Modification of pigmentation patterns in allophenic mice by the W gene

Mouse embryos heterozygous at the W locus were combined with embryos which were wild type at this locus but homozygous for albino. The resulting allophenics displayed an unusual pigmentation phenotype consisting of entirely white fur and ruby-coloured eyes. Microscopic examination showed the eye pigment to be located exclusively in the retinal epithelium, which was a mosaic of black and white sectors. This ruby-eyed white pattern corresponds to what would have been expected for WWCC in equilibrium wwcc mosaics but not for WwCC in equlibrium wwcc mice. WW mice are black-eyed whites, but Ww mice have black eyes and black fur, except for a small ventral white spot. These results suggest that melanocytes of the Ww genotype, although capable of producting normally pigmented fur in Ww animals, fail to populate hair follicles when the competition with wwcc (albino) melanocytes that are wild type at the W locus. The genotype of these WwCC in equilibrium wwcc alophenes was proved by progeny testing. This is apparently the first report of a single gene change affecting the competitive ability of cells in allophenic mice, and suggests that such changes may play a significant role in the clonal selection of embryonic cells during development.     

Evidence for Alpha-MSH Binding Sites on Human Scalp Hair Follicles: Preliminary Results

Alpha-MSH, considered an important pigmentation hormone, binds to melanocytes and is thought to stimulate melanogenesis through a cyclic-AMP-dependent mechanism. The binding of alpha-MSH to follicular melanocytes has been investigated in human hair of different colors, ranging from black to blond and senile white. Hairs were plucked, the follicles were cut off, and an alpha-MSH binding assay, using a radiolabeled alpha-MSH analogue, was performed on these bulbs. As controls of each assay, fragments of hairs of the same person were used. The results show a dose-response relationship and the assay seems to be specific for alpha-MSH, because other peptides such as ACTH, beta-LPH and beta-endorphins do not compete for binding sites as alpha-MSH does. These binding sites seem to be present only on melanin synthesizing melanocytes, since the controls and follicles of senile white hair, which do not contain active melanocytes, show negative results. All the assays were performed on raw material, i.e., whole plucked hair follicles. This is the first time that binding sites for alpha-MSH have been demonstrated on human scalp hair follicles. In addition, their presence was found to be associated with active melanin production; their absence was demonstrated on senile white hair follicles.     

Evidence for alpha-MSH binding sites on human scalp hair follicles: preliminary results.

Alpha-MSH, considered an important pigmentation hormone, binds to melanocytes and is thought to stimulate melanogenesis through a cyclic-AMP-dependent mechanism. The binding of alpha-MSH to follicular melanocytes has been investigated in human hair of different colors, ranging from black to blond and senile white. Hairs were plucked, the follicles were cut off, and an alpha-MSH binding assay, using a radiolabeled alpha-MSH analogue, was performed on these bulbs. As controls of each assay, fragments of hairs of the same person were used. The results show a dose-response relationship and the assay seems to be specific for alpha-MSH, because other peptides such as ACTH, beta-LPH and beta-endorphins do not compete for binding sites as alpha-MSH does. These binding sites seem to be present only on melanin synthesizing melanocytes, since the controls and follicles of senile white hair, which do not contain active melanocytes, show negative results. All the assays were performed on raw material, i.e., whole plucked hair follicles. This is the first time that binding sites for alpha-MSH have been demonstrated on human scalp hair follicles. In addition, their presence was found to be associated with active melanin production; their absence was demonstrated on senile white hair follicles.     

The mutant gene "wal" is active in cells of mouse hair follicles

In order to determine the place of action of the mutant gene waved alopecia (wal), we have obtained chimeric wal/wal c/c Gpi-1aa<-->+/+ C/C Gpi-1bb animals by aggregation of eight-cellular embryos of BALB/c-wal/wal mice and CBA (+/+) mice. The presence or absence of the chimeric structure was determined from the mosaic nature of fur color and hair structure, as well as on the basis of the presence of electrophoretically distinct variants of glucosephosphate isomerase in blood. Chimeras had alternating transverse patches of different lengths and widths consisting of curly (genotype wal/wal) or straight (genotype +/+) hairs. The percentage of cells with wal/wal mutant genotype in chimeras established on the basis of glucosephosphate isomerase isozymes varied from 10 to 80%. A higher percentage of the parental wal/wal component in chimeras correlated with the number of patches having wavy hairs. Analysis of the fur pattern represented by the alternation of transverse patches of wavy or straight hairs in chimeric wal/wal (+/+ mice has shown that mutant gene wal acts in ectodermal cells of hair follicles.     

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 effect of methyl-containing supplements during pregnancy on the phenotypic modification of offspring hair color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

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.     

The effect of methyl supplements during pregnancy on the phenotypic modification of offspring agouti coat color in rats

The effect of methyl supplements to the diet of pregnant homozygous (AAHH) female rats with agouti coat color mated with homozygous (aahh) males on the phenotypic modification of the coat color of their heterozygous offspring (AaHh) has been studied. Comparative morphological analysis of the main parameters of hair that determine coat color, including the total length of hairs of different types and the length of the upper black (eumelanin) and light (pheomelanin) parts of awn hairs has been performed. The pattern of pigment granule distribution among hair layers has been analyzed. The melanin content of the hair has been determined using electron spin resonance (ESR). Although all offspring have a typical agouti coat color (alternating black and light portions of hair), 39% of them have a darker coat color than control and other experimental rats have. The main differences between the offspring with darkened and standard coat colors are accounted for by the ratio between the eumelanin and pheomelanin portions of awn hairs. In darkened offspring, this ratio is significantly higher than in control rats. The possible mechanisms of the phenotypic modification of agouti coat color in experimental animals are discussed.     

Regulation of yellow pigment formation in mice: a historical perspective

Pigment synthesis by hair follicle melanocytes is modulated by a large number of environmental and genetic factors, many of which are discussed in this review. Eumelanic (non-yellow) pigment is produced by hair follicle melanocytes following the binding of alpha-melanocyte stimulating hormone to melanocortin receptor 1. Binding of this hormone to the melanocyte membrane is blocked by agouti signaling protein (ASP) which is encoded by the agouti locus and results in the synthesis of yellow pigment, instead of non-yellow (black/brown) pigment. The cyclical release of ASP by hair follicle cells results in a black/brown hair with a subapical yellow band. This is the wild-type coat color pattern of many mammals and is called agouti. Several dominant mutations at the agouti locus in mice, induced by retrotransposon-like intracisternal A particles, result in ectopic over-expression of ASP and animals with much higher proportions of all-yellow hairs. This abnormal presence of ASP in essentially all body cells results in the 'yellow agouti obese mouse syndrome.' The obesity has been associated with binding of ASP to melanocortin receptor 4 inactivating the latter. The syndrome also includes hyperinsulinemia, increased somatic growth, and increased susceptibility to hyperplasia and carcinogenesis. The physiologic and molecular bases for these syndrome components have not yet been elucidated. This historically orientated review is subdivided, where applicable, into pre- and post-1992 subsections to emphasize the impact of the cloning of the agouti and extension loci and their protein products on the identification of the molecular and physiological pathways modulating the manifold aspects of pheomelanogenesis.     

A new sexual signal in rutting male red deer: Age related chemical scent constituents in the belly black spot

Rutting behaviour of red deer stags (Cervus elaphus) includes an extensive repertoire of visual and acoustic signals directed either to rival males or to females. As in other mammals, olfactory communication is expected to play a central role in these rutting interactions too, but this has rarely been investigated. Only during the rutting season, red deer males show a conspicuous black spot area throughout most of their underbelly produced by the impregnation of substances with a strong scent. Here, we examined the origin of these compounds and their potential role as chemical signals. By using gas chromatography–mass spectrometry (GC–MS), we identified 67 compounds in the hair from the belly black spot of red deer stags, mainly heterocyclic aromatic organic compounds, such as m-cresol, benzoic acid, cyclohexanecarboxylic acid and ethylphenol, but we also found steroids, such as cholesterol and androstane-3,17-dione, carboxylic acids and their esters between n-C₆ and n-C₂₂, alcohols, squalene and other minor compounds. Many of these compounds are found in the belly black spot but not in other hair areas, and may have originated from several sources, such as the urine or the sebaceous glands of the skin, which impregnated the belly. Moreover, we found differences in chemical profiles depending on age, with older males having higher proportions of benzoic acid and androstane-3,17-dione, but lower proportions of m-cresol. Because most of these compounds are strongly odoriferous, and appear related to male characteristics, our data indicate that scent from the hairs forming the black spot of the belly may be regarded as an overlooked new sexual chemical signal in red deer in the context of competition for mates during the rutting season.     

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.     

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.     

The genetics of coat colors in the mongolian gerbil (Meriones unguiculatus)

Genetic studies demonstrated three loci controlling coat colors in the Mongolian gerbil. F1 hybrids of white gerbils with red eyes and agouti gerbils with wild coat color had the agouti coat color. The segregating ratio of agouti and white in the F2 generation was 3:1. In the backcross (BC) generation (white x F1), the ratio of the agouti and white coat colors was 1:1. Next, inheritance of the agouti coat color was investigated. Matings between agouti and non-agouti (black) gerbils produced only agouti gerbils. In the F2 generation, the ratio of agouti to non-agouti (black) was 3:1. There was no distortion in the sex ratios within each coat color in the F1, F2 and BC generations. This indicated that the white coat color of gerbils is governed by an autosomal recessive gene which should be named the c allele of the c (albino) locus controlling pigmentation, and the agouti coat color is controlled by an autosomal dominant gene which might be named the A allele of the A (agouti) locus controlling pigmentation patterns in the hair. The occurrence of the black gerbil demonstrated clearly the existence of the b (brown) locus, and it clearly indicated that the coat colors of gerbils can basically be explained by a, b, and c loci as in mice and rats.     

Evidence for eumelanin and pheomelanin producing genotypes in the Arabian horse

The ultrastructural imaging of melanocytes coupled with analyses to detect sulfur-containing melanosomes by energy-dispersive X-ray spectroscopy were used to test the hypothesis that the yellowish-red and black pigments found in Arabian horses result from pheomelanogenesis and eumelanogenesis, respectively. These procedures detected pheomelanosomes in follicles at the base of hairs in chestnut horses and eumelanosomes in follicles at the base of hairs in black horses. By analyzing tissue obtained by skin biopsy, these procedures also demonstrated that skin melanocytes in a chestnut horse produce eumelanosomes, and follicular melanocytes in the same horse produce pheomelanosomes. It was also shown that the type of follicular melanosome present in light bay horses is correlated with the color of the hair. The results of this study give experimental evidence for the Odriozola-Adalsteinsson hypothesis that the e allele is responsible for the chestnut phenotype; they also give fine structure and chemical confirmation of the action of the A and E loci in the Arabian horse as currently proposed for the mouse and other mammals.     

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.     

STX17在不同毛色小鼠皮肤中差异表达与在毛囊中的定位

突触融合蛋白17 (STX17)是一种囊泡蛋白,参与细胞中物质的运输.为研究Stx17在不同毛色皮肤中是否存在差异表达及明确它在毛囊中的定位,进行了普通PCR、real-time PCR、免疫组化和蛋白免疫印迹实验对小鼠皮肤组织和体外培养黑素细胞的Stx17基因及蛋白的检测.普通PCR检测得出小鼠皮肤和黑色素细胞总RNA有Stx17 CDS区序列的表达;荧光定量检测显示,在白、灰、黑3种组织中Stx17均有表达,在灰色腹部表达量最高,是黑色皮肤的1.682倍,昆明鼠白色皮肤中表达量最低,是黑色皮肤的0.115倍;皮肤组织免疫组化结果显示,STX17表达于毛囊的上皮根鞘,且毛囊上段和中段表达量高于下段,黑色素细胞的免疫组化分析得出,STX17在黑色素细胞的细胞质和细胞膜上均有表达;蛋白免疫印迹结果显示,在白色、灰色和黑色皮肤均有STX17蛋白阳性条带且灰色皮肤中表达量最高,黑色皮肤次之,白色皮肤中表达量是最低的,这与荧光定量检测结果一致,体外培养的小鼠黑色素细胞中也有STX17蛋白阳性条带.实验结果表明,小鼠Stx17基因在皮肤组织、毛囊角化细胞以及黑色素细胞中均有表达,Stx17可能参与毛色的形成,且在小鼠腹部毛色变浅中起到了一定的作用.     

Studies of Sl/Sld in equilibrium with +/+ mouse aggregation chimaeras. I. Different distribution patterns between melanocytes and mast cells in the skin

In spite of their different origin, both melanocytes and mast cells are deficient in the skin of mutant mice of the Sl/Sld genotype. Since the neural crest and the liver of Sl/Sld embryos contain normal precursors of melanocytes and mast cells, respectively, the deficiency is attributed to a defect in tissue environment necessary for migration and/or differentiation of precursor cells. We investigated whether the tissue environment used for differentiation of melanocytes and mast cells was identical by producing aggregation chimaeras from Sl/Sld and +/+ embryos. Chimaeric mice with apparent pigmented and nonpigmented stripes were obtained. In the nonpigmented stripes of these Sl/Sld in equilibrium with +/+ chimaeras, melanocytes were not detectable in hair follicles but were detectable in the dermis. In contrast, melanocytes were detectable neither in hair follicles nor in the dermis of nonchimaeric Sl/Sld mice. Concentrations of mast cells were comparable in the pigmented and nonpigmented stripes of Sl/Sld in equilibrium with +/+ chimaeras, but the average concentration of mast cells significantly varied in the chimaeras (from 8% to 74% of the value observed in control +/+ mice). The present result suggests that mesodermal cells that support the migration and differentiation of both melanocyte precursors and mast-cell precursors mix homogeneously in the dermis and that ectodermal cells that influence the invasion of differentiating melanocytes into hair follicles make discrete patches.     

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.     

No differences in pineal synaptic ribbon and spherule numbers in different stocks and strains of laboratory rats

Previous studies have shown that the pineal glands of different stocks and strains of laboratory rats have different melatonin-forming capacities. In the present investigation a widely studied morphological parameter of the pineal, i.e. synaptic ribbon (SR) and synaptic spherule (SS) numbers, was explored in 6 different stocks and strains of laboratory rats, viz.:Han:WIST (albino), LEW/Han (albino), DA/Han (agouti), BN/Han (dark brown), LE/Han (black hooded) and (LEW x BN)/F1 (black with white belly). The rats were maintained under the usual laboratory conditions (lights on from 06.00-18.00 h) for 3 weeks and killed between 10.00-12.00 h, when they were 6 weeks old. The pineals were rapidly excised and processed for transmission electron microscopy. The morphology, distribution (in singles or groups, distant from, or near cell membrane etc.) and number of SR and SS per 20,000 microns2 area of pineal tissue were similar in all groups of rats studied. It is concluded that, in contrast to pineal gland size and melatonin synthesis, SR number is a fairly constant pineal parameter in different stocks and strains of laboratory rats and independent of pigmentation.