小麦族植物的分类现状及主要存在的问题

小麦族(Triticeae)是禾本科、早熟禾亚科中一个有重要经济价值、以多年生植物占优势的族,族内绝大多数种类是重要的粮食作物和畜牧业上的优良牧草,饲用价值极高,有些种类具有耐寒、耐旱、耐碱等特性,是农牧业上良种繁育、牧草利用的重要基因资源。但该族同时又是分类学上的一个疑难族,各学者对族内系统分类意见不一、争议颇大,尤其在族的界限、族下类群划分以及类群演化关系上问题较多,至今尚未解决。查阅了国内外分类学文献,探讨其分类差异以及存在问题,为充分开发利用中国丰富的小麦族植物资源提供理论依据。     

小麦的远亲近邻

小麦族植物 小麦族是禾本科植物中最具有经济价值的一大植物类群，它包含与人类生活密切相关的3种粮食作物：小麦、大麦和黑麦；还有许多重要的牧草种类，如偃麦草等。     

小麦族中间鹅观草不同居群的形态多样性分析

小麦族（Triticeae）植物的野外调查、收集通常是以形态学为依据的。为了探讨小麦族植物在野外调查、收集的科学取样策略,本项研究以小麦族具有自花授粉习性的3个中间鹅观草（Roegneria sinica．vat．media Keng）居群、每个居群30个单株为材料,对11个形态学性状的多样性进行了分析。结果表明,3个居群的总遗传多样性指数为1．991,遗传多样性主要集中于居群内（91．76％）,而居群间的遗传变异（8．24％）相对较小;不同取样梯度下的遗传多样性指数随单株取样数目的增加呈现增大趋势,但当取样数目达到18株时,遗传多样性指数达到最高值。上述结果说明,对于小麦族自花授粉植物野外调查、收集时,应以居群为单位,而且每一居群至少应调查、收集18个单株,才能代表居群的遗传多样性。以形态学为依据的取样策略的建立,对于指导野外调查、收集具有现实意义。     

小麦族中间鹅观草不同居群的形态多样性分析

小麦族（Triticeae）植物的野外调查、收集通常是以形态学为依据的。为了探讨小麦族植物在野外调查、收集的科学取样策略,本项研究以小麦族具有自花授粉习性的3个中间鹅观草（Roegneria sinica. var. media Keng）居群、每个居群30个单株为材料,对11个形态学性状的多样性进行了分析。结果表明,3个居群的总遗传多样性指数为1.991,遗传多样性主要集中于居群内（91.76%）,而居群间的遗传变异（8.24%）相对较小;不同取样梯度下的遗传多样性指数随单株取样数目的增加呈现增大趋势,但当取样数目达到18株时,遗传多样性指数达到最高值。上述结果说明,对于小麦族自花授粉植物野外调查、收集时,应以居群为单位,而且每一居群至少应调查、收集18个单株,才能代表居群的遗传多样性。以形态学为依据的取样策略的建立,对于指导野外调查、收集具有现实意义。     

赖草属植物的分类现状及主要存在的问题

赖草属(Leymus Hochst.)为禾本科(Poaceae)小麦族(Triticeae)中的一个有重要经济价值的属,属内多数种类是优良牧草,有些种类具有耐寒、耐旱、耐碱等特性,是农业良种繁育、畜牧业牧草改良利用的重要基因资源。该属在分类学上是一个疑难属,在属的界限、属下组系的划分,以及类群间演化关系上问题较多。对赖草属分类学问题进行了综述,为赖草属植物资源的开发利用和保护提供资料。     

赖草属植物的遗传学研究与利用

赖草属植物具有广泛的适应性和丰富的抗逆性,作为麦类作物的重要基因资源愈来愈受到人们的重视。介绍了赖草属植物的种类及分布,分析了赖草属植物的优良特性及潜在利用价值,探讨了赖草属植物的核型、染色体带型及分子细胞遗传学研究,重点论述了赖草属植物在小麦遗传改良中的应用．阐明挖掘利用小麦近缘野生植物是未来小麦品种改良的有效途径。     

植物萜类次生代谢及其调控

植物次生代谢在植物生长发育、环境适应、抵御病虫害等方面发挥着重要作用,这些天然产物组成地球上最丰富的有机化合物的宝库．萜类是植物代谢产物中种类最多的一类,具有重要的生理和生态功能,一些成分还有应用价值．近十几年来,人们在萜类化合物的分离、鉴定、应用、生物合成、相关基因与基因族、酶蛋白结构和功能、代谢调控以及代谢工程等各方面取得了重大进展．本文概述了植物萜类化合物代谢及其调控领域的研究进展与发展趋势．     

基于nrITS、psbA-trnH和DMC1序列中国短柄草族的系统进化和生物地理学研究

短柄草族（Brachypodieae）有短柄草（Brachypodium sylvaticum）和二穗短柄草（Brachypodium distachyum）两种模式植物,具有重要科研价值,与雀麦族（Bromeae）和小麦族（Triticeae）的系统位置关系尚不明确。据此,本文运用最大简约法（MP）、最大似然法（ML）和贝叶斯推断法（BI）对叶绿体基因片段psbA-trnH、核糖体基因转录间隔区ITS、单拷贝核基因片段DMC1以及psbA-trnH+nrITS+DMC1联合序列数据进行分析,来揭示三者的系统学位置关系。研究结果表明,在DMC1、nrITS以及联合基因序列构建的系统进化树中,短柄草族、雀麦族、小麦族各自聚为一支,且具有较高的支持率;在叶绿体基因psbA-trnH构建的系统进化树中,短柄草族聚为一支,雀麦族分散镶嵌在小麦族中,提示小麦族、雀麦族之间发生了多种进化情况。利用BEAST和RASP对psbA-trnH+nrITS+DMC1联合序列分析,结果表明：小麦族起源于西北地区,物种形成时间多集中在13-7 Ma,与青藏高原中新世中晚期（13-7 Ma）的隆起一致;短柄草族起源于西南地区,物种形成时间多集中在3 Ma之后,这与东亚季风的加强和青藏高原上新世以来的剧烈抬升时间一致,中国特有种草地短柄草（Brachypodium pratense）也是在该时间段分化形成。     

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。     

赤霉素生物合成与信号传递对植物株高的调控

植物株高是影响作物产量和品质的重要农艺性状。赤霉素(Gibberellins,GAs)是调控植物株高的重要激素,GA相关株高基因的克隆与分子机制研究对于合理调控作物生长发育和农业生产具有极其重要的利用价值,在水稻、小麦等粮食作物育种中得到了广泛应用。为了促进GA在果树、花卉等园艺作物育种中的有效利用,文中在分子生物学水平上介绍GA生物合成和GA信号传递途径对植物株高的调控。     

TriMEDB: A database to integrate transcribed markers and facilitate genetic studies of the tribe Triticeae

Background  

The recent rapid accumulation of sequence resources of various crop species ensures an improvement in the genetics approach, including quantitative trait loci (QTL) analysis as well as the holistic population analysis and association mapping of natural variations. Because the tribe Triticeae includes important cereals such as wheat and barley, integration of information on the genetic markers in these crops should effectively accelerate map-based genetic studies on Triticeae species and lead to the discovery of key loci involved in plant productivity, which can contribute to sustainable food production. Therefore, informatics applications and a semantic knowledgebase of genome-wide markers are required for the integration of information on and further development of genetic markers in wheat and barley in order to advance conventional marker-assisted genetic analyses and population genomics of Triticeae species.     

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.     

Developmental pathways for shaping spike inflorescence architecture in barley and wheat

Grass species display a wide array of inflorescences ranging from highly branched compound/panicle inflorescences to unbranched spike inflorescences. The unbranched spike is a characteristic feature of the species of tribe Triticeae, including economically important crops,such as wheat and barley. In this review, we describe two important developmental genetic mechanisms regulating spike inflorescence architecture in barley and wheat.These include genetic regulation of(i) row-type pathway specific to Hordeum species and(ii) unbranched spike development in barley and wheat. For a comparative understanding, we describe the branched inflorescence phenotypes of rice and maize along with unbranched Triticeae inflorescences. In the end, we propose a simplified model describing a probable mechanism leading to unbranched spike formation in Triticeae species.     

Analysis of recombination and gene distribution in the 2L1.0 region of wheat (Triticum aestivum L.) and barley (Hordeum vulgare L.)

Both wheat and barley belong to tribe Triticeae and are closely related. High-density detailed comparison of physical and genetic linkage maps revealed that wheat genes are present in physically small gene-rich regions (GRRs). One of the largest GRRs is located around fraction length 1.0 of the long arm of wheat homoeologous group 2 chromosomes termed the "2L1.0 region." The main objective of this study was to analyze the structural and functional organization of the 2L1.0 region in barley in comparison to wheat. Using the 29 physically mapped RFLP markers for the region, wheat and barley consensus genetic linkage maps of the 2L1.0 region were generated by combining information from 18 wheat and 7 barley genetic linkage maps. Comparative analysis using these consensus maps and other available wheat and barley mapping resources identified 227 DNA markers and ESTs for the region. The region accounted for 58% of the genes and 68% of the arm's recombination in wheat. However, the corresponding region in barley accounted for about 42% of the genes and 81% of the recombination. The kb/cM ratio for the region was 122 in barley compared to 244 in wheat. Distribution of genes and recombination varied between the two species even though the gene order and density were similar.     

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     

Towards a whole‐genome sequence for rye (Secale cereale L.)

We report on a whole‐genome draft sequence of rye (Secale cereale L.). Rye is a diploid Triticeae species closely related to wheat and barley, and an important crop for food and feed in Central and Eastern Europe. Through whole‐genome shotgun sequencing of the 7.9‐Gbp genome of the winter rye inbred line Lo7 we obtained a de novo assembly represented by 1.29 million scaffolds covering a total length of 2.8 Gbp. Our reference sequence represents nearly the entire low‐copy portion of the rye genome. This genome assembly was used to predict 27 784 rye gene models based on homology to sequenced grass genomes. Through resequencing of 10 rye inbred lines and one accession of the wild relative S. vavilovii, we discovered more than 90 million single nucleotide variants and short insertions/deletions in the rye genome. From these variants, we developed the high‐density Rye600k genotyping array with 600 843 markers, which enabled anchoring the sequence contigs along a high‐density genetic map and establishing a synteny‐based virtual gene order. Genotyping data were used to characterize the diversity of rye breeding pools and genetic resources, and to obtain a genome‐wide map of selection signals differentiating the divergent gene pools. This rye whole‐genome sequence closes a gap in Triticeae genome research, and will be highly valuable for comparative genomics, functional studies and genome‐based breeding in rye.     

Cereal breeding takes a walk on the wild side

Elite cultivated crop gene pools of the Triticeae tribe (wheat, barley and rye) exhibit limited genetic diversity, raising concerns about our ability to increase or simply sustain crop yield and quality in the face of dynamic environmental and biotic threats. Although exploiting their wild relatives as a source of novel alleles is challenging, it has provided notable successes in cereal improvement for >100 years. Increasingly facile gene discovery, improved enabling technologies for genetics and breeding and a better understanding of the factors limiting practical exploitation of exotic germplasm promise to transform existing, and accelerate the development of new, strategies for efficient and directed germplasm utilization.     

The {beta}-amylase genes of grasses and a phylogenetic analysis of the Triticeae (Poaceae)

There are two forms of β-amylase in the Triticeae crop plants wheat, barley, and rye: an endosperm-specific form encoded by two or three closely linked genes, and a tissue-ubiquitous form encoded by a single gene. Both rice and corn have one ubiquitously expressed form encoded by a single gene. This study focuses on two phylogenetic analyses of β-amylase gene sequences. First, a phylogenetic analysis of coding sequences from wheat, barley, rye, rice, and corn was expected to clarify the relationship between the endosperm-specific and tissue-ubiquitous forms of the protein. Instead, it illustrates possible effects of distant outgroups, based on conflicting patterns of character state variation consistent with different root positions. Next, a broad sample of the monogenomic Triticeae was included in a phylogenetic analysis based on sequences from a portion of the tissue-ubiquitous β-amylase gene. The results were compared to existing Triticeae gene trees, among which extensive conflict had been noted in the past. One additional gene tree has not completely clarified the complexity of the group, but has shed additional light on reticulate phylogenetic patterns within the tribe, including relationships involving Eremopyrum, Thinopyrum, and the Triticum/Aegilops group.     

Comparative mapping of a major aluminum tolerance gene in sorghum and other species in the poaceae

In several crop species within the Triticeae tribe of the grass family Poaceae, single major aluminum (Al) tolerance genes have been identified that effectively mitigate Al toxicity, a major abiotic constraint to crop production on acidic soils. However, the trait is quantitatively inherited in species within other tribes, and the possible ancestral relationships between major Al tolerance genes and QTL in the grasses remain unresolved. To help establish these relationships, we conducted a molecular genetic analysis of Al tolerance in sorghum and integrated our findings with those from previous studies performed in crop species belonging to different grass tribes. A single locus, AltSB, was found to control Al tolerance in two highly Al tolerant sorghum cultivars. Significant macrosynteny between sorghum and the Triticeae was observed for molecular markers closely linked to putatively orthologous Al tolerance loci present in the group 4 chromosomes of wheat, barley, and rye. However, AltSB was not located within the homeologous region of sorghum but rather mapped near the end of sorghum chromosome 3. Thus, AltSB not only is the first major Al tolerance gene mapped in a grass species that does not belong to the Triticeae, but also appears to be different from the major Al tolerance locus in the Triticeae. Intertribe map comparisons suggest that a major Al tolerance QTL on rice chromosome 1 is likely to be orthologous to AltSB, whereas another rice QTL on chromosome 3 is likely to correspond to the Triticeae group 4 Al tolerance locus. Therefore, this study demonstrates a clear evolutionary link between genes and QTL encoding the same trait in distantly related species within a single plant family.