Genomic fingerprints in the tribe Triticeae produced by PCR using a tRNA consensus primer

Forty-one accessions belonging to ten genera of the tribe Triticeae representing both wild and cultivated species were analyzed by polymerase chain reaction (PCR). Of two consensus tRNA primers tested, one primer revealed characteristic amplification products for all of the species. A total of 35 tRNA markers were scored across all accessions. Five genus-specific and three species-specific markers were obtained. Genomic fingerprints were largely conserved within a genus. The phylogram obtained using parsimony has separated most of the accessions into their prevailing taxonomic species and genus groups. The phylogram showed close association among the three genera Secale, Triticum and Hordeum as expected. The Triticum-Secale relationship was closer than the Triticum-Hordeum or the Secale-Hordeum relationships. The tree also reflected the close associations among the forage grass species belonging to Leymus and Elymus. Thus tDNA-PCR helped to identify species and genera. This revised version was published online in July 2006 with corrections to the Cover Date.     

Strain-specific fingerprints of Rhizobium galegae generated by PCR with arbitrary and repetitive primers

Strain-specific genomic patterns of Rhizobium galegae were generated by PCR using both arbitrary and repetitive (BOX, ERIC and REP) primers. The identification of the strains was achieved also by RFLP analysis. However, the PCR genomic fingerprinting has significant advantages: it is not only simpler and faster, but it is also much more discriminative because it deals with the full bacterial genome and not only with parts of it as is the case with RFLP. In addition, both kinds of PCR fingerprinting (using arbitrary or repetitive primers) generated highly specific and reproducible patterns when parallel reactions with total bacterial DNA, extracted from independent liquid cultures were performed. The latter shows that AP- and rep-PCR are convenient for controlling the production and application of Rhizobium inoculants.     

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.     

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.     

Use of tRNA consensus primers to indicate subgroups of Pseudomonas solanacearum by polymerase chain reaction amplification.

Polymerase chain reaction amplification of DNA from 112 Pseudomonas solanacearum strains with the tRNA consensus primers T3A and T5A divided the species into three fingerprint groups. These groups correspond well with previous divisions made by restriction fragment length polymorphism analysis. This polymerase chain reaction test is a facile method for rapidly classifying P. solanacearum strains.     

Genomic fingerprinting using arbitrarily primed PCR and a matrix of pairwise combinations of primers.

Polymorphisms in genomic fingerprints generated by arbitrarily primed PCR (AP-PCR) can distinguish between slightly divergent strains of any organism. Single oligodeoxyribonucleotide (oligo) primers have been used to generate such fingerprints, with the same primer being present at the 5' end of both strands for every PCR product. We used three arbitrary oligos, individually and in pairs, to generate six different genomic fingerprints of the same mouse genomic DNAs. Fewer than half of the products in genomic fingerprints generated using the oligos in pairs were the same as those produced by AP-PCR using one of the three oligos alone. Thus, a few oligos could be used in a very large number of single and pairwise combinations, each producing a distinct AP-PCR fingerprint with the potential to identify new polymorphisms. For example, 50 oligos can be used in a matrix of pairwise combinations to produce 2,500 fingerprints, in which at least half the data can be expected to be unique to each pair. We demonstrate this principle by using two oligos, alone and together, to generate three sets of fingerprints and map thirteen polymorphisms in the C57BL/6J x DBA/2J set of recombinant inbred mice.     

Fingerprinting genomes using PCR with arbitrary primers.

Simple and reproducible fingerprints of complex genomes can be generated using single arbitrarily chosen primers and the polymerase chain reaction (PCR). No prior sequence information is required. The method, arbitrarily primed PCR (AP-PCR), involves two cycles of low stringency amplification followed by PCR at higher stringency. We show that strains can be distinguished by comparing polymorphisms in genomic fingerprints. The generality of the method is demonstrated by application to twenty four strains from five species of Staphylococcus, eleven strains of Streptococcus pyogenes and three varieties of Oryza sativa (rice).     

Multiplex genotyping of PCR products with MassTag-labeled primers.

A simple mass spectrometric based assay, the PinPoint assay, has previously been described for typing single nucleotide polymorphisms. The identity of a polymorphism is determined by mass differences of single base extended genotyping primers as determined by MALDI-TOF mass spectrometry. A simple method for multiplexing the assay is described, employing multiple primers with 5'oligo(dT) sequences (MassTags) which serve to mass discriminate the peaks of multiple extended and non-extended primers. The assay is extremely rapid and requires no labeling reagents.     

High-throughput SNP genotyping by single-tube PCR with Tm-shift primers

Despite many recent advances in high-throughput single nucleotide polymorphism (SNP) genotyping technologies, there is still a great need for inexpensive and flexible methods with a reasonable throughput. Here we report substantial modifications and improvements to an existing homogenous allele-specific PCR-based SNP genotyping method, making it an attractive new option for researchers engaging in candidate gene studies or following up on genome-wide scans. In this advanced version of the melting temperature (Tm)-shift SNP genotyping method, we attach two GC-rich tails of different lengths to allele-specific PCR primers, such that SNP alleles in genomic DNA samples can be discriminated by the Tms of the PCR products. We have validated 306 SNP assays using this method and achieved a success rate in assay development of greater than 83% under uniform PCR conditions. We have developed a standalone software application to automatically assign genotypes directly from melting curve data. To demonstrate the accuracy of this method, we typed 592 individuals for 6 SNPs and showed a high call rate (>98%) and high accuracy (>99.9%). With this method, 6-10,000 samples can be genotyped per day using a single 384-well real-time thermal cycler with 2-4 standard 384-well PCR instruments.     

Rapid identification of Enterococcus italicus by PCR with primers targeted to 16S rRNA gene

AIMS: To develop a species-specific PCR assay with primers targeted to 16S rRNA gene for the identification of Enterococcus italicus, a new species of Enterococcus, involved in the production of Italian cheeses. METHODS AND RESULTS: The type strain of E. italicus (DSM 15952(T) - 16S rRNA gene accession no. AJ582753) and other strains of the species were subjected to a rapid identification by PCR using primer pairs located within the 16S rRNA gene. A species-specific PCR product of approximately 323 bp was obtained after amplification of all E. italicus strains tested. The specificity of the primers was validated with representatives of the most closely related genera and species and a number of other bacterial species. In addition, the technique enabled the recognition of E. italicus from cheeses. CONCLUSIONS: The protocol was highly efficient and sensitive, enabling the identification of E. italicus from cheeses. SIGNIFICANCE AND IMPACT OF THE STUDY: The species-specific PCR offers a reliable and rapid alternative to conventional phenotypic methods for the identification of E. italicus within the heterogeneous genus Enterococcus.     

Genomic sequencing by ligation-mediated PCR

Genomic sequencing permits studies of in vivo DNA methylation and protein-DNA interactions, but its use has been limited due to the complexity of the mammalian genome. Ligation-mediated PCR (LMPCR) is a sensitive genomic sequencing procedure that generates high quality, reproducible sequence ladders starting with only 1 μg of uncloned mammalian DNA per reaction. This genomic sequencing procedure can be adapted for various methylation, in vivo footprinting and DNA adduct mapping procedures. We provide a detailed protocol for genomic sequencing by LMPCR and discuss the principles and applications of the method.     

DNA amplification using PCR with abutting primers

Molecular Biology - DNA analysis of ñîmplex biological objects (wastewater, soil, archaeological and forensic samples, etc.) is currently of great interest. DNA of these objects is...     

Detection of genetic variation in Bradyrhizobium japonicum USDA 110 variants using DNA fingerprints generated with GC rich arbitrary PCR primers

Bradyrhizobium japonicum USDA 110 has been shown to contain several genetically similar naturally occurring colony morphology variants. These variants differ in symbiotic nitrogen fixation ability and in the utilization of various carbon substrates. They have been shown to share extensive DNA homology and appear to be derived from a common ancestor. Despite these similarities certain B. japonicum USDA 110 variants have been shown to be devoid of symbiotic nitrogen fixation. One of these variants (L2-110), however, was recently shown to possess significant levels of explanta nitrogen fixation and to synthesize functional dinitrogenase enzyme within bacteroids. In an effort to identify genetic markers which could explain differences in symbiotic nitrogen fixation between B. japonicum variants, DNA fingerprints were generated by PCR using arbitrary primers. Two of these primers with GC rich sequences were able to differentiate between B. japonicum USDA 110 variants I-110, L2-110, and MN-110. Unique markers have now been identified which could be examined further to determine if they explain the differences in symbiotic nitrogen fixation between USDA 110 variants.     

Using universal degenerate primers for restriction digestion mapping by PCR.

In this study, a polymerase chain reaction (PCR) is developed to determine the restriction map without using restriction endonucleases. A 937 bp fragment of pUC 19 which contained one cut site for EcoRI and two recognition sites for PvuII was used as a model. The PCR was carried out using designed degenerate primers and the products were analyzed on 1.5% agarose gel. The number of cut sites, length of fragments and the arrangement of the fragments from 3' or 5' end of desired sequence were determined.     

PCR detection of Salmonella spp. using primers targeting the quorum sensing gene sdiA

Bacteria communicate with one another and with their host using chemical signalling molecules. This phenomenon is generally described as quorum sensing. A set of primers for PCR detection of Salmonella spp. has been designed using as target the sdiA gene which encodes a signal receptor of the LuxR family. The PCR product (274 bp) was confirmed by sequencing. A number of 81 non-Salmonella strains (representing 24 different species) were tested and gave negative results, while a total of 101 different serotypes of Salmonella (155 strains) tested positive for the presence of the sdiA gene. The sensitivity and specificity of the sdiA-based PCR assay were also checked in artificially contaminated human faecal samples. In this study, we demonstrate that quorum sensing genes can be successfully exploited as diagnostic markers.