A missense mutation in the endothelin-B receptor gene is associated with Lethal White Foal Syndrome: an equine version of Hirschsprung Disease

Lethal White Foal Syndrome is a disease associated with horse breeds that register white coat spotting patterns. Breedings between particular spotted horses, generally described as frame overo, produce some foals that, in contrast to their parents, are all white or nearly all white and die shortly after birth of severe intestinal blockage. These foals have aganglionosis characterized by a lack of submucosal and myenteric ganglia from the distal small intestine to the large intestine, similar to human Hirschsprung Disease. Some sporadic and familial cases of Hirschsprung Disease are due to mutations in the endothelin B receptor gene (EDNRB). In this study, we investigate the role of EDNRB in Lethal White Foal Syndrome. A cDNA for the wild-type horse endothelin-B receptor gene was cloned and sequenced. In three unrelated lethal white foals, the EDNRB gene contained a 2-bp nucleotide change leading to a missense mutation (I118K) in the first transmembrane domain of the receptor, a highly conserved region of this protein among different species. Seven additional unrelated lethal white foal samples were found to be homozygous for this mutation. No other homozygotes were identified in 138 samples analyzed, suggesting that homozygosity was restricted to lethal white foals. All (40/40) horses with the frame overo pattern (a distinct coat color pattern that is a subset of overo horses) that were tested were heterozygous for this allele, defining a heterozygous coat color phenotype for this mutation. Horses with tobiano markings included some carriers, indicating that tobiano is epistatic to frame overo. In addition, horses were identified that were carriers but had no recognized overo coat pattern phenotype, demonstrating the variable penetrance of the mutation. The test for this mutant allele can be utilized in all breeds where heterozygous animals may be unknowingly bred to each other including the Paint Horse, Pinto horse, Quarter Horse, Miniature Horse, and Thoroughbred. Received: 25 November 1997 / Accepted: 3 February 1998     

Kit基因对白马被毛褪色的影响

马毛色是品种鉴定和个体识别的重要依据,也是制定育种方案时必须考虑的重要性状之一。因此,研究马被毛褪色已成为当今国际马毛色研究领域的重要内容,试图弄清导致马被毛褪色的真正机理。目前已经发现,许多马种被毛褪色表型个体中3号染色体上的kit基因存在不同的显著突变。研究结果表明马kit基因的正常表达与否与表皮中黑色素细胞及黑色素的形成密切相关,从而控制是否出现褪色表型。然而,研究证明在不同马种间褪色表型个体在该位点上出现的突变存在着较大的种间差异。具有被毛完全褪色表型的马群非常少见,只是偶尔见于有些马种,但在内蒙古锡林郭勒盟西乌珠穆沁旗生存着较大数量的被毛褪色表型个体,被称为蒙古白马。然而,造成其被毛褪色的机理还没有得到证实,有趣的是至今为止在蒙古白马kit基因的21个外显子中还没有发现任何典型突变。因此,文章对近些年国际上对马被毛褪色的分子研究进展做一比较系统的综合叙述,为蒙古白马毛色形成的机理研究奠定基础,为今后的马匹毛色研究及其育种工作提供有价值的参考依据。     

Chinese white Rongchang pig does not have the dominant white allele of KIT but has the dominant black allele of MC1R

The mast/stem cell growth factor receptor (KIT) and melanocortin receptor 1 (MC1R) mutations are responsible for coat color phenotypes in domestic pigs. Rongchang is a Chinese indigenous pig breed with a white coat color phenotype. To investigate the genetic variability of the KIT and MC1R genes and their possible association with the coat color phenotype in this breed, a gene duplication and splice mutation of KIT were diagnosed in a sample of 93 unrelated Rongchang animals. The results show that Rongchang pigs have a single copy of KIT without the splice mutation at the first nucleotide of intron 17, indicating that the dominant white I allele of KIT is not responsible for their white phenotype. The KIT mRNA and MC1R coding sequences were also determined in this breed. Three putative amino acid substitutions were found in the KIT gene between Rongchang and Western white pigs, their association with the Rongchang white phenotype remains unknown. For the MC1R gene, Rongchang pigs were demonstrated to have the same dominant black allele (E(D1)) as other Chinese breeds, supporting the previous conclusion that Chinese and Western pigs have independent domestication origin. We also clarified that the Rongchang white phenotype was recessive to nonwhite color phenotypes. Our results provide a good starting point for the identification of the mutations underlying the white coat color in Rongchang pigs.     

白色基因座(I)在中国地方猪种毛色遗传中的作用研究

通过利用PCR—RFLP和PCR—SSCP技术对中国地方猪种KIT基因内含子17、18的序列进行多态性分析。结果表明：内含子17上的替换突变(G→A)发生于毛色为白色的个体——白色五指山猪、大白猪、长白猪上,其基因型(AB型)频率分别为1、1和0．8;其他中国地方猪种的此基因型频率均为0。内含子18上的缺失突变(AGTT)也同样发生在上述3个猪种的白色个体中,其基因型(AA型)频率分别为1、1和0．93;而且同样在其他的地方品种中其基因型频率均为0。这充分证明KIT基因对于猪的白毛色有重要的调控作用,而且I基因座对于其他的经典遗传基因座有上位作用。另一方面,中国地方猪种荣昌猪虽然在表型上与引入猪种大白猪、长白猪相似(白毛色),但是在KIT基因上发生的突变完全不同,推测它们分别属于不同的毛色遗传体系。     

A new inbred strain JF1 established from Japanese fancy mouse carrying the classic piebald allele

A new inbred strain JF1 (Japanese Fancy Mouse 1) was established from a strain of fancy mouse. Morphological and genetical analysis indicated that the mouse originated from the Japanese wild mouse, Mus musculus molossinus. JF1 has characteristic coat color, black spots on the white coat, with black eyes. The mutation appeared to be linked to an old mutation piebald (s). Characterization of the causative gene for piebald, endothelin receptor type B (ednrb), demonstrated that the allele in JF1 is same as that of classic piebald allele, suggesting an identical origin of these two mutants. Possibly, classic piebald mutation was introduced from the Japanese tame mouse, which was already reported at the end of the 1700s. We showed that JF1 is a useful strain for mapping of mutant genes on laboratory strains owing to a high level of polymorphisms in microsatellite markers between JF1 and laboratory strains. The clarified genotypes of JF1 for coat color are ``aa BB CC DD ss'. Received: 30 May 1997 / Accepted: 26 August 1997     

A blond coat color variation in meadow vole (Microtus pennsylvanicus)

Color mutations occur frequently among rodents. Here we describe a blond coat color mutation in the meadow vole (Microtus pennsylvanicus) that arose in a captive breeding colony established from wild-caught animals from southern Illinois. The blond coat coloration results from changes in the color and distribution of pigments in the hair. The mutation is monogenic autosomal recessive.     

Allelic heterogeneity at the equine KIT locus in dominant white (W) horses

White coat color has been a highly valued trait in horses for at least 2,000 years. Dominant white (W) is one of several known depigmentation phenotypes in horses. It shows considerable phenotypic variation, ranging from ~50% depigmented areas up to a completely white coat. In the horse, the four depigmentation phenotypes roan, sabino, tobiano, and dominant white were independently mapped to a chromosomal region on ECA 3 harboring the KIT gene. KIT plays an important role in melanoblast survival during embryonic development. We determined the sequence and genomic organization of the ~82 kb equine KIT gene. A mutation analysis of all 21 KIT exons in white Franches-Montagnes Horses revealed a nonsense mutation in exon 15 (c.2151C>G, p.Y717X). We analyzed the KIT exons in horses characterized as dominant white from other populations and found three additional candidate causative mutations. Three almost completely white Arabians carried a different nonsense mutation in exon 4 (c.706A>T, p.K236X). Six Camarillo White Horses had a missense mutation in exon 12 (c.1805C>T, p.A602V), and five white Thoroughbreds had yet another missense mutation in exon 13 (c.1960G>A, p.G654R). Our results indicate that the dominant white color in Franches-Montagnes Horses is caused by a nonsense mutation in the KIT gene and that multiple independent mutations within this gene appear to be responsible for dominant white in several other modern horse populations.     

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。     

利用混合样本池法对鸡显性白羽基因PMEL17突变位点的检测

显性白羽基因座是影响鸡羽色形成的重要基因座位之一, 该基因座上的显性等位基因I 会抑制黑色素合成, 从而使携带该基因的个体全身羽毛呈现白色。目前已确认鸡显性白羽基因座编码PMEL17蛋白: 是一种黑素细胞特异性蛋白, 在黑素细胞的分化与成熟中起到重要作用, 并证明PMEL17基因的突变与显性白羽的形成有关。文章利用混合样本池建立了一种低成本、高效率, 并能在大规模群体中检测PMEL17基因突变的方法, 称为PCR产物混合样本池法。该方法的基本步骤如下: 首先, 提取个体基因组DNA, 并设计相关引物对每一个体单独进行PCR扩增; 其次, 将PCR产物等比例混合, 10个样品混在一个池中; 然后, 将PCR产物混合池样品于非变性聚丙烯酰胺凝胶上进行电泳; 最后, 待电泳结束后进行银染, 根据凝胶上所显条带判定是否存在突变体。此外, 文章还将这种方法与传统基因组DNA混合样本池法进行了比较试验, 并利用该方法对试验鸡群显性白羽基因PMEL17突变进行检测, 证实该方法具有较高准确度。     

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 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.     

豚鼠气管平滑肌化学介质敏感性与体征表型的相关性

目的研究豚鼠体征表型与气管平滑肌化学介质敏感性的相关性。方法根据体征表型眼睛颜色、毛色、性别差异选取36只豚鼠,将动物按体征表型分为白色黑眼雌性组（WBEF）,白色黑眼雄性组（WBEM）,白色红眼雌性组（WREF）,白色红眼雄性组（WREM）,杂色黑眼雌性组（VBEF）,杂色黑眼雄性组（VBEM）,每组动物各6只。用旋割法制备离体豚鼠气管螺旋条,以组胺histamine（浴槽浓度2.0×10^-3g/L）和乙酰胆碱acetylcholine（浴槽浓度2.0×10^-4g/L）诱导气管螺旋条收缩,用BL420生物信号采集系统与张力传感器测定标本张力变化值,分析豚鼠眼睛颜色、毛色、性别与组胺、乙酰胆碱诱导的气管螺旋条收缩效应强弱的关系。数据采用SPSS 11.5软件在α=0.05的信度下进行单因素方差检验。结果豚鼠毛色与眼睛颜色表型其气管平滑肌化学介质敏感性差异有显著性（P〈0.05）,白色体征表型豚鼠的气管平滑肌化学介质敏感性较杂色表型高,红色眼睛表型较黑色眼睛表型高。性别表型对其介质敏感性差异不显著。结论毛色、眼睛颜色表型不同其豚鼠气管平滑肌化学介质敏感性差异显著,性别表型不同其介质敏感性差异不显著,平喘动物模型宜优先选择白色红眼表型豚鼠。     

Slc7a11基因在不同被毛颜色哈萨克羊皮肤组织中的表达分析

Slc7a11基因属于溶质转运家族,编码胱氨酸/谷氨酸xCT转运载体,经证实该基因调控黑色素与伪黑色素的转换。文章利用实时荧光定量PCR技术分析Slc7a11基因在3种不同毛色哈萨克绵羊羔羊皮肤组织中的mRNA转录水平,构建原核表达载体,诱导表达融合蛋白,并对包涵体蛋白进行纯化,免疫新西兰大白兔制备抗血清,最后检测不同毛色皮肤中该蛋白的表达水平。结果表明,Slc7a11基因在3种毛色皮肤中的表达水平有显著差异,棕色被毛皮肤中表达水平最高,其次是黑色,在白色中表达最少。利用纯化的融合蛋白制备多克隆抗体,发现sxCT蛋白在棕色被毛中表达最高,其次是黑色,白色最低,因此,Slc7a11基因可能与哈萨克绵羊毛色表型有相关性。     

The dominant-white spotting (W) locus of the mouse encodes the c-kit proto-oncogene

Mutations at the W locus in the mouse have pleiotropic effects on embryonic development and hematopoiesis. The characteristic phenotype of mutants at this locus, which includes white coat color, sterility, and anemia, can be attributed to the failure of stem cell populations to migrate and/or proliferate effectively during development. Mapping experiments suggest that the c-kit proto-oncogene, which encodes a putative tyrosine kinase receptor, is a candidate for the W locus. We show here that the c-kit gene is disrupted in two spontaneous mutant W alleles, W44 and Wx. Genomic DNA that encodes amino acids 240 to 342 of the c-kit polypeptide is disrupted in W44; the region encoding amino acids 342 to 791 is disrupted in Wx. W44 homozygotes exhibit a marked reduction in levels of c-kit mRNA. These results strongly support the identification of c-kit as the gene product of the W locus.     

A missense mutation in the gene for melanocyte-stimulating hormone receptor (MCIR) is associated with the chestnut coat color in horses

The melanocyte-stimulating hormone receptor gene (MC1R) is the major candidate gene for the chestnut coat color in horses since it is assumed to be controlled by an allele at the extension locus. MC1R sequences were PCR amplified from chestnut (e/e) and non-chestnut (E/−) horses. A single-strand conformation polymorphism was found that showed a complete association to the chestnut coat color among 144 horses representing 12 breeds. Sequence analysis revealed a single missense mutation (83Ser → Phe) in the MC1R allele associated with the chestnut color. The substitution occurs in the second transmembrane region, which apparently plays a key role in the molecule since substitutions associated with coat color variants in mice and cattle as well as red hair and fair skin in humans are found in this part of the molecule. We propose that the now reported mutation is likely to be the causative mutation for the chestnut coat color. The polymorphism can be detected with a simple PCR-RFLP test, since the mutation creates a TaqI restriction site in the chestnut allele. Received: 20 May 1996 / Accepted: 31 July 1996     

Variation of coat color in house mice throughout Asia

Coat color variation due to melanin pigment synthesis in house mice Mus musculus in Asia is described and found to be consistent with Gloger's rule, which states that individuals of endothermic animals are darker in humid habitats than those in drier habitats. Three properties of coat color (hue, value and chroma) were measured, and a lightness variable was derived from a principal components analysis using 428 skin specimens representing three subspecies from 85 localities. Dorsal coat color ranged from yellow through brown to black, whereas ventral coat color ranged from white to black. Dorsal coat color varied less than the ventral color. In our samples, the variation in coat color in natural populations was far less than that observed in the laboratory. We found a significant correlation between the lightness variable of dorsal coat color and precipitation. Dark coat color was observed in more humid and closed habitats (darker background color), and pale coat color in drier, more open habitats (lighter background color). This result might imply the role of concealment as a selective force affecting dorsal coat color that was observed in house mice. We also discussed other selective forces that could affect the coat color variation in house mice, such as resistance to bacterial degradation and thermoregulation. In addition, the color spectra of the dorsal pelage among the three subspecies were different, the major distinction being the environmental background color of the habitats in which they are distributed.     

Effects of a Locus Affecting Floral Pigmentation in Ipomoea Purpurea on Female Fitness Components

A locus influencing floral pigment intensity in the morning glory, Ipomoea purpurea, is polymorphic throughout the southeastern United States. Previous work has suggested that the white allele at this locus has a transmission advantage during mating because of the effect of flower color on pollinator behavior. The experiment described here was designed to determine whether other effects of the W locus may contribute an opposing selective advantage to the dark allele. Dark homozygotes were vegetatively smaller and produced fewer flowers, seed capsules and seeds than either light heterozygotes or white homozygotes. In addition, dark homozygotes produced smaller seeds than heterozygotes, and there is some indication that white homozygotes also produced smaller seeds than heterozygotes. Pleiotropic effects on seed number thus do not seem to contribute to selection opposing the mating advantage associated with the white allele. However, pleiotropic effects on seed size might contribute to overdominance that could stabilize the W locus polymorphism.