藏獒MC1R基因多态性与毛色表型的关联研究

目的:通过检测藏獒黑素皮质激素受体1(MC1R)基因的单链构象多态性(SSCP)在不同毛色群体中的分布,探讨MC1R基因多态性与毛色表型的相关性。方法:采用DNA测序技术,选择不同毛色藏獒的DNA为样本,根据GenBank发布的荷斯坦牛MC1R基因序列设计一对引物,采用PCR-SSCP技术分析MC1R基因在藏獒中的SSCP。结果:MC1R基因在藏獒中具有PCR-SSCP多态性,分别检测到3种基因型(AA、AB和BB);对MC1R基因多态性片段DNA克隆测序后发现,MC1R基因在编码区第313位存在单碱基突变(G→A),该突变导致第105位氨基酸发生由丙氨酸向苏氨酸的改变(T105A)。结论:MC1R基因的多态性与毛色性状不存在显著的相关性。     

比格犬MC4R基因多态性与体重相关性的研究

为了分析比格犬黑素皮质素受体-4基因多态性与犬体重的关系, 根据犬MC4R基因DNA外显子序列, 设计MC4R基因特异PCR引物1对, 犬DNA经PCR扩增, 克隆和测序, 寻找和确定犬MC4R基因的多态性位点, 分析多态性与犬体重的关系。结果在比格犬MC4R基因中发现2处单碱基缺失突变, 1个单碱基颠换变异, 存在Psh AⅠ酶切位点, 并基于PshAⅠ酶切位点建立了PCR-RFLP技术。统计分析显示犬MC4R基因型与体重显著相关, 可以考虑将MC4R基因作为犬体重的候选基因。     

犬MC1R基因T105A基因座多态性及 与毛色性状相关性的研究The

为了检测犬MC1R基因T105A基因座的多态性,并分析该多态性与犬毛色表型的相关性,抽取111只外科手术学实验用杂种犬血液并提取DNA,记录毛色表型。采用PCR-RFLP技术,对MC1R基因T105A基因座进行基因多态性分析,并对该基因座DNA进行克隆测序;用二元变量相关分析的统计学方法分析基因座多态性与毛色性状之间的相关性。经PCR-RFLP分析结果表明,T105A基因座序列具有多态性,表现为A、B二个等位基因和AA、AB及BB 3种基因型。A、B等位基因频率分别为72.97%和27.03%,基因杂合度（H）为0.39。基因型AA频率为55.86%,BB为9.91%,AB为34.23%。对T105A多态性片段DNA克隆测序后发现,MC1R基因在编码第105位氨基酸的密码子第一个碱基存在由G到A的单碱基突变,该突变导致第105位氨基酸发生由丙氨酸向苏氨酸的改变。统计分析结果表明MC1R基因T105A基因座的多态性与毛色性状不存在显著的相关性,这可能是由于外科手术学实验用犬是杂种犬,其遗传背景不同所致,尚须在纯种犬群体中进一步研究MC1R基因对毛色的影响。 Abstract: In order to detect the polymorphism of T105A in MC1R gene in dogs and to analyze the relationship between the genetic polymorphisms and phenotypes of dog coat color, the blood samples of 111 cross-breed dogs were taken and their genomic DNAs were extracted. The phenotypes of dog coat color were recorded. The T105A locus of MC1R gene in the canine was detected through the technology of PCR-RFLP. Furthermore, the polymorphic fragments at T105A were sequenced. The relationships between the polymorphism of T105A and coat color trait were analyzed by the statistical methods of bivarate correlation analysis. By the method of PCR-RFLP, the T105A polymorphism was found with two alleles A and B and three genotypes AA, AB and BB. The frequencies of two alleles were 72.97% and 27.03%, respectively. The heterozygosity of T105A locus was 0.39. The frequencies of three genotypes were 55.86%, 34.23% and 9.91%, respectively. According to the results of sequencing, one base change from G to A at the position 105 was found at T105A locus and it altered amino acid at the position 105 from alanine to threonine. According to the statistical analysis, no significant association between the polymorphism of MC1R gene and the coat color was found and the result may be due to the differences of genetic background. Further research on MC1R gene should be done in pure breed dogs.     

牦牛MC1R基因的克隆测序及其分析研究

以麦洼牦牛、斯布牦牛、天祝牦牛和九龙牦牛为研究对象,对黑色素皮质素受体1(Melanocortin receptor I,MCIR)基因编码区进行了克隆测序及分析.结果表明,牦牛的MC1R基因编码区全长954 bp,编码317个氨基酸:4个牦牛品种间及与普通牛间在MC1R基因的编码区内共有13个碱基差异,无碱基的插入和缺失现象,编码蛋白共有9个氨基酸差异.MC1R蛋白为亲水性蛋白,无信号肽,有糖基化位点和7个跨膜区.系统进化分析显示,麦洼牦牛与斯布牦牛的MC1R基因相似性最近.本研究结果时今后开展MC1R基因与牦牛毛色性状的相关性分析以及牦牛的毛色遗传机理、基因定位、基因表达调控等研究具有重要的意义.     

牦牛MC1R基因的多态性研究

旨在为探究牦牛MC1R基因多态性与毛色形成的相关性,利用PCR-SSCP和DNA测序技术,对64头牦牛(33头黑色九龙牦牛,31头白色天祝白牦牛)的MC1R基因多态性进行检测。结果表明:天祝白牦牛和九龙牦牛均有3种基因型(AA、BB、AB),但天祝白牦牛的多态性较低,而九龙牦牛表现为中度多态。经χ2适合性检验,2个牦牛品种在该基因多态位点上均偏离Hardy-Weinberg平衡。测序结果表明BB型与AA型在该片段的第179位碱基处存在C→A单碱基突变;第214位碱基处发生T→C突变。     

MC1R基因多态性与豚鼠隐性黄毛色的相关性分析

豚鼠Cavia porcellus的隐性黄毛色表型是由编码黑素皮质激素受体1(MC1R)的extension基因座位的等位基因e控制。本研究对野生型和黄毛色豚鼠MC1R基因位点所在区域进行PCR扩增与测序发现,在黄毛色豚鼠中存在1个2 760 bp的基因组缺失,该缺失涵盖了MC1R基因的整个编码区。采用三引物扩增体系对豚鼠MC1R基因缺失突变进行群体基因分型,在随机选择的58只野生型个体中,36只为EE纯合子,22只为Ee杂合子,而31只黄毛色个体均为ee纯合子;在15只测交后代中,8只黄毛色个体均为ee纯合子,而7只野生型个体均为Ee杂合子。基因分型结果表明,MC1R基因2 760 bp的缺失与隐性黄毛色完全相关。本研究为进一步探究MC1R基因在哺乳动物毛色遗传机制中的作用以及豚鼠的分子标记辅助育种提供了理论依据。     

红鳍东方鲀(Takifugu rubripes)MC4R基因的多态性分析

采用PCR-SSCP(single strand conformation polymorphism)技术和DNA测序方法分析红鳍东方鲀MC4R(Melanocortin-4receptor)基因编码区多态性。在MC4R基因编码区48 nt和264 nt均发生了碱基的转换突变(G→A),两个突变位点分别位于M1和M2引物扩增产物中。引物M1扩增产物SSCP分析得到两种基因型:AA基因型和AB基因型,并且AA基因型和A等位基因频率明显高于AB基因型和B等位基因。引物M2扩增产物也得到两种基因型:CC基因型和CD基因型,CC基因型和C等位基因频率明显高于CD基因型和D等位基因。遗传变异结果分析表明,两个突变位点均属于低度多态性,而且群体遗传杂合度较低,反映了该群体的遗传一致性较高。     

鸽黑素皮质素受体3、4(MC3R、MC4R)基因多态性与生长性状的相关分析

利用PCR-SSCP技术和DNA测序方法检测广东石岐肉鸽和哈尔滨地区灰色家鸽MC3R和MC4R基因部分编码区序列的单核苷酸多态性, 分析了MC3R基因T91G突变位点和MC4R基因A903G突变位点导致的基因型与两群体鸽生长和体组成性状的关系。结果表明, 这两个多态位点所导致的基因型对石岐肉鸽活重、屠体重、全净膛重均有显著影响(P<0.05); 另外, 利用这两个突变位点所产生的合并基因型在鸽群体中与生长和体组成性状作最小二乘分析, 结果表明, 两位点合并后的基因型对全净膛重影响显著(P<0.05)。多重比较结果表明, BBAA型全净膛重显著大于AABB型, BBAA型对于体重增长是有利基因型。     

MC1R是控制鸡黑色素形成的候选主效基因

黑素皮质素受体1 (melanocortin 1-receptor, MC1R)基因是控制动物黑色素合成的重要基因.采用多聚酶链反应-单链构象多态性分析(PCR-SSCP)以及DNA测序的方法,在由丝羽乌骨鸡与明星肉鸡为亲本建立的中国农业大学资源家系群体鸡MC1R基因的编码区检测到3个单核苷酸多态位点,并对该单核苷酸多态性进行了分析.结果显示,鸡MC1R基因编码区引物3扩增片段多态性是由G→A（867位）点突变引起的,引物5扩增片段的多态性是由C→T（1 292位）与C→G（1 377位）两个点突变引起的,最后对单核苷酸多态性与肤色、肉色、胫色与内脏膜色等黑色素性状进行了卡方独立性分析,结果显示,MC1R基因编码区867处突变与鸡的肤色性状显著相关（P＜0.05）,1 292处突变与鸡的活体胫色性状显著相关（P＜0.05）,1 377处突变与鸡的肉色性状显著相关（P＜0.05）.研究表明,MC1R基因可能是鸡黑色素性状的主效基因或者与鸡控制黑色素性状的主效基因连锁.     

猪资源家系MC4R基因扫描及其与脂肪性状的相关分析

黑素皮质激素受体－4（Melanocortin-4 Receptor,MC4R)是在人类肥胖研究中发现的重要调节因子,它可以与瘦蛋白（Leptin),神经肽Y（Neuropeptide Y,NPY),α－黑素细胞刺激激素（Alpha-melanocyte-stimulating hormone,α-MSH)第一起调节动物体重和采食量。采用PCR－RFLP技术,分析了MC4R基因部分片段在猪资源家系群体中的TaqⅠ酶切片段多态性分析。MC4R基因多态性与生长肥育性状,肉质性状,胴体性状的相关性分析的结果表明,MC4R基因型频率在不同品种群体中的分布不同;MC4R基因与猪胸腰椎间膘厚,臀部膘厚,平均背膘,眼肌宽度,眼肌面积,皮率呈显著性相关。MC4R基因主要以显性作用方式发挥作用,加性作用不显著。     

Polymorphism and chromosomal location of the MC4R (melanocortin-4 receptor) gene in the dog and red fox

The melanocortin-4 receptor (MC4R) is expressed in the hypothalamus and regulates energy intake and body weight. In silico screening of the canine chromosome 1 sequence and a comparison with the porcine MC4R sequence by BLAST were performed. The nucleotide sequence of the whole coding region and 3'- and 5'-flanking regions of the dog (1214 bp) and red fox (1177 bp) MC4R gene was established and high conservation of the nucleotide sequences was revealed (99%). Five sets of PCR primers were designed and a search for polymorphism was performed by the SSCP technique in a group of 31 dogs representing nineteen breeds and 35 farm red foxes. Sequencing of DNA fragments, representing the identified SSCP patterns, revealed three single nucleotide polymorphisms (including a missense one) in dogs and four silent SNPs in red foxes. An average SNP frequency was approx. 1/400 bp in the dog and 1/300 bp in the red fox. We mapped the MC4R gene by FISH to the canine chromosome 1 (CFA1q1.1) and to the red fox chromosome 5 (VVU5p1.2).     

MC1R studies in dogs with melanistic mask or brindle patterns

Black mask is a characteristic pattern in which red, yellow, tan, fawn, or brindle dogs exhibit a melanistic muzzle which may extend up onto the ears. Melanistic mask is inherited in several breeds as an autosomal dominant trait, and appears to be a fixed trait in a few breeds of dogs. A MC1R nonsense mutation, R306ter, has been shown to cause a completely red or yellow coat color in certain breeds such as Irish setters, yellow Labrador retrievers, and golden retrievers. The amino acid sequence for the melanocortin receptor 1 gene (MC1R) was examined in 17 dogs with melanistic masks from seven breeds, 19 dogs without melanistic masks, and 7 dogs in which their coat color made the mask difficult to distinguish. We also examined nine brindle dogs of four breeds, including three dogs who also had a black mask. No consistent amino acid change was observed in the brindle dogs. All dogs with a melanistic mask had at least one copy of a valine substitution for methionine at amino acid 264 (M264V) and none were homozygous for the premature stop codon (R306ter). These results suggest that black mask, but not brindle, is caused by a specific MC1R allele.     

TYRP1 and MC1R genotypes and their effects on coat color in dogs

We used PCR amplification of cDNA prepared from skin biopsies to determine the nearly full-length, protein-coding sequence of dog TYRP1, and to define sequence variants potentially responsible for the B locus. One common variant contained a premature stop codon in exon 5 (Q331ter), and the other deleted a proline residue in exon 5 (345delP). A third variant in exon 2 (S41C) occurred less frequently. We genotyped 43 brown (including brown and white) and 34 black (including tricolor, black-and-tan, and black and white) dogs. All 43 of the brown group carried two or more of these sequence variants likely to interfere with TYRP1 function, whereas 0 of 34 in the black group carried two or more of these variants (10 carried one variant). We also genotyped 13 black-nosed and 10 brown-nosed dogs whose coat color was described as red, yellow, gold, apricot, or orange (including various degrees of white). All these dogs were homozygous for a R306X MC1R variant shown to be associated with these coat color phenotypes. The black or brown nose correlated perfectly with the absence or presence of the same three TYRP1 variants described above. TYRP1 was linkage mapped to dog chromosome 11, with a SNP in exon 7.     

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.     

黑素皮质激素受体1（MC1R）基因系统发育树与犬的毛色

犬的驯养迄今约有1万多年,由于不同环境和不同目的人工选择形成了犬品种间或品种内极丰富的毛色多样性,经证实,这些犬的很多毛色类型与MC1R相关 ,MC1R在一些物种中有同源基因 本文阐述了犬MC1R多态性研究进展,并选择其它9个有代表性的哺乳动物物种与犬MC1R同源基因进行了比较,以此建立系统发育树。结果显示,10个物种的MC1R基因的分子进化关系与物种的经典分类学地位基本相符。      

Identification of a premature stop codon in the melanocyte-stimulating hormone receptor gene (MC1R) in Labrador and Golden retrievers with yellow coat colour

We have examined whether black/yellow coat colour in Labrador retrievers is controlled by allelic variants at the extension locus. As the gene encoding the melanocyte-stimulating hormone receptor (MC1R) has been shown to correspond to the extension locus in several species, we have determined the genomic MC1R sequence in Labrador retrievers with black and with yellow coat colour. Using primers based on the fox (Vulpes vulpes) MC1R sequence we initially isolated and sequenced the innerpart of the canine MC1R. By means of inverse PCR we succeeded in the characterization of both flanking regions of the MC1R gene (Genbank: AF064455). Comparison of the complete MC1R sequences of a yellow and a black Labrador retriever revealed a single C-->T mutation at nucleotide position 916 in the yellow dog. This transition changed the codon for arginine at position 305 into a stop codon, resulting in the elimination of the evolutionary strongly conserved 10 carboxyterminal amino acid residues. With an allele-specific-oligonucleotide (ASO) test it was shown that the mutation cosegregated with the recessively inherited yellow coat colour in the Labrador retriever. Golden retrievers also appeared to be homozygous for the mutation. Seventeen other breeds were all negative for the mutation. Since the Labrador and Golden retriever are closely related, we suggest a common founder for the yellow coat colour in Labrador and Golden retrievers.