EST分子标记开发及在比较基因组学中的应用

数量迅速增加的EST(expressed sequence tags)为分子标记的开发提供了宝贵的资源。与来自于基因组DNA开发的传统标记相比,以EST为基础的分子标记是一种新型分子标记,具有其显著的优势,如开发简便、信息量高和通用性好等,在多方面都有重要的利用价值。本文详细地介绍了目前基于EST开发的5类分子标记以及基于生物信息学方法的开发策略,这些标记包括EST-PCR、EST-SSR、EST-SNP、EST-RFLP和EST-AFLP。此外,对这些标记在比较基因组学研究中的应用进行了评述,包括比较作图、遗传多样性评价及系统发育研究等。     

葫芦科主要瓜类作物EST-SSR标记的开发与应用

与基因组SSR(gSSR)相比,基于EST开发的SSR(EST-SSR)成本低,物种间通用性更强,同时EST-SSR来源于基因编码区,可以作为功能基因的直接标记,因此EST-SSR的开发和应用逐渐受到人们的重视.就葫芦科主要瓜类作物(西瓜、甜瓜和黄瓜)EST-SSR的研究进展进行回总结,并预测和探讨了EST-SSR标记的发展趋势,以期为今后该种新型分子标记在瓜类作物上的应用提供参考.     

功能性分子标记在小麦育种中的应用

功能标记是根据与表型紧密相关的功能基因内部特定区域的多态性序列,利用关联分析、表达谱分析、RNA干扰和QTL作图等方法开发而出的一种新型显性分子标记,此类标记可以对不同遗传背景下目标等位基因的有无作直接、快速的判定。简单介绍了功能标记的概念及特点,着重探讨功能标记作为一种辅助育种手段在小麦育种中的应用及其开发前景,以期为相关分子标记的开发提供参考。     

小麦抗赤霉病研究现状与展望

小麦是我国最重要的口粮作物之一。在小麦生产所面临的各种病害中,赤霉病的发生具有愈来愈严重的趋势,引起小麦产业界的高度关注。近几十年来,科研人员在小麦抗赤霉病遗传育种以及防控技术领域进行了持续不懈的努力,在赤霉病病原菌致病基因、小麦赤霉病抗性基因定位、克隆及功能研究以及抗赤霉病分子育种等方面取得了重大进展。本文主要从赤霉病抗性基因资源的发掘和鉴定、不同抗源遗传基础解析、小麦赤霉病抗性基因、抗赤霉病分子标记辅助选择育种与基因聚合以及小麦抗赤霉病基因的克隆和功能研究等方面进行了综述,分析了目前小麦抗赤霉病研究中存在的问题,并提出应加强基因克隆、功能分子标记开发以及应用单体型辅助选择(HAS)和标记组辅助选择(MSAS)等小麦抗赤霉病研究的相关建议。     

EST-SSR及其在植物基因组学研究中的应用

数量迅速增加的表达序列标签已经成为开发分子标记的重要资源。EST—SSR是基于表达序列标签开发微卫星的一种新型分子标记,与基因组SSR相比,EST-SSR具有在植物物种之间可转移性的优点。目前,EST—SSR被广泛应用于植物基因组学研究如遗传图谱构建、比较作图、遗传多样性评价、种质鉴定、系统发育与进化研究等方面。该文介绍了EST—SSR原理、引物开发、实验方法,并对其物种间通用性以及其在植物基因组研究中的应用进行了评述。     

一种新的DNA分子标记技术——起始密码子-微卫星扩增多态性

综合SCoT和ISSR分子标记技术开发了一种既能将标记位点与表达序列紧密联系,又具有相对较高的多态性的新的分子标记技术——起始密码子一微卫星扩增多态性（start codon-simple sequence repeat, SC-SSR）。SC—SSR标记是基于PCR的目的基因标记系统．上游引物用SCoT标记引物,瞄准基因区域,下游引物用ISSR标记引物,上下游引物间可自由组配。引物设计原则同SCoT标记和ISSR标记。使用50℃的退火温度,保证了扩增结果的稳定性。PCR结果采用琼脂糖凝胶电冰和聚丙烯酰胺凝胶电泳检测。SC—SSR分子标记结合了ISSR标记和SCoT标记的优点,具有操作简单、成本低廉、多态性丰富、重复性好、引物设计简单且通用性良好、同时与表达序列紧密连锁等诸多优点,可用于种质资源的鉴定评价、遗传图谱的构建、重要性状基因标记、gDNA与cDNA指纹分析乃至图位克隆等方面。     

玉米抗病虫性的分子标记研究进展

本文评述了近十年来利用分子标记研究玉米抗病虫性的进展,主要论述了抗病虫性基因定位中出现的问题、通过分子标记研究这些基因在基因组中的分布和基因组结构等,提出了玉米抗病虫性基因的标记和定位的发展方向和策略。     

玉米抗病虫性的分子标记研究进展

本文评述了近十年来利用分子标记研究玉米抗病虫性的进展。主要论述了抗病虫性基因定位中出现的问题、通过分子标记研究这些基因在基因组中的分布和基因组结构等,提出了玉米抗病虫性基因的标记和定位的发展方向和策略。     

向日葵分子生物学研究进展

向日葵是一种营养价值极高的资源植物,向日葵的研究和生产在当前我国中西部大开发的战略中具有重要的意义。本文对近年来国内外向日葵分子生物学研究的最新进展,在蛋白质、酶、基因及基因工程、分子标记等方面进行了综述。特别对生化标记、分子标记技术在向日葵研究上的应用及所取得的成果作了重点介绍,并对今后向日葵研究工作进行了展望。     

向日葵分子生物学研究进展

向日葵是一种营养价值极高的资源植物,向日葵的研究和生产在当前我国中西部大开发的战略中具有重要的意义。本文对近年来国内外向日葵分子生物学研究的最新进展,在蛋白质、酶、基因及基因工程、分子标记等方面进行了综述。特别对生化标记、分子标记技术在向日葵研究上的应用及所取得的成果作了重点介绍,并对今后向日葵研究工作进行了展望。     

重要花卉植物高密度遗传连锁图谱构建研究进展

遗传连锁图谱是以遗传标记间重组频率为基础的染色体或基因组内位点相对位置的线性排列图,高密度遗传图谱构建可实现物理图谱和遗传图谱的整合,对促进基因图位克隆具有重要作用。利用遗传图谱可有效地提高育种效率和改良品种。重要花卉植物高遗传图谱精密度尚无法满足精细定位研究的要求,百合、紫薇、郁金香、向日葵等重要花卉高密度遗传图谱构建研究较少,制约了花卉植物分子育种研究进程。概述了高密度遗传图谱构建流程及作图方法,综述了牡丹、梅花、月季、菊花、兰花、荷花、桂花等重要花卉植物遗传图谱构建研究进展,讨论了重要花卉植物高密度遗传图谱构建存在的主要问题,对今后重要花卉植物遗传图谱构建研究的发展方向及其在育种中的应用前景进行了展望,以期为花卉植物基因定位、辅助基因组组装、比较基因组学、基因克隆、分子标记辅助育种等提供参考。     

High-Throughput Genomics Enhances Tomato Breeding Efficiency

Tomato (Solanum lycopersicum) is considered a model plant species for a group of economically important crops, such as potato, pepper, eggplant, since it exhibits a reduced genomic size (950 Mb), a short generation time, and routine transformation technologies. Moreover, it shares with the other Solanaceous plants the same haploid chromosome number and a high level of conserved genomic organization. Finally, many genomic and genetic resources are actually available for tomato, and the sequencing of its genome is in progress. These features make tomato an ideal species for theoretical studies and practical applications in the genomics field. The present review describes how structural genomics assist the selection of new varieties resistant to pathogens that cause damage to this crop. Many molecular markers highly linked to resistance genes and cloned resistance genes are available and could be used for a high-throughput screening of multiresistant varieties. Moreover, a new genomics-assisted breeding approach for improving fruit quality is presented and discussed. It relies on the identification of genetic mechanisms controlling the trait of interest through functional genomics tools. Following this approach, polymorphisms in major gene sequences responsible for variability in the expression of the trait under study are then exploited for tracking simultaneously favourable allele combinations in breeding programs using high-throughput genomic technologies. This aims at pyramiding in the genetic background of commercial cultivars alleles that increase their performances. In conclusion, tomato breeding strategies supported by advanced technologies are expected to target increased productivity and lower costs of improved genotypes even for complex traits.Key Words: Solanum lycopersicum, genetic and genomic resources, molecular markers, microarray, resistance to pathogens, fruit quality.     

大麦基因组和分子育种研究进展

大麦(Hordeum vulgare L.)是世界上重要的谷类作物之一,其二倍体特性使其成为麦类作物基因组研究的重要材料。随着大量分子标记图谱、BACs文库、突变集合和DNA阵列技术的应用,大麦基因组测序工作已不断深入,越来越多的大麦基因组信息使综合分析大麦基因组结构和功能,了解基因表达网络同重要农艺性状之间的关系成为可能。就大麦基因组研究内容,如ESTs系统、物理图谱的构建、功能基因组学研究和大麦分子育种研究作简要综述,为进一步阐述大麦基因组结构和功能特性,提高大麦分子育种能力提供理论依据。     

单核苷酸多态性及其在油菜分子标记辅助育种中的应用

油菜是一种重要的油料作物,油菜的基因组功能研究已引起了各国政府和科研工作者的高度重视。SNP是目前为止分布最广泛,存在数量最多且标记密度最高的一种遗传多态性标记。对油菜等作物的基因组功能研究提供了丰富的信息资源。综述了近来单核苷酸多态性的研究进展以及其在油菜的分子标记辅助品质育种中的可能用途。     

分子标记在绿豆遗传连锁图谱构建和基因定位研究中的应用

绿豆(Vigna radiata(L.)Wilczek)作为一种医食两用作物,不仅是重要的食物资源,在改善土壤环境、提高农民收入等方面也发挥着重要作用。然而,相对于大宗作物而言,绿豆基础研究薄弱,基因组研究更是落后。近年来,分子标记技术迅速发展,在绿豆基因组学研究中发挥了重要的作用。国内外利用分子标记技术已构建了超过20张绿豆遗传连锁图谱。一些优良基因尤其是与抗性相关的基因被鉴定或精细定位,为绿豆分子标记辅助选择打下基础,加快了抗性新品种的培育进程。本研究通过对分子标记技术在绿豆遗传连锁图谱构建、重要功能基因的定位等方面的应用进行综述,以期为绿豆遗传育种研究及功能基因组学分析提供参考。     

How Can We Use Genomics to Improve Cereals with Rice as a Reference Genome?

Rice serves as a model crop for cereal genomics. The availability of complete genome sequences, together with various genomic resources available for both rice and Arabidopsis, have revolutionized our understanding of the genetic make-up of crop plants. Both macrocolinearity revealed by comparative mapping and microcolinearity revealed by sequence comparisons among the grasses indicate that sequencing and functional analysis of the rice genome will have a significant impact on other cereals in terms of both genomic studies and crop improvement. The availability of mutants, introgression libraries, and advanced transformation techniques make functional genomics in rice and other cereals more manageable than ever before. A wide array of genetic markers, including anchor markers for comparative mapping, SSRs and SNPs are widely used in genetic mapping, germplasm evaluation and marker assisted selection. An integrated database that combines genome information for rice and other cereals is key to the effective utilization of all genomics resources for cereal improvement. To maximize the potential of genomics for plant breeding, experiments must be further miniaturized and costs must be reduced. Many techniques, including targeted gene disruption or allele substitution, insertional mutagenesis, RNA interference and homologous recombination, need to be refined before they can be widely used in functional genomic analysis and plant breeding.     

燕麦基因组学研究进展

燕麦具有较高的营养价值和保健功能,是一种可用于均衡营养、科学饮食的健康食品,正逐渐受到人们的青睐和认可。基因组学研究有助于燕麦重要农艺性状的定位和克隆,对开发利用燕麦优质种质资源具有重要意义。本文从以下几个方面对燕麦基因组学研究进展进行综述:(1)燕麦属基因组类型、大小及染色体倍性研究;(2)基于多种分子标记手段构建燕麦基因组遗传图谱进展;(3)二倍体、六倍体燕麦基因组测序进展;(4)基于数量性状基因座定位和全基因组关联性分析手段对燕麦基因组功能基因的注释研究;(5)燕麦群体基因组/泛基因组学研究。同时对燕麦基因组学研究方向进行了探讨,以期为今后燕麦遗传育种提供参考信息。     

Molecular approaches for improvement of medicinal and aromatic plants

Medicinal and aromatic plants (MAPs) are important sources for plant secondary metabolites, which are important for human healthcare. Improvement of the yield and quality of these natural plant products through conventional breeding is still a challenge. However, recent advances in plant genomics research has generated knowledge leading to a better understanding of the complex genetics and biochemistry involved in biosynthesis of these plant secondary metabolites. This genomics research also concerned identification and isolation of genes involved in different steps of a number of metabolic pathways. Progress has also been made in the development of functional genomics resources (EST databases and micro-arrays) in several medicinal plant species, which offer new opportunities for improvement of genotypes using perfect markers or genetic transformation. This review article presents an overview of the recent developments and future possibilities in genetics and genomics of MAP species including use of transgenic approach for their improvement.     

Advances in Arachis genomics for peanut improvement

Peanut genomics is very challenging due to its inherent problem of genetic architecture. Blockage of gene flow from diploid wild relatives to the tetraploid; cultivated peanut, recent polyploidization combined with self pollination, and the narrow genetic base of the primary genepool have resulted in low genetic diversity that has remained a major bottleneck for genetic improvement of peanut. Harnessing the rich source of wild relatives has been negligible due to differences in ploidy level as well as genetic drag and undesirable alleles for low yield. Lack of appropriate genomic resources has severely hampered molecular breeding activities, and this crop remains among the less-studied crops. The last five years, however, have witnessed accelerated development of genomic resources such as development of molecular markers, genetic and physical maps, generation of expressed sequenced tags (ESTs), development of mutant resources, and functional genomics platforms that facilitate the identification of QTLs and discovery of genes associated with tolerance/resistance to abiotic and biotic stresses and agronomic traits. Molecular breeding has been initiated for several traits for development of superior genotypes. The genome or at least gene space sequence is expected to be available in near future and this will further accelerate use of biotechnological approaches for peanut improvement.