DNA fragments of organellar origin in random amplified polymorphic DNA (RAPD) patterns of sugar beet (Beta vulgaris L.)

The technique of random amplified polymorphic DNA (RAPD) offers a broad range of applications in the investigation of plant genomes. A promising prospect is the use of RAPD products as genetic markers. We have investigated a possible organellar source of fragments in RAPD patterns of total DNA. Two nearly-isogenic lines of cytoplasmic male-sterile and male-fertile sugar beet (Beta vulgaris L.) were subjected to RAPD analysis with six different primers. Total, nuclear, mitochondrial (mt), and chloroplast (cp), DNA from each line were investigated. Reproducible DNA fingerprints could be obtained from both organellar DNAs. Differences in band patterns of mtDNA between cytoplasmic male-sterile and -fertile lines were observed with five out of six primers, whereas different cpDNA patterns were generated by one of the primers. Consequently, the RAPD technique can be used to discriminate between different cytoplasms. Clear evidence is provided for the organellar origin of fragments in genomic (total DNA) RAPD patterns. The consequences of these results for the interpretation of RAPD analyses are discussed.     

Detection of Bradyrhizobium spp. and B. japonicum in Thailand by primer-based technology and direct DNA extraction

Total chromosomal DNAs from 20 Bradyrhizobium spp. strains (10 strains isolated from Vigna radiata and 10 from Arachis hypogaea) and 18 B. japonicum strains isolated from Glycine max were extracted. These DNAs served as templates for REP, ERIC and RAPD primers in PCR analyses. The patterns of the resulting PCR products were analyzed and highly specific for each strain, especially when grouped together with their antibiotic-resistance profiles. A method for extracting DNA directly from soil was developed. Recovery was approximately 30 g DNA g-1 soil and the procedure yielded DNA suitable for PCR amplification.     

Identification of Escherichia coli Recovered from Milk of Sows with Coliform Mastitis by Random Amplified Polymorphic DNA (RAPD) Using Standardized Reagents

A standardized-reagents commercial kit for random amplified polymorphic DNA (RAPD) analysis was used for typing 58 Escherichia coli strains that were recovered from the milk of sows, having coliform mastitis, within a single swineherd in Sweden. Previously, the 58 E. coli strains were characterized serologically and profiled biochemically. They were also evaluated for their serum resistance and their ability to adhere to fibronectin and bovine fetal fibroblasts. The RAPD analysis was fast, easily performed, and required only a nanogram of DNA. The indistinguishable banding patterns obtained with repeated analyses of 2 isolates from each strain demonstrated that RAPD analysis using standardized beads is a technique that provides reproducible results for typing E. coli strains that cause mastitis in sows. The results of the RAPD analyses demonstrated that E. coli sow mastitis strains are highly variable in serotype, biochemical profiles, virulence factors, and RAPD type, and that all 58 strains can be differentiated by means of the RAPD technique. The strains grouped into 24 RAPD types by combining the results of 2 primers, and into 38 groups by combining the results of serotype and RAPD type. No relationship between serotypes, virulence factors and RAPD types was found.     

Evolutionary distances and identification of Candida species in clinical isolates by Randomly Amplified Polymorphic DNA (RAPD)

Fast and reliable identification of different species of the genus Candida is important to define adequate therapeutic decisions, because the different species have highly variable susceptibilities to antifungal drugs; azoles and amphothericin B. Accurate statistical records on case history and epidemiological studies also depend on effective identification. To address this problem we established a RAPD method that enabled direct identification of five very common species of Candida. Initially, reference band patterns were established for C. albicans, C. tropicalis, C. parapsilosis, C. glabrata and C. krusei. One of the primers, M2, showed remarkably conserved intra-specific patterns of approximately 10 bands each, ranging in size from 2.0 to 0.1 kb. These patterns were significantly different and species-specific. Few bands were conserved between different species of Candida, which was assumed to be consistent with their phylogenetic relatedness. In addition, band patterns were constant and reproducible and DNA isolated from single colonies yielded sufficient DNA for identification. The reference band patterns were then used, in blind experiments, to identify species of Candida in 50 randomly chosen samples, including clinical isolates and ATCC strains. RAPD results were 100% consistent with results obtained by conventional diagnostic methods and were achieved in one day instead of several days taken by conventional methods. Because ideal identification methods should be consistent with phylogeny and taxonomy we tested whether RAPD could be used to calculate genetic distances. Comparison of RAPD phylogenetic trees with 18S rRNA trees showed significant differences in tree topologies which indicated that RAPD data could not accurately measure the relative distances between different species. Also, computer simulations of RAPD random patterns were used to test whether the observed degree of RAPD band pattern similarities could occur at random. These simulations suggested that the level of inter-specific band pattern similarities observed in our data could be obtained at random, while intra-specific pattern similarities could not. RAPD would be helpful to discriminate between isolates but not to quantitate the differences. We suggest that the inaccurate estimate of genetic distances from RAPD is a general limitation of the technique and not a specific problem of our identification method. Because of the repetitive character of the target sequences, genetic distances calculated from RAPD could be affected by paralogy, namely, recombination and duplication events not parallel with speciation events. This revised version was published online in June 2006 with corrections to the Cover Date.     

Rapid estimation of genetic relatedness among heterogeneous populations of alfalfa by random amplification of bulked genomic DNA samples

A procedure which involves the use of RAPD markers, obtained from bulked genomic DNA samples, to estimate genetic relatedness among heterogeneous populations is demonstrated in this study. Bulked samples of genomic DNA from several alfalfa plants per population were used as templates in polymerase chain reactions with different random primers to produce RAPD patterns. The results show that the RAPD patterns can be used to determine genetic distances among heterogeneous populations and cultivars which correspond to their known relatedness. The results also indicate that, by using ten primers with bulked DNA samples from ten individuals, 18–72 populations or cultivars can be distinguished from each other on the basis of at least one unique RAPD marker. We anticipate that DNA bulking and methods for comparing RAPD patterns will be very useful for identifying cultivars, for studying phylogenetic relationships among heterogeneous populations and for selecting parents to maximize heterosis in crosses.     

RAPD技术在芦荟属植物分类研究中的应用

采用CTAB法提取11个芦荟材料的基因组DNA为模板,以50个随机引物进行RAPD分析。结果表明：大部分引物可以在不同模板上扩增出条带,但仅有6个引物可以同时在11个芦荟材料的DNA上扩增出条带,对11个芦荟种变种的RAPD结果进行聚类分析,结果表明基本符合传统分类观点。对RAPD技术在芦荟属植物分类研究中的问题进行了讨论。     

RAPD analysis of isolated mitochondrial DNA reveals heterogeneity in elite wild abortive (WA) cytoplasm in rice

 RAPD profiles were generated using mitochondrial DNA (mtDNA) isolated from two cytoplasmic male-sterile lines, two restorer lines and four maintainer lines of rice. Of the 40 primers tested, 25 generated consistent and easily scoreable patterns that were used for the computation of pairwise similarities as well as UPGMA analyses. The different lines of rice, including lines IR58025A and IR62829A that contained the same wild abortive (WA) cytoplasm, were distinguishable on the basis of RAPD profiles. These latter two lines were not distinguishable from each other by mtDNA RFLP analyses with as many as 16 mtDNA probes. The data illustrate the utility of the RAPD technique as a powerful tool for distinguishing different cytoplasms that by other techniques appear to be similar. To our knowledge, this is the first report wherein RAPD profiles obtained with isolated mtDNA templates enable the distinction between two or more types of cytoplasms in rice. Received: 1 April 1997 / Accepted: 2 June 1997     

Quantitative Properties of Random Amplified Polymorphic DNA (RAPD)

Random Amplified Polymorphic DNA analysis (RAPD) is a methodology that has been used as a tool for monitoring microbial communities. To be useful in this application RAPD, and any other methodology, must show properties that allows for the detection of quantitative changes in composition of the microbiota. Therefore, the objective of this study was to establish whether RAPD possesses such properties. The strategy was to use genomic DNA, extracted from a set of tertiary bacterial mixtures defined according to an experimental mixture design, and containing varying proportions of Escherichia coli, Bacillus subtilis, and Pseudomonas CF600. RAPD-PCR was performed on the mixed DNA extracts and the amplified DNA fragments were separated on sequencing gels to produce genomic fingerprints that were digitized and modeled by Partial Least Squares regression (PLS). Significant predictions were obtained using an external test set for validation, with Root Mean Square Error of Predictions (RMSEP) of 0.21, 0.19 and 0.20 for the proportion of E. coli, B. subtilis and Pseudomonas CF600 respectively. Taken together, the results showed that RAPD patterns quantitatively represented the initial mixture proportions. Therefore, the view that RAPD could be useful for whole microbial community monitoring was strengthened.     

Problems in the Use of RAPD to the Study of Genetic Diversity and Systematics

Rapid, simple and highly sensitive are the great advantages of RAPD (random amplified polymorphic DNA) method. However, its optimum condition of amplification varies greatly among different studies and, in turn, causes much debates in terms of its reproducibility and validation of its application to the study of systemetics. For this reason the authors tried to probe into some essential factors that might affect the result of RAPD assay. The results from the authors' genetic diversity research in Cathaya argyrophylla confirmed that (a) DNA templates, whether undergoing multiple steps of purification or not, showed the same RAPD profiles, hence, most of the steps would be unnecessary: (b) RNA, no matter deprived or not from the DNA templates, had no influence on amplification; (c) DNA templates with a wide range of concentration produced the same band patterns constantly; (d) DNA templates extracted from either fresh or dry leaves produced the same RAPD results. Therefore, it was concluded that RAPD exhibited very good reproducibility. Furthermore, the authors had also discussed some problems in product analysis and data analysis of RAPD. The use of RAPD method in taxonomic study was evaluated in the study on the relationships of congeneric species of Cimicifuga, Actaea asatica and Aconitum sungpanense, and the applicability of RAPD to systematic studies of species and closely related genera, although with some limitations, was highly appreciated.     

Suicide polymerase endonuclease restriction, a novel technique for enhancing PCR amplification of minor DNA templates

PCR-based molecular analyses can be hindered by the presence of unwanted or dominant DNA templates that reduce or eliminate detection of alternate templates. We describe here a reaction in which such templates can be exclusively digested by endonuclease restriction, leaving all other DNAs unmodified. After such a modification, the digested template is no longer available for PCR amplification, while nontarget DNAs remain intact and can be amplified. We demonstrate the application of this method and use denaturing gradient gel electrophoresis to ascertain the removal of target DNA templates and the subsequent enhanced amplification of nondigested DNAs. Specifically, plastid 16S rRNA genes were exclusively digested from environmental DNA extracted from plant roots. In addition, pure culture and environmental DNA extracts were spiked with various amounts of genomic DNA extracted from Streptomyces spp., and selective restriction of the Streptomyces 16S rRNA genes via the suicide polymerase endonuclease restriction PCR method was employed to remove the amended DNA.     

RAPD标记在紫菜遗传多样性检测和种质鉴定中的应用

用ＲＡＰＤ技术对４类紫菜（Ｐｏｒｐｈｙｒａ ｙｅｚｏｅｎｓｉｓ,Ｐ．ｈａｉｔａｎｅｎｓｉｓ,Ｐ．ｋａｔａｄｎｉ ｖａｒ．ｈｅｍｉｐｈｙｌｌａ和Ｐ．ｏｌｉｇｏｓｐｅｒｍａｔａｎｇｉａ）的１５个无性系丝状体进行了遗传多样履分析,从５０个ＯＰＥＲＯＮ引物中经过初筛,其中６个引物可以扩增出稳定的可重复的图谱。这６个引物共扩增出了６０条带,多态性比例达９７．１％。根据ＲＡＰＤ结果将这１５个无性了紫菜的ＤＮＡ     

The Application of RAPD Markers in Diversity Detection and Variety Identification of Porphyra

RAPD (random amplified polymorphic DNA) markers were generated from filaments of 15 Porphyra lines representing four important groups, P. yezoensis, P. haitanensis, P. katadai var. hemiphylla and P. oligospermatangia. Among the total 69 fragments generated by 6 selected primers (among 50 primers), 67 appeared to be polymorphic (97.1%). Cluster analysis based on the RAPD results was performed. The 15 Porphyra lines were divided into 3 groups. This result was consistent with that from taxonomy analysis. A DNA fingerprinting based on 8 bands amplified with OPN-02 and OPJ-18 was constructed and might be used in Porphyra variety identification. Five specific RAPD fragments of 5 Porphyra lines were isolated and cloned into pGEM-T easy vector. These five RAPD fragments may be useful in germplasm identification and property protection of Porphyra.     

Suicide Polymerase Endonuclease Restriction, a Novel Technique for Enhancing PCR Amplification of Minor DNA Templates

PCR-based molecular analyses can be hindered by the presence of unwanted or dominant DNA templates that reduce or eliminate detection of alternate templates. We describe here a reaction in which such templates can be exclusively digested by endonuclease restriction, leaving all other DNAs unmodified. After such a modification, the digested template is no longer available for PCR amplification, while nontarget DNAs remain intact and can be amplified. We demonstrate the application of this method and use denaturing gradient gel electrophoresis to ascertain the removal of target DNA templates and the subsequent enhanced amplification of nondigested DNAs. Specifically, plastid 16S rRNA genes were exclusively digested from environmental DNA extracted from plant roots. In addition, pure culture and environmental DNA extracts were spiked with various amounts of genomic DNA extracted from Streptomyces spp., and selective restriction of the Streptomyces 16S rRNA genes via the suicide polymerase endonuclease restriction PCR method was employed to remove the amended DNA.     

Application of randomly amplified polymorphic DNA (RAPD) analysis for typing avian Salmonella enterica subsp. enterica

Randomly amplified polymorphic DNA (RAPD) analysis was performed for the molecular genetic typing of 30 Salmonella enterica subsp. enterica strains isolated from chickens and ducks in Thailand. Six different primers were tested for their discriminatory ability. While some of the primers could only differentiate between the different serovars, the use of multiple primers showed that the RAPD method could also subdivide within a given serovar. The Ready-To-Go RAPD analysis beads used, resulted in reproducible and stable banding patterns. As the RAPD technique is simple, rapid and rather cheap, we suggest that it may be a valuable new tool for studying the molecular genetic epidemiology of S. enterica ssp. enterica, both inter- and intra-serovars.     

Typing of bacteriophages by randomly amplified polymorphic DNA (RAPD)-PCR to assess genetic diversity

The recent boom in phage therapy and phage biocontrol requires the design of suitable cocktails of genetically different bacteriophages. The current methods for typing phages need significant quantities of purified DNA, may require a priori genetic information and are cost and time consuming. We have evaluated the randomly amplified polymorphic DNA (RAPD)-PCR technique to produce unique and reproducible band patterns from 26 different bacteriophages infecting Staphylococcus epidermidis, Staphylococcus aureus, Lactococcus lactis, Escherichia coli, Streptococcus thermophilus, Bacillus subtilis and Lactobacillus casei bacterial strains. Initially, purified DNA and phage suspensions of seven selected phages were used as a template. The conditions that were found to be optimal 8 μM of 10-mer primers, 3 μM magnesium oxalacetate and 5% dimethyl sulfoxide. The RAPD genomic fingerprints using a phage titer suspension higher than 10(9) PFU mL(-1) were highly reproducible. Clustering by the Pearson correlation coefficient and the unweighted pair group method with arithmetic averages clustering algorithm correlated largely with genetically different phages infecting the same bacterial species, although closely related phages with a similar DNA restriction pattern were indistinguishable. The results support the use of RAPD-PCR for quick typing of phage isolates and preliminary assessment of their genetic diversity bypassing tedious DNA purification protocols and previous knowledge of their sequence.     

Discrimination of species and strains of basidiomycete genusCoprinus by random amplified polymorphic DNA (RAPD) analysis

All five examined strains ofCoprinus cinereus could be clearly discriminated from the strains of five otherCoprinus species by RAPD patterns with 12 of 13 primers. Also one specimen of unknownCoprinus strain was identified to beC. cinereus by this method. The RAPD patterns were similar among the strains in the same species; many common DNA fragments were recognized as well as some strain-specific DNA fragments. Thus all seven strains ofC. cinereus and all four strains ofC. angulatus examined could be distinguished individually. Diakryotic strains showed the combined RAPD patterns of the two monokaryotic strains constituting the dikaryon. The combined RAPD markers observed in the dikaryons were segregated in their basidiospore progeny. All 18 randomly picked progeny showed different combinations of RAPD markers from the parental strains.     

Lactate and acetate production in Listeria innocua

S.A. HOWELL, R.M. ANTHONY AND E. POWER 1996. The genetic similarity of nineteen isolates of Candida albicans from four patients were compared by restriction fragment length polymorphism (RFLP) using Eco RI or Hin fI, which both detected five types, and by random amplification of polymorphic DNA (RAPD), which detected three types. Phenotypically unusual isolates also produced distinct patterns with both typing systems demonstrating the carriage of two groups of C. albicans as well as the presence of more than one type in some subjects. Methods of DNA preparation were compared for the production of reproducible patterns; including using the supernatant fluid of boiled intact or spheroplasted cells for RAPD, and DNA precipitated from chloroform extracted cell lysate for RFLP and RAPD. Consistent patterns were produced from the DNA precipitate by RAPD and after an additional precipitation by RFLP, thus removing the necessity for lengthy extraction procedures or the use of toxic chemicals for purification.     

Rapid DNA extraction methods and new primers for randomly amplified polymorphic DNA analysis of Giardia duodenalis.

A randomly amplified polymorphic DNA (RAPD) procedure using simple genomic DNA preparation methods and newly designed primers was optimized for analyzing Giardia duodenalis strains. Genomic DNA was extracted from in vitro cultivated trophozoites by five freezing-thawing cycles or by sonic treatment. Compared to a conventional method involving proteinase K digestion and phenol extraction, both freezing-thawing and sonication were equally efficient, yet with the advantage of being much less time- and labor-intensive. Five of the 10 tested RAPD primers produced reproducible polymorphisms among five human origin G. duodenalis strains, and grouping of these strains based on RAPD profiles was in agreement among these primers. The consistent classification of two standard laboratory reference strains, Portland-1 and WB, in the same group confirmed previous results using other fingerprinting methods, indicating that the reported simple DNA extraction methods and the selected primers are useful in RAPD for molecular characterization of G. duodenalis strains.     

Efficient removal of PCR inhibitors using agarose-embedded DNA preparations.

The use of agarose blocks containing embedded DNA improves the PCR amplification from templates naturally contaminated with polysaccharides or humic acids, two powerful PCR inhibitors. Presumably, the difference in size between the DNA macromolecules and these contaminants allows their effective removal from the agarose blocks by diffusion during the washing steps, whereas genomic DNA remains trapped within them. In addition, agarose-embedded DNA can be directly used for PCR since low melting point agarose does not interfere with the reaction. This simple and inexpensive method is also convenient for genomic DNAs extracted by other procedures, and it is potentially useful for samples containing other kinds of soluble inhibitors, overcoming this important problem of current amplification techniques.