Estimation of the reaction efficiency in polymerase chain reaction

Polymerase chain reaction (PCR) is largely used in molecular biology for increasing the copy number of a specific DNA fragment. The succession of 20 replication cycles makes it possible to multiply the quantity of the fragment of interest by a factor of 1 million. The PCR technique has revolutionized genomics research. Several quantification methodologies are available to determine the DNA replication efficiency of the reaction which is the probability of replication of a DNA molecule at a replication cycle. We elaborate a quantification procedure based on the exponential phase and the early saturation phase of PCR. The reaction efficiency is supposed to be constant in the exponential phase, and decreasing in the saturation phase. We propose to model the PCR amplification process by a branching process which starts as a Galton-Watson branching process followed by a size-dependent process. Using this stochastic modelling and the conditional least-squares estimation method, we infer the reaction efficiency from a single PCR trajectory.     

Enhanced analysis of real-time PCR data by using a variable efficiency model: FPK-PCR

Current methodology in real-time Polymerase chain reaction (PCR) analysis performs well provided PCR efficiency remains constant over reactions. Yet, small changes in efficiency can lead to large quantification errors. Particularly in biological samples, the possible presence of inhibitors forms a challenge. We present a new approach to single reaction efficiency calculation, called Full Process Kinetics-PCR (FPK-PCR). It combines a kinetically more realistic model with flexible adaptation to the full range of data. By reconstructing the entire chain of cycle efficiencies, rather than restricting the focus on a 'window of application', one extracts additional information and loses a level of arbitrariness. The maximal efficiency estimates returned by the model are comparable in accuracy and precision to both the golden standard of serial dilution and other single reaction efficiency methods. The cycle-to-cycle changes in efficiency, as described by the FPK-PCR procedure, stay considerably closer to the data than those from other S-shaped models. The assessment of individual cycle efficiencies returns more information than other single efficiency methods. It allows in-depth interpretation of real-time PCR data and reconstruction of the fluorescence data, providing quality control. Finally, by implementing a global efficiency model, reproducibility is improved as the selection of a window of application is avoided.     

Chromatin immunoprecipitation (ChIP): revisiting the efficacy of sample preparation, sonication, quantification of sheared DNA, and analysis via PCR

The "quantitative" ChIP, a tool commonly used to study protein-DNA interactions in cells and tissue, is a difficult assay often plagued with technical error. We present, herein, the process required to merge multiple protocols into a quick, reliable and easy method and an approach to accurately quantify ChIP DNA prior to performing PCR. We demonstrate that high intensity sonication for at least 30 min is required for full cellular disruption and maximum DNA recovery because ChIP lysis buffers fail to lyse formaldehyde-fixed cells. In addition, extracting ChIP DNA with chelex-100 yields samples that are too dilute for evaluation of shearing efficiency or quantification via nanospectrophotometry. However, DNA extracted from the Mock-ChIP supernatant via the phenol-chloroform-isoamyl alcohol (PCIA) method can be used to evaluate DNA shearing efficiency and used as the standard in a fluorescence-based microplate assay. This enabled accurate quantification of DNA in chelex-extracted ChIP samples and normalization to total DNA concentration prior to performing real-time PCR (rtPCR). Thus, a quick ChIP assay that can be completed in nine bench hours over two days has been validated along with a rapid, accurate and repeatable way to quantify ChIP DNA. The resulting rtPCR data more accurately depicts treatment effects on protein-DNA interactions of interest.     

Comparison of relative mRNA quantification models and the impact of RNA integrity in quantitative real-time RT-PCR

Relative quantification in quantitative real-time RT-PCR is increasingly used to quantify gene expression changes. In general, two different relative mRNA quantification models exist: the delta-delta Ct and the efficiency-corrected Ct model. Both models have their advantages and disadvantages in terms of simplification on the one hand and efficiency correction on the other. The particular problem of RNA integrity and its effect on relative quantification in qRT-PCR performance was tested in different bovine tissues and cell lines (n = 11). Therefore different artificial and standardized RNA degradation levels were used. Currently fully automated capillary electrophoresis systems have become the new standard in RNA quality assessment. RNA quality was rated according the RNA integrity number (RIN). Furthermore, the effect of different length of amplified products and RNA integrity on expression analyses was investigated. We found significant impact of RNA integrity on relative expression results, mainly on cycle threshold (Ct) values and a minor effect on PCR efficiency. To minimize the interference of RNA integrity on relative quantification models, we can recommend to normalize gene expression by an internal reference gene and to perform an efficiency correction. Results demonstrate that innovative new quantification methods and normalization models can improve future mRNA quantification.     

Bias in the Cq value observed with hydrolysis probe based quantitative PCR can be corrected with the estimated PCR efficiency value

For real-time monitoring of PCR amplification of DNA, quantitative PCR (qPCR) assays use various fluorescent reporters. DNA binding molecules and hybridization reporters (primers and probes) only fluoresce when bound to DNA and result in the non-cumulative increase in observed fluorescence. Hydrolysis reporters (TaqMan® probes and QZyme? primers) become fluorescent during DNA elongation and the released fluorophore remains fluorescent during further cycles; this results in a cumulative increase in observed fluorescence. Although the quantification threshold is reached at a lower number of cycles when fluorescence accumulates, in qPCR analysis no distinction is made between the two types of data sets. Mathematical modeling shows that ignoring the cumulative nature of the data leaves the estimated PCR efficiency practically unaffected but will lead to at least one cycle underestimation of the quantification cycle (C_q value), corresponding to a 2-fold overestimation of target quantity. The effect on the target–reference ratio depends on the PCR efficiency of the target and reference amplicons. The leftward shift of the C_q value is dependent on the PCR efficiency and with sufficiently large C_q values, this shift is constant. This allows the C_q to be corrected and unbiased target quantities to be obtained.     

聚合酶链式反应热流变化的DSC实验研究

在PCR每个循环中,目的基因在DNA聚合酶的催化作用下实现快速扩增,同时伴随着化学键的断裂和生成,而不同循环数的扩增效率不同,引起的热现象也不同。实验通过差示扫描量技术,以HBV为PCR扩增体系,分别研究了变性、退火和延伸阶段的热焓及其随循环数的变化,通过分析得出：变性阶段是放热过程,第17个循环放热量达到最大,退火和延伸阶段是吸热过程;3个阶段的热焓随循环数增加都发生明显的变化,其中变性阶段的热流变化最关键。     

影响多重PCR扩增效果的因素

不同循环参数、PCR缓冲液及反应体积的对比实验表明,循环参数中退火温度和时间、延伸时间及PCR缓冲液的成分影响多重PCR的扩增效果,而反应体积、循环次数对其扩增效果影响较小。     

Development of a temperature sensor array chip and a chip-based real-time PCR machine for DNA amplification efficiency-based quantification

A temperature sensor array chip was developed to monitor the thermal cycling profiles of a polymerase chain reaction (PCR). DNA amplification efficiency of each cycle was estimated through temperature data to fit the stochastic model. A fluorescence detector system was constructed to detect the PCR amplifications of latter cycles, at which the fluorescence intensity passed the optical detection threshold. Through monitoring of both temperature and fluorescence, DNA amplification efficiency curve was completed for quantification. The F?rster resonance energy transfer (FRET) was employed to detect the measurements of the PCR product amount at the reaction endpoint. The chip-based, real-time PCR machine was constructed to perform the amplification efficiency curve-based quantification method. This novel method achieved the absolute quantification of the Hepatitis B virus (HBV) DNA using a single sample without the construction of the standard curve. The coefficient of variation (CV) of the 15 replicates inter assay experiments was less than 5.87%. Compared with the CV values obtained from the commercial machine in the range of 4.33-14.56%, it is noted that CV values of the prototype with respect to the samples of different initial concentration ranging from 10(7) to 10(3)copies/ml are almost equable.     

快速PCR研究进展

PCR是最常用的分子生物学技术之一,通过变性、退火和延伸的循环来完成核酸分子的大量扩增。快速PCR就是基于普通PCR的工作原理,在保证PCR反应特异性、灵敏性、保真度的前提下,在更短时间内完成对核酸分子的扩增。近年来已经开展了许多有关方面的研究工作。本文将以DNA聚合酶的改进、添加剂的选择、热循环仪改进为重点内容,综述快速PCR技术的研究进展。     

An alternative PCR assay for quantifying mitochondrial DNA in crude preparations.

A method is described for the quantification of mitochondrial DNA present in crude biological preparations. A known copy number of a standard is amplified in the presence of inactivated target DNA so as to determine the overall efficiency of the PCR process in a particular sample. In this way any inhibitory and/or stimulatory substances present in sample preparations can be taken into account. To reduce tube-to-tube variations product DNA quantification is limited to small cycle numbers. Using this method quantitations of DNA amounts in different crude preparations can be compared.     

标准品制备方法对FQ-PCR定量基因表达水平的影响

实时荧光定量PCR (FQ-PCR)标准曲线法准确定量基因表达的关键在于标准品与待检样本的扩增效率是否一致. 为检测DNA标准品与样本cDNA扩增效率的一致性,探讨定量用标准品的最佳制备方法,本研究以脂肪酸结合蛋白5(Fabp5)、过氧化物酶体增殖活化受体α (Ppar-α)及β肌动蛋白（β-Actin）的3个基因为对象,分别采用质粒纯化法、PCR产物直接纯化法、PCR产物凝胶回收法制备DNA标准品,10倍梯度稀释后用FQ PCR制作标准曲线. 并以10倍梯度稀释的样本cDNA标准曲线的参数为对照,进行比较分析. 结果表明,不同方法制备的DNA标准品的扩增效率差异较大,并且与cDNA的扩增效率不一致,不能对cDNA样本进行准确定量. 另外,虽然目的基因在cDNA样本中的拷贝未知,不能对基因表达水平进行绝对定量,但因不同cDNA样本的同一基因的扩增效率一致, 可对基因的表达进行准确的相对定量.     

18O labeling over a coffee break: a rapid strategy for quantitative proteomics

Proteomics-based quantification methods for differential protein expression measurements are among the most important and challenging techniques in the field of mass spectrometry. Though numerous quantification methods have been established, no method meets all the demands for measuring accurate protein expression levels. Of the various relative quantification methods by isotopic labeling, (18)O labeling method has been shown to be simple, specific, cost-effective and applicable to a wide range of analyses. However, some researchers refrain from using the method due to long incubation periods required during the labeling process. To address this problem, we demonstrate a method by which the labeling procedure can be completed in 15 min. We digested and labeled samples using immobilized trypsin on micro-spin columns to speed up the enzyme-mediated oxygen substitution, thereby completing the labeling process within 15 min with high labeling efficiency. We demonstrate the efficiency and accuracy of the method using a four protein mixture and whole cell lysate from rat vascular endothelial cells.