5.6- Dihydroxyindoles oxidation

A more detailed discussion of the evidence supporting the involvement of 5,6-indolequinones in 5,6-dihydroxyindole oxidation will be presented in Section V. The following discussion will be limited to listing the main oligomeric products... 

Dihydroxyindole blocking factor blocks the indolization of quinone imine derivatives. Dihydroxyindole conversion factor catalyzes the dehydrogenation of 5,6-dihydroxyindole to indole-5,6-qui-none. Dopachrome oxidoreductase converts dopachrome to 5,6-dihydroxyindole and also may block 5,6-dihydroxyindole oxidation and subsequent melanogenic reactions. Relatively little information is available about the physical, chemical and kinetic properties of these proteinaceous factors in mammals. Controversy about melanin-related regulatory factors has focused on whether activity is due to unique individual proteins or is only an expression of activities of a multicatalytic enzyme (61.62). For example, dihydroxyindole conversion activity in mice melanoma is apparently due to tyrosinase, not a unique factor (56). 

Such results seem to be rather indicative of the opportunity to exploit TD-DFT and the PBEO functional in predicting spectroscopic properties of mixtures containing the three tautomers 1-Q, 1-QM, and 1-QI in aqueous solution. This approach should be very useful for future experimental mechanistic investigations clarifying the complex mechanisms of dihydroxyindole oxidation. 

Melanin Drying. One development (ca 1993) in hair coloring involves the formation of pigments within the hair that are very similar to natural melanin. Thus either catalytic or air oxidation of 5,6-dihydroxyindole [3131-52-0] can be effectively used to permanently dye hair within a short time (38). The formed color can, if required, be further modulated with dilute H2O2 or can be even totally removed from hair by this oxidant. 

Melanin biosynthesis in animals is a complex process starting with the L-tyrosine amino acid. In the first step, L-tyrosine is converted first into DOPA and then into dopaquinone, a process catalyzed by tyrosinase. In the biosynthesis of eumelanins, dopaquinone undergoes a cyclization to form dopachrome and subsequently a tau-tomerization into 5,6-dihydroxyindole-2-carboxylic acid (DHICA). DHICA is further oxidized to indole-5,6-quinone2-carboxylic acid, the precnrsor of DHICA eumelanins. Tyrosinase-related proteins TRP-2 and TRP-1, respectively, are responsible for the last two steps, and they are under the control of the tyrosinase promoter. 

The oxidative polymerization of 5,6-dihydroxyindole (1) and related tyrosine-derived metabolites is a central, most elusive process in the biosynthesis of eumelanins, which are the characteristic pigments responsible for the dark color of human skin, hair, and eyes. Despite the intense experimental research for more than a century,36 the eumelanin structure remains uncharacterized because of the lack of defined physicochemical properties and the low solubility, which often prevents successful investigations by modem spectroscopic techniques. The starting step of the oxidative process is a one-electron oxidation of 5,6-dihydroxyindole generating the semiquinone 1-SQ (Scheme 2.7). 

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. 

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. 

A. Pezzella, D. Vogna and G. Prota, Synthesis of optically active tetrameric intermediates by oxidation of the melanogenic procursor 5,6-dihydroxyindole-2-carboxilic acid under bio-mimetic conditions. Tetrahedron Assymetry 14 (2003) 1133-1140. 

The structurally related diindolocarbazoles are produced as a mixture of isomers in moderate yields by the ammonium persulfate-mediated oxidation of 5,6-dihydroxyindoles in aqueous acidic media <1998JOC7002>. 

In 1927 Raper showed that the red pigment obtained on oxidation of DOPA [i.e. 2,3-dihydroindole-5,6-quinone-2-carboxylic acid, dopachrome (4)] rearranged spontaneously by an autoreduction process in vacuo to 5,6-dihydroxyindole (29).72 The rearrangement process could be accelerated by the action of alkali or sulfur dioxide.72 In the latter case, decarboxylation did not accompany the rearrangement and the colorless derivative was 5,6-dihydroxyindole-2-carboxylic acid (17).72 Compounds 17 and 29 were isolated as their dimethyl ethers, (30A) and (30B).72 Immediate decolorization of epinochrome (27) solutions on addition of alkali was reported a few years later.134... 

Subsequent investigations have shown that Raper s suggestion that dopachrome (4) and related aminochromes decompose by an internal oxidation-reduction process forming 5,6-dihydroxyindoles was essentially correct.73,118,120,184-137 The 5,6-dihydroxyindoles obtained from aminochromes such as dopachrome (4) and epino-chrome (27) (i.e. with no substitution in the 3-position) show only a relatively weak blue to blue-mauve fluorescence.118,120 The intense yellow-green fluorescence shown by the rearrangement products of aminochromes with a 3-hydroxyl group is due to the formation of... 

Dihydroxyindole and 5,6-dihydroxyindole-2-carboxylic acid were shown to form after the red pigment stage that occurred during the conversion of DOPA into a melanin, by Raper, who isolated these compounds as their dimethyl ethers.72 The presence of 5,6-dihydroxyindoles in solutions of DOPA, dopamine, and noradrenaline which are undergoing oxidation has subsequently been confirmed by paper and thin-layer chromatography.118,120,222 5,6-Dihydroxyin-dole and 5,6-dihydroxyindole-2-carboxylic acid have recently been isolated from the alkali fusion products of sepiomelanin, indicating... 

Assay procedures for dopamine which are superficially similar to the lutin procedure described above have been reported recently.266-268 The chemistry of the production of the fluorophore from dopamine is, however, somewhat different since the fluorophore is not a 5,6-dihydroxyindoxyl, it is incorrect to refer to the trihy-droxyindole fluorophore of dopamine (cf. ref. 252). Oxidation of the extracted catecholamine is usually carried out with iodine,266-268 presumably with the formation of 7-iodonorepinochrome. The aminochrome is subsequently rearranged to 5,6-dihydroxyindole (it is probable that deiodination accompanies the rearrangement in this case) by a solution of sodium sulfite in aqueous alkali the solution is acidified before measuring the fluorescence of the product (which is said to form relatively slowly and to be very stable).266-268 Irradiation of the reaction mixture with ultraviolet light accelerates the maximal development of fluorescence.266 Since acidification will produce sodium bisulfite in the reaction mixture, it is probable that the fluorophore is a 5,6-dihydroxyindole-sodium bisulfite addition complex. Complexes of this type are known to be both fluorescent and relatively stable in dilute acid solution.118 123,156 265 They also form relatively slowly.255... 

Harley-Mason has shown that 5,6-dihydroxyindole (29) can also be obtained from /9-(2,4,5-trihydroxyphenyl)ethylamine (101). Oxidation of 101 with potassium ferricyanide, buffered with sodium bicarbonate, gives a deep red solution [presumably containing norepinochrome (106)] from which 29 was obtained, after the solution had been allowed to stand under hydrogen for 24 hours.281... 

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-... 

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... 

High-energy irradiation of aqueous solutions of 5,6-dihydroxyindole (136) in the presence of azide ions yields the oxidized product (137) in equilibrium with the quinone (138). Reaction of the quinone (138) with azide leads to the trapped product (139) and subsequently to 6,7-dihydroxy-l,2,3-triazolo[4,5-6]indole (140). It appears that the driving force for this reaction (138)->(140) is the electrocyclic ring closure as the quinone (138) is unreactive towards other nucleophiles (Scheme 11) <92TL3045>. 

Synthetic melanic compounds can also be prepared by peroxidase oxidation of dihydroxyindoles. Similarly to phenol oxidation, the reaction proceeds through radical coupling, and the product distribution agrees with the radical delocalization in the semiquinone [47] (Fig. 6.3d). 

Alessandro Pezzella received his Ph.D. in 1997 under the direction of Prof. G. Prota at Naples University Federico II. Since 1999 he holds a permament position as researcher in the Department of Organic Chemistry and Biochemistry of Naples University. He has carried out research mainly in the field of 5,6-dihydroxyindole polymerization and oxidative behavior of phenolic compounds. 

A conducting, polymeric film of poly(indole-5-carboxylic acid) has been employed for covalent immobilization of tyrosinase, which retains catalytic activity and catalyzes oxidation of catechol to the quinone <2006MI41>. Poly(l-vinylpyrrole), polyfl-vinylindole), and some methyl-substituted compounds of poly(l-vinylindole) are of potential interest as photorefractive materials with a relatively low glass-transition temperature and requiring a lower quantity of plasticizer in the final photorefractive blend <2001MI253>. Polymers of 5,6-dihydroxyindoles fall within the peculiar class of pigments known as eumelanins and their chemistry has been reviewed <2005AHC(89)1>. 

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. 

Natural melanins are generally differentiated by their origin, e.g., bovine eye, melanoma, sepia melanin. They usually occur in the form of granular particles, the melanosomes, and are secretory products of pigment-producing cells, the melanocytes. Synthetic melanins are named after the compound from which they were prepared via chemical or enzymatic oxidation (e.g., (/./-dopa, 5,6-dihydroxyindole, catechol melanin). 

---