辣椒疫霉产毒共分离RAPD标记的研究*

辣椒疫霉（Ｐｈｙｔｏｐｈｔｈｏｒａ　ｃｏｐｓｉｃｉ）毒素的产生是由一个不完全显性基因所控制,通过ＲＡＰＤ／ＢＳＡ分析证明,用ＯＰＷ１２扩增得到一条约１３００ｂｐ的ＲＡＰＤ标记带,该带与辣椒疫霉产毒共分离。纯化回收ＯＰＷ１２　１３００ＤＮＡ,共转化感受态Ｅ．ｃｏｌｉ　ＤＨ５ａ,筛选出３个白色阳性克隆,序列分析发现该标记ＤＮＡ为１２９１ｂｐ。这一标记ＤＮＡ序列的阐明为进一分析产毒遗传机理提供了新的信息。     

辣椒疫霉产毒共分离RAPD标记的研究

辣椒疫毒（Ｐｈｙｔｏｐｈｔｈｏｒａ ｃａｐｓｉｃｉ）毒素的产生是由一个不完全显性基因所控制,通过ＲＡＰＤ／ＢＳＡ分析证明,用ＯＰＷ１２扩增得到一条约１３００ｂｐ的ＲＡＰＤ标记带,该带与辣椒疫霉产毒共分离。纯化回收ＯＰＷ１２１３００ＤＮＡ,共转化感受态Ｅ．ｃｏｌｉ ＤＨ５α,筛选出３个白色阳性克隆,序列分析发现该标记ＤＮＡ为１２９１ｂｐ。这一标记ＤＮＡ序列的阐明为进一步分析产毒遗传机理提供了新的信息     

利用分子标记定位农垦58S的光敏核不育基因

对农垦５８Ｓ（Ｏｒｙｚａｓａｔｉｖａｓｐ．ｊａｐｏｎｉｃａ）／大黑矮生标记基因系ＦＬ２组合组建可育集团和不育集团,并以亲本为对照进行了ＲＦＬＰ、ＲＡＰＤ和双引物ＲＡＰＤ分析,结果第１２染色体上的一个单拷贝标记Ｇ２１４０与光敏核不育基因连锁遗传,二者间的遗传图距为１４．１ｃＭ（ｃｅｎｔｉｍｏｒｇａｎ）。在筛选过的１０４０个随机单引物和１９０个双引物中,仅引物ＯＰＡＵ１０扩增出与光敏核不育基因连锁的１．５ｋｂＤＮＡ片段,回收、克隆该ＤＮＡ片段并制备探针,将其转换成共显性的ＲＦＬＰ标记并命名为ＯＰＡＵ１０１５００。分离群体连锁分析表明该标记与标记Ｇ２１４０紧密连锁,将农垦５８Ｓ的一对光敏核不育基因定位于第１２染色体上。     

中国对虾cDNA文库的构建

中国对虾ｃＤＮＡ文库的构建ＣＯＮＳＴＲＵＣＴＩＯＮＯＦｃＤＮＡＬＩＢＲＡＲＹＯＦＳＨＲＩＭＰＰＥＮＡＥＵＳＣＨＩＮＥＮＳＩＳ（ＣＲＵＳＴＡＣＥＡ,ＤＥＣＡＰＯＤＡ）关键词中国对虾ｃＤＮＡ文库构建ＫｅｙｗｏｒｄｓＰｅｎａｅｕｓｃｈｉｎｅｎｓｉｓ,ｃＤＮ...     

用PCR扩增和克隆马立克氏病病毒糖蛋白D基因

用ＰＣＲ技术,从ＧＡ株马立克氏病病毒（ＭＤＶ）感染的成纤维细胞（ＧＥＦ）基因组ＤＮＡ中扩增出ＭＤＶ糖蛋白Ｄ（ｇＤ）抗原基因片段的约１３００ｂｐ编码序列,将该ｐｃＲ扩增的产物于ＥｃｏＲＩ和Ｋｐｎｌ位点克隆到ｐＵＣ１８质粒载体中,在以ｄｉｇｏｘｉｇｅｎｉｎ（ｄｉｇ）标记的ｇＤＰＣＲ产物作为探针,进行原位杂交初步筛选到阳性重组质粒克隆,再根据酶切分析筛选到含ＭＤＶｇＤ基因的重组质粒ｐ１８ＭｇＤ。将ｐ１８ＭｇＤ质粒ＤＮＡ用ｄｉｇ标记后,在Ｓｏｕｔｈｅｒｎｂｌｏｔ中,该探针能识别ＭＤＶ基因组ＤＮＡ的ＢａｍＨＩ－Ａ克隆中的Ａ片段ＤＮＡ。酶切位点分析表明,该ｇＤ克隆也和已发表的ＭＤＶ的ＲＢＩＢ株ｇＤ一样,不含有ＥｃｏＲⅠ、ＨｉｎｄⅢ、ＰｓｔⅠ、ＳｍａⅠ、ｐｖｕⅡ等酶切位点。证明该重组质粒是ＭＤＶｇＤ克隆。     

番茄OVATE基因调控果实梨形发育

ＰｒｏｃＮａｔｌＡｃａｄＳｃｉＵＳＡ ,2 0 0 2 ,99:1 330 2～ 1 330 6早期研究表明番茄果实的梨形性状由位于第二染色体的一个隐性基因ｏｖａｔｅ所控制 ,ｏｖａｔｅ基因位于分子标记ＴＧ645附近 ,以此标记为探针筛选番茄ＢＡＣ文库将该基因定位于一个长为 1 0 5ｋｂ的ＤＮＡ片段内 ,进一步的分子标记定位表明该基因在含有 8个ＯＲＦ的 55ｋｂＤＮＡ内。通过ＰＣＲ扩增了圆形番茄这一区域ＤＮＡ并进行测序 ,结果表明突变体的ＯＲＦ6中有三处发生了突变。ＯＲＦ6由两个外显子和 1个内含子组成 ,有一个点突变和一个 2ｂｐ的插入或缺失突变…     

RAPD标记构建水稻分子连锁图

利用随机扩增多态性ＤＮＡ（ＲＡＰＤ）,在一个水稻（Ｏｒｙｚａ ｓａｔｉｖａ Ｌ．）的双单倍体（ＤＨ）群体中发展分子标记,仅用５２ 个ＲＡＰＤ标记建成了一个水稻ＲＡＰＤ分子连锁图。该图覆盖基因组的总长度为８９８．４ ｃＭ （ｃｅｎｔｉｍ ｏｒｇａｎ）,标记间的平均间距为１７．３ ｃＭ,它能与用同一群体构成的ＲＦＬＰ图谱互相补充     

一个新的水稻MADS—box基因的克隆及表达分析

根据ＭＡＤＳ－ｂｏｘ基因保守区结构,设计简并性引物,利用３＇ＲＡＣＥ从水稻（Ｏｒｙｚａ ｓａｔｉｖａ Ｌ．）中克隆了１个新的水稻ＭＡＤＳ－ｂｏｘ基因的ｃＤＮＡ片段,同时利用５＆ＲＡＣＥ获得了全长ｃＤｎＡ命名为ＦＤＲＭＡＤＳＳ。序列分析表明,该ｃＤＮＡ全长１４０６ｂｐ,开放阅读框共编码２３３个到,具有典型的植物ＭＡＤＳ－ｂｏｘ基因的结构。推测的氨基酸序列与拟南芥的ＭＡＤＳ－ｂｏｘ基因,ＡＧＬ１４同     

随机扩增多态DNA（RAPD）标记用于丁香品种遗传分析及品种分类

采用随机扩增多态ＤＮＡ（ＲＡＰＤ）标记分析了１５个丁香品种的ＤＮＡ扩增产物。研究选用了１６个随机引物,共扩增出９６条带,其中５５条带为可重复性条带,有价值条带大小多在５１７ｂｐ至１６３６ｂｐ之间。这些标记足以区分这些丁香品种。欧丁香（Ｓｙｒｉｎｇａｖｕｌｇａｒｉｓ）与Ｓ．×ｈｙａｃｉｎｔｈｉｆｌｏｒａ间的相似系数为６１．５％,欧丁香与Ｓ．×ｐｒｅｓｔｏｎｉａｅ间的相似系数为４７．２％,Ｓ．×ｈｙａｃｉｎｔｈｉｆｌｏｒａ与Ｓ．×ｐｒｅｓｔｏｎｉａｅ间的相似系数为４３．６％。结果表明,欧丁香与Ｓ．×ｈｙａｃｉｎｔｈｉｆｌｏｒａ亲缘关系最近。应用ＲＡＰＤ资料分析讨论了一些品种的起源。ＲＡＰＤ技术为丁香品种分类鉴定提供了可靠方法。     

葡萄感霜霉病基因RAPD标记的序列分析

利用Ｗｉｚａｒｄ ＤＮＡ ｃｌｅａｎ－ｕｐ ｓｙｓｔｅｍ纯化葡萄感霜霉病基因ＲＡＰＤ遗传标记的ＤＮＡ片段,用细菌质粒ｐＧＥＭ Ｔ－ｅａｓｙ ｖｅｃｔｏｒ克隆该片段,采用自动荧光ＤＮＡ测序仪对片段的核苷酸组成进行双向测序。来自欧洲葡萄粉红玫瑰的葡萄感霜霉病基因ＲＡＰＤ标记由８３５对核苷酸及其特定序列组成。所获的感霜霉病基因ＲＡＰＤ标记可以作为合成探针的基础,用于葡萄抗病育种过程中的早期选择及品种对霜     

葡萄早熟芽变品种“早生高墨”的RAPD分析

以中国野生葡萄的部分株系、河岸葡萄、砧木品种S04和欧洲葡萄部分品种的幼叶为试材,采用改良CTAB法,提取葡萄基因组DNA的完整性好、纯度高。以所提葡萄基因组DNA为模板,共筛选随机寡核苷酸引物180个,对葡萄品种高墨及其早熟芽变品种早生高墨(紫玉)进行RAPD分析,结果发现引物OPW02和OPG06在两者之间扩增出了与葡萄早熟性状相关的多态性DNA片段OPW02—590、OPG06—1300和OPG06—400。这为进一步克隆、测序并分析它们的序列构成,了解葡萄早熟芽变的分子机理乃至其它果树植物芽变的分子机理提供了分子依据。     

Identification,cloning and sequence analysis of a dwarf genome-specific RAPD marker in rubber tree [<Emphasis Type="Italic">Hevea brasiliensis</Emphasis> (Muell.) Arg.]

High-yielding dwarf clones of Hevea brasiliensis are tolerant to wind damage and therefore useful for high-density planting. The identification of molecular markers for the dwarf character is very important for isolating true-to-type high-yielding dwarf hybrid lines in the early stage of plant breeding programs. We have identified a dwarf genome-specific random amplified polymorphic DNA (RAPD) marker in rubber tree. A total of 115 random oligonucleotide 10-mer primers were used to amplify genomic DNA by PCR, of which 19 primers produced clear and detectable bands. The primer OPB-12 generated a 1.4-kb DNA marker from both natural and controlled F₁ hybrid progenies (dwarf stature) derived from a cross between a dwarf parent and a normal cultivated clone as well as from the dwarf parent; it was absent in other parent (RRII 118). To validate this DNA marker, we analyzed 22 F₁ hybrids (13 with a dwarf stature and nine with a normal stature); the dwarf genome-specific 1.4-kb RAPD marker was present in all dwarf-stature hybrids and absent in all normal-stature hybrids. This DNA marker was cloned and characterized. DNA marker locus specificity was further confirmed by Southern blot hybridization. Our results indicate that Southern blot hybridization of RAPD using probes made from cloned DNA fragments allows a more accurate analysis of the RAPD pattern based on the presence/absence of specific DNA markers than dye-stained gels or Southern blot analysis of RAPD blots using probes made from purified PCR products. Detection of RAPD markers in the hybrid progenies indicates that RAPD is a powerful tool for identifying inherited genome segments following different hybridization methods in perennial tree crops.     

Molecular characterization of RAPD and SCAR markers linked to the Tm-1 locus in tomato

We have cloned and sequenced six RAPD fragments tightly linked to the Tm-1 gene which confers tomato mosaic virus (ToMV) resistance in tomato. The terminal ten bases in each of these clones exactly matched the sequence of the primer for amplifying the corresponding RAPD marker, except for one in which the 5-endmost two nucleotides were different from those of the primer. These RAPD clones did not cross-hybridize with each other, suggesting that they were derived from different loci. From Southern-hybridization experiments, five out of the six RAPD clones were estimated to be derived from middle- or high-repetitive sequences, but not from any parts of the ribosomal RNA genes (rDNA), which are known to be tightly linked with the Tm-1 locus. The remaining clone appeared to be derived from a DNA family consisting of a few copies. These six RAPD fragments were converted to sequence characterized amplified region (SCAR) markers, each of which was detectable using a pair of primers having the same sequence as that at either end of the corresponding RAPD clone. All pairs of SCAR primers amplified distinct single bands whose sizes were the same as those of the RAPD clones. In four cases, the SCAR markers were present in the line with Tm-1 but absent in the line without it, as were the corresponding RAPD markers. In the two other cases, the products of the same size were amplified in both lines. When these SCAR products were digested with different restriction endonucleases which recognize 4-bp sequences, however, polymorphisms in fragment length were found between the two lines. These co-dominant markers are useful for differentiating heterozygotes from both types of homozygote.     

Targeted identification of markers linked to malaria and filarioid nematode parasite resistance genes in the mosquito Aedes aegypti.

Quantitative trait loci (QTL) have been identified for competence of the mosquito Aedes aegypti to transmit the avian malaria parasite Plasmodium gallinaceum and the human filarial parasite Brugia malayi. Efforts towards the map-based cloning of the associated genes are limited by the availability of genetic markers for fine-scale mapping of the QTL positions. Two F2 mosquito populations were subjected to bulked segregant analysis to identify random amplified polymorphic DNA (RAPD)-PCR fragments linked with the major QTL determining susceptibility to both parasites. Individual mosquitoes for the bulks were selected on the basis of their genotypes at restriction fragment length polymorphism (RFLP) loci tightly linked with the QTL. Pool-positive RAPD fragments were cloned and evaluated as RFLP markers. Of the 62 RAPD/RFLP fragments examined, 10 represented low-copy number sequences. Five of these clones were linked with the major QTL for P. gallinaceum susceptibility (pgs1), of which one clone mapped within the flanking markers that define the QTL interval. The remaining five clones were linked with the major QTL for B. malayi susceptibility (fsb1), and again one clone mapped within the flanking markers that define the QTL interval. In addition, nine RAPD/RFLP fragments were isolated that seem to be of non-mosquito origin.     

Primary Study of Rice AFLP Analysis-Optimization of Reaction Conditions and Analysis of Thermo sensitive Genic Male Sterile Rice Allelic Mutant Lines

AFLP analysis was performed between a pair of thermo-sensitive genic male sterile (TGMS) rice allelic mutant lines (5460S and 5460F). The reaction conditions for rice AFLP assay were optimized. The relative efficiencies for polymorphism detection of RFLP, RAPD and AFLP were compared. The results indicated that the efficiency for polymorphism detection in rice was in the order of AFLP > RAPD > RFLP, and also indicated that AFLP was a powerful DNA molecular marker technique for polymorphism detection, especially in the case of extremely low polymorphism, such as isogenic lines and allehc mutant hnes. Some of the AFLP products between the TGMS rice allehc mutant lines were cloned. Three of them were used as mixed probes to screen BAC library of rice line 5460S. 12 positive clones were screened out. In addition, the advantages and disadvantages of these three molecular marker systems were discussed.     

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。     

Marker-based cloning of the region containing the UhAvr1 avirulence gene from the basidiomycete barley pathogen Ustilago hordei

Race-cultivar specialization during the interaction of the basidiomycete smut pathogen Ustilago hordei with its barley host was described in the 1940s. Subsequent genetic analyses revealed the presence of dominant avirulence genes in the pathogen that conform to the gene-for-gene theory. This pathosystem therefore presents an opportunity for the molecular genetic characterization of fungal genes controlling avirulence. We performed a cross between U. hordei strains to obtain 54 progeny segregating for three dominant avirulence genes on three differential barley cultivars. Bulked segregant analysis was used to identify RAPD and AFLP markers tightly linked to the avirulence gene UhAvr1. The UhAvr1 gene is located in an area containing repetitive DNA and this region is undetectable in cosmid libraries prepared from the avirulent parental strain. PCR and hybridization probes developed from the linked markers were therefore used to identify cosmid clones from the virulent (Uhavr1) parent. By walking on Uhavr1-linked cosmid clones, a nonrepetitive, nearby probe was found that recognized five overlapping BAC clones spanning 170 kb from the UhAvr1 parent. A contig of the clones in the UhAvr1 region was constructed and selected probes were used for RFLP analysis of the segregating population. This approach genetically defined an approximately 80-kb region that carries the UhAvr1 gene and provided cloned sequences for subsequent genetic analysis. UhAvr1 represents the first avirulence gene cloned from a basidiomycete plant pathogen.     

Restriction Fragment Length Polymorphism and Random Amplified Polymorphic DNA Analysis of Chickpea Accessions

Genetic diversity analysis was carried out in chickpea accessions using restriction fragment length polymorphism (RFLP) and random amplified polymorphic DNA (RAPD) techniques. RFLP analysis using 26 Pst I sub-genomic clones on ten chickpea accessions in 130 probe-enzyme combinations detected polymorphism with only two clones. Pst I clones, CG 141 detected polymorphism in ICC 4918 and Pusa 209 while CG 500 detected polymorphism in Pusa 261, ILC 26 and in ILC 13326. These clones detected very few polymorphic markers. Analysis using 10 Eco RI clones on twelve chickpea accessions have shown better hybridisation signal and one clone detected polymorphism in Pusa 256. RFLP analysis of both cultivated and wild Cicer species using heterologous DNA probe Cab3C revealed polymorphism only in wild Cicer species (Cicer reticulatum L., JM 2100). RAPD analysis of 13 chickpea accessions which includes mutants of C 235 and E100Y showed greater degree of polymorphism with 1 - 5 unique DNA bands for all the accessions. Phylogenetic analysis of the RAPD data helped to group the accessions. C 235 and its mutants were found to be closely grouped while E100Y and its mutant E100Ym grouped apart. Desi and kabuli chickpea accessions however, could not be separately grouped. This revised version was published online in July 2006 with corrections to the Cover Date.     

Development of reliable PCR-based markers linked to downy mildew resistance genes in lettuce

Summary Sequence characterized amplified regions (SCARs) were derived from eight random amplified polymorphic DNA (RAPD) markers linked to disease resistance genes in lettuce. SCARs are PCR-based markers that represent single, genetically defined loci that are identified by PCR amplification of genomic DNA with pairs of specific oligonucleotide primers; they may contain high-copy, dispersed genomic sequences within the amplified region. Amplified RAPD products were cloned and sequenced. The sequence was used to design 24-mer oligonucleotide primers for each end. All pairs of SCAR primers resulted in the amplification of single major bands the same size as the RAPD fragment cloned. Polymorphism was either retained as the presence or absence of amplification of the band or appeared as length polymorphisms that converted dominant RAPD loci into codominant SCAR markers. This study provided information on the molecular basis of RAPD markers. The amplified fragment contained no obvious repeated sequences beyond the primer sequence. Five out of eight pairs of SCAR primers amplified an alternate allele from both parents of the mapping population; therefore, the original RAPD polymorphism was likely due to mismatch at the primer sites.