Allelic diversity of simple sequence repeats among elite inbred lines of cultivated sunflower.

Simple sequence repeat (SSR) markers were developed for cultivated sunflower (Helianthus annuus L.) from the DNA sequences of 970 clones isolated from genomic DNA libraries enriched for (CA)n,, (CT)n, (CAA)n, (CATA)n, or (GATA)n. The clones harbored 632 SSRs, of which 259 were unique. SSR markers were developed for 130 unique SSRs by designing and testing primers for 171 unique SSRs. Of the total, 74 SSR markers were polymorphic when screened for length polymorphisms among 16 elite inbred lines. The mean number of alleles per locus was 3.7 for dinucleotide, 3.6 for trinucleotide, and 9.5 for tetranucleotide repeats and the mean polymorphic information content (PIC) scores were 0.53 for dinucleotide, 0.53 for trinucleotide, and 0.83 for tetranucleotide repeats. Cluster analyses uncovered patterns of genetic diversity concordant with patterns produced by RFLP fingerprinting. SSRs were found to be slightly more polymorphic than RFLPs. Several individual SSRs were significantly more polymorphic than RFLP and other DNA markers in sunflower (20% of the polymorphic SSR markers had PIC scores ranging from 0.70 to 0.93). The newly developed SSRs greatly increase the supply of sequence-based DNA markers for DNA fingerprinting, genetic mapping, and molecular breeding in sunflower; however, several hundred additional SSR markers are needed to routinely construct complete genetic maps and saturate the genome.     

Human repeat element-mediated PCR: cloning and mapping of chromosome 10 DNA markers.

Repeat element-mediated PCR can facilitate rapid cloning and mapping of human chromosomal region-specific DNA markers from somatic cell hybrid DNA. PCR primers directed to human repeat elements result in human-specific DNA synthesis; template DNA derived from a somatic cell hybrid containing the human chromosomal region of interest provides region specificity. We have generated a series of repeat element-mediated PCR clones from a reduced complexity somatic cell hybrid containing a portion of human chromosome 10. The cloning source retains the centromere and tightly linked flanking markers, plus additional chromosome 10 sequences. Twelve new inter-Alu, two inter-L1, and four inter-Alu/L1 repeat element-mediated PCR clones were mapped by hybridization to Southern blots of repeat element-mediated PCR products amplified from somatic cell hybrid DNA templates. Two inter-Alu clones mapped to the pericentromeric region. We propose that a scarcity of Alu elements in the pericentromeric region of chromosome 10 contributed to the low number of clones obtained from this region. One inter-Alu clone, pC11/A1S-6-c23, defines the D10S94 locus, which is tightly linked to MEN2A and D10Z1.     

Identification of wild and cultivated Hordeum species using two-primer RAPD fragments

Random amplified polymorphic DNAs (RAPD) analysis has been adapted to assess the degree of RAPD polymorphism within the genus Hordeum to determine if this approach can distinguish wild and cultivated species. Nineteen wild and seven cultivated accessions were evaluated using 4 random 10-mer primers. The potential of the RAPD assay was further increased by combining two primers in a single polymerase chain reaction (PCR). RAPD fragments generated by two pairs of arbitrary 10-mer primers discriminated six wild species and one cultivated species by banding profiles. The size of the amplified DNA fragments ranged from 150 to 2300 base pairs. 33 %percent of the fragments were common to both wild and cultivated species; 67% were specific to either wild or cultivated species. The average difference in fragments was less within the species than among the species. By comparing RAPD fingerprints of wild and cultivated barley, markers were identified among the set of amplified DNA fragments which could be used to distinguish wild and cultivated Hordeum species. This revised version was published online in July 2006 with corrections to the Cover Date.     

Characterization and authentication of insect cell lines using RAPD markers

Random amplified polymorphic DNA (RAPD) analysis was used to characterize 11 insect cell lines, including six from lepidoptera (five species), one from diptera and four from coleoptera (one species: Leptinotarsa decemlineata). Whatever the order and even when comparing two closely related species from the same genus (Spodoptera), the DNA fingerprints are very different from one species or from one primer to the other. On the other hand, two independently isolated cell lines from the lepidopteran Phthorimaea operculella produce nearly identical profiles with only minor differences. Finally, a statistical analysis based on Nei's similarity coefficient was performed on the fingerprints of four independent cell lines from the Colorado potato beetle, L. decemlineata. Each possesses a common recognizable pattern also found in field-collected insects, while also showing a series of polymorphic markers which allow one to distinguish each cell line from the three others. RAPD fingerprinting, together with the use of appropriate statistics, thus constitutes a highly specific method both for the authentication of the species from which a cell line was developed and for the individual characterization of each cell line from a given species.     

Mouse cell line authentication

The scientific community has responded to the misidentification of human cell lines with validated methods to authenticate these cells; however, few assays are available for nonhuman cell line identification. We have developed a multiplex polymerase chain reaction assay that targets nine tetranucleotide short tandem repeat (STR) markers in the mouse genome. Unique profiles were obtained from seventy-two mouse samples that were used to determine the allele distribution for each STR marker. Correlations between allele fragment length and repeat number were determined with DNA Sanger sequencing. Genotypes for L929 and NIH3T3 cell lines were shown to be stable with increasing passage numbers as there were no significant differences in fragment length with samples of low passage when compared to high passage samples. In order to detect cell line contaminants, primers for two human STR markers were incorporated into the multiplex assay to facilitate detection of human and African green monkey DNA. This multiplex assay is the first of its kind to provide a unique STR profile for each individual mouse sample and can be used to authenticate mouse cell lines.     

Use of RAPD technique in evolution studies of four species in the family Canidae

The RAPD-PCR technique was applied to identify genetic markers able to distinguish between four canid species: the arctic fox (Alopex lagopus), red fox (Vulpes vulpes), Chinese raccoon dog (Nyctereutes procyonoides procyonoides) and six breeds of the domestic dog (Canis familiaris). A total of 29 ten-nucleotide arbitrary primers were screened for their potential use in the differentiation of these species. Ten primers amplified RAPD profiles that made it possible to distinguish between the investigated taxa. A number of species-specific bands was scored within RAPD profiles produced by these primers: 35.6% of all the polymorphic bands were unique to the Chinese raccoon dog, 29.6% were unique to the domestic dog, 21.2% were diagnostic for the red fox and 13.6% for the arctic fox. No breed-specific fragments were amplified from canine DNA; however, three primers produced bands characteristic for the dog, but not present in all of the investigated breeds. A Neighbor-Joining tree constructed on the basis of the analysis of RAPD profiles amplified by six primers revealed that the phylogenetic distance between the dog and the arctic fox is larger than the distance between the dog and the red fox. The phylogenetic branch of the Chinese raccoon dog was the most distinct on the dendrogram, suggesting that this species belongs to a different phylogenetic lineage. Obtained results make it possible to conclude that RAPD analysis can be a powerful tool for developing molecular markers useful in distinguishing between species of the family Canidae and for studying their phylogenetic relations.     

Investigations of genetic variation between olive (Olea europaea L.) cultivars using arbitrarily primed polymerase chain reaction (AP-PCR)

Characterization and selection of olive clones for the production of olive oil is essential in Turkey because of its profitable exploitation. AP-PCR (Arbitrarily-Primed PCR) is a technique that can distinguish the genetic relationship among plant species and other organisms. In this study, AP-PCR approach was used in order to determine the genetic relationship of different six olive clones. The purity of DNA is one of the most important factors affecting the product of the AP-PCR method. In this respect, modified genomic DNA isolation procedure from Oleae europaea clones was developed so that this procedure can be used to obtain plant genomic DNA from diverse aromatic plants, which produce essential oils and secondary metabolites. By following the optimized AP-PCR amplification protocol, unique DNA fingerprint profiles for each olive clone were produced. AP-PCR-generated unique DNA fingerprint profiles can be used in the identification, distribution and diversity of various olive cultivars.     

Identification of closely related citrus cultivars with inter-simple sequence repeat markers

 Inter-simple sequence repeat (ISSR) markers generated by 22 primers were tested for their ability to distinguish among samples from 94 trees of 68 citrus cultivars. Within each of the six cultivar groups studied, most of these cultivars are so closely related that they are difficult to distinguish by other molecular-marker techniques. ISSR markers involve PCR amplification of DNA using a single primer composed of a microsatellite sequence anchored at the 3′ or 5′ end by 2–4 arbitrary, often degenerate, nucleotides. The amplification products were separated on non-denaturing polyacrylamide gels and detected by silver staining. ISSR banding profiles were very repeatable on duplicate samples. Different citrus species had very different fingerprint patterns. Within Citrus sinensis (L.) Osbeck and C. paradisi Macf., in which all cultivars have originated by the selection of mutants, ISSR markers distinguished 14 of 33 sweet orange and 1 of 7 grapefruit cultivars. Five of six lemon cultivars were discriminated by ISSR markers. Many differences were found among mandarin cultivars; however, all five satsuma cultivars analyzed had identical ISSR fingerprints. Four of five citrange cultivars were distinguishable, but ‘Troyer’ and ‘Carrizo’ had identical ISSR fingerprints. ‘Kuharske Carrizo’ citrange, which has better citrus nematode resistance than other ‘Carrizo’ citrange accessions, had unique ISSR fingerprints. Three ISSR markers that differentiated certain sweet orange cultivars were hybridized to Southern blots of sweet orange DNA digested with different restriction endonucleases. The sweet orange cultivars tested could be distinguished by these ISSR-derived RFLP markers. Moreover, one ISSR marker unique to ‘Ruby’ blood orange was observed in its progeny trees. Received: 9 September 1996 / Accepted: 4 April 1997     

Clonal structure of Rubus chamaemorus populations: comparison of different molecular methods

The clonal structure of Rubus chamaemorus populations was investigated using DNA fingerprinting. The PCR-based methods included the use of 10-base RAPD primers and 16-base simple sequence repeat primers. In the hybridization method variation was studied using hypervariable multilocus probes, one derived from the M13 bacteriophage and the other a synthetic (AC)/(TG) polynucleotide. Although R. chamaemorus expresses clear variation in morphology, the level of genetic differentiation appears to be fairly low. The observed numbers of clones in the three populations examined in Finland varied from 2 to 4. The total number of genotypes across populations was 5, of which one was unique. The results obtained using the two fingerprinting methods were comparable but lead to a slightly different grouping of clones.     

Evaluation of the genetic fidelity of in vitro-propagated gerbera (<Emphasis Type="Italic">Gerbera jamesonii</Emphasis> Bolus) using DNA-based markers

The genetic fidelity of in vitro-raised gerbera clones was assessed by using random amplified polymorphic DNA (RAPD) and inter-simple sequence repeat (ISSR) markers. Out of 35 RAPD and 32 ISSR primers screened, only 12 RAPD and 10 ISSR primers produced clear, reproducible and scorable bands. The 12 RAPD primers produced 54 distinct and scorable bands, with an average of 4.5 bands per primer. The number of scorable bands for ISSR primers varied from 3 (ISSR-14) to 9 (ISSR-07), with an average of 5.5 bands per primer. The number of bands generated per primer was greater in ISSR than RAPD. All banding profiles from micropropagated plants were monomorphic and similar to those of the mother plant. A similarity matrix based on Jaccard’s coefficient revealed that the pair-wise value between the mother and the in vitro-raised plantlets was 1, indicating 100% similarity. This confirmed the true-to-type nature of the in vitro-raised clones.     

The use of ISSR and RAPD markers for detecting DNA polymorphism,genotype identification and genetic diversity among barley cultivars with known origin

The potential of bulk analyses of RAPD and ISSR-PCR markers for fingerprinting purposes was evaluated using ten RAPD and ten ISSR primers. The phylogenetic relationships of 16 barley cultivars from different countries, and all having a known pedigree, were analysed using 353 PCR markers (125 RAPDs and 228 ISSRs). The band profiles generated were reproducible in spite of the different DNA extractions, PCR techniques, electrophoretic methods and gel scorings used. The RAPD primer S10 and four ISSR primers (811, 820, 835 and 881) were both able to distinguish all cultivars. A strong and quite linear relationship was observed between Resolving Power (Rp) of a primer and its ability to distinguish genotypes. The dendrograms obtained using these two molecular markers are in agreement with their known origin, showing clusters that separate very well the spring/winter and six-rows/two-rows cultivars. Thus, bulk analyses of RAPD and ISSR PCR markers provides a quick, reliable and highly informative system for DNA fingerprinting and also permit to establish genetic relationships which agree with, by other means, known origin of the cultivars.     

Complex probes for high-throughput parallel genetic mapping of genomic mouse BAC clones

We describe a novel approach for the identification and mapping of polymorphic markers. Amplicons are generated by ligation of double-stranded adaptor molecules to genomic DNA cleaved with a restriction enzyme. Using primers that extend beyond the restriction site, reduced-complexity subsets of fragments are generated by PCR. Differences in the composition of complex probes generated from DNA of different strains are revealed through hybridization against high-density filter grids of large-insert genomic clones. Genetic mapping of genomic clones is achieved by hybridizing complex probes derived from backcross animals against the polymorphic clones. The mouse was chosen as a model system to test the feasibility of this technique because of the general availability of backcross resources and genomic libraries. Nevertheless, we would expect the method to be of particular use to generate markers for species that have not yet been extensively studied, because a substantial number of easy-to-use markers can be recruited in a relatively short period of time. Received: 20 January 1998 / Accepted: 21 April 1998     

Identification of insect cell lines and cell‐line cross‐contaminations by nuclear ribosomal ITS sequences

This report shows how the internal transcribed spacer (ITS) region of nuclear ribosomal DNA (rDNA) can be used to determine the species identity of insect cell lines and to distinguish between cell lines derived from closely related insect species. A PCR‐RFLP method with the endonucleases HincII and PstI produces restriction fragment profiles that could distinguish between insect cell lines at the species level. Another PCR‐based method used three species‐specific primer sets, Ly‐ITS1/Ly‐ITS2, ITS1‐1/Ld‐ITS1 and Sf9‐F2/ITS4, to identify the cell lines from Lymantria xylina, L. dispar and Spodoptera frugiperda, respectively. This method also detected cell‐line cross‐contaminations (CLCC) with contamination levels as low as 1% (10 cells in a population of 1000 cells) even when the contaminating cells were from a closely related species. Compared with conventional methods used for cell‐line identification and CLCC detection, the methods presented here are fast and sensitive and could easily be applied to other cell culture laboratories.     

Detection of Polymorphic DNA and Taxonomic Relationships Among 10 Wild Perennial Soybean Species Using Specific and Arbitrary Nucleotide Primers

Polymorphic DNA in complex genomes of agronomic crops can be detected using specific nucleotide and arbitrary primers and the polymerase chain reaction (PCR). Nineteen accessions representing 10 species of the wild perennial soybean were evaluated using 4 sets of specific primers and 3 sets of random amplified polymorphic DNAs (RAPD) primers. The potential of the RAPD assays was further increased by combining two primers in a single PCR. The fragments generated by the two assays discriminated 10 wild species by banding profiles. The size of the amplified DNA fragments ranged from 100 to 2100 base pairs. The resolved PCR products yielded highly characteristic and homogeneous DNA fingerprints. The fingerprints were useful not only for investigating genetic variability but also for further characterizing the wild soybean species by detecting inter- and intra-specific polymorphisms, constructing dendrograms defining the phylogenetic relationships among these species, and identifying molecular markers for the construction of genetic linkage maps. Furthermore, unique markers distinguishing particular species were also identified. Thus, it is expected that PCR will have great relevance for taxonomic studies. This revised version was published online in July 2006 with corrections to the Cover Date.     

Rapid development of gene-tagged microsatellite markers from bacterial artificial chromosome clones using anchored TAA repeat primers

We developed a technique to improve the efficiency of producing TAA repeat microsatellite markers linked to interspecific conserved genes. Template DNA was prepared from cultures derived from single bacterial artificial chromosome (BAC) colonies using a simple alkaline lysis miniprep. The presence of conserved genes in each BAC clone was verified by sequencing with gene-specific primers. The BAC templates were directly sequenced using short tandem repeat-anchored primers (STRAPs), consisting of TAA repeats with one or two unique 3' terminal bases. At least one STRAP provided sufficient 3' flanking sequence from each clone for the design of a BAC-specific primer. The BAC-specific primer was used to sequence back through the tandem repeat and obtain 5' flanking sequence, and a second BAC-specific primer was designed for microsatellite genotype analysis. This technique quickly provided microsatellite markers with an average of 15 tandem repeats for the BAC clones tested. The identification of polymorphic microsatellite loci in these clones permits the identification of alleles linked to candidate genes, placement of conserved genes on genetic linkage maps, and integration of linkage and physical maps.     

First searchable database for DNA profiles of human cell lines: sequential use of fingerprint techniques for authentication.

The authenticity and freedom from cross-contaminants of a cell line are important prerequisites for any research, development or production programs involving cell lines. Mini- and microsatellites in the human genome harboring variable-numbers of tandem repeat (VNTR) DNA markers allow individualization at the DNA level and are of practical value for genetic linkage mapping, forensic legal medicine, paternity testing, monitoring of bone marrow transplants, and individualization of established cell lines. We have validated fingerprint techniques of different single- and multiple-locus VNTRs enabling the establishment of a searchable database of DNA profiles. As a result, multiplexed polymerase chain reaction amplification fragment length polymorphism (AmpFLP) of four prominent and highly polymorphic minisatellite VNTR loci was proven as the best tool for screening the uniqueness of DNA profiles in a fingerprint database. In order to avoid false positivity, identical or similar DNA profiles based on AmpFLP VNTR were tested further using a multi-locus fingerprint system. Our data demonstrate that misidentification remains a chronic problem among human continuous cell lines (detailed information at URL http://www.dsmz.de). The combination of rapidly generated DNA profiles based on single-locus VNTR loci, their authentication by screening the fingerprint database, and confirmation of duplicate banding patterns using multilocus fingerprints constitute a highly reliable and robust method, which enables high fidelity and quality of maintenance independent from the quantity of individual cell lines.     

Comparative Evaluation of RAPD, ISSR and Anchored-SSR Markers in the Assessment of Genetic Diversity and Fingerprinting of Oilseed Brassica Genotypes

Forty-two genotypes representing oilseed Brassica species were analyzed for the level of genetic diversity and molecular identity using Random Amplified Polymorphic DNA (RAPD), Inter-Simple Sequence Repeat (ISSR) and 5'-Anchored Simple Sequence Repeat (ASSR) markers. DNA profiles revealed high degree of interspecific polymorphism, while the level was considerably low within a species, particularly in B. juncea. The UPGMA clusters clearly delineated genotypes of the respective Brassica species. Comparison of cophenetic matrices indicated a high degree of correspondence between dendrograms generated by different marker systems. A minimum of 10 random primers (approximately 105 bands) were required for the RAPD profiles to generate the expected cluster. Comparatively less number of primers was required to do the same in case of ISSR (4 primers) and ASSR (3 primers). The principal component analysis revealed similar genetic relationship among the genotypes as in cluster analysis. Although none of the DNA profiles could individually identify all the B. juncea genotypes, a combined DNA profile consisting 125 markers from the informative primers of all the three DNA marker systems could do the same. A positive correlation was found among the marker utility parameters (calculated for individual primers of different marker systems) such as marker index (MI), resolving power (Rp) and discrimination coefficient (D) with the number of genotypes identified by each primer with a few exceptions. Single plant analysis for a set of five B. juncea varieties revealed absence of intra-varietal heterogeneity in case of ASSR profiles, thereby suggesting its utility in varietal identification and differentiation.     

Isolation and characterization of SSR sequences from the genome and TAC clones of common wheat using the PCR technique.

We have developed the 2-step PCR method, a kind of suppression PCR procedure, to isolate simple sequence repeats (SSRs) from common wheat (Triticum aestivum L.) in a more convenient manner. This system requires neither genomic library screening nor the SSR-enrichment procedure. As a result, we designed 131 primer pairs based on isolated SSRs from not only genomic DNA, but also transformation-competent artificial chromosome (TAC) clones. It has been demonstrated that 34 of the 131 SSR markers developed were polymorphic among 8 wheat lines. Four of 34 polymorphic SSR markers were derived from TAC clones, indicating that this method could be applied to the targeted development of unique SSR markers in large genomic DNA libraries such as those composed of bacterial artificial chromosomes (BACs). A considerable number of isolated SSR clones had similarities with part of several long terminal repeats of retrotransposons (LTR-RTs) identified in various Triticeae genome sequences. Most of those SSRs showed smear amplification profiles, suggesting that a considerable number of dysfunctional SSRs originating from repetitive DNA components, especially LTR-RTs, might exist in the common wheat genome.     

Phytochemical analysis and genetic characterization of six Hypericum species from Serbia

The secondary metabolite contents and genetic profiles of six Hypericum species (H. barbatum Jacq., H. hirsutum L., H. linarioides Bosse, H. maculatum Crantz, H. rumeliacum Boiss. and H. tetrapterum Fries), collected from different locations in Serbia, have been analyzed. Methanol extracts of the aerial parts of the plants were obtained by accelerated solvent extraction (ASE) at 40 degrees C and 100 bar, and analyzed for five pharmacologically important standard constituents (hyperoside, quercitrin, pseudohypericin, hyperforin and hypericin) by LC-MS/MS. The highest content of hypericin and pseudohypericin was observed in the H. barbatum extract, while the highest content of hyperforin and quercitrin was found in the H. tetrapterum extract and the highest content of hyperoside in the H. maculatum extract. A literature survey shows that the above six Hypericum species, with the exception of H. maculatum, have not been previously genetically profiled. In order to correlate the chemical constituents of the species under investigation with their genetic factors, genetic profiling of these species was undertaken using the random amplification of polymorphic DNA (RAPD) and single sequence repeat (SSR) profiles of the above selected plants. Among the 52 random primers used for the initial screening, only 10 yielded polymorphic RAPD profiles. A total of 111 polymorphic markers were generated using these primers. The SSR analysis shows that 8 out of the 10 primers used were polymorphic. The correlation among the species under investigation using the two genetic markers was performed using Jaccuard's coefficients of similarity and a high correlation (r=0.99) was obtained. The main conclusion from the above data is that there exists a stronger correlation for secondary metabolite contents with RAPD data than with SSR data among the six Hypericum species from Serbia.     

Identification of novel simple sequence length polymorphisms (SSLPs) in mouse by interspersed repetitive element (IRE)-PCR.

Interspersed repetitive element (IRE)-PCR is a useful method for identification of novel human or mouse sequence tagged sites (STSs) from contigs of genomic clones. We describe the use of IRE-PCR with mouse B1 repetitive element primers to generate novel, PCR amplifiable, simple sequence length polymorphisms (SSLPs) from yeast artificial chromosome (YAC) clones containing regions of mouse chromosomes 13 and 14. Forty-two IRE-PCR products were cloned and sequenced from eight YACs. Of these, 29 clones contained multiple simple sequence repeat units. PCR analysis with primers derived from unique sequences flanking the simple sequence repeat units in seven clones showed all to be polymorphic between various mouse strains. This novel approach to SSLP identification represents an efficient method for saturating a genomic interval with polymorphic genetic markers that may expedite the positional cloning of genes for traits and diseases.