Optimization of random amplification of polymorphic DNA analysis for molecular subtyping of Escherichia coli O157

Random amplification of polymorphic DNA (RAPD) analysis using the polymerase chain reaction has proved to be a useful technique in the epidemiological investigation of micro-organisms but may suffer from a lack of reproducibility in poorly optimized protocols. In this study a method of obtaining reproducible genomic fingerprints using RAPD analysis of Escherichia coli O157 is described. By systematic optimization of reaction conditions and selection of suitable primers, reproducible and discriminatory profiles could be obtained from all E. coli O157 strains tested. In addition, two other methods of obtaining reproducible profiles from E. coli O157 strains without the need to purify genomic DNA are described.     

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.     

Application of Random Amplified Polymorphic DNA analysis to differentiate strains of Salmonella typhi and other Salmonella species

A Random Amplified Polymorphic DNA (RAPD) fingerprinting method was developed to differentiate isolates of Salmonella serotype typhi ( S. typhi ) and other Salmonella isolates. A panel of five primers was used to examine 63 isolates of Salm. typhi , including 56 strains isolated in Taiwan and seven strains obtained abroad. Twenty-one RAPD types were revealed using the RAPD fingerprinting method. An RAPD with primer 6032 yielded a polymorphism in a 350 bp fragment that differentiated the attenuated vaccine strain Salm. typhi Ty21a from the rest of the Salm. typhi strains. Strains of Salm. typhi were divided into five types with primer D14307. Primer D14307 also proved capable of discrimination among 65 other Salmonella isolates representing 42 different serotypes. The bacterial DNA used in this RAPD protocol was obtained using a commercially available DNA extraction kit (GeneReleaser). The DNA of various strains of Salmonella from this simple extraction procedure could be discriminated within a few hours using the RAPD technique.     

应用RAPD技术鉴别微生态菌种

目的：建立应用RAPD技术鉴别微生态菌种的方法,提高菌种鉴别水平。方法：应用RAPD（随机扩增多态性）方法,选用5条随机引物,利用PCR方法,对3株长双歧杆菌,3株嗜酸乳杆菌,3株粪肠球菌进行基因组DNA指纹图谱分析。结果：发现不同菌株扩增的DNA片段的大小、数量是有差异的。结论：此方法具有可重复性,方便、快速和准确的优势,可用于微生态制剂生产用菌株的鉴别。     

Random amplification of polymorphic bacterial DNA: evaluation of 11 oligonucleotides and application to food contaminated with Listeria monocytogenes

CH. NIEDERHAUSER, CH. HÖFELEIN, M. ALLMANN, P. BURKHALTER, J. LÜTHY AND U. CANDRIAN. 1994. The polymerase chain reaction was used to obtain randomly-amplified polymorphic DNA (RAPD) profiles from Listeria spp. and enterobacteria. Eleven different oligonucleotides were evaluated. Only one, HR4 (19mer), generated reproducible and specific profiles for Listeria spp., while results for enterobacteria were controversial. A total of 57 different Listeria strains were subjected to the RAPD analysis and 27 different profiles were recognized. RAPD typing allowed strains of the same serotype to be distinguished but the same profile was obtained from different serotypes of L. monocytogenes in three cases and in one case two different serotypes of L. innocua yielded the same profile. RAPD-typing with HR4 allowed L. monocytogenes contamination in several food outlets to be traced back to a food processing plant. In additional experiments, the general utility of this RAPD system in typing Yersinia enterocolitica, verotoxigenic Escherichia coli and Salmonella enteritidis was evaluated.     

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.     

Optimization of the conditions for RAPD-PCR of Candida spp. and Cryptococcus spp

In this study, we determined the optimal RAPD amplification conditions to obtain genetic molecular markers for the rapid and accurate identification of Cryptococcus spp. and Candida spp. The following parameters are modified: template DNA, DNA polymerase, magnesium cloride and primer concentration; denaturation, annealing and extension time, temperature of annealing and thermal cycles. After the optimization, reliable and reproducible RAPD patterns are obtained.     

RAPD分析花椰花不同品种的遗传变异

利用随机扩增多态性DNA（RAPD）方法,对13个花椰花品种的基因组DNA进行多态性分析。选用20个10bp随机引物,共扩增出175条DNA片段,其中多态性片段118例,占67．4％,结果表明,花椰花品种间具有丰富的遗传多样性。依据扩增结果进行遗传相似系数分析,构建聚类分析树状图。初步探讨了各品种间的遗传变异关系及RAPD技术在花椰花种质资源分类鉴定和育种工作中的应用前景。     

Random amplification of polymorphic DNA (RAPD) of Salmonella: strain differentiation and characterization of amplified sequences

Random amplification of polymorphic DNA (RAPD) was evaluated for its ability to differentiate Salmonella strains from various sources. Under defined conditions RAPD using a 10-mer primer (1254) produced a series of amplification products able to reproducibly distinguish strains representing 20 different serotypes of Salmonella. Primer 1254 also proved capable of discrimination between some but not all isolates of Salm. ser. Enteritidis and Salm. ser. Typhimurium, phage typing proving to be most discriminatory for the latter serotype. Cloning of fragments into a vector allowed sequencing and database searching for identification of fragments and an indication of criteria for primer template interaction in RAPD. Southern blotting using a digoxigenin-labelled probe allowed identification of related bands between RAPD profiles. These observations demonstrate the potential of rapid molecular typing by RAPD for the genomic typing of Salmonella strains.     

Clonal relations among Salmonella enteritidis phage type 3 outbreak isolates traced by DNA fingerprinting.

Isolates of Salmonella enteritidis PT3, a rare phage type, were recovered from patients and strains were isolated from an outbreak of gastroenteritis that occurred during the summer of 1997 in North-East Sardinia, Italy. To investigate possible clonal involvement in the outbreak and to evaluate the capacity to discriminate among S. enteritidis PT3 strains, a number of molecular typing methods including ribotyping with a mixture of PstI and SphI (PS-ribotyping), PFGE with endonuclease XbaI and RAPD typing with four arbitrary primers was used. The typical XbaI endonuclease generated PFGE pattern also explained the prevalence of highly clonal S. enteritidis PT3 strains in the outbreak and adjacent areas. RAPD fingerprinting with primers OPA 4, OPB 15, OPB17 and P1254 exhibited a single but unique RAPD profile among the outbreak strains from various sources that differed significantly from control strains. The results of this study showed that when an appropriately chosen set of primers is employed, RAPD fingerprinting can be used as an alternative, rapid, highly reproducible technique for tracing the clonal relations of S. enteritidis PT3, and can be more discriminatory than PFGE. Furthermore, this study revealed the possibility of PT3 causing outbreak.     

Identification of a molecular marker for genotyping human lymphatic filarial nematode parasite Wuchereria bancrofti

In India, Mass Drug Administration is on going towards elimination of lymphatic filariasis in many areas, which might lead to intense selection pressure on the parasite populations and their genetic restructuring. This calls for molecular finger printing of Wuchereria bancrofti parasite populations at national level and monitoring genetic changes in the future. For this purpose a reliable, less expensive, rapid, and reproducible molecular tool is necessary, which is not available for W. bancrofti at this time. We identified robust molecular markers based on the comparison of random amplified polymorphic DNA (RAPD) and amplified fragment length polymorphism (AFLP) profiles and the genetic data generated from parasite populations collected from areas in Northern (Varanasi, Uttar Pradesh state), Southern (Kozhikode, Kerala State) and Central regions (Jagdalpur, Chattisgarh state) of India, where lymphatic filariasis is endemic for many decades. RAPD profiles for these parasite populations were generated using three different primers and the dendrograms constructed using the profiles were all different. In order to identify appropriate RAPD primer(s), we compared the results of RAPD with the fingerprint profile and genetic data obtained by the more reliable AFLP technique, using the parasite populations from the same areas. RAPD marker (OP8) primer produced phylogenetic data almost similar to that of AFLP analysis. The marker was able to reveal variations between the parasite populations collected from Varanasi, Kozhikode, and Jagdalpur. Most importantly, RAPD primer OP8 produced reproducible results, when tested in three different trials. In view of the limited availability of W. bancrofti parasite DNA, along with a lower cost and ease of performance, RAPD appears to be more suitable compared to AFLP at the present juncture, since complete genome information of this parasite is still not available. Thus, RAPD primer OP8 can be a very useful molecular maker for DNA finger printing of W. bancrofti populations at present.     

Effect of DNA preparation from laver (Porphyra yezoensis) thalli on reproducibility of RAPD (random amplified polymorphic DNA) patterns

Laver (Porphyra yezoensis) DNAs were extracted from thalli with five different procedures and used for RAPD (random amplified polymorphic DNA) analysis as templates. Restriction enzyme-digestive DNAs were obtained with all procedures examined. However, RAPD patterns generated with these DNAs appeared highly irreproducible and were considerably different from each other. When DNAs purified with CsCl gradient centrifugation were used for RAPD analysis as templates, highly reproducible RAPD patterns were obtained, suggesting that unpurified DNAs extracted from thalli with all five extraction procedures contained an excess of RNA, polysaccharides and/or other materials which affected the RAPD reproducibility. Thus, results indicated that purification of DNA is essential to produce reproducible RAPD patterns of Porphyra DNA. This revised version was published online in June 2006 with corrections to the Cover Date.     

Analysis of clinical isolates of Propionibacterium acnes by optimised RAPD

Random amplification of polymorphic DNA (RAPD) was evaluated as a genotypic method for typing clinical strains of Propionibacterium acnes. RAPD can suffer from problems of reproducibility if parameters are not standardised. In this study the reaction conditions were optimised by adjusting template DNA concentration and buffer constituents. All isolates were typeable using the optimised RAPD protocol which was found to be highly discriminatory (Simpson's diversity index, 0.98) and reproducible. Typing of P. acnes by optimised RAPD is an invaluable tool for the epidemiological investigation of P. acnes for which no other widely accepted method currently exists.     

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.     

RAPD analysis of Campylobacter isolates: DNA fingerprinting without the need to purify DNA

A method was developed to obtain reproducible DNA fingerprints from Campylobacter by PCR-based amplification, without the need to isolate total DNA. Randomly amplified polymorphic DNA (RAPD) profiles were generated with three randomly designed 10-mers, using each separately as an amplification primer. A range of C. jejuni serotypes could be typed by RAPD analysis. Depending on the primer, the analysis of RAPD profiles resulted in different levels of discrimination between the strains. Clear correlations were observed between results of RAPD analysis and serotyping. Two of the primers tested generated RAPD profiles which allowed discrimination of strains within given Penner and Lior serotypes.     

Differentiation of Brucella species by random amplified polymorphic DNA analysis

Random amplification of polymorphic DNA (RAPD) was used for discrimination between 46 Brucella strains and 14 representatives of the alpha-2 and alpha-1 subgroups of Proteobacteria. To evaluate a relatively quick and exact method for Brucella identification, the authors specified the most suitable conditions for RAPD amplification of Brucella DNA with two 10-mer primers, containing lower and higher percentages of G and C. The software package PHYLIP 3.1 was used for cluster analysis of the RAPD fingerprints. The optimization of RAPD conditions resulted in PCR mixes suitable for reliable typing of Brucellae. The distance-based methods (Fitch-Margoliash, UPGMA and Neighbour-joining) gave clear discrimination between Brucella species. The constructed dendrograms put Br. canis and Br. suis bv. 1 in the same cluster and differentiated Brucella strains according to their host preferences. RAPD can be useful method to distinguish related bacterial species, and under strictly established conditions the reaction appears to be a simple, quick and sensitive technique for the epidemiological investigation of brucellosis.     

Evaluation and comparison of random amplification of polymorphic DNA, pulsed-field gel electrophoresis and ADSRRS-fingerprinting for typing Serratia marcescens outbreaks

Amplification of DNA fragments surrounding rare restriction sites (ADSRRS-fingerprinting) is a novel assay based on suppression of polymerase chain reaction (PCR). This phenomenon allows the amplification of only a limited subset of DNA fragments, since only those with two different oligonucleotides ligated at the ends of complementary DNA strands are amplified in the PCR. The DNA fragments can be easily analyzed on polyacrylamide gels, stained with ethidium bromide. We have implemented this method using a set of clinical Serratia marcescens isolates from three outbreaks ongoing in the Public Hospital in Gdańsk (Poland). Clustering of ADSRRS-fingerprinting data matched epidemiological, microbiological, random amplification of polymorphic DNA (RAPD) and pulsed-field gel electrophoresis (PFGE) data. Based on this study, we found that there is at least a similar power of discrimination between the present 'gold-standard' PFGE and the novel method, ADSRRS-fingerprinting. Although the ADSRRS-fingerprinting method may appear to be more complex than the RAPD technique, we found it fast and reproducible.     

Random Amplified Polymorphic DNA Analysis of Heterodera cruciferae and H. schachtii populations

Heterodera schachtii and H. cruciferae are sympatric in California and frequently occur in the same field upon the same host. We have investigated the use of polymerase chain reaction (PCR) amplification of nematode DNA sequences to differentiate H. schachtii and H. cruciferae and to assess genetic variability within each species. Single, random oligodeoxyribonucleotide primers were used to generate PCR-amplified fragments, termed RAPD (random amplified polymorphic DNA) markers, from genomic DNA of each species. Each of 19 different random primers yielded from 2 to 12 fragments whose size ranged from 200 to 1,500 bp. Reproducible differences in fragment patterns allowed differentiation of the two species with each primer. Similarities and differences among six different geographic populations of H. schachtii were detected. The potential application of RAPD analysis to relationships among nematode populations was assessed through cluster analysis of these six different populations, with 78 scorable markers from 10 different random primers. DNA from single cysts was successfully amplified, and genetic variability was revealed within geographic populations. The use of RAPD markers to assess genetic variability is a simple, reproducible technique that does not require radioisotopes. This powerful new technique can be used as a diagnostic tool and should have broad application in nematology.     

RAPD typing for distinguishing species and strains in the genus Listeria

The randomly amplified polymorphic DNA (RAPD) technique was employed in the development of a typing protocol for Listeria isolates, particularly Listeria monocytogenes strains. A single strain of L. monocytogenes was used and 200 random decamer primers were screened for their discriminatory abilities by visualizing the amplification products electrophoretically. Three candidate primers displaying potentially useful banding patterns were selected and tested against 52 L. monocytogenes strains, encompassing 11 serotypes, and 12 other strains representing five other Listeria spp. Thirty-four banding profiles were obtained with one particular primer. RAPD analysis allowed differentiation between Listeria spp. and was found to further subdivide strains of the same serotype. Where only one primer was used strains from different serotypes were occasionally found to produce identical banding profiles. RAPD analysis, which in our hands proved to be reproducible, shows much promise as a molecular alternative to traditional L. monocytogenes typing protocols.     

Automated ribotyping and random amplified polymorphic DNA analysis for molecular typing of Salmonella enteritidis and Salmonella typhimurium strains isolated in Italy

AIMS: The ability of automated ribotyping and random amplified polymorphic DNA (RAPD) analysis to differentiate Salmonella enteritidis and Salmonella typhimurium isolates in relation to their origin was evaluated. METHODS AND RESULTS: The restriction enzymes EcoRI, PvuII and PstI, and the random primers OPB17 and P1254, were tested for ribotyping and RAPD analysis, respectively. Seventeen subtypes were identified among the isolates of the two pathogenic Salmonella serovars using the RiboPrinter, and 25 subtypes using RAPD. CONCLUSIONS: The greatest degree of genetic diversity was observed among Salm. typhimurium isolates using both automated ribotyping (Simpson's index of discrimination 0878) and RAPD (Simpson's index of discrimination 0886). SIGNIFICANCE AND IMPACT OF THE STUDY: According to the results of this research, automated ribotyping and RAPD are two useful genotyping techniques for identifying unique and common subtypes associated with a specific source and location, and provide powerful tools for epidemiological investigations.