我国草鱼野生群体D-Loop序列遗传变异分析

利用线粒体DNA的D-Loop区序列, 对来自长江水系(邗江、吴江、九江、石首、木洞和万州)、珠江水系(肇庆)和黑龙江水系(嫩江)的8个草鱼野生群体开展了遗传变异分析。在424尾鱼中检测到34个变异位点, 34个单倍型, 单倍型多样性介于0.4740.708。群体间Kimura双参数遗传距离介于0.00200.0049。长江下游3个群体间遗传距离最近, 遗传分化不显著(P0.05); 肇庆群体与长江上游3个群体遗传距离较近, 与九江群体遗传分化不显著(P0.05); 嫩江群体与长江上游2个群体遗传距离较近, 与万州群体遗传分化不显著(P0.05)。遗传距离与地理距离存在极显著正相关(R=0.61, P0.01)。分子方差分析显示, 不同流域间遗传变异占总变异26.24%, 差异极显著(P0.01)。34个单倍型分为2个分支, 分化极显著(FST=0.644, P0.01), 推测分化时间为第四纪更新世纪晚期。       

三峡库区5 个鲢群体遗传变异的微卫星分析

研究利用10 个高度多态的微卫星标记对三峡水库秭归、巫山、云阳、忠县、木洞等5 个库区鲢(Hypophthalmichthys molitrix)的野生群体进行了遗传多样性分析。检测到161 个等位基因, 群体共有等位基因84 个, 每个微卫星位点的等位基因数729 不等。平均观测杂合度Ho 为0.7840.846, 平均期望杂合度He 为0.8280.847, 平均多态信息含量PIC 为0.7970.817。Fst 值为-0.0010.009, 表明5 个鲢群体间没有遗传分化。Hardy-Weinberg 平衡检验表明巫山、云阳、木洞群体在一些位点上偏离遗传平衡。Bottleneck 分析显示长江三峡库区江段的鲢群体可能在历史上经历了遗传瓶颈。5 个群体间的遗传相似系数为0.8910.950, 遗传距离为 0.0500.115, 根据 Nei's 遗传距离所绘制的聚类图, 表明鲢群体间的遗传距离与其地理距离基本一致。贝叶斯分析结果也证实三峡库区5 个鲢群体可视为一个类群。尽管没有检测到遗传分化, 数据清晰地表明三峡库区的鲢群体仍有很高的遗传多样性, 研究结果为三峡地区和长江上游的鲢种质资源保护和种群评估提供了参考。       

长江水系钱草鱼遗传结构及变异性的RAPD研究

采用随机扩增多态性DNA（RAPD）技术对长江中游的湖北嘉鱼与江西瑞昌两个地理群体和中游的汉江和湘江两大水系的鲢和草鱼的群体进行了遗传学研究。发现长江水系链的遗传变异要高于草鱼,与现今生物量成反比的反常现象。鲢遗传多样性从大到小的分布是嘉鱼→湘江→瑞昌→汉江。草鱼遗传多样性从大到小的分布是瑞昌→汉江→湘江→嘉鱼,鲢和草鱼的遗传多样性地理分布并不一致。遗传分化指数Gst分别为12.3%和17.5%,表明鲢和草鱼的四个地理群体的遗传分化度较低,可能与地理较近和基因交流频繁有关。     

草鱼EST-SSR标记及5个不同地域群体的遗传结构分析

以草鱼(Ctenopharyngodon idella)脑、肌肉、肝等组织构建cDNA文库,经测序获得unigenes序列45 318个,从中筛选微卫星序列共5 556个,据此设计EST-SSR引物118对,其中19对引物能够扩增出带型清晰且多态性较高的谱带。用这19个EST-SSR标记研究3个长江水系群体(石首、监利和长沙)和2个珠江水系群体(清远和肇庆)草鱼的遗传结构。结果表明,5个群体的平均多态信息含量(PIC)为0.415 4～0.460 4,显示草鱼群体的遗传多样性偏低;平均观测杂合度(Ho)为0.415 8～0.501 3,平均期望杂合度为(He)0.450 6～0.502 8,其中,长沙群体平均期望杂合度最高,为0.502 8,监利群体的平均观察杂合度和平均期望杂合度均最低,分别为0.415 8和0.450 6,即长沙群体的遗传多样性最高,监利群体的遗传多样性最低;对数据进行F-检验,结果表明,群体间的遗传分化程度低。Hardy-Weinberg平衡的卡方检验结果表明,5个群体均一定程度上偏离了平衡;聚类分析显示长沙群体、石首群体与监利群体聚成一支;肇庆群体与清远群体聚成一支,这与草鱼群体的流域分布一致。     

基于G-SSR和EST-SSR标记的鲫6个群体遗传结构分析

研究同时利用非编码区和编码区微卫星标记(G-SSR和EST-SSR)分析黑龙江、长江、奉化江及淮河水系共6个野生鲫(Carassius auratus)群体的遗传多样性及遗传结构, 并比较2类不同来源SSR用于鲫群体遗传多样性分析的差异。8个G-SSR标记在6个鲫群体中检测到173个等位基因, 平均N_a、N_e、H_o、H_e以及PIC分别为22、12.9、0.769、0.893和0.879, 群体间F_st值介于0.008—0.085, 其中来自黑龙江水系的2个群体与其余水系的所有群体均达到或接近于中等程度的遗传分化, 而长江、奉化江和淮河水系4个群体间的遗传分化程度不明显。Nei’s遗传距离介于0.203—0.701; 根据遗传距离所绘制的UPGMA聚类图将6个鲫群体划分为2个大分支, 其中来自黑龙江水系的2个群体聚为一枝, 其余水系群体聚为另一枝。贝叶斯分析也支持这一结果, 将6个鲫群体划分为2个最佳理论群。利用8个EST-SSR标记在6个鲫群体中共检测到155个等位基因, 平均N_a、N_e、H_o、H_e以及PIC分别为19、9.5、0.728、0.870和0.855; 群体间F_st值和Nei’s遗传距离分别介于0.005—0.084和0.117—0.683; 基于EST-SSR标记的UPGMA聚类分析和贝叶斯分析也将6个鲫群体划为两大类群: 黑龙江水系群体; 长江、奉化江和淮河水系群体。G-SSR和EST-SSR标记检测6个鲫群体的平均多态信息含量(PIC)分别为0.786—0.864和0.761—0.833。研究结果显示: 6个野生鲫群体均具有较高的遗传多样性, 但黑龙江水系群体多样性低于其他水系群体; 尽管EST-SSR标记的多态性略小于G-SSR标记, 但是2类微卫星标记均揭示了相似的鲫群体遗传结构和分化格局。研究结果对鲫种质资源的保护和EST-SSR标记在鱼类群体遗传学研究价值的评价提供了新的信息。     

长江草鱼不同群体EST-SSR 多态性标记的筛选及其遗传结构分析

为对我国不同地域草鱼群体进行鉴定和遗传多样性分析, 在2400 条草鱼EST 序列中, 对其二碱基至五碱基重复序列进行筛选, 共筛选出微卫星位点181 个, 选取其中的46 个进行引物的设计与合成, 获得呈多态性的微卫星引物9 对。利用这9 对引物对8 个长江水系草鱼群体和1 个红色草鱼自然突变群体进行了遗传结构分析。结果显示, 长沙草鱼、安庆草鱼、嘉兴草鱼、靖江草鱼、石首草鱼、松江草鱼、瑞昌草鱼、邗江草鱼和红色突变草鱼9 个群体的平均等位基因数(Na)分别为4.67、5.22、5.33、5.00、4.89、4.78、4.89、4.67 和2.56, 平均期望杂合度(He)分别为0.6397、0.6543、0.6831、06356、0.6737、0.6483、0.6664、0.7129 和0.4696, 平均多态信息含量(PIC)分别为0.5787、0.6126、0.6283、0.5894、0.6217、0.5956、0.6136、0.6582 和0.3949, 表明邗江草鱼的遗传多样性最高, 而红草鱼的遗传多样性最低。聚类分析表明, 8 个长江水系草鱼群体首先聚类, 最后与红色草鱼聚类;其中, 安庆草鱼与松江草鱼首先聚为一支, 遗传距离较近, 为0.0725;红色草鱼与长沙草鱼的遗传距离最远, 为0.5217。研究结果对我国草鱼种质资源保存、种群鉴定和良种选育具有重要意义。       

长江水系草鱼遗传多样性的微卫星DNA分析

利用已发表的鲤微卫星引物在草鱼中进行PCR扩增,结果有5对引物(6个座位)能成功扩增并且有较高多态性,等位基因数在3-7个之间。这些异种扩增的草鱼微卫星符合孟德尔遗传规律。测序证明草鱼中的微卫星核心重复序列部分与鲤中的原始核心序列相似,也有一些变化。随后用这6个多态微卫星座位研究了来自长江水系的四个草鱼群体的遗传结构,结果显示每个群体的平均等位基因数在38与48之间,平均观测杂合度(Ho)在04000与05741之间,平均期望杂合度(HE)在04773与06489之间,有多个座位在不同的群体中偏离哈代-温伯格平衡。遗传距离分析表明四川群体与洞庭湖群体遗传距离最远,而嘉鱼群体与鄱阳湖群体遗传距离较近。分子变异分析(AMOVA)表明,群体内遗传变异与群体间遗传变异分别占总遗传变异的9560%与440%,固定系数(FST)为0044,这表明长江水系草鱼目前的群体分化很微弱。       

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。     

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。     

黄颡鱼微卫星标记的筛选及三个野生群体的遗传结构分析

为了探明长江中上游流域黄颡鱼野生群体的遗传多样性状况和遗传结构,本研究采用磁珠富集法筛选出10个黄颡鱼微卫星标记,并利用其对长江中上游流域3个黄颡鱼(Pelteobagrus fulvidrac)野生群体(赤水群体、乐山群体、洞庭群体)的遗传结构进行分析。获得65个阳性克隆并测序,得到36个含有微卫星的序列,设计并合成了22对微卫星引物,经筛选得到10对多态性稳定的引物,其中高多态性位点6个,中多态位点3个。每对引物等位基因数2-9个,平均4.8。3个群体(赤水、乐山和洞庭)的平均多态信息含量(PIC)分别为0.5438、0.4568和0.3965,平均有效等位基因(Ne)分别为2.9928、2.5401和2.1713,平均期望杂合度(He)分别为0.6280、0.5277和0.4757,表明这3个群体遗传多样性水平较高,其中赤水群体遗传多样性最高,洞庭群体最低。种群分化指数(Fst)和遗传距离(Ds)分析表明,洞庭群体和乐山群体之间的亲缘关系最近,而与赤水群体的亲缘关系最远。聚类分析显示,乐山群体和洞庭群体聚为一支,赤水群体单独聚为一支。     

Native bighead carp Hypophthalmichthys nobilis and silver carp Hypophthalmichthys molitrix populations in the Pearl River are threatened by Yangtze River introductions as revealed by mitochondrial DNA

Bighead carp Hypophthalmichthys nobilis and silver carp Hypophthalmichthys molitrix have been two economically important aquaculture species in China for centuries. In the past decades, bighead and silver carp have been introduced from the Yangtze River to many river systems in China, including the Pearl River, in annual, large-scale, stocking activities to enhance wild fisheries. Nonetheless, few studies have assessed the ecological or genetic impacts of such introductions on native conspecific fish populations. An mtDNA D-loop segment of 978 bp from 213 bighead carp samples from 9 populations and a 975 bp segment from 204 silver carp samples from 10 populations were obtained to evaluate genetic diversity and population integrity. Results from a haplotype network analysis revealed that most haplotypes of the Pearl River clustered with those of Yangtze River origin and only a small proportion were distinct, suggesting that both the native Pearl River bighead and silver carp populations are currently dominated by genetic material from the Yangtze River. The genetic diversity of Pearl River populations is high in both species because of this inter-population gene flow, but the diversity of native Pearl River populations is low. To preserve the native genetic diversity, stocking of non-native fingerlings should cease immediately and native Pearl River bighead and silver carp fish farms should be established. This research demonstrates the danger to native biodiversity across China because of the substantial, ongoing stock-enhancement activities without prior genetic assessment.     

Microsatellite genetic diversity and differentiation of native and introduced grass carp populations in three continents

Grass carp (Ctenopharyngodon idella), a freshwater species native to China, has been introduced to about 100 countries/regions and poses both biological and environmental challenges to the receiving ecosystems. In this study, we analyzed genetic variation in grass carp from three introduced river systems (Mississippi River Basin in US, Danube River in Hungary, and Tone River in Japan) as well as its native ranges (Yangtze, Pearl, and Amur Rivers) in China using 21 novel microsatellite loci. The allelic richness, observed heterozygosity, and within-population gene diversity were found to be lower in the introduced populations than in the native populations, presumably due to the small founder population size of the former. Significant genetic differentiation was found between all pairwise populations from different rivers. Both principal component analysis and Bayesian clustering analysis revealed obvious genetic distinction between the native and introduced populations. Interestingly, genetic bottlenecks were detected in the Hungarian and Japanese grass carp populations, but not in the North American population, suggesting that the Mississippi River Basin grass carp has experienced rapid population expansion with potential genetic diversification during the half-century since its introduction. Consequently, the combined forces of the founder effect, introduction history, and rapid population expansion help explaining the observed patterns of genetic diversity within and among both native and introduced populations of the grass carp.     

草鱼中国土著群体与欧美日移居群体遗传差异的线粒体序列分析

草鱼是中国的土著鱼类,自20世纪60年代以来已被移居到100多个国家和地区,主要用来控制水草或水产养殖。本研究通过线粒体D-Loop区（764bp)和COII＋tRNA基因(719bp)序列分析,了解草鱼的中国土著群体（长江、珠江、黑龙江）和国外移居群体（匈牙利多瑙河、美国密西西比河、日本利根川河）之间以及各地方群体间的遗传差异。结果表明,中国土著草鱼群体的遗传变异高于国外移居群体;分子方差分析（AMOVA）表明,不同草鱼群体的遗传变异主要来自群体内,而不同地域间的差异极少;群体两两间Fst值比较表明,大多数群体之间遗传差异极显著;由TCS构建的单倍型网络结构图显示,长江草鱼群体是最原始的群体,其他水系草鱼均由长江群体演化而来;通过基因流分析发现,匈牙利多瑙河群体和日本利根川河群体来自长江和黑龙江群体,美国密西西比河群体除引自长江、黑龙江水系外,还有部分引自于珠江水系。     

Genetic variation analysis within and among six varieties of common carp (Cyprinus carpio L.) in China using microsatellite markers

Five microsatellites were used to study the genetic diversity and genetic structure of one wild and five domestic varieties of common carp in China (the Yangtze River wild common carp, Xingguo red carp, purse red carp, Qingtian carp, Russian scattered scaled mirror carp and Japanese decorative carp). All loci in this study showed marked polymorphism with the number of alleles from 4 to 13. Domestic varieties (except Xingguo red carp) showed less genetic diversity than the Yangtze River wild common carp in terms of allelic diversity. Population differentiation was assessed and each combination of populations displayed significant differentiation (p < 0.05) with the exception of that between the Yangtze River wild common carp and Xingguo red carp. Genetic distance analysis (Nei's standard genetic distance and pairwise F(st) distance) showed that the largest distance was between Russian scattered scaled mirror carp and the Yangtze River wild common carp and the smallest distance was between the Yangtze River wild common carp and Xingguo red carp. However, among six populations Japanese decorative carp displayed the highest level of variability in terms of heterozygosity.     

Genetic Variation Analysis within and among Six Varieties of Common Carp (Cyprinus carpio L.) in China Using Microsatellite Markers

Five microsatellites were used to study the genetic diversity and genetic structure of one wild and five domestic varieties of common carp in China (the Yangtze River wild common carp, Xingguo red carp, purse red carp, Qingtian carp, Russian scattered scaled mirror carp and Japanese decorative carp). All loci in this study showed marked polymorphism with the number of alleles ranging from 4 to 13. Domestic varieties (except Xingguo red carp) showed less genetic diversity than the Yangtze River wild common carp in terms of allelic diversity. Population differentiation was assessed and each combination of populations displayed significant differentiation (P < 0.05) with the exception of that between the Yangtze River wild common carp and Xingguo red carp. Genetic distance analysis (Nei's standard genetic distance and pairwise F _st distance) showed that the largest distance was between Russian scattered scaled mirror carp and the Yangtze River wild common carp and the smallest distance was between the Yangtze River wild common carp and Xingguo red carp. However, among six populations Japanese decorative carp displayed the highest level of variability in terms of heterozygosity.