大黄鱼连续4代选育群体遗传多样性与遗传结构的微卫星分析

利用13个多态性微卫星位点分析了大黄鱼官井洋优快01品系F1到F44个选育世代的遗传结构与遗传多样性变化情况。结果显示,随着选育的进行,4个世代群体遗传多样性指标值渐次下降,F1到F413个微卫星位点的平均多态信息含量从0.638下降到0.524,平均等位基因数从5.462下降到4.308,平均观测杂合度从0.779下降到0.532,平均Shannon多样性指数从1.356下降为1.092。F1与其后各代遗传相似系数逐渐减小(从0.7194到0.5813),遗传距离逐渐增加,而相邻世代间的遗传相似性逐步升高,遗传分化指数(FST)渐次变小(F1～F2为0.0619,F2～F3为0.0511,F3～F4则为0.0475)。随着选育的进行,微卫星位点LYC0002和LYC0054等位基因频率有规律地发生变化,推测其可能与选育性状存在遗传上的相关。结果表明,经过连续4代的选育,部分不利基因遭到淘汰,选育群体的遗传基础逐步得到纯化,基因型逐渐趋向纯合、稳定,经进一步的选育可望获得较稳定的品系。     

三疣梭子蟹选育家系微卫星分析

采用微卫星标记技术分析不同世代三疣梭子蟹选育家系的遗传结构。利用16个多态性微卫星位点分析了三疣梭子蟹家系F1到F4 4个选育家系的遗传结构与遗传多样性变化情况。结果显示,随着选育的进行,4个世代家系遗传多样性指标值逐渐下降,F1到F4 16个微卫星位点的平均多态信息含量从0.675 3下降到0.406 1,平均等位基因数从3.500 0下降到2.133 3,平均观测杂合度从0.643 5下降到0.4774,平均等位基因纯合率从0.566 9下降到0.402 4。对各个位点进行H-W检验,每个世代出现不同程度的平衡偏离。对各家系进行F-检验,结果表明,各家系存在不同程度的遗传分化,19.07%的遗传分化来自群体间,80.93%的遗传分化来自群体内。另外,对FIS值的计算显示,4个家系在整体上均表现为一定程度的杂合子缺失,其中F4有12个位点、F3有6个位点、F2有3个位点、F1有8个位点处于杂合子缺失状态。遗传距离逐渐增加,相邻世代间的遗传相似性逐步升高。经过连续4代的选育,选育群体的遗传基础逐步得到纯化,基因型逐渐趋向纯合、稳定,经进一步的选育可望获得较稳定的品系。     

三疣梭子蟹选育家系微卫星分析

采用微卫星标记技术分析不同世代三疣梭子蟹选育家系的遗传结构。利用16个多态性微卫星位点分析了三疣梭子蟹家系F1到F4 4个选育家系的遗传结构与遗传多样性变化情况。结果显示，随着选育的进行，4个世代家系遗传多样性指标值逐渐下降，F1到F4 16个微卫星位点的平均多态信息含量从0.6753 下降到0.4061，平均等位基因数从3.5下降到2.1333，平均观测杂合度从0.6435 下降到0.4774，平均等位基因纯合率从0.5669到0.4024。对各个位点进行H-W检验，每个世代出现不同程度的平衡偏离。对各家系进行F-检验，各家系存在不同程度的遗传分化，结果表明，19.07％ 的遗传分化来自群体间，80.93％的遗传分化来自群体内。另外，对Fis值的计算显示，4个家系在整体上均表现为一定程度的杂合子缺失，其中F4有12个位点、F3有6个位点、F2有3个位点、F1有8个位点处于杂合子缺失状态。遗传距离逐渐增加，相邻世代间的遗传相似性逐步升高。随着选育的进行，结果表明，经过连续4代的选育，选育群体的遗传基础逐步得到纯化，基因型逐渐趋向纯合、稳定，经进一步的选育可望获得较稳定的品系。     

14个尼罗罗非鱼家系遗传差异的微卫星标记分析

利用12个微卫星标记分析14个尼罗罗非鱼Oreochromis niloticus家系的遗传多样性,以P_0代为对照,研究P_4、P_5代家系的遗传多态性,指导尼罗罗非鱼的选育。研究结果表明:14个罗非鱼家系的平均有效等位基因数、平均杂合度、平均多态信息含量分别为3.1819、0.6276、0.5753,其遗传多样性丰富;家系N312与N314遗传距离最小(0.1214),而家系N304与N306遗传距离最大(0.3137),14个家系间的平均遗传距离为0.1973;UP_GMA进化树分析结果表明,14个尼罗罗非鱼家系聚为4个分支,第一分支为家系N303,第二分支由N301、N306和N311组成,第三分支由N302、N308和N310组成,其余家系组成第四分支;P_4代尼罗罗非鱼群体遗传多态性比P_0代小幅降低,而构建P_5代家系时参考了微卫星标记的分析结果,其遗传多态性明显高于P_0和P_4代。结果表明:参考微卫星标记计算的家系间的亲缘关系,人为控制选配提高后代稀有等位基因的频率和杂合子的比例,可以有效防止近交衰退,维持较高的种群遗传多样性和选择潜力。     

中国海南三亚大珠母贝不同年代种群的遗传变异研究

利用10个多态微卫星标记对中国海南三亚海域大珠母贝（Pinctada maxima）3个不同年代（2007、2009和2010）群体的遗传变异进行了分析，每个群体30个样品。10个位点共扩增出60个等位基因，平均每个位点6（2—8）个，3个群体分别丢失了1、2和4个稀有等位基因。平均期望杂合度（Hc）、平均多态信息含量（PIC）、平均Shannon多样性指数均呈下降趋势。各群体均存在一定程度的杂合子缺失。30个数据中（3个种群×10个位点）有18个偏离了Hardy—Weinberg平衡。两两群体间的平均近交系数（FIS）介于0．2273～0．2601之间，平均遗传分化指数（FST）介于0．0204～0．0462，遗传分化显著（P〈0．01）。结果表明，3个年代群体遗传多样性水平已经出现了逐渐降低的趋势，遗传结构存在显著差异，近交程度增加，因此，人工繁育工作中应注意避免近亲繁殖和遗传多样性的降低。     

翘嘴鳜连续4代选育群体遗传多样性及遗传结构分析

利用微卫鳜星分子标记技术对翘嘴鳜(Siniperca chuatsi)选育群体世代F1至F4的遗传结构进行分析,并以长江中游野生翘嘴作为对照群体。结果显示:筛选出的7个微卫星位点在5个实验群体中共检测到了149个等位基因;随着选育的进行,4个世代群体遗传多样性参数逐代下降,平均等位基因数从5.14下降到2.57,平均观测杂合度从0.405下降到0.229,平均多态信息含量从0.702下降到0.424。野生群体与选育群体间的遗传距离逐代增加(从0.345 4到0.751 7),遗传相似度逐代减小(从0.707 9到0.471 6),遗传分化指数逐代增大(从0.093 8到0.239 7)。结果表明,经过连续4代选育,部分位点的基因型逐渐趋向纯合,在多数位点上4代群体仍表现出较高遗传多样性。     

微卫星分析鲤鱼杂交系F2代家系群体遗传多样性

利用10个微卫星分子标记,对8个鲤鱼杂交系家系进行遗传多样性分析,结果显示:10对微卫星引物在鲤鱼杂交系F2代8个家系共240个个体中均获得了稳定、清晰的扩增条带,并在个体间表现出不同程度的多态性。共检测到59个等位基因,位点等位基因数在3~9个,平均等位基因数5.9个,片段长度在129~371 bp,有效等位基因在1.533~5.821,平均为3.452 5;观测杂合度在0.421~0.882,平均为0.647,期望杂合度在0.506~0.826,平均0.628;多态性信息含量(PIC)在0.452~0.815,平均多态信息含量0.675,为高度多态性;个体间遗传距离0.3586~0.8302,相似性系数在0.5012~0.7906。8个家系中,20号家系与59号家系的遗传距离最小,为0.357 3;20号家系与35号家系遗传距离最大,为0.830 2。实验结果表明:该鲤鱼杂交系F2代群体遗传多样性水平较高,等位基因数量较多,杂合度较高,多态信息含量丰富,家系间没有受到近交的影响,具有较大的选育潜力。     

人工雌核发育鲢近交F_2微卫星DNA变异分析

采用17对鲢微卫星引物,以野生鲢、养殖鲢、雄鲤作对照对人工雌核发育鲢近交F2及其亲本进行了微卫星分析。结果表明:人工雌核发育鲢近交F2、养殖鲢和野生鲢群体的平均等位基因数范围为2.1～4.0;平均观测杂合度范围为0.2762～0.9588;期望杂合度范围为0.2774～0.7360;遗传多样性指数范围为0.4500～1.2258,人工雌核鲢近交F2为0.4500,显著低于养殖鲢(1.0273)和野生鲢(1.2258),揭示人工雌核发育鲢近交F2遗传多样性水平较低,纯合度较高。从遗传距离来看,人工雌核发育鲢近交F2与对照群体之间的遗传距离都要大于野生鲢与养殖鲢群体之间遗传距离,表明人工雌核发育鲢近交F2发生了一定程度的遗传分化。     

鳡遗传多样性的ISSR分析

利用ISSR分子标记技术对长江下游苏州段野生和野生F1代人工养殖的2个鳡群体遗传多样性进行分析研究.从77个ISSR引物中筛选出4个引物对鳡2个群体48个样品进行扩增,得到41个清晰的扩增位点.鳡野生和野生F1代人工养殖2个群体的多态位点比率和群体内遗传多样性指数分别为21.95%、17.07%,0.0724、0.0426;前者遗传多样性较后者略高.基因分化系数Gst和群体内遗传多样性指数估算分析均显示2个鳡群体之间出现一定遗传分化.鳡UPGMA系统树有较明显的歧化,表现出一定的遗传趋异.结果分析表明,鳡群体的遗传多样性相对贫乏;野生F1代人工养殖群体尚未形成自己独立的遗传结构,但2个群体间已经产生了一定的遗传分化,经过较多世代的人工繁育有可能形成自己独立而稳定的遗传结构.     

剑尾鱼RW-H近交系的遗传结构分析

筛选31条随机引物对剑尾鱼的第8代近交RW-H系A、B、C3窝共11尾剑尾鱼个体基因组DNA进行RAPD扩增，计算近交系个体间及不同窝间的相似系数及遗传距离。结果筛选的31条引物共扩增出383条带，扩增片段的大小在0．2～3kb。其中多态性带30条，多态性带频率在0～58．33％，平均为7．83％。近交系剑尾鱼不同个体拥有相同条带的比率较高。计算得到近交系的平均相似系数(S)为0．9829(0．9716～0．9960)，平均等位基因频率(q)为0．8692，最低平均杂合率(H)为0．1308。同时，用5个微卫星标记对非选育剑尾鱼和近交系RW-H系的基因组进行分析，检测等位基因的个数和大小，结果5个微卫星座位在非选育剑尾鱼中显示为多态，而在近交系RW-H系除1个位点出现等位基因外，其余均为纯合子，计算得到近交系的平均遗传相似系数为0．9345，两种方法均证明近交RW-H系第8代剑尾鱼有较高的遗传纯合度。     

凡纳滨对虾引进群体和2个养殖群体遗传变异的微卫星分析

利用8个微卫星标记对引进的SPF凡纳滨对虾G0和两个养殖群体(G1,G2)进行遗传多样性分析。8个座位共获得64个等位基因,位点的等位基因数在5~l3之间。多态信息含量PIC在0.405 2~0.869 3之间,其中有6个位点为高度多态位点,适合于多态性分析。8个座位丢失的和新产生的等位基因共30个,占总数的47%。3个群体的平均观测杂合度分别为0.193 8、0.196 1、0.232 5,说明3个群体的遗传多样性较低。对近交系数Fis分析显示3个群体中存在近交,通过对哈迪温伯格平衡检验,显示所有座位均显著偏离平衡,存在杂合子缺失。通过配对Fst和Ne i遗传距离分析,显示3个群体之间有明显的遗传分化,说明种群结构发生了明显的遗传变异,变异可能来自于突变、随机漂变和选择的共同作用。实验结果能够很好地解释经过若干群体选育后,子代群体发生种质退化的现状,由此建议综合采用遗传育种的方法从引进的亲虾中筛选出性状优良稳定的仔虾作为虾苗。     

用微卫星DNA技术对中国对虾人工选育群体遗传多样性的研究

利用微卫星技术对中国对虾人工选育群体第1代和第6代群体的遗传多样性进行了分析。对10个微卫星位点进行了扩增,共产生74个等位基因,每个位点产生的等位基因数从3到13不等。在两个群体中,所观察到的等位基因数都比有效等位基因数多。多态信息含量PIC值0．5567～0．8877,说明这10个微卫星位点在中国对虾中具有较高的信息含量。两个群体的平均杂合度分别为0．6400(CP1)、0．6300(CP6),并通过计算基因型的P值,确定了对Hardy-Weinberg平衡的偏离情况。对Fis值的计算表明两个群体内共有5个微卫星位点存在杂合度观察值过剩的现象。两个群体的Shannon多样性指数分别为1．6830、1．7382,整个选育群体(两个群体作为一个群体)的遗传多样性指数为1．7742。从遗传多样性所占的比例来看,96．415％的遗传变异是来自群体内,只有3．585％的遗传变异是来自群体间。两个群体间的相似性系数高达0．9187,彼此间的遗传距离仅为0．0848,体现出人工选育群体的遗传分化程度较低。结果均说明第6代群体还有较大的选育潜力,可以继续保持遗传效应,最终保证选种育种工作的成功。     

Can genetic diversity be maintained during mass selection of the Chinese mitten crab,Eriocheir sinensis?

The Chinese mitten crab (Eriocheir sinensis) is an important aquaculture species and food source in Eastern Asia. This study assesses the changes in genetic diversity in successive generations of early‐ and late‐maturing strains of E. sinensis using 30 microsatellite markers with high polymorphism. The mean average number of alleles (N) in the founder population (G0), first generation (G1), second generation (G2) and third generation (G3) of the early‐maturing strain were 18.367, 14.800, 16.400 and 16.533, respectively; while in late‐maturing strain the values were 18.500, 16.267, 14.367 and 16.533 respectively. Likewise, there was a slight decline in average allelic richness (R_s) in the three successive generations. In both strains, the mean observed heterozygosity (H_o) remained relatively constant for the early‐maturing strain and the values were 0.655, 0.667, 0.685 and 0.705, respectively; and for the late‐maturing strain these were 0.665, 0.672, 0.688 and 0.702 respectively. Similarly, the expected heterozygosity (H_e) remained constant, ranging from 0.823 to 0.854. There was a decrease in effective population sizes (N_e) of the early‐maturing strain with successive generations: values were 492.2, 35.0, 134.7 and 193.2, respectively; while the values in the late‐maturing strain were 1268.5, 75.6, 111.5 and 97.2 respectively. All pairwise population distances were very close in both strains. In conclusion, these results suggest that mass selection of E. sinensis did not significantly diminish genetic diversity although there was a decline for the N_e. Therefore, it is important to maintain sufficient broodstock numbers and a large effective population when following a selective breeding programme.     

Genetic variability of cultured populations of the Pacific abalone (Haliotis discus hannai Ino) in China based on microsatellites

The genetic diversity of cultured populations of the Pacific abalone (Haliotis discus hannai Ino) from northern China was analysed using seven microsatellite markers. The microsatellite loci were polymorphic for all the populations, with an average of 8.7 alleles per locus (range 8.0–9.4). The mean observed and expected heterozygosities were 0.547 (range 0.500–0.596) and 0.774 (range 0.754–0.787) respectively. The allelic diversity in terms of number of alleles per locus was considerably lower than that previously found in wild populations (range 21.8–23.0), indicating that bottleneck effects occurred when each population was founded. Significant genetic differentiation among the five cultured populations was shown using F_st and R_st values, and pairwise comparison based on allelic distribution. A neighbour‐joining analysis of the genetic distance did not show a consistent relationship between the geographic and the genetic distances, suggesting the existence of exchanges of breeds and eggs between the hatcheries. The results obtained in this study are useful for a number of areas of interest for fisheries management and the aquaculture industry, especially with regard to breeding programmes.     

Genetic relationship between broodstocks of olive flounder, Paralichthys olivaceus (Temminck and Schlegel) using microsatellite markers

For the first generation of a selective breeding programme, it is important to minimize the possibility of inbreeding. This mostly occurs by mating between closely related individuals, while proper mating can provide an opportunity to establish the base families with wide genetic variation from which selection for subsequent generations can be more effective. Genotyping with microsatellite‐based DNA markers can help us determine the genetic distances between the base populations. The genetic markers further facilitate the identification of the correct parents of the offspring (parentage assignments) reared together with many other families after hatching. We established a genetic analysis system with microsatellite DNA markers and analysed the genetic distances of three farmed stocks and a group of fish collected from wild populations using eight microsatellite markers. The averaged heterozygosity of the farming stocks was 0.826 and that of the wild population was 0.868. The hatchery strains had an average of 8.6 alleles per marker, which was less than a wild population that carried an average of 14.3 alleles per marker. Significant Hardy–Weinberg disequilibrium (HWDE) was observed in two farming stocks (P<0.05). Despite relatively low inbreeding coefficiency of the hatchery populations, the frequency of a few alleles was highly represented over others. It suggests that the hatchery stocks to some extent have experienced inbreeding or they originated from closely related individuals. We will develop a selective program using the DNA markers and will widen the usage of the DNA‐based genetic analysis system to other fish species.     

微卫星用于凡纳滨对虾育种过程中亲权分析及遗传多样性的变化监测

利用7个微卫星标记分析了6个凡纳滨对虾家系的亲本（G₀）及其后代（G₁）的基因型分离情况，同时对G₀和G₁的所有座位期望杂合度进行配对比较分析，并且通过对G₁群体每个位点的F-statistics分析检验群体的遗传分化，以期对凡纳滨对虾育种进行遗传监测。结果表明：共检测到44个等位基因。G₀和G₁的平均每个座位的等位基因数目分别为6.14和6.27，平均期望杂合度为0.786和0.733，平均多态性信息含量为0.709和0.695。7个微卫星座位的累计排除概率为0.99，并且在有亲本存在的情况下，能够将6个家系分开。G₀与G₁的所有座位期望杂合度的配对比较分析结果表明G₀平均期望杂合度要显著高于G₁(P<0.01)。G₁各座位的遗传分化指数F_ST在0.270 3～0.465 4，平均分化系数为0.358 4。说明亚群间属于高度遗传分化。最后，根据6个家系的遗传距离，利用UPGMA法对G₁个体聚类分析，结果表明亲缘关系较近的家系A和B以及C和D的相似系数很高分别各聚为一类，E和F分别聚为一类。     

Genetic parameters of survival for six generations in the giant freshwater prawn Macrobrachium rosenbergii

Genetic parameters were estimated for survival of Macrobrachium rosenbergii using a fully pedigreed synthetic population formed by three introduced strains. The data included 107 398 progeny from 394 sires and 654 dams in six generations with a nested mating structure. The variance components and genetic parameters were estimated using a generalized linear mixed model with the probit link function. Available heritabilities in survival from the generation G₃ to G₅ ranged from 0.007 ± 0.020 to 0.066 ± 0.044 (P > 0.05) using a model that included the common environmental effect (c). Across generations, low heritability (0.016 ± 0.012, P > 0.05) was estimated using the model with inclusion of the c effect. There were statistically significant differences in the heritability estimates between different ponds for most generations. Moreover, the genetic correlation of survival between ponds over six generations varied from low to high (?0.0007 ± 0.17 to 0.80 ± 0.069) and was significantly different from unity. There were low correlation coefficients (?0.039 ± 0.096 to 0.342 ± 0.081) between body weight estimated breeding value (EBV) and survival EBV of families in different generations. The low heritabilities for survival are most likely caused by low genetic variation in the founder populations and reduced genetic variation because of consecutive selection.     

斑节对虾7个全同胞家系间亲缘关系的微卫星分析

为了斑节对虾（Penaeus monodon）后续育种工作的需要,研究了斑节对虾7个全同胞家系的亲缘关系。从95对微卫星引物中筛选出16对,16个微卫星位点共发现79个等位基因（A）。每个位点的A为2～10个,平均4.9375,有效等位基因（Ne）1.7575～5.3980,平均3.3878,平均杂合度观测值（Ho）0.6679,平均杂合度期望值（He）0.6698。平均多态信息含量（PIC）0.6110。7个家系总近交系数（FIT）0.0099,家系内近交系数（FIS）-0.3725,家系间基因分化系数（FST）0.2709。根据遗传距离采用UPGMA法对7个家系进行聚类,F2和F6家系之间的遗传距离最小聚为一类,与F7家系遗传距离最远。结果表明,家系间基因交流较低,遗传分化程度较高,且很少发生近交,F7家系可以优先考虑与其他家系进行杂交选育。     

白梭吻鲈3个群体的遗传结构比较

为了加强良种选育工作,切实做好亲本遗传管理,防止近交衰退的发生,利用20个微卫星分子标记对白梭吻鲈(Sander lucioperca)新疆野生群体及山东和苏州2个养殖群体的遗传结构进行检测。结果表明,20个微卫星标记中18个有扩增产物,14个呈现多态性;每个位点的等位基因数为2~6个,平均等位基因数为3.6个,3个群体的平均等位基因数为2.57~3.36,平均观测杂合度为0.5085~0.5621,平均多态性信息含量为0.3931~0.4764,表明3个白梭吻鲈群体的遗传多样性处于中等偏低水平,遗传多样性大小为:新疆群体苏州群体山东群体。群体的Fst为0.1798,表明群体间有一定的遗传分化。在白梭吻鲈人工繁殖与养殖过程中,必须加强亲本遗传结构监测并维持一定数量的亲本规模,以利于其产业的持续发展。