小麦及其近缘种中基因组特异性DNA重复序列的研究进展

本文对小麦族植物中基因组特异性DNA重复序列的分类、基本特征、分离和鉴定方法、在小麦遗传改良中的应用以及未来研究的发展趋势进行了简述。综合已有的研究结果可以看出基因组特异性DNA重复序列是小麦族植物基因组特异性形成的重要构成部分。对基因组特异性DNA重复序列的研究是认识小麦族植物基因组的有效途径之一,基因组特异性DNA重复序列的应用将进一步促进小麦族植物分子细胞遗传学和普通小麦遗传改良研究的进展。 Advances in Studies of Genome-Specific Repetitive DNA Sequences in Wheat and Related Species BAI Jian-rong1,2,JIA Xu1,WANG Dao-wen1 1.The State Key Laboratory of Plant Cell and Chromosome Engineering,Institute of Genetics and Developmental Biology,The Chinese Academy of Sciences,Beijing 100101,China; 2.Crop Genetics Institute,Shanxi Academy of Agricultural Sciences,Taiyuan 030031,China Abstract:In this paper we review recent advances in studies of several aspects of genome specific repetitive DNA sequences in wheat and related species.The available results demonstrate that genome specific repetitive DNA sequences are important components of genome specificity in wheat and related species.Research on genome specific repetitive DNA sequences is essential to the elucidation of genome function.The application of genome specific repetitive DNA sequences will aid molecular cytogenetic studies in wheat and related species and contributes to genetic improvement of common wheat. Key words：wheat;genome specific repetitive DNA sequence;chromosome     

E和St基因组特异RAPD片段在部分小麦族植物中的分布

两个Ｅ基因组（包括Ｅｅ和Ｅｂ）特异ＲＡＰＤ片段和两个Ｓｔ基因组特异ＲＡＰＤ片段的序列分析表明,４个片段均为新的ＤＮＡ克隆片段。染色体原位杂交显示ＯＰＤ１２４４４为区域化连续高度重复序列,而ＯＰＦ０３１２９６（Ｅｂ特异）、ＯＰＢ０８５２５（Ｓｔ特异）、ＯＰＮ０１８１７（Ｓｔ特异）为弥散性高度重复序列。研究还显示：大部分ＤＮＡ高度重复序列在亲缘关系较近的小麦族植物基因组间是共享的,差异可能主要是在重复次数及片段长度上,而能否用ＲＡＰＤ技术扩增主要决定于某一基因组的这些重复序列中有无与特定引物相匹配的区域。文中就这些重复序列在小麦远缘杂交后代外源遗传物质检测、多倍体物种染色体组组成研究中的潜在价值进行了讨论。     

玉米特异DNA通过有性杂交导入小麦DH后代的分子证据

构建了玉米的随机基因组文库,筛选了近100个玉米基因组特异的重复DNA克隆,用它们作探针分别对2个来自小麦×玉米的小麦DH群体进行RFLP分析.结果发现,玉米的MR64克隆导入到2个小麦群体的各1株后代中,即在普通小麦DH系的18号株和波斯小麦DH系的15号株中检测到强杂交信号,这个结果首次从DNA水平上证明某些玉米特异的DNA序列,可通过受精作用以很低的频率转移到小麦DH后代的基因组中.测序分析证实,克隆MR64的插入片段长度为695Pb,A+T含量为58%,用多种酶切玉米基因组进行RFLP分析表明它是一个带1～3个主串联重复单位的散布重复序列.同时还对它的序列结构、甲基化图谱、拷贝数和在玉米染色体上的分布以及在其它小麦品种和禾本科种基因组中的序列同源性情况进行了详细的研究.     

赖草(Leymus secalinus(Georgi)Tzvel.)中一个染色体标记的克隆与鉴定

通过构建Cot-1 DNA文库以及利用荧光原位杂交技术,从赖草(Leymus secalinus(Georgi)Tzvel.)中克隆获得一个在染色体多个部位具有点状杂交信号的重复序列。进一步对该序列在赖草基因组进行克隆和分析表明该序列为一个具有90 bp的重复单元(p Ls-90),并在基因组中呈串联状排列。利用p Ls-90对赖草进行分子核型分析,结果表明:p Ls-90在染色体的着丝粒、近着丝粒、臂间以及近端粒区均有分布,而且在每对染色体上信号分布模式不尽相同,结合染色体臂比可以清楚地对赖草的14对(28条)染色体进行识别。p Ls-90不仅可作为赖草种质鉴定和利用中染色体识别的理想标记,也可作为研究小麦族不同物种染色体组进化的有力工具。     

小麦WOX转录因子基因的全基因组鉴定与分析

小麦是全球主要粮食作物之一.本研究运用生物信息学技术手段对普通小麦(Triticum aestivum L.)的WOX基因进行了全基因组鉴定、系统发育树构建、序列分析.结果显示:小麦基因组一共包含了26个WOX基因,其中在Phytozome数据库中收录有序列信息的有20个,可分为3个亚族,各亚族内的WOX基因具有相似的...     

小麦族遗传资源的多样性及其保护

禾木科小麦族中包含了三种世界最重要的粮食作物,即：小麦、大麦和黑麦以及许多具有重要经济价值的牧草种类。小麦族植物种类繁多、分布广泛、生态多样,具有极其丰富的形态和遗传变异类型。作为巨大的基因资源库,小麦族植物在通过现代生物技术而导入外源有益基因的麦类作物育种程序中,具有重要和特殊的价值。然而对于小麦族植物的生物多样性的研究和了解还远远不足。同时在全球环境的不断改变和遭到破坏的今天,一些小麦族的物种已处于濒危的状态而面临灭绝,因此对于小麦族丰富的遗传多样性制定有效的措施进行保护是摆在我们面前亟待解决的课题。     

黑麦属植物的遗传学研究与利用

黑麦属植物具有许多有益基因,将其导入普通小麦对于拓宽其遗传基础具有重要作用。概述了黑麦属的分类及分布,分析了黑麦属染色体的C分带核型、DNA重复序列及其与小麦染色体间的部分同源关系,论述了黑麦有益基因导入小麦的途径及其在小麦改良中的应用,阐明了全面挖掘黑麦有益基因是未来努力的方向。     

核酸序列重复片段的统计分析

对核酸序列编码区的重复片段进行了统计分析。发现不同物种的序列具有近似相等的约化重复长度和次数,研究了重复区内碱基分布的特点,并讨论了此结果可能的生物学涵义。     

DNA重复序列的宏观分布趋势

以ＧＣＧ软件和数学模型为工具,用观察到的某ＤＮＡ序列的频数（Ｏ）与理论计算出的此序列频数（Ｔ）的比值（Ｏ／Ｔ）为参数（即相对频数）,将基因资料库（包括ＧｅｎＢａｎｋ和ＥＭＢＬＤａｔａＢａｓｅ）的ＤＮＡ序列进行了分析．结果显示ＤＮＡ重复序列的分布存在着如下趋势：（１）越简单的ＤＮＡ重复序列,其相对频数越高,离平衡分布越远;（２）顺向重复序列的分布的相对频数高于反向重复序列的分布;（３）较长的保守序列的相对频数较高;（４）含ＡＴ碱基对的重复序列的相对频数高于含ＧＣ碱基对的重复序列,在较长的ＤＮＡ重复序列中尤其明显：（５）上述ＤＮＡ重复序列分布的趋势存在种属特异性．     

乙型肝炎病毒B2和C2亚型中SSRs的比较分析

乙型肝炎病毒(hepatitis B virus,HBV)属于嗜肝DNA病毒科(hepadnaviridae),它分布在世界各地并严重危害人类的健康。本文从NCBI的GenBank中下载了106条B2亚型和130条C2亚型的基因组全长序列,以下载的数据为材料,分析简单重复序列(simple sequence repeats,SSRs)在B2和C2亚型基因组序列中的分布情况。结果显示,简单重复序列的重复次数比较少;二型简单重复序列在研究的五种简单重复序列类型中占绝对优势;这可能与B2和C2亚型基因组序列有较高的突变率有关。同时还发现最普遍的SSRs、序列间SSRs的平均相对丰度和平均相对密度在B2和C2亚型中分布情况相似。     

Phylogenetic analysis of North American Elymus and the monogenomic Triticeae (Poaceae) using three chloroplast DNA data sets.

Although the monogenomic genera of the Triticeae have been analyzed in numerous biosystematic studies, the allopolyploid genera have not been as extensively studied within a phylogenetic framework. We focus on North American species of Elymus, which, under the current genomic system of classification, are almost all allotetraploid, combining the St genome of Pseudoroegneria with the H genome of Hordeum. We analyze new and previously published chloroplast DNA data from Elymus and from most of the monogenomic genera of the Triticeae in an attempt to identify the maternal genome donor of Elymus. We also present a cpDNA phylogeny for the monogenomic genera that includes more data than, and thus builds on, those previously published. The chloroplast DNA data indicate that Pseudoroegneria is the maternal genome donor to all but one of the Elymus individuals. There is little divergence among the Elymus and Pseudoroegneria chloroplast genomes, and as a group, they show little divergence from the rest of the Triticeae. Within the monogenomic Triticeae, the problematic group Thinopyrum is resolved as monophyletic on the chloroplast DNA tree. At the intergeneric level, the data reveal several deeper-level relationships that were not resolved by previous cpDNA trees.     

Molecular-genetic maps for group 1 chromosomes of Triticeae species and their relation to chromosomes in rice and oat

Group 1 chromosomes of the Triticeae tribe have been studied extensively because many important genes have been assigned to them. In this paper, chromosome 1 linkage maps of Triticum aestivum, T. tauschii, and T. monococcum are compared with existing barley and rye maps to develop a consensus map for Triticeae species and thus facilitate the mapping of agronomic genes in this tribe. The consensus map that was developed consists of 14 agronomically important genes, 17 DNA markers that were derived from known-function clones, and 76 DNA markers derived from anonymous clones. There are 12 inconsistencies in the order of markers among seven wheat, four barley, and two rye maps. A comparison of the Triticeae group 1 chromosome consensus map with linkage maps of homoeologous chromosomes in rice indicates that the linkage maps for the long arm and the proximal portion of the short arm of group 1 chromosomes are conserved among these species. Similarly, gene order is conserved between Triticeae chromosome 1 and its homoeologous chromosome in oat. The location of the centromere in rice and oat chromosomes is estimated from its position in homoeologous group 1 chromosomes of Triticeae.     

Comparative mapping in grasses. Wheat relationships

Conventionally, the genetics of species of the family Gramineae have been studied separately. Comparative mapping using DNA markers offers a method of combining the research efforts in each species. In this study, we developed consensus maps for members of the Triticeae tribe (Triticum aestivum, T. tauschii, andHordeum spp.) and compared them to rice, maize and oat. The aneuploid stocks available in wheat are invaluable for comparative mapping because almost every DNA fragment can be allocated to a chromosome arm, thus preventing erroneous conclusions about probes that could not be mapped due to a lack of polymorphism between mapping parents. The orders of the markers detected by probes mapped in rice, maize and oat were conserved for 93, 92 and 94% of the length of Triticeae consensus maps, respectively. The chromosome segments duplicated within the maize genome by ancient polyploidization events were identified by homoeology of segments from two maize chromosomes to regions of one Triticeae chromosome. Homoeologous segments conserved across Triticeae species, rice, maize, and oat can be identified for each Triticeae chromosome. Putative orthologous loci for several simply inherited and quantitatively inherited traits in Gramineae species were identified.Communicated by H. Saedler     

Characterization of a family of tandemly repeated DNA sequences in Triticeae

The recombinant plasmid dpTa1 has an insert of relic wheat DNA that represents a family of tandemly organized DNA sequences with a monomeric length of approximately 340 bp. This insert was used to investigate the structural organization of this element in the genomes of 58 species within the tribe Triticeae and in 7 species representing other tribes of the Poaceae. The main characteristic of the genomic organization of dpTa1 is a classical ladder-type pattern which is typical for tandemly organized sequences. The dpTa1 sequence is present in all of the genomes of the Triticeae species examined and in 1 species from a closely related tribe (Bromus inermis, Bromeae). DNA from Hordelymus europaeus (Triticeae) did not hybridize under the standard conditions used in this study. Prolonged exposure was necessary to obtain a weak signal. Our data suggest that the dpTa1 family is quite old in evolutionary terms, probably more ancient than the tribe Triticeae. The dpTa1 sequence is more abundant in the D-genome of wheat than in other genomes in Triticeae. DNA from several species also have bands in addition to the tandem repeats. The dpTa1 sequence contains short direct and inverted subrepeats and is homologous to a tandemly repeated DNA sequence from Hordeum chilense.     

Comparative mapping in grasses. Oat relationships

The development of RFLP linkage maps in hexaploid and diploid oat allows us to study genetic relationships of these species at the DNA level. In this report, we present the extension of a previously developed diploid oat map (Avena atlantica x A. hirtula) and its molecular-genetic relationships with wheat, rice and maize. Examination of 92–99% of the length of the oat genome map with probes common to Triticeae species, rice or maize showed that 84, 79 and 71%, respectively, was conserved between these species and oat. Generally, the orders of loci among chromosomes homoeologous to oat chromosomes A and D were the most conserved and those of chromosomes homoeologous to oat chromosome G were the least conserved. Conservation was observed for blocks ranging from whole chromosomes 101 cM long to small segments 2.5 cM long containing two loci. Comparison of the homoeologous segments of Triticeae, rice and maize relative to oat indicated that certain regions have been maintained in all four species. The relative positions of major genes governing traits such as seed storage proteins and resistance to leaf rusts have been conserved between cultivated oat and Triticeae species. Also, the locations of three vernalization/or photo-period response genes identified in hexaploid oat correspond to the locations of similar genes in homoeologous chromosomes of wheat, rice or maize. The locations of the centromeres for six of the seven oat chromosomes were estimated based on the homoeologous segments between oat and Triticeae chromosomes.     

麦类作物遗传转化

麦类作物包括小麦(Triticum aestivum L.)、硬粒小麦(Triticum turgidum con v.durum Dest.e.m)、大麦(Hordeum vulgare L.)、黑麦(Secale cereal L.)、燕麦(Avena sativa L.)及小大麦(×Tritordeum Ascherson et Graebuer.).自从基因枪被发明以来,科学家们已经利用来自麦类作物的幼胚、 盾片、成熟种子胚、花粉粒、花药、幼穗、叶基组织、发芽种子幼苗的顶端分生组织及其愈伤组织或培养物作为外植体,通过基因枪、农杆菌介导、 PEG法、电激法、微注射法、硅化纤维素介导、幼穗注射法等技术先后将一些选择标记基因、报告基因和有用的目的基因如抗真菌、抗虫、 籽粒品质、抗干旱基因等转化到麦类作物中.转基因植物表现为抗性增强或籽粒的加工品质提高和营养成份增加.被转化的基因通常以单位点多拷贝的形式随机整合到受体细胞的基因组中,并以孟德尔规律遗传.整合位点一般分布在染色体的近端粒区域,整合的拷贝数大多为5～10个拷贝,最高可达到50个拷贝.在转化过程中,被转化的质粒上的片段包括选择标记基因、目标基因、甚至质粒的抗生素基因和其他无关序列,随机地连接并形成多个分子量大小不等,组成成分不同的分子簇,或首先由其中一个分子簇整合到植物基因组中,这会导致在整合位点附近产生"热点",易于其他分子簇在此处整合,从而完成两期整合;或被转化的质粒上的选择标记基因、目标基因、质粒的抗生素基因和其他无关序列、植物基因组DNA等片段共同形成各种不同类型的分子簇,当植物细胞染色体复制时,在复制叉处整合到植物基因组中.转基因可以在各种水平上表达,也会时常发生基因沉默,这会导致转基因植物DNA水平上表达但在蛋白质水平上不表达,后代偏向分离,沉默的转基因重新表达.转基因的位置效应、甲基化和启动子都会诱发转基因沉默.在麦类作物中,35S启动子易于导致转基因沉默,应尽量减少使用.转基因还导致被转化麦类作物在农艺性状和细胞学上的变异.目前,麦类作物遗传转化已经成为一种常规的技术,转基因麦类作物正开始进入商业应用阶段.相信多种转化新技术的应用和发展将会培育出高产、稳产、优质、低投入的各类品种和种质.     

麦类作物遗传转化(英)

麦类作物包括小麦 (TriticumaestivumL .)、硬粒小麦 (Triticumturgidumconv .durumDest.e.m)、大麦 (HordeumvulgareL .)、黑麦 (SecalecerealL .)、燕麦 (AvenasativaL .)及小大麦 (×TritordeumAschersonetGraebuer.)。自从基因枪被发明以来 ,科学家们已经利用来自麦类作物的幼胚、盾片、成熟种子胚、花粉粒、花药、幼穗、叶基组织、发芽种子幼苗的顶端分生组织及其愈伤组织或培养物作为外植体 ,通过基因枪、农杆菌介导、PEG法、电激法、微注射法、硅化纤维素介导、幼穗注射法等技术先后将一些选择标记基因、报告基因和有用的目的基因如抗真菌、抗虫、籽粒品质、抗干旱基因等转化到麦类作物中。转基因植物表现为抗性增强或籽粒的加工品质提高和营养成份增加。被转化的基因通常以单位点多拷贝的形式随机整合到受体细胞的基因组中 ,并以孟德尔规律遗传。整合位点一般分布在染色体的近端粒区域 ,整合的拷贝数大多为 5～ 10个拷贝 ,最高可达到 5 0个拷贝。在转化过程中 ,被转化的质粒上的片段包括选择标记基因、目标基因、甚至质粒的抗生素基因和其他无关序列 ,随机地连接并形成多个分子量大小不等 ,组成成分不同的分子簇 ,或首先由其中一个分子簇整合到植物基因组中 ,这会导致在整合位点附近产生“热点     

History of the Triticeae Symposia

The International Triticeae Symposia were initiated to encourage scientists working on different aspects of the Triticeae1 to share information and examine the distant relatives of its cereal species. There have now been seven symposia, each in a different country. The scope of these symposia is briefly reviewed. The merits of the symposium series are identified as their interdisciplinary nature and small size.     

Different patterns in molecular evolution of the Triticeae

A huge part of the genomes of most Triticeae species is formed by different families of repetitive DNA sequences. In this paper the phylogenetic distribution of two major classes of the repeats, retrotransposons and tandemly organized DNA sequences, are considered and compared with the evolution of gene-rich regions and generally accepted Triticeae phylogenetic relationships. In Hordeum, LTR-containing retrotransposons are dispersed along the chromosomes and are consistent with the existing picture of the phylogeny of Hordeum. Another retrotransposon class, LINEs, have evolved independently from LTR-retrotransposons. Different retrotransposon classes appear to have competed for genome space during the evolution of Hordeum. Another class of repeats, tandemly organized DNA sequences, tends to cluster at the functionally important regions of chromosomes, centromeres and telomeres. The distribution of a number of tandem DNA families in Triticeae is not congruent with generally accepted phylogenetic relationships. While natural selection is the dominant factor determining the structure of genic regions we suggest that the contribution of random events is important in the evolution of repetitive DNA sequences. The interplay of stochastic processes, molecular drive, and selection determines the structure of chromosomal regions, notably at centromeres and telomeres, stabilizing and differentiating species-specific karyotypes. Thus, the evolution of these regions may occur largely independently of the evolution of gene-rich regions.     

Comparison of wheat physical maps with barley linkage maps for group 7 chromosomes

Comparative genetic maps among the Triticeae or Gramineae provide the possibility for combining the genetics, mapping information and molecular-marker resources between different species. Dense genetic linkage maps of wheat and barley, which have a common array of molecular markers, along with deletion-based chromosome maps of Triticum aestivum L. will facilitate the construction of an integrated molecular marker-based map for the Triticeae. A set of 21 cDNA and genomic DNA clones, which had previously been used to map barley chromosome 1 (7H), were used to physically map wheat chromosomes 7A, 7B and 7D. A comparative map was constructed to estimate the degree of linkage conservation and synteny of chromosome segments between the group 7 chromosomes of the two species. The results reveal extensive homoeologies between these chromosomes, and the first evidence for an interstitial inversion on the short arm of a barley chromosome compared to the wheat homoeologue has been obtained. In a cytogenetically-based physical map of group 7 chromosomes that contain restriction-fragment-length polymorphic DNA (RFLP) and random amplified polymorphic DNA (RAPD) markers, the marker density in the most distal third of the chromosome arms was two-times higher than in the proximal region. The recombination rate in the distal third of each arm appears to be 8–15 times greater than in the proximal third of each arm where recombination of wheat chromosomes is suppressed.