哲罗鱼微卫星亲子鉴定的应用

该文通过7对微卫星标记,对哲罗鱼的微卫星亲子鉴定准确率、亲子鉴定能力与候选亲本群体大小的关系及应用作了研究.通过计算机软件分析,亲子鉴定能力随候选亲本群体的增大而减小.在81个可能的父母对条件下,单独养殖家系鉴定准确率为80%,混合养殖家系有78.9%的后裔可以鉴定其父母;而在9个可能的父母对条件下,单独养殖家系鉴定准确率为93.3%,混合养殖家系鉴定率为92.2%.该研究表明微卫星分子标记可以用于哲罗鱼的家系鉴定.     

微卫星标记在不同壳色虾夷扇贝家系亲权鉴定的适用性

实验选取8 个多态性微卫星位点, 用于虾夷扇贝4 个不同壳色全同胞和半同胞家系160 个子代的亲权鉴定。在亲本未知和一亲本已知的情况下, 8 个微卫星位点累积排除概率分别为0.823 和0.961。鉴于亲权分析时子代的亲本在已知和未知情况下位点的累积排除概率不同, 实验采用了两种方法用于家系的亲权鉴定。方法1: 当子代的父母本情况未知时, 根据子代基因型数据, 通过CERVUS 2.0 软件计算子代所对应的候选亲本的LOD 值, 直接将候选亲本中具有最大的两个LOD 值的亲本确定为子代的父母本; 方法2: 在子代的亲本未知情况下, 视具有最大LOD 值的候选亲本为子代的第一候选亲本, 然后将该亲本视为已知, 通过CERVUS 2.0 软件重新计算每个侯选亲本的LOD 值, 再从中选择具有最大LOD 值的候选亲本作为该子代的第二候选亲本。结果表明, 采用方法2 得到的家系亲权鉴定成功率达到95%以上, 确定了微卫星标记在虾夷扇贝家系鉴定中的可行性。所检测的微卫星位点在子代中出现无效等位基因现象, 而无效等位基因存在会引起子代与亲本的错配。实验在家系鉴定时采用了无效等位基因存在(情况1)和缺失(情况2)两种子代基因型文件进行分析, 不同情况下同一方法家系鉴定成功率相差无几。这表明了基于多个微卫星位点计算候选亲本LOD 值大小寻找子代真实父母本可以降低由无效等位基因引起的错配的几率。研究表明了微卫星标记适合于不同壳色虾夷扇贝家系亲权鉴定工作。       

基于微卫星标记的斑点叉尾鮰家系鉴定技术及应用

研究旨在建立准确、高效且经济的斑点叉尾鮰(Ictalures punctatus)家系亲缘鉴定体系, 以期为斑点叉尾鮰的遗传评估及家系育种提供科学依据。选用10对具有较高多态性SSR标记, 建立两个5重PCR反应体系。应用建立的斑点叉尾鮰家系亲缘鉴定体系对来源于13个全同胞家系和8个半同胞家系的333尾个体进行亲权鉴定。结果表明: 10个位点平均等位基因数为9.8、平均观测杂合度0.8591、平均期望杂合度0.8092、平均多态信息含量0.7845; 3种情况下的累积排除概率分别为: 0.99996806、0.99833267和0.99999998; 验证群体的鉴定结果与系谱高度一致, 真实鉴定率达到99.1%, 子代与父母本三者之间配对平均LOD值介于13.30—24.70, 且置信度均达到95%。研究选择的微卫星位点等位基因数目较多, 多态性较高, 可以快速、准确地对斑点叉尾鮰混养群体进行家系鉴定。     

微卫星标记应用于凡那滨对虾家系鉴别的研究

以人工选育建立的凡那滨对虾（Litopenaeus vannamei）全同胞家系为实验材料,探讨了微卫星标记对混养家系进行亲权鉴定的可能性。Cervus模拟分析表明从10个微卫星基因座组合中选取的多态性信息含量最高的6个进行组合与原组合的累积排除概率均在0.99,多态性信息含量最高的6个基因座的组合判定正确率为0.97,置信度为95%。在家系混养的模拟实验中使用这6个高多态性的微卫星基因座从20个候选雌虾中找到真正母亲的概率为88%,从30个候选雄虾中找到真正父亲的概率为78%,低于理论预测值,分析可能与微卫星基因座中的无效等位基因,等位基因的突变以及PCR过程中Taq酶发生链滑移等因素有关。      

建鲤(Cyprinus carpio var. Jian)微卫星DNA亲权鉴定

利用16个微卫星座位对建鲤10个全同胞家系647个子代进行亲权鉴定。Cervus3.0分析表明,16个微卫星位点的平均多态信息含量为0.7025,平均等位基因数为6.63,期望杂合度平均为0.7405。当双亲未知时,累积排除概率为0.999225,已知单亲时的累积排除概率为0.999996,置信度为95%。进一步模拟分析表明,要达到亲权鉴定的要求在双亲未知时通常需要8～12个微卫星位点,已知单亲时需要5～8个微卫星位点。在双亲均未知的情况下进行亲权鉴定,94.6%的后裔找到了其父母本,真实鉴定率低于模拟分析预测值,分析可能是与候选亲本间存在亲缘关系、无效等位基因的存在以及分型错误等因素有关。9个建鲤全同胞家系的鉴定,为今后的遗传图谱构建、QTL定位及分子标记辅助育种研究奠定了基础。     

太平洋牡蛎养殖与野生群体遗传变异的微卫星研究

应用微卫星标记技术研究5个中国太平洋牡蛎养殖群体和2个日本太平洋牡蛎野生群体的遗传变异。研究中所使用的7个微卫星位点在养殖和野生群体中都显示出了高多态性,平均等位基因数为19.1～29.9,平均期待杂合度为0.916～0.958。养殖群体和野生群体的平均等位基因丰度及观察杂合度没有显著性差异。遗传分化系数及等位基因杂合度分析显示所有的群体间都有显著性差异。构建的NJ树中,7个群体聚为3支,养殖群体和野生群体可以清楚地分开,在养殖群体中又分为南北两支。分配检验中,97%～100%的正确率证明了微卫星标记在群体识别分析中的可行性。本研究结果对太平洋牡蛎管理模式的设计和选择育种具有重要意义。     

应用微卫星标记分析野生中国明对虾的亲权关系

利用5个高度多态性的微卫星座位(Fc04、Fc06、Fc18、Fc24、Fc27),分析了不同年份中建立的10个野生中国明对虾家系中的雌性亲虾及其后代基因型分离的情况,表明每个家系中只有一个雄性野生中国明对虾对子代的遗传有贡献.从其中3个家系的雌性亲虾纳精囊中提取了雄虾精子DNA,微卫星标记显示各家系的子代个体均有一个等位基因与雄性亲虾的基因型相符,且符合孟德尔遗传规律,这为野生中国明对虾雌虾在繁殖季节一对一的繁殖行为提供了遗传学的证据.用UPMGA的方法随机对3个家系的40尾子代个体进行聚类分析,每个家系都能被单独聚成一类.上述工作表明微卫星标记在对虾育种中作为一种有效的亲子关系分析工具,在种群的遗传结构、亲缘关系、繁殖行为等方面具有广阔的应用前景.     

鳙基于10个微卫星标记的亲子鉴定分析

为开展鳙(Hypophthalmichthys nobilis)家系选育工作,本研究进行了基于微卫星标记的亲子鉴定研究。试验中筛选了10个扩增效率较高的微卫星标记,通过引物荧光修饰,引物结合毛细管电泳分型技术,对鳙48尾亲本及384尾子代进行了基因分型,并计算了等位基因频率和模拟分析和亲子鉴定等分析。结果发现,各位点的等位基因数介于4~13之间,其中9个位点均具有较高的多态性和杂合度(PIC>0.5,He>0.5),研究发现位点的多态性信息含量(PIC)与亲本对排除率(E-PP)存在显著正相关(p<0.01)。模拟分析结果显示,该10个标记预计可用于已知性别的50组亲本(100尾)或未知性别的50尾亲本的鉴定分析(鉴别成功率>95%)。亲子鉴定发现,对试验中2个交配组(每组12对亲本)的鉴别成功率分别为98.96%和100%;且父母本对子代的贡献率存在极显著差异(p<0.01)。通过累积位点的鉴定分析发现,当标记数为7个和9个时分别能满足试验中12组和24组亲本对应子代的鉴定分析(鉴别率>95%),模拟分析和亲子鉴定分析成功率趋势基本符合。本研究所开发的亲子鉴定技术可为鳙家系选育提供技术支持。     

微卫星分型法应用于豢养繁殖长江江豚的父权鉴定

目的:鉴定武汉白鱀豚馆及安徽铜陵淡水豚保护区两个豢养长江江豚繁殖群体中出生的6头幼豚的生物学父亲.方法:选择8对江豚物种特异性微卫星引物对两个待鉴定群体的14个DNA样品进行了荧光标记PCR扩增,将纯化后的扩增产物在ABI3130遗传分析仪上进行基因分型,并根据GeneScan Rox 500内标确定不同等位基因的大小,随后对待鉴定对象进行等位基因分析,并计算主要多态性参数.结果:所采用的8个微卫星座位在待鉴定的两个江豚群体中均表现出不同程度的多态性.在母本已知的条件下,利用其中6个微卫星座位的等位基因数据,通过排除法成功地鉴定出两个繁殖群体中出生的6头幼豚的生物学父亲.结论:本研究首次成功地将6个物种特异性微卫星标记应用于豢养长江江豚的父权鉴定,从而为该物种微卫星亲子鉴定技术体系的建立及迁地保护繁殖群体遗传谱系的构建奠定了技术基础.     

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。     

凡纳滨对虾繁殖中不同亲本对子代遗传贡献率的差异

利用5个含有稀有等位基因的高度多态性微卫星位点比较了凡纳滨对虾繁殖中不同亲本对子代遗传贡献率的差异。通过稀有等位基因的5个微卫星位点能够对亲代和子代的谱系进行明确的鉴别。10个亲代个体中有8个个体对子代群体的基因库有贡献,不同个体之间的贡献率存在差别,最高为54.28%,最低为8.57%。在亲代和子代群体遗传结构的分析中,子代等位基因的数目与亲代相比降低了11.11%。子代的平均期望杂合度(He)、平均观测杂合度(Ho)和平均多态性信息含量(PIC)等指标均低于亲代。实验结果表明:亲本对子代基因库的贡献率的差异也是造成子代群体遗传变异水平降低的原因之一;微卫星标记可作为一种有效的工具用于对虾系谱的确认、人工繁育群体遗传多样性水平的监测等方面     

Parentage determination of mandarin fish (Siniperca chuatsi) based on microsatellite DNA markers

In this study, ten microsatellite loci were chosen to estimate the parentage of 260 progeny in five mandarin fish (Siniperca chuatsi) full-sib families. Simulation based on allele frequency date demonstrated the combined exclusion power would be over 97% if the number of loci was up to nine. Based on the information from these nine loci, 98% of progeny were unambiguously allocated to their putative parental pairs in the parentage analysis. The assignment success rate by the real data set was lower than that predicted by the simulations, with 94% of progeny assigned correctly. The discrepancies might be caused by a scoring error or allelic dropout caused by poor quality genomic DNA. Moreover, 69 progeny were selected randomly for the double-blind test, the result indicated that 95% of the progeny can be correctly assigned to their families. This study provided a microsatellite-based approach for parentage assignment in S. chuatsi, and that will be useful for investigation of genetic background and molecular marker-assisted selective breeding in this species.     

Can microsatellite markers replace PIT tags in rohu (Labeo rohita Hamilton, 1822) selective breeding programmes?

This study was undertaken to assess the feasibility of microsatellite markers for resolving parentage in Labeo rohita (rohu) selective breeding programmes in lieu of conventional PIT tag marking. Ten microsatellite markers were used to assign offspring parentage. A total of 160 individuals were tested from eight full‐sibling families. Eight highly polymorphic loci with allele numbers ranging from 2 to 8 and polymorphism information content (PIC) values in the 0.47–0.82 range were utilized. With the use of a real data set from a breeding programme, all but 12 individuals out of 160 could be assigned exclusively to their correct parental pairs. The matching rate was 92.5%, which was lower than in a simulated study (98.44%, Excl‐2). Discrepancies between simulations and real data sets may be due to several factors such as genetic relatedness among candidate parents (half‐sib and full‐sib), presence of null alleles, and sampling variance of the parents. The results of this study suggest that a marker panel probably with a wider genome coverage may be necessary for near‐100% accuracy in assigning parentage in rohu selective breeding programmes.     

Parentage testing of racing camels (Camelus dromedarius) using microsatellite DNA typing

The camel racing industry would have added value in being able to assign parentage with high certainty. This study was aimed at assessing and applying microsatellite multiplexes to construct a parentage testing system for camels. An efficient system of 17 loci from 700 camel samples was used to construct a database of unrelated adults. Based on this, we estimated measures of polymorphism among the markers. In three multiplex reactions, we detected a total of 224 alleles, with 5–23 alleles/locus (mean = 13.18 ± 6.95 SD) and an average heterozygosity (H_E) of 0.54 (range 0.032–0.905). The total parentage exclusion probability was 0.99999 for excluding a candidate parent from parentage of an arbitrary offspring, given only the genotype of the offspring, and 0.9999 for excluding a candidate parent from parentage of an arbitrary offspring, given the genotype of the offspring and the other parent. We used 15 juveniles for parentage testing, as well as 17 sires (bull camels) and 21 dams (cows). In the case of parentage assignment, the microsatellite panel assigned all 15 offspring parentage with high confidence. Overall, these findings offer a set of microsatellite markers that are easy, simple and highly informative for parentage testing in camels.     

Establishment and application of a microsatellite-based parentage identification method for Oreochromis niloticus,O. aureus,and O. niloticus × O. aureus

In genetic fish breeding research, clear pedigree information is of great significance for breeding and parental management. In order to establish a stable, highly accurate, and widely applicable parentage identification method for tilapia, 13 highly polymorphic microsatellite loci within populations of Oreochromis niloticus, O. aureus, O. niloticus × O. aureus, and their mixed population were screened. Four groups of fluorescent-labeled multiple capillary electrophoresis were established for allelic genotyping. The assignment success rate reached 100% when 7, 9, 8 and 12 loci were used in the population of O. niloticus, O. aureus, O. niloticus × O. aureus, and their mixed population, respectively. All 175 progeny individuals of “Yuemin No. 1” tilapia were exclusively assigned to their parental pairs when the 12 loci for the mixed population were used. This study established a fluorescent-labeled microsatellite-based parentage assignment method for O. niloticus, O. aureus, O. niloticus × O. aureus, and their mixed population with high identification accuracy and efficiency, which lays a foundation for pedigree information and population genetic management in tilapia breeding.     

Analysis of microsatellites and parentage testing in saltwater crocodiles

Fifteen microsatellite loci were evaluated in farmed saltwater crocodiles for use in parentage testing. One marker (C391) could not be amplied. For the remaining 14, the number of alleles per locus ranged from two to 16, and the observed heterozygosities ranged from 0.219 to 0.875. The cumulative exclusion probability for all 14 loci was .9988. the 11 loci that showed the greatest level of polymorphism were used for parentage testing, with an exclusion probability of .9980. With these 11 markers on 107 juveniles from 16 known breeding pairs, a 5.6% pedigree error rate was detected. This level of pedigree error, if consistent, could have an impact on the accuracy of gentic parameter and breeding value estimation. The usefulness of these markers was also evaluated for assigning parentage in situations where maternity, paternity, or both may not be known. In these situations, a 2% error in parentage assignment was predicted. It is therefore recommended that more micro-satellite markers be used in these situations. The use of these microsatellite markers will broaden the scope of a breeding program, allowing progeny to be tested from adults maintained in large breeding lagoons for selection as future breeding animals.     

Power of exclusion of 19 microsatellite markers for parentage testing in river buffalo (Bubalus bubalis)

In the present study, 19 microsatellite markers were assessed for their power of exclusion to test parentage in river buffalo. Microsatellite genotypes of 216 unrelated buffaloes belonging to five different breeds were utilized for the study. The probabilities of exclusion were calculated for three hypothetical situations viz. paternity testing (PE1), one parental genotype unavailable (PE2) and exclusion of both parents i.e. substituted offspring (PE3). The mean probability of exclusion across 19 investigated markers in buffalo was 0.578 (PE1), 0.405 (PE2) and 0.764 (PE3) respectively. The probability of exclusion for paternity (PE1) ranged between 0.297 and 0.814 across different markers. The exclusion probability for the cases one parent unavailable (PE2) and substituted offspring (PE3) varied from 0.143 to 0.688 and 0.465 to 0.946 respectively. Polymorphism information content and expected heterozygosity were found to have significantly high correlation with probability of exclusion of microsatellite markers. The cumulative PE1 of nine marker loci was estimated to be 0.9999 while in case of absence of one of the parental genotypes, a minimum of 11 markers were required to achieve a cumulative PE2 of 0.999. In conclusion, the present study proposes two multiplex sets with four and five markers respectively for routine parentage testing in buffalo and an additional set of four markers for doubtful cases of paternity.