小麦与高冰草体细胞杂种后代的核基因组和叶绿体基因组的遗传特征

以小麦(TriticumaestivumL.)与高冰草(Agropyronelongatum(Host)Nevski)体细胞杂种同一个克隆来源的F2-F6自交系Ⅱ-2、Ⅱ-Ⅰ-8以及由Ⅱ-Ⅰ-8F2分离形成的8-1(F3-F6)为材料,利用小麦叶绿体基因组的微卫星(Microsatellite)特异引物及随机扩增多态性DNA(RAPD)引物进行分析。结果表明,杂种株系的叶绿体基因组组成一致,均以小麦叶绿体基因组为主,仅在rpl14和rpl16基因的间隔序列中检测到双亲的特征带,表明有高冰草的叶绿体DNA在杂种中存在,并稳定遗传至第六代。RAPD分析表明,不同杂种株系中存在不同的高冰草核DNA片段,核基因组在传代中基本稳定。     

小麦与高冰草体细胞杂种后代的核基因组和叶绿体基因组的遗传特征

以小麦(Triticum aestivum L.)与高冰草(Agropyron elongatum(Host)Nevski)体细胞杂种同一个克隆来源的F2-F6自交系Ⅱ-2、Ⅱ-Ⅰ-8以及由Ⅱ-Ⅰ-8 F2分离形成的8-1(F3-F6)为材料,利用小麦叶绿体基因组的微卫星(Microsatellite)特异引物及随机扩增多态性DNA(RAPD)引物进行分析.结果表明,杂种株系的叶绿体基因组组成一致,均以小麦叶绿体基因组为主,仅在rpl14和rpl16基因的间隔序列中检测到双亲的特征带,表明有高冰草的叶绿体DNA在杂种中存在,并稳定遗传至第六代.RAPD分析表明,不同杂种株系中存在不同的高冰草核DNA片段,核基因组在传代中基本稳定.     

苜蓿红豆草属间体细胞杂种的分子生物学鉴定

通过原生质体融合和培养获得苜蓿红豆草属间体细胞杂种植株。采用一种简便方法从杂种组织再生植株叶片、红豆草羟脯氨酸抗性系再生植株叶片和苜蓿根癌农杆菌702转化系愈伤组织提取DNA用于RAPD和Southern杂交分析。随机引物扩增结果显示两种亲本的RAPD多态具有明显差异。在所用20种随机引物中,6种产生较多的DNA片段。杂种组织具有两种亲本特有的DNA片段,但倾向于排除红豆草亲本的染色体,表明该杂种为非对称杂种,两种亲本染色体之间可能发生了重组。由于红豆草DNA的介入,杂种组织表现出较强的分化能力。分别利用RAPD扩增得到的OPA141000bp红豆草羟脯氨酸抗性系特异产物和OPA141600bp苜蓿根癌农杆菌702转化系特异产物为探针进行Southern分子杂交,证明杂种组织同时具有这两种DNA片段的同源序列。     

RAPD鉴定栽培稻与野生稻体细胞杂种

利用随机引物扩增DNA(RAPD)技术,对栽培稻和野生稻原生质体融合获得的体 细胞杂种进行了鉴定。证实了它们包含有双亲的基因组成分。但来自双亲的基因组成分并不是对等的。一些体细胞杂种含有一个亲本更多的基因组成分,而另一些相反。利用RAPD数据和聚类图讨论了体细胞杂种和双亲的亲缘关系。     

利用RAPD分析鉴定花椰菜杂种纯度

应用随机扩增多态性DNA(RAPD)分析方法,鉴定花椰菜F1代杂种纯度。筛选出20个10bp随机引物对杂种F1代和父母本基因组DNA进行RAPD分析,共获得扩增片段124条,分子量在0.3-3kb之间,其中2个引物S120和S174可用来鉴定杂种纯度。RAPD分析结果与田间形态鉴定结果基本一致,表明RAPD分析方法适用于花椰菜杂种的纯度鉴定。     

小麦矮腥黑穗菌差异片段筛选与分子检测体系的建立

采取随机扩增DNA多态性(Random amplified polymorphic DNA,RAPD)引物介导的半特异PCR技术(RAPD primer mediated hemi-specific PCR,RM-PCR),在从不同地域征集的18个小麦矮腥黑穗菌(Tilletia controversa Kühn,TCK)菌株和29个小麦网腥黑穗病菌(Tilletia caries(DC)Tul,TCT)菌株的总基因组DNA中筛选鉴定出TCK独有的大小为1322bp差异基因组片段。根据该片段序列设计筛选出2对特异性引物CQUTCK2/CQUTCK3和CQUTCK4/CQUTCK5,均可以从18个TCK菌株的菌丝体和冬孢子DNA中稳定地扩增出747bp和200bp的单一靶带DNA,而在29个TCT菌株的菌丝体或冬孢子DNA均无任何扩增产物。以腥黑穗菌属通用引物对CQUK6/CQUK7为内置对照,可以确定被检样品是否含PCR抑制物质进而判断检测体系是否正确,同时有效地排除样品检测结果的假阳性和假阴性。采用建立的TCK特异PCR检测技术体系,实现简单而快速地鉴定小麦矮腥黑穗菌冬孢子或罹病小麦组织中侵染菌丝体的目的。     

冰草P基因组特异RAPD标记的筛选

以二倍体、四倍体和六倍体冰草（P基因组）以及中国春、Fukuho、栽培一粒小麦和硬粒小麦（ABD基因组）等为材料进行RAPD分析,从520个RAPD随机引物中,筛选出2个P基因组特异的RAPD分子标记OPC04和OPP12.利用OPC04和OPP12对小麦族其它基因组植物和8个小麦-冰草二体附加系进行扩增,结果表明OPC04和OPP12在ABD、C、E、AG、I、M、R、S、V、Y等基因组扩增中未出现相应结合位点;而在对8个小麦-冰草二体附加系扩增中均出现此2个特异片段,且扩增稳定、重复性好.进一步表明OPC04和OPP12是冰草P基因组的特异标记,可作为小麦-冰草重组系外源P染色质的鉴定标记之一.     

RAPD条件优化及天麻基因组DNA多态性分析

建立了RAPD扩增条件快速优化程序与方法．并应用于天麻基因组DNA扩增条件的优化及多态性的测定：获得了天麻基因组DNA的RAPD扩增优化条件和DNA指纹图谱;分析了模板DNA、引物、dNTP、Taq DNA聚合酶等的浓度和退火温度对RAPD扩增的影响．结果表明：天麻基因组DNA用引物S1扩增的片段具有更明显的多态性,这种指纹图谱更适合于天麻遗传分化研究;而用引物S12扩增的DNA指纹图谱具有更大的相似性,这种指纹图谱更适合于天麻真伪鉴别．该方法使RAPD扩增条件优化过程实现了程序化和数量化,是获得RAPD优化条件的简便快速、经济实用方法．应用该方法进行RAPD扩增,可获得图谱清晰、稳定可靠的实验结果．     

粘类小麦细胞质雄性不育系的RAPD分析

利用250条10-聚寡核苷酸随机引物对具粘果山羊草(Aegilops kotschyi)、易变山羊草(Ae.variabilis)、偏凸山羊草(Ae.ventricosa)和二角山羊草(Ae．bicornis)细胞质不育系及其保持系5-1的总DNA进行了RAPD多态性分析,其中31条引物对4种不育系及其保持系总DNA均无扩增,217条引物扩增条带完全相同。有2条随机引物在2种不育系之间有特异的扩增片段,其中引物S22在偏凸山羊草细胞质雄性不育系基因组DNA中扩增出分子量约为1600bp的特异带,引物S202在粘果山羊草细胞质雄性不育系基因组DNA中扩增出约1300bp特异带。线粒体基因组DNA的RAPD分析表明,4种不育系及其保持系mtDNA存在明显的差异。证明了S22—1600为偏凸山羊草细胞质不育系及其mtDNA基因组DNA的RAPD特异片段．S202—1300可能为粘果山羊草细胞质不育系及其ctDNA基因组DNA的RAPD特异片段。     

山羊草属S基因组与小麦属B／G基因组RAPD标记和特异DNA片段克隆及研究

本研究利用132个随机引物,对山羊草属和小麦属11个种的DNA进行扩增。对其中特异RAPD扩增产物进行克隆,然后用其做探针与小麦族23个种属DNA的RAPD扩增产物进行Southern杂交。共得到24个特异克隆：其中小麦族共有特异克隆1个,山羊草属和小麦属共有特异克隆2个,S基因组特异克隆2类7个,B／G基因组特异克隆2类6个,S基因组与B／G基因组共有的特异克隆8个。24个特异克隆中有22个测定了序列,其中15个为Fasta数据库里显示未见报导的序列。用这24个特异DNA克隆制成的探针与相应的23个材料经HindⅢ酶切消化的总DNA进行Southern杂交,发现其中7个可做为基因组特异探针。通过对24个特异DNA克隆分析研究表明：①S基因组是由两个基本不同的类型构成的,即拟斯卑尔脱山羊草为一个类型,其余4个S组山羊草为另一类型;因此建议前基因型符号仍保留为“S”,而其余4个种之间无明显不同,故应把基因组符号统一为“S^1”②S基因组是小麦B／G基因组的供体,而拟斯卑尔脱山羊草可能是最主要的供体,但并不排除其余S基因组的种参与了B／G基因组形成的可能;研究还表明B基因组与S基因组还是有很大区别的,并已找到了B基因组的特异标记。     

RAPD method for the identification of intergeneric asymmetric somatic hybrid plants of wheat]

Randomly amplified polymorphic DNA (RAPD) method was used to identify the hybrid nature of three kinds of intergeneric asymmetric somatic hybrid plants of wheat: wheat (Triticum aestivum) + Haynaldia villosa, Wheat + Leymus chinensis and wheat + Agropyron elongatum. It was shown from the electrophoresis profiles that the genome of somatic hybrid plants contained specific section genome of both parents after DNA amplification with arbitrary primers. A specific RAPD product (DNA fragment of 0.77 kbp) of A. elongatum generated with primer OPJ-12 was isolated, purified, labeled and used as a probe. Southern blot from OPJ-12 primer-generated specific section genome of the hybrid (T. aestivum + A. elongatum) hybridized to this probe (0.77 kbp) proved that they are homologous in nature. This paper also discussed the advantage of RAPD method in identification of hybrid plants, especially asymmetric somatic hybrids.     

Intermediate fertile Triticum aestivum （＋）Agropyron elongatum somatic hybrids are generated by low doses of UV irradiation

We report the production and characterization of somatic hybrids between Triticum aestivum L. and Agropyron elongatum (Host) Nevishi (the synonym is Thinopyrum ponticum). Asymmetric protoplast fusion was performed between Agropyron elongatum protoplasts irradiated with a low UV dose and protoplasts of wheat taken from nonregenerable suspension cultures. More than 40 green plantlets were obtained from 15 regenerated clones and one of them produced seeds. The phenotypes of the hybrid plants and seeds were intermediate between wheat and Agropyron elongatum. All of the regenerated calli and plants were verified as intergeneric hybrids on the basis of morphological observation and analysis of isozyme, cytological, 5SrDNA spacer sequences and random amplified polymorphic DNA (RAPD). RFLP analysis of the mitochondrial genome revealed evidence of random segregation and recombination of mtDNA.     

Asymmetric somatic hybridization between wheat (Triticum aestivum L.) and Agropyron elongatum (Host) Nevishi

Suspension-derived protoplasts of Agropyron elongatum irradiated by ultra-violet light (UV) were fused with the suspension-derived protoplasts of Triticum astivum using PEG. Fertile intergeneric somatic hybrid plants were produced and various hybrid lines have been selected and propagated in successive generations. Their hybrid nature was confirmed by analysis of profiles of isozymes, RAPDs, and 5S rDNA spacer sequences, and via GISH analysis. By the procedure described, the phenotype and chromosome number of wheat could be maintained besides transfer of a few chromosomes and chromosomal fragments from the donor A. elongatum. The results above indicated that highly asymmetric fertile hybrid plants and hybrid progenies of wheat were produced via somatic hybridization.     

Transfer of small chromosome fragments of Agropyron elongatum to wheat chromosome via asymmetric somatic hybridization

~~Transfer of small chromosome fragments of Agropyron elongatum to wheat chromosome via asymmetric somatic hybridization1 .Dong,Y.C,GenePools of common wheat,Journal of Triticeae CroPs(in Chinese),2000,20(3):78-81. 2 .Wei,Y.M.,Zheng,YL.Zhou,R.H., Detectlon of the rye chro- matin in multisPikelet wheat germplasm 10-A background using fluorescence in situ hybridization(FISH)and RFLP markers,Acta Bot.Sinica(in Chinese),1999,41(7):722-725. 3 .Xiang,E N.,Xia,G M.…     

Transfer of small chromosome fragments of<Emphasis Type="Italic">Agropyron elongatum</Emphasis> to wheat chromosome via asymmetric somatic hybridization

The chromosome constitution of hybrids and chromatin patterns of Agropyron elongatum (Host)Neviski in F₅ somatic hybrid lines -1–3 and I-1-9 between Triticum aestivum L. and A. elongatum were analyzed. Based on the statistic data of pollen mother cells, F₅ I-1-9 and-1-3 had 20–21 bivalents with a frequency of 84.66% and 85.28%, of which, 89.83% and 89.57% were ring bivalents. The result indicated that both hybrid lines were basically stable in the chromosome constitution and behavior. RAPD analysis showed that the two hybrids contained biparental and integrated DNA. GISH (Genome in situ hybridization) revealed that in the form of small chromosome segments, A. elongatum chromatin was scattered on 4–6 wheat chromosomes near by the region of centromere and telomere in the two hybrid lines. SSR analysis indicated that A. elongatum DNA segments were distributed on the 2A, 5B, 6B and 2D wheat chromosomes in the hybrids, which was in accordance with the GISH results that small-segments intercalated poly-site.     

Construction of a primary RH panel of Italian ryegrass genome via UV-induced protoplast fusion

Symmetric and asymmetric somatic hybrids were produced via protoplast fusion between common wheat ( TRITICUM AESTIVUM L.) cv. "Jinan 177" and Italian ryegrass ( LOLIUM MULTIFLORUM Lam.). The ryegrass without or with UV irradiation was used as a donor, providing a small amount of chromatin. In these somatic hybrids, most ryegrass chromosomes have been confirmed preferential elimination and the somatic hybrid calli and plants showed wheat-like morphology. Some of the hybrid lines were used for the analysis of distribution and heredity of donor DNA in the hybrid genome and the possibility of establishing a radiation hybrid (RH) panel of the ryegrass in the present experiment. These hybrids, subcultured for two and three years, retained the ryegrass DNA examined by RFLP and GISH analysis, respectively. Distribution of the ryegrass DNA in the wheat genomes of 20 single-cell individuals, randomly selected from hybrid cell lines produced, were analyzed by 21 ryegrass genome specific SSR markers. The average frequencies of molecular marker retention in symmetric hybrid lines (UV 0), as well as asymmetric hybrid lines from UV 30 s and 1 min were 10.88, 15.48 and 33.86, respectively. It was suggested that the UV dose increased the introgression of donor DNA into wheat genome. The ryegrass SSR fragments in most asymmetric hybrid cell lines remained stable over a period of 2 approximately 3 years. This revealed that those asymmetric somatic hybrids are suitable for the introgression of ryegrass DNA into wheat, and for RH panel and RH mapping.     

Agronomic Trait and Protein Component of F2 Hybrid Originated from Intergeneric Somatic Hybridization Between Triticum aestivumand Agropyron elongatum

Protoplasts derived from common wheat ( Triticum aestivum L． cv. Jinan 177) were fused with UV-treated protoplasts of Agropyron elongatum (Host) Nevski by PEG method, and fertile asymmetric somatic hybrid plants resembling wheat morphology were obtained. The F2 hybrid plants could be divided into 3 types according to their morphology. Type Ⅰ hybrids had high and loosely standing stalks with big spikes and grains. TypeⅡ hybrids were dwarf and compact in shape with high tillering ability and smaller spikes. Type Ⅲ hybrids were similar to typeⅠas a whole but had more compact and erect spikes. All the F2 hybrid lines were superior to wheat in seed protein content, although some difference existed between themselves. Protein analysis of immature embryos and flag leaves from hybrids by two-dimensional electrophoresis showed that they possessed characteristic proteins of both parents and some new proteins. There existed also some different kinds of proteins in different lines.     

簇毛麦基因组特异性PCR标记的建立和应用

以普通小麦中国春、簇毛麦、中国春－簇毛麦二体附加系和代换系为材料进行RAPD分析,筛选出一个簇毛麦基因组特异性RAPD片段OPFO2757,该片段分布于簇毛麦所有染色体上。在对OPFO2757进行克隆、测序的基础上,设计一对PCR引物,建立了簇毛麦基因组特异性PCR标记。用这对PCR引物对不同普通小麦品种、不同硬粒小麦品种、不同居群的簇毛麦、中国春－簇毛麦二体附加系、中国春－簇毛麦二体代换系、普通小麦－簇毛麦双二倍体、硬粒小麦－簇毛麦双二倍体等材料进行扩增,凡具有簇毛麦染色体的材料都能扩增出一条长为677bp的DNA片段,而不具簇毛麦染色体的材料包括大麦、黑麦、长穗偃麦草、中间偃麦草等不能扩增出该片段。所以,该特异性PCR标记可用于快速跟踪检测小麦背景中的簇毛麦染色体。     

Regeneration of asymmetric somatic hybrid plants from the fusion of two types of wheat with Russian wildrye

Two types of protoplasts of wheat (Triticum aestivum L. cv. Jinan 177) were used in fusion experiments—cha9, with a high division frequency, and 176, with a high regeneration frequency. The fusion combination of either cha9 or 176 protoplasts with Russian wildrye protoplasts failed to produce regenerated calli. When a mixture of cha9 and 176 protoplasts were fused with those of Russian wildrye, 14 fusion-derived calli were produced, of which seven differentiated into green plants and two differentiated into albinos. The morphology of all hybrid plants strongly resembled that of the parental wheat type. The hybrid nature of the cell lines was confirmed by cytological, isozyme, random amplified polymorphic DNA (RAPD) and genomic in situ hybridization (GISH) analyses. GISH analysis revealed that only chromosome fragments of Russian wildrye were transferred to the wheat chromosomes of hybrid calli and plants. Simple sequence repeat (SSR) analysis of the chloroplast genome of the hybrids with seven pairs of wheat-specific chloroplast microsatellite primers indicated that all of the cell lines had band patterns identical to wheat. Our results show that highly asymmetric somatic hybrid calli and plants can be produced via symmetric fusion in a triparental fusion system. The dominant effect of two wheat cell lines on the exclusion of Russian wildrye chromosomes is discussed.Abbreviations GISH Genome in situ hybridization - RAPD Random amplified polymorphic DNA - SCF Small chromosome fragment - SSR Simple sequence repeat