三疣梭子蟹遗传连锁图谱的初步构建

利用AFLP和SSR标记技术结合"拟测交"策略,以三疣梭子蟹莱州湾、舟山野生群体杂交(1♂×3♀)产生的F2代家系为作图群体,初步构建了三疣梭子蟹雌、雄性遗传连锁图谱。用经过筛选的60对AFLP引物和3对SSR引物对亲本及108个F2代个体进行遗传分析,共得到母本分离标记214个,其中155个标记(AFLP标记153个,SSR标记2个)符合1∶1孟德尔分离规律;父本分离标记195个,139个标记(AFLP标记138个,SSR标记1个)符合1∶1孟德尔分离规律。雌性图谱包括100个遗传标记,分布在9个连锁群,6个三联体,15个连锁对,图谱总长度为1544cM,标记平均间隔22.0cM,总覆盖率为52.9%。雄性图谱包括71个遗传标记,分布在6个连锁群,6个三联体,11个连锁对,图谱总长度1174.2cM,标记平均间隔24.0cM,总覆盖率为49.5%,图谱中遗传标记分布比较均匀。     

合浦珠母贝印度家系F↓（1）代的AFLP分析

用AFLP标记对合浦珠母贝(Pinctada fucata)印度家系的亲本及其子一代(F1)进行了遗传分析。27对引物共扩增出1 013个位点,其中835个位点在F1代分离,178个位点不分离,多态位点比例82.4%。分离位点中,符合孟德尔分离规律的位点458个,占分离位点数的54.9%。偏孟德尔分离规律的位点377个,占分离位点数的45.1%。分离比为3∶1的位点共有482个,占分离位点数的57.7%,符合孟德尔分离规律的位点251个,占52.1%(占分离位点数的30.1%);分离比为1∶1的位点共有353个,占分离位点数的42.3%,符合孟德尔规律的位点207个,占58.6%(占分离位点数的24.8%)。半数以上的标记符合孟德尔遗传规律。表明AFLP标记适合于合浦珠母贝的遗传图谱构建。[中国水产科学,2007,14(1):52-58]     

文蛤养殖群体和野生群体遗传多样性的AFLP 分析

应用AFLP标记技术对辽宁和山东沿海文蛤（Meretrix meretrix）养殖群体和野生群体的遗传多样性进行分析。采用7对AFLP引物组合对5个群体（3个野生群体，2个养殖群体）150个个体进行扩增，共得到364个的位点。5个群体内的多态位点比例为84．3945％～87．6465％，总多态位点比例为99．6300％。群体的Nei’s基因多样性指数（H）为0．2301～0．2634；群体的Shannon多样性指数为0．3617～0．4248，群体间的遗传距离为0．0394～0．1609，群体内个体间的遗传距离为0．2592～0．5360。辽宁大洼野生群体和山东河口野生群体的多态位点比例、Shannon多样性指数和群体内遗传距离均高于辽宁盘山和辽宁庄河养殖群体，辽宁庄河野生群体的遗传多样性处于中等水平。用UPGMA方法构建的群体系统进化树显示，辽宁庄河野生群体单独成为一支，辽宁大洼野生群体与庄河养殖群体聚到一起，辽宁盘山养殖群体与山东野生群体聚到一起，但是用这5个群体的150个个体进行的聚类结果显示，所有个体基本是随机交叉聚类，不能形成明显的类群分支。分子变异分析（AMOVA）表明，文蛤群体94．04%的变异来源于群体内，群体间的变异仅占5．96％。以上结果表明，文蛤群体内遗传多样性非常丰富，群体间相似性较大，且存在较强的基因交流。[中国水产科学，2008，15（2）：215-221]     

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。     

基于线粒体D-loop基因的中国海三疣梭子蟹遗传多样性与遗传分化研究

为探明分布于中国四大海区的天然三疣梭子蟹群体遗传多样性与遗传分化状况,实验以大连(DL)、东营(DY)、连云港(LYG)、舟山(ZS)、湛江(ZJ)和漳州(ZZ)6个三疣梭子蟹地理群体为研究对象,采用线粒体控制区D-loop全基因序列为分子标记,对中国海三疣梭子蟹野生群体的遗传多样性及群体遗传结构进行了分析。结果发现,在用于分析的1 141 bp的D-loop全基因序列中共有185个变异位点,129个简约信息位点。60个个体中共计48个单倍型,单倍性多样性指数和核苷酸多样性指数显示中国沿海三疣梭子蟹群体具有较高的遗传多样性,而且三疣梭子蟹在过去没有出现很强的选择效应,群体大小稳定。6群体三疣梭子蟹遗传分化指数(F_ST)为0.189 7,将中国沿海三疣梭子蟹作为一个大群体来讲已产生了中度分化,群体分化时间推断为(19.68～26.05)万年。LYG分别和DY、ZJ、ZZ,以及ZJ和ZZ这4组之间无明显分化,基因流较大(N_em>5),而其他11个群组间已存在一定程度的分化。特别是ZS与其它5群体产生了高度的遗传分化,DL与其他4群体发生了中度分化。遗传距离与地理距离不存在显著的相关性,群体发生与扩散可能有更复杂的原因。     

合浦珠母贝3个家系的AFLP标记分离与遗传多样性研究

对AFLP标记在合浦珠母贝(Pinctada fucata)印度家系(印度贝♀×印度贝♂,PII)、杂交家系(三亚贝♀×印度贝♂,PSI)和三亚家系(三亚贝♀×三亚贝♂,PSS)的遗传分离及3个家系的遗传多样性进行了分析。3对引物共产生57个位点,分离位点比例为57.4%~87.7%,符合孟德尔规律的分离位点为70.0%~71.0%;1:1分离位点占总分离位点的24.0%~45.2%,其中杂交家系的比例最高。3个家系的多态位点比例为93.0%~100.0%,总基因多样性为0.460。家系内的基因多样性为PII0.434,PSI0.331,PSS0.366,平均为0.377±0.030。家系间的遗传分化显著(GST=0.180)。遗传距离分析表明,PSI与PSS之间的遗传距离最大(0.157),PII与PSS之间的遗传距离最小(0.121)。UPGMA系统树表明,PII和PSS的亲缘关系较近,而PSI与这2个家系较远。上述结果表明,第一代家系的遗传多样性仍很高,但家系之间的遗传分化较大。该研究结果对育种过程中遗传资源管理具有一定指导作用。     

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。     

两种壳色虾夷扇贝的RAPD分析

采用RAPD技术对两种壳色虾夷扇贝Patinopecten yessoensis的遗传多样性和遗传结构及其分化进行研究。用筛选出的22个随机引物对白色贝和褐色贝各40个个体进行RAPD扩增，进行群体内及群体间的遗传学分析。白色贝共检测出128个多态位点，多态位点的比例为79．5％，Shannon遗传多样性指数为0．424；褐色贝共检测出127个多态位点，多态位点的比例为78．9％，Shannon遗传多样性指数为0．423。白色贝和褐色贝之间的遗传相似性指数和遗传距离为0．961和0．039，二者之间的遗传分化指数Gst为0．052，遗传分化的程度较低。结果表明，白色贝和褐色贝之间的等位基因频率、多态位点的比例和遗传多样性等的差别不明显，遗传变异主要来自于群体内。S285—1在褐色贝大部分个体中都能获得扩增片段，但在白色贝所有个体中均未见这个位点的扩增片段，推断S285—1为白色贝的特异阴性片段。     

长江口刀鲚遗传多样性的随机扩增多态DNA(RAPD)分析

用随机扩增多态DNA(RAPD)技术对长江口刀鲚(Coilia ectenes)30个个体的遗传多样性进行了检测，从40个随机引物中筛选出17个对每个刀鲚的DNA进行扩增，结果表明，17个引物共检测到148条清晰且重复性好的条带，分子量在200～2000bp之间，其中多态位点为86个，占58．11％；群体的Shannon多样性指数为0．1905，Nei基因多样性指数为0．2280；个体间最大遗传距离为0.212，最小遗传距离为0．092。通过与其他鱼类的遗传多样性的研究结果比较可初步判断，刀鲚群体的遗传多样性比较丰富。     

中国对虾近交两代的DNA随机扩增多态性及其遗传规律分析

为评估DNA随机扩增多态性标记在中国对虾遗传连锁图谱构建中的应用前景，利用中国对虾单对交配亲本及其子二代材料，对RAPD标记及其遗传规律进行了研究。22条RAPD随机引物扩增结果的统计分析表明，标记在中国对虾F2的遗传规律可归为不分离标记和分离标记：不分离标记，指在亲本和后代中均不分离的标记，占总位点的54.1%；分离标记占总位点的45.9%。其中，分离标记又包括符合孟德尔遗传分离的标记、偏离孟德尔遗传分离标记和异常分离标记。符合孟德尔分离的标记中，分离比例为3:1的标记占分离标记的14.7%;总的1:1标记占分离标记的64.7%；偏离孟德尔分离和异常分离的标记分别占分离标记的11.7%和8.9%。在这些分离的标记中，有76.5%的位点在“双假测交理论”的策略中适合构建中国对虾的遗传连锁图谱，这为以中国对虾F2为作图群体，并利用RAPD标记构建中国对虾遗传连锁图谱提供了理论支持。     

A first‐generation genetic map of the Japanese scallop Patinopecten yessoensis‐based AFLP and microsatellite markers

We constructed genetic linkage maps of the Japanese scallop Patinopecten yessoensis using AFLP and microsatellite markers. With 32 AFLP primer combinations, a total of 413 markers (209 from the female parent and 204 from the male parent) segregated in a 1:1 ratio, corresponding to DNA polymorphisms which were heterozygous in one parent and null in the other. Among the six microsatellite markers we used, there were four polymorphic loci. Two segregated in the female parent, and the other two segregated in both parents. In the maternal parent, 161 framework markers were mapped in 20 linkage groups, with a total coverage of 2198.8 cM. In the paternal parent, 166 framework markers established a map with 21 linkage groups, spanning a genome length of 2137.6 cM. The AFLP markers on the maps were randomly distributed with an average spacing between markers of 14.7–15.6 cM. The estimated coverage for the framework maps are 77.9% both for the female and the male. These are the first linkage maps for P. yessoensis, which constitute a basis for further genome studies and provide a useful framework for consensus map construction by adding orthologous anchor markers developed in P. yessoensis.     

Genetic linkage map of the pearl oyster,Pinctada martensii (Dunker)

Genetic linkage maps were constructed with amplified fragment length polymorphism (AFLP) and microsatellite markers for the pearl oyster, Pinctada martensii (Dunker), the main bivalve used for marine pearl production in Asia. Twenty‐four AFLP and 84 microsatellite primer pairs were used for linkage analysis in a full‐sib family with two parents and 78 offspring. Of the 2357 AFLP fragments generated, 394 (16.7%) were polymorphic and segregating. Most (340 or 86.2%) of the markers segregated according to expected Mendelian ratios. Female and male linkage maps were constructed using 230 and 189 markers, including 15 and 10 microsatellites respectively. The female map consisted of 110 markers in 15 linkage groups, covering 1415.9 cM, with an average interval of 14.9 cM. The male map consisted of 98 markers in 16 linkage groups, with a total length of 1323.2 cM and an average interval of 16.1 cM. When unlinked doublets were considered, genome coverages were 78.5% for the female and 73.5% for the male map. Although preliminary, the genetic maps constructed here should be useful for future linkage and quantitative trait loci mapping efforts.     

Genetic linkage map of bay scallop, Argopecten irradians irradians (Lamarck 1819)

The bay scallop (Argopecten irradians irradians Lamarck 1819) has become one of the most important aquaculture species in China. Genetic improvement of cultured bay scallop can benefit greatly from a better understanding of its genome. In this study, we developed amplified fragment length polymorphisms (AFLPs) and simple sequence repeat markers from expressed sequence tags (EST‐SSRs) for linkage analysis in bay scallop. Segregation of 390 AFLP and eight SSR markers was analysed in a mapping population of 97 progeny. Of the AFLP markers analysed, 326 segregated in the expected 1:1 Mendelian ratio, while the remaining 74 (or 19.0%) showed significant deviation, with 33 (44.6%) being deficient in heterozygotes (A/a). Among the eight polymorphic EST‐SSR loci, one marker (12.5%) was found skewing from its expected Mendelian ratios. Eighteen per cent of the markers segregating from female parent were distorted compared with 21% of the markers segregating from male parent. The female map included 147 markers in 17 linkage groups (LGs) and covered 1892.4 cM of the genome. In the male map, totally 146 AFLP and SSR markers were grouped in 18 LGs spanning 1937.1 cM. The average inter‐marker spacing in female and male map was 12.9 and 13.3 cM respectively. The AFLP and SSR markers were distributed evenly throughout the genome except for a few large gaps over 20 cM. Although preliminary, the genetic maps presented here provide a starting point for the mapping of the bay scallop genome.     

A preliminary genetic map of Zhikong scallop (Chlamys farreri Jones et Preston 1904)

Zhikong scallop (Chlamys farreri Jones et Preston 1904) is one of the most important aquaculture species in China. The development of a genetic linkage map would provide a powerful tool for the genetic improvement of this species. Amplified fragment length polymorphism (AFLP) is a PCR‐based technique that has proven to be powerful in genome fingerprinting and mapping, and population analysis. Genetic maps of C. farreri were constructed using AFLP markers and a full‐sib family with 60 progeny. A total of 503 segregating AFLP markers were obtained, with 472 following the Mendelian segregation ratio of 1:1 and 31 markers showing significant (P<0.05) segregation distortion. The male map contained 166 informative AFLP markers in 23 linkage groups covering 2468 cM. The average distance between markers was 14.9 cM. The female genetic map consisted of 198 markers in 25 linkage groups spanning 3130 cM with an average inter‐marker spacing of 15.8 cM. DNA polymorphisms that segregated in a 3:1 ratio as well as the AFLP markers that were heterozygous in both parents were included to construct combined linkage genetic map. Five shared linkage groups, ranging from 61.1 to 162.5 cM, were identified between the male and female maps, covering 431 cM. Amplified fragment length polymorphism markers appeared to be evenly distributed within the linkage groups. Although preliminary, these maps provide a starting point for the mapping of the functional genes and quantitative trait loci in C. farreri.     

团头鲂“浦江1号” 选育后期世代群体同野生群体间遗传变异的ISSR分析

以团头鲂“浦江1号” 选育后期3个世代群体（F₇、F₈、F₉）为试验对象、其选育奠基群体（1985年淤泥湖野生群体）后代、淤泥湖野生群体（2007年）、梁子湖野生群体（2007年）为对照材料，通过ISSR标记技术分析，并通过部分样本的细胞色素b基因测序的补充验证，了解选育所产生的遗传变异及野生群体遗传结构现状。主要结果：（1）从100个ISSR引物中筛选出26个引物，扩增出清晰、可重复的条带共164条，多态性条带比例49.39%。细胞色素b基因在选育良种3个世代中只发现一种单倍型。（2）选育群体同选育奠基群体后代、野生群体间的遗传差异显著，如群体多态位点百分数，F₉（28.05%）比选育奠基群体后代（40.24%）减少了30.29%，比淤泥湖野生群体（41.46%）减少了32.34%。选育群体同淤泥湖野生群体间的遗传相似系数最小（0.935 0），距离最大（0.067 2），两两配对F_ST值最大（F_ST=0.305 72）；UPGMA法构建系统进化树表明，选育群体同野生群体处于两个大分支，而在野生群体大支中，选育奠基群体后代与淤泥湖原种野生群体间配对F_ST值最小（F_ST=0.050 45）。（3）选育群体F₇、F₈、F₉各世代间遗传分化虽弱（低G_ST 0.141 7值，高N_m 3.027 9值），但多态位点百分数、位点基因平均多样性、Nei氏基因多样性、群体内Shannon多样性指数等遗传参数仍然都呈现随选育世代数的累进而降低的趋势。（4）ISSR比细胞色素b基因更适合近缘种的相关关系研究。（5）经过二十多年9代的选育，相对于野生群体，团头鲂“浦江1号”良种已产生了明显的遗传分化，性状已相当稳定，但离选育极限尚有一定距离，今后应在继续监测其遗传结构变化的基础上，进一步挖掘选育潜力，同时要避免种质混杂、近交衰退及瓶颈效应等的发生。     

辽宁沿海海蜇与沙海蜇遗传多样性的AFLP分析

海蜇和沙海蛰均为腔肠动物门的大型食用水母,采用AFLP分子标记技术对辽宁沿海的海蜇野生群体、养殖群体和沙海蜇野生群体共90个个体进行了遗传多样性分析.10对引物共得到560个稳定扩增位点.3个群体的多态性位点比例为海蜇野生群体82.05%.海蜇养殖群体78.46%,沙海蜇野生群体74.10%;平均杂合度分别为0.2072,0.1850和0.2116,Shannon多样性指数分别为0.3248、0.2954和0.3262,海蜇野生群体与海蜇养殖群体和沙海蜇野生群体的遗传距离分别为0.0300和0.2702.分析结果表明,3个群体的遗传多样性均保持了相对较高的水平.     

斑节对虾养殖群体遗传多样性的同工酶和RAPD分析

采用聚丙烯酰胺凝胶电泳（PAGE）和RAPD方法对厦门养殖斑节对虾（Penaeus monodon Fabricius）群体的遗传多样性进行分析。9种同工酶共检测到21个座位，其中多态座位13个，多态座位比例为61．90％，预期杂合度0．151，观察杂合度0．120，Hardy—Weinberg遗传偏离指数（d）为-0．208，存在杂合子缺失。经x^2拟合度检验，多数座位偏离Hardy—Weinberg平衡，表明群体未达到随机交配。14个10bp引物共获得了83个标记，单个引物获得的标记数为2～11个，平均每个引物扩增出5．93个座位，其中多态标记数68个，多态位点比例为81．93％，杂合度为0．246，基因多样性为0．260，Shannon’S信息指数为0．397。两种方法均表明该斑节对虾养殖群体的遗传多样性水平较高，但可能已有近交衰退发生。     

黄姑鱼群体遗传多样性的AFLP分析

对青岛和厦门黄姑鱼群体的遗传多样性进行了AFLP分析，5对选择性引物在两个群体47个个体中，共扩增出461个位点，多态位点265个。青岛和厦门群体的多态位点比例、Nei遗传多样性指数和Shannon遗传多样性指数分别为51.70%、51.99%，0.1022、0.0996，0.1643、0.1622；两个群体遗传多样性在同一水平上。基因分化系数G_st、Shannon遗传多样性指数和AMOVA分析均显示黄姑鱼的遗传变异主要来源于群体内个体间，而群体间无明显的遗传分化。群体的显性基因型频率分布和位点差异数分布显示两个群体有基本相同的群体遗传结构。结果表明，黄姑鱼青岛和厦门群体间无明显的遗传差异，群体间有明显的基因交流。     

A first genetic linkage map of bluegill sunfish (<Emphasis Type="Italic">Lepomis macrochirus</Emphasis>) using AFLP markers

Genetic linkage maps were constructed for bluegill sunfish, Lepomis macrochirus, using AFLP in a F₁ inter-population hybrid family based on a double-pseudo testcross strategy. Sixty-four primer combinations produced 4,010 loci, of which 222 maternal loci and 216 paternal loci segregated at a 1:1 Mendelian ratio, respectively. The female and male framework maps consisted of 176 and 177 markers ordered into 31 and 33 genetic linkage groups, spanning 1628.2 and 1525.3 cM, with an average marker spacing of 10.71 and 10.59 cM, respectively. Genome coverage was estimated to be 69.5 and 69.3% for the female and male framework maps, respectively. On the maternal genetic linkage map, the maximum length and marker number of the linkage groups were 122.9 cM and 14, respectively. For the paternal map, the maximum length and marker number of the linkage groups were 345.3 cM and 19, respectively, which were much greater than those on the maternal genetic linkage map. The other genetic linkage map parameters of the paternal genetic linkage map were similar to those in the maternal genetic linkage map. For both the female and male maps, the number of linkage groups was greater than the haploid chromosome number of bluegill (2n = 48), indicating some linkage groups may distribute on the same chromosome. This genetic linkage mapping is the first step toward to the QTL mapping of traits important to cultured breeding in bluegill.     

Application of DNA markers to the management of Atlantic halibut (Hippoglossus hippoglossus) broodstock

For many aquaculture finfish species, the current broodstock have been collected from the wild or have undergone only a few generations of domestication. The Atlantic halibut (Hippoglossus hippoglossus) aquaculture industry in Atlantic Canada has retained F₁ juveniles (n=145) from the 1996 spawning of wild adults for candidate broodstock. Through the development and use of a five-microsatellite DNA marker multiplex, we determined the parentage of these 1996 F1 individuals, which are being reared at one government and two industry hatcheries, and evaluated the change in genetic variation between the wild and the 1996 F₁ stock. In the three groups of F₁ fish, single parental pairs were assigned to 98%, 96% and 100% of individuals. Large full- and half-sibling groups were identified within and across F₁ groups and, overall, only 36% of attempted crosses were represented in the retained fish. Effective population size in the parental group decreased from 27 to 13 when variance in family size was accounted for and to 12.5 when changes in gene diversity (compared to the combined F₁ stocks) were considered. Statistically significant differences in measures of genetic variation were not widely observed between groups (original wild sample, parental group, three F₁ groups and combined F₁). However, the F₁ population shows a 26% decrease in total allele numbers compared to the wild sample. These observations demonstrate the utility of genetic tools in the evaluation of genetic diversity and determination of pedigree during the establishment of new broodstock. They also emphasize the necessity for closely monitoring future matings among these fish and suggest the need to introduce additional genetic variation into this group of Atlantic halibut broodstock.