Wilkening Stefan, Bader Augustinus
German Research Centre for Biotechnology, Braunschweig, Germany.
J Biomol Tech. 2004 Jun;15(2):107-11.
Real-time polymerase chain reaction was established for 16 genes using the LightCycler system to evaluate gene expression in human hepatocytes. During the experiments a large set of data has been obtained. These data have now been evaluated with respect to template stability, accuracy of melting curve analysis, and reproducibility. In addition, the statistical evaluation of the efficiencies of all 16 polymerase chain reactions led to a new mathematical model. To examine template stability, the degradation of mRNA and cDNA was determined at different temperatures. Surprisingly, cDNA, which was obtained by first-strand synthesis, appeared to degrade significantly faster than the respective mRNA. Melting curve analysis is a fast and sensitive method to check for polymerase chain reaction specificity. However, we show that two transcription variants of the glutathione S-transferase 1 gene, with over 100 bp length difference, could not be distinguished by this method. Furthermore, an equation was set up describing the correlation between polymerase chain reaction efficiency and crossing point. This equation can be used to estimate the number of template molecules without having a standard of known concentration. Finally, experimental reproducibility of the real-time polymerase chain reaction was defined.
利用LightCycler系统建立了针对16个基因的实时聚合酶链反应,以评估人类肝细胞中的基因表达。在实验过程中获得了大量数据。现已针对模板稳定性、熔解曲线分析的准确性和可重复性对这些数据进行了评估。此外,对所有16个聚合酶链反应的效率进行统计评估后得出了一个新的数学模型。为了检测模板稳定性,在不同温度下测定了mRNA和cDNA的降解情况。令人惊讶的是,通过第一链合成获得的cDNA似乎比相应的mRNA降解得明显更快。熔解曲线分析是一种快速且灵敏的检测聚合酶链反应特异性的方法。然而,我们发现谷胱甘肽S-转移酶1基因的两个转录变体,长度相差超过100 bp,无法通过该方法区分。此外,还建立了一个描述聚合酶链反应效率与交叉点之间相关性的方程。该方程可用于在没有已知浓度标准品的情况下估计模板分子的数量。最后,定义了实时聚合酶链反应的实验可重复性。