猕猴桃属种间体细胞杂种

利用PEG融合方法,分别进行了中华猕猴桃(Actinidia chinensis var.chinensis)(2n=2x=58)子叶愈伤组织来源的原生质体与美味猕猴桃(A.deliciosa var.deiciosa)(2n=6x=174)子叶愈伤组织原生质体、以及狗枣猕猴桃(A.kolomikta)(2n=2x=58)叶肉原生质体种间原生质体融合。结果表明:中华猕猴桃与美味猕猴桃融合的1个克隆和中华猕猴桃与狗枣猕猴桃融合的4个克隆的RAPD谱带分别具有双亲特异的DNA谱带;经流式细胞仪分析,前者细胞核倍性推测为8倍体,后者细胞核为3倍体、4倍体和5倍体。初步鉴定这5个克隆是猕猴桃属种间体细胞杂种。     

Identification and classification of celery cultivars with RAPD markers

Summary Twenty-one celery (Apium graveolens L. var. dulce) cultivars, one celeriac (var. rapaceum) and one annual smallage (var. secalinum) cultivar were screened for polymorphic RAPD (Random Amplified Polymorphic DNA) markers with 28 arbitrary 10-mer primers. Among a total of 309 bands observed, 29 (9.3%) were polymorphic in the 23 cultivars screened, but only 19 (6.1%) markers were polymorphic within the 21 type dulce cultivars. These markers were sufficient to distinguish each of the cultivars used. The average marker difference was 6.4 between two celery cultivars, 16.7 between celery and annual smallage, 14.7 between celery and celeriac, and 12.0 between annual smallage and celeriac. The celery cultivars surveyed were classified into three groups based on the marker differences. The relationship among the dulce-type cultivars concluded from this research is basically consistent with the known lineage of the cultivars and the previous study using stem protein and isozyme markers. RAPD technology provides a new alternative for cultivar identification and classification in celery.     

Application of RAPD markers for characterization of γ-ray-induced rose mutants and assessment of genetic diversity

Six parent and their 12 gamma ray-induced somatic flower colour mutants of garden rose were characterized to discriminate the mutants from their respective parents and understanding the genetic diversity using Random amplification of polymorphic DNA (RAPD) markers. Out of 20 primers screened, 14 primers yielded completely identical fragments patterns. The other 7 primers gave highly polymorphic banding patterns among the radiomutants. All the cultivars were identified by using only 7 primers. Moreover, individual mutants were also distinguished by unique RAPD marker bands. Based on the presence or absence of the 48 polymorphic bands, the genetic variations within and among the 18 cultivars were measured. Genetic distance between all 18 cultivars varied from 0.40 to 0.91, as revealed by Jaccard’s coefficient matrix. A dendrogram was constructed based on the similarity matrix using the Neighbor Joining Tree method showed three main clusters. The present RAPD analysis can be used not only for estimating genetic diversity present in gamma ray-induced mutants but also for correct identification of mutant/new varieties for their legal protection under plant variety rights.     

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.     

Development of DNA markers for identifying chrysanthemum cultivars generated by ion-beam irradiation

Four chrysanthemum cultivars were generated through (carbon) ion-beam irradiation of the original ‘Jimba’ (Chrysanthemum morifolium Ramat.). The new cultivars had acquired a number of superior cultivation traits, while remaining identical to the commercially available ‘Jimba’ in appearance. In this study, polymerase chain reaction (PCR) assays were used to detect the mutated region of each strain, thereby allowing clear identification at the molecular level. PCR assays were performed with 446 primer sets, including random amplified polymorphic DNA (RAPD) primer sets (10-mer RAPD), arbitrarily primed (AP)-PCR primers based on retrotransposon-like sequences and modified RAPD primers (15-mer RAPD). 15-mer RAPD primers generated a 1.49-fold increased band number at high annealing temperatures compared with the original 10-mer RAPD primers and could thus be effective for detection of polymorphic patterns. Our results provide information on the mutated regions of these ion-beam-irradiated chrysanthemum cultivars. Thus, specific DNA markers could be used to improve identification of new cultivars of chrysanthemum as well as other clonal cultivars of horticultural and agricultural crops.     

Comparison of RAPD and RFLP genetic markers in determining genetic similarity among Brassica oleracea L. genotypes

Genetic similarity among 45 Brassica Oleracea genotypes was compared using two molecular markers, random amplified polymorphic DNA (RAPD) and restriction fragment length polymorphisms (RFLPs). The genotypes included 37 broccolis (var. italica), five cauliflowers (var. botrytis) and three cabbages (var. capitata) which represented a wide range of commercially-available germplasm, and included open-pollinated cultivars, commercial hybrids, and inbred parents of hybrid cultivars. Fifty-six polymorphic RFLP bands and 181 polymorphic RAPD bands were generated using 15 random cDNA probes and 62 10-mer primers, respectively. The objectives were to compare RFLP and RAPD markers with regard to their (1) sampling variance, (2) rank correlations of genetic distance among sub-samples, and (3) inheritance. A bootstrap procedure was used to generate 200 random samples of size n (n=2,3,5,... 55) independently from the RAPD and RFLP data sets. The coefficient of variance (CV) was estimated for each sample. Pooled regressions of the coefficient of variance on bootstrap sample size indicated that the rate of decrease in CV with increasing sample size was the same for RFLPs and RAPDs. The rank correlation between the Nei-Li genetic similarity values for all pairs of genotypes (990) based on RFLP and RAPD data was 0.745. Differences were observed between the RFLP and RAPD dendrograms of the 45 genotypes. Overlap in the distributions of rank correlations between independent sub-samples from the RAPD data set, compared to correlations between RFLP and RAPD sub-samples, suggest that observed differences in estimation of genetic similarity between RAPDs and RFLPs is largely due to sampling error rather than due to DNA-based differences in how RAPDs and RFLPs reveal polymorphisms. A crossing algorithm was used to generate hypothetical banding patterns of hybrids based on the genotypes of the parents. The results of this study indicate that RAPDs provide a level of resolution equivalent to RFLPs for detemination of the genetic relationships among genotypes.     

利用RAPD和ISSR分子标记分析怀地黄种质遗传多样性

用RAPD与ISSR技术对怀地黄的8个品种和2个脱毒品系进行了种质遗传多样性分析。分别从80条RAPD引物和44条ISSR引物中筛选出适合怀地黄种质分析的17条RAPD引物和10条ISSR引物,用于RAPD和ISSR分析。17条RAPD引物共扩增出177条带, 多态性位点数为109; 多态性位点比率为61.58%;平均多样性指数(I)为0.3135;每个位点的有效等位基因数（Ne）是1.3641; 10条ISSR引物共扩增出110条带. 多态性位点数为79; 多态性位点比率为71.58%;平均多样性指数(I)为0.3577;每个位点的有效等位基因数（Ne）是1.4037。 基于扩增条带数据库建立了各自的Jaccard遗传相关系数矩阵,构建了相似的分子树状图,将10个供试材料分为2类:一类群含组培85.5、大田85.5、组培9302、大田9302、金状元和金白6个材料;另一类群含北京1号、大红袍、地黄9104和野生地黄4个材料。两种分子标记的分析结果呈极显著正相关(r＝0.649)。结果表明,RAPD与ISSR标记适合于怀地黄种质遗传多样性分析,ISSR标记技术是一种多态性和重复性优于RAPD技术的实用技术。     

利用RAPD技术对葱属品种遗传关系的分析

利用随机扩增多态性DNA(RAPD)技术分析了我国栽培的几个主要葱属品种。所用的20个引物,有11个能扩增出重现性好且稳定的谱带,10个品种共扩增出102条带,其中68条具多态性。根据DNA谱带计算的10个品种相似系数范围为0.571～0.947。对10个品种的UPGMA聚类分析表明,章丘大葱(Allium fistulosum var. gigantum cv. Zhangqiu Welsh onion)、天津五叶齐（A. fistulosum var.gigantum cv. Tianjin Wuyeqi Welsh onion）、上海分葱（A. fistulosum var. caepitosum cv.Shanghai Spring onion）、南京冬葱（A. fistulosum var. caepitosum cv. Nanjing Winter onion）和韩国大葱（A. fistulosum var .gigantum cv. Korea Welsh onion）关系较近。根据聚类结果,将章丘大葱、天津五叶齐、上海分葱、南京冬葱、韩国大葱、细香葱（A. schoenoprasum）以及楼葱（A. fistulosum var. viviparum）归为葱组;而将胡葱（A. ascalonicum）、洋葱（A. cepa）及洋葱和大葱的杂交种归为洋葱组。最后根据RAPD标记,讨论了各品种之间的亲缘关系。     

利用RAPD研究桂林桂花品种间的亲缘关系

采用随机扩增多态性DNA(RAPD)技术,从100个随机引物中筛选出扩增效果较好的20个引物,分 析桂林市23个桂花品种的基因组多态性。20个随机引物共检测到193个位点,其中多态位点114个,占 59.1%。并进行了聚类分析,构建出树状聚类图,将这些品种划分为4个品种群,与传统分类学结果一致。结 果表明,以基因型而不是以表现型为基础,分析桂花品种间的区别是可能的。该技术为解决桂林市的桂花品 种分类问题提供了重要依据。     

Molecular Characterization of Brinjal (Solanum melongena L) Cultivars using RAPD and ISSR Markers

Molecular characterization of 19 advanced cultivars and landraces of brinjal was carried out using RAPD and ISSR markers. Twenty-nine RAPD primers generated a total of 240 amplified fragments, while 23 anchored and non-anchored ISSR primers produced 299 fragments. Of these, 66 (27.5%) RAPD and 56 (18.73%) ISSR fragments were polymorphic. All the cultivars could be distinguished based on RAPD and/or ISSR profiles. A set of two RAPD primers, OPW 11 and OPX 07, was adequate to distinguish all the 19 cultivars. On the other hand, a minimum of ten ISSR primers were required to achieve the same result. Eleven cultivars could be identified by the unique presence or absence of one to four markers. The correlation between primer Rp and the number of cultivars distinguished by RAPD was r = 0.873, while that for ISSR it was r = 0.327. The correlation between PIC of primer and the number of cultivars distinguished was r = 0.324 for RAPD, while for ISSR primers it was r = ? 0.066. The probability of chance identity between two cultivars for RAPD and ISSR markers was calculated as 8.94×10^?4 and 2.25×10^?2, respectively. The average Jaccard’s similarity coefficient between cultivars based on combined RAPD and ISSR data was estimated to be 0.919. The UPGMA analysis grouped the cultivars into three main clusters with significant bootstrap support. While the cultivars bred at Indian Agricultural Research Institute, New Delhi formed one sub-cluster; others did not show a prominent region-based clustering.     

红豆杉科植物RAPD分析及其系统学意义

利用随机扩增多态性ＤＮＡ（ＲＡＰＤ）技术分析了红豆杉科（Ｔａｘａｃｅａｅ）红豆杉属（Ｔａｘｕｓ）、白豆杉属（Ｐｓｅｕｄｏｔａｘｕｓ）、穗花杉属（Ａｍｅｎｔｏｔａｘｕｓ）和榧树属（Ｔｏｒｒｅｙａ）的６种植物：红豆杉（Ｔａｘｕｓ ｃｈｉｎｅｎｓｉｓ （Ｐｉｌｇｅｒ）Ｒｅｈｄ）、南方红豆杉（Ｔａｘｕｓ ｃｈｉｎｅｎｓｉｓ ｖａｒ．ｍａｉｒｅｉ（Ｌｅｍｅｅ ｅｔＬｅｖｌ．）Ｃｈｅｎｇ ｅｔＭａｉｒｅＹｅｗ     

Use of RAPD markers for identifying Nelore bulls with early reproductive maturation onset

Random amplified polymorphic DNA (RAPD) markers were used for identifying animals with early (precocious) or late (non-precocious) reproductive maturation onset. Animals (n=34) were phenotyped according to spermatozoa appearance in ejaculates (group A, 20 animals) or to the expected progeny difference (EPD) values for scrotal circumference (group B, 14 animals). The RAPD markers were initially detected by amplifying two pooled samples of equimolar amounts of DNA from the eight precocious 12 and non-precocious animals of group A. Only 38 out of 320 random primers used for screening group A pooled samples detected polymorphisms. These polymorphic primers generated 443 distinguishable and reproducible bands, from which 174 were polymorphic and 269, monomorphic. These polymorphic primers were then used in RAPD reactions to amplify individual DNA samples from animals belonging to both groups, A and B. The dendrograms generated from RAPD patterns allowed phenotypic class differentiation in both cases. Therefore, RAPD markers can be used as a tool for identifying genotypes favoring early sexual maturation in Nelore breeding programs.     

Optimization of primer screening for evaluation of genetic relationship in rose cultivars

Optimization of primer screening for evaluation of genetic relationship in 34 cultivars of rose through random amplified polymorphic DNA (RAPD) markers was investigated. Four series of decamer primers were used for screening and optimization of RAPD analysis between which A and N series performed good amplification of fragments as compared with other series. The primers OPN-07 and OPN-15 produced maximum number of DNA fragments in Rosa hybrida cv. Anuraag. Some primer either did not produce amplification or produced very poor amplification. Further, ten selected primers were used for genetic analysis of 34 rose cultivars. The primer OPN-15 amplified 21 fragments in all cultivars tested. A total of 162 distinct DNA fragments (bands) ranging from 100 to 3400 base pairs were amplified by using 10 selected random primers. The cluster analysis indicated that these rose cultivars formed nine clusters.     

中国水仙与欧洲水仙品种RAPD指纹的研究

利用随机多态性DNA(RAPD)技术对中国水仙和欧洲红口水仙共6个品种进行了分析。选用了12个10bp引物共扩增出119条DNA片段。计算各样本间的相似性系数和遗传距离,并采用UPGMA法对遗传距离进行了聚类分析。结果表明：中国水仙3个品种亲缘关系十分密切,红口水仙3个品种亲缘关系较近,而中国水仙与红口水仙3个品种间的亲缘关系较远。建立的水仙RAPD技术体系可帮助育种亲本的选配及水仙品种的鉴定。     

Genetic stability of three economically important micropropagated banana (Musa spp.) cultivars of lower Indo-Gangetic plains, as assessed by RAPD and ISSR markers

An efficient micropropagation protocol produced large number of plants of the three elite banana (Musa spp.) cultivars Robusta (AAA), Giant Governor (AAA) and Martaman (AAB) from shoot tip meristem. The genetic relationships and fidelity among the cultivars and micropropagated plants as assessed by random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers, revealed three somaclonal variants from Robusta and three from Giant Governor. A total of 5330 RAPD and 2741 ISSR fragments were generated with 21 RAPD and 12 ISSR primers in micropropagated plants. The percentage of polymorphic loci by RAPD and ISSR were found to be 1.75, 5.08 in Robusta and 0.83, 5.0 in Giant Governor respectively. Among the two marker systems used, ISSR fingerprinting detected more polymorphism than RAPD in Robusta and Giant Governor with most of the primers showing similar fingerprinting profile, whereas Martaman revealed complete genetic stability.     

Application of random amplified polymorphic DNA and inter-simple sequence repeat markers in the genus Crataegus

Hawthorn ( Crataegus spp.) has a long history as an ornamental and a source of medicine. We report the use of random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers to determine genetic relationships in the genus Crataegus . Twenty-eight accessions, including eight species ( Crataegus pinnatifida , Crataegus bretschneideri , Crataegus maximowiczii , Crataegus kansuensis , Crataegus altaica , Crataegus songarica , Crataegus dahurica and Crataegus sanguinea ) and two botanical varieties ( C. pinnatifida var. major and C. maximowiczii var. ninganensis ) were analysed. Twelve RAPD primers reproducibly and strongly amplified 128 fragments of which 116 were polymorphic; similarly, 13 ISSR primers generated 127 products of which 119 were polymorphic. Dendrograms based on unweighted pair group method with arithmetic average analysis were constructed from both the RAPD and the ISSR data. Similarity coefficient based on RAPD and ISSR markers ranged from 0.22 to 0.98 and 0.23 to 0.98, respectively. The range in similarity coefficient indicated that the genus has a high level of genetic diversity. The Mantel test on the similarity matrices produced by RAPD and ISSR markers gave r  = 0.86, showing high correlation between RAPD and ISSR markers in their ability to detect genetic relationships between Crataegus accessions. RAPD and ISSR appear to be reliable methods for the analysis of genetic relationships among hawthorns.     

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。     

RAPD polymorphisms in spring wheat cultivars and lines with different level of Fusarium resistance

Random amplified polymorphic DNA (RAPD) markers have been used to characterize the genetic diversity among 35 spring wheat cultivars and lines with different levels of Fusarium resistance. The objectives of this study were to determine RAPD-based genetic similarity between accessions and to derive associations between Fusarium head blight (FHB) and RAPD markers. Two bulked DNA from either highly resistant lines or susceptible lines were used to screen polymorphic primers. Out of 160 screened primers, 17 primers generated reproducible and polymorphic fragments. Genetic similarity calculated from the RAPD data ranged from 0.64 to 0.98. A dendrogram was prepared on the basis of a similarity matrix using the UPGMA algorithm, which corresponded well with the results of principal component analysis and separated the 35 genotypes into two groups. Association analysis between RAPD markers and the FHB index detected three RAPD markers, H19(1000), F2(500) and B1(2400), significantly associated with FHB-resistant genotypes. These results suggest that a collection of unrelated genotypes can be used to identify markers linked to an agronomically important quantitative trait like FHB. These markers will be useful for marker-assistant breeding and can be used as candidate markers for further gene mapping and cloning.     

Identification of broccoli and cauliflower cultivars with RAPD markers

Summary RAPD (Random Amplified Polymorphic DNA) markers generated by 4 arbitrary 10-mer primers, discriminated 14 broccoli and 12 cauliflower cultivars (Brassica oleracea L.) by banding profiles. The size of the amplified DNA fragments ranged from 300 to 2600 base pairs. Twenty-eight percent of the markers were fixed in both broccoli and cauliflower, whereas 12.5% were specific to either crop. The rest were polymorphic in either or both crops. The markers generated by two and three primers were sufficient to distinguish each of the broccoli and cauliflower cultivars, respectively. The average difference in markers was 14.5 between broccoli and cauliflower markers, 5.8 between two broccoli cultivars and 7.9 between two cauliflower cultivars. Larger differences for each crop were found between cultivars from different seed companies than within the same company. RAPD markers provide a quick and reliable alternative to identify broccoli and cauliflower cultivars.     

Genomic variation and relationships in aerial yam (Dioscorea bulbifera L.) detected by random amplified polymorphic DNA.

Random amplified polymorphic DNA (RAPD) markers were used to assess intraspecific variability and relationships in aerial yam (Dioscorea bulbifera L.). A total of 23 accessions from different geographic locations in Africa, Asia, and Polynesia were analyzed by 10 arbitrarily chosen GC-rich decamer primers. Using cesium chloride purified genomic template DNA, highly reproducible polymorphic fingerprints were generated by all 10 primers, resulting in a total of 375 informative characters. Only eight bands were monomorphic among all investigated accessions. A binary character matrix was generated by scoring for presence/absence of a band at a particular position, transformed into a matrix of pairwise distances using either the Jaccard or a simple matching coefficient, and analyzed by neighbour joining, UPGMA (unweighted pair group method with arithmetic averaging) cluster analysis, or split decomposition. All methods of data evaluation resulted in similar groupings that reflected the geographical origin of the samples. The African accessions formed a distinct isolated group, whereas Asian and Polynesian accessions proved to be more heterogeneous. With two exceptions (var. suavior and var. sativa), the RAPD data supported previous varietal classification based on morphological characters. Stepwise reduction of the number of evaluated characters did not affect branching patterns of the trees above a minimum threshold of 150. Key words : Dioscorea bulbifera, random amplified polymorphic DNA (RAPD), genetic variation, genetic relatedness.