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 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.     

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.     

An improved strategy based on RAPD markers efficiently identified 95 peach cultivars

DNA markers have useful applications in cultivar identification. A novel analysis approach called cultivar identification diagram (CID) was developed using DNA markers in the separation of plant individuals. This new strategy is less time- and cost-consuming, has reliable results, and was constructed for fingerprinting. Ten 11-mer primers were used to amplify the genotypes; all 95 peach genotypes (from the National Peach Germplasm Repository, in Nanjing, China) were distinguished by a combination of 54 primers. The utilization of the CID among these 95 peach cultivars was also verified by the identification of three randomly chosen groups of cultivars. This identification showed some advantages including the use of fewer primers and easy separation of all cultivars by the corresponding primers marked in the right position on the CID. This peach CID could provide the information to separate any peach cultivars of these 95, which may be of help to the peach industry in China and for the utilization of DNA markers to identify other plant species.     

沙梨8个栽培品种的DNA指纹鉴定

利用RAPD标记技术,对8个沙梨(Pyrus pyrifolia)主栽品种进行RAPD分析。结果显示,从33个10碱基随机引物中筛选出了2个多态性高的引物S2075和S1296,扩增位点分别为11个和10个,以此为基础建立了8个品种的DNA指纹图谱;根据这2个引物中任何一个的扩增图谱均可以将这8个品种区分。研究结果为沙梨品种的区别与鉴定提供了一种有效方法。     

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     

Identification and analysis of genetic variation among rose cultivars using random amplified polymorphic DNA

Identified germplasm is an important component for efficient and effective management of plant genetic resources. Traditionally, cultivars or species identification has relied on morphological characters like growth habit or floral morphology like flower colour and other characteristics of the plant. Studies were undertaken for identification and analysis of genetic variation within 34 rose cultivars through random amplified polymorphic DNA (RAPD) markers. Analysis was made by using twenty five decamer primers. Out of twenty five, ten primers were selected and used for identification and analysis of genetic relationships among 34 rose cultivars. A total of 162 distinct DNA fragments ranging from 0.1 to 3.4 kb was amplified by using 10 selected random decamer primers. The genetic similarity was evaluated on the basis of presence or absence of bands. The cluster analysis indicated that the 34 rose cultivars form 9 clusters. The first cluster consists of eight hybrid cultivars, three clusters having five cultivars each, one cluster having four cultivars, two clusters having three cultivars each and two clusters having one cultivar each. The genetic distance was very close within the cultivars. Thus, these RAPD markers have the potential for identification of clusters and characterization of genetic variation within the cultivars. This is also helpful in rose breeding programs and provides a major input into conservation biology.     

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.     

Conversion of an RAPD marker to an STS marker for barley variety identification

Barley (Hordeum vulgare L.) variety identification is important to the malting and brewing industries. Because many new malting cultivars (varieties) are closely related, new and more effective identification techniques are needed. We report on a series of techniques used to convert an RAPD marker to a more stable STS marker that can identify barley Stander from Robust, an important distinction for the American malting and brewing industries. The techniques included DNA extraction, RAPD amplification, random cloning of all amplified fragments, selection of clones by insert size, DNA sequencing of select inserts, design of a barley-based primer pair, and detection of a single nucleotide polymorphism using restriction endonucleaseAlu I. The barley-based primer pair was used to further sequence the RAPD fragment. Five single nucleotide polymorphisms between Robust and Stander exist, one of which was detected by electrophoresing DNA fragments differentially restricted byAlu I. The conversion technique was different from ones previously reported in that it did not require manual extraction of DNA fragments from a gel. This could be applied to other situations in which RAPD marker conversion would be desirable.     

A Comparison of AFLP and RAPD Markers for Genetic Diversity and Cultivar Identification in Cotton

AFLP and RAPDmarkers were employed in sixteen diploid cotton (Gossypium sp) cultivars for genetic diversity estimation and cultivar identification. Polymorphism information content (PIC) and percent polymorphism were found to be more for AFLP markers as compared to RAPD markers. Average Jaccard’s genetic similarity index was found to be almost similar using either AFLP or RAPD markers. All the cultivars could be distinguished from one another using AFLP markers and also by the combined RAPD profiles. Cultivar identification indicators like resolving power, marker index and probability of chance identity of two cultivars suggested the usefulness of AFLP markers over the RAPD markers. AFLP and RAPD analyses revealed limited genetic diversity in the studied cultivars. Cluster analysis of both RAPD and AFLP data produced two clusters, one containing cultivars of G. herbaceum and another containing cultivars of G. arboreum species. Highly positive correlation between cophenetic matrices using RAPD and AFLP markers was observed. AFLP markers were found to be more efficient for genetic diversity estimation, polymorphism detection and cultivar identification.     

26个唐菖蒲品种RAPD分析

唐菖蒲是世界著名的切花之一,由于是纯粹的外来品种,目前国际上对其分类尚无统一的方法,主要是依据其生物习性等形态特征进行分类,受环境影响很大。同工酶是基因的产物,利用同工酶可以进行唐菖蒲品种鉴定和分类,但它在植物的不同器官组织发育的不同时期存在差异,而分子标记技术具有不受环境、器官、组织发育不同时期影响、遗传性稳定、分析简单等特点而被广泛应用在花卉品种分类上。利用RAPD技术对26个主要唐菖蒲切花品种进行分类和亲缘关系的研究,从520个随机引物中筛选出33个用于PCR反应,共在206个位点上扩增出条带,平均每个引物扩增位点6.24个,多态性位点185个,占总带数的89.8%,可以进行品种的鉴定。从分子水平揭示出唐菖蒲切花品种种质资源遗传基础狭窄,夏花大花型唐菖蒲品种间存在一定的亲缘关系。     

Microsatellite DNA and RAPD fingerprinting,identification and genetic relationships of hybrid poplar (<Emphasis Type="Italic">Populus x canadensis</Emphasis>) cultivars

Microsatellite DNA markers of ten SSR loci and 248 RAPD loci (resolved by 26 RAPD primers) were used for DNA fingerprinting and differentiation of 17 widely grown Populus x canadensis syn. Populus x euramericana (interspecific Populus deltoides x Populus nigra hybrids) cultivars ("Baden 431", "Blanc du Poitou", "Canada Blanc", "Dorskamp 925", "Eugenei", "Gelrica", "Grandis", "Heidemij", "I-55/56", "I-132/56", "I-214", "Jacometti", "Ostia", "Regenerata", "Robusta", "Steckby" and "Zurich 03/3"), and determination of their genetic interrelationships. Informativeness of microsatellite and RAPD markers was also evaluated in comparison with allozyme markers for clone/cultivar identification in P. x canadensis. High microsatellite DNA and RAPD genetic diversity was observed in the sampled cultivars. All of the 17 P. x canadensis cultivars could be differentiated by their multilocus genotypes at four SSR loci, and were heterozygous for their parental species-specific alleles at the PTR6 SSR locus. Except for "Canada Blanc" and "Ostia", which had identical RAPD patterns, all cultivars could also be differentiated by RAPD fingerprints produced by each of the two RAPD primers, OPA07 and OPB15. For microsatellites, the mean number of alleles, polymorphic information content, observed heterozygosity, observed number of genotypes and the number of cultivars with unique genotypes per locus was 5.2, 0.64, 0.67, 5.7 and 2.2, respectively. For RAPD markers, the number of haplotypes per locus, and the number of cultivars with unique RAPD profiles per locus were 1.06 and 0.72, respectively. Overall, microsatellite DNA markers were the most informative for DNA fingerprinting of P. x canadensis cultivars. On the per locus basis, microsatellites were about six-times more informative than RAPD markers and about nine-times more informative than allozyme markers. However, on the per primer basis, RAPD markers were more informative. The UPGMA cluster plots separated the 17 cultivars into two major groups based on their microsatellite genotypic similarities, and into three major groups based on their RAPD fragment similarities. Both the microsatellite and RAPD data suggest that the cultivars "Baden 431", "Heidemij", "Robusta" and "Steckby" are genetically closely related. The inter-cultivar genetic relationships from microsatellite DNA and RAPD markers were consistent with those observed from allozyme markers, and were in general agreement with their speculated origin. Microsatellite DNA and RAPD markers could be used for clone and cultivar identification, varietal control and registration, and stock handling in P. x canadensis.     

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.     

Genetic variance between some Egyptian Date Palm cultivars using PCR-based markers with emphasis on the prevalence of Al wijam disease

Date Palm is one of the most important crops in Egypt. At present, Egypt ranked second in world date production. The objectives of this study are the identification the genetic variance between some local varieties of Date Palm, in line with the establishment of a molecular diagnostic method to study the aetiology and the prevalence of Al Wijam disease. Date palm plantations have been suffering from number of pests and diseases infestation, mainly due to Dubas Bug, Red Palm Weevil, Lesser Date moth, and Al Wijam disease. Genomic DNAs were extracted from 18 Date Palm cultivars collected from Date Palm Research Institute, ARC using three different extraction methods. Nine common cultivars (Zaghlool, Hayani, Oraibi, Samani, Sultan, Bent-Aisha, Amrey, Aglani, and Barhee) and nine Siwi cultivars (Siwi, Fryhee, Taktakt, Quaipe, Karama Ghazally, Helw Ghanem, Gorm Agazal, and Oshbeigel,) were used in this study. In order to determine the genetic polymorphism and discriminate between each of these cultivars, RAPD and ISSR analysis were conducted on the isolated DNA samples from each cultivar. DNA fingerprints of the studied cultivars were conducted using 10 RAPD and eight ISSR primers. Dendrograms representing genetic relationships as well as genetic similarity matrices were performed for the studied cultivars using the UPGMA (Unweighted Pair Group Method with Arithmetic Average). Furthermore, 40 date palm trees representing the studied cultivars were collected from El-Marazik, El-Badrasheen, El-Wahat, and Demiate Governorates to study the prevalence of Al-Wijam disease using the DNA hybridisation technique. Symptoms including retardation in terminal bud growth, whole crown of leaves (rosetting symptoms), and yellow longitudinal lines on the midribs were observed. Non-radioactive Dig-labeled probes specific for 16s rDNA region of virus like agents were used to detect the infected trees.     

Identification and genetic variation among Hibiscus species (Malvaceae) using RAPD markers

Germplasm identification and characterization is an important link between the conservation and utilization of plant genetic resources. Traditionally, species or cultivars identification has relied on morphological characters like growth habit or floral morphology like flower colour and other characteristics of the plant. Studies were undertaken for identification and determination of genetic variation within the two species of Hibiscus and 16 varieties of Hibiscus rosa-sinensis L. through random amplified polymorphic (RAPD) markers. Primer screening was made by using the DNA of variety "Prolific". Genetic analysis was made by using ten selected decamer primers. A total of 79 distinct DNA fragments ranging from 0.3 to 2.5 kb were amplified by using ten selected random decamer primers. The genetic similarity was evaluated on the basis of presence or absence of bands. The cluster analysis indicated that the 16 varieties and two species formed one cluster. The first major cluster consisted of three varieties and a second major cluster consisted of two species and 13 varieties. The genetic distance was very close within the varieties and also among the species. Thus, these RAPD markers have the potential for identification of species/varieties and characterization of genetic variation within the varieties. This is also helpful in Hibiscus breeding programs and provides a major input into conservation biology.     

Use of morphological and physiological characters, and molecular markers to evaluate the genetic diversity of three clementine cultivars

Originating from a natural crossing between mandarin and sweet orange at the end of the 19(th) century, clementine diversified through the selection of spontaneous mutations. Today, it seems almost impossible to distinguish one variety from another. The development of molecular tools for variety identification is thus necessary. Three clementine cultivars, representing distinct groups of fruit maturity, were evaluated. Identification criteria were searched at the phenotypical level (organoleptic characteristics, leaves morphology) as well as the DNA level (isozymes, RAPD, and ISSR). The phenotypical diversity observed is relatively high and contrasted with the low molecular polymorphism. In fact, only the cultivar 'Guerdane' presents profiles of genetic fingerprints different from those of the two other cultivars. The frequency of the genetic modifications would thus be variable from a cultivar to another. Moreover, the specific molecular markers of the cultivar 'Guerdane', added to the phenotypic markers, extend the possibilities of identification to the young nursery plants.     

Genetic diversity of commercially grown Moringa oleifera Lam. cultivars from India by RAPD, ISSR and cytochrome P450-based markers

Moringa oleifera is a less used, drought-tolerant tropical plant, rich in nutritionally and nutraceutically important bioactive compounds. It is native to India and now under cultivation in many countries, but no data is available on genetic variability. Three DNA marker techniques, i.e., random amplified polymorphic DNA (RAPD), inter simple sequence repeat (ISSR) and cytochrome P₄₅₀ gene-based markers were used for the detection of genetic variability in eight Indian cultivars of M. oleifera, collected from various states of India. A total of 17 RAPD, 6 ISSR and 7 pairs of cytochrome P₄₅₀-based markers generated 48.68, 48.57 and 40.00 % polymorphisms, respectively. The marker index (MI) for each of these marker systems (3.25 for RAPD, 4.73 ISSR and 2.95 for Cyt P₄₅₀-based markers) suggest that ISSR markers are the most effective for assessment of genetic diversity. Based on the three types of marker data, the eight cultivars of M. oleifera were grouped into four sub-clusters in a dendrogram, but without any distinct geographical pattern. This suggests spread of planting material and high rates of gene flow through cross pollination. High bootstrap values (94.4 and 82.3) were obtained at major nodes of the dendrogram using the winboot software. The dendrogram and PCA plots generated from the binary data matrices of the three marker systems were found highly concordant to each other. This study reveals a huge genetic diversity among the cultivars and this can be utilised for conservation and cultivar development in breeding programmes to produce high yielding, nutritionally superior cultivars.     

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.