绿豆基因组研究进展

绿豆是亚洲国家重要的经济作物。绿豆基因组的研究工作已开展多年,至今已经发布了6张遗传连锁图谱,然而还未有一张图谱的连锁群数与绿豆(2n=2x=22,n=11)的染色体基数一致。近年来,豆科植物比较基因组学的研究成果,为绿豆遗传连锁图谱的发展提供了新的思路。通过将绿豆遗传连锁图与其他豆类连锁图比较发现,绿豆与小豆、豇豆、普通菜豆、大豆、藊豆以及豆科模式植物—蒺藜苜蓿的基因组间有不同程度的保守性,其中尤以绿豆与普通菜豆基因组间共线性水平高。本文分别从绿豆遗传连锁图谱构建、比较基因组作图以及抗豆象基因定位等方面进行了综述,以期为绿豆遗传研究工作者提供参考。     

线虫(Caenorhabditis elegans)基因组的研究进展

线虫（Ｃａｅｎｏｒｈａｂｄｉｔｉｓ ｅｌｅｇａｎｓ）是重要的模式生物,其基因组序列分析工作于１９９８年底基本完成,已有１９０００多个基因被鉴定。本文概述线虫基因组研究中遗传图谱、物理图谱、序列测定和基因识别等方面的研究成果,以及线虫基因组计划将对生命科学研究产生的影响。     

肿瘤基因组研究进展

所有的肿瘤都源自于细胞基因组DNA序列的异常。在整个生命过程中,甚至从最初的受精卵开始,人体细胞的基因组就暴露于各种突变诱变因素和自身的复制错误之中,这些不利影响可能导致任何细胞的DNA序列渐进的、细微的突变。过去的25年中,这些突变和基因异常如何调控肿瘤的成长已经越来越多地为人们所认识,在此基础上,大量获得肿瘤基因组的完整DNA序列已经成为可能。这些研究将为人类提供肿瘤发生和成长的重要线索。     

鸡基因组研究新进展

鸡基因组测序草图的完成标志着禽类功能基因组时代的到来。鸡不仅是全世界广泛饲养且有重要经济价值的禽类,而且是极具生命科学研究价值的模式动物。因此,鸡基因组测序草图的完成将对遗传育种和生物学研究有重要的影响。本文综述了近年来鸡基因组研究的最新进展,主要内容包括鸡基因组的有关数据、物理图谱、遗传连锁图谱、比较基因组学、序列表达标签、生物信息学等方面所取得的成绩,同时对鸡基因组研究结果的应用前景进行了展望。     

重叠群物理图谱的构建及其应用

人类对各种生物的基因组结构和功能的研究都需要确定DNA序列在染色体上的位置.与遗传图相比,物理图反映了基因或DNA标记之间在染色体上的真实距离.依其作图方法分为三类,即限制性酶切图谱、重叠群图谱和DNA序列图谱.重叠群物理图是将获得的大片段克隆,如YAC、BAC克隆,依其在染色体上的真实顺序排列而成,主要应用于基因组测序、重要基因的图位克隆、靶分子标记开发及比较基因组学研究等,特别是为那些由于缺乏合适的作图群体而不能建立遗传图的物种提供了一个重要的从事基因组学研究的平台.本文综述了近年来重叠群物理图构建研究的主要进展,比较分析了不同重叠群物理图谱构建方法的特点,提出了改进物理作图质量的建议,认为应根据基因组不同区域的特点,综合特异性探针的杂交、PCR筛选、酶切指纹分析、BAC克隆STC延伸、BAC末端测序等多种方法才能完成重叠群的构建.此外,物理图的构建还应努力整合各种基因组的资源和数据,如遗传连锁图、分子细胞遗传图、DNA序列图、EST数据等,这将有助于提高其在基因组学研究中的使用价值及应用范围.文章最后对重叠群物理图的发展趋势进行了展望.     

应用RAPD技术对不同基因组组合生物型遗传多态性的研究

利用RAPD技术对不同基因组合的鱼类进行了基因组指纹图谱构建,在DNA水平上对基因组成分进行了分析,探讨陈春遗传多态性。PARD结果发现,在26个随机引物扩增的产物中,平均每个个体观察到约142个RAPD标记,单个的扩增图谱（Fig.1)可将红鲫（RA）与其它组合区分开,还可将鲫鲫杂种二倍体（CA)鲫鲤杂种三倍体（CAA）和人工复合三倍体鲤（CCA）区分开;S－8引物（Fig.2)可区分开红鲤（RC）和镜锂（MC）;S－45引物（Fig.3)可区分开RC和CA;S－22引物则可区分开CAA和CCA。六种生物型均存在基因组特异性的图谱即各种独特的“诊断性”图谱,作者由此建立了详细的分子标记检索表（Table1）。通过对RAPD图谱的量化分析。利用UPGMA构建了不同生物型的遗传关系树图,反映了鲤鲫及各种组合生物型之间的遗传相似关系:RC的MC属同一种系,聚为一族;CAA和CA基因组类型相同,聚为一族;CCA虽自成一体,但可与各种生物型内个体间的遗传相似率均大于群体间的（P＜0．05）。此外,本研究还对基因剂量效应对PAPD扩增图谱的影响进行了探讨。综合以上结果,RAPD技术有简捷,灵魂、花费少等特点、在鱼类品系鉴定和遗传多态性研究方面具有血型血清学和蛋白质多态性等其它技术无可比拟的优势。     

酿酒酵母基因组学研究进展

酿酒酵母是第一个完成基因组测序的真核生物,在基因组序列信息研究上取得了重大的进展,并且成为后基因组研究的主要模式材料,在基因功能、转录组、蛋白质组等方面获得了许多重要的成果,为高等生物,以及人基因组的研究提供了很好的借鉴,并为深入认识酵母以及生命的进化提供了基本的信息。     

家畜基因组选择研究进展

近年来,随着基因芯片技术的发展与育种技术的进步,动植物的基因组选择成为研究热点。在家畜育种中,基因组选择凭借其准确性高、世代间隔短和育种成本低等优势被应用于各种经济动物的种畜选择中。本文详细介绍了基因分型技术和基因组育种值估计方法(最小二乘法、RR-BLUP法、GBLUP法、ssGBLUP法、贝叶斯A法、贝叶斯B法等),并对这些育种方法选用的标记范围、准确性以及计算速度进行了比较,总结了我国和其他国家基因组选择在种畜选择中的应用情况及存在的问题,展望了目前国内外在基因组选择上的最新研究动态及进展,以期为其他育种工作者进一步了解基因组选择提供参考。     

群体基因组结构变异检测工作流

结构变异作为人类基因组上的一种大规模的变异类型,对分子与细胞进程、调节功能、基因表达调控、个体表型具有重要的影响,检测群体中基因组结构变异有助于绘制群体基因组变异图谱,刻画群体遗传进化特征,为疾病诊治、精准医疗的发展提供支撑。本研究提出一种面向高通量测序的群体基因组结构变异检测工作流,该工作流通过使用多种高性能基因组结构变异检测算法实现全面、精准的结构变异挖掘,使用多层融合与过滤获得高精度群体结构变异候选集合,利用基因型重新校正、变异修剪、类型校对,最终完整绘制群体基因组结构变异图谱。基于该工作流对由267个样本组成的人群进行群体结构变异检测,检测出了96 202个结构变异,其变异种类和频率分布与其他国际基因组计划相符,这些结果证明了本工作流具有良好的群体结构变异检测能力。同时,工作流通过并行的方式在内存可控的基础上显著降低了分析时间,为大规模人群基因组结构变异的高效检测提供了重要支撑。     

桃基因组及全基因组关/联分析研究进展

桃(Prunus persica [L.] Batsch)是蔷薇科重要的核果类果树, 适应性强, 栽培范围广, 果实口感好, 深受消费者喜欢。提高桃果实品质及增加抗病、抗虫性一直是桃遗传育种者关注的焦点。文章对近年来桃遗传分子标记连锁图谱和物理图谱构建、分子标记开发应用、全基因组和转录组测序工作中所取得的最新成果进行综述, 同时阐述了高密度SNP芯片标记技术在桃以及其它作物上所开展的全基因组关联分析应用实例, 为桃进一步开展全基因组关联分析, 挖掘目标性状QTLs以及高效育种选择标记提供理论基础     

绵羊基因组研究进展

过去几年中,家畜基因组计划取得了巨大进展。已经构建了猪、鸡、牛、绵羊、马、鹿的遗传图谱,其遗传标记间距在5～20cM。这些图谱对于家畜中与重要经济性状相关的基因或遗传标记的鉴定非常重要。该文从绵羊的基因图谱、比较图谱、重要经济性状基因及QTL定位方面对绵羊基因组的研究进展作了简要阐述。 Abstract:During the last few years,advances in livestock genome projects have been remarkable.Species-specific genetic maps exist for pig,chicken,cattle,sheep,horse,and deer with marker intervals of 5 to 20 cM.These maps have been essential for the identification of genes and genetic markers associated with importantly economic traits in livestock.In this paper,advances of gene map,comparative map,the genes for importantly economic traits and quantitative trait loci (QTL) mapping were briefly introduced in sheep.     

鸡基因组研究进展

随着人类基因组计划实施而开展的动物基因组计划受到了科学界和各国政府的支持. 无论是作为一种实验用模式生物,还是作为一种农业经济动物,鸡都有着独特的生物学特性和经济学价值,因此,开展鸡基因组研究是十分有意义的. 综述了近年来鸡基因组研究（包括鸡基因组的有关参数、遗传连锁图、物理图谱、比较定位、表达序列标签和数量性状座位定位等方面）所取得的成就并对其前景进行了讨论.     

水产动物遗传连锁图谱的研究现状及应用展望

综述了近年来遗传连锁图谱在水产生物中的研究现状,包括作图群体、作图方法等,并对连锁图谱的应用前景作了展望,指出其在分子标记辅助育种、基因定位与克隆及比较基因组学等方面的应用潜力。 Abstract:Constructing genetic linkage map is an essential tool to acknowledge genome in aquaculture species.This paper has reviewed the current status of genetic linkage map research,including mapping population,mapping method and molecular markers used to construct linkage map.Linkage map has great potential in marker assisted selection (MAS),gene locating and cloning,and comparative genome mapping.Genetic linkage map with high density and wide coverage of genome will allow cloning the genes which contribute to economically important traits.The ultimate aim of the constructing linkage map is the development of fast-growing,disease-resistant strains of the major aquaculture species.     

SCA10 and ATTCT repeat expansion: clinical features and molecular aspects

Analysis of the horse genome is proceeding at a rapid pace. Within a short span of 6-7 years, approximately 1,500 markers have been mapped in horse, of which at least half are genes/ESTs. Health, performance and phenotypic characteristic are of major concern/interest to horse breeders and owners. Current efforts to analyze the equine genome are primarily aimed at developing critical resources (including an advanced gene map) that could readily be used in the near future to i) identify genes and mutations responsible for inherited equine diseases/disorders and to formulate approaches for accurate diagnostics, therapeutics and prevention, ii) discover genes associated with various other traits of significance, e.g. fertility, disease resistance, coat color and athletic performance etc., and iii) use functional genomic approaches to identify gene regulatory events involved in the manifestation of various diseases.     

A 4,103 marker integrated physical and comparative map of the horse genome

A comprehensive second-generation whole genome radiation hybrid (RH II), cytogenetic and comparative map of the horse genome (2n = 64) has been developed using the 5000rad horse x hamster radiation hybrid panel and fluorescence in situ hybridization (FISH). The map contains 4,103 markers (3,816 RH; 1,144 FISH) assigned to all 31 pairs of autosomes and the X chromosome. The RH maps of individual chromosomes are anchored and oriented using 857 cytogenetic markers. The overall resolution of the map is one marker per 775 kilobase pairs (kb), which represents a more than five-fold improvement over the first-generation map. The RH II incorporates 920 markers shared jointly with the two recently reported meiotic maps. Consequently the two maps were aligned with the RH II maps of individual autosomes and the X chromosome. Additionally, a comparative map of the horse genome was generated by connecting 1,904 loci on the horse map with genome sequences available for eight diverse vertebrates to highlight regions of evolutionarily conserved syntenies, linkages, and chromosomal breakpoints. The integrated map thus obtained presents the most comprehensive information on the physical and comparative organization of the equine genome and will assist future assemblies of whole genome BAC fingerprint maps and the genome sequence. It will also serve as a tool to identify genes governing health, disease and performance traits in horses and assist us in understanding the evolution of the equine genome in relation to other species.     

RAD-seq技术在基因组研究中的现状及展望

Restriction-site associated DNA sequencing(RAD-seq)技术是在二代测序基础上发展起来的一项基于全基因组酶切位点的简化基因组测序技术。该方法技术流程简单, 不受有无参考基因组的限制, 可大大简化基因组的复杂性, 减少实验费用, 通过一次测序就可以获得数以万计的多态性标记。目前, RAD-seq技术已成功应用于超高密度遗传图谱的构建、重要性状的精细定位、辅助基因组序列组装、群体基因组学以及系统发生学等基因组研究热点领域。文章主要介绍了RAD-seq的技术原理、技术发展及其在基因组研究中的广泛应用。鉴于RAD-seq方法的独特性, 该技术必将在复杂基因组研究领域具有广泛的应用前景。     

Integrated genome sequence and linkage map of physic nut (Jatropha curcas L.), a biodiesel plant

The family Euphorbiaceae includes some of the most efficient biomass accumulators. Whole genome sequencing and the development of genetic maps of these species are important components in molecular breeding and genetic improvement. Here we report the draft genome of physic nut (Jatropha curcas L.), a biodiesel plant. The assembled genome has a total length of 320.5 Mbp and contains 27 172 putative protein‐coding genes. We established a linkage map containing 1208 markers and anchored the genome assembly (81.7%) to this map to produce 11 pseudochromosomes. After gene family clustering, 15 268 families were identified, of which 13 887 existed in the castor bean genome. Analysis of the genome highlighted specific expansion and contraction of a number of gene families during the evolution of this species, including the ribosome‐inactivating proteins and oil biosynthesis pathway enzymes. The genomic sequence and linkage map provide a valuable resource not only for fundamental and applied research on physic nut but also for evolutionary and comparative genomics analysis, particularly in the Euphorbiaceae.     

Single linkage group per chromosome genetic linkage map for the horse, based on two three-generation, full-sibling, crossbred horse reference families

A genetic linkage map of the horse consisting of 742 markers, which comprises a single linkage group for each of the autosomes and the X chromosome, is presented. The map has been generated from two three-generation full-sibling reference families, sired by the same stallion, in which there are 61 individuals in the F2 generation. Each linkage group has been assigned to a chromosome and oriented with reference to markers mapped by fluorescence in situ hybridization. The average interval between markers is 3.7 cM and the linkage groups collectively span 2772 cM. The 742 markers comprise 734 microsatellite and 8 gene-based markers. The utility of the microsatellite markers for comparative mapping has been significantly enhanced by comparing their flanking sequences with the human genome sequence; this enabled conserved segments between human and horse to be identified. The new map provides a valuable resource for genetically mapping traits of interest in the horse.     

Congruent population structure across paralogous and nonparalogous loci in Salish Sea chum salmon (Oncorhynchus keta)

Whole‐genome duplications are major evolutionary events with a lasting impact on genome structure. Duplication events complicate genetic analyses as paralogous sequences are difficult to distinguish; consequently, paralogs are often excluded from studies. The effects of an ancient whole‐genome duplication (approximately 88 MYA) are still evident in salmonids through the persistence of numerous paralogous gene sequences and partial tetrasomic inheritance. We use restriction site‐associated DNA sequencing on 10 collections of chum salmon from the Salish Sea in the USA and Canada to investigate genetic diversity and population structure in both tetrasomic and rediploidized regions of the genome. We use a pedigree and high‐density linkage map to identify paralogous loci and to investigate genetic variation across the genome. By applying multivariate statistical methods, we show that it is possible to characterize paralogous loci and that they display similar patterns of population structure as the diploidized portion of the genome. We find genetic associations with the adaptively important trait of run‐timing in both sets of loci. By including paralogous loci in genome scans, we can observe evolutionary signals in genomic regions that have routinely been excluded from population genetic studies in other polyploid‐derived species.