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.     

利用微卫星标记分析贵州白水牛与普通水牛的遗传多样性与亲缘关系

利用11对微卫星引物对贵州白水牛和6个普通水牛群体的有效等位基因数、基因杂合度、多态信息含量和遗传距离进行了分析。结果表明,11个微卫星基因座在7个水牛群体中均存在多态性,可以用于水牛的遗传多样性评估。贵州白水牛和6个普通水牛群体的平均杂合度和平均多态信息含量分别为0·7450～0·7922和0·7021～0·7605。贵州白水牛和遵义普通水牛的亲缘关系最近,遗传距离为0·0910。由UPGMA聚类法得到的系统聚类图反映了贵州白水牛和6个普通水牛群体的亲缘关系远近程度,贵州白水牛没有单独聚为一类,而是与同分布区的遵义普通水牛首先聚类,然后依次与其余地区的普通水牛聚类。研究提出了贵州白水牛应是其产地的普通水牛群体中的一个突变群的见解,为开展贵州白水牛的遗传资源评估、保护与利用提供了分子水平的遗传学依据。     

沼泽型水牛Y染色体微卫星标记的筛选与多态性检测

为了研究水牛Y染色体的遗传多样性, 文章以滇东南水牛3个地方群体- 红河(HH)、西双版纳(BN)和普洱(PR)共31头公牛为研究对象, 选取14个家牛Y染色体特异性微卫星标记, 以检测这些标记在水牛Y染色体遗传多样性研究中的可行性。结果表明, 3个标记(INRA008、UMN0103和UMN0504)只有1个等位基因, 表现为单态; 3个标记(UMN1113、UMN0304和BC1.2)均为3个等位基因, 但呈单态; 3个标记(UMN0920、UMN0307和UMN3008)呈现无规律的梯状条带, 所以这9个标记都不适用于水牛的Y染色体遗传多样性研究; 只有5个标记(INRA124、INRA189、BM861、PBR1F1和UMN2001)具有多态性, 表明适用于水牛的Y染色体遗传多样性研究。这5个多态性Y染色体特异微卫星标记在滇东南水牛群体中的平均等位基因数(NA)为2.8000, 平均期望杂合度(He)为0.3998, 基因多样性(GD)为0.4144, 多态信息含量(PIC)为0.3245, Shannon信息熵(SI)为0.5849, 表明滇东南水牛群体的Y染色体具有中等遗传多态性。     

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.     

牛黑素皮质素受体1(MCIR)基因与毛色表型的研究

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(ED,E ,e)。中国荷斯坦黑白花牛主要是ED和E 等位基因(ED=0.12、E =0.80);渤海黑牛也主要是ED和E 等位基因(ED=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ED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)。     

Phylogenetic analysis of the tribe Bovini using microsatellites

The objective of the present study was to determine if the generally accepted phylogenetic relationships in the tribe Bovini correspond to a phylogenetic scheme derived from polymorphisms at 20 bovine microsatellite loci. This study comprises 17 representative populations: eight Bos taurus, two Bos indicus, one Poëphagus, one Bibos, one Bison, three Bubalus and one Syncerus. Phylogenetic analyses using (δμ)² and chord (D_C) distances revealed substantial divergence among species. Neighbor‐joining trees with both distance measures showed only minor differences. Bos taurus and Bos indicus grouped first, followed by Bos frontalis (Mithan) and Bos grunniens (Yak), Bison bison branched off next and Bubalus bubalis and Syncerus caffer emerged as the two most divergent species from the Bos clade. These findings would suggest that Bos, Poëphagus, and Bibos should be integrated into the Bos genus with each group classified as a subgenus. On the other hand, Bison, Bubalus and Syncerus should each be considered a separate genus. Direct estimates of the divergence times were calculated using the (δμ)² genetic distance. Bos taurus and Bos indicus were estimated to have diverged 0·31–0·82 MYA, Bos and Poëphagus: 0·57–1·53 MYA, Bos and Bibos: 0·57–1·52 MYA, Bos and Bison: 0·46–1·23 MYA, Bos and Bubalus: 1·85–4·93 MYA and Bos and Syncerus: 0·98–2·61 MYA.     

8个亚洲水牛群体的遗传结构分析

应用13个微卫星标记结合荧光–多重PCR技术, 对德昌水牛、兴隆水牛、富钟水牛、温州水牛、东流水牛、福安水牛和两个引进品种摩拉水牛、尼里－拉菲水牛进行遗传结构分析。结果表明: 8个水牛群体在13个微卫星座位中共检测到157个等位基因, 其中7个群体具有各自的特有等位基因, 其和为23; 8个群体的有效等位基因数在2.2908～4.2308之间, 杂合度在0.4951～0.7194之间, 多态信息含量在0.4495～0.6776之间; 有11个座位为高度多态座位, 是适合分析水牛遗传多样性的多态标记; 聚类分析表明富钟水牛和东流水牛先聚在一起, 再与兴隆水牛聚在一起, 然后与温州水牛和福安水牛聚在一起, 德昌水牛独自聚为一类; 两个引进品种聚为一类。     

Genetic diversity and differentiation of Chinese domestic buffalo based on 30 microsatellite markers

To determine genetic diversity and evolutionary relationships among Chinese buffalo populations, 18 indigenous swamp buffalo populations and two introduced river buffalo breeds were genotyped for 30 microsatellite loci. The mean number of alleles across the 30 loci was 8.13, and the expected heterozygosity ranged from 0.517 (Yanjin) to 0.609 (Dehong). Although there was abundant genetic variation, genetic differentiation between Chinese buffalo populations was low, with only 2.8% of the total genetic variance among populations. The genetic differentiation pattern and genetic relationships among Chinese buffalo populations were consistent with their geographic distribution. The Dehong population was discerned as a distinct indigenous population, but suffered genetic admixture with river buffalo. The remaining populations were divided into four major clusters, i.e. the Upper and Middle Reaches of Yangtze Valley cluster (Guizhou, Guizhoubai, Yanjin, Fuling, Enshi and Jianghan), the Lower Reaches of Yangtze Valley cluster (Haizi, Shanqu and Dongliu), the South China cluster (Fuan and Xinfeng) and the Southwest China cluster (Xinglong, Xilin, Diandongnan and Dechang).     

三个虹鳟养殖群体遗传结构的微卫星分析

利用20个微卫星标记对3个虹鳟(Oncorhynchus mykiss)养殖群体进行遗传结构分析。结果表明,(1)3个群体检测的平均等位基因数为3·6～4·1,平均观测杂合度为0·5224～0·6328,平均期望杂合度为0·4736～0·5522,平均多态信息含量为0·4354～0·5084,说明这几个群体多态性属于偏高水平,遗传多样性高。通过d值,确定了Hard-Weinberg平衡的偏离情况,发现AY039638、AY039646在3个群体中都表现为不平衡。对3个群体的遗传距离进行了估算,并进行聚类分析,本溪的两个群体先聚为一支,再与渤海群体相聚,显示出明显的地理特征。(2)本溪虹鳟群体在位点AF352770出现部分等位基因消失的现象;AF352754在本溪群体中表现为位点消失,可作为区分本溪群体和渤海群体的分子标记。(3)综合评价3个群体,渤海站虹鳟群体的遗传多样性最高,与前人研究结果一致。     

Microsatellite analysis reveals high genetic diversity but low genetic structure in Ethiopian indigenous cattle populations

Ethiopian cattle are under threat from uncontrolled mating practices and are at high risk of becoming genetically homogeneous. Therefore, to evaluate genetic diversity, population structure and degree of admixture, 30 microsatellite markers were genotyped using 351 DNA samples from 10 Ethiopian cattle populations and the Holstein breed. The mean number of alleles per cattle population ranged from 6.93 ± 2.12 in Sheko to 7.50 ± 2.35 in Adwa. The mean observed and expected heterozygosities were 0.674 ± 0.015 and 0.726 ± 0.019 respectively. Ethiopian cattle populations have maintained a high level of within-population genetic differentiation (98.7%), the remainder being accounted for by differentiation among populations (1.3%). A highly significant deficiency in heterozygotes was detected within populations ( F _IS = 0.071; P  <   0.001) and total inbreeding ( F _IT = 0.083; P  <   0.001). The study populations were highly admixed but distinct from pure Bos taurus and Bos indicus breeds. The various levels of admixture and high genetic diversity make Ethiopian cattle populations suitable for future genetic improvement and utilization under a wide range of agro-ecologies in Ethiopia.     

Isolation and Characterization of the Bovine Microsatellite Loci

Microsatellite loci were isolated using five repetitive probes for Korean native cattle. Eleven microsatellite loci were developed based on a biotin hybrid capture method, and enrichment of the genomic libraries (AAAT, TG, AG, T, and TGC repeats) was performed using Sau3AI adapters. The isolated markers were tested in two half-sib Korean cattle families and four imported breeds (Angus, Limousine, Holstein, and Shorthorn). Nine informative microsatellite loci were observed, and two microsatellite loci were revealed as monomorphic in Korean cattle. In the imported breeds, however, all of the markers were informative. In total, 213 alleles were obtained at the 11 loci across five breeds, and the average number of alleles found per locus, considering all populations, was 4.26. Heterozygosity was 0.71 (expected) and 0.57 (observed). The range of the polymorphic information content for the markers in all cattle populations was 0.43-0.69. Eleven percent of genetic variation was attributed to differentiation between populations as determined by the mean F (ST) values. The remaining 89% corresponded to differences among individuals. The isolated markers may be used to identify and classify the local breeds on a molecular basis.     

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)。     

Establishment of paternity testing system using microsatellite markers in Chinese Holstein

To estimate the efficiency of microsatellite markers in paternity testing among Chinese Holstein, 30 microsatellite loci were used to differentiate 330 Chinese Holstein genotypes, according to the calculation of the allele frequency, number of alleles, effective number of alleles, genetic heterozygosity, polymorphic information content (PIC), and the exclusion probability in this cattle population. The results demonstrated that the exclusion probability ranged from 0.620 in locus BM1818 to 0.265 in locus INRA005 with the average of 0.472 and 11 microsatellite markers exceeding 0.5. The combined exclusion probability of nine microsatellite markers was over 0.99. The result showed that paternity testing of Chinese Holstein was basically resolved using the nine microsatellite markers selected.     

Microsatellite analysis reveals substantial genetic differentiation between contemporary New World and Old World Holstein Friesian populations

Genotypic data from 39 microsatellite loci typed in 211 animals were used to assess the genetic differentiation between Old World and New World Holstein Friesian cattle populations. Gene diversities were similar in all five Holstein Friesian populations surveyed, ranging from 0.43 to 0.48. A tree of individuals based on the proportion of shared alleles indicated a clear distinction between Old World and New World Holstein Friesian populations. Similarly, genetic differentiation between populations, as measured by FST, was highly significant. Using the split decomposition method, we were able to visualize the significant introgression of New World Holstein Friesian into European Holstein Friesian populations.     

Analysis of conserved microsatellite sequences suggests closer relationship between water buffalo Bubalus bubalis and sheep Ovis aries.

The distribution and evolutionary pattern of the conserved microsatellite repeat sequences (CA)n, (TGG)6, and (GGAT)4 were studied to determine the divergence time and phylogenetic position of the water buffalo, Bubalus bubalis. The mean allelic frequencies of these repeat loci showed a high level of heterozygosity among the euartiodactyls (buffalo, cattle, sheep, and goat). Genetic distances calculated from the allelic frequencies of these microsatellites were used to position Bubalus bubalis in the phylogenetic tree. The tree topology revealed a closer proximity of the Bubalus bubalis to the Ovis aries (sheep) genome than to other domestic species. The estimated time of divergence of the water buffalo genome relative to cattle, goat, sheep, pig, rabbit, and horse was found to be 21, 0.5, 0.7, 94, 20.3, and 408 million years (Myr), respectively. Although water buffaloes share morphological and biochemical similarities with cattle, our study using the microsatellite sequences places the bubaline species in an entirely new phylogenetic position. Our results also suggest that with respect to these repeat loci, the water buffalo genome shares a common ancestry with sheep and goat after the divergence of subfamily Bovinae (Bos taurus) from the family Bovidae.     

Estimation of the time of divergence between Japanese Mishima Island cattle and other cattle populations using microsatellite DNA markers

We applied the theory of random genetic drift to determine the divergence history of a closed cattle population over the relatively short timescale of several hundred years. The divergence history of the closed population of Mishima Island cattle, a national natural treasure of Japan, was examined, and the results were compared with historical documents. Inbreeding depression in the isolated population was investigated for body size and fertility. Twenty-one DNA microsatellite markers in Mishima Island cattle and 3 major breeds from the mainland were genotyped. For the mainland breeds, all 21 or 20 markers were segregating. However, nearly half the number of loci (9 of 21) was fixed in the Island cattle. The average number of alleles per locus of Island cattle was markedly lower than that in the mainland breeds. These results support the theory that Island cattle have been isolated for a considerable period of time. The number of generations of isolation was estimated as 14.1-22.6, and the year of divergence was calculated as 1778-1846. In view of these findings, we propose that Island cattle diverged from the mainland population at around 1800 and were isolated for about 200 years. These estimates are in agreement with historical documents showing that divergence occurred between 1672 and 1880. The total inbreeding coefficient of the present population was predicted to be in the range of 0.51-0.60. However, historical reports dated over 100 years do not support changes in fertility, so that there is no evidence for inbreeding depression.     

德宏水牛微卫星标记分析的群体遗传变异

德宏水牛是云南省地方水牛的优良品种之一,为了进一步阐明其群体遗传变异和遗传结构,筛选了分别位于水牛14条染色体上的15对微卫星引物,对德宏水牛81个个体进行了检测分析.共检测到62个等位基因,每个座位等位基因数目从2到6个不等,平均等位基因数为4.13,该水牛群体期望杂合度和多态信息含量分别为0.6520±0.1526和0.5863±0.1789,各座位的遗传分化系数在0～0.0919之间,平均值为0.0202.每个座位的基因流较大,平均12.1502.研究结果表明德宏水牛群体遗传多样性较丰富,亚群间的遗传分化程度低,基因流较大,且很少发生近交.     

湘江野鲤养殖群体和自然群体遗传多样性的微卫星分析

采用微卫星技术,用17对微卫星引物对湘江野鲤养殖群体和自然群体的的遗传多样性进行分析.结果表明:有15对引物扩增出清晰的条带,其中13对引物在群体间呈现多态性;2个群体中,13对多态性引物分别扩增等位基因2～12个,共90个,其中35个等位基因为2群体共有,55个等位基因具有群体特异性,引物平均等位基因数为6.92个,等位基因频率为0.0667～0.8333;养殖群体和自然群体的平均遗传杂合度和平均多态信息含量分别为0.5688、0.5152,0.5860、0.5347;2个群体间遗传相似性指数为0.6762,遗传距离为0.3238,表明湘江野鲤养殖和自然群体遗传多样性均较为丰富,2个群体间遗传变异程度较高.     

云南野生小蜜蜂群体SSR遗传多样性分析

【目的】小蜜蜂Apis florea是蜜蜂属野生种类之一,在我国主要分布于西南部。对于小蜜蜂的研究我国多集中在形态方面,遗传多样性的研究较少。本文旨在阐明云南地区小蜜蜂的群体遗传特征,评价其遗传多样性。【方法】本研究利用14对微卫星引物对采自云南省的13群野生小蜜蜂进行了群体遗传变异检测和遗传多样性分析。【结果】在小蜜蜂群体中共检测到53个等位基因,平均等位基因数为3.7857,平均有效等位基因数2.9420,平均期望杂合度和表观杂合度分别为0.5708和0.2184,平均多态信息含量为0.5300。根据Nei’s遗传距离用UPGMA方法对13群小蜜蜂进行亲缘关系分析,结果 13群野生小蜜蜂先分出红河(HH),再分出缅甸(MD)和普洱(PE),最后所有的西双版纳的聚在一起。【结论】说明同一地区的小蜜蜂的遗传距离相对不同地区的较近。     

Genetic diversity of Asian water buffalo (Bubalus bubalis): microsatellite variation and a comparison with protein-coding loci

Twenty-one microsatellite loci in 11 populations of Asian water buffalo (eight swamp, three river type) were analysed and, within and among populations, genetic variability was compared with results from 25 polymorphic protein-coding loci. Within-population mean heterozygosity ranged from 0·380–0·615, approximately twice that estimated from the protein-coding loci (0·184– 0·346). Only eight significant departures from Hardy–Weinberg equilibrium (involving four loci) were detected; global tests showed significant heterozygote deficiencies for these four loci. Non-amplifying alleles are likely to be segregating in some or all populations for one of these loci, and probably for the other three. There was significant differentiation between the swamp and river types of water buffalo, and among populations within each buffalo type. Estimates of θ (measure of population differentiation) for each locus for the eight swamp populations were all highly significant (mean θ = 0·168 ± 0·018). Mean θ for protein-coding loci was not significantly different (0·182 ± 0·041). The variance among protein-coding loci was significantly higher than among microsatellite loci, suggesting balancing selection affecting allele frequencies at some protein-coding loci. Genetic distances show clear separation of the swamp and river types, which were estimated to have diverged at least 10 000–15 000 years ago. The topology of the swamp populations’ microsatellite tree is consistent with their geographical distribution and their presumed spread through south-east Asia. By contrast, the tree based on the protein-coding loci distances is quite different, being clearly distorted by a bottleneck effect in one population, and possibly in at least two others. As many domestic livestock breeds are possibly descended from small numbers of founders, microsatellite-based trees are to be preferred in assessing breed genetic relationships.