Relative quantification

1 Relative quantificationMichael W. Pfaffl in: Real-time PCR. Published by International University Line (Editor: T. Dorak), p IntroductionReverse transcription (RT) followed by a polymerase chain reaction (PCR)represents the most powerful technology to amplify and detect traceamounts of mRNA (Heid et al., 1996; Lockey, 1998). To quantify these lowabundant expressed genes in any biological matrix the real-time quantita-tive RT-PCR (qRT-PCR) is the method of choice.

2 Real-time qRT-PCR hasadvantages compared with conventionally performed semi-quantitativeend point RT-PCR, because of its high sensitivity, high specificity, goodreproducibility, and wide dynamic quantification range (Higuchi et al.,1993; Gibson et al., 1996; Orland et al., 1998; Freeman et al., 1999;Schmittgen et al., 2000; Bustin, 2000). qRT-PCR is the most sensitive andmost reliable method, in particular for low abundant transcripts in tissueswith low RNA concentrations, partly degraded RNA, and from limited tissuesample (Freeman et al.)

3 , 1999; Steuerwald et al., 1999; Mackay et al., 2002).While real-time RT-PCR has a tremendous potential for analytical andquantitative applications in transcriptome analysis, a comprehensiveunderstanding of its underlying quantification principles is reaction fidelity and reliable results of the performed mRNA quantifi-cation process is associated with standardized pre-analytical steps (tissuesampling and storage, RNA extraction and storage, RNA quantity andquality control)

4 , optimized RT and PCR performance (in terms of speci-ficity, sensitivity, reproducibility, and robustness) and exact post-PCT dataprocession (data acquisition, evaluation, calculation and statistics) (Bustin,2004; Pfaffl, 2004; Burkardt, 2000).The question which might be the best RT-PCR quantification strategy toexpress the exact mRNA content in a sample has still not been answered touniversal satisfaction. Numerous papers have been published, proposingvarious terms, like absolute , Relative , or comparative general types of quantification strategies can be performed in qRT-PCR.

5 The levels of expressed genes may be measured by an absolute quantification or by a Relative or comparative real-time qRT-PCR (Pfaffl,2004). The absolute quantification approach relates the PCR signal toinput copy number using a calibration curve (Bustin, 2000; Pfaffl andHageleit, 2001; Fronhoffs et al., 2002). Calibration curves can be derivedfrom diluted PCR products, recombinant DNA or RNA, linearized plasmids,or spiked tissue samples. The reliability of such a an absolute real-time RT-PCR assay depends on the condition of identical amplification efficienciesfor both the native mRNA target and the target RNA or DNA used in thecalibration curve (Souaze et al.)

6 , 1996; Pfaffl, 2001). The so-called absolute quantification is misleading, because the quantification is shown Relative tothe used calibration curve. The mRNA copy numbers must be correlated tosome biological parameters, like mass of tissue, amount of total RNA orDNA, a defined amount of cells, or compared with a reference gene copynumber ( ribosomal RNA, or commonly used house keeping genes(HKG)). The absolute quantification strategy using various calibrationcurves and applications are summarized elsewhere in detail (Pfaffl andHageleit, 2001; Donald et al.

7 , 2005; Lai et al., 2005; Pfaffl et al., 2002).This chapter describes the Relative quantification strategies in quantita-tive real-time RT-PCR with a special focus of Relative quantification modelsand newly developed Relative quantification software Relative quantification : The quantification is relativeto what? Relative quantification or comparative quantification measures the relativechange in mRNA expression levels. It determines the changes in steady-state mRNA levels of a gene across multiple samples and expresses it relativeto the levels of another RNA.

8 Relative quantification does not require acalibration curve or standards with known concentrations and the referencecan be any transcript, as long as its sequence is known (Bustin, 2002). Theunits used to express Relative quantities are irrelevant, and the relativequantities can be compared across multiple real-time RT-PCR experiments(Orlando et al., 1998; Vandesompele et al., 2002; Hellemans et al., 2006). Itis the adequate tool to investigate small physiological changes in geneexpression levels.

9 Often constant expressed reference genes are chosen asreference genes, which can be co-amplified in the same tube in a multiplexassay (as endogenous controls) or can be amplified in a separate tube (asexogenous controls) (Wittwer et al., 2001; Livak, 1997, 2001; Morse et al.,2005). Multiple possibilities are obvious to compare a gene of interest (GOI)mRNA expression to one of the following parameters. A gene expressioncan be Relative to: an endogenous control, a constant expressed reference gene oranother GOI an exogenous control, an universal and/or artificial control RNA orDNA an reference gene index, consisting of multiple averaged endoge-nous controls a target gene index, consisting of averaged GOIs analyzed in thestudyTo determine the level of expression, the differences ( ) between thethreshold cycle (Ct) or crossing points (CP) are measured.

10 Thus the mentionedmethods can be summarized as the CPmethods (Morse et al., 2005; Livakand Schmittgen, 2001). But the complexity of the Relative quantificationprocedure can be increased. In a further step a second Relative parameter canbe added, comparing the GOI expression level Relative to:64 Real-time PCR a nontreated control a time point zero healthy individualsThese more complex Relative quantification methods can be summarizedas CPmethods (Livak and Schmittgen, 2001).