Genomic fingerprints of Salmonella species generated with repetitive element sequence-based PCR

We describe the use of repetitive element sequence-based PCR (rep-PCR) on the two repetitive sequences, REP and ERIC elements, to distinguish members of closely related Salmonella species. Within the species, ERIC–PCR showed a higher discriminative potential than REP–PCR, but by using a combination of the two PCR methods it was possible to distinguish all the isolates examined. The rep-PCR fingerprints of Salmonella organisms were distinctly different from some Gram-positive bacteria, for example Staphylococcus, Bacillus megaterium, and even the closely related Escherichia coli and Serratia marcescens. Identical fingerprints were observed with whole-cell preparations. Rapid specimen preparation has enhanced the value of rep-PCR in timely analysis of epidemiological relationships.     

Campylobacter spp. subtype analysis using gel-based repetitive extragenic palindromic-PCR discriminates in parallel fashion to flaA short variable region DNA sequence analysis

AIMS: The repetitive extragenic palindromic-PCR (rep-PCR) subtyping technique, which targets repetitive extragenic DNA sequences in a PCR, was optimized for Campylobacter spp. These data were then used for comparison with the established genotyping method of flaA short variable region (SVR) DNA sequence analysis as a tool for molecular epidemiology. METHODS AND RESULTS: Uprime Dt, Uprime B1 or Uprime RI primers were utilized to generate gel-based fingerprints from a set of 50 Campylobacter spp. isolates recovered from a variety of epidemiological backgrounds and sources. Analysis and phenogram tree construction, using the unweighted pair group method with arithmetic mean, of the generated fingerprints demonstrated that the Uprime Dt primers were effective in providing reproducible patterns (100% typability, 99% reproducibility) and at placing isolates into epidemiological relevant groups. Genetic stability of the rep-PCR Uprime Dt patterns under nonselective, short-term transfer conditions revealed a Pearson's correlation approaching 99%. These same 50 Campylobacter spp. isolates were analysed by flaA SVR DNA sequence analysis to obtain phylogenetic relationships. CONCLUSIONS: The Uprime Dt primer-generated rep-PCR phenogram was compared with a phenogram generated from flaA SVR DNA sequence analysis of the same isolates. Comparison of the two sets of resulting genomic relationships revealed that both methods segregated isolates into similar groups. SIGNIFICANCE AND IMPACT OF THE STUDY: These results indicate that rep-PCR analysis performed using the Mo Bio Ultra Clean Microbial Genomic DNA Isolation Kit for DNA isolation and the Uprime DT primer set for amplification is a useful and effective tool for accurate differentiation of Campylobacter spp. for subtyping and epidemiological analyses.     

Fingerprinting of Cyanobacteria Based on PCR with Primers Derived from Short and Long Tandemly Repeated Repetitive Sequences

The presence of repeated DNA (short tandemly repeated repetitive [STRR] and long tandemly repeated repetitive [LTRR]) sequences in the genome of cyanobacteria was used to generate a fingerprint method for symbiotic and free-living isolates. Primers corresponding to the STRR and LTRR sequences were used in the PCR, resulting in a method which generate specific fingerprints for individual isolates. The method was useful both with purified DNA and with intact cyanobacterial filaments or cells as templates for the PCR. Twenty-three Nostoc isolates from a total of 35 were symbiotic isolates from the angiosperm Gunnera species, including isolates from the same Gunnera species as well as from different species. The results show a genetic similarity among isolates from different Gunnera species as well as a genetic heterogeneity among isolates from the same Gunnera species. Isolates which have been postulated to be closely related or identical revealed similar results by the PCR method, indicating that the technique is useful for clustering of even closely related strains. The method was applied to nonheterocystus cyanobacteria from which a fingerprint pattern was obtained.     

Cloning and characterization of KM190, a specific satellite DNA family of Drosophila kitumensis and D. microlabis

The nucleotide sequences of nine clones, pKA191/l-4 from Drosophila kitumensis and pMR.190/1–5 from D. microlabis, were determined. They represent a tandemly arranged and highly repetitive satellite DNA family, KM190, which is specific for the two species.     

Application of Rep-PCR fingerprint in rapid identification of beer-spoilage bacteria

The application potential of rep-PCR in typing beer-spoilage isolates was studied. The effects of different factors, including DNA templates and primers, on the quality and reproducibility of fingerprints were investigated. The CATB protocol was shown to be the feasible method for DNA extraction. Primers BOXA1R and (GTG)₅ were used in rep-PCR, and the PCR products were sequenced to identify strains isolated from two breweries. Rep-PCR fingerprint profiles were obtained using GelCompar II software. Cluster analysis showed that the isolates belonging to Lactobacillus brevis, L. buchneri, L. casei/paracasei, and L. plantarum are divided into 2 or 3 subgroups. In addition, the two rep-PCR fingerprint profiles complemented each other in typing these isolates. By combining the similarity coefficient cut-off (SCC) of species, 9 unknown isolates were rapidly identified using both fingerprint databases. The results indicate that rep-PCR is a simple, reliable, and promising method for the rapid identification of beer-spoilage bacteria.     

Optimization of Analytical Parameters for Inferring Relationships among Escherichia coli Isolates from Repetitive-Element PCR by Maximizing Correspondence with Multilocus Sequence Typing Data

Repetitive-element PCR (rep-PCR) is a method for genotyping bacteria based on the selective amplification of repetitive genetic elements dispersed throughout bacterial chromosomes. The method has great potential for large-scale epidemiological studies because of its speed and simplicity; however, objective guidelines for inferring relationships among bacterial isolates from rep-PCR data are lacking. We used multilocus sequence typing (MLST) as a “gold standard” to optimize the analytical parameters for inferring relationships among Escherichia coli isolates from rep-PCR data. We chose 12 isolates from a large database to represent a wide range of pairwise genetic distances, based on the initial evaluation of their rep-PCR fingerprints. We conducted MLST with these same isolates and systematically varied the analytical parameters to maximize the correspondence between the relationships inferred from rep-PCR and those inferred from MLST. Methods that compared the shapes of densitometric profiles (“curve-based” methods) yielded consistently higher correspondence values between data types than did methods that calculated indices of similarity based on shared and different bands (maximum correspondences of 84.5% and 80.3%, respectively). Curve-based methods were also markedly more robust in accommodating variations in user-specified analytical parameter values than were “band-sharing coefficient” methods, and they enhanced the reproducibility of rep-PCR. Phylogenetic analyses of rep-PCR data yielded trees with high topological correspondence to trees based on MLST and high statistical support for major clades. These results indicate that rep-PCR yields accurate information for inferring relationships among E. coli isolates and that accuracy can be enhanced with the use of analytical methods that consider the shapes of densitometric profiles.     

Rep-PCR应用于快速鉴定啤酒污染菌的研究

为评价rep-PCR在快速鉴定啤酒污染菌中的应用,首先比较了DNA提取方法,确定CTAB法作为制备rep-PCR的DNA模板的方法。并通过PCR产物直接测序的方法,从分离菌中鉴定得到11种常见的啤酒污染菌。用BOXA1R和(GTG)_5引物扩增分离菌,采用Gel ComparⅡ软件处理电泳图,构建污染菌的标准指纹图库。经过聚类分析表明,BOXA1R和(GTG)5对Lactobacillusbrevis、L.buchneri、L.casei/paracasei、L.plantarum和L.fermentum的聚类效果具有互补性,并首次提出指纹比对快速鉴定的相似系数阈值的概念。对来自三个不同来源的9株乳酸菌的快速鉴定结果表明,rep-PCR鉴定技术简单、快速、可靠,在快速鉴定方面将具有重要的应用价值。     

Intraspecies variability of Desulfovibrio desulfuricans strains determined by the genetic profiles

Fifteen (soil and intestinal) strains of Desulfovibrio desulfuricans species were typed by PCR method with the use of primers specific for repetitive extragenic palindromic (REP) and enterobacterial repetitive intergenic consensus (ERIC) sequences. As a result, characteristic DNA fingerprints for the strains were obtained. Moreover, the genetic profiles were found to be useful for typing and distinguishing the strains of D. desulfuricans. According to cluster analysis, PCR with primers complementary to the sequences REP appeared to be slightly more discriminatory than PCR with ERIC primers for the investigated strains. Distinct fingerprint patterns of two isolates derived from the same patient pointed to the different origin of both strains.     

Genetic Distinctions among Clinical and Environmental Strains of Vibrio vulnificus

Vibrio vulnificus causes rare but frequently fatal septicemia associated with raw oyster consumption by persons with underlying hepatic or immune system dysfunction. The virulence potential of environmental reservoirs appears widely distributed, because most strains are virulent in animal models; however, several investigations recently demonstrated genetic divergence among strains from clinical versus environmental origin at independent genetic loci. The present study used PCR to screen DNA polymorphisms in strains from environmental (n = 35) or clinical (n = 33) sources, and genomic relationships were determined by repetitive extragenic palindromic DNA PCR (rep-PCR) typing. Significant (P < 0.01) association was observed for typical “clinical” or “environmental” polymorphism profiles based on strain origin. Most oyster isolates (88%), including all of those with the “environmental” profile, also formed a single rep-PCR genogroup. Clinical isolates within this group did not have the typical “clinical” profile. On the other hand, clinical isolates with the typical polymorphism profile were distributed among multiple rep-PCR genogroups, demonstrating greater genetic diversity than was evident by profiling genetic polymorphisms. Wound isolates were genetically distinct from typical blood isolates by all assays. Strains from an outbreak of wound infections in Israel (biotype 3) were closely related to several U.S. strains by rep-PCR, indicating potential reservoirs of emerging disease. Strains genetically related to blood isolates appeared to be relatively rare in oysters, as only one had the “clinical” polymorphism profile or clustered by rep-PCR. However, this study was not an extensive survey, and more sampling using rep-PCR for sensitive genetic discrimination is needed to determine the virulence potential of environmental reservoirs.     

Analysis of the Pan Genome of <Emphasis Type="Italic">Campylobacter jejuni</Emphasis> Isolates Recovered from Poultry by Pulsed-Field Gel Electrophoresis,Multilocus Sequence Typing (MLST), and Repetitive Sequence Polymerase Chain Reaction (rep-PCR) Reveals Different Discriminatory Capabilities

Campylobacter jejuni is one of the leading bacterial causes of food-borne illness in the USA. Molecular typing methods are often used in food safety for identifying sources of infection and pathways of transmission. Moreover, the identification of genetically related isolates (i.e., clades) may facilitate the development of intervention strategies for control and prevention of food-borne diseases. We analyzed the pan genome (i.e., core and variable genes) of 63 C. jejuni isolates recovered from chickens raised in conventional, organic, and free-range poultry flocks to gain insight into the genetic diversity of C. jejuni isolates recovered from different environments. We assessed the discriminatory power of three genotyping methods [i.e., pulsed-field gel electrophoresis (PFGE), multilocus sequence typing (MLST), and repetitive extragenic palindromic polymerase chain reaction (rep-PCR)]. The rep-PCR fingerprint was generated by determining the presence of repetitive sequences that are interspersed throughout the genome via repetitive extragenic palindromic PCR, enterobacterial repetitive intergenic consensus sequence PCR (ERIC-PCR), and BOX element PCR (BOX-PCR) and combining the data to form a composite fingerprint. The genetic fingerprints were subjected to computer-assisted pattern analysis. Comparison of the three genotypic methods revealed that repREB-PCR showed greater discriminatory power than PFGE and MLST. ERIC-PCR and BOX-PCR yielded the highest number of PCR products and greatest reproducibility. Regardless of the genotyping method, C. jejuni isolates recovered from chickens reared in conventional, organic, and free-range environments all exhibit a high level of genotypic diversity.     

Comparison of Ribotyping and Repetitive Extragenic Palindromic-PCR for Identification of Fecal Escherichia coli from Humans and Animals

This report compares the performances of two popular genotypic methods used for tracking the sources of fecal pollution in water, ribotyping and repetitive extragenic palindromic-PCR (rep-PCR). The rep-PCR was more accurate, reproducible, and efficient in associating DNA fingerprints of fecal Escherichia coli with human and animal hosts of origin.     

Molecular structure and chromosomal localization of major repetitive DNA families in the chickpea (Cicer arietinum L.) genome

Three major repetitive DNA sequences were isolated from a genomic library of chickpea (Cicer arietinum L.) and characterized with respect to their genomic organization and chromosomal localization. All repetitive elements are genus-specific and mostly located in the AT-rich pericentric heterochromatin. Two families are organized as satellite DNAs with repeat lengths of 162–168 bp (CaSat1) and 100 bp (CaSat2). CaSat1 is mainly located adjacent to the 18S rDNA clusters on chromosomes A and B, whereas CaSat2 is a major component of the pericentric heterochromatin on all chromosomes. The high abundance of these sequences in closely related species of the genus Cicer as well as their variation in structure and copy number among the annual species provide useful tools for taxonomic studies. The retrotransposon-like sequences of the third family (CaRep) display a more complex organization and are represented by two independent sets of clones (CaRep1 and CaRep2) with homology to different regions of Ty3-gypsy-like retrotransposons. They are distributed over the pericentric heterochromatin block on all chromosomes with extensions into euchromatic regions. Conserved structures within different crossability groups of related Cicer species suggest independent amplification or transposition events during the evolution of the annual species of the genus.     

Application of PCR, rep-PCR and RAPD techniques for typing ofLactococcus lactis strains

A collection of 34 lactococcal strains were characterized using the polymerase chain reaction (PCR) for the acmA gene, and for the 16S rDNA gene, and DNA fingerprinting methods for randomly amplified polymorphic DNA (RAPD) and repetitive extragenic palindrome-PCR (rep-PCR). PCR experiments corroborated the genotypic identification of Lactococcus lactis strains by RAPD; rep-PCR did not distinguish between L. lactis subspecies. In some cases, phenotypic classification of L. lactis subspecies did not correlate with genotypic characterization.     

Heterogeneity of<Emphasis Type="Italic">Escherichia coli</Emphasis> derived from artiodactyla animals analyzed with the use of rep-PCR fingerprinting

Genetic polymorphism of 83 isolates of E. coli, derived from 4 species of artiodactyla animals living in a relatively close contact on the grounds of a theme park ZOO Safarii Swierkocin (Poland) was determined using the rep-PCR fingerprinting method, which utilizes oligonucleotide primers matching interspersed repetitive DNA sequences in PCR reaction to yield DNA fingerprints of individual bacterial isolates based on repetitive extragenic palindrome (REP) primers. The fingerprint patterns demonstrated the essential polymorphism of distribution of REP sequences in genomes of the examined isolates. The arithmetic averages clustering algorithm (UPGMA) statistical analysis of fingerprints with the use of the Jaccard similarity coefficient differentiated E. coli isolates into three similarity groups containing various numbers of isolates. The groups comprised isolates derived from two, three and four species of the source animals. The isolates derived from each source segregated in the dendrogram in a different way, both within the similarity groups and among them, indicating an individual repertoire of E. coli in the examined species of animals. The similarity relations among E. coli derived from the same source, illustrated in a dendrogram with a number of subclusters of a low mutual similarity (< or = 20%), indicated an essential interstrain differentiation in terms of the distribution of REP sequences. Our results confirmed the hypothesis of the oligoclonal characters of populations obtained from particular sources. The rep-PCR fingerprinting method with REP primers is simple and highly differentiating and can be recommended for use in explorations of large groups of animals and monitoring the variability of strains.     

Identification of Bifidobacterium species using rep-PCR fingerprinting

The aim of the present study was to evaluate the use of repetitive DNA element PCR fingerprinting (rep-PCR) for the taxonomic discrimination among the currently described species within the genus Bifidobacterium. After evaluating several primer sets targeting the repetitive DNA elements BOX, ERIC, (GTG)s and REP, the BOXA1R primer was found to be the most optimal choice for the establishment of a taxonomical framework of 80 Bifidobacterium type and reference strains. Subsequently, the BOX-PCR protocol was tested for the identification of 48 unknown bifidobacterial isolates originating from human faecal samples and probiotic products. In conclusion, rep-PCR fingerprinting using the BOXA1R primer can be considered as a promising genotypic tool for the identification of a wide range of bifidobacteria at the species, subspecies and potentially up to the strain level.     

Applications of the rep-PCR DNA fingerprinting technique to study microbial diversity, ecology and evolution

A large number of repetitive DNA sequences are found in multiple sites in the genomes of numerous bacteria, archaea and eukarya. While the functions of many of these repetitive sequence elements are unknown, they have proven to be useful as the basis of several powerful tools for use in molecular diagnostics, medical microbiology, epidemiological analyses and environmental microbiology. The repetitive sequence-based PCR or rep-PCR DNA fingerprint technique uses primers targeting several of these repetitive elements and PCR to generate unique DNA profiles or 'fingerprints' of individual microbial strains. Although this technique has been extensively used to examine diversity among variety of prokaryotic microorganisms, rep-PCR DNA fingerprinting can also be applied to microbial ecology and microbial evolution studies since it has the power to distinguish microbes at the strain or isolate level. Recent advancement in rep-PCR methodology has resulted in increased accuracy, reproducibility and throughput. In this minireview, we summarize recent improvements in rep-PCR DNA fingerprinting methodology, and discuss its applications to address fundamentally important questions in microbial ecology and evolution.     

Cloning and characterization of KM190, a specific satellite DNA family of Drosophila kitumensis and D. microlabis.

The nucleotide sequences of nine clones, pKA191/l-4 from Drosophila kitumensis and pMR.190/1–5 from D. microlabis, were determined. They represent a tandemly arranged and highly repetitive satellite DNA family, KM190, which is specific for the two species.     

Identification of Staphylococcus spp. using (GTG)₅-PCR fingerprinting

A group of 212 type and reference strains deposited in the Czech Collection of Microorganisms (Brno, Czech Republic) and covering 41 Staphylococcus species comprising 21 subspecies was characterised using rep-PCR fingerprinting with the (GTG)₅ primer in order to evaluate this method for identification of staphylococci. All strains were typeable using the (GTG)₅ primer and generated PCR products ranging from 200 to 4500 bp. Numerical analysis of the obtained fingerprints revealed (sub)species-specific clustering corresponding with the taxonomic position of analysed strains. Taxonomic position of selected strains representing the (sub)species that were distributed over multiple rep-PCR clusters was verified and confirmed by the partial rpoB gene sequencing. Staphylococcus caprae, Staphylococcus equorum, Staphylococcus sciuri, Staphylococcus piscifermentans, Staphylococcus xylosus, and Staphylococcus saprophyticus revealed heterogeneous fingerprints and each (sub)species was distributed over several clusters. However, representatives of the remaining Staphylococcus spp. were clearly separated in single (sub)species-specific clusters. These results showed rep-PCR with the (GTG)₅ primer as a fast and reliable method applicable for differentiation and straightforward identification of majority of Staphylococcus spp.     

Rep-PCR mediated genomic fingerprinting of rhizobia and computer-assisted phylogenetic pattern analysis

A rapid and reproducible method has been developed for genomic fingerprinting of rhizobia and other soil microbes interacting with plants. The method is based on the use of oligonucleotide primers, corresponding to conserved motifs in naturally occurring interspersed repetitive DNA elements in bacteria (rep-elements), and the polymerase chain reaction (rep-PCR). Rep-PCR results in the amplification of inter-element genomic DNA fragments of characteristic lengths and thereby generates a genomic fingerprint. These fingerprints resemble UPC bar code patterns, and can be used to identify bacteria at the sub-species and strain level, as well as for phylogenetic analyses. Here we show that highly characteristic and very reproducible rep-PCR generated genomic fingerprints can be obtained not only from purified genomic DNA, but also directly from rhizobial cells derived from liquid cultures or from colonies on plates, as well as from nodule tissue. We examine the effect of growth phase of the bacterial cells, serial subculturing and other parameters on the reproducibility of the rep-PCR fingerprinting protocol. Moreover, we describe the results of mixing experiments designed to determine if individual genomic fingerprints can be recognized in mixtures of strains. Lastly, we review the use of computer-based fragment detection and phylogentic analysis packages to analyse rep-PCR generated genomic fingerprints of a collection of Rhizobium loti and Bradyrhizobium strains nodulating different Lotus spp.The authors are with the NSF Center for Microbial Ecology and the MSU-DOE Plant Research Laboratory. F. J. de Bruijn is also with the Microbiology Department and Genetics Program of Michigan State University, E. Lansing, MI 48824 USA.     

Genomic fingerprinting of Bradyrhizobium japonicum isolates by RAPD and rep-PCR

Genetic diversity of indigenous Bradyrhizobium japonicum population in Croatia was studied by using different PCR-based fingerprinting methods. Characteristic DNA profiles for 20 B. japonicum field isolates and two reference strains were obtained using random primers (RAPD) and two sets of repetitive primers (REP- and ERIC-PCR). In comparison with the REP, the ERIC primer set generates fingerprints of lower complexity, but still several strain-specific bands were detected. Different B. japonicum isolates could be more efficiently distinguished by using combined results from REP- and ERIC-PCR. The most polymorphic bands were observed after amplification with four different RAPD primers. Both methods, RAPD and rep-PCR, resulted in identical grouping of the strains. Cluster analysis, irrespective of the fingerprinting method used, revealed that all the isolates could be divided into three major groups. Within the major groups, the degree of relative similarity between B. japonicum isolates was dependent upon the method used. Our results indicate that both RAPD and rep-PCR fingerprinting can effectively distinguish different B. japonicum strains. RAPD fingerprinting proved to be slightly more discriminatory than rep-PCR.