Real-time quantitative polymerase chain reaction (QPCR) to identify Myxobolus cerebralis in rainbow trout Oncorhynchus mykiss

This study describes the development of a TaqMan real-time quantitative polymerase chain reaction (QPCR) technique using the heat-shock protein 70 (Hsp 70) and 18S ribosomal DNA (18S rDNA) sequences to identify Myxobolus cerebralis and attempt to quantify infection severity within rainbow trout fry Oncorhynchus mykiss. Rainbow trout for this study were exposed to M. cerebralis under natural river conditions and examined for infection by histology, polymerase chain reaction (PCR) and QPCR analysis at 900 Celsius temperature units (CTUs) following exposure. Detection sensitivity by QPCR was shown to be equal to traditional PCR but greater than histopathology. Primer/probe combinations developed for this study were capable of specifically detecting M. cerebralis DNA in infected fish tissue and single triactinomyxon (TAM) spores with a sensitivity of 12.5 and 6.3 pg microl(-1) of DNA for the Hsp 70 and 18S rDNA sequences, respectively. A strong relationship between QPCR and infection severity was found for the Hsp 70 probe when parasite copy number and histology scores of 0-4 were compared (R2 = 0.96, p = 0.003). However, a reduction in copy number was observed at higher histology scores for the 18S probe (scores of 4 and 5) and the Hsp 70 probe (score of 5). The results of this study demonstrate that QPCR analysis is an effective tool for detecting M. cerebralis in fish tissue and may provide a relative indication of infection severity.     

Theoretical uncertainty of measurements using quantitative polymerase chain reaction.

Current quantitative polymerase chain reaction (PCR) protocols are only indicative of the quantity of a target sequence relative to a standard, because no means of estimating the amplification rate is yet available. The variability of PCR performed on isolated cells has already been reported by several authors, but it could not be extensively studied, because of lack of a system for doing kinetic data acquisition and of statistical methods suitable for analyzing this type of data. We used the branching process theory to simulate and analyze quantitative kinetic PCR data. We computed the probability distribution of the offspring of a single molecule. We demonstrated that the rate of amplication has a severe influence on the shape of this distribution. For high values of the amplification rate, the distribution has several maxima of probability. A single amplification trajectory is used to estimate the initial copy number of the target sequence as well as its confidence interval, provided that the amplification is done over more than 20 cycles. The consequence of possible molecular fluctuations in the early stage of amplification is that small copy numbers result in relatively larger intervals than large initial copy numbers. The confidence interval amplitude is the theoretical uncertainty of measurements using quantitative PCR. We expect these results to be applicable to the data produced by the next generation of thermocyclers for quantitative applications.     

New buffers to improve the quantitative real-time polymerase chain reaction

Real-time PCR is a potent technique for nucleic acid quantification for research and diagnostic purposes, the wide dynamic range being one of the advantages over other techniques like the microarray. Several additives and enhancers have been studied to expand the PCR dynamic range in order to be more efficient in quantifying low quantities of nucleic acids, increase the yield and improve reaction efficiency. Shown here is that a combination of new buffers with the regularly used Tris buffer makes it possible to expand the real-time PCR dynamic range and to improve the efficiency and correlation coefficient. Mixing HEPES, TEA or MOPS with Tris was more efficient than Tris alone. It was also found that, if the pH value of the Tris buffer was calibrated with phosphoric acid instead of hydrochloric acid, then the dynamic range was significantly improved and low quantities could be detected and quantified more efficiently. Mixing more than one compound with the Tris buffer was also effective for expanding the dynamic range and increasing the efficiency and correlation coefficient in quantitative real-time PCR.     

Rapid titer determination of baculovirus by quantitative real-time polymerase chain reaction

Titer determination is a prerequisite for the study of viruses. However, the current available methods are tedious and time-consuming. To improve the efficiency of titer determination, we have developed a rapid and simple method for the routine detection of baculovirus titers using a quantitative real-time PCR. This method is based on the amplification of approximately 150-bp fragments located in the coding regions of selected genes. The PCR was found to be quantitative in a range of 10(3) to 10(9) virus particles per 200 microL of supernatant, and the results were closely correlated with titers detected from 50% tissue culture infectious doses (TCID(50)) of baculovirus. This quantitative real-time PCR requires only 30 min to perform, and the entire titer determination can be accomplished within 1 h without the need for cell seeding or further virus dilution and infection. Because this technology is easy to operate, generates data with high precision, and most importantly is very quick, it will certainly be broadly applied for titer determination of baculoviruses in the future.     

Comparison of proteases in DNA extraction via quantitative polymerase chain reaction

We compared four proteases in the QIAamp DNA Investigator Kit (Qiagen) to extract DNA for use in multiplex polymerase chain reaction (PCR) assays. The aim was to evaluate alternate proteases for improved DNA recovery as compared with proteinase K for forensic, biochemical research, genetic paternity and immigration, and molecular diagnostic purposes. The Quantifiler Kit TaqMan quantitative PCR assay was used to measure the recovery of DNA from human blood, semen, buccal cells, breastmilk, and earwax in addition to low-template samples, including diluted samples, computer keyboard swabs, chewing gum, and cigarette butts. All methods yielded amplifiable DNA from all samples.     

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.     

Detecting and resolving position-dependent temperature effects in real-time quantitative polymerase chain reaction

Real-time quantitative polymerase chain reaction (qPCR) depends on precise temperature control of the sample during cycling. In the current study, we investigated how temperature variation in plate-based qPCR instruments influences qPCR results. Temperature variation was measured by amplicon melting analysis as a convenient means to assess well-to-well differences. Multiple technical replicates of several SYBR Green I-based qPCR assays allowed correlation of relative well temperature to quantification cycle. We found that inadequate template denaturation results in an inverse correlation and requires increasing the denaturation temperature, adding a DNA destabilizing agent, or pretreating with a restriction enzyme. In contrast, inadequate primer annealing results in a direct correlation and requires lowering the annealing temperature. Significant correlations were found in 18 of 25 assays. The critical nature of temperature-dependent effects was shown in a blinded study of 29 patients for the diagnosis of Prader–Willy and Angelman syndromes, where eight diagnoses were incorrect unless temperature-dependent effects were controlled. A method to detect temperature-dependent effects by pairwise comparisons of replicates in routine experiments is presented and applied. Systematic temperature errors in qPCR instruments can be recognized and their effects eliminated when high precision is required in quantitative genetic diagnostics and critical complementary DNA analyses.     

Analysis of gene-specific DNA damage and repair using quantitative polymerase chain reaction

Soon after discovery of the polymerase chain reaction (PCR), various laboratories have attempted to use quantitative PCR (QPCR) to detect DNA damage in specific gene segments. The development of techniques that facilitate long PCR increased the sensitivity of the assay so that biologically relevant doses of DNA-damaging agents could be assessed. QPCR has been used to survey DNA damage induced by different genotoxicants and to establish the repair kinetics of numerous genes. Current work seeks to analyze damage and repair in specific genes from animals exposed to specific DNA-damaging agents such as oxidative stress.