甘蓝品种''''争春''''和''''寒光2号''''的DNA指纹图谱构建

用SDS法提取甘蓝（Brassfca oleraceavat．capitata）品种‘争春’、‘寒光2号’及其各自亲本的基因组DNA,通过SRAP、RAPD两种分子标记方法,构建其DNA指纹图谱,用于种子纯度鉴定。利用30对SRAP引物组合和200个RAPD随机引物,以各品种及其亲本的基因组DNA为模板组进行筛选,结果显示：多数SRAP引物组合对模板组的扩增带型一致,少数组合扩增出差异,但未能找到具有互补差异的引物组合;通过RAPD标记方法筛选出能鉴定2个品种纯度的引物分别为S42、S103、S193和S42、S89、S151,其中引物S42对2组材料均能扩增出特异的RAPD指纹图谱,并将RAPD指纹图谱转变为相应的数字指纹。     

莲藕品种DNA指纹图谱的绘制

采用RAPD技术对14个莲藕品种进行遗传多态性分析,用5个Operon引物和80个SBS的RAPD引物进行筛选,从中选出来自SBS的RAPD-C13和RAPD-D15扩增出的8条多态性条带,绘制了14个品种的DNA指纹图谱,在该图谱中每个品种均有各自特异的DNA指纹。     

对5个S180克隆细胞株RAPD特征的研究

目的运用随机扩增多态性DNA(RAPD)技术建立S180的5个克隆细胞株的特异性图谱。方法运用23条引物对S180-S2D9、S180-S2D7、S180-S1F11、S180-S1H10、S180-S1B115个克隆细胞株的基因组DNA进行RAPD-PCR扩增,以琼脂糖电泳观察结果。结果筛选出3条在各克隆株扩增产物间有差异的引物。结论5个S180克隆细胞株的RAPD特征有明显区别。     

BALB/c小鼠遗传质量检测的新方法

目的比较随即扩增多态性方法（RAPD）、微卫星方法（STR）与生化标记方法对近交系小鼠遗传质量检测的差异,为近交系动物遗传质量控制提供一种分子生物学方法。方法提取近交系小鼠BALB/c基因组DNA,用6条RAPD引物和20对STR引物对其进行PCR扩增,用生化标记法检测13个位点。结果在6条RAPD引物中,引物2（p2）、引物3（p3）、引物5（p5）和引物6（p6）这四条引物扩增的条带出现差异,表现为不同的RAPD图谱;在20对STR引物中,引物2、4、10和11,这四对引物扩增的条带出现差异,表现为不同的STR图谱;13个生化标记位点中,过氧化氢酶-2（Ce-2）等6个生化位点发现杂合基因。结论RAPD和STR可用于验证生化标记方法的实验结果,并用于保证近交系动物的遗传质量。     

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．     

DNA指纹图谱鉴别双歧杆菌的研究

采用RAPD技术选用10条引物对7种9株双歧杆菌基因组DNA进行PCR扩增,根据在优化条件下所得DNA指纹图谱分析了双歧杆菌菌株的遗传多样性,并构建了相似性指数矩阵和树状图.结果表明,不同序列的随机引物可扩增不同形式的RAPD图谱,但并非所有图谱都具有分类学意义,其中引物S256对双歧杆菌种及同种不同菌株均具有良好的区分能力,由该引物扩增的RAPD图谱计算出的相对性指数矩阵以及由此构建的聚类树状图均能正确地反映出双歧杆菌的系统发育关系,同时对RAPD图谱作为工业双歧杆菌分子标记的可能性进行了探讨.     

SCAR标记在茶树种质资源鉴定中的应用

SCAR标记是一种在RAPD技术的基础上发展起来的新型分子标记技术,提高了分子标记辅助选择育种的效率,在茶树种质资源的合理开发与利用中具有广阔的应用前景.运用优化后的RAPD反应体系对10个茶树品种的基因组DNA进行遗传差异分析,随机引物S89、S4分别在白毫早和福云6号中扩增得到长度为498 bp、1 622 bp的差异片段,命名为BHZ498、FY1622.根据它们的测序结果分别设计了一对特异引物,BHZ498的特异引物为SB1/SB2;FY1622的特异引物为SC1/SC2,用这两对特异引物对10个茶树品种的基因组DNA进行扩增.引物SB1/SB2和SC1/SC2分别在白毫早和福云6号中扩增出唯一的一条扩增带,而这两对引物在其他供试茶树材料中均无相应的扩增带,结果表明已将BHZ498、FY1622标记成功转化成SCAR标记.     

普通小麦抗、感赤霉病品种(系)的RAPD标记分析

采用RAPD技术,用524个随机引物对3个抗病品种和4个感病品种的基因组DNA进行扩增,发现3个引物能在抗、感品种间检测到稳定的多态性。这3个引物及它们产生的多态片段是S347 1220bp、S372 872bp和S375 1360bp,其中S347 1220bp和S372 875bp在感病品种上呈显性扩增,在抗病品种上无扩增,相反S375 1360bp在感病品种上无扩增,在抗病品种上呈显性扩增。初步判断这3个特异带与小麦赤霉病抗性有关。     

小麦品种Triticum spelta album中抗条锈病基因Yr5的RAPD标记

共用520个10碱基随机引物对小麦抗条锈基因Yr5的近等基因系进行了RAPD分析,发现了3个特异性DNA片段S1496、S14181950与Yr5基因连锁,其中S1496761与Yr5基因紧密连锁,遗传距离为2．7cM。经对特异性DNA片段S1496 761进行克隆,测序,设计了PCR扩增用专化引物SC－S1496 761a和SC－S149676b,用该引物可扩增出与原RAPD引物扩增出的相似的特异DNA片段,由于该引物还可扩增出迁移率极为相近的另1条非特异带,在琼脂糖凝胶上难以分辨,需用聚丙烯酰胺凝胶电泳结合银染进行检测,经用F2分离群体及部分相关品种材料检测,已证明该标记的可靠性。     

柚类种质资源RAPD标记研究的引物筛选

利用 10 0个 10碱基随机引物 ,对柚类 4个品种酸柚、沙田柚、文旦柚和泰国柚进行了RAPD标记的引物筛选研究 ,结果为无扩增产物的引物 18个 ,在 1、 2、 3个和所有 4个样品中有扩增产物的引物数分别为 2 0、 13、 2 5和 2 4个 ;读取了 12个在所有 4个样品中都有扩增产物的引物的 RAPD带 ,计算了样品间 RAPD多态性位点的百分率为 60 .6% ;计算了样品间的相似系数和遗传距离 ,并对遗传距离进行了 UPGMA聚类分析 ,论证了利用所筛选出的引物对柚类进行 RAPD标记研究的可行性和可靠性     

Polymorphisms in grapevine DNA detected by the RAPD PCR technique

A sensitivie, reproducible technique is described for detecting polymorphisms between the nuclear DNA of grapevine isolates using the RAPD PCR technique. Unique fingerprints of a number of cultivars were readily distinguished by using either single primers or mixtures of two primers. The method will be used to provide a databank of fingerprints for the rapid identification of grapevine cultivars, and to develop phylogenetic relationships. It will also be extended and modified in an attempt to detect polymorphisms between DNAs of clonal selections of individual cultivars.     

牛鞭草品种EST-SSR指纹图谱构建及遗传多样性分析

为探讨牛鞭草(Hemarthria spp.)品种间的遗传多样性,从86对EST-SSR引物中筛选出8对引物对牛鞭草属6个品种进行指纹图谱的构建及遗传多样性分析。结果表明,8对EST-SSR引物对牛鞭草属6个品种共扩增出193条清晰条带,多态性条带161条,多态性比例为83.4%。每条引物的多态信息含量(PIC)为0.480~0.695,平均为0.602。UPGMA聚类分析表明,牛鞭草属6个品种在相似系数为0.652处可分为两大类群。8对EST-SSR引物均能将6个品种完全区分开,以3对EST-SSR引物扩增的电泳图谱为基础,建立了牛鞭草属6个品种的指纹图谱标准模式图,每个品种都有唯一的指纹图谱。牛鞭草属6个品种的平均Nei’s基因多样性指数为0.333,平均Shannon信息指数为0.496,品种间的相似系数介于0.399~0.782之间。可见,牛鞭草属植物品种的遗传多样性较丰富,种间差异明显。     

Development of a novel and efficient strategy for practical identification of Pyrus spp (Rosaceae) cultivars using RAPD fingerprints

Accurate and reliable cultivar identification of crop species is essential to guarantee plant material identity for purposes of registration, cultivar protection and production. To facilitate identification of plant cultivars, we developed a novel strategy for efficient recording of DNA molecular fingerprints in genotyped plant individuals. These fingerprints can be used as efficient referential information for quick plant identification. We made a random amplified polymorphic DNA (RAPD) marker analysis of 68 pear cultivars. All pear genotypes could be distinguished by a combination of eight 11-mer primers. The efficiency of the method was further verified by correct identification of four cultivars randomly chosen from the initial 68. The advantages of this identification include use of fewer primers and ease of cultivar separation by the corresponding primers marked on the cultivar identification diagram. The cultivar identification diagram can efficiently serve for pear cultivar identification by readily providing the information needed to separate cultivars. To the best of our knowledge, this is the most efficient strategy for identification of plant varieties using DNA markers; it could be employed for the development of the pear industry and for the utilization of DNA markers to identify other plant species.     

A comparison of methods for the estimation of genetic diversity in strawberry cultivars

RAPD markers were used to examine the genetic relatedness of eight strawberry cultivars released from four breeding programmes around the world. Ten random primers successfully amplified DNA fragments from each cultivar and specific fingerprints were generated from the molecular marker data. The cultivars were traced back to founding clones and the relationships between the cultivars were examined from both the molecular and the pedigree data.     

Identification of hazelnut (Corylus avellana) cultivars by RAPD analysis

The random amplified polymorphic DNA (RAPD) technique offers a useful tool to detect DNA polymorphisms. It can also be used to distinguish different clones and cultivars. We have developed a comprehensive RAPD-based procedure for the routine molecular typing of various plants. Here we report the application of this technique for the correct identification of six hazelnut cultivars (Corylus avellana) widespread in the Campania region (south Italy). The analysed hazelnut cultivars were successfully distinguished by their RAPD fingerprints using the DNA primers U2, U3, U4, U11 and U14. However, in each cultivar we observed very low genetic heterogeneity among the clonal variants. Since this technique is among the simplest and easiest methods used to fingerprint DNA, it could be easily transferred to less sophisticated laboratory infrastructures (e.g. outstations of crop regulatory agencies). Received: 20 December 1997 / Revision received: 6 August 1998 / Accepted: 13 November 1998     

Stability of RAPD fingerprints in potato: Effect of source tissue and primers

Variations in random amplified polymorphic DNA (RAPD) profiles from leaf, stem, root, and tuber tissues were observed in case of two glasshouse grown potato cultivars using 40 decamer primers suggesting possible danger of cultivar misidentification. Genomic DNA extracted from the above four tissues of four in vitro grown potato cultivars, however, produced more uniform RAPD fingerprints. A significant effect of random primers on fingerprint uniformity was observed in case of both glasshouse and in vitro grown samples. A new concept of stability index for random primers based on homogeneity of RAPD profiles obtained from different tissues of a single plant have been introduced. It is concluded that RAPD analysis of genomic DNA extracted from any tissue of in vitro grown potato plants using 14 selected decamer primers could be used to develop RAPD fingerprints for identification of Indian potato cultivars.     

A new strategy employed for identification of sweet orange cultivars with RAPD markers

We optimized RAPD techniques by increasing the length of RAPD primers and performing a strict screening of PCR annealing temperature to distinguish 60 sweet orange cultivars from the Research Institute of Pomology at the Chinese Academy of Agricultural Sciences. A new approach called cultivar identification diagram (CID) was used to improve the efficiency of RAPD markers for cultivar identification. Thirteen effective primers were first screened from 54 RAPD arbitrary 11-mer primers based on their amplification products and amplified polymorphic bands; they were then used for PCR amplification of all 60 cultivars. All cultivars were manually and completely separated by the polymorphic bands appearing in DNA fingerprints from 13 primers; a CID of the 60 sweet orange cultivars was then constructed. This CID separated all the cultivars from each other, based on the polymorphic bands; the corresponding primers were marked in the correct positions on the sweet orange CID. The CID strategy facilitates the identification of fruit cultivars with DNA markers. This CID of sweet orange cultivars will be very useful for the protection of cultivar rights and for early identification of seedlings in the nursery industry.     

Interpretation of randomly amplified polymorphic DNA marker data for fingerprinting sweet potato (Ipomoea batatas L.) genotypes

In this paper we present a method for the generation of randomly amplified polymorphic DNA (RAPD) markers for sweet potato. These were applied to produce genetic fingerprints of six clonal cultivars and to estimate genetic distances between these cultivars. The level of polymorphism within the species was extremely high. From the 36-decamer random primers used, 170 fragments were amplified, of which 132 (77.6%) were polymorphic. Ten primers resulted in no detected amplification. Of the remaining 26 primers for which amplification was achieved, only one did not reveal polymorphism. Six primers used alone enabled the discrimination of all six genotypes. Pattern analysis, which employed both a classification and ordination method, enabled the grouping of cultivars and the identification of primers which gave greatest discrimination among the cultivars.     

Enhanced detection of polymorphic DNA by multiple arbitrary amplicon profiling of endonuclease-digested DNA: identification of markers tightly linked to the supernodulation locus in soybean

Multiple endonuclease digestion of template DNA or amplification products can increase significantly the detection of polymorphic DNA in fingerprints generated by multiple arbitrary amplicon profiling (MAAP). This coupling of endonuclease cleavage and amplification of arbitrary stretches of DNA, directed by short oligonucleotide primers, readily allowed distinction of closely related fungal and bacterial isolates and plant cultivars. MAAP analysis of cleaved template DNA enabled the identification of molecular markers linked to a developmental locus of soybean (Glycine max L. Merrill). Ethyl methane sulfonate (EMS)-induced supernodulating, near-isogenic lines altered in the nts locus, which controls nodule formation, could be distinguished from each other and from the parent cultivar by amplification of template pre-digested with 2–3 restriction enzymes. A total of 42 DNA polymorphisms were detected using only 19 octamer primers. In the absence of digestion, 25 primers failed to differentiate these soybean genotypes. Several polymorphic products co-segregated tightly with the nts locus in F₂ families from crosses between the allelic mutants nts382 and nts1007 and the ancestral G. soja Sieb. & Succ. PI468.397. Our results suggest that EMS is capable of inducing extensive DNA alterations, probably around discrete mutational hot-spots. EMS-induced DNA polymorphisms may constitute sequence-tagged markers diagnostic of specific genomic regions.     

DNA Fingerprinting of Trypanosoma vivax Isolates Rapidly Identifies Intraspecific Relationships

ABSTRACT. Using the polymerase chain reaction and arbitrarily selected oligonucleotide primers of 10 or 11 bases, we have amplified DNA sequences from Trypanosoma vivax parasites isolated from South America and Africa. On the basis of polymorphisms in the DNA fingerprints generated by three of the primers, the parasites could be separated into two major groups, one comprising T. vivax isolates from Kenya and the second including all the other T. vivax parasites (from Colombia, The Gambia, Nigeria and Uganda). One of these three primers (ILo 525) also gave isolate-specific DNA fingerprints for the parasites for the parasites tested, which will allow the use of this technique both in the species identification and discrimination of T. vivax parasites.