鄱阳湖日本沼虾15个群体遗传多样性的微卫星分析

利用徽卫星分子标记研究鄱阳湖15个日本沼虾(Macrobrachium nipponense野生群体的遗传多样性.结果表明:10个微卫星位点呈高度多态性,共检测到129个多态性位点;每个群体中至少有5个位点显著偏离Hardy-Weinberg平衡,表现出杂合不足;15个日本沼虾群体均表现出较高的遗传多样性,其中大坝外群体和星池群体遗传多样性较高,万户和湖口群体相对较低.瓶颈效应和突变-漂移平衡分析表明,鄱阳湖日本沼虾群体近期没有经历过瓶颈效应,群体数量也没有下降.群体间F统计量及AMOVA分析显示,鄱阳湖日本沼虾群体存在极显著的遗传分化程度(FST=0.04709,P＜O.01).综上所述,鄱阳湖日本沼虾群体具有丰富的遗传多样性,可作为日本沼虾选育的基础群.     

长江下游地区夜鹭种群微卫星变异及遗传多样性

利用微卫星位点对长江下游地区夜鹭3个地方种群的遗传多样性及其种群结构进行了分析。研究结果表明:除了Ah526位点外,其他7个位点在夜鹭种群中均为高度多态。在3个地方种群中,6个微卫星位点中经Bonferroni校正后南京大校场种群和芜湖四褐山种群中分别有2个及3个位点显示杂合不足,显著偏离了哈迪-温伯平衡,这可能与夜鹭繁殖后个体的扩散能力较强及长江下游地区夜鹭存在着替代型迁徙现象有关。突变-漂移平衡分析表明,长江下游地区夜鹭种群显著具有杂合过剩的位点,这表明长江下游地区夜鹭种群已偏离了突变-漂移平衡,近期可能经历了瓶颈效应,种群数量曾经下降。地方种群间Fst分析表明,长江下游地区夜鹭地方种群间遗传分化程度较低,并没有形成显著的遗传结构,在保护与管理上可以作为同一个保护单元(或管理)单元     

人工养殖与选育对罗氏沼虾遗传多样性的影响

为探讨人工养殖与选择育种对罗氏沼虾(Macrobrachium rosenbergii)遗传多样性的影响,实验测定了孟加拉野生群体、缅甸野生群体、浙江养殖群体、广西养殖群体及选育群体"南太湖2号"共111只罗氏沼虾核糖体转录间隔区2(Internal transcribed spacer 2,ITS2)基因序列,结果发现58个碱基变异位点,定义56个单倍型。在5个群体中,孟加拉野生群体的遗传多样性最高(平均核苷酸差异数K和核苷酸多态性指数Pi分别为7.186和0.0155),依次为缅甸野生群体、浙江养殖群体、广西养殖群体,选育群体"南太湖2号"遗传多样性最低(K和Pi分别为3.032和0.0065)。5个群体间配对Fst分析表明,养殖群体与野生群体遗传分化显著(P<0.01),选育群体"南太湖2号"不仅与野生群体遗传分化显著,同时还与广西养殖群体产生了显著的遗传分化(P<0.01)。系统树显示,孟加拉野生群体和缅甸野生群体聚为一支,浙江养殖群体、广西养殖群体和选育群体"南太湖2号"则聚为另一支。研究结果表明,人工养殖和选育降低了罗氏沼虾的遗传多样性水平,并导致群体间发生了显著的遗传分化。     

利用COI基因序列分析长江与澜沧江水系日本沼虾群体的遗传结构

测定了我国长江水系和澜沧江水系的日本沼虾9个群体,共79个个体的线粒体COI基因序列片段(约450bp),结果发现有89个变异位点,共计有46个单倍型。其中云南昆明(KM)群体具有较丰富的遗传多样性(h=1.000,π=0.028),而重庆(CQ)群体的遗传多样性最小(h=0.700,π=0.008)。AMOVA分析表明,群体间的遗传变异占总遗传变异的9.66%,而90.34%的遗传变异源于群体内。采用邻接法(NJ)构建的分子系统树显示,46个单倍型明显地聚为长江中下游和长江上游与澜沧江两个族群。其结果可以为合理开发和利用日本沼虾自然野生资源,以及建立和保护日本沼虾种质资源库及基因库提供必要的参考。     

钱塘江日本沼虾野生群体遗传变异的SSR分析

利用微卫星标记分析了钱塘江干流水域闻堰、富阳、场口、桐庐等7个野生日本沼虾群体的遗传多样性和遗传结构。结果表明:10个微卫星位点呈现高度多态性;闻堰、富阳、场口、新安江等中下游野生群体的遗传多样性水平有高于歙县和休宁两个上游群体遗传多样性水平的趋势。符号检验和Wilcoxon符号秩次检验的结果表明,钱塘江日本沼虾群体近期没有发生瓶颈效应,群体数量也没有下降。FST的范围介于0.0201～0.1069。分子方差分析结果显示,大部分的遗传变异(93.48%)存在于个体间,少部分遗传变异(6.52%)存在于群体之间。群体间FST及AMOVA分析表明,群体处于中等遗传分化水平;基于DA遗传距离构建的NJ聚类树显示,地理位置相邻的群体聚在一起。STRUCTURE分析413份参试的日本沼虾样本被分为2个理论种群,即上游歙县和休宁群体为一个理想种群,其余中下游的5个群体为另一个理想种群。日本沼虾的遗传多样性和遗传结构与所生存的地理位置具有相关性。     

利用COI基因序列分析长江与澜沧江水系日本沼虾群体的遗传结构

测定了我国长江水系和澜沧江水系的日本沼虾9个群体，共79个个体的线粒体COI基因序列片段（约450 bp），结果发现有89个变异位点，共计有46个单倍型。其中云南昆明（KM）群体具有较丰富的遗传多样性（h=1.000，π=0.028），而重庆（CQ）群体的遗传多样性最小（h=0.700，π=0.008）。AMOVA分析表明，群体间的遗传变异占总遗传变异的9.66%，而90.34%的遗传变异源于群体内。采用邻接法（NJ）构建的分子系统树显示，46个单倍型明显地聚为长江中下游和长江上游与澜沧江两个族群。其结果可以为合理开发和利用日本沼虾自然野生资源，以及建立和保护日本沼虾种质资源库及基因库提供必要的参考。     

长江野鲤(Cyprinus carpio)及两种养殖鲤群体遗传多样性评估

为了给鲤鱼遗传资源保护及利用提供较为准确的基础数据,利用10对微卫星标记分析了黄河鲤(Huanghe Cyprinus carpio,人工养殖群体)、长江野鲤(Changjiang wild Cyprinus carpio,安徽段)、安徽养殖鲤(Anhui cultured Cyprinus carpio,宿州市)群体遗传多样性。遗传多样性分析实验表明:3个群体均具有较高的遗传水平,且长江野鲤群体遗传多样性高于黄河鲤、安徽养殖鲤;卡方检验表明:3个群体在较大程度上受到人类活动及生态环境变化的影响,30个位点中76.67%的位点显著偏离Hardy-Weinberg平衡。遗传距离、遗传相似度、非加权组平均法(unweighted pair-group method with arithmetic means,UPGMA)聚类树及贝叶斯聚类分析均显示,长江野鲤与安徽养殖鲤亲缘关系较近,研究情况与实际生产中养殖户从长江里获得鲤鱼亲本用于繁殖苗种的现象相符。突变-漂移平衡分析显示,在TPM模式下,Wilcoxon符号秩次检验中黄河鲤群体显著偏离突变-漂移平衡,需进一步扩大选育群体。总体来说,黄河鲤、长江野鲤、安徽养殖鲤群体遗传多样性均较高,具有进一步的选育空间。     

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。       

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。     

飘鱼微卫星位点的筛选及珠江流域5个地理群体的遗传多样性分析

为了解珠江流域飘鱼(Pseudolaubuca sinensis)群体间的遗传多样性及其分化程度, 利用RAD-Seq技术开发出微卫星位点, 并设计了100对微卫星引物, 筛选出66个可稳定扩增出目的条带的位点, 其中16个具有较高的多态性(PIC>0.5), 以2碱基重复居多。利用其中10对多态性位点对珠江流域的郁江(YuJ)、左江(ZJ)、右江(YJ)、融江(RJ)和桂江(GJ)飘鱼群体进行遗传多样性研究, 得到有效等位基因数、观测杂合度、期望杂合度范围分别为5.2028—6.3800、0.6773—0.7667和0.7975—0.8425, 表明珠江流域5个飘鱼群体具有较高的遗传多样性, 以YuJ群体遗传多样性最高, RJ群体遗传多样性为最低。且群体间各个遗传参数相差较小, 说明他们的遗传多样性水平相近。AMOVA分析显示, 遗传变异主要来自于群体内(98.45%), 仅一小部分的变异来自于群体间(1.55%), 总群体的遗传分化系数F_st为0.015, 两两群体间的F_st在–0.0033—0.0295波动, 属于低等程度的分化。群体间基因交流值(N_m)在8.2246—76.0075, 表明群体间基因交流频繁, 对遗传漂变作用的抵制能力较强。研究筛选出了多态性高的微卫星位点, 并利用其对5个飘鱼群体遗传多样性进行评价, 旨在有效地监测飘鱼的种质资源状况, 为其资源的开发利用和保护提供科学指导。     

Genetic diversity of common carp from two largest Chinese lakes and the Yangtze River revealed by microsatellite markers

Six polymorphic microsatellites (eight loci) were used to study the genetic diversity and population structure of common carp from Dongting Lake (DTC), Poyang Lake (PYC), and the Yangtze River (YZC) in China. The gene diversity was high among populations with values close to 1. The number of alleles per locus ranged from 2 to 11, and the average number of alleles among 3 populations ranged from 6.5 to 7.9. The mean observed (H _O) and expected (H _E) heterozygosity ranged from 0.4888 to 0.5162 and from 0.7679 to 0.7708, respectively. Significant deviations from Hardy–Weinberg Equilibrium expectation were found at majority of the loci and in all three populations in which heterozygote deficits were apparent. The analysis of molecular variance (AMOVA) indicated that the percent of variance among populations and within populations were 3.03 and 96.97, respectively. The Fst values between populations indicated that there were significant genetic differentiations for the common carp populations from the Yangtze River and two largest Chinese freshwater lakes. The factors that may result in genetic divergence and significant reduction of the observed heterozygosity were discussed.     

斑节对虾两个野生亲虾种群遗传多样性

采用RAPD和mtDNA 16S rRNA基因序列分析方法对海南和马来西亚斑节对虾(Penaeus monodon)种群进行了遗传多样性和遗传分化研究.结果表明:15个RAPD随机引物共检测到82个位点,海南和马来西亚种群的多态位点比例分别为75.90％和76.83％,杂合度分别为0.199和0.218,遗传多样性指数分别为0.276和0.288,种群间的遗传距离为0.015;16S rRNA基因检测的种内遗传变异较低,马来西亚和海南种群的核苷酸多样性分别为0.011和0,种群之间的遗传距离为0.008;马来西亚种群比海南种群的遗传变异水平要高得多,且海南种群可能起源于马来西亚种群;进行遗传选育时可考虑引进马来西亚亲虾作为奠基群体.     

广西石灰岩地区蜈蚣蕨居群的遗传多样性研究

采用等位酶分析方法 ,研究了广西石灰岩地区蜈蚣蕨居群的遗传多样性 ,分析了其空间变化趋势。检测了 8个酶系统 ,1 5个酶位点。分析结果表明 :广西石灰岩地区蜈蚣蕨居群遗传多样性程度较高 ,每个位点的等位基因平均数为 1 .6 7,多态位点为 5 7.78% ,平均期望杂合度为 0 .2 4 9。蜈蚣蕨居群的遗传组成在居群间有一定的差异 ,但差异的程度并不与空间距离成正比     

Genetic variation within and between populations of hermaphroditic <Emphasis Type="Italic">Bulinus truncatus</Emphasis> tetraploid freshwater snails of the Albertine Rift,East Africa

Genetic variability within and among Bulinus truncatus of the Albertine Rift freshwater bodies were assessed to investigate the degree of inbreeding and gene flow in the snail populations. The effect of ploidy on the genetic structuring of B. truncatus is also described. We characterized the genetic structure of seven B. truncatus populations from Lake Albert, Lake Kivu, and Katosho swamp in Tanzania using five polymorphic microsatellite loci. Genetic differentiation was quantified using pairwise FST values and Nei’s standard genetic distances. Different alleles were observed across all loci and genetic diversity was low although it varied greatly across populations; observed heterozygosity was, however, higher than the expected heterozygosity in three of the populations studied. Significant heterozygote deficiencies were observed coupled with significant linkage disequilibria in five populations for all the five loci examined in this study. We found significant genetic differentiation among the seven freshwater bodies; private alleles were observed across all loci indicating restricted or absence of gene flow between populations. Limited snail dispersal and the reproductive biology of B. truncatus are the major forces shaping the genetic variation observed. Low genetic variation within B. truncatus populations exposes them to a high parasite infection risk as predicted in the Red Queen hypothesis.     

Genetic structure of two Turkish brown trout populations

The genetic structure of two brown trout Salmo trutta populations living in Lake Abant in Bolu and Üzüm River in Antalya was determined by examining 15 enzyme coding loci ( AAT, ADH, LDH, MDH, MEP, GPI, PGM and SOD ) using starch gel electrophoresis. Population specific mobilities were observed for the fixed alleles of LDH-B2, mMEP-2 and SOD-1 loci. Polymorphisms in sAA T-4, GPI-B2 loci were observed within the populations. Average heterozygosity of Abant and Antalya populations was 0.0358 and 0.0224 respectively. For LDH-C which is the post glaciation marker locus, the ancestral allele * 105 was found to be fixed in both of the populations. Nei's genetic distance between the two populations was 0.2507 which is the level of genetic distance often found between different species. This difference seems to be due to the presence of unique alleles in the LDH-B2, mMEP-2 and SOD-1 loci of the Abant population, indicating that the conservation of the Abant population and its heterozygosity is of prime importance.     

Isolation and characterization of 15 nuclear microsatellite markers for Baillonella toxisperma Pierre (Sapotaceae), a low-density tree species of Central Africa

Baillonella toxisperma is a scattered endemic species of the Guineo-Congolian forest. We developed 15 nuclear microsatellite markers specifically for B. toxisperma to analyse the genetic diversity of 188 individuals distributed in two natural populations in Gabon. On average, 8.3 alleles per locus were identified; observed heterozygosity ranged from 0.056 to 0.872 and expected heterozygosity from 0.282 to 0.823 among populations. Only three loci showed a significant departure to Hardy-Weinberg equilibrium, but no linkage disequilibrium was observed for any pair of loci.     

Morphological and genetic differentiation of the African clupeid Limnothrissa miodon 34 years after its introduction to Lake Kivu

The evolutionary consequences of an artificial introduction of the clupeid Limnothrissa miodon from Lake Tanganyika into Lake Kivu, East Africa were examined. In 1959, 57 400 fry (mixture of Limnothrissa and the related clupeid, Stolothrissa tanganicae ), were released into Lake Kivu to boost fisheries production. Comparisons were made between respective source and transplant populations 34 years later (1993) using morphometrics ('truss' method), allozymes (29 enzyme-coding loci) and mitochondrial (mt) DNA variation (RFLP analysis of PCR-amplified ND5/6 genes). Significant morphological and genetic differentiation between source and transplant samples was detected, with a distinct clustering of Kivu Limnothrissa on respective dendrograms, especially at the morphometric and mtDNA levels. Differentiation within Lake Tanganyika was, however, consistently higher than that between lakes. Allozymic diversity was similar in samples from both lakes (Lake Tanganyika: heterozygosity = 0.0658, mean number of alleles=1.44; Lake Kivu: heterozygosity = 0.0655; mean number of alleles = 1.48), however, a significantly lower mtDNA haplotype diversity was detected in Lake Kivu (Lake Tanganyika: 0.905; Lake Kivu: 0.755). Data suggest that high post-introduction mortality and various demographic factors reduced the effective population size of the introduced population to tens rather than thousands of individuals, resulting in a reduction in genetic diversity and founder effect.     

Genetic characterization and management of the endangered Mohave tui chub

The Mohave tui chub (Siphateles bicolor mohavensis) is the only fish native to the Mojave River, California. The fish were displaced by introduced arroyo chubs (Gila orcutti) throughout most of their range, starting in the 1930s. Two potentially relictual populations and two transplanted populations were genetically characterized using 12 microsatellite DNA loci, along with contemporary cyprinid populations in the Mojave River. We found only un-hybridized Mohave tui chubs in the refuge populations, and only un-hybridized arroyo chubs in the Mojave River. The two largest Mohave tui chub populations (Lake Tuendae and China Lake) exhibit similar, comparatively high genetic variation. Another large population (Camp Cady) with low genetic diversity shows the effect of a bottleneck of ten individuals during the historic founding event. The fourth population (MC Spring) has the fewest alleles, lowest heterozygosity, and is the most divergent, suggesting that genetic drift from a persistently low effective population size has reduced genetic diversity since its apparent isolation in 1934. We recommend instituting artificial gene flow to rebuild genetic variation in Camp Cady from both Lake Tuendae and China Lake, and the establishment of new populations with founders from both Lake Tuendae and China Lake. Additionally, we comment on the infeasibility of restoring populations of Mohave tui chub in their historic habitats.     

Conservation of the Lake Kasumigaura population of Nymphoides indica (L.) Kuntze based on genetic evaluation using microsatellite markers

We compared the genetic diversity of the Lake Kasumigaura population of Nymphoides indica with that of pond populations in Hyogo and Kagawa Prefectures, which are thought to maintain high genetic diversity, to elucidate the current genetic diversity and occurrence of distinctive alleles in the Lake Kasumigaura population. The genetic diversity, as measured by the mean number of alleles per polymorphic locus, effective number of alleles per locus, mean observed heterozygosity, mean expected heterozygosities, total gene diversity, and number of multilocus genotypes was lower in the Lake Kasumigaura population than in the Hyogo and Kagawa populations. In addition, the inbreeding coefficient suggests that random mating does not occur in the Lake Kasumigaura population. The degree of genetic differentiation between the Lake Kasumigaura population and the Hyogo and Kagawa populations suggests that the Lake Kasumigaura population is largely genetically distinct. We found five genotypes in the Lake Kasumigaura population that were absent from the Hyogo and Kagawa populations. These results demonstrate that the Lake Kasumigaura population is an important component of the overall genetic diversity of N. indica in Japan.