Rapid generation of chromosome-specific alphoid DNA probes using the polymerase chain reaction

Summary Non-isotopic in situ hybridization of chromosome-specific alphoid DNA probes has become a potent tool in the study of numerical aberrations of specific human chromosomes at all stages of the cell cycle. In this paper, we describe approaches for the rapid generation of such probes using the polymerase chain reaction (PCR), and demonstrate their chromosome specificity by fluorescence in situ hybridization to normal human metaphase spreads and interphase nuclei. Oligonucleotide primers for conserved regions of the alpha satellite monomer were used to generate chromosome-specific DNA probes from somatic hybrid cells containing various human chromosomes, and from DNA libraries from sorted human chromosomes. Oligonucleotide primers for chromosome-specific regions of the alpha satellite monomer were used to generate specific DNA probes for the pericentromeric heterochromatin of human chromosomes 1, 6, 7, 17 and X directly from human genomic DNA.     

Detection of Chlamydia psittaci using DNA probes and the polymerase chain reaction

Fewer than 10(5) elementary bodies of Chlamydia psittaci could be detected by using DNA hybridisation with a plasmid probe specific for avian chlamydial strains. PCR amplification of chlamydial DNA using primers specific for conserved regions of the major outer membrane protein gene enabled the detection of fewer than 10 elementary bodies. DNA could be amplified from 22 of the 24 chlamydial strains tested including avian, feline, ovine, caprine, koala and lymphogranuloma venereum strains.     

Recombinant DNA probes and polymerase chain reaction for detection of Mycoplasma gallisepticum strains

Abstract Two recombinant DNA clones, pMG286.2 and pMG301.1, were isolated from the partial genomic library of Mycoplasma gallisepticum strain S6. Recombinant M. gallisepticum specific fragments were used as probes in Southern hybridisation with 10 M. gallisepticum strains whose DNA was digested by Eco RI, Hin dIII, Bgl II, Rsa I and Bam HI. The 1.5 kb fragment pMG301.1 did not show polymorphism in hybridisation patterns with M. gallisepticum strains, while the 3.5 kb fragment pMG286.2 enabled differentiation of M. gallisepticum strains into clusters. The DNA sequence of pMG301.1 was used to design a pair of 27-mer oligonucleotides flanking a 1.3 kb genomic region. These two primers directed specific in vitro amplification of all M. gallisepticum strains assayed giving an expected 1.3 kb product. Digestion of polymerase chain reaction products by Dde I enabled simple differentiation between clusters of M. gallisepticum strains and may be useful for improved epizootiological studies of M. gallisepticum infections in poultry.     

Detection of Streptococcus pneumoniae DNA by using polymerase chain reaction and microwell hybridization with Europium-labelled probes

The present paper describes a novel modification of polymerase chain reaction (PCR) for the detection of Streptococcus pneumoniae DNA in clinical specimens. PCR was based on the detection of a 209-base pair segment of the S. pneumoniae pneumolysin gene. For the demonstration of the amplification product, microwell hybridization with a Europium-labelled oligonucleotide probe complementary to a biotinylated strand of the PCR product was performed, and the presence of the PCR product was monitored by time-resolved fluorescence (TRF) of the Europium chelate. The sensitivity of the assay for purified S. pneumoniae DNA was 50 fg DNA corresponding to 20 genome equivalents of S. pneumoniae DNA. The efficiency of the hybridization step was monitored by using known amounts of synthetic target oligonucleotides as standards. Sensitivity of 3×10⁸ molecules per individual reaction well was achieved with a 30-min attachment time and a 3-h hybridization time.

Detection of PCR-amplified products by the microwell hybridization technique and TRF was compared to agarose gel electrophoresis in 50 middle ear fluid samples obtained from children with acute otitis media. The agarose gel and TRF detection methods identified all culture-positive samples, but both were also positive for 55% of the culture-negative samples. The results suggest that the detection of amplified PCR products by microwell hybridization using Europium-labelled oligonucleotides is a reliable method for the demonstration of the pneumolysin gene fragment. Furthermore, the method is suitable for automation and, thus, for testing high numbers of samples. The clinical significance of the PCR findings remains to be studied.     

Production of discrete high specific activity DNA probes using the polymerase chain reaction

Conditions are described for the synthesis of discrete DNA probes with high specific activity using the polymerase chain reaction. This method enables the production of DNA probes between any two oligonucleotide sequences from cloned or uncloned templates. These probes are uniform in length and their specific activity (1 × 10⁹ cpm/μg) is comparable to probes produced by other methods.     

Affinity generation of single-stranded DNA for dideoxy sequencing following the polymerase chain reaction

A method to rapidly generate single stranded DNA for dideoxy sequencing following the polymerase chain reaction is described. By incorporating biotin in one of the amplification primers, we are able to physically separate the two DNA strands produced in the polymerase chain reaction. After amplification, the mixture is passed through a column containing streptavidin agarose. The strand produced by the biotinylated primer is bound in this matrix. The unbiotinylated strand is eluted with 0.2 N NaOH and sequenced by the dideoxy method. This method was utilized to sequence mitochondrial DNA from crude genomic DNA and to determine the sequences of four clones containing human mitochondrial DNA as a test of its accuracy. The use of biotin-facilitated separation permitted us to amplify and sequence DNA samples in a single day.     

The polymerase chain reaction

This essay on the polymerase chain reaction is one of a series developed as part of FASEB's efforts to educate the general public, and the legislators whom it elects, about the benefits of fundamental biomedical research-particularly how investment in such research leads to scientific progress, improved health, and economic well-being.     

The polymerase chain reaction

The polymerase chain reaction (PCR) is a powerful new method for 'in vitro cloning'. It can selectively amplify a single molecule of template DNA several millionfold in a few hours and has made possible new approaches to problems in molecular genetics, evolutionary biology, and development.     

Quantitative analysis of total mitochondrial DNA: competitive polymerase chain reaction versus real-time polymerase chain reaction

An efficient and effective method for quantification of small amounts of nucleic acids contained within a sample specimen would be an important diagnostic tool for determining the content of mitochondrial DNA (mtDNA) in situations where the depletion thereof may be a contributing factor to the exhibited pathology phenotype. This study compares two quantification assays for calculating the total mtDNA molecule number per nanogram of total genomic DNA isolated from human blood, through the amplification of a 613-bp region on the mtDNA molecule. In one case, the mtDNA copy number was calculated by standard competitive polymerase chain reaction (PCR) technique that involves co-amplification of target DNA with various dilutions of a nonhomologous internal competitor that has the same primer binding sites as the target sequence, and subsequent determination of an equivalence point of target and competitor concentrations. In the second method, the calculation of copy number involved extrapolation from the fluorescence versus copy number standard curve generated by real-time PCR using various dilutions of the target amplicon sequence. While the mtDNA copy number was comparable using the two methods (4.92 +/- 1.01 x 10(4) molecules/ng total genomic DNA using competitive PCR vs 4.90 +/- 0.84 x 10(4) molecules/ng total genomic DNA using real-time PCR), both inter- and intraexperimental variance were significantly lower using the real-time PCR analysis. On the basis of reproducibility, assay complexity, and overall efficiency, including the time requirement and number of PCR reactions necessary for the analysis of a single sample, we recommend the real-time PCR quantification method described here, as its versatility and effectiveness will undoubtedly be of great use in various kinds of research related to mitochondrial DNA damage- and depletion-associated disorders.     

Rapid isolation of DNA probes within specific chromosome regions by interspersed repetitive sequence polymerase chain reaction

A method was recently developed for the specific amplification of human DNA sequences from interspecific somatic cell hybrids by the polymerase chain reaction (PCR) using primers directed to Alu, a short interspersed repeat element (SINE). We now show human-specific amplification using a primer to the 3' end of the human long interspersed repeat element L1Hs (LINE). A monochromosomal hybrid containing an intact human X chromosome yielded approximately 25 discrete products, ranging in size from 800 to 4500 bp. Combination of a single Alu primer and the L1Hs primer yielded a large number of smaller products (300-1000 bp) distinct from those observed with either primer alone. Inspection of ethidium bromide-stained gels showed one Alu-Alu and three Alu-L1Hs products which were present in an intact X chromosome but absent in a hybrid containing an X chromosome deleted for the single metaphase band q28. These four fragments were isolated from the gel and used as probes on Southern blots which confirmed their localization to Xq28. These results demonstrate that primers can be constructed to a variety of interspersed repetitive sequences (IRS) and used individually or in combination for the rapid isolation of DNA fragments from defined chromosomal regions by IRS-PCR.     

HLA-DR typing using DNA amplification by the polymerase chain reaction and sequential hybridization to sequence-specific oligonucleotide probes

A series of sequence-specific oligonucleotides (SSOs) have been used to type alleles at the HLA-DRB1 locus. Genomic DNA was amplified to high copy number by the polymerase chain reaction (PCR) and hybridizations of the dot-blotted, amplified DNA to a series of 14 SSOs enabled the identification of the major specificities DR1-DRw14. Certain alleles (DR3 and DR4) could be rapidly and accurately identified by running the products of allele-specific amplification of genomic DNA on agarose gels. This approach facilitated the typing of serological specificities such as subtypes of DR3 (DRw17 and DRw18) as well as alleles previously detected by the mixed lymphocyte reaction including subtypes of DR4 (Dw4, Dw10, Dw13, Dw14, and Dw15). The HLA-DR types obtained by SSO probing conformed to rules of Mendelian inheritance when they were applied to a series of 75 families. A full DR type could be obtained from many individuals simultaneously without needing to separate or store viable lymphocytes. Thus, this technique may have considerable implications for the analysis of disease associations with HLA class II alleles, particularly in circumstances where facilities for the initial preparation and storage of the samples may be limited.     

Apolipoprotein E genotyping using the polymerase chain reaction and allele-specific oligonucleotide probes

A rapid procedure for determining apolipoprotein E genotype from genomic DNA has been developed. In this procedure, DNA is amplified by the polymerase chain reaction, and allele-specific oligonucleotide probes are used to detect the cysteine-arginine interchanges at residues 112 and 158 that distinguish the three common isoforms of apolipoprotein E. The method was tested with 68 subjects, representing the six common phenotypes, and yielded results consistent with the known phenotype.     

The real-time polymerase chain reaction

The scientific, medical, and diagnostic communities have been presented the most powerful tool for quantitative nucleic acids analysis: real-time PCR [Bustin, S.A., 2004. A-Z of Quantitative PCR. IUL Press, San Diego, CA]. This new technique is a refinement of the original Polymerase Chain Reaction (PCR) developed by Kary Mullis and coworkers in the mid 80:ies [Saiki, R.K., et al., 1985. Enzymatic amplification of beta-globin genomic sequences and restriction site analysis for diagnosis of sickle cell anemia, Science 230, 1350], for which Kary Mullis was awarded the 1993 year's Nobel prize in Chemistry. By PCR essentially any nucleic acid sequence present in a complex sample can be amplified in a cyclic process to generate a large number of identical copies that can readily be analyzed. This made it possible, for example, to manipulate DNA for cloning purposes, genetic engineering, and sequencing. But as an analytical technique the original PCR method had some serious limitations. By first amplifying the DNA sequence and then analyzing the product, quantification was exceedingly difficult since the PCR gave rise to essentially the same amount of product independently of the initial amount of DNA template molecules that were present. This limitation was resolved in 1992 by the development of real-time PCR by Higuchi et al. [Higuchi, R., Dollinger, G., Walsh, P.S., Griffith, R., 1992. Simultaneous amplification and detection of specific DNA-sequences. Bio-Technology 10(4), 413-417]. In real-time PCR the amount of product formed is monitored during the course of the reaction by monitoring the fluorescence of dyes or probes introduced into the reaction that is proportional to the amount of product formed, and the number of amplification cycles required to obtain a particular amount of DNA molecules is registered. Assuming a certain amplification efficiency, which typically is close to a doubling of the number of molecules per amplification cycle, it is possible to calculate the number of DNA molecules of the amplified sequence that were initially present in the sample. With the highly efficient detection chemistries, sensitive instrumentation, and optimized assays that are available today the number of DNA molecules of a particular sequence in a complex sample can be determined with unprecedented accuracy and sensitivity sufficient to detect a single molecule. Typical uses of real-time PCR include pathogen detection, gene expression analysis, single nucleotide polymorphism (SNP) analysis, analysis of chromosome aberrations, and most recently also protein detection by real-time immuno PCR.     

Detection and identification of pathogenic bacteria by polymerase chain reaction with primers from DNA sequence of ribosomal RNA]

Applicability of the polymerase chain reaction method for identification of pathogenic bacteria was examined with the primers synthesized from the ribosomal RNA gene sequence containing both homologous and species-specific regions of bacterial species from Mycoplasma to Mycobacteria. Two out of the nine sets of promoters prepared, each covering about 650 nucleotides spanning from 16S RNA to 23S RNA regions, produced the corresponding DNA fragments from all the strains tested, and another set did so from all species but Mycoplasma. This method enabled one to detect and identify E. coli in a sample containing 2 x 10(2) CFU. The restriction enzyme patterns of the PCR products obtained with Hae-III, Hha-I, Mbo-I, Msp-I, Rsa-I and Taq-I were so characteristic as to differentiate one species from another. Ten strains of E. coli showed identical restriction patterns and 10 of S. aureus also showed identical patterns indicating that the restriction pattern is species-specific. The method may be applicable to detection and identification of a certain species bacteria which are suspected to be consealed in water or food samples, or clinical specimens, especially when the consealed bacterial genus or species can not be predicted.     

Detection of coliform bacteria in water by polymerase chain reaction and gene probes

Polymerase chain reaction (PCR) amplification and gene probe detection of regions of two genes, lacZ and lamB, were tested for their abilities to detect coliform bacteria. Amplification of a segment of the coding region of Escherichia coli lacZ by using a PCR primer annealing temperature of 50 degrees C detected E. coli and other coliform bacteria (including Shigella spp.) but not Salmonella spp. and noncoliform bacteria. Amplification of a region of E. coli lamB by using a primer annealing temperature of 50 degrees C selectively detected E. coli and Salmonella and Shigella spp. PCR amplification and radiolabeled gene probes detected as little as 1 to 10 fg of genomic E. coli DNA and as a few as 1 to 5 viable E. coli cells in 100 ml of water. PCR amplification of lacZ and lamB provides a basis for a method to detect indicators of fecal contamination of water, and amplification of lamB in particular permits detection of E. coli and enteric pathogens (Salmonella and Shigella spp.) with the necessary specificity and sensitivity for monitoring the bacteriological quality of water so as to ensure the safety of water supplies.     

Deletion mutagenesis during polymerase chain reaction: dependence on DNA polymerase

Polymerase chain reaction (PCR) was performed with two polymerases. Thermus aquaticus DNA polymerase (Taq), and modified T7 DNA polymerase (Sequenase). Both polymerases were used to amplify the same portion of the human 18S rRNA gene. We report a PCR artifact, namely a deletion of 54 bp, when Taq polymerase was used to amplify a portion of the human 18S rRNA gene. PCR performed with Sequenase did not produce this artifact. The deletion eliminated a potentially stable hairpin loop. Our data are consistent with the following model for generation of the deletion: (i) the formation of an intrastrand hairpin, and (ii) polymerization across the base of the hairpin, thus deleting the nucleotide sequence in the hairpin. Furthermore, we show that the deletion occurs mainly during synthesis of the (-)DNA strand. Our observations suggest that similar artifacts may occur in other sequences containing stable secondary structures.