茶花鸡群体遗传多样性

茶花鸡是我国具有独特遗传特性的地方家禽品种,为了进一步阐明其群体遗传变异和遗传结构状况,采用了33个家鸡特异性的微卫星标记对该鸡种自然群体中30个个体进行了多态性电泳检测。33个微卫星座位共检测到105个等位基因,所有座位都呈现出多态性,每个座位的等位基因数在2~5个之间,平均每个座位等位基因数3.20个。群体平均杂合度和平均多态信息含量分别为0.612 9和0.527 6。结果表明,茶花鸡自然群体遗传多样性较丰富。     

尼西鸡遗传多样性微卫星标记分析

尼西鸡抗病力强,产蛋性能高,适应高海拔及寒冷的气候条件,是具有独特群体遗传特性的高原地方鸡种。为了对其有效保护和合理利用提供遗传背景资料,筛选了家鸡基因组24条染色体上的33个微卫星标记,对随机选取的50个尼西鸡个体进行多态性检测,共检测到122个等位基因,每个座位平均等位基因数为3·7个。该群体平均多态信息含量和平均杂合度分别为0·5514和0·6350,大染色体较小染色体的微卫星多态性程度高。表明尼西鸡属多态性较丰富的群体。     

大河猪76个STR基因座的遗传多态性

大河猪是中国西南中海拔地区代表性猪种之一,长期以来在当地养猪生产中发挥了重要作用。为了阐明其群体遗传变异情况,为进一步有效保护和合理利用提供科学依据,采用分布在家猪19对染色体上的76个微卫星标记对该猪种60个随机抽样个体进行了微卫星PCR–聚丙烯酰胺凝胶电泳检测。共检测到347个等位基因,所有座位都呈现出多态性,每个座位的等位基因数在3—10个之间,平均每个座位等位基因数4.57个,有效等位基因数3.50个,群体平均杂合度及平均多态信息含量分别为0.696 2±0.071 6和0.644 1±0.091 4。结果表明,大河猪群体遗传多样性较丰富,选择潜力较大。     

鳜原种群体和养殖群体遗传多样性的微卫星分析

本研究利用20对微卫星引物对鳜(Siniperca chuatsi)原种群体和养殖群体进行遗传多样性分析。结果表明,在鳜原种群体中检测到多态性位点14个,养殖群体11个。在两个群体中共检测到等位基因数96个,其中原种群体检测到等位基因数53个,每个位点的等位基因数在1～7之间,平均有效等位基因数为2.7390;养殖群体检测到等位基因数43个,每个位点的等位基因数在1～6之间,平均有效等位基因数为2.1284。原种群体的平均观察杂合度0.5708,Nei氏期望杂合度0.5295,平均多态信息含量PIC0.5353;养殖群体的平均观察杂合度0.3839,Nei氏期望杂合度0.4011,平均多态信息含量PIC0.5043。因此,与养殖群体相比,鳜原种群体仍有丰富的遗传多样性。本研究可为鳜种质资源的保护、监测和遗传育种提供分子水平上的数据。     

利用30个微卫星标记分析长江中下游鲢群体的遗传多样性

摘要: 利用30对微卫星分子标记对长江中下游5个鲢群体进行了遗传多样性分析。结果表明: 在30个基因座中, 共检测到144个等位基因, 每个座位检测到的等位基因数为1～10个, 其中有25个座位具有多态性, 多态位点百分率为83.33,5个群体的平均等位基因数A为4.0/4.1, 平均有效等位基因数Ne为2.4445～2.6332, 平均观察杂合度Ho为0.3233～0.3511, 平均期望杂合度He为0.4421～0.4704, 平均多态信息含量PIC为0.4068～0.4286。对数据进行F-检验, Fst值表明群体间的遗传分化程度中等, 并对基因型进行了基于Hardy-Weinberg平衡的卡方检验, 所得P值说明5个群体均一定程度上偏离了平衡。5个群体间的遗传相似系数为0.8466～0.9146,遗传距离为0.0893～0.1665, 并根据Nei氏标准遗传距离用UPGMA方法对5个鲢群体进行亲缘关系聚类。     

雪峰乌骨鸡自然群体遗传多样性的微卫星分析

雪峰乌骨鸡是具有独特遗传特性的优质肉药兼用地方家禽品种.为了评价雪峰乌骨鸡现有品种资源的遗传背景、群体遗传结构等,提出合理的保种方法和措施,本研究筛选了家鸡基因组23条染色体上的23个微卫星标记,对采自湖南怀化的50只纯种乌骨鸡个体进行了多态性检测.结果表明:23个微卫星座位共检测到79个等位基因,所有座位都呈现出多态性,每个座位的等位基因数在2-6个之间,平均为3.435个.群体表现出较高的平均杂合度和平均多态信息含量,分别为0.6285和0.5496,说明雪峰乌骨鸡自然群体具有较丰富的遗传多样性.研究结果将为雪峰乌骨鸡种的保护和利用提供重要的理论依据.     

云南南部地区野猪群体的遗传多样性

野猪(Sus scrofa)是家猪的祖先,也是野生动物遗传资源和生物多样性的重要组成部分.为了阐明其群体遗传变异,以对其进一步有效保护和合理利用提供科学依据,本研究采用分布在家猪19条染色体上的76个微卫星标记对云南南部地区野猪群体65只个体进行了群体遗传变异分析.共检测到349个等位基因,每个座位的等位基因数从3到9不等,有效等位基因数在1.683 5-8.066 7之间,平均每个座位等位基因数(4.592 1±1.145 2)个,有效等位基因数(3.709 9±0.990 4)个,群体平均表观杂合度、期望杂合度及平均多态信息含量分别为(0.949 2±0.113 5)、(0.711 6±0.078 7)和(0.663 4±0.092 1).结果表明,本实验检测到的野猪群体遗传多样性较丰富.     

秦川母牛群体遗传特性的微卫星标记研究

为了从DNA分子水平揭示秦川牛群体遗传多态性和群体遗传结构,寻找可用于秦川牛的微卫星标记,本研究选择了12个普通牛（Bos taurus）微卫星标记检测了90头秦川母牛各微卫星位点的遗传变异及多态性。结果表明,在秦川母牛群体中,12个微卫星位点共检测到了247个等位基因,各位点的等位基因数在13（INRA005）～33个（HEL13）之间,平均每个微卫星位点的等位基因数为21个;总有效等位基因数和平均每个位点平均有效等位基因数（Ne）分别分为142．6229和11．8852。各位点平均基因频率取样方差（V（pij））为2．6036×10^-4。12个微卫星位点平均观察杂合度（Ho）和平均期望杂合度（He）在0．7842（INRA005）～0．9775（BM315）和0．7952（BM315）～0．9446（HEL13）之间。12个位点平均多态信息含量（PIC）在0．7653（INRA005）～0．9420（HEL13）之间,平均为0．8965．12个微卫星位点均属于高度多态位点,这表明秦川母牛群体中所检测各微卫星位点具有丰富的遗传多态性,具备较大的选择潜力。12个微卫星位点的平均固定指数（F）为-0．0076,即各位点杂合子的缺陷度不高,即偏离Hardy—Weinberg平衡的程度不大。     

长江中上游两个鲢群体遗传变异的微卫星分析

对长江中上游2个鲢群体使用39个微卫星标记进行了遗传多样性分析, 计算并统计了平均观测等位基因数、平均有效等位基因数、多态信息含量、遗传杂合度、Hardy-Weinberg平衡偏离指数、遗传相似系数、遗传距离等遗传参数。结果表明: 万州鲢和监利鲢群体所检测微卫星位点的平均观测等位基因数分别为6.128和4.974; 平均有效等位基因数分别为4.107和3.395; 多态位点百分率分别为100和94.87; 39个微卫星标记共有等位基因259个, 173个等位基因为两群体所共有; 多态微卫星位点的PIC在0.077~0.865之间变动,平均为0.617; 两群体所检测位点平均观测杂合度为0.834和0.775, 平均期望杂合度为0.713和0.623; 两个群体间的遗传相似系数为0.618, 群体间的遗传距离为0.482。结果显示长江中上游两个鲢群体间存在显著遗传分化, 应隶属于不同的种群。     

滩羊微卫星标记多态性及与体尺性状关联分析

滩羊是我国特有的蒙古羊品种,肉质鲜美但生长缓慢。通过筛选的29个高多态性微卫星标记,对宁夏盐池滩羊种羊场基础母羊群体用随机抽样法检测了96个成年个体,测量了体重和体尺数据,分析了其微卫星标记遗传多样性、群体遗传结构及分子标记与表型的相关关系。结果显示,微卫星标记平均等位基因数9.5,平均有效等位基因数4.5,平均期望杂合度0.72,平均观测杂合度0.64,平均多态信息含量0.69;滩羊基础母羊群体保持了丰富的遗传多样性;关联分析结果显示MAF33与滩羊的体高、胸深显著相关,BMS1788与荐高、胸围显著相关,而BL41、BMS835、BOVILS56、MAF33和BMS500与管围极显著关联。这些标记对未来滩羊的分子辅助育种有所帮助。     

红原鸡与家鸡的亲缘关系研究

对中国红原鸡滇地亚种和海南亚种与我国茶花鸡,泰和鸡和寿光鸡等地方鸡种以及芦花鸡,洛岛红等外国鸡种进行了血型（３个位点,１３个等位基因）,蛋白质（酶）多态（５个位点,１１个等位基因）和ＤＮＡ指纹分析,结果表明,红原鸡与茶花鸡（原始型品种）的亲缘关系较近;与泰和鸡,寿光鸡,芦花鸡,洛岛红（进化型品种）的亲缘关系较远,呈红原鸡－茶花鸡－泰和鸡,寿光鸡或芦花鸡,洛岛红这样一个进化阶梯,以上结果与国外资料（     

Genetic diversity within chicken populations from different continents and management histories

Intra-population variation was assessed in 1970 chickens from 64 populations using 29 autosomal microsatellites. On average, 95% of the loci were polymorphic across populations. In 1456 ( c. 83%) of the 1763 combinations of populations and polymorphic loci, no departure from Hardy–Weinberg equilibrium was observed. On average, there were 11.4 alleles per locus and 3.6 alleles per population across loci. Within populations, the average observed heterozygote frequency was 0.46, with a range between 0.20 and 0.64. Dagu, a Chinese population, and the Red Jungle Fowl ( Gallus gallus gallus ) had the highest average heterozygote frequencies at 0.64 and 0.63 respectively. An inbred line used as a reference population for comparison showed the lowest average of observed heterozygote frequency (0.05), followed by the European population Hamburger Lackhuhn, whose average observed heterozygote frequency was 0.20. A total of 32 private alleles (alleles detected in only one population) for 20 loci were found in 18 populations. H'mong chickens, a Vietnamese population, carried the largest number of private alleles at five, followed by the Red Jungle Fowl with four private alleles. Genetic diversity within populations was low in the NW European fancy breeds and high in the non-commercial Asian populations, in agreement with population management history.     

藏鸡群体遗传多样性研究

藏鸡的体型外貌和生活习性与红色原鸡非常相似,是具有自己独特群体遗传特性的高原地方鸡种。为了有效保护并合理利用这一遗传资源,我们采用多重PCR与半自动荧光标记微卫星聚丙烯酰胺凝胶电泳相结合的方法检测了20个微卫星基因座的多态性,并随机抽取藏鸡群体中部分个体进行个体体形特征与生产性能的统计。结果表明藏鸡群体的20个微卫星基因座的多态等位基因数为4~10个,平均值为7.25个/基因座,多态信息含量（CPI）和杂合度（H）平均值分别为0.67、0.74。大染色体较小染色体的微卫星标记多态性程度要高。藏鸡群体的微卫星基因座多态性丰富,也解释了生产性能不均,外貌表现迥异的群体遗传特性。 Abstract: Morphological traits and living habit of Tibetan chicken, which is an aboriginal chicken breed on plateau with its own characteristic populational genetic features, are in great common with the Red Jungle Fowl, the assumed ancestry of domestic chicken. To fully exploit this chicken resource, Multiplex PCR with semi-automated polyacrilamide gel electrophoresis (PAGE) using fluorescently labeled microsatellite primers was used to detect the polymorphism at 20 microsatellite loci. At the same time, we randomly test the individual morphology and performance. It showed that numbers of polymorphic alleles were 4-10, with mean value 7.25 per locus. Polymorphism Information Content (CPI) and Heterozygosity (H) had mean values 0.67 and 0.74, respectively. Macrochromosomes had relatively higher polymorphism than microchromosomes(P>0.05). In all, high polymorphisms at microsatellite loci related to the uneven production performance and morphological discrepancy of population genetic characteristics in Tibetan chicken.     

Genetic diversity of Vietnamese domestic chicken populations as decision‐making support for conservation strategies

The aims of this study were to assess the genetic diversity of 17 populations of Vietnamese local chickens (VNN) and one Red Jungle Fowl population, together with six chicken populations of Chinese origin (CNO), and to provide priorities supporting the conservation of genetic resources using 20 microsatellites. Consequently, the VNN populations exhibited a higher diversity than did CNO populations in terms of number of alleles but showed a slightly lower observed heterozygosity. The VNN populations showed in total seven private alleles, whereas no CNO private alleles were found. The expected heterozygosity of 0.576 in the VNN populations was higher than the observed heterozygosity of 0.490, leading to heterozygote deficiency within populations. This issue could be partly explained by the Wahlund effect due to fragmentation of several populations between chicken flocks. Molecular analysis of variance showed that most of genetic variation was found within VNN populations. The Bayesian clustering analysis showed that VNN and CNO chickens were separated into two distinct groups with little evidence for gene flow between them. Among the 24 populations, 13 were successfully assigned to their own cluster, whereas the structuring was not clear for the remaining 11 chicken populations. The contributions of 24 populations to the total genetic diversity were mostly consistent across two approaches, taking into account the within‐ and between‐populations genetic diversity and allelic richness. The black H'mong, Lien Minh, Luong Phuong and Red Jungle Fowl were ranked with the highest priorities for conservation according to Caballero and Toro's and Petit's approaches. In conclusion, a national strategy needs to be set up for Vietnamese chicken populations, with three main components: conservation of high‐priority breeds, within‐breed management with animal exchanges between flocks to avoid Wahlund effect and monitoring of inbreeding rate.     

Genetic characterization of biodiversity in highly inbred chicken lines by microsatellite markers

Forty-two microsatellite loci were analysed in 23 highly inbred chicken lines derived from Leghorn, Jungle Fowl, Fayoumi and Spanish breeds. Line-specific alleles among breeds and lines were detected. The band-sharing (BS) values were calculated and the proportion of shared alleles distances (Dps) were estimated. The BS values and Dps between sets of MHC-congenic lines ranged from 0.74 to 0.96, and 0.05-0.35, respectively. The BS values between each pair of noncongenic Leghorn lines were 0.32-0.97, and between Leghorn and exotic (Jungle Fowl, Fayoumi and Spanish) breeds were 0.03-0.55. The Dps between Fayoumi lines and other lines were much larger (0.66-1.34) than within Leghorns, and the Jungle Fowl breed had the largest distances with other lines (1.12-5.38). The phylogenetic consensus tree that was constructed grouped these 23 inbred chicken lines into four different clusters. These results are in accordance with the origin and breeding history of these inbred lines, which indicates that the use of microsatellites for the study of genetic biodiversity is accurate and reliable. In addition, the significance and value of inbred chicken lines in molecular genetic research is discussed.     

利用微卫星技术分析不同类群鸡的遗传多样性

利用8个微卫星标记分析了6个生产类群鸡的遗传多样性。计算了各群体在各位点上的等位基因频率,并据此计算出各群体的平均遗传杂合度(h)、多态信息含量(PIC)和有效等位基因数(Ne)。结果表明:6个鸡群在8个微卫星座位上的基因频率存在明显的差异,其平均基因杂合度为0.7317,平均多态信息含量为0.6815。其中,群体平均杂合度最高的是安卡红鸡,为0.7716;平均杂合度最低的是新罗曼鸡,为0.7073。所选的8个微卫星座位均为高度多态,可作为有效的遗传标记用于鸡群体遗传多样性的分析。     

鸡SNP多样性的比较研究与群体有效规模的估算

以红色原鸡(Red Jungle Fowl, RJF)、丝羽乌骨鸡(Taihe silk Chicken, TS)、隐性白洛克鸡(White Recessive Rock, WRR)为资源群, 在鸡一号染色体的Contig.060226.1上选取了一个200 kb的区域, 比较研究了3个群体的SNP (single nucleotide polymorphism)多样性、估算了鸡的初始群体有效规模大小(effective size of population, Ne)。红色原鸡、丝羽乌骨鸡、隐性白洛克鸡3个群体的平均杂合度分别为0.28533±0.03475、0.32926±0.03919、0.30168±0.04038。显著性检验差异不显著(P=0.2368>0.05)。根据Latter 和Nei的方法对鸡的群体有效规模进行了估算, 鸡的初始群体有效规模大小为20 000～150 000。鸡在驯养的早期阶段经历过严厉的瓶颈效应, 但瓶颈效应对鸡各品种SNP的多样性并未产生显著影响。笔者认为, 鸡在驯养的早期阶段群体有效规模足够大, 品种分化过程中群体迅速扩张, 品种间的广泛杂交(特别是和红色原鸡之间)以及鸡基因组的高重组率等因素是导致家鸡和原鸡以及各家鸡品种间SNP多样性没有显著差别的重要原因。     

A set of polymorphic dinucleotide and tetranucleotide microsatellite markers for the Indo-Pacific humpback dolphin (Sousa chinensis) and cross-amplification in other cetacean species

Eleven dinucleotide and five tetranucleotide polymorphic microsatellite loci were presented for the Indo-Pacific humpback dolphin Sousa chinensis, a species categorized as ‘data deficiency’ in the IUCN Red List. These markers were developed to allow future population studies, such as characterization of population structure and genetic diversity that are important for the species’ conservation. The number of alleles ranged from 2 to 9 with observed heterozygosity ranging from 0.167 to 0.917, and expected heterozygosity ranging from 0.159 to 0.913. Test of these loci in five additional cetacean species found that 10–13 loci have successful cross-amplifications.     

Isolation and characterization of twenty-one polymorphic microsatellite loci in the Tibetan macaque (<Emphasis Type="Italic">Macaca thibetana</Emphasis>)

Twenty-one microsatellite loci were isolated from AC-enriched library of Tibetan macaque (Macaca thibetana). The number of alleles at the 21 microsatellite loci ranged from 8 to 15, with an average of 12.2 per locus. Polymorphism information content (PIC) ranged from 0.805 to 0.910 with an average of 0.873. The observed and expected heterozygosities ranged from 0.208 to 0.792 and from 0.843 to 0.938, respectively. These microsatellite loci will be useful for future studies that relate to the genetic diversity and population structure of Tibetan macaque.