牛黑素皮质素受体1(MC1R)基因与毛色表形的研究

牛MC1R基因不仅与毛色有关, 而且与牛乳中乳蛋白的含量有关。利用PCR-RFLP和DNA测序技术分析了中国荷斯坦黑白花牛, 中国荷斯坦红白花牛, 鲁西黄牛和渤海黑牛共4个品种的MC1R基因。共检测出3种等位基因(E^D, E⁺, e)。中国荷斯坦黑白花牛主要是E^D和E⁺等位基因(E^D=0.12、E⁴=0.80); 渤海黑牛也主要是E^D和E⁺等位基因(E^D=0.52、E⁺=0.47); 中国荷斯坦红白花牛和鲁西黄牛大多为e等位基因(e=0.95)。中国荷斯坦红白花牛和鲁西黄牛还存在E⁺/e基因型。由此推测E^D和E⁺等位基因导致黑色素合成。另外发现牛MC1R基因编码区725处存在一重要的SNP(单核苷酸多态性)。     

荷斯坦奶牛红毛性状的基因检测及红毛形成机制的探讨

荷斯坦奶牛黑素皮质素受体1(MC1R)基因310G缺失突变产生e等位基因,导致红白花毛色。实验利用PCR-RFLP和DNA测序技术建立了荷斯坦奶牛红毛性状的基因检测方法,并在4个荷斯坦奶牛全同胞家系中得到了证实,可见其可用于鉴定携带e等位基因的种公牛,以指导奶牛育种。通过分析黑素皮质素(MC)受体蛋白家族序列,找到了MC1R蛋白结构与功能的区域(TM3、TM6、TM7和EL3)。利用VHMPT软件预测MC1R突变蛋白的结构,结果显示其丢失了TM3、TM6、TM7和EL3区,也失去了与α-促黑素(α-MSH)结合的区域,最终导致红毛的产生。     

中国荷斯坦牛和鲁西黄牛mtDNAD-loop序列多态性分析

为了从母系遗传角度深入阐明中国荷斯坦牛和鲁西黄牛的群体遗传多样性以及起源进化,本研究采用PCR测序法测定了9头中国荷斯坦牛和11头鲁西黄牛的线粒体DNA D-loop区的部分序列,并经剪切后进行生物信息学软件分析.结果表明,20个个体D-loop区共711 bp,共检测到19种单倍型和50个多态位点.核苷酸多样性(Pi)为0.021 33±0.004 54,单倍型多样性(Hd)为0.994±0.019,平均核苷酸差异数(k)为15.146 20.构建的NJ网络进化树共分为两大支系,其中部分鲁西黄牛与瘤牛聚为一支,而中国荷斯坦牛和部分鲁西黄牛与普通黄牛聚为一支.说明中国荷斯坦牛和鲁西黄牛群体遗传多样性均较高;鲁西黄牛同时含有瘤牛和普通黄牛的血统,而中国荷斯坦牛只含有普通黄牛的血统.     

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。     

秦川牛和中国荷斯坦牛POU1F1基因多态性研究

采用PCR-RFLP技术研究了秦川牛(QQ)和中国荷斯坦牛(HC)共计218头个体POU1F1基因的多态性。结果表明: 秦川牛及中国荷斯坦牛群体POU1F1-HinfⅠ基因座的451 bp 的PCR产物经限制性酶HinfⅠ消化后表现多态, 其等位基因A/B频率分别为0.232/0.768、0.132/0.868; 两个群体AA、AB和BB 3种基因型的频率分别为0.030/0.403/0.567、0.007/0.251/0.742。在该基因座秦川牛群体处于Hardy-Weinberg平衡状态, 中国荷斯坦牛群体处于不平衡状态。它们在该基因座的杂合度、有效等位基因数、Shannon信息熵、多态信息含量分别为0.356/1.553/0.541/0.292、0.229/1.297/0.390/0.203; 秦川牛群体的位点杂合度、有效等位基因数、Shannon信息熵、多态信息含量均大于中国荷斯坦牛群体。     

牛脊柱畸形综合征检测方法的建立与应用

牛脊柱畸形综合征(Complex vertebral malformation, CVM)是近年来新发现的致死性牛常染色体隐性遗传缺陷病。由于编码UDP-N-乙酰葡糖胺载体的SLC35A3基因发生G→T的突变而引起本病的发生, 可引起胎牛死胎、流产、早产。为了解我国正常的荷斯坦牛(黑白花奶牛)的CVM携带和发生情况, 建立、应用创造酶切位点PCR(Created restriction site PCR, CRS-PCR)、等位基因特异性PCR(Allele-specific polymerase chain reaction, AS-PCR)检测方法检测了表型正常的436头荷斯坦母牛和93头荷斯坦公牛, 检测到3头CVM携带者, 其中杂合母牛1头, 杂合公牛2头, 携带率分别为0.60%、2.20%。此方法简便、可靠, 为奶牛CVM有害基因的分型和筛选提供了新的方法和思路, 为我国奶牛的分子选育提供了可靠的理论依据。     

藏黄牛β-乳球蛋白基因启动子部分序列特征

目的:阐明藏黄牛、牦牛、中国荷斯坦牛β-乳球蛋白(β-Lg)遗传变异体在乳中表达差异的分子基础。方法:采用聚丙烯酰胺凝胶电泳确定乳中β-Lg遗传变异体及其相对表达量,然后利用PCR方法扩增β-Lg启动子部分序列(375bp)并直接测序。结果:在杂合型β-Lg个体中,中国荷斯坦牛乳中β-Lg A的相对表达量(63.7±2.9%)均一致性地高于β-Lg B,而藏黄牛乳中二者比例十分接近,但个体差异差异较大。16个测序样品中共检测到13处碱基突变,其中有5处为牦牛特异的。另外,在牦牛β-Lg启动子-452与-453之间,还存在一个插入碱基。结论:β-Lg启动子-430碱基在中国荷斯坦牛中表现为等位基因特异的,而在藏黄牛中无等位基因特异性。     

体细胞克隆牛和转基因体细胞克隆牛的遗传学分析(英)

分析了来自同一细胞系的体细胞克隆牛甜甜、庆庆、浒娃及来源同一培养转基因体细胞系转基因体细胞克隆牛九妹、乐娃和1个妊娠8个月转基因流产胎牛8C2以及随机抽取的1头鲁西黄牛(LX)、1头褐斯坦牛(HS)在24个微卫星位点标记牛的基因型.结果表明24个多态位点均表现出多态,等位基因数为1～5个,平均为3.17个.根据网上公布的数据,按其最高频率计算,甜甜、庆庆、浒娃、九妹、乐娃、8C2与培养细胞系、转基因细胞系间匹配概率为1.17×10^－36,根据本研究观察到的数据计算,匹配概率为1.90×10^－23;而与随机抽取的1头鲁西黄牛及褐斯坦牛的基因型分别在23和20个位点上完全不同.     

利用全基因组连锁不平衡估计中国荷斯坦牛有效群体大小

有效群体大小是群体遗传学研究的一个重要内容,有助于我们更清楚地了解群体的遗传变异、进化和复杂性状的遗传机制等。随着高密度SNP标记的出现,越来越多的研究利用SNP标记间连锁不平衡估计有效群体大小。文章采集北京地区中国荷斯坦牛2 093个样本,并利用牛SNP芯片(Illumina BovineSNP50,含5 4001 SNPs)进行基因型测定,估计不同世代中国荷斯坦牛的有效群体大小。质量控制标准设定为SNP检出率0.95,最小等位基因频率>0.05,样本检出率0.95,哈代温伯格平衡检验显著性水平P<0.0001。经过质量控制,共1 968个样本和38 796个SNPs用于连锁不平衡分析。文章选取SNP间距0.1、0.2、0.5、1、2、5、10、15(Mb),估计中国荷斯坦牛在4世代之前有效群体大小。结果表明,中国荷斯坦牛的有效群体呈逐代下降趋势,至4世代前,中国荷斯坦牛平均有效群体为45头左右。     

荷斯坦牛HSP70-1基因遗传多态性与乳腺炎抗性关系

以253头中国荷斯坦奶牛为研究对象, 检测HSP70-1基因的多态性, 并分析其多态性与中国荷斯坦牛体细胞评分(Somatic cell score, SCS)的相关性。首先以PCR-SSCP法寻找HSP70-1基因编码区的突变, 并通过测序确定突变的类型, 根据突变类型寻找合适的内切酶, 最终采用PCR-RFLP方法鉴定实验牛基因型; 然后分析基因多态性与中国荷斯坦牛SCS的相关性。结果表明HSP70-1基因的1 623 bp处产生G→A→C突变, 2 409 bp处产生G→A突变, 两位点都是沉默突变, 未引起氨基酸序列的改变; 经χ2 适合性检验, 中国荷斯坦牛在两个位点均未达到Hardy-Weinberg平衡状态; 同时, 群体基因座不同基因型与SCS相关分析的结果表明, 2409位点基因型与SCS相关性不显著(P>0.05), 1623位点基因型与SCS相关性显著(P<0.05), CC型SCS显著低于AG、GG型(P<0.05), CC基因型为乳腺炎抗性基因型。在中国荷斯坦奶牛群体中, HSP70-1基因CC基因型可作为改良奶牛乳腺炎抗性性状的分子遗传标记。     

The analysis of genetic diversity and differentiation of six Chinese cattle populations using microsatellite markers

A total of 321 individuals from six cattle populations of four species in a bovine subfamily in China were studied using 12 pairs of microsatellite markers. The genetic diversities within and between populations were calculated. The phylogenetic trees were constructed by （δμ）^2 and DA distances, and the divergence times between populations were estimated by （δμ）^2. Altogether, 144 microsatellite alleles were detected including 24 private alleles and nine shared alleles. Chinese Holstein had the largest number of private alleles （10）, whereas Bohai black and Buffalo had the smallest number of private alleles （2）. Chinese Holstein showed the highest genetic variability. Its observed number of alleles （Na）, mean effective number of alleles （MNA）, and mean heterozygosity （He） were 7.7500, 4.9722, and 0.7719, respectively, whereas, the Buffalo and Yak showed low genetic variability. In the phylogenetic trees, Luxi and Holstein grouped first, followed by Bohai and Minnan. Yak branched next and buffalo emerged as the most divergent population from other cattle populations. Luxi and Bohai were estimated to have diverged 0.039-0.105 million years ago （MYA）, however, buffalo and Holstein diverged 0.501-1.337 MYA. The divergence time of Yak versus Minnan, Holstein and buffalo was 0.136-0.363, 0.273-0.729, and 0.326-0.600 MYA, respectively.     

Genetic Structure and Differentiation of Three Chinese Indigenous Cattle Populations

Levels of genetic differentiation, gene flow, and genetic structure of three indigenous cattle populations (Luxi, Bohai, and Minnan) and two reference cattle populations (Chinese Holstein and Qinhai yak) in China were estimated using the information from 12 microsatellites, and 141 microsatellite alleles were identified. The mean number of alleles per locus ranged from 2.9005 in yak to 4.9722 in Holstein. The observed heterozygosity ranged from 0.5325 (yak) to 0.7719 (Holstein); 29 private alleles were detected. The global heterozygote deficit across all populations amounted to 58.5% (p < 0.001). The overall significant (p < 0.001) deficit of heterozygotes because of inbreeding within breeds amounted to 43.2%. The five cattle populations were highly differentiated (F _st = 26.9%, p < 0.001) at all loci. The heterozygote deficit within the population was highest in Luxi cattle and lowest in yak. The average number of effective migrants exchanged per generation was highest (1.149) between Luxi and Holstein, and lowest (0.509) between Luxi and yak. With the application of prior population information, cluster analysis achieved posterior probabilities from 91% to 98% of correctly assigning individuals to populations. Combining the information of cluster analysis, gene flow, and Structure analysis, the five cattle populations belong to three genetic clusters, a taurine (Luxi and Chinese Holstein), a zebu (Bohai and Minnan), and a yak cluster. This indicates that Bohai black is closer to Bos indicus than Luxi cattle. The evolution and development of three indigenous cattle populations are discussed.     

Association of SCD1 and DGAT1 SNPs with the intramuscular fat traits in Chinese Simmental cattle and their distribution in eight Chinese cattle breeds

Intramuscular fat (IMF) is a key parameter for evaluation of nutritional quality of beef, with its endogenous synthesis regulated by stearoyl CoA desaturase (SCD1) and diacylglycerol-acyl transferase 1 (DGAT1) genes in cattle. The object of this research was to evaluate the effect of SCD1 and DGAT1 polymorphisms on IMF trait in beef cattle and to estimate the frequency distribution of SNPs in the two genes in Chinese cattle populations. The SCD1 and DGAT1 polymorphisms were detected by PCR-single strand conformation polymorphism (PCR-SSCP) method in Chinese Simmental cattle and their associations with IMF traits were analyzed using the general linear model (GLM). The frequency distribution of SNPs in SCD1 and DGAT1 genes were detected by PCR-SSCP method and analyzed in seven other cattle populations. The results showed significant associations of SNPs SCD1-878, SCD1-762, and DGAT1 10433 and 10434 with IMF (%) and shearing force values (SFV; kg) in Chinese Simmental cattle. A haplotype combining SCD1-878C, SCD1-762T, and DGAT1 10433 and 10434-GC had the highest IMF, marbling score and shearing force. The polymorphic investigation indicated that the frequency of SCD1-878C or SCD1-762T was significantly higher in Chinese southern cattle (Leiqiong, Yunnan High pump, BMY or Minnan Cattle) than in Chinese northern cattle (Chinese Simmental, Luxi Cattle, Bohai Black or Chinese Holstein), while the frequency of DGAT1 10433 and 10434-GC in Chinese indigenous breed (Leiqiong, Yunnan High pump, BMY, Luxi Cattle, Bohai Black, or Minnan Cattle) was significantly lower than breeds with imported blood (Chinese Simmental or Chinese Holstein). These findings demonstrated that both the SCD1 and DGAT1 SNPs were prospect genetic markers for IMF traits, and the SCD1 SNPs could be used as a genetic marker for southern or northern blood in Chinese cattle.     

Detecting a deletion in the coding region of the bovine bone morphogenetic protein 15 gene (BMP15)

The aim of this study was to detect polymorphism in the bovine bone morphogenetic protein 15 (BMP 15) gene. On the basis of PCR-SSCP and DNA sequencing, a 4-bp deletion was identified in the coding region of the gene. Sequence analysis revealed that the deletion altered the reading frame and introduced a stop codon at position 264. Eight breeds (Luxi, Qinchuan, Nanyang, Jinnan, Bohai Black, Menggolian, Holstein, and Simmental) were genotyped by PCR-SSCP. No cows homozygous for this mutation were observed in these breeds. Heterozygous cows were detected in Luxi, Qinchuan, Nanyang, Jinnan and Bohai Black cattle. Fecundity was not increased in heterozygous individuals.     

Melanocortin receptor 1 (MC1R) mutations and coat color in pigs.

The melanocortin receptor 1 (MC1R) plays a central role in regulation of eumelanin (black/brown) and phaeomelanin (red/yellow) synthesis within the mammalian melanocyte and is encoded by the classical Extension (E) coat color locus. Sequence analysis of MC1R from seven porcine breeds revealed a total of four allelic variants corresponding to five different E alleles. The European wild boar possessed a unique MC1R allele that we believe is required for the expression of a wild-type coat color. Two different MC1R alleles were associated with the dominant black color in pigs. MC1R*2 was found in European Large Black and Chinese Meishan pigs and exhibited two missense mutations compared with the wild-type sequence. Comparative data strongly suggest that one of these, L99P, may form a constitutively active receptor. MC1R*3 was associated with the black color in the Hampshire breed and involved a single missense mutation D121N. This same MC1R variant was also associated with EP, which results in black spots on a white or red background. Two different missense mutations were identified in recessive red (e/e) animals. One of these, A240T, occurs at a highly conserved position, making it a strong candidate for disruption of receptor function.     

Molecular and pharmacological characterisation of the MSH-R alleles in Swiss cattle breeds

The coat colour in mammals is determined by the relative amounts of eumelanin (black/brown) and phaeomelanin (red/yellow), produced in melanocytes, which are controlled by melanocyte stimulating hormone receptor (MSH-R). Melanocyte stimulating hormone receptor is activated by alpha-melanocyte-stimulating hormone (alpha-MSH). Stimulated MSH-R activates adenylyl cyclase (AC), thereby increasing the amount of cyclic AMP in the cell, which activates the enzyme tyrosinase resulting in eumelanin synthesis. In this study the complete coding sequences of five alleles of the MSH-R gene found in Holstein, Red Holstein, Simmental, and Brown Swiss cattle were cloned into a mammalian expression vector and transfected into human embryonic kidney (HEK) 293 cells. The expressed receptors were analyzed for their ability to increase intracellular cAMP in response to stimulation by alpha-MSH. The recessive red allele (e) found in Red Holstein and Simmental and the dominant black allele (ED) found in Holstein were unresponsive to a wide range of alpha-MSH concentrations. Two alleles from Brown Swiss (E(d1), E(d2)) and one allele found in the Simmental breed (e(f)) responded to stimulation by alpha-MSH in a dose-dependent manner. When compared to E(d1) and E(d2), the cells transfected with the e(f) MSH-R allele, however, reached the corresponding intracellular cAMP concentrations at a 10-fold higher concentration of alpha-MSH. In conjunction with the mode of inheritance of coat colour, the results indicate that the e MSH-R allele is a non-functional receptor, E(D) is constitutively activated receptor, and E(d1) and E(d2) are hormonally activated receptors. The delay in e(f) MSH-R response may explain the similarity between the e and e(f) phenotypes.     

A new αS1-casein allele in bovine milk and its occurrence in different breeds

A new asi-casein variant (α_S1-CN F) with a frequency of 0.009 was demonstrated in a genetic resource of German Black and White Cattle by isoelectric focusing in polyacrylamide gels and by polyacrylamide gel electrophoresis under alkaline conditions. α_s1-CN F was not present either in German Holstein Friesians, which originate from crossing Holstein Friesians with German Black and White Cattle, or in milk samples from eight other breeds in Germany.     

Three novel SNPs of the bovine Tf gene in Chinese native cattle and their associations with milk production traits

Transferrin (Tf) is a β-globulin protein that transports iron ions in mammalian cells. It contributes to innate immunity to microbial pathogens, primarily by limiting microbial access to iron. Thus, polymorphisms present in bovine Tf could potentially underlie inherited differences in mastitis resistance and milk production traits. We detected three novel single-nucleotide polymorphisms of the Tf gene in Chinese native cattle by screening for genetic variation of Tf in 751 individuals of three Chinese cattle breeds, namely China Holstein, Luxi Yellow and Bohai Black, using PCR-RFLP and DNA sequencing techniques. The three new SNPs, g.-1748G>A ss250608649, g.13942T>C ss250608650, and g.14037A>G ss250608651, had allele frequencies of 85.9, 86.3 and 92.5%, 64.5, 73.3 and 65.0%, and 67.6, 73.7 and 60.0%, respectively. SNP g.-1748G>A was located in the 5' flanking region of Tf. SNP g.14037A>G was located in intron 8 of Tf. SNP g.13942T>C, located in exon 8 of Tf, was a synonymous mutation (TTA > CTA), encoding a leucine (326 aa) in the Tf protein. Associations of the Tf SNPs with milk traits were also analyzed. Significant (P < 0.05) relationships among the Tf polymorphisms, somatic cell scores (SCS), and milk productive traits were observed. Cows with genotypes TT (g.13942T>C), GG (g.-1748G>A) and AG (g.14037A>G) had a lower SCS and higher protein levels and 305-day milk yield. Nineteen combinations of different haplotypes from the three SNPs were identified in Chinese Holstein cattle. The haplotype combination ATA/GCA, GCA/GCA and GCG/ GTA was dominant in cows with a lower SCS, a higher protein level and a higher 305-day milk yield, respectively. Moreover, the gene expression level of Tf was higher in mastitis-affected mammary tissues than in normal mammary tissues. These results suggest that the Tf gene affects milk production, as well as mastitis-resistance traits, in Chinese Holsteins.     

Coat colours in the Massese sheep breed are associated with mutations in the agouti signalling protein (ASIP) and melanocortin 1 receptor (MC1R) genes

Massese is an Italian dairy sheep breed characterized by animals with black skin and horns and black or apparent grey hairs. Owing to the presence of these two coat colour types, this breed can be considered an interesting model to evaluate the effects of coat colour gene polymorphisms on this phenotypic trait. Two main loci have been already shown to affect coat colour in sheep: Agouti and Extension coding for the agouti signalling protein (ASIP) and melanocortin 1 receptor (MC1R) genes, respectively. The Agouti locus is affected by a large duplication including the ASIP gene that may determine the Agouti white and tan allele (A(Wt)). Other disrupting or partially inactivating mutations have been identified in exon 2 (a deletion of 5 bp, D(5); and a deletion of 9 bp, D(9)) and in exon 4 (g.5172T>A, p.C126S) of the ASIP gene. Three missense mutations in the sheep MC1R gene cause the dominant black E(D) allele (p.M73K and p.D121N) and the putative recessive e allele (p.R67C). Here, we analysed these ASIP and MC1R mutations in 161 Massese sheep collected from four flocks. The presence of one duplicated copy allele including the ASIP gene was associated with grey coat colour (P = 9.4E-30). Almost all animals with a duplicated copy allele (37 out of 41) showed uniform apparent grey hair and almost all animals without a duplicated allele (117 out of 120) were completely black. Different forms of duplicated alleles were identified in Massese sheep including, in almost all cases, copies with exon 2 disrupting or partially inactivating mutations making these alleles different from the A(Wt) allele. A few exceptions were observed in the association between ASIP polymorphisms and coat colour: three grey sheep did not carry any duplicated copy allele and four black animals carried a duplicated copy allele. Of the latter four sheep, two carried the E(D) allele of the MC1R gene that may be the cause of their black coat colour. The coat colour of all other black animals may be determined by non-functional ASIP alleles (non-agouti alleles, A(a)) and in a few cases by the E(D) Extension allele. At least three frequent ASIP haplotypes ([D(5):g.5172T], [N:g.5172A] and [D(5):g.5172A]) were detected (organized into six different diplotypes). In conclusion, the results indicated that coat colours in the Massese sheep breed are mainly derived by combining ASIP and MC1R mutations.