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。     

野生与人工驯养长爪沙鼠群体遗传结构比较分析

目的探索野生与人工驯养的长爪沙鼠群体遗传状况。方法采用12个微卫星引物,对银川与呼和浩特地区捕获的野生长爪沙鼠群体和首都医科大学人工驯养20余年的长爪沙鼠群体的遗传结构进行比较分析。结果12个微卫星位点中有等位基因29个,3个群体的平均等位基因数分别为2.4167、2.2500、2.2500,平均有效等位基因数分别为1.7505、1.7195、1.6968;有11个微卫星位点呈现多态,多态位点百分率分别为91.67%、83.33%、83.33%,香隆指数分别为0.6239、0.5962、0.5591;平均观测杂合度分别为0.5231、0.5051、0.4825,平均期望杂合度分别为0.4008、0.3882、0.3655;银川和首医群体之间的遗传距离最大,为0.1033;呼和浩特和首医群体之间的距离最小,为0.0592。结论3个群体处于Hardy-Weinberg平衡状态,3个群体之间及与总体之间的遗传结构差异无显著性（P〉0.05）。     

红壳色文蛤F1代养殖群体多样性分析

运用形态学标记和分子标记对江苏省文蛤良种场红壳色文蛤F1代养殖群体(父母本为江苏野生红壳色群体)进行遗传多样性分析。用文蛤壳长、壳宽、壳高和体重4个可量性状进行形态学数据的聚类分析,显示可量性状变异系数在38.48%-82.95%。运用7个引物微卫星基因座的多态性进行了养殖群体F1代的分子标记评估,结果表明,7个微卫星基因位点的平均等位基因数3.857 1,平均有效等位基因数2.583 0,平均观察杂合度0.565 3,平均期望杂合度0.565 3,Shannon指数平均数1.050 1,多态信息含量平均数0.522 5。综合形态学数据和分子标记的研究结果表明,红壳色文蛤江苏养殖群体F1代的遗传多样性处于中度偏高水平,具有较高的遗传改良潜力。     

草鱼野生和养殖群体间遗传变异的微卫星分析

运用微卫星标记对江苏境内草鱼(Ctenopharyngodonidella)一个野生群体(邗江群体)和两个养殖群体(淡水中心群体和无锡前洲群体)遗传多样性进行了分析。在10个座位中,每个座位检测到的等位基因数2~8个。有效等位基因数、多态信息含量、期望杂合度、平均表观杂合度均以邗江草鱼野生群体最高,分别为3·9、0·5068、0·6939、0·7;无锡前洲草鱼养殖群体最低,分别为2·2、0·1796、0·5235、0·5286;淡水中心草鱼养殖群体各参数均介于两者之间,分别为3·5、0·2902、0·5418、0·5429。以上结果表明:草鱼野生群体遗传多样性更为丰富,而草鱼养殖群体存在杂合度降低,遗传多样性下降的现象。邗江草鱼野生群体与淡水中心草鱼养殖群体和无锡前洲草鱼养殖群体间遗传分化系数分别为0·219和0·246,而两个草鱼养殖群体间遗传分化系数为0·034。这表明草鱼野生群体与草鱼养殖群体间分化严重,而草鱼养殖群体间分化微弱。各座位分化程度的χ2检验结果表明,10个座位中有GM18、MFW1-1、MFW1-2三个座位群体间分化达到极显著水平,GM03-2、MFW5两个座位群体间分化差异显著,其他座位分化不显著。针对每个座位对各群体进行Hardy-Weinberg平衡检验发现:由于草鱼养殖群体在GM03-1、GM03-2、GM18三个位点杂合子缺失,草鱼野生群体在位点GM19杂合子过剩而严重偏离平衡。实验表明:近交容易引起草鱼遗传多样性下降,纯合速度加快。     

草鱼野生和养殖群体间遗传变异的微卫星分析

运用微卫星标记对江苏境内草鱼(Ctenopharyngodon idella)一个野生群体(邗江群体)和两个养殖群体(淡水中心群体和无锡前洲群体)遗传多样性进行了分析。在10个座位中，每个座位检测到的等位基因数2～8个。有效等位基因数、多态信息含量、期望杂合度、平均表观杂合度均以邗江草鱼野生群体最高，分别为3.9、0.506 8、0.693 9、0.7；无锡前洲草鱼养殖群体最低，分别为2.2、0.179 6、0.523 5、0.528 6；淡水中心草鱼养殖群体各参数均介于两者之间，分别为3.5、0.290 2、0.541 8、0.542 9。以上结果表明：草鱼野生群体遗传多样性更为丰富，而草鱼养殖群体存在杂合度降低，遗传多样性下降的现象。邗江草鱼野生群体与淡水中心草鱼养殖群体和无锡前洲草鱼养殖群体间遗传分化系数分别为0.219和0.246，而两个草鱼养殖群体间遗传分化系数为0.034。这表明草鱼野生群体与草鱼养殖群体间分化严重，而草鱼养殖群体间分化微弱。各座位分化程度的χ2检验结果表明，10个座位中有GM18、MFW1-1、MFW1-2三个座位群体间分化达到极显著水平，GM03-2、MFW5两个座位群体间分化差异显著，其他座位分化不显著。针对每个座位对各群体进行Hardy-Weinberg平衡检验发现：由于草鱼养殖群体在GM03-1、GM03-2、GM18三个位点杂合子缺失，草鱼野生群体在位点GM19杂合子过剩而严重偏离平衡。实验表明：近交容易引起草鱼遗传多样性下降，纯合速度加快。     

三个野生群体日本囊对虾遗传多样性的SSR分析

为了解野生种群日本囊对虾遗传分化和改良遗传育种,用SSR技术对福建厦门(XM)、广东湛江(ZJ)、广西北海(BH)3个地区野生日本囊对虾进行遗传多样性的研究。采用了10对微卫星引物对3个野生种群进行分析,10个微卫星位点在3个种群中均表现为高度的多态性,每个位点平均检测到3.87个等位基因;平均多态信息含量为0.5893;3个群体的观测杂合度分别为0.6243、0.5704、0.4661,全部群体观测杂合度平均为0.5536;期望杂合度分别为0.7193、0.6189、0.6226,全部群体平均期望杂合度为0.6536。这说明3个野生种群在10个微卫星位点上均具有丰富的遗传多样性。基于Nei's遗传距离的聚类分析显示厦门群体和湛江群体的遗传距离较近。     

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。     

虹鳟6个养殖群体遗传多样性的微卫星分析

利用14对微卫星分子标记对虹鳟的6个养殖群体进行遗传多样性分析。结果表明：6个群体的平均等位基因数A为 2.89～4.22,平均有效等位基因数Ne 为2.15～2.78,平均观察杂合度Ho 为0.4801～0.6786,平均期望杂合度He 为0.5052～0.6211,平均多态信息含量PIC 为0.4298～0.5762;其中渤海站群体的等位基因数最多、多态信息含量最高,有效种群最大,通过基因型的P值发现6个群体只在位点AF375034符合Hardy-Weinberg平衡,在其他位点都不同程度的偏离平衡,同时对6个群体的遗传距离进行了估算,聚类分析发现挪威群体与其他群体遗传距离最远。     

牙鲆微卫星标记的筛选及群体遗传结构分析

采用生物素-磁珠吸附微卫星与质粒二次检测相结合的方法克隆牙鲆微卫星,并利用所得到的引物分析野生群体遗传结构.共获得2805个阳性克隆,测序得到3120个含微卫星的序列.其中完美型、非完美型和混合型分别占57.97%、7.25%和34.78%.用Primer 3.0软件设计牙鲆微卫星引物,从中筛选出具稳定多态性的30对,分析中国黄海、渤海海域4个不同海区牙鲆野生群体(大连、北戴河、丹东、青岛)遗传结构.结果显示:有效等位基因数为3.93～9.94,平均为6.95;观测杂合度为0.532～0.895,平均为0.753;期望杂合度为0.635～0.902,平均为0.820;Hardy-Weinberg平衡指数(d)的变化范围为-0.247～0.512,其中7个位点表现为杂合子过剩(d>0),其余位点表现为杂合子缺失(d>0).聚类分析显示:4个群体聚为两类,大连与丹东聚为一类,北戴河与青岛聚为一类.     

大鳞副泥鳅5个野生群体的遗传多样性分析

利用微卫星分子标记分析了天津地区于桥水库、大黄堡湿地、七里海湿地、团泊水库和潮白新河5个野生大鳞副泥鳅群体的遗传多样性。5个群体在12个微卫星位点共检测到98个等位基因,平均等位基因数为8.500;有效等位基因数为2.713;平均观测杂合度为0.526;平均期望杂合度为0.544。5个群体间的遗传分化指数介于0.021~0.106之间,平均遗传分化指数为0.059,属中低水平的遗传分化。AMOVA分析结果显示,在总的变异中,94.1%的遗传变异来自群体内,5.90%的遗传变异来自于群体间。根据Nei’s遗传距离所绘制的系统树显示,于桥水库、团泊水库、七里海湿地和大黄堡湿地4个群体的遗传距离相对较小聚为一支,潮白新河群体单独为一支。遗传瓶颈效应分析表明,该5个群体近期未经受遗传瓶颈效应,处于突变-漂移平衡。总体来看,天津地区5个野生大鳞副泥鳅群体的遗传多样性较高,可作为品种选育的基础群体。     

Comparative genetic diversity of wild and hatchery-produced Pacific oyster (Crassostrea gigas) populations in Korea using multiplex PCR assays with nine polymorphic microsatellite markers

The Pacific oyster, Crassostrea gigas, is the most important and valuable commercial fishery species in Korea. Its farming started 20 years ago and is still rapid expansion in Korea. In this study, to maintain the genetic diversity of this valuable marine resource, possible genetic similarity and differences between the wild population and hatchery population in Tongyeong, Korea were accessed using multiplex assays with nine highly polymorphic microsatellite loci. A total of 250 different alleles were found over all loci. Despite a long history of hatchery practices, very high levels of polymorphism (mean alleles = 22.89 and mean heterozygosity = 0.92) were detected between the two populations. No statistically significant reductions were found in heterozygosity or allelic diversity in the hatchery population compared with the wild population. However, significant genetic heterogeneity was found between two populations. These results provide no evidence to show that hatchery practice of Pacific oyster in Korea has significantly affected the genetic variability of the hatchery stock. Although further studies are needed for comprehensive determinations of the hatchery and wild populations with increased number of Pacific oyster sample collections, information on the genetic variation and differentiation obtained in this study can be applied for genetic monitoring of aquaculture stocks, genetic improvement by selective breeding and designing of more efficient conservation management guidelines for these valuable genetic materials.     

Population genetic structure of wild and hatchery black rockfish Sebastes inermis in Korea, assessed using cross-species microsatellite markers

The population structure of the black rockfish, Sebastes inermis (Sebastidae), was estimated using 10 microsatellite loci developed for S. schlegeli on samples of 174 individuals collected from three wild and three hatchery populations in Korea. Reduced genetic variation was detected in hatchery strains [overall number of alleles (N(A)) = 8.07; allelic richness (A(R)) = 7.37; observed heterozygosity (H(O)) = 0.641] compared with the wild samples (overall N(A) = 8.43; A(R) = 7.83; H(O) = 0.670), but the difference was not significant. Genetic differentiation among the populations was significant (overall F(ST) = 0.0237, P < 0.05). Pairwise F(ST) tests, neighbor-joining tree, and principal component analyses showed significant genetic heterogeneity among the hatchery strains and between wild and hatchery strains, but not among the wild populations, indicating high levels of gene flow along the southern coast of Korea, even though the black rockfish is a benthic, non-migratory marine species. Genetic differentiation among the hatchery strains could reflect genetic drift due to intensive breeding practices. Thus, in the interests of optimal resource management, genetic variation should be monitored and inbreeding controlled within stocks in commercial breeding programs. Information on genetic population structure based on cross-species microsatellite markers can aid in the proper management of S. inermis populations.     

Analysis of microsatellite DNA markers reveals no genetic differentiation between wild and hatchery populations of Pacific threadfin in Hawaii

Pacific threadfin, Polydactylus sexfilis, is popular fish in recreational fishing, as well as aquaculture in Hawaii. Its natural population has been continuously declining in the past several decades. Microsatellite DNA markers are useful DNA-based tool for monitoring Pacific threadfin populations. In this study, fifteen Microsatellite (MS) DNA markers were identified from a partial genomic Pacific threadfin DNA library enriched in CA repeats, and six highly-polymorphic microsatellite loci were employed to analyze genetic similarity and differences between the wild population and hatchery population in Oahu Island. A total of 37 alleles were detected at the six MS loci in the two populations. Statistical analysis of fixation index (F(ST)) and analysis of molecular variance (AMOVA) showed no genetic differentiation between the wild and hatchery populations (F(ST) = 0.001, CI(95%) = -0.01-0.021). Both high genetic diversity (H(o) = 0.664-0.674 and H(e) = 0.710-0.715) and Hardy-Weinberg equilibrium were observed in the wild and hatchery populations. Results of genetic bottleneck analysis indicated that the hatchery was founded with sufficient numbers of brooders as inbreeding coefficient is very low (F(IS) = 0.052-0.072) in both wild and hatchery populations. Further studies are needed for comprehensive determinations of genetic varieties of primary founder broodstocks and successive offspring of the hatchery and wild populations with increased number of Pacific threadfin sample collections.     

Wild and aquaculture populations of the eastern oyster compared using microsatellites

Five new microsatellite markers were developed for the eastern oyster (Crassostrea virginica), and allelic variability was compared between a wild Chesapeake Bay population (James River) and a hatchery strain (DEBY). All loci amplified readily and demonstrated allelic variability with the number of alleles ranging from 16 to 36 in the wild population and from 11 to 19 in the DEBY strain. Average observed and expected heterozygosities were estimated at 0.66 and 0.80 in the hatchery sample. The corresponding estimates were 0.91 and 0.75 in the wild sample. Results indicated lower genetic variability in the DEBY strain and significant genetic differentiation between the wild population and hatchery strain. These microsatellite loci will prove valuable for future population genetic studies and in tracking of hatchery strains used in restoration.     

青鱼野生与养殖群体遗传变异的微卫星分析

研究利用自主开发的12个微卫星标记, 对来自于长江水系4个野生群体(湖北石首、湖南湘江、江苏邗江、浙江嘉兴)和1个养殖群体(江苏吴江)青鱼(Mylopharyngodon piceus)进行遗传多样性和遗传结构分析。遗传多样性分析结果显示这12个位点多态信息含量(PIC)介于0.660—0.923, 表明这12个位点均具有高度多态性(PIC>0.5)。5个群体的平均等位基因数(N_a)介于7.917—11.667, 平均有效等位基因数(N_e)介于4.837—6.035; 平均观测杂合度介于0.713—0.861; 平均期望杂合度介于0.749—0.819; 平均多态信息含量介于0.711—0.788, 表明这5个群体均具有较高的遗传多样性。遗传距离分析结果表明4个野生群体之间遗传距离较近, 养殖群体与这4个野生群体遗传距离均较远。UPGMA系统进化树显示, 湘江群体和石首群体首先聚为一支, 然后与邗江群体和嘉兴群体聚为一支, 最后与吴江养殖群体聚为一支。这12个微卫星位点具有较为丰富的遗传多样性特征, 可以用于青鱼不同群体的种质资源的评估和遗传多样性的分析。     

Genetic diversity and variation in wild populations of dark sleeper (Odontobutis potamophila) in China inferred with microsatellite markers

Twenty-one highly variable microsatellite loci were used to investigate the genetic diversity and variation of Odontobutis potamophila in China. A total of 160 samples from five wild populations (Dangtu, Sheyang, Yuyao, Minjiang and Donxishan) were genotyped. All of the 21 microsatellite loci tested in this study showed polymorphism. The number of allele per locus ranged from 5.05 to 9.90. Locus 87a of Minjiang population had a 259-bp characteristic allele. The average observed heterozygosity and expected heterozygosity ranged from 0.33 to 0.62 and from 0.40 to 0.70, respectively. The pair-wise F_ST tests and NJ trees of the five O. potamophlia populations revealed that Dangtu, Sheyang, Yuyao and Dongxishan were genetically close to one another and distinct from Minjiang. Far genetic distances were observed among populations from distant geographical areas. This result provided guide for the use of O. potamophila breeds and the protection of the species.     

New polymorphic microsatellite markers in Pacific abalone Haliotis discus hannai and their application to genetic characterization of wild and aquaculture populations

Seven new microsatellite markers were developed for the Pacific abalone (Haliotis discus hannai, Haliotidae), and allelic variability was compared between a wild population and a hatchery population in Yeosu, Korea. All loci amplified readily and demonstrated allelic variability, with the number of alleles ranging from 6 to 15 in the wild population and from 3 to 12 in farmed populations. Average observed and expected heterozygosities were estimated at 0.65 and 0.77 in the hatchery samples, and 0.79 and 0.87 in the wild samples. These results indicated lower genetic variability in the hatchery population, as compared with the wild population and significant genetic differentiation between the wild population and the hatchery samples (F _ST=0.055, p<0.001). These microsatellite loci may be valuable for future population genetic studies and for tracking hatchery samples used in stock enhancement programs.     

Microsatellite variability and differentiation of hatchery stocks of chum salmon Oncorhynchus keta Walbaum in Sakhalin

Variability at eight microsatellite loci was examined in five populations of chum salmon Oncorhynchus keta Walbaum from Sakhalin hatcheries. The population of Kalinino hatchery had the lowest heterozygosity and the lowest average number of alleles per locus. The populations examined exhibited significant differentiation, theta ST = 0.026 on average per locus. The maximum genetic differences were found between the populations of the Kalinino and the Ado-Tymovo hatcheries; the latter differs from the remaining populations also by the highest number and high frequencies of specific alleles. The genetic features of the Taranai hatchery population, observed at microsatellite loci, reflect its "mixed" origin.     

Comparison of genetic diversity at microsatellite loci and quantitative traits in hatchery populations of Japanese flounder Paralichthys olivaceus

Relationships of genetic diversity at microsatellite loci and quantitative traits were examined in hatchery-produced populations of Japanese flounder using a relatively straightforward experiment. Five hatchery populations produced by wild-caught and domesticated broodstocks were used to examine the effects of different levels (one to three generations) of domestication on the genetic characteristics of hatchery populations. Allelic richness at seven microsatellite loci in all hatchery populations was lower than that in a wild population. Genetic variation measured by allelic richness and heterozygosity tended to decrease with an increase in generations of domestication. In addition, the degree of genetic differentiation from a wild population increased with an increase in generations of domestication. Significant differences in three morphometric traits (dorsal and anal fin ray counts and vertebral counts) and three physiological traits (high temperature, salinity and formalin tolerance) were observed among the hatchery populations. The degree of phenotypic difference among populations was larger in morphometric traits than in physiological traits. The divergence pattern of some quantitative traits was similar to that observed at microsatellite loci, suggesting that domestication causes the decrease of genetic variation and the increase of genetic differentiation for some quantitative traits concomitantly with those for microsatellite loci. Significant positive correlation was observed between F _ST and the degree of phenotypic difference in the three morphometric traits and formalin tolerance, indicating that genetic variation at microsatellite loci predicts the degree of phenotypic divergence in some quantitative traits.