The slaty mutation affects eumelanin and pheomelanin synthesis in mouse melanocytes

The slaty (Dct(slt)) mutation is known to reduce the activity of dopachrome tautomerase (DCT) in melanocytes. However, it is unknown whether the reduced DCT activity leads to a defect in the proliferation and differentiation of mouse melanocytes. To address this point, the proliferation and differentiation of neonatal melanocytes from Dct(slt)/Dct(slt) congenic mice in serum-free primary culture were investigated in detail. The proliferation of slaty epidermal melanoblasts/melanocytes in culture did not differ from that of wild-type mice. However, the differentiation was greatly inhibited. Tyrosinase (TYR) activity detected by dopa reaction as well as staining of DCT in slaty melanocytes was greatly reduced. The content of eumelanin in cultured slaty melanocytes was reduced, whereas the content of pheomelanin in media derived from cultured 7.5-day-old slaty melanocytes was greatly increased. The contents of eumelanin and pheomelanin in the neonatal slaty epidermis and dermis were reduced, except that the pheomelanin content in 3.5-day-old dermis was increased. These results suggest that the slaty mutation affects both eumelanin and pheomelanin synthesis in developmental stage-specific and skin site-specific manners, and, in addition, the gene controls the differentiation of melanocytes via the regulation of activity of TYR in addition to its own DCT.     

Dermal-epidermal interactions and the action of alleles at the agouti locus in the mouse

In the mouse, alleles at the agouti locus determine eumelanin or pheomelanin synthesis by the follicular melanocytes. Previous studies have identified the dermis as the site of action of these alleles. However, a recent investigation utilizing the yellow (A^y) allele suggested a possible role of the epidermis in the expression of agouti locus alleles. Using dermal-epidermal recombinations of embryonic skin of various agouti genotypes, the present investigation supports the role of both the dermis and epidermis. If nonagouti ($\text{a}\text{a}$) dermis is recombined with agouti ($\text{A}\text{A}$) epidermis, the resulting hairs are pigmented in the nonagouti pattern. The reciprocal recombination of agouti dermis and nonagouti epidermis results in hairs pigmented in the agouti pattern. The recombinations of yellow ($\text{A}{}^{\mathrm{y}}\text{a}$) dermis and agouti or extreme nonagouti ($\text{a}{}^{\mathrm{e}}\text{a}{}^{\mathrm{e}}$) epidermis result in hairs completely pigmented in the yellow pattern (pheomelanin). However, when extreme nonagouti or agouti dermis is recombined with yellow epidermis, the resulting hairs are completely pigmented with pheomelanin. Similar results occur in recombinations of “young” yellow epidermis (13 days) and “old” dermis (17 days) even though dermal papillae are present. The role of dermal-epidermal interactions in the expression of agouti alleles as well as possible explanations for the unique action of the yellow allele are discussed.     

Dermal-epidermal interactions and the site of action of the yellow (Ay) and nonagouti (a) coat color genes in the mouse

The alleles at the agouti locus in mice determine whether eumelanin or pheomelanin is synthesized by the follicular melanocytes. Previous studies have indicated the dermis as the site of action of the agouti alleles, while implying that the epidermis plays only a passive role. Using methods of dermal-epidermal recombinations of embryonic yellow (A^y) and nonagouti (a) mouse skin, the study reported here indicates that the epidermis, as well as the dermis, plays a role in the action of the agouti alleles. When yellow dermis is recombined with nonagouti epidermis, the hairs produced contain only pheomelanin, thus substantiating the role of the dermis. However, the reciprocal combination of nonagouti dermis and yellow epidermis also produces hairs containing pheomelanin, indicating a more important role for the epidermis. The role of the dermal-epidermal interactions in the action of the alleles at the agouti locus is discussed.     

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.     

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.     

In situ localization of agouti signal protein in murine skin using immunohistochemistry with an ASP-specific antibody

Switching between production of eumelanin or pheomelanin in follicular melanocytes is responsible for hair color in mammals; in mice, this switch is controlled by the agouti locus, which encodes agouti signal protein (ASP) through the action of melanocortin receptor 1. To study expression and processing patterns of ASP in the skin and its regulation of pigment production in hair follicles, we have generated a rabbit antibody (termed alphaPEP16) against a synthetic peptide that corresponds to the carboxyl terminus of ASP. The specificity of that antibody was measured by ELISA and was confirmed by Western blot analysis. Using immunohistochemistry, we characterized the expression of ASP in the skin of newborn mice at 3, 6, and 9 days postnatally. Expression in nonagouti (a/a) black mouse skin was negative at all times examined, as expected, and high expression of ASP was observed in 6 day newborn agouti (A/+) and in 6 and 9 day newborn lethal yellow (A(y)/a) mouse skin. In lethal yellow (pheomelanogenic) mice, ASP expression increased day by day as the hair color became more yellow. These expression patterns suggest that ASP is delivered quickly and efficiently to melanocytes and to hair matrix cells in the hair bulbs where it regulates melanin production.     

Modulation of murine melanocyte function in vitro by agouti signal protein.

Molecular and biochemical mechanisms that switch melanocytes between the production of eumelanin or pheomelanin involve the opposing action of two intercellular signaling molecules, alpha-melanocyte-stimulating hormone (MSH) and agouti signal protein (ASP). In this study, we have characterized the physiological effects of ASP on eumelanogenic melanocytes in culture. Following exposure of black melan-a murine melanocytes to purified recombinant ASP in vitro, pigmentation was markedly inhibited and the production of eumelanosomes was decreased significantly. Melanosomes that were produced became pheomelanosome-like in structure, and chemical analysis showed that eumelanin production was significantly decreased. Melanocytes treated with ASP also exhibited time- and dose-dependent decreases in melanogenic gene expression, including those encoding tyrosinase and tyrosinase-related proteins 1 and 2. Conversely, melanocytes exposed to MSH exhibited an increase in tyrosinase gene expression and function. Simultaneous addition of ASP and MSH at approximately equimolar concentrations produced responses similar to those elicited by the hormone alone. These results demonstrate that eumelanogenic melanocytes can be induced in culture by ASP to exhibit features characteristic of pheomelanogenesis in vivo. Our data are consistent with the hypothesis that the effects of ASP on melanocytes are not mediated solely by inhibition of MSH binding to its receptor, and provide a cell culture model to identify novel factors whose presence is required for pheomelanogenesis.     

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.     

Characterization of Melanogenesis in Normal Human Epidermal Melanocytes by Chemical and Ultrastructural Analysis

Chemical and ultrastructural studies were conducted to define the relationship between type of melanogenesis and fine structures of melanosomes in normal human epidermal melanocytes. Chemical analysis of epidermal melanin demonstrated that the ratio of eumelanin/pheomelanin varied individually, ranging from 1.31 to exclusively eumelanic. Ultrastructural analysis of fine structures of melanosomes revealed that spheroid melanosomes were frequently observed in melanocytes of the epidermis whose eumelanin/pheomelanin ratio was less than 5. Conversely, ellipsoid melanosomes predominated in melanocytes of the epidermis whose ratio was more than 10. On the basis of these findings, it seems reasonable to conclude that 1) normal human epidermal melanocytes synthesize both eumelanin and pheomelanin and 2) pheomelanin synthesis may be characterized by the presence of spheroid melanosomes whereas eumelanin synthesis is ascribed to ellipsoid melanosomes.     

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.     

Effects of the lethal yellow (Ay) and recessive yellow (e) genes on the population of epidermal melanocytes in newborn mice

Very few melanocytes can be detected by the DOPA reaction in the dorsal epidermis of newborn lethal yellow mice (Ay/a). Nevertheless, the epidermis contains a considerable number of melanoblasts (cells positive for the combined DOPA-premelanin reaction). On the other hand, numerous melanocytes as well as melanoblasts are found in the dorsal epidermis of black mice (a/a). The number of epidermal melanoblasts is smaller in (Ay/a than in a/a mice even though the same number of melanocytes is found in the dermis of these animals. It seems probable that the product of the A y gene suppresses either the differentiation or the proliferation of epidermal melanoblasts. The number of melanoblasts plus melanocytes in day-17 embryos from a cross between Ay/a and a/a mice shows a bimodal distribution. It seems possible that half of the embryos were Ay/a and possessed a reduced number of melanoblasts and melanocytes. This result seems to suggest that the Ay gene is active at this embryonic stage. In contrast to the case for the epidermis from Ay/a mice, numerous DOPA-positive melanocytes were detected in the epidermis from e/e mice. However, the total number of melanoblasts plus melanocytes in e/e epidermis did not differ from that in Ay/a epidermis, suggesting that the mode of action of the e gene in the epidermis is different from that of the Ay gene.     

Mesoderm-Ectoderm Interaction in the Production of the Agouti Pigmentation Pattern in Mice

Alleles at the agouti locus in the mouse determine the synthesis of either phaeomelanin or eumelanin by follicular melanocytes by altering the hair follicle environment. The method of dermal-epidermal recombination of mouse skin from C57BL/6J a/a and C57BL/6J A(w-J)/A(w-J) embryos was used in this study to establish the precise site of agouti gene action within the hair follicle. The pigmentary pattern of hairs formed in the recombination skin grafts was specific for the genotype of the dermal (mesodermal) component of the hair follicle. The genotype of the epidermal (ectodermal) component had no influence on the type of hair pigmentary pattern. These results indicate that future studies on gene mechanisms should focus on the dermis as the determining factor in altering the hair follicle environment.     

Ultrastructural change of melanosomes associated with agouti pattern formation in mouse hair.

We have studied the structural alteration of melanosomes in the melanocytes of agouti mice whose genetic characteristic is to produce eumelanin and phaeomelanin alternately in a single hair bulb. Melanocytes of hair bulbs from 1 to 2 day old mice of the black phase were observed to contain rod-shaped melanosomes of the eumelanin type (eumelanosome). In the melanocytes of the hair bulbs from 4 to 6-day old skin, which exclusively contain phaeomelanin, spherical melanosomes (phaeomelanosomes) were seen. On the other hand, the mice of the transitional phase from black to yellow possessed melanocytes that contained both eumelanosomes and phaeomelanosomes within a single cell. This result indicates that the shift from the eumelanin formation to the phaeomelanin formation or vice versa in agouti hair occurs within a single melanocyte.We observed multivesicular bodies in both the agouti melanocytes of the yellow phase and the genotypically yellow melanocytes. These bodies are considered to be the precursor of the phaeomelanin-containing melanosome. They are sometimes observed to have continuity with E. R. suggesting that the melanosomes are derived from E. R. in the phaeomelanin-forming melanocytes.     

Stimulation of the proliferation and differentiation of mouse pink-eyed dilution epidermal melanocytes by excess tyrosine in serum-free primary culture

The epidermal cell suspensions of the neonatal dorsal skin derived from wild type mouse at the pink-eyed dilution (p) locus (black, C57BL/10JHir-P/P) and their congenic mutant mouse (pink-eyed dilution, C57BL/10JHir-p/p) were cultured with a serum-free melanocyte growth medium supplemented with additional L-tyrosine (Tyr) from initiation of the primary culture. L-Tyr inhibited the proliferation of P/Pmelanocytes in a dose-dependent manner, whereas L-Tyr stimulated the proliferation of p/p melanoblasts and melanocytes regardless of dose. On the other hand, L-Tyr stimulated (P/P) or induced (p/p) the differentiation of epidermal melanocytes in a dose-dependent manner. In both P/P and p/p melanoblasts and melanocytes cultured with 2.0 mM L-Tyr for 14 days, slight increases in contents of eumelanin marker, pyrrole-2,3,5-tricarboxylic acid (PTCA) and pheomelanin marker, aminohydroxyphenylalanine (AHP) were observed. The average number of total melanosomes (stages I, II, III, and IV) per P/P melanocyte was not changed by L-Tyr treatment, but the proportion of stage IV melanosomes in the total melanosomes was increased. On the contrary, in p/p melanoblasts and melanocytes L-Tyr increased dramatically the number of stage II, III, and IV melanosomes as well as the proportion of stage III melanosomes. Contents of PTCA and eumelanin precursor, 5,6-dihydroxyindole-2-carboxylic acid (DHICA) of cultured media in p/p melanocytes were much more greatly increased than in P/P melanocytes. However, contents of AHP and pheomelanin precursor, 5-S-cysteinyldopa (5-S-CD) of cultured media in p/p melanocytes were increased in a similar tendency to P/Pmelanocytes. These results suggest that p/p melanocytes in the primary culture are induced to synthesize eumelanin by excess L-Tyr, but difficult to accumulate them in melanosomes.     

Tyrosinase activity in the first coat of agouti and black mice

Tyrosinase activity was compared in the skin and hair bulbs of young black and agouti mice between 4 and 12 days old. Differences in activity were found to be maximal in both the hair and skin at the time of yellow pigment synthesis in agouti mice. Histological examination suggested that the number of dopa-positive melanocytes is similar in the hair bulbs of agouti and black mice. The level of SH-compounds in the hair bulb was examined and found to be elevated in agouti tissue at the time of phaeomelanin formation. It was shown that sulphydryl compounds such as cysteine and glutathione have an inhibitory effect on tyrosinase, and it is possible that the elevated levels of SH-compounds are responsible for a reduction in tyrosinase activity in agouti mice. In agouti hair bulbs, this effect can be reversed in vitro by addition of copper.     

A variation of pigmentation in the glabrous skin of dogs

The usual pigmentation pattern in mammalian skin consists of fixed melanocytes in the basal layer of the epidermis, supplying keratinocytes with melanosomes. We observed that the glabrous skin (rhinaria and footpads) of dogs deviates from this pattern. In dogs, melanocytes are found in both the dermis and epidermis. The epidermal melanocytes are situated in the intercellular spaces of the basal and spinous layers. They are characterized by a quantity of cytoplasm containing a centriole, also developing melanosomes, and in some cases annulate lamellae. There is a high frequency of closely apposed melanocytes in the epidermis. Melanosomes in different stages of formation are also abundant. The morphology of the glabrous skin of dogs suggests transport of melanocytes from the dermis into the epidermis and formation of melanosomes in the epidermis. A distributed and intense pigment formation may be necessary to achieve the black noses of many dog breeds and wild canids, as well as dark footpads despite heavy abrasion and rapid skin renewal.