文蛤(Meretrix meretrix)选育群体的遗传测定及生长相关SNP鉴定
|
摘要
文蛤作为我国重要经济贝类之一,其养殖产业的快速发展对优质苗种资源的
需求日益迫切。提高养殖产量和效益一直是文蛤养殖业的焦点,这要求我们选育高产、抗逆并且稳定遗传的文蛤良种。本研究利用开发的微卫星标记,结合传统的选择和杂交手段,对文蛤不同选育群体进行了遗传测定,另外开发了与生长性状相关的SNP标记,以期为文蛤新品系培育提供基础数据和理论依据,推动文蛤养殖业健康持续的发展。
利用文蛤野生群体构建了一批家系,从中选取3个家系(P1、P2、P3)按3×3完全双列杂交设计得到9个组合。利用8个微卫星标记对9个组合进行亲权鉴定,统计各个组合中亲本对子代的贡献率。结果显示,同一个家系来源的不同亲本间的子代贡献率差异很大,同一个亲本在不同组合中的贡献率也明显不同。根据亲本贡献率估算了有效亲本数量(Ne),发现所有组合的有效亲本数量都有所偏小,Ne/N值从0.58到0.86不等。另外,大部分组合的子代遗传多样性较其亲本都有所下降。
从9个组合中选取3个高存活率的杂交组合和3个近交组合分别构成对照组和近交组,利用8个微卫星标记评估它们的遗传多样性。结果显示,与对照组相比,近交组的平均等位基因数(Na)下降19.4%,平均观测杂合度(Ho)和期望杂合度(He)分别下降20.8%和9.3%。近交组的平均近交系数(FIS)显著高于对照组以及野生群体。在12月龄时,近交组在壳长、壳高、壳宽和湿重4个性状上的近交衰退系数分别为0.803、0.747、0.826和2.073。另外,通过研究家系P1和其子代组合P1×P1发现,在繁育过程中出现了严重的遗传漂变现象。模拟分析显示,较大的亲本数量可以控制闭锁群体杂合度的降低。
将9个组合的子代分别养殖在室内池和室外池两种环境中,测量其12月龄时的生长数据并利用一般线性模型进行方差分析,结果显示存在显著的组合效应、环境效应以及组合环境互作效应。配合力分析显示,3个家系中P2在生长性状上的一般配合力(GCA)最高,P1和P3组合的特殊配合力(SCA)最高,而且组合间的反交效应显著。另外,计算了在单个环境内和综合环境间6个杂交组合的杂种优势(MPH)。结果显示,有半数的杂交组合存在有利的杂种优势(>1%)。
基于文蛤EST数据库和生物信息学的方法预测了一批EST-SNP标记,经混合测序验证后,将确认的16个SNPs通过SNaPshot的方法在一个生长优势群体和一个对照群体中分型,利用标记-性状关联分析鉴定出7个与生长性状显著相关的SNPs(SNPg3、SNPg4、SNPg5、SNPg6、SNPg8、SNPg9和SNPg16)(P<0.05),又利用一个独立群体进行双向选择性分型验证了其中3个标记(SNPg5、SNPg6和SNPg9)与生长性状的相关性。这是首次在文蛤中进行生长相关EST-SNP标记的批量开发,为文蛤标记辅助选育提供了有价值的信息。
利用生长差异的群体材料,开展了重要功能基因多态性与文蛤生长的关联分析。从文蛤中克隆到一个长链酯酰辅酶A合成酶基因(MmeACSL1),全长1867bp,编码475个氨基酸。利用Real-time PCR检测了在不同营养条件下文蛤该基因的表达,发现MmeACSL1在禁食条件下的表达水平显著高于正常进食下的表达水平(P <0.05),提示其参与了文蛤的能量代谢。通过生物信息学预测和直接测序,在此基因中发现2个外显子SNPs和6个内含子SNPs。基于标记-性状关联分析,从这些SNPs中鉴定出5个显著生长相关的SNPs(mmACSLe-2、mmACSLi-2、mmACSLi-3、mmACSLi-5和mmACSLi-4)(P <0.05),而且它们所构建的单倍型也与生长性状显著相关(P <0.05),表明MmeACSL1在文蛤能量代谢中具有重要作用,并与文蛤生长存在密切联系。
克隆获得了文蛤细胞周期蛋白依赖性激酶基因(CDK10),cDNA全长1854bp,编码390个氨基酸。此基因与哺乳动物中CDK10基因的同源性最高,将其命名为MmeCDK10。通过对该基因测序,发现5个外显子SNPs和5个内含子SNPs。利用两个生长差异显著的群体对这些SNPs进行标记-性状关联分析,发现4个外显子SNPs(mmCDKe-1、mmCDKe-3、mmCDKe-4和mmCDKe-5)和1个内含子SNP(mmCDKi-1)与生长性状显著相关(P <0.05),提示MmeCDK10参与了文蛤的生长。
The clam Meretrix meretrix is one of the most important commercial mollusks inChina. With the development of its artificial culture, the demand for quality seedresources increasingly urgent. High yield and benefit have been the focus of itsaquculture, which requires us to raise improved seeds with high-yield, resistance andgenetic stability. In the present study, with the microsatellite markers and thetraditional methods of selection and hybridization, we conducted genetic test fordifferent populations of M. meretrix. And we further developed SNP markersassociated with growth traits. These are expected to provide basic data and theory forbreeding new strains and promote the sustainable and healthy development of clamaquaculture.
A natural population of M. meretrix was used to found a number of families, fromwhich three (P1, P2, P3) were chosen to set a complete3×3diallel cross comprisingnine crosses. Eight microsatellite markers were used for parentage analysis in the ninecrosses. Estimation of parental contributions to offspring showed that thecontributions of different sires or dams from one family to offspring had greatdifference and the contributions of the same parent to offspring in different crosseswere markedly unequal. Effective parent number (Ne) was calculated based onparental contribution. It was found that there was a significant reduction of Nein allthe crosses. The Ne/N ratio for the nine crosses ranged from0.58to0.86. In addition,the genetic diversity of all the parents was some degree higher than that of theirrespective offspring in most crosses.
Three outbred crosses with high survival rate and three inbred crosses wererespectively chosen from the nine crosses to establish a control group and an inbredgroup. After evaluated by eight microsatellite markers, genetic variability of the inbred group diminished relative to the control group, as evidenced by drop of19.4%,20.8%and9.3%on average number of alleles, observed and expected heterozygosity,respectively. The inbred line had a higher average FISvalue than the control group andnatural population. The estimated inbreeding depression coefficients for shell length,shell height, shell width and whole body weight at12months post-fertilization were
0.803,0.747,0.826and2.073per10%increase in FIS. Investigation of familyP1and its progeny cross P1×P1indicated that a serious genetic drift occurred in thebreeding. Simulation results showed that a large Necould control reduction ofheterozygosity in a closed population.
Progeny of the nine crosses were reared in two environments, indoor ponds andopen-air ponds. After cultured for12months, the growth data were measured and ageneral linear model was used for analysis of variance. The results indicated highlysignificant cross effects, environment effects and the interaction of cross byenvironment. Analysis of combining ability showed that P2was the top combineramong the three parental families for growth traits, the cross of P1and P3had thehighest specific combing ability (SCA) and there were significant reciprocal effects.In addition, Mid-parent heterosis (MPH) was estimated for the six crossbredcombinations in individual environment and over environments. The results showedthat about half of the crossbred combinations had favorable MPH (>1%).
Based on EST database of M. meretrix and bioinformatic methods, a batch ofEST-SNPs were predicted, and then validated by pooled sequencing. A total of16confirmed SNPs were genotyped with SNaPshot assay between a fast-growingpopulation and a control population. A marker-trait association analysis identifiedseven SNPs (SNPg3, SNPg4, SNPg5, SNPg6, SNPg8, SNPg9and SNPg16)significantly associated with growth (P <0.05). After bidirectional selectivegenotyping in an independent population, three SNPs (SNPg5, SNPg6and SNPg9) ofthe seven markers were further confirmed to be associated (P <0.05). This is the firstreport on identification of a batch of growth-associated SNPs in M. meretrix, whichprovides valuable information for marker-assisted selection for this species.
Based on two populations with significant difference in growth, association studyof SNPs in important functional genes with the growth traits of M. meretrix was made.A long-chain fatty acyl-CoA ligase gene (MmeACSL1) was cloned in M. meretrix,with a full-length cDNA of1876bp encoding475amino acids. Examination ofMmeACSL1gene expression under different nutrient conditions by Real-time PCRshowed that the expression of MmeACSL1gene under fasting condition had asignificant increase compared with that under feeding condition (P <0.05), whichsuggested that MmeACSL1was involved in energy metabolism of M. meretrix. Bymeans of bioinformatic prediction and direct sequencing, two exon SNPs and sixintron SNPs were detected in this gene. A marker-trait association analysis identifiedfive SNPs (mmACSLe-2, mmACSLi-2, mmACSLi-3, mmACSLi-5and mmACSLi-4)significantly associated with growth (P <0.05), and haplotypes comprising these fiveSNPs were also significantly growth-associated (P <0.05), which implied theimportant role of MmeACSL1in energy metabolism and its association with thegrowth of M. meretrix.
A cyclin-dependent kinase (CDK) gene was cloned in M. meretrix, with afull-length cDNA of1854bp, which encoded390amino acids. This gene showed thehighest homology with CDK10in mammals, so it was named MmeCDK10. Directsequencing of this gene detected five exon SNPs and five intron SNPs, from whichfour exon SNPs (mmCDKe-1, mmCDKe-3, mmCDKe-4and mmCDKe-5) and oneintron SNP (mmCDKi-1) were found to be significantly associated with growth traits(P <0.05), by a marker-trait association analysis between two populations withsignificant difference in growt, which suggested that MmeCDK10was involved in thegrowth of this clam.
需求日益迫切。提高养殖产量和效益一直是文蛤养殖业的焦点,这要求我们选育高产、抗逆并且稳定遗传的文蛤良种。本研究利用开发的微卫星标记,结合传统的选择和杂交手段,对文蛤不同选育群体进行了遗传测定,另外开发了与生长性状相关的SNP标记,以期为文蛤新品系培育提供基础数据和理论依据,推动文蛤养殖业健康持续的发展。
利用文蛤野生群体构建了一批家系,从中选取3个家系(P1、P2、P3)按3×3完全双列杂交设计得到9个组合。利用8个微卫星标记对9个组合进行亲权鉴定,统计各个组合中亲本对子代的贡献率。结果显示,同一个家系来源的不同亲本间的子代贡献率差异很大,同一个亲本在不同组合中的贡献率也明显不同。根据亲本贡献率估算了有效亲本数量(Ne),发现所有组合的有效亲本数量都有所偏小,Ne/N值从0.58到0.86不等。另外,大部分组合的子代遗传多样性较其亲本都有所下降。
从9个组合中选取3个高存活率的杂交组合和3个近交组合分别构成对照组和近交组,利用8个微卫星标记评估它们的遗传多样性。结果显示,与对照组相比,近交组的平均等位基因数(Na)下降19.4%,平均观测杂合度(Ho)和期望杂合度(He)分别下降20.8%和9.3%。近交组的平均近交系数(FIS)显著高于对照组以及野生群体。在12月龄时,近交组在壳长、壳高、壳宽和湿重4个性状上的近交衰退系数分别为0.803、0.747、0.826和2.073。另外,通过研究家系P1和其子代组合P1×P1发现,在繁育过程中出现了严重的遗传漂变现象。模拟分析显示,较大的亲本数量可以控制闭锁群体杂合度的降低。
将9个组合的子代分别养殖在室内池和室外池两种环境中,测量其12月龄时的生长数据并利用一般线性模型进行方差分析,结果显示存在显著的组合效应、环境效应以及组合环境互作效应。配合力分析显示,3个家系中P2在生长性状上的一般配合力(GCA)最高,P1和P3组合的特殊配合力(SCA)最高,而且组合间的反交效应显著。另外,计算了在单个环境内和综合环境间6个杂交组合的杂种优势(MPH)。结果显示,有半数的杂交组合存在有利的杂种优势(>1%)。
基于文蛤EST数据库和生物信息学的方法预测了一批EST-SNP标记,经混合测序验证后,将确认的16个SNPs通过SNaPshot的方法在一个生长优势群体和一个对照群体中分型,利用标记-性状关联分析鉴定出7个与生长性状显著相关的SNPs(SNPg3、SNPg4、SNPg5、SNPg6、SNPg8、SNPg9和SNPg16)(P<0.05),又利用一个独立群体进行双向选择性分型验证了其中3个标记(SNPg5、SNPg6和SNPg9)与生长性状的相关性。这是首次在文蛤中进行生长相关EST-SNP标记的批量开发,为文蛤标记辅助选育提供了有价值的信息。
利用生长差异的群体材料,开展了重要功能基因多态性与文蛤生长的关联分析。从文蛤中克隆到一个长链酯酰辅酶A合成酶基因(MmeACSL1),全长1867bp,编码475个氨基酸。利用Real-time PCR检测了在不同营养条件下文蛤该基因的表达,发现MmeACSL1在禁食条件下的表达水平显著高于正常进食下的表达水平(P <0.05),提示其参与了文蛤的能量代谢。通过生物信息学预测和直接测序,在此基因中发现2个外显子SNPs和6个内含子SNPs。基于标记-性状关联分析,从这些SNPs中鉴定出5个显著生长相关的SNPs(mmACSLe-2、mmACSLi-2、mmACSLi-3、mmACSLi-5和mmACSLi-4)(P <0.05),而且它们所构建的单倍型也与生长性状显著相关(P <0.05),表明MmeACSL1在文蛤能量代谢中具有重要作用,并与文蛤生长存在密切联系。
克隆获得了文蛤细胞周期蛋白依赖性激酶基因(CDK10),cDNA全长1854bp,编码390个氨基酸。此基因与哺乳动物中CDK10基因的同源性最高,将其命名为MmeCDK10。通过对该基因测序,发现5个外显子SNPs和5个内含子SNPs。利用两个生长差异显著的群体对这些SNPs进行标记-性状关联分析,发现4个外显子SNPs(mmCDKe-1、mmCDKe-3、mmCDKe-4和mmCDKe-5)和1个内含子SNP(mmCDKi-1)与生长性状显著相关(P <0.05),提示MmeCDK10参与了文蛤的生长。
The clam Meretrix meretrix is one of the most important commercial mollusks inChina. With the development of its artificial culture, the demand for quality seedresources increasingly urgent. High yield and benefit have been the focus of itsaquculture, which requires us to raise improved seeds with high-yield, resistance andgenetic stability. In the present study, with the microsatellite markers and thetraditional methods of selection and hybridization, we conducted genetic test fordifferent populations of M. meretrix. And we further developed SNP markersassociated with growth traits. These are expected to provide basic data and theory forbreeding new strains and promote the sustainable and healthy development of clamaquaculture.
A natural population of M. meretrix was used to found a number of families, fromwhich three (P1, P2, P3) were chosen to set a complete3×3diallel cross comprisingnine crosses. Eight microsatellite markers were used for parentage analysis in the ninecrosses. Estimation of parental contributions to offspring showed that thecontributions of different sires or dams from one family to offspring had greatdifference and the contributions of the same parent to offspring in different crosseswere markedly unequal. Effective parent number (Ne) was calculated based onparental contribution. It was found that there was a significant reduction of Nein allthe crosses. The Ne/N ratio for the nine crosses ranged from0.58to0.86. In addition,the genetic diversity of all the parents was some degree higher than that of theirrespective offspring in most crosses.
Three outbred crosses with high survival rate and three inbred crosses wererespectively chosen from the nine crosses to establish a control group and an inbredgroup. After evaluated by eight microsatellite markers, genetic variability of the inbred group diminished relative to the control group, as evidenced by drop of19.4%,20.8%and9.3%on average number of alleles, observed and expected heterozygosity,respectively. The inbred line had a higher average FISvalue than the control group andnatural population. The estimated inbreeding depression coefficients for shell length,shell height, shell width and whole body weight at12months post-fertilization were
0.803,0.747,0.826and2.073per10%increase in FIS. Investigation of familyP1and its progeny cross P1×P1indicated that a serious genetic drift occurred in thebreeding. Simulation results showed that a large Necould control reduction ofheterozygosity in a closed population.
Progeny of the nine crosses were reared in two environments, indoor ponds andopen-air ponds. After cultured for12months, the growth data were measured and ageneral linear model was used for analysis of variance. The results indicated highlysignificant cross effects, environment effects and the interaction of cross byenvironment. Analysis of combining ability showed that P2was the top combineramong the three parental families for growth traits, the cross of P1and P3had thehighest specific combing ability (SCA) and there were significant reciprocal effects.In addition, Mid-parent heterosis (MPH) was estimated for the six crossbredcombinations in individual environment and over environments. The results showedthat about half of the crossbred combinations had favorable MPH (>1%).
Based on EST database of M. meretrix and bioinformatic methods, a batch ofEST-SNPs were predicted, and then validated by pooled sequencing. A total of16confirmed SNPs were genotyped with SNaPshot assay between a fast-growingpopulation and a control population. A marker-trait association analysis identifiedseven SNPs (SNPg3, SNPg4, SNPg5, SNPg6, SNPg8, SNPg9and SNPg16)significantly associated with growth (P <0.05). After bidirectional selectivegenotyping in an independent population, three SNPs (SNPg5, SNPg6and SNPg9) ofthe seven markers were further confirmed to be associated (P <0.05). This is the firstreport on identification of a batch of growth-associated SNPs in M. meretrix, whichprovides valuable information for marker-assisted selection for this species.
Based on two populations with significant difference in growth, association studyof SNPs in important functional genes with the growth traits of M. meretrix was made.A long-chain fatty acyl-CoA ligase gene (MmeACSL1) was cloned in M. meretrix,with a full-length cDNA of1876bp encoding475amino acids. Examination ofMmeACSL1gene expression under different nutrient conditions by Real-time PCRshowed that the expression of MmeACSL1gene under fasting condition had asignificant increase compared with that under feeding condition (P <0.05), whichsuggested that MmeACSL1was involved in energy metabolism of M. meretrix. Bymeans of bioinformatic prediction and direct sequencing, two exon SNPs and sixintron SNPs were detected in this gene. A marker-trait association analysis identifiedfive SNPs (mmACSLe-2, mmACSLi-2, mmACSLi-3, mmACSLi-5and mmACSLi-4)significantly associated with growth (P <0.05), and haplotypes comprising these fiveSNPs were also significantly growth-associated (P <0.05), which implied theimportant role of MmeACSL1in energy metabolism and its association with thegrowth of M. meretrix.
A cyclin-dependent kinase (CDK) gene was cloned in M. meretrix, with afull-length cDNA of1854bp, which encoded390amino acids. This gene showed thehighest homology with CDK10in mammals, so it was named MmeCDK10. Directsequencing of this gene detected five exon SNPs and five intron SNPs, from whichfour exon SNPs (mmCDKe-1, mmCDKe-3, mmCDKe-4and mmCDKe-5) and oneintron SNP (mmCDKi-1) were found to be significantly associated with growth traits(P <0.05), by a marker-trait association analysis between two populations withsignificant difference in growt, which suggested that MmeCDK10was involved in thegrowth of this clam.
引文
Aho T, Ronn J, Piironen J, et al. Impacts of effective population size on geneticdiversity in hatchery reared Brown trout (Salmo trutta L.) populations.Aquaculture,2006,253:244-248
Allen SK Jr, Bushek D. Large-scale production of triploid oysters Crassostreavirglniea (Gmelin) using “stripped” gametes. Aquaculture,1992,103:241-251
Appleyard SA, Ward RD. Genetic diversity and effective population size in massselection lines of Pacific oyster (Crassostrea gigas). Aquaculture,2006,254:148-159
Araneda C, Lam N, Díaz N, et al. Identification, development, and characterization ofthree molecular markers associated to spawning date in Coho salmon(Oncorhynchus kisutch). Aquaculture,2009,296:21-26
Araneda C, Neira R, Iturra P. Identification of a dominant SCAR marker associatedwith colour traits in Coho salmon (Oncorhynchus kisutch). Aquaculture,2005,247:67-73
Ashley MV, Dow BD. The use of microsatellite analysis in population biology:background, methods and potential applications. In: Schierwater B, Wagner GP,DeSalle R (eds) Molecular ecology and evolution: approaches and applications.Birkhauser Verlag, Basel, Switzerland,1994,185-201
Bakos J, Gorda S. Genetic improvement of common carp strains using intraspecifichybridization. Aquaculture,1995,129:183-186
Baranski M, Loughnan S, Austin CM, et al. A microsatellite linkage map of theblacklip abalone, Haliotis rubra. Anim Genet,2006,37:563-570
Bardon A, Vandeputte M, Dupont-Nive M, et al. What is the heritable component ofspinal deformities in the European sea bass (Dicentrarchus labrax)? Aquaculture,2009,294(3-4):194-201
Bashirullah A, Cooperstock RL, Lipshitz HD. Spatial and temporal control ofRNAstability. Proc Natl Acad Sci USA,2001,98:7025-7028
Beardmore JA, Mair GC, Lewis RI. Biodiversity in aquatic systems in relation toaquaculture. Aquac Res,1997,28:829-839
Beattie JH, Chew KK, Hershberger WK. Differential survival of selected strains ofPacific oysters (Crassostrea gigas) during summertime mortality. Proc NatlShellfish Assoc,1980,70:184-189
Beattie JH, Perdue J, Hershberger W, et al. Effects of inbreeding on growth in thePacific oyster (Crassostrea gigas). J Shellfish Res,1987,6:25-28
Beaumont AR, Beveridge CM, Budd MD. Selection and heterozygosity within singlefamilies of mussel Mytilus edulis L. Mar Biol Lett,1984,4:151-161
Beaumont AR, Budd MD. Effects of self-fertilization and other factors on the earlydevelopment of the scallop Pecten maximus. Mar Biol,1983,76:285-289
Beaumont AR, Hoare K. Biotechnology and genetics in fisheries and aquaculture.Blackwell, Langdon, UK,2003
Bentsen HB, Eknath AE, Palada-de Vera MS, et al. Genetic improvement of farmedtilapias: growth performances in a complete diallel cross experiment with eightstrains of Oreochromis niloticus. Aquaculture,1998,160:145-173
Bernatchez L, Duchesne P. Individual-based genotype analysis in studies of parentageand population assignment: how many loci, how many alleles? Can J Fish AquatSci,2000,57:1-12
Bhateria S, Sood SP, Pathania A. Genetic analysis of quantitative traits acrossenvironments in linseed (Linum usitatissimum L.). Euphytica,2006,150:85-194
Bierne N, Launey S, Naciri-Graven Y, et al. Early effect of inbreeding as revealed bymicrosatellite analysis on Ostrea edulis larvae. Genetics,1998,148:1893-1906
Bionaz M, Loor JJ. ACSL1, AGPAT6, FABP3, LPIN1, and SLC27A6are the mostabundant isoforms in bovine mammary tissue and their expression is affected bystage of lactation. J Nutr,2008,138(6):1019-1024
Birkhead TR, Moller AP. Sperm Competition and Sexual Selection. Academic Press,London,1998
Black PN, Zhang Q, Weimar JD, et al. Mutational analysis of a fatty acyl-coenzyme Asynthetase signature motif identifies seven amino acid residues that modulatefatty acid substrate specificity. J Biol Chem,1997,272(8):4896-4903
Borrell YJ, álvarez J, Vázquez E, et al. Applying microsatellites to the managementof farmed turbot stocks (Scophthalmus maximus L.) in hatcheries. Aquaculture,2004,241:133-150
Borrell YJ, Blanco G, Vázquez E, et al. Assessing the spawning season in commondentex (Dentex dentex) using microsatellites. Aquac Res,2008,39(12):1258-1267
Bosworth BG, Wolters WR, Saxton AM. Analysis of a diallel cross to estimate effectsof crossing on performance of red swamp crawfish, Procambarus clarkii.Aquaculture,1994,121:301-312
Bouchard M, Giannakopoulos S, Wang EH, et al. Hepatitis B virus HBx proteinactivation of cyclin A-cyclin-dependent kinase2complexes and G1transit via aSrc kinase pathway. J virol,2001,75(9):4247-4257
Boudry P, Collet B, Cornette F, et al. High variance in reproductive success of thePacific oyster (Crassostrea gigas, Thunberg) revealed by microsatellite basedparentage analysis of multifactorial crosses. Aquaculture,2002,204:283-296
Brambilla R, Draetta G. Molecular cloning of PISSLRE, a novel putative member ofthe Cdk family of protein serine/threonine kinases. Oncogene,1994,9:3037-3041
Brown RC, Woolliams JA, McAndrew BJ. Factors influencing effective populationsize in commercial populations of gilthead seabream, Sparus aurata. Aquaculture,2005,247:219-225
Bryden CA, Heath JW, Heath DD. Performance and heterosis in farmed and wildChinook salmon (Oncorhynchus tshawytscha) hybrid and purebred crosses.Aquaculture,2004,235:249-261
Bucklin KA. Analysis of the genetic basis of inbreeding depression in the Pacificoyster Crassostrea gigas. PhD dissertation, University of California Davis, Davis,CA, USA,2002,140
Capon F, Allen MH, Ameen M, et al. A synonymous SNP of the corneodesmosingene leads to increased mRNA stability and demonstrates association withpsoriasis across diverse ethnic groups. Hum Mol Genet,2004,13:2361-2368
Caskey CT, Pizzuti A, Hu Y-H, et al. Triplet repeat mutations in humandisease. Science,1992,256:784-789
Chanley PE. Inheritance of shell marking and growth in the hard clam, Mercenariamercenaria. Proc Natl Shellfish Assoc,1961,50:163-169
Charlesworth D, Charlesworth B. Inbreeding depression and its evolutionaryconsequences. Annu Rev Ecol Syst,1987,18:237-268
Chatterjee S, Pal JK. Role of5’-and3’-untranslated regions of mRNAs in humandiseases. Biol Cell,2009,101:251-62
Chaudhary RC. Introduction to plant breeding. New Delhi-Bombay, Oxford and IBHpublishing Co Pvt Ltd,1982
Chen R, Davydov EV, Sirota M, et al. Non-Synonymous and synonymous codingSNPs show similar likelihood and effect size of human disease association. PLoSONE,2010,5(10): e13574
Cheng TC, Xia QY, Qian JF, et al. Mining single nucleotide polymorphisms from ESTdata of silkworm, Bombyxmori, inbred strain Dazao. Insect Biochem Mol Biol,2004,34:523-530
Chiu HC, Kovacs A, Ford DA, et al. A novel mouse model of lipotoxiccardiomyopathy. J Clin Invest,2001,107(7):813-812
Coleman RA, Lewin TM, Muoio DM. Physiological and nutritional regulation ofenzymes of triacylglycerol synthesis. Annu Rev Nutr,2000,20:77-103
Conne B, Stutz A, Vassalli JD. The3’untranslated region of messenger RNA: amolecular ‘hotspot’ for pathology? Nat Med,2000,6:637-641
Coque M, Gallais A. Genomic regions involved in response to grain yield selection athigh and low nitrogen fertilization in maize. Theor Appl Genet,2006,112:1205-1220
Crawford AM, Dodds KG, Ede AJ, et al. An autosomal genetic linkage map of sheepgenome. Genetics,1995,140:730-724
Crenshaw JW, Heffernan PB, Walker RL. Heritability of growth rate in the southernBay scallop, Argopecte nirradians concentricus. J Shellfish Res,1991(10):55-63
Crow JF. Alternative hypotheses of hybrid vigor. Genetics,1948,33(5):477-487
Crow JF. Dominance and overdominance. In: Gowen JW (ed.) Heterosis. Iowa StateCollege Press, Ames, IA, USA,1952,282-294
Cruz P, Ibarra AM. Larval growth and survival of two catarina scallop (Argopectencircularis, Sowerby,1835) populations and their reciprocal crosses. J Exp MarBiol Ecol,1997,212:95-110
Dai P, Wang HX, Liu BZ. Assessment of parental contribution and effectivepopulation size from a3×3diallel cross of clam Meretrix meretrix. Chin JOceanol Limnol,2014,32(2):306-315
Darvasi A, Soller M. Selective genotyping for determination of linkage between amarker locus and a quantitative trait locus. Theor Appl Genet,1992,85:353-359
Darvasi A, Soller M. Selective DNA pooling for determination of linkage between amolecular marker and a quantitative trait locus. Genetics,1994,138:1365-1373
Davenport CB. Degeneration, albinism and inbreeding. Science,1908,28:454-455
de Jone H, Neal AC, Coleman RA. Ontogeny of mRNA expression and activity oflong-chain acyl-CoA synthetase (ACSL) isoforms in Mus musculus heart.Biochim Biophys Acta,2007,1771(1):75-82
Deng YW, Liu X, Zhang GF, et al. Heterosis and combining ability: a diallel cross ofthree geographically isolated populations of Pacific abalone Haliotis discushannai Ino. Chin J Oceanol Limnol,2010,28(6):1195-1199
Deshpande A, Sicinski P, Hinds PW. Cyclins and CDKs in development and cancer:a perspective. Oncogene,2005,24:2909-2915
Dupont-Nivet M, Vandeputte M, Haffray P, et al. Effect of different mating designs oninbreeding, genetic variance and response to selection when applying individualselection in fish breeding programs. Aquaculture,2006,252(2-4):161-170
East EM. Inbreeding in corn. Rep Conn Agric Exp Stn,1908,14:419-428
Eknath AE, Bentsen HB, Ponzoni RW, et al. Genetic improvement of farmed tilapias:composition and genetic parameters of a synthetic base population ofOreochromis niloticus for selective breeding. Aquaculture,2007,273:1-14
Eknath AE, Doyle RW. Effective population size and rate of inbreeding in aquacultureof Indian major carps. Aquaculture,1990,85:293-305
Ellegren H. Microsatellites: simple sequences with complex evolution. Nat Rev Genet,2004,5:435-445
Evans B, Bartlett J, Sweijd N, et al. Loss of genetic variation at microsatellite loci inhatchery produced abalone in Australia (Haliotis rubra) and South Africa(Haliotis midae). Aquaculture,2004,233:109-127
Evans S, Langdon C. Effects of genotype×environment interactions on the selectionof broadly adapted Pacific oysters (Crassostrea gigas). Aquaculture,2006,261(2):522-534
Falconer DS. Patterns of response in selection experiments with mice. Cold SpringHarbor Symp Quant Biol,1955(20):178-196
Falconer DS, Mackay TFC. Introduction to quantitative genetics. Longman GroupLimited, UK,1996,236-244
Fairbrother JE. Viable gynogenetic diploid Mytilus edulis (Linnaeue) larvae producedby ultraviolet light irradiation and cytochalasin B shock. Aquaculture,1994,126:25-34
Felip A, Young W, Wheeler P, et al. An AFLP-based approach for the identificationof sex-linked markers in rainbow trout (Oncorhynchus mykiss). Aquaculture,2005,247:35-43
Fjalestad KT. Breeding strategies. In: Gjedrem T (Ed.) Selection and BreedingPrograms in Aquaculture. The Netherlands, Springer,2005,145-158
Frankham R. Effective population size/adult population size ratios in wildlife: areview. Genet Res,1995,66:95-107
Frazer KA, Ballinger DG, Cox DR, et al. A second gene ration human haplotype mapof over3.1million SNPs. Nature,2007,449:851-861
Fujino T, Kang MJ, Suzuki H, et al. Molecular characterization and expression of ratacyl-CoA synthetase3. J Biol Chem,1996,271(28):16748-16752
Gaffney PM, Davis CV, Hawes RO. Assessment of drift and selection in hatcherypopulations of oysters (Crassostrea virginica). Aquaculture,1992,105:1-20
Gao XG, He CB, Liu H, et al. Intracellular Cu/Zn superoxide dismutase (Cu/Zn-SOD)from hard clam Meretrix meretrix: its cDNA cloning, mRNA expression andenzyme activity. Mol Biol Rep,2012,39:10713-10722
Gjerde B, Gjoen HM, Villanueva B. Optimum designs for fish breeding programmeswith constrained inbreeding Mass selection for a normally distributed trait.Livest Prod Sci,1996,47(1):59-72
Gjerde B, Reddy PVGK, Mahapatra KD, et al. Growth and survival in two completediallel crosses with five stocks of Rohu carp (Labeo rohita). Aquaculture,2002,209:103-115
Gjerde B, Refstie T. Complete diallel cross between five strains of Atlantic salmon.Livest Prod Sci,1984,11:207-226
Goudet J. Fstat version1.2: a computer program to calculate F-statistics. J Hered,1995,86:485-486
Grana X, Claudio PP, De Luca A, et al. PISSLRE, a human novel CDC-2relatedprotein kinase. Oncogene,1994,9:2097-2013
Guo X, Allen SK Jr. Sex determination and polyploid gigantism in the dwarf surfclam(Mulinia lateralis Say). Genetics,1994,138:1199-1206
Guo X, Hershberger WK, Cooper K, et al. Artificial gynogenesis with ultravioletlight-irradiated sperm in the Pacific oyster, Crassostrea gigas. I. Induction andsurvival. Aquaculture,1993,113:201-214
Hadley NH, Dillon RT, Manzi JJ. Realized heritability of growth rate in the hard clamMercenaria mercenaria. Aquaculture,1991(93):109-119
Hara M, Kikuchi S. Increasing the growth rate of abalone, Haliotis discus hannai,using selection techniques. NOAA Tech Rep NMFS,1992,106:21-26
Haskins HH, Ford SE. Characteristics of inbred oyster strains selected for resistanceto Haplosporidium nelsoni (MSX). J Shellfish Res,1988,7:162
Hayes B, Laerdahl JK, Lien S, et al. An extensive resource of single nucleotidepolymorphism markers associated with Atlantic salmon (Salmo salar) expressedsequences. Aquaculture,2007,265:82-90
Heath WA. Development in shellfish culture in British Columbia. Annual Meeting ofNational Shellfish Association,1995,14:228
Hedgecock D. Does variance in reproductive success limit effective population sizesof marine organisms? In: Beaumont AR (ed.) Genetics and evolution of aquaticorganisms. Chapman and Hall, London, UK,1994,122-134
Hedgecock D, Chow V, Waples RS. Effective population numbers of shellfishbroodstocks estimated from temporal variance in allelic frequencies. Aquaculture,1992,108:215-232
Hedgecock D, Cooper K, Hershberger W. Genetic and environmental components ofvariance in harvest body size among pedigreed Pacific oyster Crassostrea gigasfrom controlled crosses. J Shellfish Res,1991,10(2):516
Hedgecock D, Davis JP. Heterosis for yield and crossbreeding of the Pacific oysterCrassostrea gigas. Aquaculture,2007,272(S1):17-29
Hedgecock D, MaGoldrick DJ, Bayne BL. Hybird vigor in Pacific oyster: anexperimental approach using crosses among inbred lines. Aquaculture,1995,137:285-298
Hedgecock D, MaGoldrick DJ, Manahan DT. Quantitative and molecular geneticanalysis of heterosis in bivalve mollusks. J Exp Mar Biol Ecol,1996,203:49-59
Hedgecock D, Sly F. Genetic drift and effective population sizes ofhatchery-propagated stocks of the Pacific oyster, Crassostrea gigas. Aquaculture,1990,88:21-38
Herbinger CM, O'Reilly PT, Verspoor E. Unraveling first-generation pedigrees inwild endangered salmon populations using molecular genetic markers. Mol Ecol,2006,15:2261-2275
Herlin M, Delghandi M, Wesmajervi M, et al. Analysis of the parental contribution toa group of fry from a single day of spawning from a commercial Atlantic cod(Gadus morhua) breeding tank. Aquaculture,2008,274:218-224
Hirschhorn JN, Daly MJ. Genome-wide association studies for common diseases andcomplex traits. Nat Rev Genet,2005,6(2):95-108
Huan P, Wang HX, Liu BZ. Transcriptomic analysis of the clam Meretrix meretrix ondifferent larval stages. Mar Biotechnol,2012,14:69-78
Hubert S, Hedgecock D. Linkage maps of microsatellite DNA markers for the Pacificoyster Crassostrea gigas. Genetics,2004,168:351-362
Hulata G. A review of genetic improvement of the common carp (Cyprinus carpio L.)and other cyprinids by crossbreeding, hybridization and selection. Aquaculture,1995,129:143-155
Hull J, Campino S, Rowlands K, et al. Identification of common genetic variation thatmodulates alternative splicing. PLoS Genet,2007,3:1009-1018
Hunt R, Sauna ZE, Ambudkar SV, et al. Silent (synonymous) SNPs: should we careabout them? Methods Mol Biol,2009,578:23-39
Huvet A, Balabaud K, Bierne N, et al. Microsatellite analysis of6-hour-old embryosreveals no preferential intraspecific fertilization between cupped oystersCrassostrea gigas and Crassostrea angulata. Mar Biotechnol,2001,3:448-453
Ibarra AM, Cruz P, Romero BA. Effects of inbreeding on growth and survival ofself-fertilized catarina scallop larvae, Argopecten circularis. Aquaculture,1995,134:37-47
Innes DJ, Hadley LE. Genetic aspects of larval growth under reduced salinity inMytilus edulis. Bio Bull,1977,153:312-321
Jackson TR, Martin-Robichaud DJ, Reith ME. Application of DNA markers to themanagement of Atlantic halibut (Hippoglossus hippoglossus) broodstock.Aquaculture,2003,220:245-259
Kalinowski ST, Taper ML, Marshall TC. Revising how the computer programCERVUS accommodates genotyping error increases success in paternityassignment. Mol Ecol,2007,16:1099-1106
Kang MJ, Fujino T, Sasano H, et al. A novel arachidonate-preferring acyl-CoAsynthetase is present in steroidogenic cells of the rat adrenal, ovary, and testis.Proc Natl Acad Sci USA,1997,94(7):2880-2884
Kasten M, Giordano A. Cdk10, a Cdc2-related kinase, associates with the Ets2transcription factor and modulates its transactivation activity. Oncogene,2001,20:1832-1838
Keightley PD, Bulfield G. Detection of quantitative trait loci from frequency changesof marker alleles under selection. Genet Res,1993,62:195-203
Keller LF, Waller DM. Inbreeding effects in wild populations. Trends Ecol Evol,2002,17:230-241
Khandker KI. Association analyses of SNPs in candidate genes with body fatdeposition and carcass merit traits in beef cattle. MS thesis, University of Alberta,Alberta, Canada,2009
Kim JH, Lewin TM, Coleman RA. Expression and characterization of recombinant ratAcyl-CoA synthetases1,4, and5(Selective inhibition by triacsin C andthiazolidinediones). J Biol Chem,2001,276(27):24667-24673
Kim SG, Morishima K, Satoh N, et al. Parentage assignment in hatchery populationof brown sole Pleuronectes herzensteini by microsatellite DNA markers. Fish Sci,2007,73:1087-1093
Kimchi-Sarfaty C, Oh JM, Kim IW, et al. A ‘‘silent’’ polymorphism in the MDR1gene changes substrate specificity. Science,2007,315:525-528
Kuang GQ, Lu SQ, Zheng SM. Isolation and evaluation of18microsatellite markersin Siniperca chuatsi (Basilewsky). Mol Ecol Resour,2009,9:1473-1475
Kuersten S, Goodwin EB. The power of the3’ UTR: translational control anddevelopment. Nat Rev Genet,2003,4:626-637
Kwok PY. Single nucleotide polymorphisms: methods and protocols. Humana Press,Totowa,2003
Lallias D, Lapègue S, Hecquet C, et al. AFLP-based genetic linkage maps of the bluemussel (Mytilus edulis). Anim Genet,2007,38(4):340-349
Lallias D, Taris N, Boudry P, et al. Variance in the reproductive success of flat oysterOstrea edulis L. assessed by parentage analyses in natural and experimentalconditions. Genet Res Camb,2010,92:175-187
Lambreghts R, Shi M, Belden WJ, et al. A high-density single nucleotidepolymorphism map for Neurospora crassa. Genetics,2009,181:767-781
Lamkey KR, Edwards JW. The quantitative genetics of heterosis. In: Coors JG,Pandey S (eds) Proceedings of the International Symposium on the Genetics andExploitation of Heterosis in Crops. Mexico City, Mexico,1999,31-48
Lande R, Barrowclough GF. Effective population size, genetic variation, and their usein population management. In: Soule M (ed.) Viable Populations forConservation. Cambridge University Press, Cambridge, UK.1987,87-124
Langdon C, Evans F, Jacobson D, et al. Yields of cultured Pacific oysters Crassostreagigas Thunberg improved after one generation of selection. Aquaculture,2003,220:227-244
Lannan JE. Broodstock management of Crassostrea gigas. IV. Inbreeding and larvalsurvival. Aquaculture,1980,21:353-356
Lee MA, Keane OM, Glass BC, et al. Establishment of a pipeline to analysenon-synonymous SNPs in Bos taurus. BMC Genomics,2006,7:298
Lee MG, Nurse P. Complementation used to clone a human homologue of the fissionyeast cell cycle control gene cdc2. Nature,1987,327:31-35
Leighton DL, Lewis CA. Experimental hybridization in abalones. Int J InvertebrReprod,1982,5(5):273-282
Lemay MA, Boulding EG. Microsatellite pedigree analysis reveals high variance inreproductive success andreduced genetic diversity in hatchery-spawned northernabalone. Aquaculture,2009,295:22-29
Leonard JL. Sexual selection: lessons from hermaphrodite mating systems. IntegrComp Biol,2006,46:349-367
Levin L, Cheng HH, Baxter-jones C, et al. Turkey microsatellite DNA lociamplified by chicken-specific primers. Anim Genet,1995,26:107-110
Li HJ, Zhu D, Gao XG, et al. Mining single nucleotide polymorphisms from EST dataof hard clam Meretrix meretrix. Conserv Genet Res,2010a,2(S1):69-72
Li JL, Wang GL, Bai ZY. Genetic variability in four wild and two farmed stocks ofthe Chinese freshwater pearl mussel (Hyriopsis cumingii) estimated bymicrosatellite DNA markers. Aquaculture,2009c,287:286-291
Li L, Guo X M. A primary linkage map for the Pacific oyster Crassostrea gigas withAFLP markrs. J Shellfish Res,2002,21(1):433
Li L, Xiang JH, Liu X, et al. Construction of AFLP-based genetic linkage map forzhikong scallop, Chlamys farreri Jones et Preston and mapping of sex-linkedmarkers. Aquaculture,2005,245:63-73.
Li LO, Klett EL, Coleman RA. Acyl-CoA synthesis, lipid metabolism and lipotoxicity.Biochim Biophys Acta,2010b,1801(3):246-251
Li Q, Kijima A. Segregation of microsatellite alleles in gynogenetic diploid Pacificabalone (Haliotis discus hannai). Mar Biotechnol,2005,7:669-676
Li Q, Nie HT, Kong LF. Microsatellite-centromere mapping in zhikong scallop(Chlamys farreri) through half-tetrad analysis in D-shaped larvae of gynogeneticdiploid families. Aquaculture,2009a,293:29-34
Li Q, Park C, Endo T, et al. Loss of genetic variation at microsatellite loci in hatcherystrains of the Pacific abalone. Aquaculture,2004,23:207-222
Li RH, Li Q, Kong LF. Characterization of expressed sequence tag-derivedsingle-nucleotide polymorphisms in the bay scallop Argopecten irradiansirradians. Fish Sci,2009b,75(6):1389-1400
Li WH, Dan G. Fundamentals of Molecular Evolution. Sinauer Associates,Sunderland, Massachusetts, USA,1991
Liu BZ, Dong B, Tang BJ, et al. Effect of stocking density on growth, settlement andsurvival of clam larvae, Meretrix meretrix. Aquaculture,2006,258:344-9
Liu CZ, Wang X, Xiang JH, et al. EST-derived SNP discovery and selective pressureanalysis in Pacific white shrimp (Litopenaeus vannamei). Chin J Oceanol Limnol,2012,30:713-723
Liu XD, Liu X, Gao QK, et al. A preliminary genetic linkage map of the Pacificabalone Haliotis discus hannai Ino. Mar Biotechnol,2006,8(4):386-397
Livak KJ, Schmittgen TD. Analysis of relative gene expression data using realtimequantitative PCR and the2(T)(-Delta Delta C) method. Methods,2001,25:402-408
Longwell AC, Stiles S. Gamete cross incompatibility and inbreeding in thecommercial oyster, Crassostrea virginica Gmelin. Cytologia,1973,38:521-533
Lu X, Wang HX, Dai P, et al. Characterization of EST-SSR and genomic-SSRmarkers in the clam, Meretrix meretrix. Conservation Genet Resour,2011a,3:655-658
Lu X, Wang HX, Liu BZ, et al. An effective method for parentage determination ofthe clam (Meretrix meretrix) based on SSR and COI markers. Aquaculture,2011b,318:223-228
Lu X, Wang HX, Liu BZ, et al. Microsatellite-based genetic and growth analysis for adiallel mating design of two stocks of the clam, Meretrix meretrix. Aquac Res,2012,43(2):260-270
Lu X, Wang HX, Liu BZ, et al. Three EST-SSR markers associated with QTL for thegrowth of the clam Meretrix meretrix revealed by selective genotyping. MarBiotechnol,2013,15:16-25
Luttikhuizen PC, Drent J. Inheritance of predominantly hidden shell colours inMacoma balthica (L.)(Bivalvia: Tellinidae). J Mollus Stud,2008(74):363-371
Lynch M, Ritland K. Estimation of pairwise relatedness with molecular markers.Genetics,1999,152:1753-1766
MacAvoy ES, Wood AR, Gardner PA. Development and evaluation of microsatellitemarkers for identification of individual Greenshell mussels (Perna canaliculus)in a selective breeding programme. Aquaculture,2008,274:41-48
MacLachlan TK, Sang N, Giordano A. Cyclins, cyclin-dependent kinases and cdkinhibitors: implications in cell cycle control and cancer. Crit Rev Eukaryot GeneExpr,1995,5(2):127-156
Mallet AL, Freeman KR, Dickie LM. The genetics of production characters in theblue mussel Mytilus edulis. I. A preliminary analysis. Aquaculture,1986,57(1-4):133-140
Marszalek JR, Kitidis C, Dirusso CC, et al. Long-chain acyl-CoA synthetase6preferentially promotes DHA metabolism. J Biol Chem,2005,280(11):10817-10826
Martin AG, Gerand A, Cochennec N, et al. Selecting flat oyster, Ostrea edulis, forsurvival against the parasite bonamia odtreae: assessment of the resistance of afirst selected generation. In Production, Enviroment and Quality, BordeauxAquaculture’92, Ghent Belgium, Euro Aquac Soc Spec Publ,1992,18:547-554
Mashek DG, Li LO, Coleman RA. Rat long chain acyl-CoA synthetase mRNA,protein and activity vary in tissue distribution and in response to diet. J Lipid Res,2006b,47(9):2004-2010
Mashek DG, McKenzie MA, van Horn CG, et al. Rat long chain acyl-CoA synthetase5increases fatty acid uptake and partitioning to cellular triacylglycerol inMcArdle-RH7777cells. J Biol Chem,2006a,281(2):945-950
Mcgoldrick DJ, Hedgecock D. Fixation, segregation and linkage of allozyme loci ininbred families of the pacific oyster Crassostrea gigas (Thunberg): implicationsfor the causes of inbreeding depression. Genetics,1997,146:321-334
McGoldrick DJ, Hedgecock D, English LJ, et al. The transmission of microsatellitealleles in Australian and north American stocks of the Pacific oyster (Crassostreagigas): selection and null alleles. J Shell Res,2000,19:779-788
Metzker ML. Sequencing technologies–the next generation. Nat Rev Genet,2010,11:31-46
Meuwissen THE, Hayes BJ, Goddard ME. Prediction of total genetic value usinggenome-wide dense marker maps. Genetics,2001,157(4):1819-1829
Miglior F, Burnside EB, Dekkers JC. Nonadditive genetic effects and inbreedingdepression for somatic cell counts of Holstein cattle. J Dairy Sci,1995,78:1168-1173
Moen T, Hayes B, Nilsen F, et al. Identification and characterisation of novel SNPmarkers in Atlantic cod: evidence for directional selection. BMC Genet,2008,9:18
Morgan DO. Cyclin-dependent kinases: engines, clocks, and microprocessors. AnnuRev Cell Dev Biol,1997,13:261-291
Naiki T, Nagaki M, Shidoji Y, et al. Analysis of gene expression profile induced byhepatocyte nuclear factor4alpha in hepatoma cells using an oligonucleotidemicroarray. J Biol Chem,2002,277(16):14011-14019
Newkirk GF. Interaction of genotype and salinity in larvae of the oyster Crassostreavirginica. Mar Biol,1978,48:227-234
Newkirk GF, Haley LE. Selection for growth rate in the European oyster, Ostreaedulis: response of second generation groups. Aquaculture,1983,33:149-155
Nguyen MT, Barnes AC, Mather PB, et al. Single nucleotide polymorphisms in theactin and crustacean hyperglycemic hormone genes and their correlation withindividual growth performance in giant freshwater prawn Macrobrachiumrosenbergii. Aquaculture,2010,301:7-15
Nie Q, Yue X, Chai XL, et al. Three vibrio-resistance related EST-SSR markersrevealed by selective genotyping in the clam Meretrix meretrix. Fish ShellfishImmunol,2013,35(2):421-8
Norris AT, Bradley DG, Cunningham EP. Parentage and relatedness determination infarmed Atlantic salmon (Salmo salar) using microsatellite markers. Aquaculture,2000,182:73-83
Oikawa E, Iijima H, Suzuki T, et al. A novel acyl-CoA synthetase, ACS5, expressed inintestinal epithelial cells and proliferating preadipocytes. J Biochem,1998,124(3):679-685
Orba Y, Sunden Y, Suzuki T, et al. Pharmacological cdk inhibitor R-Roscovitinesuppresses JC virus proliferation. Virology,2008,370(1):173-183
Pagani F, Baralle FE. Genomic variants in exons and introns: identifying the splicingspoilers. Nat Rev Genet,2004,5:389-396
Pan Y, Li Q, Yu R, et al. Induction of gynogenesis and effects of ultravioletirradiation on ultrastructure of sperm of the Zhikong scallop Chlamys farreri.Fisheries Sci,2004,70:487-496
Parkes HA, Preston E, Wilks D, et al. Overexpression of acyl-CoA synthetase-1increases lipid deposition in hepatic (HepG2) cells and rodent liver in vivo. Am JPhysiol Endocrinol Metab,2006,291(4): E737-44
Paynter KT, Dimichele L. Growth of tray-cultured oysters (Crassostrea virginicaGmelin) in Chesa-peake Bay. Aquaculture,1990,87:289-297
Pemberton JM, Slate J, Bancroft DR, et al. Nonamplifying alleles at microsatelliteloci: a caution for parentage and population studies. Mol Ecol,1995,4:249-252
Ponomarenko JV, Orlova GV, Merkulova TI, et al. rSNP_Guide: an integrateddatabase-tools system for studying SNPs and site-directed mutations intranscription factor binding sites. Hum Mutat,2002,20:239-248
Ponzoni RW, Hamzah A, Tan S, et al. Genetic parameters and response to selectionfor live weight in the GIFT strain of Nile tilapia (Oreochromis niloticus).Aquaculture,2005,247:203-210
Porta J, Porta JM, Martinez-Rodriguez G, et al. Development of a microsatellitemultiplex PCR for Senegalese sole (Solea senegalensis) and its application tobroodstock management. Aquaculture,2006,256:159-166
Quinlan AR, Stewart DA, Stromberg MP, et al. Pyrobayes: an improved base callerfor SNP discovery in pyrosequences. Nat Methods,2008,5:179-181
Quinton C, McMillan I, Glebe BD. Development of an Atlantic salmon (Salmo salar)genetic improvement program: Genetic parameters of harvest body weight andcarcass quality traits estimated with animal models. Aquaculture,2005,247:211-217
Rawson PD, Hilbish TJ. Heritability of juvenile growth for the hard clam Mercenariamercenaria. Mar Biol,1990,105(3):429-436
Rawson PD, Hilbish TJ. Genotype-environment interaction for juvenile growth in thehard clam Mercenaria mercenaria. Evolution,1991,45(8):1924-1935
Raymond M, Rousset F. GENEPOP Version1.2: population genetics software forexact tests and ecumenicism. Heredity,1995,86:248-249
Reece KS, Ribeiro WL, Gaffney PM, et al. Microsatellite marker development andanalysis in the eastern oyster (crassostrea virginica): confirmation of null allelesand non-mendelian segregation ratios. Heredity,2004,95:346-352
Ritland K. Estimators for pairwise relatedness and individual inbreeding coefficients.Genetics,1996,67:175-185
Rousset F, Raymond M. Testing heterozygote excess and deficiency. Genetics,1995,140:1413-1419
Saavedra C. Low effective sizes in hatchery populations of the European Oyster(Ostrea edulis): implications for the management of genetic resources. J ShellfishRes,1997,16:441-446
Salem M, Vallejo RL, Leeds TD, et al. RNA-Seq identifies SNP markers for growthtraits in Rainbow Trout. PLoS ONE,2012,7: e36264
Sauvage C, Bierne N, Lapegue S, et al. Single nucleotide polymorphisms and theirrelationship to codon usage bias in the Pacific oyster Crassostrea gigas. Gene,2007,406(1-2):13-22
Sbordoni V, De Matthaeis E, Cobolli Sbordoni M, et al. Bottleneck effects and thedepression of genetic variability in hatchery stocks of Penaeus japonicus(Crustacea, Decapoda). Aquaculture,1986,57:239-251
Scarpa J, Komaru A, Wada KT. Gynogenetic induction in the mussel, Mytilusgalloprovincialis. Bull Natl Res Inst Aquac,1994,23:33-41
Schlotterrer C, Amos W, Tautz D. Conservation of polymorphic simple sequence lociin cetacean species. Nature,1991,354:63-65
Seeb JE, Carvalho G, Hauser L, et al. Single-nucleotide polymorphism (SNP)discovery and applications of SNP genotyping in non-model organisms. Mol EcolResour,2011,11:1-8
Sekino M, Hamaguchi M, Aranishi F. Development of novel microsatellite DNAmarkers from the Pacific oyster Crassostrea gigas. Mar Biotechnol,2003,5:227-233
Sekino M, Hara M. Microsatellite DNA loci in Pacific abalone Haliotis discus discus(Mollusca, Gastropoda, Haliotidae). Mol Ecol Notes,2001,1:8-10
Selvamani MJP, Degnan SM, Degnan BM. Microsatellite genotyping of individualabalone larvae: Parentage assignment in aquaculture. Mar Biotechnol,2001,3:78-485
Sham PC, Cherny SS, Purcell S. Application of genome-wide SNP data foruncovering pairwise relationships and quantitative trait loci. Genetica,2009,136:237-243
Sherrc J, Roberts JM. Living with or without Cyclins and Cyclin-dependent Kinases.Gene Dev,2004,18:2699-2711
Shi YY, He L. SHEsis, a powerful software platform for analyses of linkagedisequilibrium, haplotype construction, and genetic association at polymorphismloci. Cell Res,2005,15:97-98
Shifman S, Bell JT, Copley RR, et al. A high-resolution single nucleotidepolymorphism genetic map of the mouse genome. PLoS Biol,2006,4:2227-2237
Shogo HS, Tomoko H, Atsuko T. Association between fatty acid compositions andgenotypes of FABP4and LXR-alpha in Japanese Black cattle. BMC Genet,2008,11:9:84
Shull GH. The composition of a field of a maize. J Hered,1908,4:296-301
Skinner DM, Beattie WG, Blattner FR, et al. The repeat sequence of a hermit carbsatellite deoxyribonucleic acid is (-T-A-G-G-)n-(-A-T-C-C-)n. Biochemistry,1974,12:3930-3937
Slate J, Gratten J, Beraldi D, et al. Gene mapping in the wild with SNPs: guidelinesand future directions. Genetica,2009,136:97-107
Soller M, Beckmann JS. Marker-based mapping of quantitative trait loci usingreplicated progenies. Theor Appl Genet,1990,80:205-208
Sprague GF, Tatum LA. General vs. specific combining ability in single crosses ofcorn. J Amer Soc Agron,1942,34:923-32
Stanley JG, Allen SK, Hidu H Jr. Polyploidy induced in the American oyster,Crassostrea virginica, with cytochalasin B. Aquaculture,1981,23(124):1-10
Stella A, Boettcher PJ. Optimal designs for linkage disequilibrium mapping andcandidate gene association test in livestock populations. Genetics,2004,166:341-350
Stiles S, Cromanski J, Longwell A. Cytological appraisal of prospects for successfulgynogenesis, parthenogenesis and androgenesis in the oyster. InternationalCouncil for the Exploration of the Sea, Mariculture Committee Paper F,1983,10:1-14
Sugama K, Taniguchi N, Umeda S. An experimental study on genetic drift in hatcherypopulation of red sea bream. Nippon Suisan Gakk,1988,54:734-744
Suzuki H, Kawarabayasi Y, Kondo J, et al. Structure and regulation of rat long-chainacyl-CoA synthetase. J Biol Chem,1990,265:8681-8685
Taniguchi N, Sumantadimata K, Iyama S. Genetic change in the first and secondgenerations of hatchery stock of black sea bream. Aquaculture,1983,35:309-320
Tao WJ, Boulding EG. Associations between single nucleotide polymorphisms incandidate genes and growth rate in Arctic charr (Salvelinus alpinus L.). Heredity,2003,91:60-69
Tautz D. Hypervariability of simple sequence as a general source for polymorphicDNA markers. Nucleic Acid Res,1989,17:6463-6471
Teklewold A, Becker HC. Heterosis and combining ability in a diallel cross ofEthiopian mustard inbred lines. Crop Sci,2005,45:2629-2635
Templeton AR. The theory of speciation via the founder principle. Genetics,1980,94:1011-1038
Tian Y, Kong J, Yang CH. Comparative growth and viability of hybrids between twopopulations of Chinese shrimp (Fenneropenaeus chinensis). Chin Sci Bull,2006,51(19):2369-2374
Toro JE, Newkirk GE. Divergent selection for growth rate in the European oyster(Ostrea edulis): Response to selection and estimation of genetic parameters. MarEcol-Prog Ser,1990,62:219-225
Toth G, Gaspari Z, Jurka J. Microsatellites in different eukaryotic genomes: surveyand analysis. Genome Res,2000,10:967-981
Tsaftaris SA. Molecular aspects of heterosis in crop plants. Physiol Plantarum,1995,94(2):362-370
Wada KT. Genetic selection for shell traits in the Japanese pearl oyster, Pinctadafucata martensii. Aquaculture,1986,57:171-176
Wang C, Chai XL, Wang HX, et al. Growth performance of the clam, Meretrixmeretrix, breeding selection populations cultured in different conditions. ActaOceanol Sin,2013,32(10):82-87
Wang C, Cote J. Heterosis and combining abilities in growth and survival in seascallops along the Atlantic coast of Canada. J Shellfish Res,2012,31(4):1145-1149
Wang C, Wang HX, Li Y. Identification of a fructose-1,6-bisphosphate aldolase geneand association of the single nucleotide polymorphisms with growth traits in theclam Meretrix meretrix. Mol Biol Rep,2012a,39:5017-5024
Wang C, You YN, Wang HX, et al. Genetic diversity of the sulfotransferase-like geneand one nonsynonymous SNP associated with growth traits of clam, Meretrixmeretrix. Mol Biol Rep,2012b,39:1323-1331
Wang HX, Chai XL, Liu BZ. Estimation of genetic parameters for growth traits incultured clam Meretrix meretrix (Bivalvia: Veneridae) using the Bayesian methodbased on Gibbs sampling. Aquac Res,2011a,42:240-247
Wang HX, Huan P, Liu BZ. Mining of EST-SSR markers in clam Meretrixmeretrix larvae from454shotgun transcriptome. Genes Genet Syst,2011b,86:197-205
Wang J, Li ZJ, Lan XY, et al. Two novel SNPs in the coding region of the bovinePRDM16gene and its associations with growth traits. Mol Biol Rep,2010,37:571-577
Wang LL, Song LS, Chang YQ, et al. A preliminary genetic map of zhikong scallop(Chlamys farreri Jones et Preston1904). Aquac Res,2005,36:643-653
Wang SL, Sha ZX, Sonstegard TS, et al. Quality assessment parameters forEST-derived SNPs from catfish. BMC Genomics,2008,9:450
Wang XM, Liu BZ, Xiang JH. Cloning, characterization and expression of ferritinsubunit from clam Meretrix meretrix in different larval stages. Comp BiochemPhys B,2009,154:12-16
Ward RD, English LJ, Mcgoldrick DJ, et al. Genetic improvement of the Pacificoyster Crassostrea gigas (Thunberg) in Australia. Aquac Res,2000,31:35-44
Weber JL. Informativeness of human (dC-dA)n.(dG-dT)n polymorphisms. Genomics,1990,7:524-530
Wedekind C. Manipulating sex ratios for conservation: short-term risks and long-termbenefits. Anim Conserv,2002,5:13-20
Weir BS, Cockerham CC. Estimating F-Statistics for the analysis of populationstructure. Evolution,1984,38:1358-1370
Wilson AJ, Ferguson MM. Molecular pedigree analysis in natural populations offishes: approaches, applications, and practical considerations. Can J Fish AquatSci,2002,59:1696-1707
Winkler FM, Estevez BF. Effects of self-fertilization on growth and survival of larvaeand juveniles of the scallop Argopecten purpuratus L. J Exp Mar Biol Ecol,2003,292(1):93-102
Winkler FM, Estevez BF, Jollan LB, et al. Inheritance of the general shell color in thescallop Argopecten purpuratus (Bivalvia: Pectinidae). J Hered,2001(92):521-525.
Woolfe A, Mullikin JC, Elnitski L. Genomic features defining exonic variants thatmodulate splicing. Genome Biol,2010,11: R20
Wright S. Inbreeding in animals: differentiation and depression. In: Evolutionand the genetics of populations, Vol.3. University of Chicago press,Chicago, USA,1977,44-96
Würschum T, Langer SM, Longin CF, et al. Population structure, genetic diversity andlinkage disequilibrium in elite winter wheat assessed with SNP and SSR markers.Theor Appl Genet,2013,126:1477-1486.
Yu Z, Guo X. Genetic linkage map of the eastern oyster Crassostrea virginica Gmelin.Biol Bull,2003,204:327-338
Yue GH, Ho MY, Orban L, et al. Microsatellites within genes and ESTs ofcommon carp and their applicability in silver crucian carp. Aquaculture,2004,234:85-98.
Yue X, Liu BZ, Xue QG. An i-type lysozyme from the Asiatic hard clam Meretrixmeretrix potentially functioning in host immunity. Fish Shellfish Immunol,2011a,30:550-558
Yue X, Liu BZ, Sun L, et al. Cloning and characterization of a hsp70gene fromAsiatic hard clam Meretrix meretrix which is involved in the immune responseagainst bacterial infection. Fish Shellfish Immunol,2011b,30:791-799
Zhang HB, Liu X, Zhang GF, et al. Growth and survival of reciprocal crosses betweentwo bay scallops, Argopecten irradians concentricus Say and A. irradiansirradians Lanmarck. Aquaculture,2007,272(S1):88-93
Zhang LP, Lin GY, Ni o-Liu D, et al. Mapping QTLs conferring early blight(Alternaria solani) resistance in a Lycopersicon esculentum×L. hirsutum cross byselective genotyping. Mol Breed,2003,12:3-19
Zhang YD, Kang MS. DIALLEL-SAS: A program for Griffing’s diallel method. In:Kang MS (ed.) Handbook of Formulus and Software for Plant Geneticists andBreeder. New York, Food Products Press,2003,1-9
柴雪良,吕振民,方军,等.泥蚶三倍体的诱导研究.浙江海洋学院学报(自然科学版),2002,21(1):16-19
常建波,魏利平,杨建敏,等.文蛤染色体核型及三倍体诱导初步研究.水产学报,1996,20(3):269-274
常亚青,刘小林,相建海,等.栉空扇贝中国种群与日本种群杂交子一代的早期生长发育.水产学报,2002,26(5):385-390
陈大鹏,沈怀舜,丁亚平,等.文蛤(Meretrix meretrix)地理种群ISSR分子标记的初步研究.南京师范大学学报,2004,27(3):74-77
陈淑吟,吉红九,许广平,等.文蛤微卫星DNA的筛选及其特性分析.生物技术通报,2009,12:134-138
陈天国,易华峰,张廷科,等.分子标记与动物遗传育种.畜牧市场,2006,(8):47-51
邓岳文,刘晓,张国范.皱纹盘鲍基因型与环境互作初步研究.海洋科学,2005,29(12):30-33
邓岳文,符韶,杜晓东,等.马氏珠母贝选系F2早期选择反应和现实遗传力估计.广东海洋大学学报,2008,28(4):27-29
郭香.长牡蛎生长相关性状QTL定位与连锁不平衡研究.青岛:中国海洋大学博士学位论文,2013
赫崇波,丛林林,葛陇利,等.文蛤养殖群体和野生群体遗传多样性的AFLP分析.中国水产科学,2008,15(2):215-221
贺艳.美洲牡蛎(Crassostrea virginica)抗病相关基因标记的筛选及应用.青岛:中国海洋大学博士学位论文,2012
蒋逸民,慕永通.中国海水产品产量与结构变动趋势研究.沈阳农业大学学报(社会科学版),2012,14(1):41-44
今井丈夫.浅海完全养殖.日本恒星社厚生阁版,1961
金武,李家乐,付龙龙,等.三角帆蚌早期阶段生长性状遗传参数估计.水产学报,2012,36(8):1209-1214
李宏俊.海湾扇贝微卫星标记的开发及遗传连锁图谱的构建.青岛:中国科学院海洋研究所博士学位论文,2009
李太武,张安国,苏秀榕.文蛤花纹的形态及形成观察.动物学杂,2008,43(6):83-87
李太武,张国安,苏秀榕,等.不同花纹文蛤(Meretrix meretrix)的ITS2分析.海洋与湖沼,2006,37(2):132-136
梁峻,郑怀平,李莉,等.虾夷扇贝养殖群体的遗传力估算.海洋科学,2011,35(3):1-7
林美金.杂交鲍三倍体诱导技术研究.水产科技情报,2013,20(4):169-173
林岳光,姜卫国.三倍体和二倍体合浦珠母贝育珠比较初步研究.热带海洋,1993,12(3):90-94
林志华,董迎辉,李宁,等.基于形态参数和AFLP标记的文蛤(Meretrix meretrix)不同地理群体遗传变异分析.海洋与湖沼,2008,39:245-251
林志华,黄晓婷,董迎辉,等.广西文蛤(Meretrix meretrix)的fAFLP及ITS分析.海洋与湖沼,2009,40(1):33-41
刘博,邵艳卿,滕爽爽,等.乐清湾养殖缢蛏群体遗传结构的微卫星标记分析.中国农学通报,2012,28(2):69-73
刘来福,毛盛贤,黄远樟.作物数量遗传.北京:农业出版社,1984
刘绿叶,刘培廷,汤建华,等.文蛤养殖密度对主要环境因子影响的模拟研究.水产养殖,2007,5:8-11
刘卫东,鲍相渤,宋文涛,等.虾夷扇贝遗传连锁图谱的初步构建遗传.遗传,2009,31(6):629-637
刘晓丹,邱陵,吴乔,等.文蛤抗癌活性多肽的生理活性研究.厦门大学学报(自然科学版),2004,43(4):432-435
楼允东.鱼类育种学.北京:中国农业出版社,2001
卢霞.分子标记应用于文蛤遗传评价、图谱构建及QTL筛选的研究.青岛:中国科学院海洋研究所博士学位论文,2012
南乐红,张金盛,丰玮,等.紫扇贝和墨西哥湾扇贝种间杂交的初步研究.中国农学通报,2012,28(20):131-135
潘洁,包振民,赵洋,等.栉孔扇贝不同地理群体的遗传多样性分析.高技术通讯,2002,12:78-82
秦艳杰.海湾扇贝遗传图谱构建及壳色基因、生长相关QTL的定位研究.青岛:中国科学院海洋研究所博士学位论文,2006
沈怀舜,朱建一,丁亚平,等.我国沿海三个文蛤地理群的RAPD分析.海洋学报,2003,25(5):97-102
宋传文,闫喜武,桑士田,等.紫贻贝生长性状的遗传力估计.水产学报,2013,37(2):201-206
宋林生,李俊强,李红蕾,等.用RAPD技术对我国栉孔扇贝野生种群与养殖群体的遗传结构及其遗传分化的研究.高技术通讯,2002,7:83-86
宋盛亮,李琪,孔令锋,等.长牡蛎生长性状的遗传效应及与环境互作分析.中国海洋大学学报,2013,43(10):41-47
苏秀榕,金春华,李春艳,等.不同花纹文蛤(Meretrix meretrix)的外套膜蛋白质的双向电泳研究.海洋与湖沼,2009,40(6):777-780
唐保军.环境因子和饵料对文蛤能量收支与幼虫生长发育的影响.青岛:中国科学院海洋研究所硕士学位论文,2005
王春德,刘保忠,李继强,等.紫扇贝与海湾扇贝种间杂交的研究.海洋科学,2009,33(10):84-88
汪德耀,刘汉英.牡蛎人工杂交初步研究.动物学报.1959,11(3):283-295
王清印.海水健康养殖的理论与实践.北京:海洋出版社,2003,45-198
王清印,杨爱国.相孔扇贝三倍体研究进展和展望.中国水产科学,2000,7(3):93-96
王如才,王昭萍,田传远,等.我国太平洋牡蛎(Crassostrea gigas)三倍体育苗与养殖技术研究进展.青岛海洋大学学报(自然科学版),2002,32(2):193-200
王昭萍,李赞,王如才,等.三倍体太平洋牡蛎生产性育苗与养成初报.海洋湖沼通报,2000,3:34-39
王子臣,张国范,王一平,等.皱纹盘鲍的三倍体研究.大连水产学报,1990,5(1):1-8
谢玉坎.我国海洋贝类的养殖概况和发展问题.科学种养,2014,2:7-8
许国强,林岳光,李刚,等.人工诱发合浦珠母贝雌核二倍体发生及“Hertwig效应”的初步研究.热带海洋学报,1990,9:1-7
阎冰,邓岳文,杜晓东,等.广西地区文蛤的遗传多样性研究.海洋科学,2002,26(5):5-8
闫喜武,张跃环,霍忠明,等.不同地理群体菲律宾蛤仔的选择反应及现实遗传力.水产学报,2010,34(5):704-710
严正凜,陈建华.三倍体九孔鲍的育种和养成技术研究.水产学报,2002,26(1):54-60
严正凜,陈建华,吴萍茹,等.6-DMAP抑制九孔鲍受精卵第二极体的释放诱导三倍体.台湾海峡,2001,20(1):15-19
严正凜,江宏,李丕廉,等.杂色鲍和九孔鲍三倍体的化学诱导.台湾海峡,1999,18(3):337-342
杨青,李琪,聂鸿涛,等.魁蚶雌核发育的人工诱导.海洋科学,2011,10:11-15
杨青,李琪,于瑞海,等.人工诱导栉江珧雌核发育的初步研究.中国水产科学,2006,13:310-315
姚国兴,宋晓村,于志华,等.环境因子对文蛤幼苗生长的影响.水产养殖,2000(1):17-18
喻达辉,王小玉,黄桂菊,等.合浦珠母贝遗传连锁图谱的构建.中国水产科学,2007,14(3):361-367
张国范.海洋贝类遗传育种研究20年.厦门大学学报(自然科学版),2006,45(S2):190-194
张国范.中国近海栉孔扇贝遗传结构及遗传变异与生长的关系.青岛:中国科学院海洋研究所博士学位论文,1992
张国范,刘述锡,刘晓,等.海湾扇贝自交家系的建立与自交效应.中国水产科学,2003,10(6):441-445
张国范,刘晓.关于贝类遗传改良几个问题的讨论.水产学报,2006,30(1):130-137
张国范,刘晓,阙华勇,等.贝类杂交及杂种优势理论和技术研究进展.海洋科学,2004,28(7):54-60
张国范,王继红,赵洪恩,等.皱纹盘鲍中国群体和日本群体的自交与杂交F1的RAPD标记.海洋与湖沼,2002,33(5):483-491
张玺,谢玉坎.近江牡蛎的养殖.北京:科学出版社,1959
张玉勇,常亚青,宋坚.杂交育种技术在海水养殖贝类中的应用及研究进展.水产科学.2005,24(4):39-41
张月月.铁蛋白在虾夷扇贝新品种“海大金贝”高抗逆性中的作用及机理研究.青岛:中国海洋大学博士学位论文,2013
郑怀平.海湾扇贝两个养殖群体数量性状及壳色遗传研究.青岛:中国科学院海洋研究所博士学位论文,2005
郑康乐,黄宁.标记辅助选择在水稻改良中的应用前景.遗传,1997,19(2):40-44
周延清.遗传标记的发展.生物学通报,2000,35:17-18
庄启谦.中国动物志:软体动物门、双壳纲、帘蛤科.北京:科学出版社,2001,229-236
Allen SK Jr, Bushek D. Large-scale production of triploid oysters Crassostreavirglniea (Gmelin) using “stripped” gametes. Aquaculture,1992,103:241-251
Appleyard SA, Ward RD. Genetic diversity and effective population size in massselection lines of Pacific oyster (Crassostrea gigas). Aquaculture,2006,254:148-159
Araneda C, Lam N, Díaz N, et al. Identification, development, and characterization ofthree molecular markers associated to spawning date in Coho salmon(Oncorhynchus kisutch). Aquaculture,2009,296:21-26
Araneda C, Neira R, Iturra P. Identification of a dominant SCAR marker associatedwith colour traits in Coho salmon (Oncorhynchus kisutch). Aquaculture,2005,247:67-73
Ashley MV, Dow BD. The use of microsatellite analysis in population biology:background, methods and potential applications. In: Schierwater B, Wagner GP,DeSalle R (eds) Molecular ecology and evolution: approaches and applications.Birkhauser Verlag, Basel, Switzerland,1994,185-201
Bakos J, Gorda S. Genetic improvement of common carp strains using intraspecifichybridization. Aquaculture,1995,129:183-186
Baranski M, Loughnan S, Austin CM, et al. A microsatellite linkage map of theblacklip abalone, Haliotis rubra. Anim Genet,2006,37:563-570
Bardon A, Vandeputte M, Dupont-Nive M, et al. What is the heritable component ofspinal deformities in the European sea bass (Dicentrarchus labrax)? Aquaculture,2009,294(3-4):194-201
Bashirullah A, Cooperstock RL, Lipshitz HD. Spatial and temporal control ofRNAstability. Proc Natl Acad Sci USA,2001,98:7025-7028
Beardmore JA, Mair GC, Lewis RI. Biodiversity in aquatic systems in relation toaquaculture. Aquac Res,1997,28:829-839
Beattie JH, Chew KK, Hershberger WK. Differential survival of selected strains ofPacific oysters (Crassostrea gigas) during summertime mortality. Proc NatlShellfish Assoc,1980,70:184-189
Beattie JH, Perdue J, Hershberger W, et al. Effects of inbreeding on growth in thePacific oyster (Crassostrea gigas). J Shellfish Res,1987,6:25-28
Beaumont AR, Beveridge CM, Budd MD. Selection and heterozygosity within singlefamilies of mussel Mytilus edulis L. Mar Biol Lett,1984,4:151-161
Beaumont AR, Budd MD. Effects of self-fertilization and other factors on the earlydevelopment of the scallop Pecten maximus. Mar Biol,1983,76:285-289
Beaumont AR, Hoare K. Biotechnology and genetics in fisheries and aquaculture.Blackwell, Langdon, UK,2003
Bentsen HB, Eknath AE, Palada-de Vera MS, et al. Genetic improvement of farmedtilapias: growth performances in a complete diallel cross experiment with eightstrains of Oreochromis niloticus. Aquaculture,1998,160:145-173
Bernatchez L, Duchesne P. Individual-based genotype analysis in studies of parentageand population assignment: how many loci, how many alleles? Can J Fish AquatSci,2000,57:1-12
Bhateria S, Sood SP, Pathania A. Genetic analysis of quantitative traits acrossenvironments in linseed (Linum usitatissimum L.). Euphytica,2006,150:85-194
Bierne N, Launey S, Naciri-Graven Y, et al. Early effect of inbreeding as revealed bymicrosatellite analysis on Ostrea edulis larvae. Genetics,1998,148:1893-1906
Bionaz M, Loor JJ. ACSL1, AGPAT6, FABP3, LPIN1, and SLC27A6are the mostabundant isoforms in bovine mammary tissue and their expression is affected bystage of lactation. J Nutr,2008,138(6):1019-1024
Birkhead TR, Moller AP. Sperm Competition and Sexual Selection. Academic Press,London,1998
Black PN, Zhang Q, Weimar JD, et al. Mutational analysis of a fatty acyl-coenzyme Asynthetase signature motif identifies seven amino acid residues that modulatefatty acid substrate specificity. J Biol Chem,1997,272(8):4896-4903
Borrell YJ, álvarez J, Vázquez E, et al. Applying microsatellites to the managementof farmed turbot stocks (Scophthalmus maximus L.) in hatcheries. Aquaculture,2004,241:133-150
Borrell YJ, Blanco G, Vázquez E, et al. Assessing the spawning season in commondentex (Dentex dentex) using microsatellites. Aquac Res,2008,39(12):1258-1267
Bosworth BG, Wolters WR, Saxton AM. Analysis of a diallel cross to estimate effectsof crossing on performance of red swamp crawfish, Procambarus clarkii.Aquaculture,1994,121:301-312
Bouchard M, Giannakopoulos S, Wang EH, et al. Hepatitis B virus HBx proteinactivation of cyclin A-cyclin-dependent kinase2complexes and G1transit via aSrc kinase pathway. J virol,2001,75(9):4247-4257
Boudry P, Collet B, Cornette F, et al. High variance in reproductive success of thePacific oyster (Crassostrea gigas, Thunberg) revealed by microsatellite basedparentage analysis of multifactorial crosses. Aquaculture,2002,204:283-296
Brambilla R, Draetta G. Molecular cloning of PISSLRE, a novel putative member ofthe Cdk family of protein serine/threonine kinases. Oncogene,1994,9:3037-3041
Brown RC, Woolliams JA, McAndrew BJ. Factors influencing effective populationsize in commercial populations of gilthead seabream, Sparus aurata. Aquaculture,2005,247:219-225
Bryden CA, Heath JW, Heath DD. Performance and heterosis in farmed and wildChinook salmon (Oncorhynchus tshawytscha) hybrid and purebred crosses.Aquaculture,2004,235:249-261
Bucklin KA. Analysis of the genetic basis of inbreeding depression in the Pacificoyster Crassostrea gigas. PhD dissertation, University of California Davis, Davis,CA, USA,2002,140
Capon F, Allen MH, Ameen M, et al. A synonymous SNP of the corneodesmosingene leads to increased mRNA stability and demonstrates association withpsoriasis across diverse ethnic groups. Hum Mol Genet,2004,13:2361-2368
Caskey CT, Pizzuti A, Hu Y-H, et al. Triplet repeat mutations in humandisease. Science,1992,256:784-789
Chanley PE. Inheritance of shell marking and growth in the hard clam, Mercenariamercenaria. Proc Natl Shellfish Assoc,1961,50:163-169
Charlesworth D, Charlesworth B. Inbreeding depression and its evolutionaryconsequences. Annu Rev Ecol Syst,1987,18:237-268
Chatterjee S, Pal JK. Role of5’-and3’-untranslated regions of mRNAs in humandiseases. Biol Cell,2009,101:251-62
Chaudhary RC. Introduction to plant breeding. New Delhi-Bombay, Oxford and IBHpublishing Co Pvt Ltd,1982
Chen R, Davydov EV, Sirota M, et al. Non-Synonymous and synonymous codingSNPs show similar likelihood and effect size of human disease association. PLoSONE,2010,5(10): e13574
Cheng TC, Xia QY, Qian JF, et al. Mining single nucleotide polymorphisms from ESTdata of silkworm, Bombyxmori, inbred strain Dazao. Insect Biochem Mol Biol,2004,34:523-530
Chiu HC, Kovacs A, Ford DA, et al. A novel mouse model of lipotoxiccardiomyopathy. J Clin Invest,2001,107(7):813-812
Coleman RA, Lewin TM, Muoio DM. Physiological and nutritional regulation ofenzymes of triacylglycerol synthesis. Annu Rev Nutr,2000,20:77-103
Conne B, Stutz A, Vassalli JD. The3’untranslated region of messenger RNA: amolecular ‘hotspot’ for pathology? Nat Med,2000,6:637-641
Coque M, Gallais A. Genomic regions involved in response to grain yield selection athigh and low nitrogen fertilization in maize. Theor Appl Genet,2006,112:1205-1220
Crawford AM, Dodds KG, Ede AJ, et al. An autosomal genetic linkage map of sheepgenome. Genetics,1995,140:730-724
Crenshaw JW, Heffernan PB, Walker RL. Heritability of growth rate in the southernBay scallop, Argopecte nirradians concentricus. J Shellfish Res,1991(10):55-63
Crow JF. Alternative hypotheses of hybrid vigor. Genetics,1948,33(5):477-487
Crow JF. Dominance and overdominance. In: Gowen JW (ed.) Heterosis. Iowa StateCollege Press, Ames, IA, USA,1952,282-294
Cruz P, Ibarra AM. Larval growth and survival of two catarina scallop (Argopectencircularis, Sowerby,1835) populations and their reciprocal crosses. J Exp MarBiol Ecol,1997,212:95-110
Dai P, Wang HX, Liu BZ. Assessment of parental contribution and effectivepopulation size from a3×3diallel cross of clam Meretrix meretrix. Chin JOceanol Limnol,2014,32(2):306-315
Darvasi A, Soller M. Selective genotyping for determination of linkage between amarker locus and a quantitative trait locus. Theor Appl Genet,1992,85:353-359
Darvasi A, Soller M. Selective DNA pooling for determination of linkage between amolecular marker and a quantitative trait locus. Genetics,1994,138:1365-1373
Davenport CB. Degeneration, albinism and inbreeding. Science,1908,28:454-455
de Jone H, Neal AC, Coleman RA. Ontogeny of mRNA expression and activity oflong-chain acyl-CoA synthetase (ACSL) isoforms in Mus musculus heart.Biochim Biophys Acta,2007,1771(1):75-82
Deng YW, Liu X, Zhang GF, et al. Heterosis and combining ability: a diallel cross ofthree geographically isolated populations of Pacific abalone Haliotis discushannai Ino. Chin J Oceanol Limnol,2010,28(6):1195-1199
Deshpande A, Sicinski P, Hinds PW. Cyclins and CDKs in development and cancer:a perspective. Oncogene,2005,24:2909-2915
Dupont-Nivet M, Vandeputte M, Haffray P, et al. Effect of different mating designs oninbreeding, genetic variance and response to selection when applying individualselection in fish breeding programs. Aquaculture,2006,252(2-4):161-170
East EM. Inbreeding in corn. Rep Conn Agric Exp Stn,1908,14:419-428
Eknath AE, Bentsen HB, Ponzoni RW, et al. Genetic improvement of farmed tilapias:composition and genetic parameters of a synthetic base population ofOreochromis niloticus for selective breeding. Aquaculture,2007,273:1-14
Eknath AE, Doyle RW. Effective population size and rate of inbreeding in aquacultureof Indian major carps. Aquaculture,1990,85:293-305
Ellegren H. Microsatellites: simple sequences with complex evolution. Nat Rev Genet,2004,5:435-445
Evans B, Bartlett J, Sweijd N, et al. Loss of genetic variation at microsatellite loci inhatchery produced abalone in Australia (Haliotis rubra) and South Africa(Haliotis midae). Aquaculture,2004,233:109-127
Evans S, Langdon C. Effects of genotype×environment interactions on the selectionof broadly adapted Pacific oysters (Crassostrea gigas). Aquaculture,2006,261(2):522-534
Falconer DS. Patterns of response in selection experiments with mice. Cold SpringHarbor Symp Quant Biol,1955(20):178-196
Falconer DS, Mackay TFC. Introduction to quantitative genetics. Longman GroupLimited, UK,1996,236-244
Fairbrother JE. Viable gynogenetic diploid Mytilus edulis (Linnaeue) larvae producedby ultraviolet light irradiation and cytochalasin B shock. Aquaculture,1994,126:25-34
Felip A, Young W, Wheeler P, et al. An AFLP-based approach for the identificationof sex-linked markers in rainbow trout (Oncorhynchus mykiss). Aquaculture,2005,247:35-43
Fjalestad KT. Breeding strategies. In: Gjedrem T (Ed.) Selection and BreedingPrograms in Aquaculture. The Netherlands, Springer,2005,145-158
Frankham R. Effective population size/adult population size ratios in wildlife: areview. Genet Res,1995,66:95-107
Frazer KA, Ballinger DG, Cox DR, et al. A second gene ration human haplotype mapof over3.1million SNPs. Nature,2007,449:851-861
Fujino T, Kang MJ, Suzuki H, et al. Molecular characterization and expression of ratacyl-CoA synthetase3. J Biol Chem,1996,271(28):16748-16752
Gaffney PM, Davis CV, Hawes RO. Assessment of drift and selection in hatcherypopulations of oysters (Crassostrea virginica). Aquaculture,1992,105:1-20
Gao XG, He CB, Liu H, et al. Intracellular Cu/Zn superoxide dismutase (Cu/Zn-SOD)from hard clam Meretrix meretrix: its cDNA cloning, mRNA expression andenzyme activity. Mol Biol Rep,2012,39:10713-10722
Gjerde B, Gjoen HM, Villanueva B. Optimum designs for fish breeding programmeswith constrained inbreeding Mass selection for a normally distributed trait.Livest Prod Sci,1996,47(1):59-72
Gjerde B, Reddy PVGK, Mahapatra KD, et al. Growth and survival in two completediallel crosses with five stocks of Rohu carp (Labeo rohita). Aquaculture,2002,209:103-115
Gjerde B, Refstie T. Complete diallel cross between five strains of Atlantic salmon.Livest Prod Sci,1984,11:207-226
Goudet J. Fstat version1.2: a computer program to calculate F-statistics. J Hered,1995,86:485-486
Grana X, Claudio PP, De Luca A, et al. PISSLRE, a human novel CDC-2relatedprotein kinase. Oncogene,1994,9:2097-2013
Guo X, Allen SK Jr. Sex determination and polyploid gigantism in the dwarf surfclam(Mulinia lateralis Say). Genetics,1994,138:1199-1206
Guo X, Hershberger WK, Cooper K, et al. Artificial gynogenesis with ultravioletlight-irradiated sperm in the Pacific oyster, Crassostrea gigas. I. Induction andsurvival. Aquaculture,1993,113:201-214
Hadley NH, Dillon RT, Manzi JJ. Realized heritability of growth rate in the hard clamMercenaria mercenaria. Aquaculture,1991(93):109-119
Hara M, Kikuchi S. Increasing the growth rate of abalone, Haliotis discus hannai,using selection techniques. NOAA Tech Rep NMFS,1992,106:21-26
Haskins HH, Ford SE. Characteristics of inbred oyster strains selected for resistanceto Haplosporidium nelsoni (MSX). J Shellfish Res,1988,7:162
Hayes B, Laerdahl JK, Lien S, et al. An extensive resource of single nucleotidepolymorphism markers associated with Atlantic salmon (Salmo salar) expressedsequences. Aquaculture,2007,265:82-90
Heath WA. Development in shellfish culture in British Columbia. Annual Meeting ofNational Shellfish Association,1995,14:228
Hedgecock D. Does variance in reproductive success limit effective population sizesof marine organisms? In: Beaumont AR (ed.) Genetics and evolution of aquaticorganisms. Chapman and Hall, London, UK,1994,122-134
Hedgecock D, Chow V, Waples RS. Effective population numbers of shellfishbroodstocks estimated from temporal variance in allelic frequencies. Aquaculture,1992,108:215-232
Hedgecock D, Cooper K, Hershberger W. Genetic and environmental components ofvariance in harvest body size among pedigreed Pacific oyster Crassostrea gigasfrom controlled crosses. J Shellfish Res,1991,10(2):516
Hedgecock D, Davis JP. Heterosis for yield and crossbreeding of the Pacific oysterCrassostrea gigas. Aquaculture,2007,272(S1):17-29
Hedgecock D, MaGoldrick DJ, Bayne BL. Hybird vigor in Pacific oyster: anexperimental approach using crosses among inbred lines. Aquaculture,1995,137:285-298
Hedgecock D, MaGoldrick DJ, Manahan DT. Quantitative and molecular geneticanalysis of heterosis in bivalve mollusks. J Exp Mar Biol Ecol,1996,203:49-59
Hedgecock D, Sly F. Genetic drift and effective population sizes ofhatchery-propagated stocks of the Pacific oyster, Crassostrea gigas. Aquaculture,1990,88:21-38
Herbinger CM, O'Reilly PT, Verspoor E. Unraveling first-generation pedigrees inwild endangered salmon populations using molecular genetic markers. Mol Ecol,2006,15:2261-2275
Herlin M, Delghandi M, Wesmajervi M, et al. Analysis of the parental contribution toa group of fry from a single day of spawning from a commercial Atlantic cod(Gadus morhua) breeding tank. Aquaculture,2008,274:218-224
Hirschhorn JN, Daly MJ. Genome-wide association studies for common diseases andcomplex traits. Nat Rev Genet,2005,6(2):95-108
Huan P, Wang HX, Liu BZ. Transcriptomic analysis of the clam Meretrix meretrix ondifferent larval stages. Mar Biotechnol,2012,14:69-78
Hubert S, Hedgecock D. Linkage maps of microsatellite DNA markers for the Pacificoyster Crassostrea gigas. Genetics,2004,168:351-362
Hulata G. A review of genetic improvement of the common carp (Cyprinus carpio L.)and other cyprinids by crossbreeding, hybridization and selection. Aquaculture,1995,129:143-155
Hull J, Campino S, Rowlands K, et al. Identification of common genetic variation thatmodulates alternative splicing. PLoS Genet,2007,3:1009-1018
Hunt R, Sauna ZE, Ambudkar SV, et al. Silent (synonymous) SNPs: should we careabout them? Methods Mol Biol,2009,578:23-39
Huvet A, Balabaud K, Bierne N, et al. Microsatellite analysis of6-hour-old embryosreveals no preferential intraspecific fertilization between cupped oystersCrassostrea gigas and Crassostrea angulata. Mar Biotechnol,2001,3:448-453
Ibarra AM, Cruz P, Romero BA. Effects of inbreeding on growth and survival ofself-fertilized catarina scallop larvae, Argopecten circularis. Aquaculture,1995,134:37-47
Innes DJ, Hadley LE. Genetic aspects of larval growth under reduced salinity inMytilus edulis. Bio Bull,1977,153:312-321
Jackson TR, Martin-Robichaud DJ, Reith ME. Application of DNA markers to themanagement of Atlantic halibut (Hippoglossus hippoglossus) broodstock.Aquaculture,2003,220:245-259
Kalinowski ST, Taper ML, Marshall TC. Revising how the computer programCERVUS accommodates genotyping error increases success in paternityassignment. Mol Ecol,2007,16:1099-1106
Kang MJ, Fujino T, Sasano H, et al. A novel arachidonate-preferring acyl-CoAsynthetase is present in steroidogenic cells of the rat adrenal, ovary, and testis.Proc Natl Acad Sci USA,1997,94(7):2880-2884
Kasten M, Giordano A. Cdk10, a Cdc2-related kinase, associates with the Ets2transcription factor and modulates its transactivation activity. Oncogene,2001,20:1832-1838
Keightley PD, Bulfield G. Detection of quantitative trait loci from frequency changesof marker alleles under selection. Genet Res,1993,62:195-203
Keller LF, Waller DM. Inbreeding effects in wild populations. Trends Ecol Evol,2002,17:230-241
Khandker KI. Association analyses of SNPs in candidate genes with body fatdeposition and carcass merit traits in beef cattle. MS thesis, University of Alberta,Alberta, Canada,2009
Kim JH, Lewin TM, Coleman RA. Expression and characterization of recombinant ratAcyl-CoA synthetases1,4, and5(Selective inhibition by triacsin C andthiazolidinediones). J Biol Chem,2001,276(27):24667-24673
Kim SG, Morishima K, Satoh N, et al. Parentage assignment in hatchery populationof brown sole Pleuronectes herzensteini by microsatellite DNA markers. Fish Sci,2007,73:1087-1093
Kimchi-Sarfaty C, Oh JM, Kim IW, et al. A ‘‘silent’’ polymorphism in the MDR1gene changes substrate specificity. Science,2007,315:525-528
Kuang GQ, Lu SQ, Zheng SM. Isolation and evaluation of18microsatellite markersin Siniperca chuatsi (Basilewsky). Mol Ecol Resour,2009,9:1473-1475
Kuersten S, Goodwin EB. The power of the3’ UTR: translational control anddevelopment. Nat Rev Genet,2003,4:626-637
Kwok PY. Single nucleotide polymorphisms: methods and protocols. Humana Press,Totowa,2003
Lallias D, Lapègue S, Hecquet C, et al. AFLP-based genetic linkage maps of the bluemussel (Mytilus edulis). Anim Genet,2007,38(4):340-349
Lallias D, Taris N, Boudry P, et al. Variance in the reproductive success of flat oysterOstrea edulis L. assessed by parentage analyses in natural and experimentalconditions. Genet Res Camb,2010,92:175-187
Lambreghts R, Shi M, Belden WJ, et al. A high-density single nucleotidepolymorphism map for Neurospora crassa. Genetics,2009,181:767-781
Lamkey KR, Edwards JW. The quantitative genetics of heterosis. In: Coors JG,Pandey S (eds) Proceedings of the International Symposium on the Genetics andExploitation of Heterosis in Crops. Mexico City, Mexico,1999,31-48
Lande R, Barrowclough GF. Effective population size, genetic variation, and their usein population management. In: Soule M (ed.) Viable Populations forConservation. Cambridge University Press, Cambridge, UK.1987,87-124
Langdon C, Evans F, Jacobson D, et al. Yields of cultured Pacific oysters Crassostreagigas Thunberg improved after one generation of selection. Aquaculture,2003,220:227-244
Lannan JE. Broodstock management of Crassostrea gigas. IV. Inbreeding and larvalsurvival. Aquaculture,1980,21:353-356
Lee MA, Keane OM, Glass BC, et al. Establishment of a pipeline to analysenon-synonymous SNPs in Bos taurus. BMC Genomics,2006,7:298
Lee MG, Nurse P. Complementation used to clone a human homologue of the fissionyeast cell cycle control gene cdc2. Nature,1987,327:31-35
Leighton DL, Lewis CA. Experimental hybridization in abalones. Int J InvertebrReprod,1982,5(5):273-282
Lemay MA, Boulding EG. Microsatellite pedigree analysis reveals high variance inreproductive success andreduced genetic diversity in hatchery-spawned northernabalone. Aquaculture,2009,295:22-29
Leonard JL. Sexual selection: lessons from hermaphrodite mating systems. IntegrComp Biol,2006,46:349-367
Levin L, Cheng HH, Baxter-jones C, et al. Turkey microsatellite DNA lociamplified by chicken-specific primers. Anim Genet,1995,26:107-110
Li HJ, Zhu D, Gao XG, et al. Mining single nucleotide polymorphisms from EST dataof hard clam Meretrix meretrix. Conserv Genet Res,2010a,2(S1):69-72
Li JL, Wang GL, Bai ZY. Genetic variability in four wild and two farmed stocks ofthe Chinese freshwater pearl mussel (Hyriopsis cumingii) estimated bymicrosatellite DNA markers. Aquaculture,2009c,287:286-291
Li L, Guo X M. A primary linkage map for the Pacific oyster Crassostrea gigas withAFLP markrs. J Shellfish Res,2002,21(1):433
Li L, Xiang JH, Liu X, et al. Construction of AFLP-based genetic linkage map forzhikong scallop, Chlamys farreri Jones et Preston and mapping of sex-linkedmarkers. Aquaculture,2005,245:63-73.
Li LO, Klett EL, Coleman RA. Acyl-CoA synthesis, lipid metabolism and lipotoxicity.Biochim Biophys Acta,2010b,1801(3):246-251
Li Q, Kijima A. Segregation of microsatellite alleles in gynogenetic diploid Pacificabalone (Haliotis discus hannai). Mar Biotechnol,2005,7:669-676
Li Q, Nie HT, Kong LF. Microsatellite-centromere mapping in zhikong scallop(Chlamys farreri) through half-tetrad analysis in D-shaped larvae of gynogeneticdiploid families. Aquaculture,2009a,293:29-34
Li Q, Park C, Endo T, et al. Loss of genetic variation at microsatellite loci in hatcherystrains of the Pacific abalone. Aquaculture,2004,23:207-222
Li RH, Li Q, Kong LF. Characterization of expressed sequence tag-derivedsingle-nucleotide polymorphisms in the bay scallop Argopecten irradiansirradians. Fish Sci,2009b,75(6):1389-1400
Li WH, Dan G. Fundamentals of Molecular Evolution. Sinauer Associates,Sunderland, Massachusetts, USA,1991
Liu BZ, Dong B, Tang BJ, et al. Effect of stocking density on growth, settlement andsurvival of clam larvae, Meretrix meretrix. Aquaculture,2006,258:344-9
Liu CZ, Wang X, Xiang JH, et al. EST-derived SNP discovery and selective pressureanalysis in Pacific white shrimp (Litopenaeus vannamei). Chin J Oceanol Limnol,2012,30:713-723
Liu XD, Liu X, Gao QK, et al. A preliminary genetic linkage map of the Pacificabalone Haliotis discus hannai Ino. Mar Biotechnol,2006,8(4):386-397
Livak KJ, Schmittgen TD. Analysis of relative gene expression data using realtimequantitative PCR and the2(T)(-Delta Delta C) method. Methods,2001,25:402-408
Longwell AC, Stiles S. Gamete cross incompatibility and inbreeding in thecommercial oyster, Crassostrea virginica Gmelin. Cytologia,1973,38:521-533
Lu X, Wang HX, Dai P, et al. Characterization of EST-SSR and genomic-SSRmarkers in the clam, Meretrix meretrix. Conservation Genet Resour,2011a,3:655-658
Lu X, Wang HX, Liu BZ, et al. An effective method for parentage determination ofthe clam (Meretrix meretrix) based on SSR and COI markers. Aquaculture,2011b,318:223-228
Lu X, Wang HX, Liu BZ, et al. Microsatellite-based genetic and growth analysis for adiallel mating design of two stocks of the clam, Meretrix meretrix. Aquac Res,2012,43(2):260-270
Lu X, Wang HX, Liu BZ, et al. Three EST-SSR markers associated with QTL for thegrowth of the clam Meretrix meretrix revealed by selective genotyping. MarBiotechnol,2013,15:16-25
Luttikhuizen PC, Drent J. Inheritance of predominantly hidden shell colours inMacoma balthica (L.)(Bivalvia: Tellinidae). J Mollus Stud,2008(74):363-371
Lynch M, Ritland K. Estimation of pairwise relatedness with molecular markers.Genetics,1999,152:1753-1766
MacAvoy ES, Wood AR, Gardner PA. Development and evaluation of microsatellitemarkers for identification of individual Greenshell mussels (Perna canaliculus)in a selective breeding programme. Aquaculture,2008,274:41-48
MacLachlan TK, Sang N, Giordano A. Cyclins, cyclin-dependent kinases and cdkinhibitors: implications in cell cycle control and cancer. Crit Rev Eukaryot GeneExpr,1995,5(2):127-156
Mallet AL, Freeman KR, Dickie LM. The genetics of production characters in theblue mussel Mytilus edulis. I. A preliminary analysis. Aquaculture,1986,57(1-4):133-140
Marszalek JR, Kitidis C, Dirusso CC, et al. Long-chain acyl-CoA synthetase6preferentially promotes DHA metabolism. J Biol Chem,2005,280(11):10817-10826
Martin AG, Gerand A, Cochennec N, et al. Selecting flat oyster, Ostrea edulis, forsurvival against the parasite bonamia odtreae: assessment of the resistance of afirst selected generation. In Production, Enviroment and Quality, BordeauxAquaculture’92, Ghent Belgium, Euro Aquac Soc Spec Publ,1992,18:547-554
Mashek DG, Li LO, Coleman RA. Rat long chain acyl-CoA synthetase mRNA,protein and activity vary in tissue distribution and in response to diet. J Lipid Res,2006b,47(9):2004-2010
Mashek DG, McKenzie MA, van Horn CG, et al. Rat long chain acyl-CoA synthetase5increases fatty acid uptake and partitioning to cellular triacylglycerol inMcArdle-RH7777cells. J Biol Chem,2006a,281(2):945-950
Mcgoldrick DJ, Hedgecock D. Fixation, segregation and linkage of allozyme loci ininbred families of the pacific oyster Crassostrea gigas (Thunberg): implicationsfor the causes of inbreeding depression. Genetics,1997,146:321-334
McGoldrick DJ, Hedgecock D, English LJ, et al. The transmission of microsatellitealleles in Australian and north American stocks of the Pacific oyster (Crassostreagigas): selection and null alleles. J Shell Res,2000,19:779-788
Metzker ML. Sequencing technologies–the next generation. Nat Rev Genet,2010,11:31-46
Meuwissen THE, Hayes BJ, Goddard ME. Prediction of total genetic value usinggenome-wide dense marker maps. Genetics,2001,157(4):1819-1829
Miglior F, Burnside EB, Dekkers JC. Nonadditive genetic effects and inbreedingdepression for somatic cell counts of Holstein cattle. J Dairy Sci,1995,78:1168-1173
Moen T, Hayes B, Nilsen F, et al. Identification and characterisation of novel SNPmarkers in Atlantic cod: evidence for directional selection. BMC Genet,2008,9:18
Morgan DO. Cyclin-dependent kinases: engines, clocks, and microprocessors. AnnuRev Cell Dev Biol,1997,13:261-291
Naiki T, Nagaki M, Shidoji Y, et al. Analysis of gene expression profile induced byhepatocyte nuclear factor4alpha in hepatoma cells using an oligonucleotidemicroarray. J Biol Chem,2002,277(16):14011-14019
Newkirk GF. Interaction of genotype and salinity in larvae of the oyster Crassostreavirginica. Mar Biol,1978,48:227-234
Newkirk GF, Haley LE. Selection for growth rate in the European oyster, Ostreaedulis: response of second generation groups. Aquaculture,1983,33:149-155
Nguyen MT, Barnes AC, Mather PB, et al. Single nucleotide polymorphisms in theactin and crustacean hyperglycemic hormone genes and their correlation withindividual growth performance in giant freshwater prawn Macrobrachiumrosenbergii. Aquaculture,2010,301:7-15
Nie Q, Yue X, Chai XL, et al. Three vibrio-resistance related EST-SSR markersrevealed by selective genotyping in the clam Meretrix meretrix. Fish ShellfishImmunol,2013,35(2):421-8
Norris AT, Bradley DG, Cunningham EP. Parentage and relatedness determination infarmed Atlantic salmon (Salmo salar) using microsatellite markers. Aquaculture,2000,182:73-83
Oikawa E, Iijima H, Suzuki T, et al. A novel acyl-CoA synthetase, ACS5, expressed inintestinal epithelial cells and proliferating preadipocytes. J Biochem,1998,124(3):679-685
Orba Y, Sunden Y, Suzuki T, et al. Pharmacological cdk inhibitor R-Roscovitinesuppresses JC virus proliferation. Virology,2008,370(1):173-183
Pagani F, Baralle FE. Genomic variants in exons and introns: identifying the splicingspoilers. Nat Rev Genet,2004,5:389-396
Pan Y, Li Q, Yu R, et al. Induction of gynogenesis and effects of ultravioletirradiation on ultrastructure of sperm of the Zhikong scallop Chlamys farreri.Fisheries Sci,2004,70:487-496
Parkes HA, Preston E, Wilks D, et al. Overexpression of acyl-CoA synthetase-1increases lipid deposition in hepatic (HepG2) cells and rodent liver in vivo. Am JPhysiol Endocrinol Metab,2006,291(4): E737-44
Paynter KT, Dimichele L. Growth of tray-cultured oysters (Crassostrea virginicaGmelin) in Chesa-peake Bay. Aquaculture,1990,87:289-297
Pemberton JM, Slate J, Bancroft DR, et al. Nonamplifying alleles at microsatelliteloci: a caution for parentage and population studies. Mol Ecol,1995,4:249-252
Ponomarenko JV, Orlova GV, Merkulova TI, et al. rSNP_Guide: an integrateddatabase-tools system for studying SNPs and site-directed mutations intranscription factor binding sites. Hum Mutat,2002,20:239-248
Ponzoni RW, Hamzah A, Tan S, et al. Genetic parameters and response to selectionfor live weight in the GIFT strain of Nile tilapia (Oreochromis niloticus).Aquaculture,2005,247:203-210
Porta J, Porta JM, Martinez-Rodriguez G, et al. Development of a microsatellitemultiplex PCR for Senegalese sole (Solea senegalensis) and its application tobroodstock management. Aquaculture,2006,256:159-166
Quinlan AR, Stewart DA, Stromberg MP, et al. Pyrobayes: an improved base callerfor SNP discovery in pyrosequences. Nat Methods,2008,5:179-181
Quinton C, McMillan I, Glebe BD. Development of an Atlantic salmon (Salmo salar)genetic improvement program: Genetic parameters of harvest body weight andcarcass quality traits estimated with animal models. Aquaculture,2005,247:211-217
Rawson PD, Hilbish TJ. Heritability of juvenile growth for the hard clam Mercenariamercenaria. Mar Biol,1990,105(3):429-436
Rawson PD, Hilbish TJ. Genotype-environment interaction for juvenile growth in thehard clam Mercenaria mercenaria. Evolution,1991,45(8):1924-1935
Raymond M, Rousset F. GENEPOP Version1.2: population genetics software forexact tests and ecumenicism. Heredity,1995,86:248-249
Reece KS, Ribeiro WL, Gaffney PM, et al. Microsatellite marker development andanalysis in the eastern oyster (crassostrea virginica): confirmation of null allelesand non-mendelian segregation ratios. Heredity,2004,95:346-352
Ritland K. Estimators for pairwise relatedness and individual inbreeding coefficients.Genetics,1996,67:175-185
Rousset F, Raymond M. Testing heterozygote excess and deficiency. Genetics,1995,140:1413-1419
Saavedra C. Low effective sizes in hatchery populations of the European Oyster(Ostrea edulis): implications for the management of genetic resources. J ShellfishRes,1997,16:441-446
Salem M, Vallejo RL, Leeds TD, et al. RNA-Seq identifies SNP markers for growthtraits in Rainbow Trout. PLoS ONE,2012,7: e36264
Sauvage C, Bierne N, Lapegue S, et al. Single nucleotide polymorphisms and theirrelationship to codon usage bias in the Pacific oyster Crassostrea gigas. Gene,2007,406(1-2):13-22
Sbordoni V, De Matthaeis E, Cobolli Sbordoni M, et al. Bottleneck effects and thedepression of genetic variability in hatchery stocks of Penaeus japonicus(Crustacea, Decapoda). Aquaculture,1986,57:239-251
Scarpa J, Komaru A, Wada KT. Gynogenetic induction in the mussel, Mytilusgalloprovincialis. Bull Natl Res Inst Aquac,1994,23:33-41
Schlotterrer C, Amos W, Tautz D. Conservation of polymorphic simple sequence lociin cetacean species. Nature,1991,354:63-65
Seeb JE, Carvalho G, Hauser L, et al. Single-nucleotide polymorphism (SNP)discovery and applications of SNP genotyping in non-model organisms. Mol EcolResour,2011,11:1-8
Sekino M, Hamaguchi M, Aranishi F. Development of novel microsatellite DNAmarkers from the Pacific oyster Crassostrea gigas. Mar Biotechnol,2003,5:227-233
Sekino M, Hara M. Microsatellite DNA loci in Pacific abalone Haliotis discus discus(Mollusca, Gastropoda, Haliotidae). Mol Ecol Notes,2001,1:8-10
Selvamani MJP, Degnan SM, Degnan BM. Microsatellite genotyping of individualabalone larvae: Parentage assignment in aquaculture. Mar Biotechnol,2001,3:78-485
Sham PC, Cherny SS, Purcell S. Application of genome-wide SNP data foruncovering pairwise relationships and quantitative trait loci. Genetica,2009,136:237-243
Sherrc J, Roberts JM. Living with or without Cyclins and Cyclin-dependent Kinases.Gene Dev,2004,18:2699-2711
Shi YY, He L. SHEsis, a powerful software platform for analyses of linkagedisequilibrium, haplotype construction, and genetic association at polymorphismloci. Cell Res,2005,15:97-98
Shifman S, Bell JT, Copley RR, et al. A high-resolution single nucleotidepolymorphism genetic map of the mouse genome. PLoS Biol,2006,4:2227-2237
Shogo HS, Tomoko H, Atsuko T. Association between fatty acid compositions andgenotypes of FABP4and LXR-alpha in Japanese Black cattle. BMC Genet,2008,11:9:84
Shull GH. The composition of a field of a maize. J Hered,1908,4:296-301
Skinner DM, Beattie WG, Blattner FR, et al. The repeat sequence of a hermit carbsatellite deoxyribonucleic acid is (-T-A-G-G-)n-(-A-T-C-C-)n. Biochemistry,1974,12:3930-3937
Slate J, Gratten J, Beraldi D, et al. Gene mapping in the wild with SNPs: guidelinesand future directions. Genetica,2009,136:97-107
Soller M, Beckmann JS. Marker-based mapping of quantitative trait loci usingreplicated progenies. Theor Appl Genet,1990,80:205-208
Sprague GF, Tatum LA. General vs. specific combining ability in single crosses ofcorn. J Amer Soc Agron,1942,34:923-32
Stanley JG, Allen SK, Hidu H Jr. Polyploidy induced in the American oyster,Crassostrea virginica, with cytochalasin B. Aquaculture,1981,23(124):1-10
Stella A, Boettcher PJ. Optimal designs for linkage disequilibrium mapping andcandidate gene association test in livestock populations. Genetics,2004,166:341-350
Stiles S, Cromanski J, Longwell A. Cytological appraisal of prospects for successfulgynogenesis, parthenogenesis and androgenesis in the oyster. InternationalCouncil for the Exploration of the Sea, Mariculture Committee Paper F,1983,10:1-14
Sugama K, Taniguchi N, Umeda S. An experimental study on genetic drift in hatcherypopulation of red sea bream. Nippon Suisan Gakk,1988,54:734-744
Suzuki H, Kawarabayasi Y, Kondo J, et al. Structure and regulation of rat long-chainacyl-CoA synthetase. J Biol Chem,1990,265:8681-8685
Taniguchi N, Sumantadimata K, Iyama S. Genetic change in the first and secondgenerations of hatchery stock of black sea bream. Aquaculture,1983,35:309-320
Tao WJ, Boulding EG. Associations between single nucleotide polymorphisms incandidate genes and growth rate in Arctic charr (Salvelinus alpinus L.). Heredity,2003,91:60-69
Tautz D. Hypervariability of simple sequence as a general source for polymorphicDNA markers. Nucleic Acid Res,1989,17:6463-6471
Teklewold A, Becker HC. Heterosis and combining ability in a diallel cross ofEthiopian mustard inbred lines. Crop Sci,2005,45:2629-2635
Templeton AR. The theory of speciation via the founder principle. Genetics,1980,94:1011-1038
Tian Y, Kong J, Yang CH. Comparative growth and viability of hybrids between twopopulations of Chinese shrimp (Fenneropenaeus chinensis). Chin Sci Bull,2006,51(19):2369-2374
Toro JE, Newkirk GE. Divergent selection for growth rate in the European oyster(Ostrea edulis): Response to selection and estimation of genetic parameters. MarEcol-Prog Ser,1990,62:219-225
Toth G, Gaspari Z, Jurka J. Microsatellites in different eukaryotic genomes: surveyand analysis. Genome Res,2000,10:967-981
Tsaftaris SA. Molecular aspects of heterosis in crop plants. Physiol Plantarum,1995,94(2):362-370
Wada KT. Genetic selection for shell traits in the Japanese pearl oyster, Pinctadafucata martensii. Aquaculture,1986,57:171-176
Wang C, Chai XL, Wang HX, et al. Growth performance of the clam, Meretrixmeretrix, breeding selection populations cultured in different conditions. ActaOceanol Sin,2013,32(10):82-87
Wang C, Cote J. Heterosis and combining abilities in growth and survival in seascallops along the Atlantic coast of Canada. J Shellfish Res,2012,31(4):1145-1149
Wang C, Wang HX, Li Y. Identification of a fructose-1,6-bisphosphate aldolase geneand association of the single nucleotide polymorphisms with growth traits in theclam Meretrix meretrix. Mol Biol Rep,2012a,39:5017-5024
Wang C, You YN, Wang HX, et al. Genetic diversity of the sulfotransferase-like geneand one nonsynonymous SNP associated with growth traits of clam, Meretrixmeretrix. Mol Biol Rep,2012b,39:1323-1331
Wang HX, Chai XL, Liu BZ. Estimation of genetic parameters for growth traits incultured clam Meretrix meretrix (Bivalvia: Veneridae) using the Bayesian methodbased on Gibbs sampling. Aquac Res,2011a,42:240-247
Wang HX, Huan P, Liu BZ. Mining of EST-SSR markers in clam Meretrixmeretrix larvae from454shotgun transcriptome. Genes Genet Syst,2011b,86:197-205
Wang J, Li ZJ, Lan XY, et al. Two novel SNPs in the coding region of the bovinePRDM16gene and its associations with growth traits. Mol Biol Rep,2010,37:571-577
Wang LL, Song LS, Chang YQ, et al. A preliminary genetic map of zhikong scallop(Chlamys farreri Jones et Preston1904). Aquac Res,2005,36:643-653
Wang SL, Sha ZX, Sonstegard TS, et al. Quality assessment parameters forEST-derived SNPs from catfish. BMC Genomics,2008,9:450
Wang XM, Liu BZ, Xiang JH. Cloning, characterization and expression of ferritinsubunit from clam Meretrix meretrix in different larval stages. Comp BiochemPhys B,2009,154:12-16
Ward RD, English LJ, Mcgoldrick DJ, et al. Genetic improvement of the Pacificoyster Crassostrea gigas (Thunberg) in Australia. Aquac Res,2000,31:35-44
Weber JL. Informativeness of human (dC-dA)n.(dG-dT)n polymorphisms. Genomics,1990,7:524-530
Wedekind C. Manipulating sex ratios for conservation: short-term risks and long-termbenefits. Anim Conserv,2002,5:13-20
Weir BS, Cockerham CC. Estimating F-Statistics for the analysis of populationstructure. Evolution,1984,38:1358-1370
Wilson AJ, Ferguson MM. Molecular pedigree analysis in natural populations offishes: approaches, applications, and practical considerations. Can J Fish AquatSci,2002,59:1696-1707
Winkler FM, Estevez BF. Effects of self-fertilization on growth and survival of larvaeand juveniles of the scallop Argopecten purpuratus L. J Exp Mar Biol Ecol,2003,292(1):93-102
Winkler FM, Estevez BF, Jollan LB, et al. Inheritance of the general shell color in thescallop Argopecten purpuratus (Bivalvia: Pectinidae). J Hered,2001(92):521-525.
Woolfe A, Mullikin JC, Elnitski L. Genomic features defining exonic variants thatmodulate splicing. Genome Biol,2010,11: R20
Wright S. Inbreeding in animals: differentiation and depression. In: Evolutionand the genetics of populations, Vol.3. University of Chicago press,Chicago, USA,1977,44-96
Würschum T, Langer SM, Longin CF, et al. Population structure, genetic diversity andlinkage disequilibrium in elite winter wheat assessed with SNP and SSR markers.Theor Appl Genet,2013,126:1477-1486.
Yu Z, Guo X. Genetic linkage map of the eastern oyster Crassostrea virginica Gmelin.Biol Bull,2003,204:327-338
Yue GH, Ho MY, Orban L, et al. Microsatellites within genes and ESTs ofcommon carp and their applicability in silver crucian carp. Aquaculture,2004,234:85-98.
Yue X, Liu BZ, Xue QG. An i-type lysozyme from the Asiatic hard clam Meretrixmeretrix potentially functioning in host immunity. Fish Shellfish Immunol,2011a,30:550-558
Yue X, Liu BZ, Sun L, et al. Cloning and characterization of a hsp70gene fromAsiatic hard clam Meretrix meretrix which is involved in the immune responseagainst bacterial infection. Fish Shellfish Immunol,2011b,30:791-799
Zhang HB, Liu X, Zhang GF, et al. Growth and survival of reciprocal crosses betweentwo bay scallops, Argopecten irradians concentricus Say and A. irradiansirradians Lanmarck. Aquaculture,2007,272(S1):88-93
Zhang LP, Lin GY, Ni o-Liu D, et al. Mapping QTLs conferring early blight(Alternaria solani) resistance in a Lycopersicon esculentum×L. hirsutum cross byselective genotyping. Mol Breed,2003,12:3-19
Zhang YD, Kang MS. DIALLEL-SAS: A program for Griffing’s diallel method. In:Kang MS (ed.) Handbook of Formulus and Software for Plant Geneticists andBreeder. New York, Food Products Press,2003,1-9
柴雪良,吕振民,方军,等.泥蚶三倍体的诱导研究.浙江海洋学院学报(自然科学版),2002,21(1):16-19
常建波,魏利平,杨建敏,等.文蛤染色体核型及三倍体诱导初步研究.水产学报,1996,20(3):269-274
常亚青,刘小林,相建海,等.栉空扇贝中国种群与日本种群杂交子一代的早期生长发育.水产学报,2002,26(5):385-390
陈大鹏,沈怀舜,丁亚平,等.文蛤(Meretrix meretrix)地理种群ISSR分子标记的初步研究.南京师范大学学报,2004,27(3):74-77
陈淑吟,吉红九,许广平,等.文蛤微卫星DNA的筛选及其特性分析.生物技术通报,2009,12:134-138
陈天国,易华峰,张廷科,等.分子标记与动物遗传育种.畜牧市场,2006,(8):47-51
邓岳文,刘晓,张国范.皱纹盘鲍基因型与环境互作初步研究.海洋科学,2005,29(12):30-33
邓岳文,符韶,杜晓东,等.马氏珠母贝选系F2早期选择反应和现实遗传力估计.广东海洋大学学报,2008,28(4):27-29
郭香.长牡蛎生长相关性状QTL定位与连锁不平衡研究.青岛:中国海洋大学博士学位论文,2013
赫崇波,丛林林,葛陇利,等.文蛤养殖群体和野生群体遗传多样性的AFLP分析.中国水产科学,2008,15(2):215-221
贺艳.美洲牡蛎(Crassostrea virginica)抗病相关基因标记的筛选及应用.青岛:中国海洋大学博士学位论文,2012
蒋逸民,慕永通.中国海水产品产量与结构变动趋势研究.沈阳农业大学学报(社会科学版),2012,14(1):41-44
今井丈夫.浅海完全养殖.日本恒星社厚生阁版,1961
金武,李家乐,付龙龙,等.三角帆蚌早期阶段生长性状遗传参数估计.水产学报,2012,36(8):1209-1214
李宏俊.海湾扇贝微卫星标记的开发及遗传连锁图谱的构建.青岛:中国科学院海洋研究所博士学位论文,2009
李太武,张安国,苏秀榕.文蛤花纹的形态及形成观察.动物学杂,2008,43(6):83-87
李太武,张国安,苏秀榕,等.不同花纹文蛤(Meretrix meretrix)的ITS2分析.海洋与湖沼,2006,37(2):132-136
梁峻,郑怀平,李莉,等.虾夷扇贝养殖群体的遗传力估算.海洋科学,2011,35(3):1-7
林美金.杂交鲍三倍体诱导技术研究.水产科技情报,2013,20(4):169-173
林岳光,姜卫国.三倍体和二倍体合浦珠母贝育珠比较初步研究.热带海洋,1993,12(3):90-94
林志华,董迎辉,李宁,等.基于形态参数和AFLP标记的文蛤(Meretrix meretrix)不同地理群体遗传变异分析.海洋与湖沼,2008,39:245-251
林志华,黄晓婷,董迎辉,等.广西文蛤(Meretrix meretrix)的fAFLP及ITS分析.海洋与湖沼,2009,40(1):33-41
刘博,邵艳卿,滕爽爽,等.乐清湾养殖缢蛏群体遗传结构的微卫星标记分析.中国农学通报,2012,28(2):69-73
刘来福,毛盛贤,黄远樟.作物数量遗传.北京:农业出版社,1984
刘绿叶,刘培廷,汤建华,等.文蛤养殖密度对主要环境因子影响的模拟研究.水产养殖,2007,5:8-11
刘卫东,鲍相渤,宋文涛,等.虾夷扇贝遗传连锁图谱的初步构建遗传.遗传,2009,31(6):629-637
刘晓丹,邱陵,吴乔,等.文蛤抗癌活性多肽的生理活性研究.厦门大学学报(自然科学版),2004,43(4):432-435
楼允东.鱼类育种学.北京:中国农业出版社,2001
卢霞.分子标记应用于文蛤遗传评价、图谱构建及QTL筛选的研究.青岛:中国科学院海洋研究所博士学位论文,2012
南乐红,张金盛,丰玮,等.紫扇贝和墨西哥湾扇贝种间杂交的初步研究.中国农学通报,2012,28(20):131-135
潘洁,包振民,赵洋,等.栉孔扇贝不同地理群体的遗传多样性分析.高技术通讯,2002,12:78-82
秦艳杰.海湾扇贝遗传图谱构建及壳色基因、生长相关QTL的定位研究.青岛:中国科学院海洋研究所博士学位论文,2006
沈怀舜,朱建一,丁亚平,等.我国沿海三个文蛤地理群的RAPD分析.海洋学报,2003,25(5):97-102
宋传文,闫喜武,桑士田,等.紫贻贝生长性状的遗传力估计.水产学报,2013,37(2):201-206
宋林生,李俊强,李红蕾,等.用RAPD技术对我国栉孔扇贝野生种群与养殖群体的遗传结构及其遗传分化的研究.高技术通讯,2002,7:83-86
宋盛亮,李琪,孔令锋,等.长牡蛎生长性状的遗传效应及与环境互作分析.中国海洋大学学报,2013,43(10):41-47
苏秀榕,金春华,李春艳,等.不同花纹文蛤(Meretrix meretrix)的外套膜蛋白质的双向电泳研究.海洋与湖沼,2009,40(6):777-780
唐保军.环境因子和饵料对文蛤能量收支与幼虫生长发育的影响.青岛:中国科学院海洋研究所硕士学位论文,2005
王春德,刘保忠,李继强,等.紫扇贝与海湾扇贝种间杂交的研究.海洋科学,2009,33(10):84-88
汪德耀,刘汉英.牡蛎人工杂交初步研究.动物学报.1959,11(3):283-295
王清印.海水健康养殖的理论与实践.北京:海洋出版社,2003,45-198
王清印,杨爱国.相孔扇贝三倍体研究进展和展望.中国水产科学,2000,7(3):93-96
王如才,王昭萍,田传远,等.我国太平洋牡蛎(Crassostrea gigas)三倍体育苗与养殖技术研究进展.青岛海洋大学学报(自然科学版),2002,32(2):193-200
王昭萍,李赞,王如才,等.三倍体太平洋牡蛎生产性育苗与养成初报.海洋湖沼通报,2000,3:34-39
王子臣,张国范,王一平,等.皱纹盘鲍的三倍体研究.大连水产学报,1990,5(1):1-8
谢玉坎.我国海洋贝类的养殖概况和发展问题.科学种养,2014,2:7-8
许国强,林岳光,李刚,等.人工诱发合浦珠母贝雌核二倍体发生及“Hertwig效应”的初步研究.热带海洋学报,1990,9:1-7
阎冰,邓岳文,杜晓东,等.广西地区文蛤的遗传多样性研究.海洋科学,2002,26(5):5-8
闫喜武,张跃环,霍忠明,等.不同地理群体菲律宾蛤仔的选择反应及现实遗传力.水产学报,2010,34(5):704-710
严正凜,陈建华.三倍体九孔鲍的育种和养成技术研究.水产学报,2002,26(1):54-60
严正凜,陈建华,吴萍茹,等.6-DMAP抑制九孔鲍受精卵第二极体的释放诱导三倍体.台湾海峡,2001,20(1):15-19
严正凜,江宏,李丕廉,等.杂色鲍和九孔鲍三倍体的化学诱导.台湾海峡,1999,18(3):337-342
杨青,李琪,聂鸿涛,等.魁蚶雌核发育的人工诱导.海洋科学,2011,10:11-15
杨青,李琪,于瑞海,等.人工诱导栉江珧雌核发育的初步研究.中国水产科学,2006,13:310-315
姚国兴,宋晓村,于志华,等.环境因子对文蛤幼苗生长的影响.水产养殖,2000(1):17-18
喻达辉,王小玉,黄桂菊,等.合浦珠母贝遗传连锁图谱的构建.中国水产科学,2007,14(3):361-367
张国范.海洋贝类遗传育种研究20年.厦门大学学报(自然科学版),2006,45(S2):190-194
张国范.中国近海栉孔扇贝遗传结构及遗传变异与生长的关系.青岛:中国科学院海洋研究所博士学位论文,1992
张国范,刘述锡,刘晓,等.海湾扇贝自交家系的建立与自交效应.中国水产科学,2003,10(6):441-445
张国范,刘晓.关于贝类遗传改良几个问题的讨论.水产学报,2006,30(1):130-137
张国范,刘晓,阙华勇,等.贝类杂交及杂种优势理论和技术研究进展.海洋科学,2004,28(7):54-60
张国范,王继红,赵洪恩,等.皱纹盘鲍中国群体和日本群体的自交与杂交F1的RAPD标记.海洋与湖沼,2002,33(5):483-491
张玺,谢玉坎.近江牡蛎的养殖.北京:科学出版社,1959
张玉勇,常亚青,宋坚.杂交育种技术在海水养殖贝类中的应用及研究进展.水产科学.2005,24(4):39-41
张月月.铁蛋白在虾夷扇贝新品种“海大金贝”高抗逆性中的作用及机理研究.青岛:中国海洋大学博士学位论文,2013
郑怀平.海湾扇贝两个养殖群体数量性状及壳色遗传研究.青岛:中国科学院海洋研究所博士学位论文,2005
郑康乐,黄宁.标记辅助选择在水稻改良中的应用前景.遗传,1997,19(2):40-44
周延清.遗传标记的发展.生物学通报,2000,35:17-18
庄启谦.中国动物志:软体动物门、双壳纲、帘蛤科.北京:科学出版社,2001,229-236
© 2004-2018 中国地质图书馆版权所有 京ICP备05064691号 京公网安备11010802017129号 地址:北京市海淀区学院路29号 邮编:100083 电话:办公室:(+86 10)66554848;文献借阅、咨询服务、科技查新:66554700 |