Functional Properties of Cloned Melanogenic Proteins

Several genes critical to the regulation of melanin production in mammals have recently been cloned and characterized. They map to the albino, brown, and slaty loci in mice, and encode proteins with similar structures and features, but with distinct catalytic capacities. The albino locus encodes tyrosinase, an enzyme with three distinct catalytic activities—tyrosine hydroxylase, 3,4-dihydroxyphenylalanine (DOPA) oxidase and DHI (5,6-dihydroxyindole) oxidase. The brown locus encodes TRP-l (tyrosinase-related protein-I), which has the same, but greatly reduced, catalytic potential. The slaty locus encodes TRP-2, another tyrosinase related-protein, which has DOPAchrome tautomerase activity. In this study we have examined the enzymatic interactions of these proteins, and their regulation by a novel melanogenic inhibitor. We observed that tyrosinase activity is more stable in the presence of TRP-l and/or TRP-2, but that the catalytic function of TRP-2 is not affected by the presence of TRP-1 or tyrosinase. Other factors also may influence melanogenesis and a unique melanogenic inhibitor suppresses tyrosinase and DOPAchrome tautomerase activities, but does not affect the spontaneous rate of DOPAchrome decarboxylation to DHI. The results demonstrate the catalytic functions of these proteins and how they stably interact within a melanogenic complex in the melanosome to regulate the quantity and quality of melanin synthesized by the melanocyte.     

Cyclic Oscillations in Melanin Composition within Hairs of Baboons

The wild‐type agouti‐banding pattern for hair is well characterized in lower mammals such as mice. The switch between eumelanin and pheomelanin in bands in the hair results from the interaction of α‐melanocyte stimulating hormone and agouti signal protein through the melanocortin 1 receptor on melanocytes. However, such banding patterns have not been described to date in higher mammals. We now report such ‘agouti’‐banding patterns that occur in several subspecies of baboons, and characterize those hairs using chemical and immunohistochemical methods. Hair and skin samples were obtained from the dorsa of adult male baboons of different subspecies (Papio cynocephalus hamadryas (PCH) and Papio cynocephalus anubis (PCA)). The hairs were excised with scissors into the gray and the white bands of the PCH subspecies and into the black and the yellow bands of the PCA subspecies, and were analyzed for total melanin, eumelanin, and pheomelanin by spectrophotometric and chemical methods. Hairs in the PCA subspecies oscillate between a eumelanic band (with high melanin content) and a pheomelanic band, while hairs in the PCH subspecies oscillate between a eumelanic band (with low melanin content) and a non‐pigmented band. Those chemical data are consistent with the histological appearance of the hair bulbs stained by the Fontana‐Masson technique. The difference in the melanin content between PCH and PCA subspecies is most likely related to tyrosinase levels, as suggested by the presence of unpigmented muzzle in the PCH subspecies compared with the black muzzle in the PCA subspecies.     

The mouse pink-eyed dilution allele of the P-gene greatly inhibits eumelanin but not pheomelanin synthesis

The mouse pink-eyed dilution (p) locus is known to control eumelanin synthesis, melanosome morphology, and tyrosinase activity in melanocytes. However, it has not been fully determined whether the mutant allele, p affects pheomelanin synthesis. Effects of the p allele on eumelanin and phemelanin synthesis were investigated by chemical analysis of dorsal hairs of 5-week-old mice obtained from the F(2) generations (black, pink-eyed black, recessive yellow, pink-eyed recessive yellow, agouti, and pink-eyed agouti) between C57BL/10JHir (B10)-congenic pink-eyed black mice (B10-p/p) and recessive yellow (B10-Mc1r(e)/Mc1r(e)) or agouti (B10-A/A) mice. The eumelanin content was dramatically (>20-fold) decreased in pink-eyed black and pink-eyed agouti mice, whereas the pheomelanin content did not decrease in pink-eyed black, pink-eyed recessive yellow, or pink-eyed agouti mice compared to the corresponding P/- mice. These results suggest that the pink-eyed dilution allele greatly inhibits eumelanin synthesis, but not pheomelanin synthesis.     

Interaction of major coat color gene functions in mice as studied by chemical analysis of eumelanin and pheomelanin

Melanocytes produce two chemically distinct types of melanin pigments, eumelanin and pheomelanin. These pigments can be quantitatively analyzed by acidic permanganate oxidation or reductive hydrolysis with hydriodic acid to form pyrrole-2,3,5-tricarboxylic acid or aminohydroxyphenylalanine, respectively. About 30 coat color genes in mice have been cloned, and functions of many of those genes have been elucidated. However, little is known about the interacting functions of these loci. In this study, we used congenic mice to eliminate genetic variability, and analyzed eumelanin and pheomelanin contents of hairs from mice mutant at one or more of the major pigment loci, i.e., the albino (C) locus that encodes tyrosinase, the slaty (Slt) locus that encodes tyrosinase-related protein 2 (TRP2 also known as dopachrome tautomerase, DCT), the brown (B) locus that encodes TRP1, the silver (Si) locus that encodes a melanosomal silver protein, the agouti (A) locus that encodes agouti signaling protein (ASP), the extension (E) locus that encodes melanocortin-1 receptor, and the mahogany (Mg) locus that encodes attractin. We also measured total melanin contents after solubilization of hairs in hot Soluene-350 plus water. Hairs were shaved from 2-3-month-old congenic C57BL/6J mice. The chinchilla (c(ch)) allele is known to encode tyrosinase, whose activity is about one third that of wild type (C). Phenotypes of chinchilla (c(ch)/c(ch)) mice that are wild type or mutant at the brown and/or slaty, loci indicate that functioning TRP2 and TRP1 are necessary, in addition to high levels of tyrosinase, for a full production of eumelanin. The chinchilla allele was found to reduce the amount of pheomelanin in lethal yellow and recessive yellow mice to less than one fifth of that in congenic yellow mice that were wild type at the albino locus. This indicates that reduction in tyrosinase activity affects pheomelanogenesis more profoundly compared with eumelanogenesis. Hairs homozygous for mutation at the slaty locus contain 5,6-dihydroxyindole-2-carboxylic acid (DHICA)-poor melanin, and this chemical phenotype was retained in hairs that were mutant at both the brown locus and the slaty locus. Hair from mice mutant at the brown locus, but not at the slaty locus, do not contain DHICA-poor melanin. This indicates that the proportion of DHICA in eumelanin is determined by TRP2, but not by TRP1. Mutation at the slaty locus (Slt(lt)) was found to have no effect on pheomelanogenesis, supporting a role of TRP2 only in eumelanogenesis. The mutation at silver (si) locus showed an effect similar to brown, a partial suppression of eumelanogenesis. The mutation at mahogany (mg) locus partially suppressed the effect of lethal yellow (Ay) on pheomelanogenesis, supporting a role of mahogany in interfering with agouti signaling. These results show that combination of double mutation study of congenic mice with chemical analysis of melanins is useful in evaluating the interaction of pigment gene functions.     

Excess tyrosine stimulates eumelanin and pheomelanin synthesis in cultured slaty melanocytes from neonatal mouse epidermis

The mouse slaty (Dct(slt)) mutation is known to reduce the activity of dopachrome tautomerase (DCT). The reduced DCT activity inhibits melanosome maturation and reduces the melanin content in the skin, hair and eyes. It is not known whether eumelanin and pheomelanin synthesis in slaty melanocytes is modulated by melanogenic factors. In this study, to address this point, epidermal melanocytes derived from 0.5-, 3.5- and 7.5-day-old wild-type mice (Dct(+)/Dct(+) at the slaty locus) and from congenic mice mutant (Dct(slt) /Dct(slt) at that locus) were cultured in serum-free primary culture with or without additional L-tyrosine (Tyr). The content of melanin was measured by high-performance liquid chromatography in the cultured melanocytes as well as culture supernatants in serum-free primary culture. L-Tyr was found to increase the content of pheomelanin in addition to eumelanin in cultured slaty melanocytes and cuture supernatants at all ages tested. The eumelanin and pheomelanin contents in culture supernatants were greater than in cultured melanocytes. The eumelanin and pheomelanin contents in culture supernatants from 7.5-day-old slaty melanocytes in the presence of L-Tyr were greater than those from wild-type melanocytes. These results suggest that the inhibition of eumelanin synthesis by the slaty mutation can be partly restored by the addition of excess L-Tyr. Eumelanin and pheomelanin may accumulate with difficulty in slaty melanocytes and be easily released from them during skin development. L-Tyr may stimulate this release.     

Eumelanin levels in rufous feathers explain plasma testosterone levels and survival in swallows

Pigment‐based plumage coloration and its physiological properties have attracted many researchers to explain the evolution of such ornamental traits. These studies, however, assume the functional importance of the predominant pigment while ignoring that of other minor pigments, and few studies have focused on the composition of these pigments. Using the pheomelanin‐based plumage in two swallow species, we studied the allocation of two pigments (the predominant pigment, pheomelanin, and the minor pigment, eumelanin) in relation to physiological properties and viability in populations under a natural and sexual selection. This is indispensable for studying the evolution of pheomelanin‐based plumage coloration. Pheomelanin and eumelanin share the same pathway only during their initial stages of development, which can be a key to unravel the functional importance of pigment allocation and thus of plumage coloration. Using the barn swallow, Hirundo rustica, a migratory species, we found that plasma testosterone levels increased with increasing the proportion of eumelanin pigments compared with pheomelanin pigments, but not with the amount of pheomelanin pigments, during the mating period. In the Pacific swallow Hirundo tahitica, a nonmigratory congener, we found that, during severe winter weathers, survivors had a proportionally smaller amount of eumelanin pigments compared with pheomelanin pigments than that in nonsurvivors, but no detectable difference was found in the pheomelanin pigmentation itself. These results indicated that a minor pigment, eumelanin, matters at least in some physiological measures and viability. Because the major pigment, pheomelanin, has its own physiological properties, a combination of major and minor pigments provides multiple information to the signal receivers, potentially enhancing the signaling function of pheomelanic coloration and its diversification across habitats.     

Cyclic oscillations in melanin composition within hairs of baboons.

The wild-type agouti-banding pattern for hair is well characterized in lower mammals such as mice. The switch between eumelanin and pheomelanin in bands in the hair results from the interaction of alpha-melanocyte stimulating hormone and agouti signal protein through the melanocortin 1 receptor on melanocytes. However, such banding patterns have not been described to date in higher mammals. We now report such 'agouti'-banding patterns that occur in several subspecies of baboons, and characterize those hairs using chemical and immunohistochemical methods. Hair and skin samples were obtained from the dorsa of adult male baboons of different subspecies (Papio cynocephalus hamadryas (PCH) and Papio cynocephalus anubis (PCA)). The hairs were excised with scissors into the gray and the white bands of the PCH subspecies and into the black and the yellow bands of the PCA subspecies, and were analyzed for total melanin, eumelanin, and pheomelanin by spectrophotometric and chemical methods. Hairs in the PCA subspecies oscillate between a eumelanic band (with high melanin content) and a pheomelanic band, while hairs in the PCH subspecies oscillate between a eumelanic band (with low melanin content) and a non-pigmented band. Those chemical data are consistent with the histological appearance of the hair bulbs stained by the Fontana-Masson technique. The difference in the melanin content between PCH and PCA subspecies is most likely related to tyrosinase levels, as suggested by the presence of unpigmented muzzle in the PCH subspecies compared with the black muzzle in the PCA subspecies.     

Acid hydrolysis reveals a low but constant level of pheomelanin in human black to brown hair

We previously reported a constant ratio of the benzothiazole pheomelanin marker thiazole‐2,4,5‐tricarboxylic acid (TTCA) to the eumelanin marker pyrrole‐2,3,5‐tricarboxylic acid (PTCA) in eumelanic, black human hair. A constant level (20%–25%) of benzothiazole‐type pheomelanin was recently demonstrated in human skin with varying concentrations of melanin. Therefore, in this study, we aimed to investigate the origin of pheomelanin markers in black to brown human hair by developing a method to remove protein components from hair by heating with 6 M HCl at 110°C for 16 hr. For comparison, synthetic melanins were prepared by oxidizing mixtures of varying ratios of dopa and cysteine with tyrosinase. Hair melanins and synthetic melanins were subjected to acid hydrolysis followed by alkaline H₂O₂ oxidation. The results show that the hydrolysis leads to decarboxylation of the 5,6‐di‐hydroxyindole‐2‐carboxylic acid moiety in eumelanin and the benzothiazole moiety in pheomelanin and that eumelanic human hair contains 11%–17% benzothiazole‐type pheomelanin.     

Genetic Regulation of Melanocyte Differentiation

Melanocytes originate from the neural crest in vertebrates and migrate to the body surface where they differentiate into functional cells. Genes involved in melanocyte differentiation can be classified into two groups. One of them consists of the functional genes that control proteins specific to the function of the melanocyte. As the representative gene of this category, albino (c) locus in the mouse is considered to control tyrosinase, the key enzyme in melanogenesis. cDNA for mouse tyrosinase has been cloned and sequenced. The cDNA can be used to detect tyrosinase mRNA synthesized during melanocyte differentiation. On the other hand, genes such as brown (b) or pink-eyed dilution (p) have been assumed to control melanosome proteins. The other category consists of genes that regulate the expression of these functional genes directly or indirectly. In the mouse, so-called white-spotting genes and genes of the agouti series are considered to fall into this category. Based on the fact that mutations at the white-spotting loci result in the absence of melanocytes in a particular area of skin, it is assumed that some of these loci control the factors that promote either differentiation or migration of melanoblasts and are candidates for the classic regulator genes Genes at the agouti (a) locus in the mouse determine the type of melanin synthesized in hair follicle melanocytes, that is eumelanin or pheomelanin. An interesting feature of this locus is that the site of gene action is not within the melanocytes but in the cells surrounding them. The results of our study indicate that the gene product of the a-locus interacts with α-MSH at the α-MSH receptor site, regulates the cellular cAMP level via a signal transduction system and, in turn, determines the type of melanin synthesized in the cells.     

The mouse ruby‐eye 2d (ru2d/Hps5ru2‐d) allele inhibits eumelanin but not pheomelanin synthesis

The novel mutation named ru2^d/Hps5^ru2‐d, characterized by light‐colored coats and ruby‐eyes, prohibits differentiation of melanocytes by inhibiting tyrosinase (Tyr) activity, expression of Tyr, Tyr‐related protein 1 (Tyrp1), Tyrp2, and Kit. However, it is not known whether the ru2^d allele affects pheomelanin synthesis in recessive yellow (e/Mc1r^e) or in pheomelanic stage in agouti (A) mice. In this study, effects of the ru2^d allele on pheomelanin synthesis were investigated by chemical analysis of melanin present in dorsal hairs of 5‐week‐old mice from F₂ generation between C57BL/10JHir (B10)‐co‐isogenic ruby‐eye 2^d and B10‐congenic recessive yellow or agouti. Eumelanin content was decreased in ruby‐eye 2^d and ruby‐eye 2^d agouti mice, whereas pheomelanin content in ruby‐eye 2^d recessive yellow and ruby‐eye 2^d agouti mice did not differ from the corresponding Ru2^d/‐ mice, suggesting that the ru2^d allele inhibits eumelanin but not pheomelanin synthesis.     

Influence of depigmenting chemical agents on hair and skin color in yellow (pheomelanic) and black (eumelanic) mice

Topical applications of monobenzylether of hydroquinone (MBEH) or intraperitoneal injections of phenol induced graying of hair in eumelanic mice but had little effect on hair color in pheomelanic mice. Amcinonide, an anti-inflammatory agent, elicited whitening of a few hairs in both pheomelanic and eumelanic mice. In phenol-treated eumelanic mice, damaged follicular melanocytes were uprooted from hair bulbs and incorporated into the developing hair. The fate of follicular melanocytes in MBEH- or amcinonide-treated mice was not determined since hair growth and graying were more variable than in phenol-treated mice. In contrast to the susceptibility of eumelanic hair follicles to depigmentation by phenol or MBEH, the tail skin of eumelanic or pheomelanic mice was not depigmented by these agents. Overall, during the 3 week period of treatment that was sufficient for phenol or MBEH to elicit graying of hair, epidermal melanocytes of the tails of eumelanic or pheomelanic mice either failed to respond (phenol) or were stimulated in their "proliferative" and melanogenic activity (MBEH). In contrast, amcinonide brought about a marked reduction in the numbers of DOPA-positive epidermal melanocytes inhabiting the tails of eumelanic or pheomelanic mice. Amcinonide exerted a deleterious influence on the structure and function of tail epidermis. Its actions were partly reversed by simultaneous treatment with MBEH but not with prostaglandin (PGE2).     

Dopachrome conversion and dopa oxidase activities in recessive yellow mice. Catalytic activities of extracts from pheomelanic and eumelanic tissues

The dopa oxidase activity of tyrosinase and the dopachrome conversion activity of dopachrome oxidoreductase (dopachrome conversion factor) are reduced in skin or hair follicle extracts of pheomelanic mice compared with eumelanic mice. In this study, pheomelanic tissues are compared with eumelanic tissues of the same mice and found to be reduced in their DO and DC activities. Implications are discussed.     

Changes in the Proliferation and Differentiation of Neonatal Mouse Pink‐Eyed Dilution Melanocytes in the Presence of Excess Tyrosine

Changes in the proliferation and differentiation of epidermal melanocytes derived from newborn mice wild‐type at the pink‐eyed dilution (p) locus (P/P) and from congenic mice mutant at that locus (p/p) were investigated in serum‐free primary culture, with or without the addition of L‐Tyr. Incubation with added L‐Tyr inhibited the proliferation of P/P melanocytes in a concentration‐dependent manner and inhibition was gradually augmented as the donor mice aged. In contrast, L‐Tyr stimulated the proliferation of p/p melanoblasts–melanocytes derived from 0.5‐day‐old mice, but inhibited their proliferation when derived from 3.5‐ or 7.5‐day‐old mice. L‐Tyr stimulated the differentiation of P/P melanocytes. However, almost all cells were undifferentiated melanoblasts in control cultures derived from 0.5‐, 3.5‐ and 7.5‐day‐old p/p mice, but L‐Tyr induced their differentiation as the age of the donor mice advanced. The content of the eumelanin marker, pyrrole‐2,3,5‐tricarboxylic acid as well as the pheomelanin marker, 4‐amino‐3‐hydroxyphenylalanine in p/p melanocytes was greatly reduced compared with P/P melanocytes. However, the contents of eumelanin and its precursor, 5,6‐dihydroxyindole‐2‐carboxylic acid, as well as the contents of pheomelanin and its precursor, 5‐S‐cysteinyldopa in culture media from p/p melanocytes were similar to those of P/P melanocytes at all ages tested. L‐Tyr increased the content of eumelanin and pheomelanin two‐ to threefold in cultured cells and media derived from 0.5‐, 3.5‐ and 7.5‐day‐old mice. These results suggest that the proliferation of p/p melanoblasts–melanocytes is stimulated by L‐Tyr, and that the differentiation of melanocytes is induced by L‐Tyr as the age of the donor mice advanced, although eumelanin and pheomelanin fail to accumulate in p/p melanocytes and are released from them at all ages of skin development.     

Latanoprost stimulates eumelanogenesis in iridial melanocytes of cynomolgus monkeys

Latanoprost, the active principle of Xalatan eye drops, is a prostaglandin F2alpha analogue in widespread use for the treatment of glaucoma. During chronic treatment with the drug, an increased pigmentation of the iris was observed in both primates and man. To gain an insight into the nature of this effect, we analyzed the stroma of the irides of cynomolgus monkeys subjected to 25-38 weeks of treatment. A highly sensitive procedure, based on chemical degradation by alkaline hydrogen peroxide oxidation, or hydriodic acid hydrolysis, was developed, which allowed eumelanin and pheomelanin analysis of a single iris at a time. Untreated monkey irides were found to be essentially pheomelanic, providing further support to the recently reported occurrence of these pigments in human irides. In the Latanoprost-treated eyes, the amount of eumelanin increased from three to sevenfold, while the variation of pheomelanin did not exceed 25%. The increase in eumelanin/pheomelanin ratio in the treated eyes, as compared with the contralateral control eyes, varied from three to fivefold, and the change was statistically significant (P < 0.01; t-test). Based on the results of parallel studies, showing that Latanoprost does not induce proliferation of iridial melanocytes, and that the other pigmented layers of the iris which do not contain melanocytes are not affected by the drug, it can be concluded that the observed effect is a result of a direct interaction with the melanogenic mechanism. This probably involves activation of tyrosinase, as suggested, to account for the stimulation of melanin synthesis by related compounds, including natural prostaglandins.     

Newer Melanogenesis Control and Melanoma Eradication

Further advances leading to more sophisticated and effective suppression of melanogenesis and melanoma growth based on clarification and utilization of common vital factors involved in both processes are reviewed. Induction of depigmentation has been achieved by both glycosylation and its processing inhibitors, which have been found to be critical for the maturation and transport of tyrosinase from ribosomes through GERL-coated vesicles into premelanosomes. Kojic acid, a copper chelating melanogenic inhibitor, can induce inhibition of isolated tyrosinase activity as well as melanization in living pigment cells in in vitro and in vivo systems. This depigmenting effect was found to be due to a concurrent decrease in both eu- and pheomelanin formation. Malignant melanoma principally has accentuated melanosome genesis, which has been utilized to accumulate selectively ¹⁰B into melanoma cells using ¹⁰B-dopa analogue. Subsequent thermal neutron irradiation induces ¹⁰B(n, α)⁷Li reaction which releases high LET particles within a range of 10–14 μm thus erradicating selectively melanoma at the cellular level. This new therapy has been applied to a human melanoma lesion for the first time, and a successful therapeutic effect on melanoma has been obtained.     

Influences of Sex,Castration, and Androgens on the Eumelanin and Pheomelanin Contents of Different Feathers in Wild Mallards

In mallards the bright nuptial plumage of the drake represents the neutral, sex hormone-independent coloration of the species that both sexes eventually exhibit after castration. We compared the pheo- and eumelanin contents of feathers from the head, breast, flank, and under-tail coverts in five groups of mallards after the post-nuptial molt in summer: intact hens, intact drakes, castrated drakes, castrated drakes injected with testosterone during the spring, and castrated drakes injected with 5α-dihydrotestosterone during the spring. In the head feathers and under-tail coverts, the gonadal hormones of the intact birds and the testosterone injections into castrates significantly reduced the eumelanin content, tended to increase the pheomelanin content, and, thereby, changed the melanin type from eumelanic in the untreated castrates to mixed melanic in the other three groups. The eumelanin contents of the flank feathers did not differ among the groups, but the pheomelanin contents at this site was significantly elevated in the two intact groups and the testosterone-treated compared to the uninjected castrates. Again, the melanin type changed from eumelanic in the castrates to mixed melanic in the other three groups. The high pheomelanin content of the breast feathers in the castrated birds was significantly reduced in the hens, intact drakes, and testosterone-injected castrates with a concomitant tendency for elevated eumelanin contents. At this site, a change occurred from pheomelanic to mixed melanic. 5α-dihydrotestosterone was clearly less effective than testosterone in affecting the melanin contents in castrates and resulted in an intermediate coloration. The differing effects of the two androgens might be a result of differences in their conversion to estrogens.