PHOTOCHEMISTRY OF MELANIN PRECURSORS: DOPA, 5-S-CYSTEINYLDOPA AND 2,5-S,S'-DICYSTEINYLDOPA

The photochemistries of the melanin precursors dopa, 5-S-cysteinyldopa (5-SCD) and 2.5-S,S'-dicysteinyldopa (2.5-SCD) were investigated by 265-nm laser flash photolysis. The quantum yield of hydrated electron following flash photolysis of dopa (9.1%) was half the yield of dopasemiquinone (19.6%), implying that dopasemiquinone is formed via two primary photochemical mechanisms: photionisation (giving e) or photohomolysis (giving H^˙). Dopasemiquinone rapidly disproportionates to form dopaquinone and re-form dopa. Dopaquinone in turn decays via a base-catalysed unimolecular cyclisation eventually to form dopachrome. Assignment of the transient species was confirmed by previous pulse radiolysis studies of the one-electron oxidation of dopa. In contrast, flash photolysis of the cysteinyldopas, 5-SCD and 2,5-SCD results in lower photoionisation quantum yields and the production of initial transient species whose absorption spectra were markedly different from their semiquinone absorption spectra previously determined pulse radiolytically. These observations indicate that the primary cysteinyldopa photochemical species is not such a semiquinone, but rather results from S-CH₂ bond photohomolysis. Absorption spectra and rate constants for the formation and decay of various transient species are reported.     

PHEOMELANIN PHOTOCHEMISTRY. PHOTOLYSIS OF MODEL COMPOUNDS

Abstract— Phytochrome control of nitrate reductase activity has been studied in cotyledons and hypocotyls of light-grown Sinapis alba. Under polychromatic irradiation, an increase in the fluence rate of far-red light added to a constant source of photosynthetically active radiation causes a decrease in the phytochrome photoequilibrium and, in the hypocotyl, this results in decreased nitrate reductase activity. However, in the cotyledons this difference is only observed transiently. In both organs, enzyme activity is correlated with the level of the far-red light absorbing form of phytochrome, P_fr. These correlations are not altered when the fluence rate (with respect to phytochrome) is increased, suggesting that the responses are not fluence rate dependent. The results obtained are consistent with the notion that in fully de-etiolated seedlings, P_ft alone controls nitrate reductase activity.     

Photochemistry and photobiology of melanogenic metabolites: formation of free radicals

Normal melanocytes produce specialized subcellular organelles called melanosomes within which the biochemical processes of melanogenesis occurs. During sunlight-induced melanogenesis, the melanocyte-specific enzyme tyrosinase catalyzes the oxidative polymerization of 3,4-dihydroxyphenyl-alanine (DOPA) to melanin. Nucleophilic addition of cysteine to tyrosinase-generated dopaquinone leads to the formation of cysteinyldopas, precursors of pheomelanin and excreted by-products of eumelanogenesis. Under conditions of low sulfhydryl content, dopaquinone undergoes a 1,4 intramolecular cycloaddition to yield, after further oxidation, 5,6-dihydroxyindoles and/or 5,6-dihydroxy-2-carboxyindoles. These indolic melanogenic intermediates and their O-methylated metabolites, like cysteinyldopas, are excreted by actively pigmenting as well as dormant melanocytes. Indeed, it has been determined that in humans, the serum and urine concentrations of these melanogenic metabolites increase dramatically following exposure to sunlight, UVA (315-400 nm), UVB (290-315 nm) exposure, as well as during PUVA therapy and in melanoma patients, and thus have proved to be excellent biochemical markers of normal and pathological melanocyte function. While controlled light exposure or PUVA therapy generally lead to 100-300% increases in 5-S-cysteinyldopa (5SCD) and 5-methoxy-6-hydroxyindole-2-carboxylic acid (6HMICA) serum levels (normal concentration about 4–16 nmol l^-1), the local concentrations in the skin and especially in the actively pigmenting melanocyte may be as high as 200 μM. Evidence is presented to document that a number of catecholic melanin precursors, including cysteinyldopas and dihydroxyindoles, are photochemically unstable in the presence of biologically relevant ultraviolet radiation (i.e. wavelengths ± 300 nm). Initial photochemical processes involve free radical production; continued photolysis yields polymeric photoproducts. Radicals produced during melanogenic metabolite photolysis have been identified by ESR spin trapping, laser flash photolysis and pulse radiolysis techniques and include hydrated electrons (e_aq), hydrogen atoms (H'), hydroxyl radicals (OH), semiquinones, aryl thiyl (ArS), and alanyl carbon-based radicals. In vitro investigations of the potential photobiological significance of these reactions have demonstrated photolysis of cysteinyldopas may lead to photoinitiated DNA binding and single strand break induction. The above mentioned radical species may also damage proteins and initiate lipid peroxidation. Definitive evidence for the occurrence of these phototoxic reactions in vivo is currently unavailable, however our in vitro studies suggest a possible role for melanogenic metabolite photolysis in acute and chronic solar responses of human skin.     

PHOTODESTRUCTION OF PHAEOMELANIN

Abstract. Phaeomelanin readily decomposes by the action of UV light and oxygen. This finding may explain many of the abnormal reactions of the skin of redheads and blondes to sunlight, including their high susceptibility to skin cancer. In aqueous solution, phaeomelanin displays an EPR signal rich in hyperfine splitting, consistent with structural information.  

SUMMARY

Phaeomelanin readily, decomposes by the action of UV light and oxygen. This finding may explain many of the abnormal reactions of the skin of redheads and blondes to sunlight, including their high susceptibility to skin cancer. We have yet to identify any of the fragmentation products. Chromatographic analysis of the photolysate indicates at least 17 different compounds. Work on the reactions of phaeomelanin with superoxide, and the identification, synthesis, and physiological evaluation of these photoproducts as etiological factors in sunburn and carcinogenesis is in progress. In aqueous solutions, phaeomelanin displays an air stable EPR signal rich in hyperfine splitting. Complete analysis of this signal will provide a better understanding of the structure of the pigment.     

Photoprotection by melanin

This paper is an attempt to summarize the current state of information on melanin and epidermal melanin pigmentation (EMP) as photoprotective agents. The chemistry and biochemistry of melanin (the particle) and its interaction, in its various forms, with UV radiation are considered. Methods of attenuation of UV radiation are discussed in terms of structure and chemical constituents. Photoprotection by constitutive and facultative pigmentation is reviewed with minimum erythema dose (MED) as the end point. The issue of acclimatization to UV radiation is discussed in terms of UVB phototherapy for psoriasis. Finally, skin cancer is considered as an end point and the reduction of its incidence with pigment level is discussed. It is concluded that whilst EMP provides protection, its extent depends on the end point chosen for evaluation. MED is a convenient photobiological end point but is rather insensitive, whereas skin cancer is sensitive but impractical for laboratory studies. Our current state of knowledge of melanin lacks information on its absorption and scattering coefficients and its refractive index. Methods for the quantitative measurement of EMP are also urgently required.     

PHOTOCHEMISTRY OF PHEOMELANIN: ACTION SPECTRUM FOR SUPEROXIDE PRODUCTION

Abstract— The action spectrum for superoxide production from aerated aqueous solutions of pheomela-nin was determined by utilizing the nitroblue tetrazolium-superoxide dismutase assay for superoxide. Superoxide production was greatest in the UVC regions, but continued well into the visible wavelengths. The marked increase in superoxide production noted in the UVC-UVB regions of the spectrum suggests that superoxide production may be involved in a number of actinic disorders in fair-skinned humans.     

SPIN TRAPPING OF THE SUPEROXIDE RADICAL BY 4-(N-METHYLPYRIDINIUM) t-BUTYL NITRONE

The synthesis of 4-(N-methylpyridinium) t-butyl nitrone (4-MePyBN) and its use as a spin trap for superoxide radicals produced in aqueous solutions is reported (a^N= 13.78 G, a^H_ß= 1.65 G, and g = 2.0091). The half-life of the spin adduct as a function of pH (83 s at pH 5.5, 78 s at pH 7.0, and 65 s at pH 8.0) the effects of iron salts, diethylenetriaminepentacetic acid (DETAPAC), and superoxide dismutase were examined, and comparisons made between 4-MePyBN and 5,5-dimethyl-1-pyrroline-N-oxide (DMPO) as spin trapping agents for the superoxide radical.     

PHOTODEGRADATION OF PHAEOMELANIN: AN IN VITRO MODEL

Abstract— A new in vitro model system for studying the photochemistry and photobiology of melanins in epidermal tissue has been developed. The photochemistry of phaeomelanin in this model system follows the same course as in pH 8.0 aqueous buffered solutions, i.e. photodegradation accompanied by production of superoxide radicals. These photoreactions may be effectively quenched by application of a broad spectrum sunscreen prior to irradiation.