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Melanins, oxidative polymerization

Since the oxidative polymerization of phenols is the industrial process used to produce poly(phenyleneoxide)s (Scheme 4), the application of polymer catalysts may well be of interest. Furthermore, enzymic, oxidative polymerization of phenols is an important pathway in biosynthesis. For example, black pigment of animal kingdom "melanin" is the polymeric product of 2,6-dihydroxyindole which is the oxidative product of tyrosine, catalyzed by copper enzyme "tyrosinase". In plants "lignin" is the natural polymer of phenols, such as coniferyl alcohol 2 and sinapyl alcohol 3. Tyrosinase contains four Cu ions in cataly-tically active site which are considered to act cooperatively. These Cu ions are presumed to be surrounded by the non-polar apoprotein, and their reactivities in substitution and redox reactions are controlled by the environmental protein. [Pg.148]

Oxidative polymerization of phenol derivatives is also important pathway in vivo, and one example is the formation of melanin from tyrosine catalyzed by the Cu enzyme, tyrosinase. The pathway from tyrosine to melanin is described by Raper (7) and Mason (8) as Scheme 8 the oxygenation of tyrosine to 4-(3,4-dihydro-xyphenyl)-L-alanin (dopa), its subsequent oxidation to dopaqui-none, its oxidative cyclization to dopachrome and succeeding decarboxylation to 5,6-dihydroxyindole, and the oxidative coupling of the products leads to the melanin polymer. The oxidation of dopa to melanin was attempted here by using Cu as the catalyst. [Pg.158]

Peroxynitrite (ONOO ) is a cytoxic species that is considered to form nitric oxide (NO) and superoxide (Oj ) in biological systems (Beckman et al. 1990). The toxicity of this compound is attributed to its ability to oxidize, nitrate, and hydroxylate biomolecules. Tyrosine is nitrated to form 3-nitrotyrosine (Ramazanian et al. 1996). Phenylalanine is hydroxylated to yield o-, m-, and p-tyrosines. Cysteine is oxidized to give cystine (Radi et al. 1991a). Glutathione is converted to S-nitro- or S-nitroso derivatives (Balazy et al. 1998). Catecholamines are oxidatively polymerized to melanin (Daveu et al. 1997). Lipids are also oxidized (Radi 1991b) and DNA can be scissored by peroxynitrite (Szabo and Ohshima 1997). [Pg.259]

With tyrosinase, on the contrary, a two-electron oxidation occurs, as no EPR signal was detected in the catechol oxidation at pH 5.3 Melanins are polymerization products of tyrosine, whereby tyrosinase catalyses the first steps the formation of dopa (3,4-dihydroxyphenylalanine) and of dopaquinone, leading to an indolequi-none polymer The peroxidase mechanism for the conversion of tyrosine into dopa in melanogenesis was not substantiated In natural and synthetic melanins free radicals of a semiquinone type were detected by EPR 4-10 x 10 spins g of a hydrated suspension (the material was modified on drying and the number of free spins increased). The fairly symmetrical EPR signal had a g-value of 2.004 and a line-width of 4-10 G The melanins seem to be natural radical scavengers. [Pg.22]

Figure 2.21. Mechanisms of the oxidative polymerization of catechol to melanins (humic polymers) in the presence of tyrosinase or birnessite. Reprinted with permission from Naidja, A., Huang, P. M., Dec, J., and Bollag, J.-M. (1999). Kinetics of catechol oxidation catalyzed by tyrosinase or 8-Mn02. In Effect of Mineral-Organic-Microorganism Interactions on Soil and Freshwater Environments, Berthelin, J., Huang, P. M., Bollag, J.-M., and Andreux, F., eds., Kluwer Academic/Plenum Publishers, New York, 181-188. Figure 2.21. Mechanisms of the oxidative polymerization of catechol to melanins (humic polymers) in the presence of tyrosinase or birnessite. Reprinted with permission from Naidja, A., Huang, P. M., Dec, J., and Bollag, J.-M. (1999). Kinetics of catechol oxidation catalyzed by tyrosinase or 8-Mn02. In Effect of Mineral-Organic-Microorganism Interactions on Soil and Freshwater Environments, Berthelin, J., Huang, P. M., Bollag, J.-M., and Andreux, F., eds., Kluwer Academic/Plenum Publishers, New York, 181-188.
Oxidative coupling polymerization provides great utility for the synthesis of high-performance polymers. Oxidative polymerization is also observed in vivo as important biosynthetic processes that, when catalyzed by metalloenzymes, proceed smoothly under an air atmosphere at room temperature. For example, lignin, which composes 30% of wood tissue, is produced by the oxidative polymerization of coniferyl alcohol catalyzed by laccase, an enzyme containing a copper complex as a reactive center. Tyrosine is an a-amino acid and is oxidatively polymerized by tyrosinase (Cu enzyme) to melanin, the black pigment in animals. These reactions proceed efficiently at room temperature in the presence of 02 by means of catalysis by metalloenzymes. Oxidative polymerization is observed in vivo as an important biosynthetic process that proceeds efficiently by oxidases. [Pg.535]

Tyrosine is one of the important a-amino acids and is oxidatively polymerized with tyrosinase to melanin, the black pigment in animals [25-30], Melanin plays a role in the prevention of damage to the organism that occurs through the absorption of ultraviolet light. Melanin is the only major paramagnetic organic com-... [Pg.537]

Catechol melanin, a black pigment of plants, is a polymeric product formed by the oxidative polymerization of catechol. The formation route of catechol melanin (Eq. 5) is described as follows [33-37] At first, 3-(3, 4 -dihydroxyphe-nyl)-L-alanine (DOPA) is derived from tyrosine. It is oxidized to dopaquinone and forms dopachrome. 5,6-Dihydroxyindole is formed, accompanied by the elimination of C02. The oxidative coupling polymerization produces a melanin polymer whose primary structure contains 4,7-conjugated indole units, which exist as a three-dimensional irregular polymer similar to lignin. Multistep oxidation reactions and coupling reactions in the formation of catechol melanin are catalyzed by a copper enzyme such as tyrosinase. Tyrosinase is an oxidase con-... [Pg.538]

In that scheme, tyrosine is first oxidized to dopaquinone, the key intermediate for the formation of all melanins. If virtually no cysteine is present, then eumelanins are the primary products that arise through cychzation and oxidative polymerization, as described in the section on eumelanins. [Pg.185]

CioHgOj, Mr 160.17, colorless platelets, mp. 140°C. A pentaketide from which typical metabolites of asco-mycetes are formed by oxidative coupling and other transformations. This family includes, e.g., bulgar-ein, 4,9-dihydroxy-3,10-perylenedione, and hypoxy-lone. Oxidative polymerization of 1,8-N. leads to brown to black fungal melanins, e.g., in the fruit bodies of the tree fungus Daldinia concentrica. Simple derivatives of 1,8-N., namely the monomethyl ether (C, H o02, Mr 174.20, cryst., mp. 55-56°C) and the dimethyl ether (C,2H,202, Mr 188.23, platelets, mp. 158-161 °C) were isolated from cultures of D. concentrica. [Pg.421]

In the Raper-Mason scheme of melanin biosynthesis (Fig. 5) 216, 217), tyrosine is enzymatically converted via dopa to dopaquinone. The subsequent oxidation steps leading to melanin formation depend upon the biochemical environment of the reaction site. However, the melanization process in vitro or in vivo has two important features the rearrangement of dopachrome and the oxidative polymerization of 5,6-dihydroxyindoles leading to melanochrome. [Pg.158]

In several instances polymeric substances arise during the transformation of secondary products, such as polymeric carbohydrates (D 1.4.1), humic acid-like polyphenols (D 3.3.1), rubber (D 6), sporopoUenins (D 6.5), polymeric products derived from 3-hydroxyanthranilic acid (D 8.4.1), melanins (D 22.1.3), lignins (D 22.2.3), and muramin (D 23.4). Many of these compounds are formed by oxidative polymerization catalyzed by phenoloxidases (C 2.3.1) and peroxidase... [Pg.63]

It is interesting to underline that there is another (plant) enzyme which possesses a coordinatively similar dicopper environment catechol oxidase.11 As already mentioned in Chapter 6, Section 3, such an ubiquitous enzyme catalyses the two-electron oxidation by molecular dioxygen of catechols to the corresponding quinones (the so-generated quinones in turn polymerize to form brown polyphenolic catechol melanins, which protect damaged plants from pathogens or insects). [Pg.451]

The non-oxidative formation of melanin from adrenochrome in acid solution, reported by Harley-Mason,6 has recently been shown by Bu Lock to be controlled by a second-order reaction between adrenochrome and acid.107 It was suggested that the initial product (not isolated) was probably l-methylindole-5,6-quinone, which polymerized rapidly to melanin via dimers and oligomers.107 (The intermediate monomer quinone also gave a melanin-like copolymer with indole.107)... [Pg.276]

Kinetically slow steps in the formation of melanin from DOPA are the formation of dopaquinone from DOPA (step 1, kD), the reaction of dopachrome to dihydroxyindole (step 2), and the polymerization to form melanin (step 3, kM). Step 1 and step 2 proceed with about the same rate in the oxidative coupling polymerization catalyzed by tyrosinase. However, step 1 becomes remarkably slow when a macromolecule-metal complex is used as a catalyst. The copper complex in poly(l-vinylimidazole-co-vinylpyrrolidone) has been found [38] to act as an excellent catalyst and to exhibit the highest activity for melanin formation. The ratio of the rate constants ( m/ d) is approximately 3 (tyrosinase... [Pg.539]

Melanin granules are secreted by melanocytes in the hair papilla and distributed to keratin in the hair cortex and inner layers of the hair sheath during normal development. Melanogenesis is subject to hormonal control and has been the focus of intensive genetic studies. Two main forms of melanin exist in human skin—eumelanin and phaeomelanin, both of which are derived from tyrosine through the action of tyrosinase (a cupro-enzyme) and possibly other key enzymes (with nickel, chromium, iron, and manganese as cofactors). Tyrosine is converted to dihydroxyphenylalanine and, via a series of intermediate steps, to indole-5,6-quinone, which polymerizes to eumelanin. Phaeomelanins are produced by a similar mechanism but with the incorporation of sulfur (as cysteine) by a nonenzymatic step in the oxidation process. [Pg.186]

Enzymes present in melanosomes synthesize two types of melanin, eumelanin and pheomelanin. Figure 2 illustrates the proposed biosynthetic pathways of eumelanin and pheomelanin. The synthesis of eumelanin requires tyrosinase, an enzyme located in melanosomes. Tyrosinase catalyzes the conversion of tyrosine to dopa, which is further oxidized to dopaquinone. Through a series of enzymatic and nonenzymatic reactions, dopaquinone is converted to 5,6-indole quinone and then to eumelanin, a polymer. This polymer is always found attached to proteins in mammalian tissues, although the specific linkage site between proteins and polymers is unknown. Polymers affixed to protein constitute eumelanin, but the exact molecular structure of this complex has not been elucidated. Pheomelanin is also synthesized in melanosomes. The initial steps in pheomelanin synthesis parallel eumelanin synthesis, since tyrosinase and tyrosine are required to produce dopaquinone. Dopaquinone then combines with cysteine to form cysteinyldopa, which is oxidized and polymerized to pheomelanin. The exact molecular structure of pheomelanin also has not been determined. [Pg.73]

Ty initiates melanin synthesis by the hydroxylation of L-tyrosine to 3,4-dihydroxyphenylalanine (Dopa) and the oxidation of dopa to dopaquinone. In the presence of L-cysteine, dopaquinone rapidly combines with the thiol group to form cysteinyldopas, which undergo nonen-zymatic conversion and polymerization to pheomelanin via benzothiazine intermediates. In the absence of thiol groups, dopaquinone very rapidly undergoes conversion to dopachrome, which is transformed to 5,6-dihydroxyindole-2-carboxylic acid (DHICA) by dopachrome tautomerase. Alternatively, dopachrome is converted nonenzymatically to 5,6-dihydroxyindole (DHI). Oxidation of DHICA and DHI to the corresponding quinones and subsequent polymerization leads to eumelanins. It is still questionable if Ty is involved in this step. [Pg.983]

The distinguishing feature of tyrosinase is that it catalyzes the oxidation of monohydric phenols, like tyrosine, to the dihydric form and dihydric phenols, like DOPA and catechol, to the corresponding quinones. The striking biological effects of this enzyme arise from quinones which polymerize to produce the darkening of various plants on injury and melanin in mammals. The relative oxidation rates of several dihydric phenols by tyrosinase are given in Table III. [Pg.289]

Melanins, which are pigments in skin and hair, are formed by polymerization of oxidation products (quinones) of dopa. [Pg.256]

See other pages where Melanins, oxidative polymerization is mentioned: [Pg.88]    [Pg.145]    [Pg.169]    [Pg.1136]    [Pg.161]    [Pg.911]    [Pg.254]    [Pg.21]    [Pg.30]    [Pg.175]    [Pg.383]    [Pg.1716]    [Pg.115]    [Pg.160]    [Pg.276]    [Pg.70]    [Pg.257]    [Pg.104]    [Pg.279]    [Pg.210]    [Pg.244]    [Pg.244]    [Pg.71]    [Pg.590]    [Pg.694]    [Pg.974]    [Pg.234]    [Pg.244]    [Pg.155]   
See also in sourсe #XX -- [ Pg.88 ]



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