Quantification of Escherichia coli genomic DNA contamination in recombinant protein preparations by polymerase chain reaction and affinity-based collection

This study describes the development of a novel assay for the quantification of Escherichia coli genomic DNA contamination in recombinant protein samples. The technique is based on PCR amplification and digoxygenin labeling of the genes encoding 5S ribosomal RNA followed by affinity-based collection and detection. Samples containing 1 pg x mL(-1) of extracted E. coli genomic DNA (gDNA) could be measured using this method. Using extracted E. coli gDNA as standards, a 35-cycle PCR reaction exhibited a linear response versus template concentration between 1 pg x mL(-1) and1 ng x mL(-1) genomic DNA even when diluted in a variety of buffering conditions. Comparison of the novel assay with a traditional filter binding and hybridization technique using recombinant protein samples confirmed that the procedure was accurate and sensitive. The assay described in this report is a safer and less expensive alternative to radioactive techniques employed for DNA quantification, utilizing readily available reagents and apparatus.     

Fast quantification of nucleic acid hybrids by affinity-based hybrid collection.

A hybridization technique for the quantification of nucleic acids is described. In the method a probe pair is allowed to form hybrids with the target nucleic acid in solution. One of the probes has been modified with an affinity label, by which the formed hybrids can be isolated after the reaction. Streptavidin-agarose was used to capture hybrids containing biotinylated DNA. The hybrids were measured using radioiodine as label on the second probe. The rate of the hybridization reaction in solution is fast, allowing the whole procedure to be carried out in 3 h. The method is quantitative with a detection limit of 4 X 10(5) molecules (0.67 attomoles) target DNA. The test is insensitive to impurities in biological samples, which are analyzed without purification of the target DNA. Non-isotopic measurement of the hybrids can also be applied. In this case the hybrids are bound to microtitration wells and detected spectrophotometrically by peroxidase-catalyzed colour development.     

Quantification of DNA sequences obtained by polymerase chain reaction using a bioluminescent adsorbent.

We studied various parameters affecting the sensitivity of assays that use nucleic acid hybridization in solution followed by capture of the hybrid on a solid phase. Sensitivity is limited not only by nonspecific binding of the detection components but also by reannealing of the target or probe to itself. To perform sensitive assays, the probe concentration must be low enough to reduce high nonspecific binding. Under these conditions, however, the strand displacement reaction or the reannealing of the target to itself drastically decreases the hybridization yield, particularly when the target and the probes are different sizes. To improve DNA detection, we propose a sandwich method based on hybridization of oligonucleotides with a single-strand DNA obtained by polymerase chain reaction under asymmetric conditions. The assay can be performed in one step using a bioluminescent detection procedure which does not require any separation step. The specificity of the method is sufficient to perform a rapid detection and quantification of papillomavirus in biological samples.     

Quantification of gene expression over a wide range by the polymerase chain reaction.

We investigated the usefulness of the polymerase chain reaction (PCR) method for the relative quantification of gene expression using a simultaneously amplified sequence of beta-actin mRNA as an internal control for the target sequence of tax/rex mRNA of human T-cell leukemia virus type I. The PCR product of the internal control was reduced by delaying the addition of the primers for its sequence. The photostimulated luminescence of the bands was measured with a laser image analyzer, and the values were plotted against the cycle number. The cycle differences between the logarithmic phase of the curves for the target sequence and for beta-actin (delta cycle) showed a linear correlation with the initial concentration of the sample. This method is highly sensitive for evaluating gene expression over a wide range.     

Universal CG cloning of polymerase chain reaction products

Single-insert cloning of DNA fragments without restriction enzymes has traditionally been achieved using TA cloning, with annealing of a polymerase chain reaction (PCR) fragment containing a single overhanging 3′ A to a plasmid vector containing a 3′ T. In this article, we show that the analogous “CG cloning” is faster and far more efficient, using AhdI to generate a C-vector. For an afternoon ligation, CG cloning achieved double the cloning efficiency and more than 4-fold the number of transformants compared with TA cloning. However, blunt-end ligation was markedly more efficient than both. CG cloning could prove to be extremely useful for single-copy high-throughput cloning.     

Quantification of Leishmania infantum parasites in tissue biopsies by real-time polymerase chain reaction and polymerase chain reaction-enzyme-linked immunosorbent assay

Most of the experimental studies of Leishmania spp. infection require the determination of the parasite load in different tissues. Quantification of parasites by microscopy is not very sensitive and is time consuming, whereas culture microtitrations remain laborious and can be jeopardized by microbial contamination. The aim of this study was to quantify Leishmania infantum parasites by real-time polymerase chain reaction (PCR) using specific DNA TaqMan probes and to compare the efficacy of detection of this technique with a PCR-enzyme-linked immunosorbent assay (ELISA). For this purpose, spleen and liver samples from L. infantum-infected mice were collected during a 3-mo longitudinal study and analyzed by both methods. PCR-ELISA failed to quantify Leishmania spp. DNA in samples with very low or very high numbers of parasites. Real-time PCR was more sensitive than PCR-ELISA, detecting down to a single parasite, and enabled the parasite quantification over a wide, 5-log range. In summary, this study developed a method for absolute quantification of L. infantum parasites in infected organs using real-time TaqMan PCR.     

Mutation detection by denaturing DNA chromatography using fluorescently labeled polymerase chain reaction products.

A specialized form of ion-pair reversed-phase high-performance liquid chromatography is gaining widespread application in mutation detection for single nucleotide polymorphisms (SNP). The technique relies on temperature-modulated heteroduplex analysis (TMHA) by chromatographic separation of partially denatured DNA heteroduplexes from homoduplexes. Here, we demonstrate that fluorescent labeling is compatible with mutation analysis by this form of DNA chromatography and offers advantages over the use of unlabeled DNA fragments. Uniform labeling of wild-type and mutant alleles for TMHA yields peak patterns identical to unlabeled fragments. However, fluorescent labels increase retention times but do not influence resolution of heteroduplexes from homoduplexes. They increase sensitivity and decrease the amount of DNA required for analysis; e.g., in the case presented here, one allele can be detected in the presence of a 500-fold excess of another allele. Furthermore, allele-specific wild-type probes, fluorescently labeled on one strand only, make it possible to selectively monitor specific homoduplexes and wild-type/mutant heteroduplexes. This, in combination with an internal homoduplex standard, greatly reduces the complexity of fluorescence chromatograms compared with chromatograms recorded in the UV. These simplified chromatograms, in which only the internal homoduplex standard and the labeled heteroduplex are detected in the presence of a mutation, greatly facilitate the detection and identification of mutant alleles.     

Quantitation and purification of polymerase chain reaction products by high-performance liquid chromatography

This work describes the application of the fully automated high-performance liquid chromatographic system to the analysis of PCR-amplified products. Efficient separations of both DNA restriction fragments and PCR products were performed using an anion-exchange DEAE-NPR column, packed with 2.5-μm nonporous particles. The automated HPLC method was employed for the separation, quantitation, and purification of PCR products in less than 10 min in a single step.     

Computing by polymerase chain reaction

A mathematical notation is introduced to represent, at a symbolic level, different mechanisms of DNA recombination, and a 'PCR lemma' is proven by analytically describing the combinatorial properties of the polymerase chain reaction process. This approach led to the discovery of novel techniques, based on a form of PCR which we called cross pairing PCR (briefly XPCR). They were mathematically analyzed and already experimentally proven in different contexts, such as DNA extraction and recombination. Thus, a mathematical analysis of standard methodologies may highlight novel mechanisms of DNA recombination and this can provide new technologies for DNA manipulation.     

Quantitation of polymerase chain reaction products by capillary electrophoresis using laser fluorescence

In samples where the amount of DNA is limited, the polymerase chain reaction (PCR) can amplify specific regions of the DNA. A quantitative analysis of the PCR product would be desirable to ensure sufficient DNA is available for analysis. In this study, we examine the use of capillary electrophoresis (CE) with laser fluorescence detection for quantitation of PCR products. A coated open tubular capillary was used with a non-gel sieving buffer and a fluorescent intercalating dye to obtain results within 20 minutes. Using an internal standard, peak migration time was below 0.1% relative standard deviation (R.S.D.) with a peak area precision of 3% R.S.D. In comparison to quantitation by hybridization, (i.e., slot blot) and spectrophotometric analysis, capillary electrophoresis shows distinct advantages due to its ability to separate unincorporated primers and PCR byproducts from the targeted PCR product. The results demonstrate that CE can be used to monitor the quality and quantity of the PCR product.     

Gene walking using sequential hybrid primer polymerase chain reaction

We developed a simple and robust method for removing nonspecific amplification produced during gene walking with a gene-specific primer and a degenerate primer. The primary walking polymerase chain reaction (PCR) was followed by two or three PCR rounds, each incorporating a low concentration of a reverse hybrid primer, where the 3′ end was bound to a target sequence generated in the preceding PCR round and the 5′ end was a new sequence that generated a target sequence for the next PCR round. The low concentration of the hybrid primer and the extent of amplicon stem-loop formation inhibited nonspecific amplification and enabled successful walking along three genes.     

Frankia genus-specific characterization by polymerase chain reaction.

The polymerase chain reaction (PCR) is an in vitro procedure for primer-directed enzymatic amplification of specific template nucleic acid sequences. In order to determine whether a given actinomycete isolated from an actinorhiza (nodule) belongs to the genus Frankia or is a contaminant, we have developed a test based on the PCR. Primers complementary to sequences of two DNA regions corresponding to the nif genes (nifH and nifD) and the rRNA genes (16S and 23S) were specifically chosen to differentially amplify DNAs from Frankia strains but not those from other microorganisms. A series of positive and negative controls were set up by using universal or selective primers resulting in a discriminant amplification, which could be detected after agarose gel electrophoresis. In the nif region, degenerate oligonucleotide primers were used to amplify a target common to all the nitrogen-fixing microorganisms tested, while another set of primers amplified a target with a high specificity for Frankia strains. In the rRNA gene region, universal and specific primers were characterized and tested with DNAs from a wide range of microorganisms. The efficiency of this rapid and sensitive PCR assay was tested with an isolate obtained from Alnus nepalensis nodules, confirming results obtained by nodulation tests.     

Frankia genus-specific characterization by polymerase chain reaction.

The polymerase chain reaction (PCR) is an in vitro procedure for primer-directed enzymatic amplification of specific template nucleic acid sequences. In order to determine whether a given actinomycete isolated from an actinorhiza (nodule) belongs to the genus Frankia or is a contaminant, we have developed a test based on the PCR. Primers complementary to sequences of two DNA regions corresponding to the nif genes (nifH and nifD) and the rRNA genes (16S and 23S) were specifically chosen to differentially amplify DNAs from Frankia strains but not those from other microorganisms. A series of positive and negative controls were set up by using universal or selective primers resulting in a discriminant amplification, which could be detected after agarose gel electrophoresis. In the nif region, degenerate oligonucleotide primers were used to amplify a target common to all the nitrogen-fixing microorganisms tested, while another set of primers amplified a target with a high specificity for Frankia strains. In the rRNA gene region, universal and specific primers were characterized and tested with DNAs from a wide range of microorganisms. The efficiency of this rapid and sensitive PCR assay was tested with an isolate obtained from Alnus nepalensis nodules, confirming results obtained by nodulation tests.     

Quantification of airborne Aspergillus fumigatus spores in rabbit houses by real-time polymerase chain reaction

To accurately quantify airborne Aspergillus fumigatus (A. fumigatus) spores in rabbit houses, the real-time polymerase chain reaction (real-time PCR) and culture-based counting method (CCM) were employed to determine the airborne A. fumigatus spore concentrations. The results showed that, of the three rabbit houses (A, B, and C), the average concentrations of airborne A. fumigatus spores determined by real-time PCR were 3.0 × 10³, 3.3 × 10³, and 1.5 × 10³ spores/m³ air, respectively, while those determined by CCM were 2.5 × 10², 2.8 × 10², and 1.1 × 10² colony-forming unit/m³ air (CFU/m³ air), respectively, i.e., the former concentration was 12–14 times higher than the latter one. Therefore, the conventional CCM underestimated the concentrations of airborne fungal spores, and it is insufficient to determine the microbial aerosol concentration and evaluate the health risk only using CCM.     

Preparative isolation of polymerase chain reaction products using mixed-mode chromatography

The polymerase chain reaction (PCR) has become one of the most useful techniques in molecular biology laboratories around the world. The purification of the target DNA product is often challenging, however, and most users are restricted to employing available commercial kits. The recent developments in mixed-mode chromatography have shown higher selectivity for a variety of nucleic acid-containing samples. Capto Adhere is a mixed-mode chromatography resin that offers a high-selectivity ligand and is here applied for the purification of amplified DNAs from PCR mixtures in a 10-min single step, with yields above 95%, high linearity, and high precision for different concentrations.