应用原位杂交及RAPD技术标记抗黄矮病小麦—中间偃麦草染色体异附加系

以生物素标记中间偃麦草基因组ＤＮＡ为探针,与抗黄矮病小麦－中间偃麦草染色体异附加系Ｚ６进行原位杂交,鉴定出附加的１对中间偃麦草染色体。对异附加系Ｚ６和Ｌ１及它们的小麦亲本进行了ＲＡＰＤ分析,从１２０个随机引物中,筛选出２个引物可以扩增出附加染色体的特异ＤＮＡ片段,可作为鉴定导入小麦的中间偃麦草染色质的分子标记。     

应用原位杂交及RAPD技术标记抗黄矮病小麦一中间偃麦草染色体异附加系

以生物素（Ｂｉｏｔｉｎ－１６－ｄＵＴＰ）标记中间偃麦草基因组 ＤＮＡ为探针,与抗黄矮病小麦－中间偃麦草染色体异附加系Ｚ６进行原位杂交,鉴定出附加的１对中间偃麦草染色体。对异附加系 Ｚ６和 Ｌ１及它们的小麦亲本进行了 ＲＡＰＤ分析,从 １２０个随机引物中,筛选出 ２个引物可以扩增出附加染色体的特异ＤＮＡ片段,可作为鉴定寻人小麦的中间偃麦草染色质的分子标记。     

抗白粉病小麦——中间偃麦草异附加系的细胞学和RAPD鉴定

利用细胞学和ＲＡＰＤ技术,对从小麦与中间偃麦草杂种后代中选育的抗白粉病异附加系ＤＡＬ６６进行了鉴定。结果证明ＤＡＬ６６根尖细胞染色体数为４４,花粉母细胞减数第一分裂中期（ＰＭＣ ＭＩ）杂色体模型为２ｎ＝２２Ⅱ。对ＤＡＬ６６及其双亲进行ＲＡＰＤ分析,从４０个随机引物中筛选出１个特异引物（ＯＰＥ－０２）能够稳定地扩增出特异带型。     

中间偃麦草染色体2Ai-2特异PCR新标记的建立和St基因组特异序列的克隆

中间偃麦草麦、小麦和小麦－中间偃麦草2Ai－2附加系Z1、Z2、X6,代换系ZD28等进行RAPD分析,从320个RAPD引物中,鉴定出2Ai－2染色体特异的2个RAPD标记OPO05650和OPMO414000。利用这2个特异OPO05和OPM04,PCR扩增普通小麦CS（ABD）及其近缘植物中间偃麦草（E1E2St）、拟鹅冠草（St）,长穗偃麦草（E）、簇毛麦（V）、黑麦（R）、大麦（H）粗山羊草（D）等基因组DNA。结果表明,OPO05650和OPO41400均是2Ai－2染色体上St基因组区域的特异标记。将上棕2个特异片段分离回收、克隆、测序,根据测序结果重新设计、合成特异引物,成功地转换RAPD标记为SCAR（sequence characterizked amplifed region）标记SC－05和SC－M4。利用SCAR标记对不同材料进行分析的结果表明,凡含有2Ai－2染色体的抗黄矮病材料及拟鹅冠草均产生一条扩增带,不含2Ai－2染色体的材料,包括小麦、长穗麦草、簇毛麦、黑麦、在麦、粗山羊草以有含有其他他中间偃麦草染色休的附加系,均没有扩增产物,说明上棕2个SCAR标记是中间偃麦草2Ai－2染色体的特异性PCR标记,且是2Ai－2染色体上St基因组区域的特异性标记。克隆与鉴定中间偃麦草的2个SCAR扩增片段TiSCO5和TiSCM4。结果表明,克隆的中间偃麦草TiSCO5和TiSCM4特异片段,分别是St基因组特异性的寡拷贝序列有多拷贝重复序列,为St基因组遗传研究的新探针。     

黑麦1R染色体特异性PCR引物的分子证据

根据黑麦（ＳｅｃａｌｅｃｅｒａｌｅＬ．）与小麦（ＴｒｉｔｉｃｕｍａｅｓｔｗｕｍＬ．）ｒＲＮＡ基因间隔区序列差异,按Ｋｏｅｂｎｅｒ设计的引物序列,合成了黑麦特异引物ＮＯＲ－Ｒ１。运用该引物对不同植物材料进行ＰＣＲ扩增,观察表明,含有黑麦１Ｒ染色体的植物均扩增出黑麦的特异带,但含有其他黑麦染色体的小麦种质,普通小麦品种及其近缘物种长穗偃麦草（Ａｇｒｏｐｙｒｏｎｅｌｏｎｇａｔｕｍ（Ｈｏｓｔ）Ｂｅａｕｖ）     

拟鹅观草St基因组ISSR特异标记的建立

以拟鹅观草(Pseudoroegneria spicata)、中间偃麦草(Thinopyrum intermedium)、长穗偃麦草(Th.elonga-tum)、二倍体簇毛麦(Dasypyrum villosum)、澳冰草(Australopyrum retrofractum)等10份小麦族物种为材料,对100条ISSR引物进行分析,结果显示引物811可以在拟鹅观草(GenBank登录号为EU368859)和中间偃麦草中扩增出一条长441 bp的特异DNA片段命名为St441,而其它供试物种均未扩出.经序列比对、软件分析结合原位杂交结果认为St441为一类新的低拷贝重复序列.利用ISSR引物811对10份不同居群的中间偃麦草、20份披碱草属物种、4份小麦-偃麦草部分双二倍体、6份小麦-茸毛偃麦草后代和12份小麦对照进行扩增,结果发现除对照小麦外均能扩增出St441;进而对小麦-中间偃麦草两套附加系进行扩增,将St441初步定位于包括第四同源群在内的8条St染色体上.同时,发现只含有整条St染色体和St染色体片段的材料能扩增出St441,而仅有Js染色体的材料未扩增出St441.因此,该标记St441可以作为检测不同背景下St染色质的分子标记.     

小偃麦部分双二部体及其异附加系异源染色体的GISH分析

应用ＧＩＳＨ对小偃麦部分双二本ＴＡＦ４６及其衍生的６个二体异附加系的中间偃麦草染色体组种类进行了分析,鉴定,以拟鹅冠草ＤＮＡ为探针的分析结果表明,ＴＡＦ４６所含有的中间偃麦草洒色体组为合成染色体组,即６条Ａ１组染色体和８条Ｅ组染色体。在其衍生的二体异附加系中,Ｌ４和Ｌ含有Ｓｔ组染色体,Ｌ１、Ｌ２、Ｌ３、Ｌ５含有Ｅ组染色体。ＴＡＦ４６所含有的中间偃麦草染色体的部分同源群依次为ＩＥ（Ｌ３）、２Ｓｔ（Ｌ     

携带抗黄矮病基因的中间偃麦草染色体2Ai—2特异的分子标记

小麦－中间偃麦草二体异附加系Ｚ１、Ｚ２具有一对携带抗黄矮病基因的中间偃麦草染色体２Ａｉ－２。利用中间偃麦草（Ｔｈｉｎｏｐｙｒｕｍ ｉｎｔｅｒｍｅｄｉｕｍ （Ｈｏｓｔ） Ｂａｋｗｏｔｈ ａｎｄ Ｄｅｗｅｙ）和拟鹅冠草（Ｐｓｅｕｄｏｒｏｅｇｎｅｉａ ｓｔｒｉｇｏｓａ）基因组ＤＮＡ作探针,对Ｚ１、Ｚ２进行基因组原位杂交分析。结果表明,Ｚ１、Ｚ２附加的一对中间偃麦草染色体２Ａｉ－２为Ｓｔ－Ｅ染色体,Ｅ组染     

大麦1H特异性SAPs标记和ASA标记的创制

选取大麦1H染色体的STS标记MWG913特异性扩增小麦,把得到的片段进行克隆。用Taq Ⅰ酶切分类并测序,把得到的序列同大麦的序列进行比较,依据比较结果,选取对大麦特异的内切酶,用该酶来酶切大麦、小麦、黑麦、长穗偃麦草、中间偃麦草、簇毛麦的MWG913扩增产物,获得对大麦1H染色体特异的CAPs标记。同时,依据酶切位点碱基的差异设计引物对扩增的产物进行第二次扩增,得到该位点的一对染色体特异性ASA标记。     

大麦1H特异性CAPs标记和ASA标记的创制

选取大麦1H染色体的STS标记MWG913特异性扩增小麦,把得到的片段进行克隆.用Taq酶切分类并测序,把得到的序列同大麦的序列进行比较.依据比较结果,选取对大麦特异的内切酶,用该酶来酶切大麦、小麦、黑麦、长穗偃麦草、中间偃麦草、簇毛麦的MWG913扩增产物,获得对大麦1H染色体特异的CAPs标记.同时,依据酶切位点碱基的差异设计引物对扩增的产物进行第二次扩增,得到该位点的一对染色体特异性ASA标记.     

应用基因组原位杂交及RFLP标记鉴定小麦中的大麦染色体

用生物素（Biotin-6-dUTP)标记的大麦Betzes基因组DNA作探针,以普通小麦中国春总DNA作封阻进行基因组原位杂交（Genomeinsituhybridization,简称GISH）,从13株小麦-大麦杂交后代中鉴定出2个含有3条大麦Betzes2H染色体的材料（2n＝43）;2个2H单体异代换系（2n＝42）;7个2H二体异代换系（2n＝42）。用已定位在小麦第2部分同源群短臂上的探针psr131进行RFLP分析,结果表明大麦Betzes、代换系A5有1条区别于小麦中国春的特异带,A     

Chromosomal assignment and deletion mapping of barley EST markers

From about 10000 PCR-based EST markers of barley we chose 1421 EST markers that were demonstrated to be amplified differently by PCR between wheat (Triticum aestivum cv. Chinese Spring) and barley (Hordeum vulgare cv. Betzes). We assigned them to the seven barley chromosomes (1H to 7H) by PCR analysis using a set of wheat-barley chromosome addition lines. We successfully assigned 701 (49.3%) EST markers to the barley chromosomes: 75 to 1H, 127 to 2H, 119 to 3H, 94 to 4H, 108 to 5H, 81 to 6H and 97 to 7H. By using a set of Betzes barley telosomic addition lines of Chinese Spring, we could successfully determine the chromosome-arm (S or L) location of at least 90% of the EST markers assigned to each barley chromosome. We conducted a trial mapping using 90 EST markers assigned to 7HS (49) or 7HL (41) and 19 wheat lines carrying 7H structural changes. More EST markers were found in the distal region than in the proximal region.     

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。     

Barley allele-specific amplicons useful for identifying wheat-barley recombinant chromosomes

Barley (Hordeum vulgare L.) is potentially a new source of genes for wheat (Triticum aestivum L.) improvement. Wheat-barley chromosome recombinant lines provide a means for introgressing barley genes to wheat genome by chromosome engineering, and since these are expected to occur only rarely in special cytogenetic stocks, an efficient selection skill is necessary to identify them. To convert RFLP markers to barley allele-specific PCR markers useful for effective production of wheat-barley recombinant lines, 91 primer sets derived from RFLP clones which were previously mapped to the barley chromosomes were examined for PCR amplification using 'Chinese Spring' wheat, 'Betzes' barley and the wheat-barley chromosome addition lines. The polymorphisms were detected by an agarose gel electrophoresis of the PCR products without digestion with restriction enzymes. Out of 81 primer sets producing polymorphisms between the wheat and barley genomes, 26 amplified barley chromosome-specific DNAs which were confirmed to be located on the same chromosome as the RFLP markers by using the wheat-barley chromosome addition lines. These amplified DNAs represent barley allele-specific amplicons, which distinguish barley alleles from their wheat homoeologous counterparts. The present investigation revealed a higher probability for obtaining allele-specific amplicons from genomic DNA-derived RFLP markers than from cDNA-derived ones. The barley allele-specific amplicons developed in this study, namely, four for chromosome 2H, two for 3H, seven for 4H, eight for 5H, one for 6H and four for 7H, are suitable for identifying 'Chinese Spring' wheat- 'Betzes' barley recombinant chromosomes. However, one out of eight barley allele-specific amplicons on chromosome 5H did not detect a unique barley band in a 'New Golden' barley chromosome 5H addition line of 'Shinchunaga' wheat, indicating there may be a need to reconstruct allele-specific amplicons with different barley cultivars.     

小麦族中含St染色体组物种的特异分子标记的建立

以拟鹅观草(Pseudoroegneria spicata)、偏凸山羊草(Aegilops ventricosa)、二倍体簇毛麦(Dasypyrum villosum)、荆州黑麦(Secale cereale cv. Jingzhou rye)、普通小麦中国春(Chinese Spring)等15个物种为材料, 用200条10碱基随机引物进行RAPD分析, 筛选到拟鹅观草基因组中1个542 bp的特异DNA片段(GenBank登录号为DQ992032), 命名为OPH11542。根据OPH11542设计特异引物, 对小麦族物种进行PCR扩增, 发现拟鹅观草可以扩增出OPH11542以及分子量分别为742 bp (GenBank登录号为DQ992033, 记为OPH11742)和743 bp (GenBank登录号为EF014218, 记为OPH11743)的DNA片段, 而其他材料均未扩增出这3个片段。经序列比对结合多个软件的分析结果认为该3个片段为同一类新重复序列。利用特异引物对15份含St染色体的物种进行扩增, 发现含StY染色体组的物种均能扩增出OPH11742或OPH11743, 而含StH染色体组的物种均能扩增出OPH11542。这表明St染色体组在与其它染色体组组合形成多倍体的过程中往往会出现不同程度的重组或修饰。OPH11542、OPH11742和OPH11743可以作为检测St染色体的分子标记。     

Molecular mapping of genes determining height, time to heading, and growth habit in barley (Hordeum vulgare).

A combination of random amplified polymorphic DNA (RAPD) and restriction fragment length polymorphism (RFLP) markers has been used to locate genes controlling important developmental characters in barley. The denso dwarfing gene has been mapped to the long arm of chromosome 3H. Stepwise multiple regression was also used to identify another region of the barley genome (on chromosome 7H), which contributed to variation in height. The denso locus was shown to be associated with delaying time to heading. A protein (WSP2) and an RAPD marker on barley chromosomes 5H and 6H, respectively, were also associated with time to heading. These results are discussed in relation to the genetic analysis of developmentally important traits and the development of dwarfing genes in barley breeding programs.     

Use of a subset of doubled-haploid lines for RAPD interval mapping in barley.

Molecular markers have been used in barley to locate genes and quantitative trait loci. Only a few RAPD markers have been located on barley marker maps. The objectives of this study were (i) to place RAPD markers in specific intervals on the barley linkage map developed from the cross Steptoe (S) x Morex (M), (ii) to examine the distribution of RAPD markers, and (iii) to compare markers amplified by Taq DNA polymerase with those amplified by the Stoffel fragment of Taq DNA polymerase. Screening of DNA from S and M with 362 decamer primers identified 85 that amplified 127 reliable RAPDs. A subset of 15 doubled-haploid (DH) lines from the 150 DH line mapping population was used to place these RAPD markers in intervals on the SM map. This subset can be used for rapid placement of any new markers on the SM linkage map. Most of the RAPD markers were dominant but four codominant RAPDs were identified. The RAPDs were not evenly distributed, with many clustered around the centromeric region of each chromosome. Two of these clusters were located in intervals larger than 15 cM. Testing of 38 to 42 additional DH lines provided more precise placement of eight of the markers in these clusters. Reliable RAPDs were detected with 44% of the primers tested with the Stoffel fragment, but with only 17% of the primers tested with Taq DNA polymerase. These RAPDs provide additional markers for use in barley improvement.