. The yield of protein-bound cysteinylcatechols appears to depend on a competition between the intermolecular nucleophilic reaction of sulphydryl groups in protein and the intramolecular nucleophilic reaction of an amino group in the side chain.
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PMID:Covalent binding of catechols to proteins through the sulphydryl group. 313 75

A series of stable quinones and their precursors, and enzymatic oxidation products of plant allelochemicals were tested for their effect on maize fungal pathogens, primarily Fusarium graminearum. Benzoquinone was typically significantly more toxic than hydroquinone, while 1,2-naphthoquinone was typically significantly more toxic than 1,2-dihydroxynaphthalene. Aspergillus flavus was the most resistant fungus to these compounds, while Phoma medicaginis was the most susceptible. Applying tyrosinase in conjunction with several phenolic compounds only increased the toxicity of gallic acid to Fusarium graminearum. Applying peroxidase generally increased toxicity of all compounds tested to this fungus in a dose-dependent fashion. Ferulic acid was generally the most toxic compound, both alone and when combined with peroxidase and H2O2, followed by coumaric acid. These results suggest that enzymatic oxidation of plant allelochemicals may result in the generation of products that either are directly toxic to maize pathogens, or indirectly inhibitory due to their ability to tie up nutrients.
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PMID:Comparative toxicity of allelochemicals and their enzymatic oxidation products to maize fungal pathogens, emphasizing Fusarium graminearum. 949 76

When 3,4-dihydroxybenzylcyanide (DBC) is oxidized by mushroom tyrosinase, the first visible product, identified as the corresponding quinomethane, exhibits an absorption maximum at 480 nm. Pulse-radiolysis experiments, in which the o-quinone is formed by disproportionation of semiquinone radicals generated by single-electron oxidation of DBC, showed that the quinomethane (A480 6440 M-1.cm-1) is formed through the intermediacy of the o-quinone with a rate constant at neutral pH of 7.5 s-1. The oxygen stoichiometry of the formation of the quinomethane by tyrosinase-catalysed oxidation of DBC was 0.5:1. On the basis of oxygen utilization rates the calculated Vmax was 4900 nmol.min-1 and the apparent Km was 374 microM. The corresponding monohydric phenol, 4-hydroxybenzylcyanide (HBC), was not oxidized by tyrosinase unless the enzyme was pre-exposed to DBC, the maximum acceleration of HBC oxidation being obtained by approximately equimolar addition of DBC. These results are consistent with tyrosinase auto-activation on the basis of the indirect formation of the dihydric phenol-activating cofactor. The rapid conversion of the o-quinone to the quinomethane prevents the formation of the catechol by reduction of the o-quinone product of monohydric phenol oxidation from occurring in the case of the compounds studied. In the absence of auto-activation, the kinetic parameters for HBC oxidation by tyrosinase were estimated as Vmax 70 nmol.min-1 and Km 309 microM. The quinomethane was found to decay with a rate constant of 2k 38 M-1.s-1, as determined both by pulse-radiolysis and tyrosinase experiments. The second-order kinetics indicate that a dimer is formed. In the presence of tyrosinase, but not in the pulse-radiolysis experiments, the quinomethane decay was accompanied by a steady-state oxygen uptake concurrently with the generation of a melanoid product measured by its A650, which is ascribed to the formation of an oligomer incorporating the oxidized dimer.
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PMID:Tyrosinase kinetics: failure of the auto-activation mechanism of monohydric phenol oxidation by rapid formation of a quinomethane intermediate. 967 29

Hemocyanin and tyrosinase are dinuclear copper proteins capable of reversibly binding dioxygen. Despite the great similarity of structure and properties of their active site, the two proteins perform different biological functions (oxygen transport/storage versus monooxygenase and oxidase activity). In this paper, we show that Octopus vulgaris hemocyanin exhibits a tyrosinase-like activity; namely, it is capable of utilizing dioxygen for the oxidation of o-diphenol to quinone. The reaction is specific for this isomer of diphenol, the meta and para isomers being unreactive, and is strongly controlled by steric factors. Dioxygen represents a cosubstrate of the reaction, and it is involved in the catalytic turnover by binding to the dinuclear copper site of the protein to form, under steady-state conditions, oxy-Hc, which is the active species. The generation of semiquinone radicals, detected by EPR and by their reaction with N,N,N',N'-tetramethyl-1,4-phenylenediamine, strongly supports a reaction mechanism in which such radicals represent the reaction products of one-electron oxidation of the substrate, quinone being generated by dismutation of semiquinones. Met-Hc is regenerated by the substrate to the deoxy form. To close the catalytic cycle, the proposed reaction mechanism also involves the participation of two transient protein forms with the total oxidation state of the active site (V and IV) intermediate between that of oxy-Hcy, [CuIIO22-CuII]VI, and deoxy-Hc, [CuICuI]II. A mathematical model has been elaborated to describe the reaction kinetics. The differences in reaction mechanisms between hemocyanin and tyrosinase are discussed in terms of accessibility to exogenous molecules of their active sites.
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PMID:The enzymatic properties of Octopus vulgaris hemocyanin: o-diphenol oxidase activity. 976 Feb 42

The amperometric response toward phenol of PPO-based rotating disk bioelectrodes is analyzed on the basis of a kinetic model taking into account internal and external mass transport effects and a CEC' electroenzymatic mechanism. Monophenolase activity of PPO catalyses the oxidation of phenol to o-quinone (step C). o-Quinone can then enter an amplification recycling process involving electrochemical reduction (step E) and enzymatic reoxidation (step C': catecholase activity). The rate-limiting steps such as monophenolase activity, catecholase recycling, permeability of the membrane, and activity and accessibility of the catalytic enzyme sites are theoretically considered and experimentally demonstrated for different electrode configurations including PPO immobilized in Laponite hydrogels and layer-by-layer self-assembled multilayers of PPO and poly(diallyldimethylammonium).
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PMID:Amplification of amperometric biosensor responses by electrochemical substrate recycling. 3. Theoretical and experimental study of the phenol-polyphenol oxidase system immobilized in Laponite hydrogels and layer-by-layer self-assembled structures. 1147 17

Two oxidation systems were examined for the oxidation of three groups of phenolic antioxidants; five cinnamic acids, two benzoic acids, and two phenols characteristic of olive fruits. Periodate oxidation, which is reported to produce products similar to polyphenol oxidase, was contrasted with the reactivity of the Fenton system, an inorganic source of hydroxyl radicals. Reaction products were identified as various quinones, dimers, and aldehydes, but the nature of the products differed between the two oxidation systems. Structure-activity effects were also observed for the different phenols. All cinnamic acids in this study reacted with the Fenton reagent to produce benzaldehydes as the main products, with the exception of 5-caffeoylquinic acid. In contrast, periodate oxidation gave no reaction with some of the cinnamic acids. Quinone formation was observed for the two compounds, caffeic acid and 5-caffeoylquinic acid, possessing o-hydroxy groups. Caffeic acid was unusual in that dimer formation was the main initial product of reaction. Benzoic acids were readily oxidized by both systems, but no identifiable products were isolated. Oleuropein was oxidized by both oxidants used in this study, resulting in quinones in each system, whereas little or no oxidation of tyrosol was observed. This highlights the importance of conjugation between the alkene double bond and the hydroxy group. The results question the validity of many existing methods of testing antioxidant activity.
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PMID:LC-MS investigation of oxidation products of phenolic antioxidants. 1496 58

Polychlorinated biphenyls (PCBs) can be oxygenated to form very reactive hydroquinone and quinone products. A guiding hypothesis in the PCB research community is that some of the detrimental health effects of some PCBs are a consequence of these oxygenated forms undergoing one-electron oxidation or reduction, generating semiquinone radicals (SQ (*-)). These radicals can enter into a futile redox cycle resulting in the formation of reactive oxygen species, that is, superoxide and hydrogen peroxide. Here, we examine some of the properties and chemistry of these semiquinone free radicals. Using electron paramagnetic resonance (EPR) to detect SQ (*-) formation, we observed that (i) xanthine oxidase can reduce quinone PCBs to the corresponding SQ (*-); (ii) the heme-containing peroxidases (horseradish and lactoperoxidase) can oxidize hydroquinone PCBs to the corresponding SQ (*-); (iii) tyrosinase acting on PCB ortho-hydroquinones leads to the formation of SQ (*-); (iv) mixtures of PCB quinone and hydroquinone form SQ (*-) via a comproportionation reaction; (v) SQ (*-) are formed when hydroquinone-PCBs undergo autoxidation in high pH buffer (approximately >pH 8); and, surprisingly, (vi) quinone-PCBs in high pH buffer can also form SQ (*-); (vii) these observations along with EPR suggest that hydroxide anion can add to the quinone ring; (viii) H 2 O 2 in basic solution reacts rapidly with PCB-quinones; and (ix) at near-neutral pH SOD can catalyze the oxidization of PCB-hydroquinone to quinone, yielding H 2 O 2. However, using 5,5-dimethylpyrroline-1-oxide (DMPO) as a spin-trapping agent, we did not trap superoxide, indicating that generation of superoxide from SQ (*-) is not kinetically favorable. These observations demonstrate multiple routes for the formation of SQ (*-) from PCB-quinones and hydroquinones. Our data also point to futile redox cycling as being one mechanism by which oxygenated PCBs can lead to the formation of reactive oxygen species, but this is most efficient in the presence of SOD.
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PMID:Semiquinone radicals from oxygenated polychlorinated biphenyls: electron paramagnetic resonance studies. 1854 51


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