Genetic Studies of the Mouse Mutations Mahogany and Mahoganoid

The mouse mutations mahogany (mg) and mahoganoid (md) are negative modifiers of the Agouti coat color gene, which encodes a paracrine signaling molecule that induces a switch in melanin synthesis from eumelanin to pheomelanin. Animals mutant for md or mg synthesize very little or no pheomelanin depending on Agouti gene background. The Agouti protein is normally expressed in the skin and acts as an antagonist of the melanocyte receptor for α-MSH (Mc1r); however, ectopic expression of Agouti causes obesity, possibly by antagonizing melanocortin receptors expressed in the brain. To investigate where md and mg lie in a genetic pathway with regard to Agouti and Mc1r signaling, we determined the effects of these mutations in animals that carried either a loss-of-function Mc1r mutation (recessive yellow, Mc1r(e)) or a gain-of-function Agouti mutation (lethal yellow, A(y)). We found that the Mc1r(e) mutation suppressed the effects of md and mg, but that md and mg suppressed the effects of A(y) on both coat color and obesity. Plasma levels of α-MSH and of ACTH were unaffected by md or mg. These results suggest that md and mg interfere directly with Agouti signaling, possibly at the level of protein production or receptor regulation.     

Recessive yellow in the Mongolian gerbil (Meriones unguiculatus)

A new autosomal recessive coat color mutant in the Mongolian gerbil (Meriones unguiculatus) is described: recessive yellow. On the dorsal side the mutant has a rich yellow to ginger color. Ventrally it shows the typical creamy white belly of a wild-type Mongolian gerbil. The dorsal yellow hairs have short black tips, and a light olive green base. A clear demarcation line between dorsal and ventral color is present. Crosses between recessive yellow animals and multiple homozygous recessive tester animals (a/a; c^chm/c^chm; g/g; p/p) resulted only in animals of an agouti (wild-type) phenotype, showing that the new allele is not allelic with any of the known coat color mutations in the Mongolian gerbil. Molecular studies showed that the new mutant is caused by a missence mutation at the extension (E) locus. On a non-agouti background (a/a; e/e) mutant animals look like a dark wild-type agouti. In contrast to wild-type agouti it shows yellow pigmentation and dark ticking at the ventral side, resulting in the absence of a demarcation line. Since black pigment is present in both the agouti and non-agouti variant (A/A; e/e and a/a; e/e), we conclude that recessive yellow in the Mongolian gerbil is non-epistatic to agouti. Additionally we describe a second mutation at the same locus leading to a similar phenotype, however without black pigment and diminishing yellow pigment during life. Fertility and viability of both new mutants are within normal range. The extension (E) gene is known to encode the melanocortin 1 receptor (MC1R). Interestingly, this is the only gene that is known to account for substantial variation in skin and hair color in humans. Many different mutations are known of which some are associated with higher skin cancer incidence.     

Melanocortin 1 receptor variation in the domestic dog

The melanocortin 1 receptor (Mc1r) is encoded by the Extension locus in many different mammals, where a loss-of-function causes exclusive production of red/yellow pheomelanin, and a constitutively activating mutation causes exclusive production of black/brown eumelanin. In the domestic dog, breeds with a wild-type E allele, e.g., the Doberman, can produce either pigment type, whereas breeds with the e allele, e.g., the Golden Retriever, produce exclusively yellow pigment. However, a black coat color in the Newfoundland and similar breeds is thought to be caused by an unusual allele of Agouti, which encodes the physiologic ligand for the Mc1r. Here we report that the predicted dog Mc1r is 317 residues in length and 96% identical to the fox Mc1r. Comparison of the Doberman, Newfoundland, Black Labrador, Yellow Labrador, Flat-coated Retriever, Irish Setter, and Golden Retriever revealed six sequence variants, of which two, S90G and R306ter, partially correlated with a black/brown coat and red/yellow coat, respectively. R306ter was found in the Yellow Labrador, Golden Retriever, and Irish Setter; the latter two had identical haplotypes but differed from the Yellow Labrador at three positions other than R306ter. In a larger survey of 194 dogs and 19 breeds, R306ter and a red/yellow coat were completely concordant except for the Red Chow. These results indicate that the e allele is caused by a common Mc1r loss-of-function mutation that either reoccurred or was subject to gene conversion during recent evolutionary history, and suggest that the allelic and locus relationships for dog coat color genes may be more analogous to those found in other mammals than previously thought.     

拟南芥种皮色素形成突变体的筛选与表型鉴定

类黄酮在植物应答各种环境胁迫和种皮发育调控中起着重要作用。通过甲基磺酸乙酯（EMS）诱变筛选获得1个透明种皮突变体,与野生型拟南芥（Arabidopsis thaliana）(Col-0)相比,突变体成熟的种子颜色为黄色,其表型性状由隐性单基因控制。利用图位克隆和精细定位技术将突变基因定位于5号染色体MAH20的BAC上,是TT4(At5G13930)基因的第1 299位碱基C突变为T,使得第324位氨基酸甘氨酸突变为谷氨酸。TT4(transparent testa 4)编码1个类黄酮合成的结构基因查尔酮合酶（CHS）,突变后种皮透明,种子颜色为黄色,突变体命名为tt4-1。利用功能回补突变体恢复褐色种皮表型,进一步证明了TT4在调节种皮颜色发育过程的重要作用。启动子偶联GUS基因组织表达分析显示TT4基因在植株幼苗的根、茎、叶和花中均有表达,生理表型分析结果显示与野生型相比,突变体tt4-1种子萌发早,幼苗主根短、侧根和根毛较多,成苗叶片气孔开度大和失水率高等特性。该研究将为进一步阐述TT4基因功能奠定理论依据。     

Exclusion of melanocortin-1 receptor (mc1r) and agouti as candidates for dominant black in dogs

The domestic dog exhibits a variety of coat colors that encompass a wide range of variation among different breeds. Very little is known about the molecular biology of dog pigmentation; current understanding is based mostly on traditional breeding experiments, which in some cases have suggested genetic interactions that are different from those reported in other mammals. We have examined the molecular genetics of dominant black, a uniform coat color characteristic of black Labrador retrievers or Newfoundlands that has been proposed to be caused by either variation in the melanocortin-1 receptor gene (Mc1r) or by variation in the Agouti gene (A). We identified several coding polymorphisms within Mc1r and several simple sequence repeat polymorphisms closely linked to A, and examined their inheritance in a Labrador retriever x greyhound cross that segregates dominant black. No single Mc1r allele was found consistently in animals carrying dominant black, and neither Mc1r nor A cosegregated with dominant black. These results refine our understanding of mammalian coat color inheritance and suggest that dominant black coat color in dogs is caused by a gene not previously implicated in pigment type switching.     

Skin layer-specific transcriptional profiles in normal and recessive yellow (Mc1re/Mc1re) mice

The melanocortin 1 receptor (Mc1r) plays a central role in cutaneous biology, but is expressed at very low levels by a small fraction of cells in the skin. In humans, loss-of-function MC1R mutations cause fair skin, freckling, red hair, and increased predisposition to melanoma; in mice, Mc1r loss-of-function is responsible for the recessive yellow mutation, associated with pheomelanic hair and a decreased number of epidermal melanocytes. To better understand how Mc1r signaling affects different cutaneous phenotypes, we examined large-scale patterns of gene expression in different skin components (whole epidermal sheets, basal epidermal cells and whole skins) of neonatal (P2.5) normal and recessive yellow mice, starting with a 26K mouse cDNA microarray. From c. 17 000 genes whose levels could be accurately measured in neonatal skin, we identified 883, 2097 and 552 genes that were uniquely expressed in the suprabasal epidermis, basal epidermis and dermis, respectively; specific biologic roles could be assigned for each class. Comparison of normal and recessive yellow mice revealed 69 differentially expressed genes, of which the majority had not been previously implicated in Mc1r signaling. Surprisingly, many of the Mc1r-dependent genes are expressed in cells other than melanocytes, even though Mc1r expression in the skin is confined almost exclusively to epidermal melanocytes. These results reveal new targets for Mc1r signaling, and point to a previously unappreciated role for a Mc1r-dependent paracrine effect of melanocytes on other components of the skin.     

Ragged--a new rexoid mutant rat with large sebaceous gland

A new hair defected mutant rat was established. This mutant was covered with ragged hair since about 10 days of age, then transiently lost most of hair in the back at approximately 5 weeks of age and re-covered with ragged hair thereafter. Thickened eyerids occurred since about 3 weeks of age. Histological examination revealed enlarged sebaceous glands with greater number of sebaceous cells in the back skin. The oil stained skin samples showed normal sebaceous transformation and pilosebaceous canal. Genetical analysis showed that the ragged hair character was a single recessive trait and indicated that this single recessive gene was not linked with the coat color genes, non-agouti (a), albino (c) and hooded (h). From the present data and previous reports, we recommended this single recessive gene is a new rexoid mutation thereby we termed this gene "Ragged (rg)".     

白色獭兔蓝眼突变体的发现与遗传分析

文章设计了杂交、回交和全同胞交配3个实验, 对美系白色獭兔(♂)和青紫蓝肉兔(♀)杂交所产生的白色蓝眼獭兔突变体的遗传机制进行了等位性测试。结果表明, 白色獭兔蓝眼突变体是维也纳座位(V)发生隐性突变的结果。基因v纯合(vv)对家兔基本毛色基因座(A、B、C、D、E)具有隐性上位作用, 无论其他毛色座位的基因型如何, 只要vv存在即可产生白色蓝眼兔。vv基因型与rr基因型组合即可产生白色蓝眼獭兔。白色蓝眼獭兔突变体在我国家兔育种中是一个新发现, 其遗传机制的阐明, 对獭兔育种和生产具有重要的指导意义。     

Uncv (uncovered): a new mutation causing hairloss on mouse chromosome 11.

A pair of mutant mice with a first sparse coat appeared spontaneously in the production stock of BALB/c mice with a normal coat. After being sib-mated, they produced three phenotypes in their progeny: mice with normal hair, mice with a first sparse coat and then a fuzzy coat, and uncovered mice. Genetic studies revealed the mutants had inherited an autosomal monogene that was semi-dominant. By using 11 biochemical loci--Idh, Car2, Mup1, Pgm1, Hbb, Es1, Es10, Gdc, Ce2, Mod1 and Es3--as genetic markers, two-point linkage tests were made. The results showed the gene was assigned to chromosome 11. The result of a three-point test with Es3 and D11Mit8 (microsatellite DNA) as markers showed that the mutation was linked to Es3 with the recombination fraction 7.89 +/- 2.19%, and linked to D11Mit8 with the recombination fraction 26.30 +/- 3.57%. The recombination fraction between Es3 and D11Mit8 was 32.90 +/- 3.81%. It is suggested that the mutation is a new genetic locus that affected the skin and hair structure of the mouse. The mutation was named uncovered, with the symbol Uncv. Further studies showed the mutation affected not only the histology of skin and hair but also the growth and reproductive performance of the mice. The molecular characterization of the Uncv locus needs to be further studied.     

Platinum coat color locus in the deer mouse

Platinum coat color in the deer mouse, Peromyscus maniculatus, is an autosomal recessive trait marking a locus, pt, distinct from silver (si), albino (c), blonde (bl), brown (b), and agouti (a). Platinum deer mice are conspicuously pale, with light ears and tail stripe. The pewter trait is allelic with and phenotypically identical to platinum, and represents an independent recurrence of this mutant. The rate of recoveries of coat color mutations from wild deer mice is consistent with available data for recurring mutation rates balanced by strong selection against the recessive phenotype.     

Sequence analysis of three pigmentation genes in the Newfoundland population of Canis latrans links the Golden Retriever Mc1r variant to white coat color in coyotes

Three genes, Mc1r, Agouti, and CBD103, interact in a type-switching process that controls much of the pigmentation variation observed in mammals. A deletion in the CBD103 gene is responsible for dominant black color in dogs, while the white-phased black bear (“spirit bear”) of British Columbia, Canada, is the lightest documented color variant caused by a mutation in Mc1r. Rare all-white animals have recently been discovered in a new northeastern population of the coyote in insular Newfoundland and Labrador, Canada. To investigate the causative gene and mutation of white coat in coyotes, we sequenced the three type-switching genes in white and dark-phased animals from Newfoundland. The only sequence variants unambiguously associated with white color were in Mc1r, and one of these variants causes the amino acid variant R306Ter, a premature stop codon also linked to coat color in Golden Retrievers and other dogs with yellow/red coats. The allele carrying R306Ter in coyotes matches that in the Golden Retriever at other variable amino acid sites and hence may have originated in these dogs. Coyotes experienced introgression with wolves and dogs as they colonized northeastern North America, and coyote/Golden Retriever interactions have been observed in Newfoundland. We speculate that natural selection, with or without a founder effect, may contribute to the observed frequency of white coyotes in Newfoundland, as it has contributed to the high frequency of white bears, and of a domestic dog-derived CBD allele in gray wolves.     

The genetics of adaptive coat color in gophers: coding variation at Mc1r is not responsible for dorsal color differences

The genetics of adaptation is a key problem in evolutionary biology. Pocket gophers of the species Thomomys bottae provide one of the most striking examples of coat color variation in mammals. Dorsal pelage color is strongly correlated with soil color across the range of the species, presumably reflecting the selective pressure exerted by predation. To investigate the genetic basis of coat color variation in T. bottae, we cloned and sequenced the melanocortin-1 receptor locus (Mc1r), a candidate pigmentation gene, in 5 dark and 5 light populations of the species. Our results show that, in contrast to many other species of mammals and other vertebrates, coding variation at Mc1r is not the main determinant of coat color variation in T. bottae. These results demonstrate that similar phenotypic variation may have a different genetic basis among different mammalian species.     

Ecological genetics of adaptive color polymorphism in pocket mice: geographic variation in selected and neutral genes

Patterns of geographic variation in phenotype or genotype may provide evidence for natural selection. Here, we compare phenotypic variation in color, allele frequencies of a pigmentation gene (the melanocortin-1 receptor, Mc1r), and patterns of neutral mitochondrial DNA (mtDNA) variation in rock pocket mice (Chaetodipus intermedius) across a habitat gradient in southern Arizona. Pocket mice inhabiting volcanic lava have dark coats with unbanded, uniformly melanic hairs, whereas mice from nearby light-colored granitic rocks have light coats with banded hairs. This color polymorphism is a presumed adaptation to avoid predation. Previous work has demonstrated that two Mc1r alleles, D and d, differ by four amino acids, and are responsible for the color polymorphism: DD and Dd genotypes are melanic whereas dd genotypes are light colored. To determine the frequency of the two Mc1r allelic classes across the dark-colored lava and neighboring light-colored granite, we sequenced the Mc1r gene in 175 individuals from a 35-km transect in the Pinacate lava region. We also sequenced two neutral mtDNA genes, COIII and ND3, in the same individuals. We found a strong correlation between Mc1r allele frequency and habitat color and no correlation between mtDNA markers and habitat color. Using estimates of migration from mtDNA haplotypes between dark- and light-colored sampling sites and Mc1r allele frequencies at each site, we estimated selection coefficients against mismatched Mc1r alleles, assuming a simple model of migration-selection balance. Habitat-dependent selection appears strong but asymmetric: selection is stronger against light mice on dark rock than against melanic mice on light rock. Together these results suggest that natural selection acts to match pocket mouse coat color to substrate color, despite high levels of gene flow between light and melanic populations.     

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。     

The inheritance of seed color in a resynthesizedBrassica napus line No. 2127-17 including a new epistatic locus

Yellow seed is an important trait inBrassica napus. To know the genet ic basis of yellow seed color inBrassica napus, we carried out genetic studies by using conventional genetics analyses. The conventional genetics was studied in generations (F1 F2 reciprocal F2, BC1, and F23) ofB. napus derived from crosses between a yellow-seeded (No. 2127-17) and nine different black-seeded parents. The results indicated that seed color was mainly controlled by the maternal genotype but influenced by the interact ion between the maternal and endosperm and/or embryonic genotypes. In the combinations which included black-seeded lines SW0780, 94560, 94545 and 1141B, the yellow seed is partially dominant over black with two or three dominance epistasis ratio. A dominant yellow-seeded gene Y which exhibits epistatic effects on the two independent dominant black-seeded genes B and C was ident ified in DH line No. 2127-17. These observations are in agreement with our previous reports. But in the rests, including the crosses with HS No.4, HS No. 3, XY No. 15, 94570 and ZS No. 10, the black seed color was dominant over yellow seed color. The inheritance of this trait in the segregating populations fits the model of a digenic dominance epistasis or triplicate dominance epistasis. A new locus was identified and designated as D: the dominant gene D for black seed color inhibits the dominant gene Y. Therefore, in combination with the Y, B and C, we found that the seed color was influenced by at least four genes. Identifying seed color genes and defining their inheritance should further our understanding of yellow seed color trait and facilitate development of new and better yellow-seeded cult ivars ofBrassics napus.     

Generation and mapping of SCAR and CAPS markers linked to the seed coat color gene in Brassica napus using a genome-walking technique.

The yellow seed coat trait in No. 2127-17, a resynthesized purely yellow Brassica napus line, is controlled by a single partially dominant gene, Y. A double-haploid population derived from the F1 of No. 2127-17 x 'ZY821' was used to map the seed coat color phenotype. A combination of AFLP analysis and bulked segregant analysis identified 18 AFLP markers linked to the seed coat color trait. The 18 AFLP markers were mapped to a chromosomal region of 37.0 cM with an average of 2.0 cM between adjacent markers. Two markers, AFLP-K and AFLP-H, bracketed the Y locus in an interval of 1.0 cM, such that each was 0.5 cM away from the Y locus. Two other markers, AFLP-A and AFLP-B, co-segregated with the seed color gene. For ease of use in breeding programs, these 4 most tightly linked AFLP markers were converted into reliable PCR-based markers. SCAR-K, which was derived from AFLP-K, was assigned to linkage group 9 (N9) of a B. napus reference map consisting of 150 commonly used SSR (simple sequence repeat) markers. Furthermore, 2 SSR markers (Na14-E08 and Na10-B07) linked to SCAR-K on the reference map were reversely mapped to the linkage map constructed in this study, and also showed linkage to the Y locus. These linked markers would be useful for the transfer of the dominant allele Y from No. 2127-17 to elite cultivars using a marker-assisted selection strategy and would accelerate the cloning of the seed coat color gene.     

Genetic mapping of the polycystic kidney gene,pcy, on mouse chromosome 9

The murine polycystic kidney disease gene,pcy, is an autosomal recessive trait located on chromosome 9. To determine the genetic locus ofpcy, 222 intraspecific backcross mice were obtained by mating C57BL/6FG-pcy andMus molossinus. Restriction fragment length polymorphism analysis of 70 of the 222 backcross progeny showed thatpcy, dilute coat color (d), and cholecystokinin (Cck) were located in the orderd—pcy—Cck from the centromere. Simple sequence repeat length polymorphism analysis of DNA of all 222 backcross mice was carried out using four markers which were located near the central regions ofd andCck. One and eight recombinations were detected betweenD9Mit24 andpcy and betweenD9Mit16 andpcy, respectively. However, no recombinant was observed amongpcy, D9Mit14, andD9Mit148. These findings strongly suggest thatD9Mit14 andD9Mit148 are located near thepcy gene and are good markers for chromosomal walking to this gene.     

Genetic analysis of 4 new mutants at the unstable k2 Mdh1-n y20 chromosomal region in soybean

In soybean (Glycine max (L.) Merr.), a chromosomal region defined by 3 closely linked loci, k2 (tan-saddle seed coat), Mdh1-n (malate dehydrogenase 1 null), and y20 (yellow foliage), is highly mutable. A total of 31 mutants have been reported from this region. In this study, a mutation with tan-saddle seed coat was found from bulk-harvested seed of cultivar Kenwood. Genetic analysis established that this tan-saddle seed coat mutation is allelic to the k2 locus and inherited as a recessive gene. Simple sequence repeat analysis showed that this mutant is not a contaminant from other existing k2 mutants. The mutant was named Kenwood-k2. To test for genetic instability at the k2 Mdh1-n y20 chromosomal region, Kenwood-k2 was crossed reciprocally with cultivars Harosoy and Williams. No new mutants were found in F2 families. In the genetic instability tests of T239 (k2) with cultivar Williams, 3 new mutants with yellow foliage (y20) and malate dehydrogenase 1 null (Mdh1-n) were identified. In the genetic instability tests of T261 (k2 Mdh1-n) with cultivar Williams, no new mutants were found. The Kenwood-k2 and the 3 yellow-foliage, malate dehydrogenase 1-null mutants provide additional genetic materials to study chromosomal aberrations in this mutable/unstable chromosomal region.