坛紫菜遗传连锁图谱的构建

以野生型坛紫菜纯系(♀)和红色型坛紫菜纯系(♂)作为杂交亲本,结合四分子分析法及单个体细胞克隆的丝状体途径,创建了由157个株系组成的坛紫菜DH作图群体,并用经过筛选的24对SRAP引物和16对SSR引物对父母本及作图群体各株系进行双标记分析,获得了224个多态性标记,其中157个标记符合孟德尔分离规律。根据标记间的连锁规律,首次构建了坛紫菜的分子遗传连锁图谱,所构建的遗传图谱由包含124个标记(含SRAP标记104个,SSR标记20个)的5个连锁群组成,总长度为879.2cM,平均标记间隔为7.09cM,各个连锁群长度为134.2～213.6cM,包含标记18～31个。最后采用3种不同方法计算得到坛紫菜的估计基因组长度平均为955.3cM,由此得到坛紫菜遗传连锁图谱的基因组覆盖率为92.0%。     

牙鲆遗传连锁图谱的构建

利用基因组测序得到的大量微卫星序列,以681383B为父本、6812E36为母本杂交获得的F1为作图群体,构建了牙鲆(Paralichthys olivaceus)微卫星标记(SSR)遗传连锁图谱。雌雄图谱共定位SSR标记529个,其中雄性连锁图谱包括418个标记,分布在24个连锁群上,总长度1 418.1 cM,标记平均间隔3.62 cM,图谱覆盖率为88.7%;雌性连锁图谱包括437个标记,分布在24个连锁群上,总长度1 298.1 cM,标记平均间隔为3.16 cM,图谱覆盖率为89.1%。牙鲆中密度遗传图谱的构建为QTL分析以及分子标记辅助育种进一步奠定基础,并可以有效推动牙鲆的遗传改良工作,推动牙鲆养殖业的可持续发展。     

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。     

利用中国明对虾单对杂交亲本及其F↓（2）群体构建RAPD遗传连锁图谱

由中国明对虾(Fenneropenaeus chinensis)单对杂交亲本(G♀和G♂)及其F2为作图群体,构建了中国明对虾RAPD分子标记的遗传连锁图谱。109个引物共产生284个符合孟德尔分离规律的位点,符合1∶1孟德尔分离类型的位点共234个,符合3∶1孟德尔分离类型的位点50个。利用拟测交理论分别构建中国明对虾雌虾、雄虾的遗传连锁图谱。107个1∶1分离标记分布于雌虾连锁图谱中,包括31个连锁群,图谱总长度为1 406.1 cM,所有标记间的平均间隔为18.5 cM;91个1∶1分离标记分布于雄虾连锁图谱中,包括26个连锁群,图谱总长度为1 187.7 cM,所有标记间的平均间隔为18.27 cM;利用F2自交模型构建了雌虾和雄虾共同的分子标记,35个3∶1分离标记分布于雌雄共有的连锁图谱中,包括10个连锁群,图谱总长度为432.9 cM,所有标记间的平均间隔为17.3 cM。     

黄颡鱼遗传图谱构建及生长相关性状的QTL定位

以野生(♂)和人工养殖(♀)黄颡鱼杂交的100个F1个体为作图群体,用SSR、SRAP和TRAP3种DNA分子标记技术构建黄颡鱼的遗传连锁图谱。图谱整合了13个SSR标记,89个SRAP标记,26个TRAP标记。其中雌性框架图谱包括16个连锁群,图谱的长度为585.5cM;雄性框架图谱包括15个连锁群,图谱的长度为752.3cM;共享框架图谱包括5个连锁群,图谱的长度为231.3cM。用该连锁图谱对黄颡鱼的5个生长相关性状进行QTL扫描,在雌性图谱上检测到1个头宽的QTL,定位于第七连锁群上,LOD值为3.2,可解释的表型变异为13%。在雄性图谱上分别检测到1个体高和体长的QTL,均定位于第一连锁群上。体高QTL的LOD值为2.4,可解释的表型变异为12%。全长QTL的LOD值为2.1,可解释的表型变异为11%。3个QTL均可用于黄颡鱼的生长性状的标记辅助育种。     

合浦珠母贝遗传连锁图谱的构建

用AFLP标记构建了印度合浦珠母贝(Pinctada fucata)全同胞家系的遗传图谱。用经过筛选的36对引物组合对父母本和62个子代个体进行遗传分析,共得到1 547个标记,包括581个1∶1分离标记。母本分离标记294个,其中178个符合1∶1孟德尔分离规律;父本分离标记287个,其中182个符合1∶1孟德尔分离规律。雌性框架图包括33个遗传标记,分布在14个连锁群中,标记间平均间隔24.3 cM,有2个3联体,11个连锁对,图谱总长度为488.5 cM。雄性框架图包括53个遗传标记,分布在19个连锁群中,标记间平均间隔30.5 cM,有4个3联体,10个连锁对,图谱总长度为1 035.5 cM。雌雄两个框架图中AFLP标记的分布都较均匀。雌雄基因组估算长度分别为1 168.4 cM和2 037.1 cM,图谱覆盖率分别为41.8%和50.8%。本研究为进一步构建高密度遗传连锁图谱及QTL定位分析奠定了基础。     

中国对虾遗传连锁图谱的构建

利用RAPD、SSR和AFLP三种标记技术结合"拟测交"策略,以中国对虾"黄海1号"雌虾与野生雄虾作为亲本进行单对杂交产生的F1家系为作图群体,初步构建了中国对虾雌、雄性遗传连锁图谱.对460个RAPD引物和44对SSR引物进行筛选,共选出61个.RAPD和20对SSR引物,结合88对AFLP引物组合对父母本和82个F1个体进行了遗传分析.共得到783个分离标记(RAPD标记237个,微卫星标记45个,AFLP标记501个),761个标记用于连锁分析.雌性图谱包括40个连锁群和15个三联体,20个连锁对,标记间平均间隔为12.5 cM,图谱共覆盖2835.5 cM,覆盖率为73.5%;雄性图谱包括41个连锁群和6个三联体,12个连锁对,标记间平均间隔为11.9 cM,图谱共覆盖2776.7 cM,覆盖率为73.3%.中国对虾遗传图谱的构建为其分子标记辅助育种、比较基因组作图及数量性状位点(QTL)的定位与克隆奠定了基础.     

基于微卫星标记整合长牡蛎遗传图谱

为了提高长牡蛎遗传图谱上的微卫星标记密度,实验采用6个家系图谱间的共有微卫星标记作为锚定标记,构建了长牡蛎的整合图谱.该整合图谱共有161个微卫星标记,覆盖10个连锁群,图谱长度和平均间距分别为615.4和3.8 cM.各连锁群的标记数介于10 ～ 24个之间,连锁群长度为47.3～73.3 cM,是目前密度最高的长牡蛎微卫星图谱.不同作图家系连锁群上的标记分组保持一致,但标记顺序出现差异,可能与长牡蛎自然群体中存在大量的染色体重排现象有关.结果表明,该图谱可以为今后长牡蛎的遗传育种研究提供新的遗传工具.     

利用OneMap软件构建鲤遗传连锁图谱

首次使用R环境中的OneMap软件包,以荷包红鲤抗寒品系(♂)和云南大头鲤(♀)为祖父母本所培育的110个F2个体为作图群体,以荧光扩增片段长度多态性(fluorescent amplification fragment length polymorphism,fAFLP)为主要分子标记,采用远交全同胞家系模型构建鲤的遗传连锁图谱。结果显示,110个F2个体中共产生1513个清晰的fAFLP标记,其中多态性标记911个;另开发多态性的EST标记12个,最后总计923个标记用于构建遗传连锁图谱;采用OneMap软件包构建的遗传图谱含有238个fAFLP标记和8个EST标记分布在50个连锁群上,总图距为2876.64cM,标记间平均间距为14.68cM,图谱覆盖率为66.56%。     

半滑舌鳎微卫星标记遗传连锁图谱的构建

利用全基因组测序方法筛选出微卫星标记,以渤海近海野生个体和人工养殖的半滑舌鳎(Cynoglossus semi-laevis)为亲本交配产生的F1全同胞家系为作图群体,构建了半滑舌鳎雌、雄微卫星标记遗传连锁图谱。用320对引物对父母本和92个F1个体进行遗传分析,共得到288个分离标记,其中包含112个偏分离标记(P<0.05)。其中雌性框架图包含242个标记,分布在21个连锁群上,总长度1 311.9 cM,标记间平均距离为4.9 cM,图谱覆盖率为83.3%;雄性框架图定位标记218个,21个连锁群,总长度1 316.2 cM,标记间平均距离为5.5 cM,覆盖率为82%。半滑舌鳎遗传连锁图谱的构建为半滑舌鳎重要经济性状QTL定位、分子标记辅助育种和性别控制奠定了重要基础。     

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.     

AFLP-based genetic linkage map of marine shrimp Penaeus (Fenneropenaeus) chinensis

This paper presents the genetic linkage map of the Chinese shrimp Penaeus (Fenneropenaeus) chinensis constructed with 472 AFLP markers. A hundred F₁ progeny from an intercross between a female from the new variety “Yellow Sea No. 1” and wild caught male used for the mapping study. Two separate maps were constructed for each parent. The female linkage map consisted of 197 marker loci forming 35 linkage groups and spanned a total length of 2191.1 cM, with an average marker space of 13.5 cM. The male map consisted of 194 marker loci mapped to 36 linkage groups and spanned a total length of 1737.3 cM, with an average marker spacing of 11.0 cM. The level of segregation distortion observed in this study was 12.2%. The estimated genome length of P. chinensis was 3150.3 cM for the female and 2549.3 cM for the male, respectively. The observed genome coverage was 69.6% for the female and 68.1% for the male map. The linkage maps constructed in this study provide basic information for further linkage studies on Chinese shrimp, and more importantly, the construction of the maps are part of the work of the genetic breeding programs which will be used for growth discovered in the QTL analysis of P. chinensis.     

A genetic linkage map of the Japanese flounder, Paralichthys olivaceus

We report the first genetic linkage map of the Japanese flounder (Paralichthys olivaceus) constructed with 111 microsatellite markers and 352 AFLP fragments. The parental male linkage map consisted of 25 linkage groups while the female map consisted of 27 groups, with an average resolution of 8 and 6.6 cM, respectively. We have identified linkage among 96% of the markers and the total map length was estimated to be around 1000–1200 cM. This study reports the first low-density linkage map for the Japanese flounder and describes differences in sex recombination. Recombination rates were higher in male flounder compared to the female (7.4:1), a rare condition among vertebrates. This map is a starting point for the mapping of single loci and quantitative traits in flatfish species.     

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.     

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.     

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 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.     

牙鲆遗传作图及生长性状QTL定位

采用牙鲆日本群体和韩国群体杂交的92个F₁个体作为分离群体, 利用微卫星标记和Joinmap 4.0作图软件构建了牙鲆遗传连锁图谱。共有221个SSR标记用于连锁图谱构建, 雌性图谱中, 共178个微卫星标记定位到22个连锁群上, 观测总长度为(G _oa )599.0 cM, 覆盖率(C _oa )达76.27%。雄性图谱中, 共194个微卫星标记定位到23个连锁群上, G _oa 为693.4 cM, C _oa 为78.82%。对全长、体质量、体高3组数据进行主成分分析处理, 得到可解释3个性状的89.6%特征的一组数据, 命名为牙鲆生长性状GT。用WinQTLCart 2.5软件的复合区间作图,在已构建的遗传连锁图谱上对牙鲆生长性状GT进行QTL定位, 取LOD经验值2.5为QTL存在的阈值; 对微卫星标记进行性状—标记之间的回归分析。本研究共定位3个与牙鲆生长性状GT相关的QTLs, qGT-f4 qGT-m20 qGT-f20,可解释表型变异率分别为27.60%, 13.74%, 10.27%。在性状—标记之间的回归分析中, 得到22个与生长性状GT相关(P<0.05)的微卫星标记, 单个标记可解释表型变异率介于3.70%~10.42%, 其中6个微卫星标记scaffold558_51720、scaffold558_26183、scaffold903_69232、scaffold485_47120 、scaffold1262_77386、scaffold809_65154与生长性状GT之间呈极显著相关(P><0.01), 可解释表型变异率分别为10.42%、7.31%、10.07%、10.07%、8.39%和11.26%。