A method for quantification of absolute amounts of nucleic acids by (RT)-PCR and a new mathematical model for data analysis

Accurate quantification of nucleic acids by competitive (RT)-PCR requires a valid internal standard, a reference for data normalization and an adequate mathematical model for data analysis. We report here an effective procedure for the generation of homologous RNA internal standards and a strategy for synthesizing and using a reference target RNA in quantification of absolute amounts of nucleic acids. Further, a new mathematical model describing the general kinetic features of competitive PCR was developed. The model extends the validity of quantitative competitive (RT)-PCR beyond the exponential phase. The new method eliminates the errors arising from different amplification efficiencies of the co-amplified sequences and from heteroduplex formation in the system. The high accuracy (relative error <2%) is comparable to the recently developed real time detection 5'-nuclease PCR. Also, corresponding computer software has been devised for practical data analysis.     

A method for quantification of absolute amounts of nucleic acids by (RT)–PCR and a new mathematical model for data analysis

Accurate quantification of nucleic acids by competitive (RT)–PCR requires a valid internal standard, a reference for data normalization and an adequate mathematical model for data analysis. We report here an effective procedure for the generation of homologous RNA internal standards and a strategy for synthesizing and using a reference target RNA in quantification of absolute amounts of nucleic acids. Further, a new mathematical model describing the general kinetic features of competitive PCR was developed. The model extends the validity of quantitative competitive (RT)–PCR beyond the exponential phase. The new method eliminates the errors arising from different amplification efficiencies of the co-amplified sequences and from heteroduplex formation in the system. The high accuracy (relative error <2%) is comparable to the recently developed real time detection 5′-nuclease PCR. Also, corresponding computer software has been devised for practical data analysis.     

Real-time PCR for mRNA quantitation

Real-time PCR has become one of the most widely used methods of gene quantitation because it has a large dynamic range, boasts tremendous sensitivity, can be highly sequence-specific, has little to no post-amplification processing, and is amenable to increasing sample throughput. However, optimal benefit from these advantages requires a clear understanding of the many options available for running a real-time PCR experiment. Starting with the theory behind real-time PCR, this review discusses the key components of a real-time PCR experiment, including one-step or two-step PCR, absolute versus relative quantitation, mathematical models available for relative quantitation and amplification efficiency calculations, types of normalization or data correction, and detection chemistries. In addition, the many causes of variation as well as methods to calculate intra- and inter-assay variation are addressed.     

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.     

Characterization of the universal Russian reagent sets for real-time PCR and its application for molecular oncodiagnostic

Universal Russian reagents for real time PCR were tested and compared with reference reagents provided by foreign companies. Testing was carried out on plasmids with cloning fragments (DNA-standards) of cDNA with chimeric (fusion) gene PML-RARalpha. Values of amplification efficiency of Russian and foreign reagents were measured on samples with serial dilutions (30-300000 copies) of cloned cDNA fragments of PML-RARalpha and internal control gene ABL. Amplification efficiencies of Russian and foreign reagents were found to be close one to another. Russian universal reagent kit RealityTM and ABI TaqMan Core Reagent Kit have amplification efficiencies 1.919 and 1.929, and correlation coefficients of copy numbers PML-RARalpha0.999 and 0.996, respectively. These values were determined by construction of a standard curve. To verify these results we studied also the samples of cDNA from blood and bone marrow of patients with acute promyelocytic leukemia. All samples posses translocation t(15;17), and appropriate chimeric gene PML-RARalpha. copy number in 1 microg of total RNA was in range 5.86 x 10(4)-8.315 x 10(5) before chemotherapy. No symptoms of minimal residual disease were found after 3.5 months since chemotherapy - fusion gene PML-RARalpha was not detected by real time PCR method. These results are in agreement with clinical data. Our investigations tend to show that application of RealityTM reagent set in real timePCR experiments gives correct results and may be used in molecular oncodiagnostics.     

Revisiting the sigmoidal curve fitting applied to quantitative real-time PCR data

Amplification of a cDNA product by quantitative polymerase chain reaction (qPCR) gives rise to fluorescence sigmoidal curves from which absolute or relative target gene content of the sample is inferred. Besides comparative C(t) methods that require the construction of a reference standard curve, other methods that focus on the analysis of the sole amplification curve have been proposed more recently. Among them, the so-called sigmoidal curve fitting (SCF) method rests on the fitting of an empirical sigmoidal model to the experimental amplification data points, leading to the prediction of the amplification efficiency and to the calculation of the initial copy number in the sample. The implicit assumption of this method is that the sigmoidal model may describe an amplification curve quantitatively even in the portion of the curve where the fluorescence signal is hidden in the noise band. The theoretical basis of the SCF method was revisited here for defining the class of experimental amplification curves for which the method might be relevant. Applying the SCF method to six well-characterized different PCR assays illustrated possible pitfalls leading to biased estimates of the amplification efficiency and, thus, of the target gene content of a sample.     

Quantitative biomarker analysis of synovial gene expression by real-time PCR

Synovial biomarker analysis in rheumatoid arthritis can be used to evaluate drug effect in clinical trials of novel therapeutic agents. Previous studies of synovial gene expression for these studies have mainly relied on histological methods including immunohistochemistry and in situ hybridization. To increase the reliability of mRNA measurements on small synovial tissue samples, we developed and validated real time quantitative PCR (Q-PCR) methods on biopsy specimens. RNA was isolated from synovial tissue and cDNA was prepared. Cell-based standards were prepared from mitogen-stimulated peripheral blood mononuclear cells. Real time PCR was performed using TaqMan chemistry to quantify gene expression relative to the cell-based standard. Application of the cellular standard curve method markedly reduced intra- and inter-assay variability and corrected amplification efficiency errors compared with the C(t) method. The inter-assay coefficient of variation was less than 25% over time. Q-PCR methods were validated by demonstrating increased expression of IL-1β and IL-6 expression in rheumatoid arthritis synovial samples compared with osteoarthritis synovium. Based on determinations of sampling error and coefficient of variation, twofold differences in gene expression in serial biopsies can be detected by assaying approximately six synovial tissue biopsies from 8 to 10 patients. These data indicate that Q-PCR is a reliable method for determining relative gene expression in small synovial tissue specimens. The technique can potentially be used in serial biopsy studies to provide insights into mechanism of action and therapeutic effect of new anti-inflammatory agents.     

New insights into the de novo gene synthesis using the automatic kinetics switch approach

Here we present a simple, highly efficient, universal automatic kinetics switch (AKS) gene synthesis method that enables synthesis of DNA up to 1.6 kbp from 1 nM oligonucleotide with just one polymerase chain reaction (PCR) process. This method eliminates the interference between the PCR assembly and amplification in one-step gene synthesis and simultaneously maximizes the amplification of emerged desired DNA by using a pair of flanked primers. In addition, we describe an analytical model of PCR gene synthesis based on the thermodynamics and kinetics of DNA hybridization. The kinetics difference between standard PCR amplification and one-step PCR gene synthesis is analyzed using this model and is validated using real-time gene synthesis with eight gene segments (318-1656 bp). The effects of oligonucleotide concentration, stringency of annealing temperature, annealing time, extension time, and PCR buffer conditions are examined systematically. Analysis of the experimental results leads to new insights into the gene synthesis process and aids in optimizing gene synthesis conditions. We further extend this method for multiplexing gene assembly with a total DNA length up to 5.74 kbp from 1 nM oligonucleotide.     

Comparison of competitive and positive control-based PCR quantitative procedures coupled with end point detection

Two PCR methods using internal standards, coupled with our sandwich nonisotopic enzyme-linked oligosorbent assay (ELOSA) in microtiter plate format, were developed for quantitation of human immunodeficiency virus type 1 (HIV-1) provirus. We present an overview of both methodologies focusing on two major features, i.e., the conditions of equivalency of replication efficiency and the definition of criteria of acceptance validating a result. Quantitative competitive PCR (QC-PCR) was based on the coamplification of the HIV-1 nef gene with different amounts of a pNEFmut plasmid that contains the nef gene with different amounts of a pNEFmut plasmid that contains the nef region but with mutations in the capture probe recognition region. The NEF wild-type (NEF) and the NEF mimic (NEFmut) amplification products were differentiated in ELOSA. NEFmut OD to NEF OD ratios were plotted against the number of mimic copies, and the deduced linear curve permitted quantitation of HIV-I copy number. Internally controlled PCR (IC-PCR) was based on coamplification of the HIV-1 nef gene with an internal endogenous standard, the ras gene, as a positive control of amplification. HIV-1 copy number was determined using external standard of known amounts of HIV-1 DNA. We address the advantages as well as the limitations of individuals protocols and discuss future improvements of quantitative amplification process.     

Principles of quantitation of viral loads using nucleic acid sequence-based amplification in combination with homogeneous detection using molecular beacons

For quantitative NASBA-based viral load assays using homogeneous detection with molecular beacons, such as the NucliSens EasyQ HIV-1 assay, a quantitation algorithm is required. During the amplification process there is a constant growth in the concentration of amplicons to which the beacon can bind while generating a fluorescence signal. The overall fluorescence curve contains kinetic information on both amplicon formation and beacon binding, but only the former is relevant for quantitation. In the current paper, mathematical modeling of the relevant processes is used to develop an equation describing the fluorescence curve as a function of the amplification time and the relevant kinetic parameters. This equation allows reconstruction of RNA formation, which is characterized by an exponential increase in concentrations as long as the primer concentrations are not rate limiting and by linear growth over time after the primer pool is depleted. During the linear growth phase, the actual quantitation is based on assessing the amplicon formation rate from the viral RNA relative to that from a fixed amount of calibrator RNA. The quantitation procedure has been successfully applied in the NucliSens EasyQ HIV-1 assay.     

Theoretical and experimental dissection of competitive PCR for accurate quantification of DNA

We frequently use competitive PCR in the plateau phase in quantifying DNA species with a small number of cells. However, the basic issues of this method are poorly understood. Here, first we analyze this method theoretically under a generalized condition that competitor and target DNA products accumulate with different amplification efficiencies. We show a theoretical reason that competitive PCR might quantify DNA more accurately during the plateau phase than during the exponential phase. Second, we demonstrate that the theoretical predictions are supported by the experimental results of beta-globin gene amplification using the lysates of human diploid fibroblast WS1 cells. We also demonstrate that we can correctly quantify target DNA by keeping the starting concentration of target DNA close to a constant preset value while using a constant number of PCR cycles and by using WS1 cells as control. Finally, we show the experimental errors in routine measurements of c-myc copy number/cell in human leukemia HL-60 cells with various levels of c-myc multiplication. The number of c-myc copies/cell was determined with an error rate of less than 10%, where agarose gel bands were stained with ethidium bromide for the product quantitation.     

基于LAMP技术建立解脲支原体基因试纸条检测方法

目的建立一种灵敏度高、特异性强、检测速度快的方法检测解脲支原体。方法基于环介导恒温扩增技术（LAMP）,根据解脲支原体序列特征设计3对引物进行解脲支原体DNA切口酶核酸恒温扩增,扩增过程在一对引物中标记生物素,随着扩增的进行生物素直接引入扩增片段中,扩增结束后产物在密闭装置中进行免疫试纸条显色反应,根据显色卡的颜色判定结果的阴阳性。结果该技术检测解脲支原体较实时荧光PCR技术灵敏度要高10倍以上,其它病原体检测均阴性该方法特异性与实时荧光PCR技术相当。结论恒温扩增联合试纸条技术检测解脲支原体具有较高的敏感性和特异性,检测速度快,适合各医院开展。     

Quantitative detection for low levels of Helicobacter pylori infection in experimentally infected mice by real-time PCR

Accurate diagnosis of Helicobacter pylori infection is important in both clinical practice and clinical research. Molecular methods are highly specific and sensitive, and various PCR-based tests have been developed to detect H. pylori in gastric biopsy specimens. We optimized a sensitive and specific quantitative SYBR Green I real-time PCR assay for detection of H. pylori based on amplification of the fragment of a 26-kDa Helicobacter species-specific antigen gene that allows for detection of 5 bacterial cells per PCR sample. Under the assay conditions, SYBR Green I real-time PCR is highly reproducible with a precise log-linear relation in the range of six orders of magnitude of bacterial DNA concentrations. For accurate comparison of H. pylori infection in different tissue samples, the amount of total host DNA in each sample is normalized by TaqMan real-time PCR of glyceraldehyde 3-phosphate dehydrogenase (GAPDH) pseudogenes. The developed method was validated in prophilactically immunized and experimentally infected mice and revealed a level of H. pylori gastric colonisation that was below the limit of detection for a rapid urease test. This new method established for a quantitative analysis of H. pylori in the host's stomach may be useful in experimental studies evaluating new anti-H. pylori drugs and vaccines.     

Simulation of between Repeat Variability in Real Time PCR Reactions

While many decisions rely on real time quantitative PCR (qPCR) analysis few attempts have hitherto been made to quantify bounds of precision accounting for the various sources of variation involved in the measurement process. Besides influences of more obvious factors such as camera noise and pipetting variation, changing efficiencies within and between reactions affect PCR results to a degree which is not fully recognized. Here, we develop a statistical framework that models measurement error and other sources of variation as they contribute to fluorescence observations during the amplification process and to derived parameter estimates. Evaluation of reproducibility is then based on simulations capable of generating realistic variation patterns. To this end, we start from a relatively simple statistical model for the evolution of efficiency in a single PCR reaction and introduce additional error components, one at a time, to arrive at stochastic data generation capable of simulating the variation patterns witnessed in repeated reactions (technical repeats). Most of the variation in values was adequately captured by the statistical model in terms of foreseen components. To recreate the dispersion of the repeats'' plateau levels while keeping the other aspects of the PCR curves within realistic bounds, additional sources of reagent consumption (side reactions) enter into the model. Once an adequate data generating model is available, simulations can serve to evaluate various aspects of PCR under the assumptions of the model and beyond.     

纳米金增强复杂体系中PCR扩增低拷贝基因的反应特异性初步研究

目的：利用纳米金颗粒提高复杂体系基因组低拷贝基因PCR扩增的反应特异性。方法：首先,模拟复杂基因组扩增模式体系,以接近单拷贝的λDNA为模板,在PCR过程中加入纳米金颗粒,设计优化实验,以便模拟建立复杂基因组低拷贝目的基因PCR扩增的模式体系。随后,扩增人类基因组的疾病相关的低拷贝基因模板（如人基因组肿瘤坏死因子基因外显子1的380bp）,以检验纳米金优化增强PCR反应特异性的实际效果。结果：在复杂体系基因组的低拷贝基因PCR扩增中,纳米金颗粒能够较好地增强其PCR反应的特异性。结论：初步表明基于纳米金的纳米粒子PCR方法可以对复杂的实际基因组体系低拷贝基因的PCR扩增起到优化作用,这对于PCR反应优化方法的改进、推广具有重要的参考价值。