Tyrosinase Activity (TH,DO, PAGE-Defined Isozymes) and Melanin Production in Regenerating Hairbulb Melanocytes of Lethal Yellow (Ay/a), Black (a/a), Agouti (AwJ/AwJ) and Albino (a/a/c2J/c2J) Mice (C57BL/6J)

We compared tyrosinase activity (TH, DO, and native PAGE-defined isozymes) and melanin production in participate and soluble fractions of hairbulb melanocytes of lethal yellow (A^y/a C/C), nonagouti black (a/a C/C), and albino (a/a c^2J/c^2J) of 3-, 6-, 9-, and 12-day regenerating hairbulbs. With respect to tyrosine hydroxylase (TH) and dopa oxidase (DO) activities, A^y/a melanocytes possessed only 25-35% of the activity of a/a; there were no genotype differences in either the subcellular distribution of activity in soluble and particulate fractions or in the relative increases of activity over the 12-day developmental period. TH data on wild-type agouti (A^wJ/A^wJ) mice over the 3-11 day regeneration interval showed an activity intermediate between that of a/a and A^y/a; the rate of TH increase reflected black and yellow phases of the agouti hair cycle. Analyses of the number and densities of dopa-sensitive bands following native PAGE of 3-, 6-, 9-, and 12-day hairbulb fractions of a/a and A^y/a mice suggested stage-dependent patterns. A comparison of rates and amounts of melanin production in 3-, 6-, 9-, and 12-day fractions showed consistent melanin production in A^y/a to be 10-20% that of a/a; however, fold increases in melanin production over the four stages were similar between genotypes. Overall, tyrosinase activity data support the notion that agouti locus modification of tyrosinase activity is a graded or quantitative rather than a qualitative phenomenon.     

Agouti-Related Maturation and Tissue Distribution of oc-Melanocyte Stimulating Hormone in Wild-Type (AwJ/AwJ) and Mutant (Ay/a,a/a) Mice

Because of ectopic overproduction of agouti protein, yellow alleles (A^y and A^vy) of the murine agouti gene may secondarily modulate the synthesis, maturation (i.e., acetylation), and/or tissue deployment of α-Melanocyte Stimulating Hormone (MSH). We used HPLC to test the hypothesis that A^y/a mice exhibit altered concentrations of desacetyl-, monoacetyl-, and diacetyl-α-MSH in pituitaries, sera, and telogen hair bulbs when compared to black (a/a) mice. We also used RIA to measure total MSH in those same tissues of A^y/a, a/a, and white-bellied agouti (A^wJ/A^wJ) mice (Strain C57BL/6J). We found no evidence that A^y/a mice possessed an imbalance of des-, mono-, and diacetylated α-MSH species. However, radioimmunoassay (RIA) analyses of total MSH suggest that wild-type agouti mice (A^wJ/A^wJ) exhibited significantly decreased (P < 0.05) tissue levels of total α-MSH in pituitaries, sera, and regenerating hair bulbs when compared to those of mutant A^y/a and a/a mice.     

Tissue microenvironment and the genetic control of hair pigment patterns in mice

This study was conducted to assess microenvironmental variability within integumental tissue of genetically identical mice with respect to a specific cellular response: cyclic synthesis of yellow and black pigment by hair bulb melanocytes. Crosses were performed within and between inbred strains of mice that were isogenic with the exception of a single gene substitution at the agouti locus. Agouti locus genes included the A^vy, A^w, A, a^td, a^t, a^x, a^m, and a alleles. The pigment patterns of dorsal, flank, and ventral hairs of the first and third hair generations and of hairs growing in special integumentary areas such as the pinna, tail, and hind foot were studied. It was found that the amount of yellow pigment synthesized by hair bulb melanocytes within genetically identical mice is both agedependent and conditioned by the integumentary environment. Furthermore, the special integumentary regions produce hairs with a variety of pigment patterns in which the distribution and relative amounts of black and yellow pigments do not necessarily conform to dominance relationships expected among agouti locus alleles as judged by their effects on the pigmentation of the dorsal pelage. We conclude that within genetically uniform integumental tissues, microenvironmental differences occur and are reflected as alterations in the metabolic pattern of differentiated cells.     

Inheritance of colour and coat in the Belgian Shepherd dog

The several colours and coats of the Belgian Shepherd dog are shown to be due primary to combinations of the following genes: dominant black (A ^s ), dominant yellow (A ^y ), chinchilla (ch), long hair (l) and wire hair (Wh). The gene for black and tan (a ^t ) is or has been present in the breed. All of the dominant yellow dogs exhibit a black facial mask and extensive suffusion of black guard hairs on the body.     

Agouti Alleles Influence Thiol Concentrations in Hair Follicles and Extrafollicular Tissues of Mice (Ay/a,AwJ/AwJ,a/a)

Agouti protein (AP) expression in the wild-type agouti mouse (A^wJ/A^wJ) coincides with a switch in hair follicle melanogenesis from black (eumelanin) to yellow (pheomelanin). Ectopic overexpression of AP in the lethal yellow (A^y/a) mouse cause a pure yellow coat and the lethal yellow syndrome. Thiol concentrations may control the conversion of dopaquinone to pheomelanin in hair follicle melanocytes. Glutathione (GSH) also plays important roles in cellular health and protection. Using HPLC, cysteine and GSH were measured in 1) hair follicles, liver and serum of A^y/a, A^wJ/A^wJ, and a/a (black) mice, and 2) adipose and spleen tissues of A^y/a and a/a mice on day 9 of regenerating hair growth (late pheomelanin phase). Agouti locus alleles influence thiol metabolism in hair follicles and in other systemic tissues. A^y/a hair follicles and serum showed highest cysteine and lowest GSH levels. A^wJ/A^wJ mice showed intermediate levels, while a/a hair follicles and serum had lowest cysteine and highest GSH concentrations. In the hair follicle, cysteine (likely derived from enzymatic degradation of GSH) appears to be the primary pheomelanogenic thiol. Agouti locus alleles may also directly or indirectly affect thiol concentrations in systemic tissues like liver and spleen. Cysteine in spleen extracts showed A^y/a > a/a (P > 0.01). An A^y-induced imbalance of thiol metabolism (altering GSH concentrations in multiple tissues) may contribute to the pleiotropic defects of the lethal yellow syndrome.     

Inheritance of coat colour in the Hovawart dog

The three recognised colour varieties of the Hovawart breed of dog, black, black and gold and blonde, are due primarily to combinations of the mutant alleles solid black (A ^s ), black and tan (a ^t ) of the agouti series and the non-extension of black allele (e). The e allele is epistatic to the agouti alleles, thereby reducing the four possible phenotypes to three.     

Inheritance of coat colour in the Anatolian Shepherd dog

The predominant colour of the Anatolian Shepherd dog varies from a dark fawn to light red, with a variable black muzzle and face (mask). Evidence is presented that the colour is due to the dominant yellow allele (A ^y) of the agouti locus. Two other frequent colours are white spotting, due to the piebald allele (s ^p), and the chinchilla allele (ch). Two rarer colours are the agouti wolf-grey wild type (A ⁺) and a light fawn with a blue facial mask, due to the dilution allele (d).     

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.     

Inheritance of coat colour in the German Pinscher dog

The two primary colour varieties of the German Pinscher breed are the red and the black and tan. Respectively, these are produced by the dominant yellow allele A ^y and the black and tan allele a ^t of the agouti locus. The dilute gene d is present in the breed at a low frequency and produces the rarer isabella and blue and tan colours, with the genotypes A ^y -dd and a ^t dd, respectively.     

Agouti: from mouse to man, from skin to fat

The agouti protein regulates pigmentation in the mouse hair follicle producing a black hair with a subapical yellow band. Its effect on pigmentation is achieved by antagonizing the binding of alpha-melanocyte stimulating hormone (alpha-MSH) to melanocortin 1 receptor (Mc1r), switching melanin synthesis from eumelanin (black/brown) to phaeomelanin (red/yellow). Dominant mutations in the non-coding region of mouse agouti cause yellow coat colour and ectopic expression also results in obesity, type 11 diabetes, increased somatic growth and tumourigenesis. At least some of these pleiotropic effects can be explained by antagonism of other members of the melanocortin receptor family by agouti protein. The yellow coat colour is the result of agouti chronically antagonizing the binding of alpha-MSH to Mc1r and the obese phenotype results from agouti protein antagonizing the binding of alpha-MSH to Mc3r and/or Mc4r. Despite the existence of a highly homologous agouti protein in humans, agouti signal protein (ASIP), its role has yet to be defined. However it is known that human ASIP is expressed at highest levels in adipose tissue where it may antagonize one of the melanocortin receptors. The conserved nature of the agouti protein combined with the diverse phenotypic effects of agouti mutations in mouse and the different expression patterns of human and mouse agouti, suggest ASIP may play a role in human energy homeostasis and possibly human pigmentation.     

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.     

Morphology of Hair Pigmentation in Wild Red Foxes, Silver Foxes, and Their Hybrids

The effects of dominant allele A ^r of locus Agoution the morphology of hair pigmentation were described in foxes. The A ^r allele was shown to determine the type of melanin and its content in hair with no effect on the morphology of pigment granules and their distribution throughout a hair. Using the method of electron spin resonance (ESR), the types of melanin (eumelanin and pheomelanin) and their content in the hair of red (A ^r A ^r EE) and silver (aaEE) foxes and their hybrids (A ^r aEE) were determined. In silver foxes, only one type of melanin (eumelanin) was found. In red foxes and their hybrids (which are phenotypically similar but darker than red foxes), both types of melanin (eu- and pheomelanin) were found. The highest melanin content was detected in the coat of silver foxes. In the hybrids, the total melanin content was lower than in silver foxes, but significantly higher than in red foxes. In red foxes, the contribution of pheomelanin to the total hair melanin content was twice as large as in the hybrids.     

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.     

Tyrosinase Depletion Prevents the Maturation of Melanosomes in the Mouse Hair Follicle

The mechanisms that lead to variation in human skin and hair color are not fully understood. To better understand the molecular control of skin and hair color variation, we modulated the expression of Tyrosinase (Tyr), which controls the rate-limiting step of melanogenesis, by expressing a single-copy, tetracycline-inducible shRNA against Tyr in mice. Moderate depletion of TYR was sufficient to alter the appearance of the mouse coat in black, agouti, and yellow coat color backgrounds, even though TYR depletion did not significantly inhibit accumulation of melanin within the mouse hair. Ultra-structural studies revealed that the reduction of Tyr inhibited the accumulation of terminal melanosomes, and inhibited the expression of genes that regulate melanogenesis. These results indicate that color in skin and hair is determined not only by the total amount of melanin within the hair, but also by the relative accumulation of mature melanosomes.     

Influence of Maternal Phenotype on Metabolic Differentiation of Agouti Locus Mutants in the Mouse

The results of extensive breeding experiments indicate that the phenotypic differentiation of embryos carrying the viable yellow, A ^vy, or mottled, a^m, mutations is influenced to a major extent by the agouti locus genotype and the strain genome of the dam. The A^vy/a and a^m/a genotypes are each expressed in a spectrum of coat color phenotypes. These can be grouped into two classes, mottled and pseudoagouti.—In a reciprocal cross of C57BL/6JNIcrWf and AM/Wf-a^m/a^m mice, 29.5% of the offspring of C57BL/6 dams were of the pseudoagouti phenotype, whereas no pseudoagouti offspring were produced by AM strain dams.—Mottled yellow A^vy/a mice become obese and tumor formation is enhanced in these mice in comparison with the lean pseudoagouti A^vy/a siblings.—In two different reciprocal crosses using four different inbred strains, the proportion of pseudoagouti A^vy/a offspring differed according to the strain of the dam. Regardless of strain, mottled yellow A ^vy/a dams produced significantly fewer pseudoagouti A ^vy/a offspring than did black a/a dams.—The data suggest that metabolic differentiation of A^vy/a zygotes into phenotypic classes with different susceptibilities to obesity and tumor formation is influenced to a considerable degree by the metabolic characteristics of the oviductal and uterine environment of the dam.     

A deletion spanning the promoter and first exon of the hair cycle-specific ASIP transcript isoform in black and tan rabbits

Black and tan animals have tan-coloured ventral body surfaces separated by sharp boundaries from black-coloured dorsal body surfaces. In the a^t mouse mutant, a retroviral 6 kb insertion located in the hair cycle-specific promoter of the murine Asip gene encoding agouti signalling protein causes the black and tan phenotype. In rabbits, three ASIP alleles are thought to exist, including an a^t allele causing a black and tan coat colour that closely resembles the mouse black and tan phenotype. The goal of our study was to identify the functional genetic variant causing the rabbit a^t allele. We performed a WGS-based comparative analysis of the ASIP gene in one black and tan and three wt agouti-coloured rabbits. The analysis identified 75 a^t-associated variants including an 11 kb deletion. The deletion is located in the region of the hair cycle-specific ASIP promoter and thus in a region homologous to the site of the retroviral insertion causing the a^t allele in mice. We observed perfect association of the genotypes at this deletion with the coat colour phenotype in 49 rabbits. The comparative analysis and the previous knowledge about the regulation of ASIP expression suggest that the 11 kb deletion is the most likely causative variant for the black and tan phenotype in rabbits.     

Spectrophotometric Characterization of Eumelanin and Pheomelanin in Hair

Mammalian melanins exist in two chemically distinct forms: the brown to black eumelanins and the yellow to reddish-brown pheomelanins. They can be quantified by HPLC analysis of pyrrole-2,3,5-tricarboxylic acid (PTCA) and aminohydroxyphenylalanine (AHP). We recently developed a spectrophotometric method for assaying the total amount of eu- and pheomelanins by dissolving melanins in Soluene-350 plus water. In this study, we examined whether absorbance at 500 nm (A₅₀₀) of the Soluene-350 solution reflects the total amount of melanins obtained by the HPLC methods, and whether the ratio of absorbances between 650 and 500 nm reflects the eumelanin/total melanin ratio in mouse hair, sheep wool, and human hair. Our findings were as follows: (1) Total melanin levels calculated from A₅₀₀ values correlate well with those obtained from PTCA and AHP values by multiplying with the following factors: for mice, PTCA × 45 + AHP × 2.5; for sheep, PTCA × 40 + AHP × 15; and for humans, PTCA × 160 + AHP × 10. (2) The A₆₅₀/A₅₀₀ ratios were higher (0.25–0.33) in black to brown hair while they were significantly lower (0.10–0.14) in yellow to red hair. These results indicate that (1) the A₅₀₀ value can be used to quantify the total combined amount of eu- and pheomelanins, and (2) the A₆₅₀/A₅₀₀ ratio can serve as a parameter to estimate the eumelanin/total melanin ratio. The present method provides a convenient way to qualitatively characterize eu- and pheomelanins in melanins produced in follicular melanocytes.