Sensitive single-stage PCR using custom-synthesized internal controls

A new approach for an internally controlled PCR was developed using a custom-synthesized oligonucleotide as the internal control. Three different PCR setups demonstrated the usefulness of this approach: (i) the addition of the respective internal control to samples containing ssDNA virus Parvo B19; (ii) the co-extraction of plasma samples and the respective internal control for the detection of the ssDNA virus TTV; and (iii) the addition of the respective internal control to a crude lysate of tail pieces for the genotyping of FVIII knockout mice, demonstrating that this approach is also applicable for dsDNA.     

荧光定量PCR测定端粒长度

目的应用实时荧光定量聚合酶链式反应（Q—PCR）方法测定端粒长度。方法选取9种人类细胞株,提取基因组DNA,采用Q—PCR方法测定相对T／S比率,DNA印迹法测定末端限制性片段（TRF）长度,进行二者之间的相关性分析。结果定量PCR测定端粒长度相对T／S比率为0．68±0．57,DNA印迹法测量平均TRF值为8．57±2．34,两种方法测定结果的相关性分析R2=0．7807（P〈0．01）。结论采用荧光定量PCR方法测量端粒长度具有重复性好、省时、简便、可靠的特点,可高通量处理大量样品。     

Detection of Phytophthora nicotianae in Soil with Real-time Quantitative PCR

Phytophthora nicotianae is one of the most important soil-borne plant pathogens. A rapid, specific and sensitive real-time polymerase chain reaction (PCR) detection method for P. nicotianae was established, which used primers targeting the internal transcribed spacer (ITS) regions of rDNA genes of Phytophthora spp. Based on the nucleotide sequences of ITS2 of 15 different species of Phytophthora , the primers and probe were designed specifically to amplify DNA from P. nicotianae. With a series of 10-fold DNA dilutions extracted from P. nicotianae pure cultures, the detection limit was 10 pg/μl in conventional PCR, whereas in SYBR Green I PCR the detection limit was 0.12 fg/μl and in TaqMan PCR 1.2 fg/μl, and real-time PCR was 10⁴–10⁵ times more sensitive than conventional PCR. The simple and rapid procedures maximized the yield and quality of recovered DNA from soil and allowed the processing of many samples in a short time. The direct DNA extractions from soil were utilized to yield DNA suitable for PCR. By combining this protocol with the real-time PCR procedure it has been possible to specifically detect P. nicotianae in soil, and the degree of sensitivity was 1.0 pg/μl. The system was applied to survey soil samples from tobacco field sites in China for the presence of P. nicotianae and the analyses of naturally infested soil showed the reliability of the real-time PCR method.     

Quantitative PCR: Procedures and precisions

We develop a multitype branching-process model for the Polymerase Chain Reaction (PCR). We apply the model to a comparison of three methods for estimating the initial number of molecules of target present in a PCR. These three methods are: one which uses a coamplified, internal control; one which uses an external control series; and one which uses simple extrapolation of log outputvs time (no control). We identify assumptions for each method which permit mathematical analysis of bias and precision. All three methods perform well if: (1) replication efficiencies are stable among reactions; (2) other method-specific conditions on efficiencies are met; and (3) product accumulates exponentially throughout the range where it is observed. When replication efficiencies vary among reactions but other optimal conditions for each method hold, the no-control and external-control methods lose precision relative to the internal control method, but they may still perform satisfactorily for many applications. The internal control method continues to perform well even if accumulation of product plateaus. This method depends, however, on a condition we call equivalence of replication efficiencies, the attainability of which in practice remains to be proven.     

实时定量PCR技术及其应用

实时定量PCR(Real—time Quantitative Polymerase Chain Reaction,RQ—PCR)技术是20世纪90年代中期发展起来的一种新型核酸定量技术。该技术具有实时监测、快速、灵敏、精确等特点,是对原有PCR技术的革新,扩大了PCR的应用范围。本文综述了RQ—PCR技术的原理、RQ—PCR仪、RQ—PCR实时定量检测系统及其应用。     

添加有扩增内标的副溶血弧菌PCR检测方法

【目的】发掘副溶血弧菌特异性更强的检测靶点,并人工构建扩增内标,建立可以有效避免假阴性的新PCR检测体系。【方法】利用生物信息学方法,从副溶血弧菌(Vibrio parahaemolyticus)基因组DNA中发掘特异性很高的序列,并设计相应的特异性引物,人工构建扩增内标,建立PCR检测体系。【结果】本研究发掘得到的序列vp1332特异性很强,经检索,该序列是编码ABC转运子接合蛋白组分的基因片段,根据此序列设计一对特异检测引物(vp1332L/vp1332R),同时,构建了扩增内标,并建立了PCR检测体系。利用该体系对296株副溶血弧菌和33株非副溶血弧菌进行检测,结果显示,所有以副溶血弧菌为模板的PCR反应均可扩增到一条343bp的特异片段,而模板来源于非副溶血弧菌的则只能扩增到一条499bp的扩增内标片段。灵敏度实验表明,该PCR反应体系的检测灵敏度为1.6×102cfu/mL。人工污染实验表明,起始染菌量为1.24cfu/25g样品时经8h增菌,即可检测到副溶血弧菌。实际样品检测结果也证实该方法的有效性。【结论】本研究建立的PCR反应体系能特异地检测副溶血弧菌,并可有效地排除假阴性,提高检测准确率。     

Quantitative PCR in the diagnosis of Leishmania

Polymerase chain reaction (PCR) is a sensitive and rapid method for the diagnosis of canine Leishmania infection and can be performed on a variety of biological samples, including peripheral blood, lymph node, bone marrow and skin. Standard PCR requires electrophoretic analysis of the amplification products and is usually not suitable for quantification of the template DNA (unless competitor-based or other methods are developed), being of reduced usefulness when accurate monitoring of target DNA is required. Quantitative real-time PCR allows the continuous monitoring of the accumulation of PCR products during the amplification reaction. This allows the identification of the cycle of near-logarithmic PCR product generation (threshold cycle) and, by inference, the relative quantification of the template DNA present at the start of the reaction. Since the amplification product are monitored in "real-time" as they form cycle-by-cycle, no post-amplification handling is required. The absolute quantification is performed according either to an internal standard co-amplified with the sample DNA, or to an external standard curve obtained by parallel amplification of serial known concentrations of a reference DNA sequence. From the quantification of the template DNA, an estimation of the relative load of parasites in the different samples can be obtained. The advantages compared to standard and semi-quantitative PCR techniques are reduction of the assay's time and contamination risks, and improved sensitivity. As for standard PCR, the minimal components of the quantitative PCR reaction mixture are the DNA target of the amplification, an oligonucleotide primer pair flanking the target sequence, a suitable DNA polymerase, deoxynucleotides, buffer and salts. Different technologies have been set up for the monitoring of amplification products, generally based on the use of fluorescent probes. For instance, SYBR Green technology is a non-specific detection system based on a fluorescent dsDNA intercalator and it is applicable to all potential targets. TaqMan technology is more specific since performs the direct assessment of the amount of amplified DNA using a fluorescent probe specific for the target sequence flanked by the primer pair. This probe is an oligonucleotide labelled with a reporter dye (fluorescent) and a quencher (which absorbs the fluorescent signal generated by the reporter). The thermic protocol of amplification allows the binding of the fluorescent probe to the target sequence before the binding of the primers and the starting of the polymerization by Taq polymerase. During polymerization, 5'-3' exonuclease activity of Taq polymerase digests the probe and in this way the reporter dye is released from the probe and a fluorescent signal is detected. The intensity of the signal accumulates at the end of each cycle and is related to the amount of the amplification product. In recent years, quantitative PCR methods based either on SYBR Green or TaqMan technology have been set up for the quantification of Leishmania in mouse liver, mouse skin and human peripheral blood, targeting either single-copy chromosomal or multi-copy minicircle sequences with high sensitivity and reproducibility. In particular, real-time PCR seems to be a reliable, rapid and noninvasive method for the diagnosis and follow up of visceral leishmaniasis in humans. At present, the application of real-time PCR for research and clinical diagnosis of Leishmania infection in dogs is still foreseable. As for standard PCR, the high sensitivity of real-time PCR could allow the use of blood sampling that is less invasive and easily performed for monitoring the status of the dogs. The development of a real-time PCR assay for Leishmania infantum infection in dogs could support the standard and optimized serological and PCR methods currenly in use for the diagnosis and follow-up of canine leishmaniasis, and perhaps prediction of recurrences associated with tissue loads of residual pathogens after treatment. At this regard, a TaqMan Real Time PCR method developed for the quantification of Leishmania infantum minicircle DNA in peripheral blood of naturally infected dogs sampled before and at different time points after the beginning of a standard antileishmanial therapy will be illustrated.     

Quantitative PCR in EBV-infected renal transplant patients

In this study we investigated the levels of Epstein Barr virus (EBV) DNA by quantitative polymerase chain reaction (Q-PCR) in serum, whole blood and peripheral blood mononuclear cells (PBMC) from anti-EA IgG seropositive or anti-EA IgG seronegative EBV infected renal transplant recipients. We compared serological data with the viral load to monitor the risk of developing post-transplant lymphoproliferative disorders (PTLD). All patients were asymptomatic and none of them developed PTLD at the time of the study. EBV DNA quantitation for each patient varied in whole blood and PBMC samples probably due to different numbers of mononuclear cells present in samples from which DNA was extracted (whole blood vs. purified PBMC). In 92% of the serum samples EBV DNA was undetectable probably due to absence of free genomes since the number of DNA copies detected in samples from whole blood and PBMC does not reach very high levels. The correlation between the presence of EA-antibody, considered serological evidence of EBV reactivation, and the viral load showed that 60% of EA-positive patients had quantifiable EBV DNA, whereas in 40% of EA-positive patients EBV DNA was undetectable, showing serological reactivity but no viral replication. Of the remaining EA-negative patients, EBV DNA could be detected in 71% of them, whereas 29% did not show EBV DNA, indicating no EBV replication. In conclusion, our results confirm that the presence of serum IgG anti-EA antibody is not a reliable marker of active EBV infection whereas the evaluation of the viral load in blood samples is a useful diagnostic tool to monitor and to better understand the course of EBV infection in immunocompromised renal transplant patients at risk of developing PTLD.     

Quantitative detection of periodontopathogens by real-time PCR

Specific bacteria are believed to play an important role in chronic periodontitis, yet the significance of their relative numbers in initiation and progress of the disease is still unclear. We report here the development of a sensitive, quantitative PCR technique for enumerating Actinobacillus actinomycetemcomitans (Aa), Porphyromonas gingivalis (Pg), Prevotella intermedia (Pi), Dialister pneumosintes (Dp) and Micromonas micros (Mm) as well as total eubacteria in subgingival plaque samples from subjects with periodontitis. Quantification was performed with specific 16S rRNA target sequences with double fluorescence labeled probes and serial dilutions of plasmid standard by real-time PCR. This method showed a broad quantification range from 10(2) to 10(8) and accurate sensitivity and specificity. Fifty subgingival plaque samples from periodontitis patients and 33 from periodontally healthy subjects were subsequently examined. Higher levels of total bacteria numbers, Aa, Pg, Dp and Mm were found in samples from periodontitis subjects in comparison to samples from periodontally healthy subjects. Quantitative real-time PCR thus provides a reliable and valuable method for quantification of periodontopathogens in subgingival plaque samples.     

A Mechanistic Model of PCR for Accurate Quantification of Quantitative PCR Data

Background

Quantitative PCR (qPCR) is a workhorse laboratory technique for measuring the concentration of a target DNA sequence with high accuracy over a wide dynamic range. The gold standard method for estimating DNA concentrations via qPCR is quantification cycle () standard curve quantification, which requires the time- and labor-intensive construction of a standard curve. In theory, the shape of a qPCR data curve can be used to directly quantify DNA concentration by fitting a model to data; however, current empirical model-based quantification methods are not as reliable as standard curve quantification.

Principal Findings

We have developed a two-parameter mass action kinetic model of PCR (MAK2) that can be fitted to qPCR data in order to quantify target concentration from a single qPCR assay. To compare the accuracy of MAK2-fitting to other qPCR quantification methods, we have applied quantification methods to qPCR dilution series data generated in three independent laboratories using different target sequences. Quantification accuracy was assessed by analyzing the reliability of concentration predictions for targets at known concentrations. Our results indicate that quantification by MAK2-fitting is as reliable as standard curve quantification for a variety of DNA targets and a wide range of concentrations.

Significance

We anticipate that MAK2 quantification will have a profound effect on the way qPCR experiments are designed and analyzed. In particular, MAK2 enables accurate quantification of portable qPCR assays with limited sample throughput, where construction of a standard curve is impractical.