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.     

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.     

Fluorescence spectrophotometric analysis of melanins in the house mouse

We extracted the yellow melanin (phaeomelanin), black melanin (eumelanin), and mixed type of melanin from dorsal hair of dominant yellow (A ^y /a), non-agouti (a/a), and agouti (A/A) mice, respectively. Spectrophotometric and fluorescence spectrophotometric analysis demonstrated that the yellow melanin was qualitatively distinct from the black melanin and that the agouti hair contained both types of pigment.This work was supported by Grant 244004 from the Ministry of Education. Part of this work was presented at the X International Pigment Cell Conference.     

Variations in the Coding Region of the Agouti Signaling Protein Gene Do Not Explain Agouti/Non-agouti Phenotypes in Macaques

Agouti is a common pigmentation phenotype in mammals including primates. Mutations in the agouti signaling protein gene (ASIP) are known to result in non-agouti black hairs in laboratory mice. It is still unclear whether sequence variation in ASIP is linked with the agouti/non-agouti phenotypes in macaques (Genus Macaca). To address this issue, we have determined and compared nucleotide sequences of protein coding region of ASIP in 18 macaque species and have identified 16 different sequences of the ASIP. Macaca nemestrina, which showed yellow agouti hairs, shared an identical amino acid sequence of ASIP with several non-agouti species. No sequence changes were found in functionally important sites of ASIP in the macaques showing non-agouti dark hair color. These results indicated that the variation in the protein coding region of ASIP did not explain the non-agouti dark coat color in the macaques. Upstream regulatory regions of ASIP and other genes participating in pigmentation system remain to be investigated for the hair color variation in the macaques.     

A Transgenic Mouse Assay for Agouti Protein Activity

The mouse agouti gene encodes an 131 amino acid paracrine signaling molecule that instructs hair follicle melanocytes to switch from making black to yellow pigment. Expression of agouti during the middle part of the hair growth cycle in wild-type mice produces a yellow band on an otherwise black hair. The ubiquitous unregulated expression of agouti in mice carrying dominant yellow alleles is associated with pleiotropic effects including increased yellow pigment in the coat, obesity, diabetes and increased tumor susceptibility. Agouti shows no significant homology to known genes, and the molecular analysis of agouti alleles has shed little new light on the important functional elements of the agouti protein. In this paper, we show that agouti expression driven by the human β-ACTIN promoter produces obese yellow transgenic mice and that this can be used as an assay for agouti activity. We used this assay to evaluate a point mutation associated with the a(16H) allele within the region encoding agouti's putative signal sequence and our results suggest that this mutation is sufficient to cause the a(16H) phenotype. Thus, in vitro mutagenesis followed by the generation of transgenic mice should allow us to identify important functional elements of the agouti protein.     

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.     

Circling,deafness, and yellow coat displayed by yellow submarine (ysb) and light coat and circling (lcc) mice with mutations on chromosome 3

We describe here two mouse mutants, yellow submarine (Ysb) and light coat and circling (Lcc). Ysb arose as the result of insertions of a transgene, pAA2, into the genome. Lcc is an independent, radiation-induced mutation. Both mutants are characterized by recessive circling behavior and deafness, associated with a non-segregating, semi-dominant yellow coat color. Complementation tests showed that Ysb and Lcc are allelic. We attribute the yellow coat in Ysb and Lcc mice to the absence of black awl overhairs, increased agouti zigzag underhairs, and the presence of agouti awls with long subapical yellow pigment. Chromosomal mapping and genomic characterization showed the Ysb and Lcc mutations involve complex chromosomal rearrangements in overlapping regions of mouse chromosome 3, A2/A3-B/C and B-E1, respectively. Ysb and Lcc show for the first time, to our knowledge, the presence of genes in the B-C region of chromosome 3 important for balance and hearing and the pigmentation and specification of coat hair.     

Molecular Markers for the agouti Coat Color Locus of the Mouse

The agouti (a) coat color locus of the mouse acts within the microenvironment of the hair follicle to control the relative amount and distribution of yellow and black pigment in the coat hairs. Over 18 different mutations with complex dominance relationships have been described at this locus. The lethal yellow (Ay) mutation is the top dominant of this series and is uniquely associated with an endogenous provirus, Emv-15, in three highly inbred strains. However, we report here that it is unlikely that the provirus itself causes the Ay-associated alteration in coat color, since one strain of mice (YBR-Ay/a) lacks the provirus but still retains a yellow coat color. Using single-copy mouse DNA sequences from the regions flanking Emv-15 we have detected three patterns of restriction fragment length polymorphisms (RFLPs) within this region that can be used as molecular markers for different agouti locus alleles: a wild-type agouti (A) pattern, a pattern which generally cosegregates with the nonagouti (a) mutation, and a pattern which is specific to Emv-15. We have used these RFLPs and a panel of 28 recombinant inbred mouse strains to determine the genetic linkage of these sequences with the agouti locus and have found complete concordance between the two (95% confidence limit of 0.00 to 3.79 centimorgans). We have also physically mapped these sequences by in situ hybridization to band H1 of chromosome 2, thus directly confirming previous assignments of the location of the agouti locus.     

Molecular Genetic Characterization of Six Recessive Viable Alleles of the Mouse Agouti Locus

The agouti locus on mouse chromosome 2 encodes a secreted cysteine-rich protein of 131 amino acids that acts as a molecular switch to instruct the melanocyte to make either yellow pigment (phaeomelanin) or black pigment (eumelanin). Mutations that up-regulate agouti expression are dominant to those causing decreased expression and result in yellow coat color. Other associated effects are obesity, diabetes, and increased susceptibility to tumors. To try to define important functional domains of the agouti protein, we have analyzed the molecular defects present in a series of recessive viable agouti mutations. In total, six alleles (a(mJ), a(u), a(da), a(16H), a(18H), a(e)) were examined at both the RNA and DNA level. Two of the alleles, a(16H) and a(e), result from mutations in the agouti coding region. Four alleles (a(mJ), a(u), a(18H), and a(da)) appear to represent regulatory mutations that down-regulate agouti expression. Interestingly, one of these mutations, a(18H), also appears to cause an immunological defect in the homozygous condition. This immunological defect is somewhat analogous to that observed in motheaten (me) mutant mice. Short and long-range restriction enzyme analyses of homozygous a(18H) DNA are consistent with the hypothesis that a(18H) results from a paracentric inversion where one end of the inversion maps in the 5' regulatory region of agouti and the other end in or near a gene that is required for normal immunological function. Cloning the breakpoints of this putative inversion should allow us to identify the gene that confers this interesting immunological disorder.     

Recessive black is allelic to the yellow plumage locus in Japanese quail and associated with a frameshift deletion in the ASIP gene

The recessive black plumage mutation in the Japanese quail (Coturnix japonica) is controlled by an autosomal recessive gene (rb) and displays a blackish-brown phenotype in the recessive homozygous state (rb/rb). A similar black coat color phenotype in nonagouti mice is caused by an autosomal recessive mutation at the agouti locus. An allelism test showed that wild type and mutations for yellow, fawn-2, and recessive black in Japanese quail were multiple alleles (*N, *Y, *F2, and *RB) at the same locus Y and that the dominance relationship was Y*F2 > Y*Y > Y*N > Y*RB. A deletion of 8 bases was found in the ASIP gene in the Y*RB allele, causing a frameshift that changed the last six amino acids, including a cysteine residue, and removed the normal stop codon. Since the cysteine residues at the C terminus are important for disulphide bond formation and tertiary structure of the agouti signaling protein, the deletion is expected to cause a dysfunction of ASIP as an antagonist of alpha-MSH in the Y*RB allele. This is the first evidence that the ASIP gene, known to be involved in coat color variation in mammals, is functional and has a similar effect on plumage color in birds.     

Switching of melanocyte pigmentation associated with pituitary pars intermedia tumors in Rb+/- and p27-/- female mice with yellow pelage

As an incidental finding in a study of mammary tumorigenesis, two lines of genetically engineered mice were observed to develop pigmentation changes of the fur. Mice with targeted mutations of the Rb1 (Rb) and Cdkn1b (p27kip1) genes were crossed from C57BL/6 (black coat color; eumelanin) and 129Sv (wild-type agouti coat color) backgrounds, respectively, to one with a dominant yellow coat color (phaeomelanin) carrying a transgene for Agouti under a keratinocyte specific promoter. Both Rb+/- and p27-/- mice developed pituitary tumors of the pars intermedia that were associated with a switch to black (eumelanic) fur but were not observed in sibling Rb+/+ and p27+/+ mice. This phenomenon was observed first in the vibrissae and, subsequently one to two weeks later, as periorbital and dorsal patches, and was associated with pituitary lesions larger than four millimeters in the longest dimension. In Rb+/- mice, pigmentation change preceded a moribund state attributable to the tumors by two to four weeks, whereas in p27-/- mice, the pigmentation alteration was earlier, more gradual, and prolonged. The switch from phaeomelanin to eumelanin in the fur is most likely due to out-competition of the agouti gene product by alpha-melanocyte-stimulating hormone from the pituitary tumors, an effect masked in black or agouti mice.     

Female Fertility and Mating Type Effects on Effective Population Size and Evolution in Filamentous Fungi

The murine agouti locus regulates a switch in pigment synthesis between eumelanin (black/brown pigment) and phaeomelanin (yellow/red pigment) by hair bulb melanocytes. We recently described a spontaneous mutation, hypervariable yellow (A(hvy)) and demonstrated that A(hvy) is responsible for the largest range of phenotypes yet identified at the agouti locus, producing mice that are obese with yellow coats to mice that are of normal weight with black coats. Here, we show that agouti expression is altered both temporally and spatially in A(hvy) mutants. Agouti expression levels are positively correlated with the degree of yellow pigmentation in individual A(hvy) mice, consistent with results from other dominant yellow agouti mutations. Sequencing of 5' RACE and genomic PCR products revealed that A(hvy) resulted from the integration of an intracisternal A particle (IAP) in an antisense orientation within the 5' untranslated agouti exon 1C. This retrovirus-like element is responsible for deregulating agouti expression in A(hvy) mice; agouti expression is correlated with the methylation state of CpG residues in the IAP long terminal repeat as well as in host genomic DNA. In addition, the data suggest that the variable phenotype of A(hvy) offspring is influenced in part by the phenotype of their A(hvy) female parent.     

Allelic Variation within the Emv-15 Locus Defines Genomic Sequences Closely Linked to the agouti Locus on Mouse Chromosome 2

Gene(s) at the agouti locus act within the microenvironment of the hair follicle to switch pigment synthesis in the melanocyte between eumelanin (black or brown pigment) and phaeomelanin (yellow pigment). Many phenotypic variants of this locus have been described. The mechanism(s) of gene action causing such variation in coat-color phenotype is not known. The close linkage of an endogenous ecotropic murine leukemia provirus, Emv-15, to the lethal yellow mutation of the agouti locus provides a means to molecularly access genes at or near the agouti locus. We have identified and used a unique mouse sequence flanking the Emv-15 provirus to define three alleles of the Emv-15 locus. We found a correlation between the presence of specific Emv-15 alleles and the origins of specific agouti locus mutations, confirming close linkage. However, we found some exceptions which suggest that the Emv-15 locus is closely linked to, but genetically separable from, the agouti locus.     

A second acromelanistic allelomorph at the albino locus of the Mongolian gerbil (Meriones unguiculatus)

A new autosomal recessive coat color mutant in the Mongolian gerbil (Meriones unguiculatus) is described: chinchilla medium (symbol c(chm)). The mutant has typical acromelanistic features similar to those of several acromelanistic c locus mutants of other species of mammals. Previously a more severe form of acromelanism (c(h)c(h)) has been described in the Mongolian gerbil. The new allele shows to be allelic with this form. On a nonagouti background compound heterozygotes (aac(chm)c(h)) show an intermediate phenotype that is very similar to that of the Siamese mouse (Mus musculus) and rat (Rattus norvegicus). Homozygotes (aac(chm)c(chm)) display a very dark acromelanistic phenotype reminiscent of that of the sable rabbit (Oryctolagus cuniculus). The gray phenotype (gg) in the Mongolian gerbil resembles the albino locus phenotype chinchilla (c(ch)c(ch)) in mice. We show that the new mutant is not allelic with gray. Fertility and viability of the new mutant are within normal range.     

Sulfhydryl Compounds in Melanocytes of Yellow (Ay/a ), Nonagouti (a/a), and Agouti (A/A) Mice

CLEFFMANN (1953, 1963a,b) has reported that yellow but not black melanocytes of agouti (A/A) rabbits contained reducing sulfhydryl compounds. We have attempted to repeat CLEFFMANN's observations in mouse melanocytes of the lethal yellow (Ay/a), nonagouti (a/a) and agouti (A/A) genotypes. Our results contradict those of CLEFFMANN and reveal that yellow and black melanocytes, regardless of genotype, possess equivalent amounts of histochemically detectable sulfhydryl compounds. These results do not support the hypothesis that agouti-locus genes act by controlling the sulfhydryl metabolism of pigment cells.     

Tawny: a novel light coat color mutation found in a wild population of Mus musculus molossinus, a new allele at the melanocortin 1 receptor (Mc1r) locus.

We found a new coat color mutant in a population of Japanese wild mice (Mus musculus molossinus) and called the trait tawny. The tawny mutant is characterized by a light yellowish brown coat color. The tawny hair has a so-called agouti pattern, but the yellow band is greatly lengthened. There are no differences between the tawny and wildtype hairs in size and the number of melanosomes. Genetic analyses revealed that the tawny trait is an autosomal recessive and its gene is located in the distal region on Chromosome 8 between the microsatellite markers D8Mit87 and D8Mit122. An allelism test indicated the tawny mutant gene to be a new allele at the Mc1r locus and dominant to the recessive yellow (Mc1re). The proposed gene symbol for the tawny is Mc1rtaw.     

Fox colors in relation to colors in mice and sheep

Color inheritance in foxes is explained in terms of homology between color loci in foxes, mice, and sheep. The hypothesis presented suggests that the loci A (agouti), B (black/chocolate brown pigment) and E (extension of eumelanin vs. phaeomelanin) all occur in foxes, both the red fox, Vulpes vulpes, and the arctic fox, Alopex lagopus. Two alleles are postulated at each locus in each species. At the A locus, the (top) dominant allele in the red fox, Ar, produces red color and the corresponding allele in the arctic fox, Aw, produces the winter-white color. The bottom recessive allele in both species is a, which results in the black color of the silver fox and a rare black color in the Icelandic arctic fox when homozygous. The B alleles are assumed to be similar in both species: B, dominant, producing black eumelanin, and b, recessive, producing chocolate brown eumelanin when homozygous. The recessive E allele at the E locus in homozygous form has no effect on the phenotype determined by alleles at the A locus, while Ed, the dominant allele is epistatic to the A alleles and results in Alaska black in the red fox and the dark phase in the arctic fox. Genetic formulae of various color forms of red and arctic fox and their hybrids are presented.     

虹鳟mc1r基因的克隆、序列分析及在 不同发育阶段和组织的表达分析

黑素皮质素1受体基因(mc1r)是控制动物色素合成的重要基因,为探讨mc1r基因与虹鳟(Oncorhynchus mykiss)体色变异的关系,本研究利用cDNA末端快速扩增(RACE)技术获得虹鳟mc1r基因的cDNA全长序列,并对其编码的蛋白进行了生物信息学分析,同时利用实时荧光定量PCR(qRT-PCR)分析该基因在野生型虹鳟(虹鳟)和黄色突变型虹鳟(金鳟)体色发生不同时期(从受精期至12月龄)及成鱼背部皮肤、腹部皮肤、背部肌肉、腹部肌肉、眼、脑、鳃、中肾、头肾、肠、肝、脾和心13种组织中的表达差异。结果显示,mc1r基因序列全长为4 518 bp,开放阅读框1 017 bp,编码338个氨基酸。氨基酸序列分析发现,虹鳟Mc1r蛋白具有7TM_GPCR_Srsx结构域。通过氨基酸序列同源比对与系统进化分析表明,Mc1r蛋白序列在鱼类间具有较高的保守性。qRT-PCR结果表明,mc1r基因在虹鳟与金鳟的受精期就开始表达,且在受精期至桑葚期胚胎的表达量高于胚胎后期;mc1r基因在虹鳟与金鳟相同时期表达比较结果显示,该基因在受精期、4细胞期、16细胞期、囊胚期、原肠期、神经期、体节期、1日龄、3日龄、7日龄胚胎或个体以及1月龄、2月龄、3月龄和6月龄背部皮肤中的表达均差异显著(P 0.05);mc1r基因在12月龄虹鳟和金鳟的13种组织中均有表达,其中,该基因在虹鳟与金鳟的背部皮肤、腹部皮肤和脑中的表达量较高,显著高于其他组织(P 0.05),且虹鳟背部皮肤中该基因的表达量高于金鳟背部皮肤(P 0.05)。以上结果表明,mc1r基因可能与虹鳟体色变异密切相关。本研究可为后期进一步深入阐明虹鳟体色变异的分子机制提供基础资料。