作物数量性状基因图位克隆研究进展

对数量性状基因(QTL)的鉴定和克隆不仅有利于从分子水平上阐明作物重要农艺性状的形成机理,而且对于有效开展这些性状的分子育种,进一步提高作物增产潜力具有重要意义.近年来作物QTL图位克隆取得了重要突破,一批QTL被成功克隆,而模式植物基因组研究的快速发展则为作物QTL图位克隆技术带来了新的策略和方法.本文就相关研究的主要进展和发展趋势进行了综述.     

基因组细菌人工染色体文库(BAC)的构建及应用

细菌人工染色体 (BAC)是一种承载DNA大片段的克隆载体系统 ,用于人、动物和植物基因组文库构建。BAC具有插入片断大、嵌合率低、遗传稳定性好、易于操作等优点。BAC文库的构建是基因组较大的真核生物基因组学研究的重要基础 ,可用于真核生物重要基因及全基因组物理作图、重要性状基因的图位克隆、基因结构及功能分析。本文主要综述了细菌人工染色体的构建与其鉴定 ,及其在物理图谱构建、图位克隆、转基因技术等研究上的应用。     

细菌人工染色体的研究和应用

细菌人工染色体 (Bacterialartificialchromosome ,BAC)是第二代大片段DNA的克隆载体系统。因其嵌合率低 ,遗传稳定性好 ,重组DNA容易分离和制备 ,转化效率高等 ,弥补了YAC的不足 ,很快在基因组研究中处于中心地位。近年来 ,已有多种BAC载体被构建出来 ,这些BAC载体在复杂基因组大片段文库的构建 ,基因的图位克隆 ,基因组物理图谱的构建 ,基因和基因组测序 ,基因组织结构分析 ,染色体组织和进化 ,以及基因的遗传转化和调控研究中得到了广泛的应用。     

基因克隆技术的研究进展

为能快速而准确地克隆目的基因,综述了一些基因克隆常用技术,包括差异表达基因分离技术、转座子标签技术、图位克隆技术、同源序列技术、表达序列标签技术的原理、应用及应用潜力,并对其作了简要的评价.这些技术有利有弊,应根据不同的实验目的和水平来选择相应的技术.     

植物基因的图位克隆

图位克隆是基因的有效方法,本文概述了植物基因图位克隆的研究进展,主要包括图位克隆的一般策略、相关技术、发展前景和其它基因组领域研究于其带来的有益借鉴。     

图位基因克隆

图位基因克隆是最近几十年中发展并逐步完善起来的基因分离及研究方法。紧密连锁分子标记的获得及ＤＮＡ大片段克隆文库的建立是顺利进行图位基因克隆的重要条件,而对于那些数量性状基因（ＱＴＬｓ）的克隆更显示了其优越性。     

BAC克隆及复杂基因组文库技术

BAC（细菌人工染色体）克隆技术是复杂基因组研究中不可缺少的工具,有关基因组研究的许多技术都是由BAC为基础发展起来的,包括大片段基因组文库的构建、重叠群的构建、全基因测序及图位基因克隆等,后又产生植物转基因的BAC克隆载体,这在人类、动物、植物等基因组研究中已广泛应用,取得令人瞩目的成就,该文将就这些研究技术及进展作一综述。     

重叠克隆群的研究进展

重叠克隆群的研究近年来取得了迅速发展,并被进一步运用到基因组测序、基因精确定位、基因图位克隆以及基因组织结构与功能研究等方面。本文着重讨论了构建重叠克隆群的策略、一般过程,同时也对构建重叠克隆群过程中存在的问题、解决方法及发展前景进行了论述。     

图位克隆技术在分离植物基因中的应用

本文综述图位克隆技术的原理及基本技术环节,并与其它基因克隆技术相比较说明图位克隆技术的优缺点。本文还对近年来图位克隆技术在分离不同的植物发育基因上的广泛应用进行了简要概述,并对其应用前景和近期的预期进展作出展望。 Abstract:In this review,the principle and basis steps of map-based gene cloning on plant were introduced in detail.At the same time,the advantages and disadvantage of the method were evaluated as compared with the other methods.The extensive application of the map-based gene cloning method on cloning genes of different plants in the past was also summarized in brief.The prospect and the expected progress in several years were proposed in this paper.     

全基因组关联分析实现水稻粒型自然变异的分子解析

全基因组关联分析(GWAS)近年来被广泛应用于解析生物自然变异的遗传基础。但限于其遗传定位精度, 在水稻(Oryza sativa)遗传学研究中, 该方法尚无法取代传统的图位克隆法在克隆复杂性状调控基因中的作用。近期, 中国科学家在应用GWAS等大数据来克隆控制水稻粒长和粒重等复杂性状的QTL方面取得了新突破。     

Mapping in the realm of polyploidy: The wheat model

Wheat is an allopolyploid containing three distinct but genetically related (homoeologous) genomes, A, B and D. Because of polyploid inheritance and large genome size (16×10¹² bp), the wheat genome is thought to be intractable to map-based cloning of agronomic and other genes of interest. We propose a targeted geneti mapping strategy that combines linkage and physical mapping and may facilitate map-based cloning. High-density linkage maps are either generated in wheat or in diploid Triticum tauschii, the donor of the D genome to wheat. Molecular marker-based chromosome maps are constructed, using an array of deletion lines in wheat. The conventional genetic linkage maps are aligned with chromosome maps to construct cytogenetic ladder maps (CLMs). The CLMs allow region-specific mapping and convert genetic distances into physical distances. The information from CLMs suggests that many genes in wheat are present in clusters that are highly recombiogenic, small, and may be amenable to cloning by chromosome walking. Therefore, the effective genome size of wheat is relatively small in comparison to the whole genome. The utility of using the smaller genome of rice for mapping and homologous gene cloning is discussed.     

Rice molecular genetic map using RFLPs and its applications

In the past decade, notable progress has been made in rice molecular genetic mapping using genomic or cDNA clones. A total of over 3000 DNA markers, mainly with RFLPs, have been mapped on the rice genome. In addition, many studies related to tagging of genes of interest, gene isolation by map-based cloning and comparative mapping between cereal genomes have advanced along with the development of a high-density molecular genetic map. Thus rice is considered a pivotal plant among cereal crops and, in addition to Arabidopsis, is a model plant in genome analysis. In this article, the current status of the construction of rice molecular genetic maps and their applications are reviewed.     

A high density physical map of chromosome 1BL supports evolutionary studies,map-based cloning and sequencing in wheat

Background

As for other major crops, achieving a complete wheat genome sequence is essential for the application of genomics to breeding new and improved varieties. To overcome the complexities of the large, highly repetitive and hexaploid wheat genome, the International Wheat Genome Sequencing Consortium established a chromosome-based strategy that was validated by the construction of the physical map of chromosome 3B. Here, we present improved strategies for the construction of highly integrated and ordered wheat physical maps, using chromosome 1BL as a template, and illustrate their potential for evolutionary studies and map-based cloning.

Results

Using a combination of novel high throughput marker assays and an assembly program, we developed a high quality physical map representing 93% of wheat chromosome 1BL, anchored and ordered with 5,489 markers including 1,161 genes. Analysis of the gene space organization and evolution revealed that gene distribution and conservation along the chromosome results from the superimposition of the ancestral grass and recent wheat evolutionary patterns, leading to a peak of synteny in the central part of the chromosome arm and an increased density of non-collinear genes towards the telomere. With a density of about 11 markers per Mb, the 1BL physical map provides 916 markers, including 193 genes, for fine mapping the 40 QTLs mapped on this chromosome.

Conclusions

Here, we demonstrate that high marker density physical maps can be developed in complex genomes such as wheat to accelerate map-based cloning, gain new insights into genome evolution, and provide a foundation for reference sequencing.     

Advanced resources for plant genomics: a BAC library specific for the short arm of wheat chromosome 1B

Common wheat (Triticum aestivum L., 2n = 6x = 42) is a polyploid species possessing one of the largest genomes among the cultivated crops (1C is approximately 17 000 Mb). The presence of three homoeologous genomes (A, B and D), and the prevalence of repetitive DNA make sequencing the wheat genome a daunting task. We have developed a novel 'chromosome arm-based' strategy for wheat genome sequencing to simplify this task; this relies on sub-genomic libraries of large DNA inserts. In this paper, we used a di-telosomic line of wheat to isolate six million copies of the short arm of chromosome 1B (1BS) by flow sorting. Chromosomal DNA was partially digested with HindIII and used to construct an arm-specific BAC library. The library consists of 65 280 clones with an average insert size of 82 kb. Almost half of the library (45%) has inserts larger than 100 kb, while 18% of the inserts range in size between 75 and 100 kb, and 37% are shorter than 75 kb. We estimated the chromosome arm coverage to be 14.5-fold, giving a 99.9% probability of identifying a clone corresponding to any sequence on the short arm of 1B. Each chromosome arm in wheat can be flow sorted from an appropriate cytogenetic stock, and we envisage that the availability of chromosome arm-specific BAC resources in wheat will greatly facilitate the development of ready-to-sequence physical maps and map-based gene cloning.     

Beyond complementation. Map-based cloning in Chlamydomonas reinhardtii

Chlamydomonas reinhardtii is an excellent model system for plant biologists because of its ease of manipulation, facile genetics, and the ability to transform the nuclear, chloroplast, and mitochondrial genomes. Numerous forward genetics studies have been performed in Chlamydomonas, in many cases to elucidate the regulation of photosynthesis. One of the resultant challenges is moving from mutant phenotype to the gene mutation causing that phenotype. To date, complementation has been the primary method for gene cloning, but this is impractical in several situations, for example, when the complemented strain cannot be readily selected or in the case of recessive suppressors that restore photosynthesis. New tools, including a molecular map consisting of 506 markers and an 8X-draft nuclear genome sequence, are now available, making map-based cloning increasingly feasible. Here we discuss advances in map-based cloning developed using the strains mcd4 and mcd5, which carry recessive nuclear suppressors restoring photosynthesis to chloroplast mutants. Tools that have not been previously applied to Chlamydomonas, such as bulked segregant analysis and marker duplexing, are being implemented to increase the speed at which one can go from mutant phenotype to gene. In addition to assessing and applying current resources, we outline anticipated future developments in map-based cloning in the context of the newly extended Chlamydomonas genome initiative.     

Gene identification using rice genome sequences

Identifying useful gene(s) is one of the most important objectives of plant geneticists. Various strategies can be used, which are based on the characteristics of plant reproduction and available technology. Rice is the first model crop whose whole genome sequence has been reported. In addition, information on the whole genome sequences of two important rice subspecies (japonica and indica rice) is also available. Rice is a self-pollinating crop and methods of artificial crossing are relatively easy to perform; such methods enable the production of numerous seeds for genetic analyses. Based on these features, a map-based cloning (i.e., positional cloning) strategy has been successfully applied over the last decade to identify rice genes. Recently, advanced next-generation sequencing (NGS) technology was used to ascertain the genome sequences of individual plants, opening up a new strategy for gene identification. This strategy has been used successfully to identify the genes responsible for certain qualitative traits in rice. However, to identify the gene(s) involved in a quantitative trait, a map-based cloning strategy is still required after quantitative trait loci analysis using NGS technology. In this review, we discuss both map-based cloning (which is still the primary strategy used to identify rice genes) and NGS-based strategies.     

Assessing the level of collinearity between Arabidopsis thaliana and Brassica napus for A. thaliana chromosome 5.

This study describes a comprehensive comparison of chromosome 5 of the model crucifer Arabidopsis with the genome of its amphidiploid crop relative Brassica napus and introduces the use of in silico sequence homology to identify conserved loci between the two species. A region of chromosome 5, spanning 8 Mb, was found in six highly conserved copies in the B. napus genome. A single inversion appeared to be the predominant rearrangement that had separated the two lineages leading to the formation of Arabidopsis chromosome 5 and its homologues in B. napus. The observed results could be explained by the fusion of three ancestral genomes with strong similarities to modern-day Arabidopsis to generate the constituent diploid genomes of B. napus. This supports the hypothesis that the diploid Brassica genomes evolved from a common hexaploid ancestor. Alignment of the genetic linkage map of B. napus with the genomic sequence of Arabidopsis indicated that for specific regions a genetic distance of 1 cM in B. napus was equivalent to 285 Kb of Arabidopsis DNA sequence. This analysis strongly supports the application of Arabidopsis as a tool in marker development, map-based gene cloning, and candidate gene identification for the larger genomes of Brassica crop species.     

主要禾谷类作物比较基因组学研究策略与进展

随着拟南芥、水稻等模式植物基因组测序计划的完成, 比较基因组学作为一门新兴学科, 近年来发展迅速, 为植物基因组的进化、结构和功能研究开辟了新的途径。文章综述了比较基因组学在作物比较遗传作图、基因结构区域的微共线性、ESTs和蛋白质水平的比较以及基于比较基因组学的基因和QTL的克隆等方面内容与研究进展, 分析了不同水平上比较基因组学研究策略的原理、特点、可行性, 以期为利用模式生物的基因和基因组数据、采用比较基因组学策略克隆作物重要性状功能基因、阐明基因组结构与进化提供帮助。     

细菌人工染色体文库的构建及应用

细菌人工染色体（BAC）是第二代大片段DNA的克隆载体系统,具有容量大、嵌合率低、遗传特性稳定、转化效率高、插入片段易回收、操作简便等优点,因而被广泛应用于基因组较大的真核生物基因组研究中,并发挥着前所未有的重要作用。本文综述了BAC的发展,利用此载体构建基因组文库的程序和鉴定方法,及其在物理图谱构建、图位克隆、基因组测序、转基因技术等研究中的应用。