The quantitative capacity of the reverse transcription-polymerase chain rea
ction (RT-PCR) is generally underestimated. In this study, PCR and RT-PCR p
roducts were amplified from serially diluted DNA and RNA templates, respect
ively, using a 35-cycle PCR. In the approximate 30- to 100-fold range of te
mplate input above the lower limit of detection, herpes simplex virus ICP27
RT-PCR product yield was dependent on the logarithm of template mRNA input
(r(2) = 0.99). Likewise, regression analysis indicated that yields of inte
rleukin-12 p40, herpes simplex virus DNA polymerase, and interferon-gamma P
CR products were dependent on the logarithm of template DNA input over 40-
(r(2) = 0.98), 60- (r(2) = 0.96), and 100-fold (r2 = 0.99) ranges, respecti
vely. This quantitative relationship appears to derive from the competition
for reactants between specific PCR products and nonspecific primer-dimers
that occurs at limiting concentrations of template. Although primer-dimers
are not generally considered a common feature of PCR, 30 of 32 primer pairs
tested in this study produced primer-dimer amplification in the absence of
template. Because the coefficient of variation in replicate PCRs was typic
ally 10-20% in the linear range, the precision of PCR was sufficient to mea
sure 4-fold differences in template concentration. Thus, with statistically
adequate sample numbers, an appropriate standard curve, and the inherent q
uantitative capacity of the method, differences in the abundance of a mRNA
species are measurable by 35-cycle RT-PCR. (C) 1999 Academic Press.