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Appl Environ Microbiol, February 1998, p. 669-677, Vol. 64, No. 2
0099-2240/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
Reverse Transcriptase (RT) Inhibition of PCR at Low
Concentrations of Template and Its Implications for Quantitative
RT-PCR
Darrell P.
Chandler,*
Christina A.
Wagnon, and
Harvey
Bolton Jr.
Pacific Northwest National Laboratory,
Environmental Microbiology, Richland, Washington 99352
Received 25 March 1997/Accepted 22 November 1997
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ABSTRACT |
Numerous instances of reverse transcriptase (RT) inhibition of the
PCR were observed while developing nonquantitative uncoupled RT-PCR
techniques for detecting nitrogenase and ammonia monooxygenase gene
expression in situ. The inhibitory effect of RT on the PCR was removed
with increasing template concentrations beyond 105 to
106 copies. Including T4 gene 32 protein during the reverse
transcription phase of the RT-PCR reaction increased the RT-PCR product
yield by as much as 483%; if gene 32 protein was introduced after
reverse transcription but prior to the PCR phase, no improvement in
product yield was observed. Addition of 1 µg of exogenous calf thymus DNA or yeast tRNA did little to relieve RT inhibition of the PCR on
both genomic DNA and mRNA templates. These results suggest that RT
inhibition of the PCR is mediated through direct interaction with the
specific primer-template combination (DNA and RNA) and point to
specific assay modifications for estimating the extent of RT inhibition
and counteracting some of the inhibitory effect. Furthermore, the
working hypothesis of RT inhibition below a 105 to
106 copy threshold has important implications for
quantitative RT-PCR studies. In particular, competitive, quantitative
RT-PCR systems will consistently underestimate the actual RNA
concentration. Hence, enumerations of RNA templates below
105 to 106 copies will be relative to an
internal standard and will not be an absolute measure of RNA abundance
in situ.
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INTRODUCTION |
The field of microbial ecology is
rapidly expanding due, in part, to the explosion of molecular microbial
ecology and advances in nucleic acid techniques. Driven in large part
by the availability of PCR, researchers are now able to recover and
analyze nucleic acid sequences from microorganisms that remain
uncultivated. Virtually every aspect of microbial ecology has been
affected by these techniques. At the forefront of nucleic acid
technological development are PCR and reverse transcriptase PCR
(RT-PCR) assays for quantifying specific microorganisms, functional
genes, and microbial activity in complex natural communities
independently of culturability (7, 8, 13, 25, 27).
Nucleic acid techniques are particularly well suited to the study of
nitrifying and denitrifying bacteria in situ, since these microorganisms are notoriously difficult to culture in the laboratory and grow very slowly under standard culture conditions (6). We have been studying the nitrogen-cycling processes in arid
shrub-steppe ecosystems and are developing PCR-based techniques for
quantifying microbial abundance and activity. During the course of
RT-PCR development for nonquantitative detection of mRNA, we routinely observed that control DNA reaction mixtures containing RT did not give
DNA amplification during PCR whereas control DNA reaction mixtures
without RT showed no signs of PCR inhibition. This observation suggested that our ability to detect and amplify mRNA from
environmental samples may be hindered by previously unknown
interactions between the RT and the template. The purpose of this study
was to investigate this phenomenon and gain a better understanding of
the variables and limitations associated with the RT-PCR process. Our
results suggest that the inhibitory effect of RT on the PCR is mediated through the RT interaction(s) with the specific mRNA or cDNA template and that the inhibitory effect is dependent upon template concentration (or copy number). Some of the inhibitory effect could be removed by
including T4 gene 32 protein specifically during the reverse transcription reaction, which has unveiled some novel properties of T4
gene 32 protein that were not previously recognized or exploited. The
implications of these findings apply to RT-PCR in general but also to
quantitative RT-PCR studies where the abundance of specific mRNA may be
relatively low.
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MATERIALS AND METHODS |
Bacterial strains and growth conditions.
Nostoc sp.
strain 27895 was obtained from the American Type Culture Collection
(Rockville, Md.), and Nitrosomonas europaea "freitag"
was obtained from E. Bock, University of Hamburg (Hamburg, Germany).
For DNA isolations, Nostoc was grown in ATCC medium 616 [containing, per liter, 1.5 g of NaNO3, 0.04 g
of K2PO4, 0.075 g of MgSO4 · 7H2O, 0.036 g of CaCl2 · 2H2O, 0.006 g of citric acid, 0.006 g of ferric ammonium
citrate, 0.001 g of disodium EDTA, 0.020 g of
Na2CO3, 2.86 mg of
H3BO3, 1.81 mg of MnCl2 · 4H2O, 0.222 mg of ZnSO4 · 7H2O, 0.39 mg of Na2MoO4 · 2H2O, 0.079 mg of CuSO4 · 5H2O, and 49.4 µg of
Co(NO3)2 · 6H2O (pH 7.1)]
for 3 weeks under constant illumination at 26°C. For total RNA
isolations, Nostoc was grown in ATCC medium 616 without
nitrate (NaNO3) for 3 weeks under constant illumination.
N. europaea was cultured in ammonia oxidizer medium
[containing, per liter, 0.5 g of
(NH4)SO4, 1.34 mg of CaCl2 · 2H2O, 0.04 g of MgSO4 · 7H2O, 0.204 g of KH2PO4, 0.002 g of
bromthymol blue, 0.1 mg of Na2MoO4 · 2H2O, 0.2 mg of MnCl2, 2.0 µg of
CoCl2 · 6H2O, 100 µg of
ZnSO4 · 7H2O, and 20 µg of
CuSO4 · 5H2O] at room temperature, and
the pH was adjusted with filter-sterilized 0.5 M
K2CO3 as needed, for up to 2 months.
DNA isolation.
Cells from a 500-ml culture of
Nostoc and N. europaea were collected by
centrifugation and frozen at 
20°C. The pellets were thawed and
resuspended in 800 µl of lysis buffer (50 mM Tris, 50 mM disodium
EDTA, 2% sodium dodecyl sulfate [pH 8.0]). Genomic DNA was liberated
from the cells by ballistic disintegration with ~1 g of sterile glass
beads (0.1 mm in diameter) in an eight-place bead beater (BioSpec
Products, Inc., Bartlesville, Okla.) at full speed for 1 min. Cellular
debris and glass beads were removed by centrifugation at 13,600 × g at room temperature for 5 min, and the supernatant was
transferred to a fresh tube. Beads and cell debris were extracted once
more with 300 µl of TE (10 mM Tris, 1 mM disodium EDTA [pH 7.8])
and centrifuged as above. Like supernatants were combined, treated with
10 µl of RNase A (10 mg ml
1; Sigma, St. Louis, Mo.) for
30 min at 37°C, and extracted twice with an equal volume of
phenol-chloroform-isoamyl alcohol (25:24:1) and once with
chloroform-isoamyl alcohol (24:1). Nucleic acids were precipitated with
NaCl-isopropanol at room temperature for 10 min, collected by
centrifugation for 8 min at 13,600 × g, washed once in
70% ethanol, dried under vacuum, and resuspended in sterile TE. DNA
concentrations were determined by fluorometry with Hoescht 33258 stain
and a TKO minifluorometer (Hoefer, San Francisco, Calif.).
Total-RNA isolation.
All glass, tubes, and plasticware were
bleached, autoclaved, and treated with an RNase inhibitor (RNAseZap;
Ambion Inc., Austin, Tex.), and all solutions were treated with
diethylpyrocarbonate (DEPC) or prepared with DEPC-treated water.
Nostoc culture (2 liters) and N. europaea culture
(6 liters) were grown as described above and harvested by
centrifugation. Cryptogamic crust (16 g [dry weight]) was rehydrated
and incubated for 1 week at room temperature under natural lighting
conditions. An equivalent of 2 liters of culture medium or 4-g
equivalents of crust was lysed with 5 ml of GIPS solution (4.0 M
guanidine isothiocyanate, 0.5% Sarkosyl, 0.25 M sodium citrate [pH
7.0]) and extracted with an equal volume of phenol-chloroform-isoamyl
alcohol (25:24:1). The phases were separated by centrifugation at
6,000 × g for 10 min, and the aqueous phase was
transferred to a new tube. Nucleic acids were precipitated with 2 volumes of ethanol overnight at room temperature and collected by
centrifugation at 10,000 × g for 20 min. Nucleic acid
pellets were washed once with 70% ethanol, dried briefly under vacuum,
resuspended in DEPC-treated water, and stored at 80°C.
Isolation of mRNA and 16S rRNA.
Aliquots of total RNA were
treated with amplification-grade DNase I as specified by the
manufacturer (Life Technologies, Gaithersburg, Md.), and the DNase was
removed by phenol-chloroform extraction. Purified RNA was then
precipitated with sodium acetate-ethanol as described above,
resuspended in DEPC-treated water, and quantified by UV absorption.
Approximately 4.2 µg of Nostoc RNA and 13.5 µg of
N. europaea RNA were used for affinity capture of
nifH mRNA and 16S rRNA, respectively. The yield of
cryptogamic crust total RNA could not be determined due to the
coextraction of humic acids and other soil constituents that interfered
with UV adsorption; in this case, 4-g equivalents of crust material in
a 150-µl total volume were used for affinity capture of
nifH mRNA. Biotinylated primers were synthesized by Keystone
Laboratory Inc. (Menlo Park, Calif.) with the following sequences:
Nostoc.I.MHC 5'-TTT TCT TCT AAG AAG TTR ATG GCG GTG AT-biotin for
nifH transcripts (this study) and 1392.r 5'-ACG GGC GGT GTG
TRC-biotin for 16S rRNA (47). The primers were reconstituted
at 50 µM in DEPC-treated water. Total RNA was initially heat
denatured at 65°C for 10 min and then subjected to affinity capture
and purification with a PolyATtract mRNA isolation system as specified
by the manufacturer (Promega Corp., Madison, Wis.), except that
captured RNA was eluted in two washes of DEPC-treated water totaling
150 µl. After mRNA capture, residual DNA was removed by DNase I
treatment and purified mRNA was recovered as outlined above for total
RNA isolation; the final mRNA sample was resuspended in 150 µl of
DEPC-treated water. RNA concentrations for N. europaea 16S
rRNA were approximately 64 ng ml1 as determined by UV
absorption; the quantity of nifH mRNA was too small to be
determined accurately by UV absorption.
Reverse transcription of RNA templates.
Purified
nifH mRNA (1 to 10 µl) or N. europaea 16S rRNA
(2 ng to 2 fg) and 2 pmol of reverse primer (see below) were heat denatured in 11 µl (total volume) at 70°C for 10 min. Where
indicated, T4 gene 32 protein was introduced at 1.5 µg per sample
during the initial 70°C template denaturation. After heat
denaturation, reverse transcription reaction mixtures were assembled in
19.5 µl (total volume), which included an additional 0.5 µl of
cloned RNase inhibitor, all as specified by the manufacturer of the RT (Life Technologies). The reverse transcription reaction mixtures were
preheated to 42°C for 2 min, after which 1 µl of SuperScriptII RNase H RT (200 U) was added. After a 50-min incubation
at 42°C, the RT was heat inactivated at 100°C for 5 min and the
reaction mixtures were quick-chilled on ice. Two microliters of each
reverse transcription reaction mixture was then used as the template
for PCR as described below. Control reverse transcription reaction
mixtures included diluted genomic DNA with or without RT, no-template
reactions with or without RT, and purified RNA templates with or
without RT. Two additional RT enzymes, Moloney murine leukemia virus
(MoMuLV) RT and avian myeloblastosis virus (AMV) RT, both from Life
Technologies, were also tested.
PCR amplification of cDNA products.
Primers and PCR
conditions for N. europaea 16S rRNA genes were as described
elsewhere (9); a hot-start PCR and 40 amplification cycles
were used. Control PCR mixtures included diluted genomic DNA that was
not subjected to reverse transcription and all relevant controls
described above for the RT reactions.
Specific primers for Nostoc nifH sequences were constructed
with the sequence 5' CAG AAC CCG GTG TAG GTT (forward) and 5' GTA ACG
ATG TAG ATT TCT TG (reverse) and are based upon a ClustalW alignment
for Nostoc commune, Nostoc muscorum,
Nostoc strain PCC6720, and Nostoc sp.
nifH sequences retrieved from the Entrez database (accession
numbers L23514, U04054, Z31716, and L15551, respectively). A 2-µl
portion of each RT reaction mixture, primers, MgCl2, and
water in 25 µl (total volume) were heat denatured at 80°C, after
which PCR buffer, Taq polymerase (Perkin-Elmer, Foster City,
Calif.), and deoxynucleoside triphosphates (Promega) were added. The
final reaction conditions consisted of 2 µl of RT template, 10 mM
Tris (pH 8.3), 50 mM KCl, 2.5 mM MgCl2, 200 µM each
deoxynucleoside triphosphate, 0.2 µM each primer, and 2.5 U of
Taq polymerase in 50 µl (total volume). Amplification
consisted of 40 cycles at 94°C for 20 s, 50°C for 20 s,
and 72°C for 1 min in 0.2-ml thin-walled tubes and a Perkin-Elmer
9600 thermal cycler. Control PCRs were similar to those described
above.
After PCR amplification, 25 µl of each reaction mixture was resolved
on 1% SeaKem GTG-1% NuSieve agarose (FMC Bioproducts,
Rockland,
Maine) gels in 1× Tris-acetate-EDTA running buffer,
both containing
ethidium bromide. Images of each gel were captured
with a Gel Doc 1000 station and Molecular Analyst software package
(Bio-Rad, Hercules,
Calif.). Individual band intensities were
quantified with the
accompanying Analyst software package, and
the localized background was
subtracted from the computer-determined
value of each band. We could
therefore compare relative product
yield between individual RT-PCRs and
measure the effects of T4
gene 32 protein in a semiquantitative manner.
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RESULTS |
The initial observation prompting this study was that DNA in
control (
5 pg of genomic DNA) reaction mixtures containing RT did not
amplify during PCR whereas control DNA reaction mixtures without RT
showed no signs of PCR inhibition. This result was observed on at least
six separate occasions with six different primer-template combinations
and is not dependent upon the type or amount of RT (data not shown).
The inhibitory effect of RT on the PCR, however, could be removed with
increasing concentrations of genomic DNA (Fig.
1). An identical result and detection
limit were obtained with the nifH PCR system and
Nostoc sp. genomic DNA. Assuming an E. coli
genome size of 4.5 fg cell1, the PCR detection limit in
both cases was approximately 45 cell equivalents of DNA, or 45 to 450 gene copies (assuming 1 to 10 copies per cell). RT inhibition of the
PCR was overcome in both cases only when 4.5 × 105
cell equivalents of genomic DNA were present throughout the RT-PCR.
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FIG. 1.
RT inhibition of the PCR. +, RT present; , RT absent.
Lanes: M,  X174 × HaeIII molecular weight marker; 1 and 2, no template; 3 and 4, 200 fg of N. europaea genomic
DNA; 5 and 6, 2 pg; 7 and 8, 20 pg; 9 and 10, 20 pg; 11 and 12, 2 ng;
13, 200 fg of N. europaea genomic DNA amplified by PCR only;
14, 2 pg of N. europaea genomic DNA; 15, 20 pg of N. europaea genomic DNA.
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RT inhibition of the PCR was also observed when nifH mRNA
was used as the template for RT-PCR (Fig.
2); in this case, Taq polymerase itself functioned as an RT, as indicated by the lack of PCR
product when the template was pretreated with RNase (Fig. 2).
Interestingly, the efficiency of reverse transcription and PCR was
significantly greater with Taq as the sole polymerase than
in the accompanying complete RT-PCR. When an identical experiment was
performed with the N. europaea 16S rRNA, Taq
polymerase was unable to reverse-transcribe the template and any
inhibitory effects of RT could not be ascertained (Fig.
3). The detection limit for the 16S rRNA
RT-PCR was approximately 0.4 amol (200 fg), or 4 × 105 copies, the same copy number at which obvious RT
inhibition was overcome when amplifying from DNA templates.
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FIG. 2.
RT inhibition of RT-PCR demonstrated on
Nostoc sp. nifH mRNA. Lanes: M, X174 × HaeIII molecular weight marker; 1, 5 µl of purified mRNA
plus RT; 2, 5 µl of purified mRNA without RT; 3 and 4, same as 1 and
2, except that the mRNA sample was pretreated with RNase A prior to
RT-PCR; 5, 20 pg of Nostoc sp. genomic DNA subject to PCR
amplification only; 6, 2 pg of genomic DNA; 7, 200 fg of genomic DNA;
8, no-template control.
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FIG. 3.
RT-PCR with a dilution series of purified N. europaea 16S rRNA as template. +, RT present; , RT absent.
Lanes: M, X174 × HaeIII molecular weight marker; 1 and 2, 2 ng of 16S rRNA with or without RT; 3 and 4, 200 pg; 5 and 6, 20 pg; 7 and 8, 2 pg; 9 and 10, 200 fg; 11 and 12, 20 fg; 13 and 14, 2 fg; 15 and 16, no-template control; 17 and 18, 2 ng of N. europaea genomic DNA; 19 to 24, same as lanes 1 to 6, except that
the sample was pretreated with RNase A prior to RT-PCR; 25 and 26, no-template controls pretreated with RNase A; 27 and 28, 2 ng of
N. europaea genomic DNA pretreated with RNase A; 29, 20 pg
of genomic DNA, PCR-only control; 30, 2 pg of genomic DNA; 31, 200 fg
of genomic DNA; 32, no-template PCR-only control.
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To further investigate the mechanism by which RT inhibits the PCR, T4
gene 32 protein was added during the reverse transcription step in an
attempt to stabilize the DNA or displace RT from the genomic template.
The addition of 1.5 µg of T4 gene 32 protein during RT-PCR resulted
in a 50 to 142% improvement in PCR sensitivity when RT was also
present (Fig. 4, compare lane 3 with lane
18 and lane 5 with lane 20). If T4 gene 32 protein was added after the
RT step, RT inhibition of the PCR was again evident (Fig. 5). Extending these analyses to
nifH mRNA templates clearly illustrated the improvement in
RT-PCR sensitivity in the presence of T4 gene 32 protein (Fig.
6, compare lanes 1 to 8 with lanes 15 to
22). In the absence of T4 gene 32 protein, no amplification products were visible in the complete RT-PCR. Taq polymerase RT
activity was augmented by 108 to 483% when T4 gene 32 protein was
included in the nifH mRNA RT-PCR mixture. The improved
RT-PCR performance was also evident with N. europaea 16S
rRNA (Fig. 7). While the detection limit
was identical whether or not T4 gene 32 protein was used in the RT-PCR
(ca. 20 fg, or 40 zmol), increased product yield was again observed in
reaction mixtures containing T4 gene 32 protein, ranging from a 20 to
80% increase when gene 32 protein was included during the initial
70°C template denaturation.
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FIG. 4.
Relief of RT-PCR inhibition through the use of T4 gene
32 protein. N. europaea genomic DNA was used as template.
(A) With T4 gene 32 protein; (B) without T4 gene 32 protein. +, RT
present; , RT absent. Lanes: M, X174 × HaeIII
molecular weight marker; 1 and 2, 2 ng of DNA with or without RT; 3 and
4, 200 pg; 5 and 6, 20 pg; 7 and 8, 2 pg; 9 and 10, 200 fg; 11 and 12, no-template RT-PCR controls; 13 to 15 = 20, 2, and 0.2 pg of
genomic DNA PCR controls; 16 to 27, same as lanes 1 to 12, except
without gene 32 protein; 28, no-template PCR control.
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FIG. 5.
Relief of RT inhibition during the reverse transcription
step in RT-PCR. Nostoc genomic DNA (200 pg) was used as the
template. T4 gene 32 protein was added during the RT phase of RT-PCR or
only for the PCR portion of the RT-PCR protocol. +, RT present; , RT
absent. Lanes: M, X174 × HaeIII molecular weight
marker; 1 and 2, no added T4 gene 32 protein; 3 and 4, gene 32 protein
added during the RT step; 5 and 6, gene 32 protein added for the PCR
phase only; 7, 20 pg of genomic DNA, PCR only; 8, 2 pg of DNA; 9, 200 fg of DNA; 10, no-template PCR control.
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FIG. 6.
Effect of T4 gene 32 protein on RT-PCR amplification of
Nostoc nifH mRNA. (A) Samples included 1.5 µg of gene 32 protein per RT-PCR; (B) no gene 32 protein present. +, RT present; ,
RT absent. Lanes: M, X174 × HaeIII molecular weight
marker; 1, 2, 15, and 16, 5 µl of mRNA as template; 3, 4, 17, and 18, 2 µl of mRNA; 5, 6, 19, and 20, 1 µl of mRNA; 7, 8, 21, and 22, 0.5 µl of mRNA; 9, 10, 23, and 24, RT-PCR no-template controls; 11, 12, 25, and 26, RT-PCR 200 pg of Nostoc genomic DNA controls;
13, 14, 27, and 28, PCR-only controls; 13, 20 pg of genomic DNA; 14, 2 pg; 27, 200 fg, 28, no template.
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FIG. 7.
Effect of T4 gene 32 protein on RT-PCR amplification of
N. europaea 16S rRNA. (A) Samples included 1.5 µg of gene
32 protein per RT-PCR; (B) no gene 32 protein. +, RT present; , RT
absent. Lanes: M, X174 × HaeIII molecular weight
marker; 1, 2, 19, and 20, 2 ng of 16S rRNA as template; 3, 4, 21, and
22, 200 pg; 5, 6, 23, and 24, 20 pg; 7, 8, 25, and 26, 2 pg; 9, 10, 27, and 28, 200 fg; 11, 12, 29, and 30, 20 fg; 13, 14, 31, and 32, RT-PCR
no-template controls; 15, 16, 33, and 34, 200 pg of N. europaea genomic DNA RT-PCR controls; 17, 18, 35, and 36, PCR-only
controls; 17, 20 pg of N. europaea genomic DNA; 18, 2 pg of
DNA; 35, 200 fg of DNA; 36, PCR-only no-template control.
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T4 gene 32 protein is normally considered a single-stranded-DNA (ssDNA)
binding protein and dsDNA helicase (28, 30, 31, 40, 44), but
the genomic DNA results in Fig. 5 suggested that the effect of T4 gene
32 protein was mediated during reverse transcription rather than PCR
amplification. To help understand the role of T4 gene 32 protein in the
RT-PCR process, T4 gene 32 protein was added to the nifH
mRNA RT-PCR mixtures during the RT step or during the PCR phase of the
protocol. At all template concentrations, gene 32 protein added prior
to reverse transcription significantly increased the PCR product yield
relative to that in the standard RT-PCR (51 to 232% increase [Fig.
8]). If T4 gene 32 protein was added
after reverse transcription but at the beginning of PCR, no increase in
RT-PCR sensitivity was observed whether or not RT was one of the
reaction components. In fact, the series of RT-PCRs without T4 gene 32 protein were more sensitive than if T4 gene 32 protein was introduced
during the PCR phase of RT-PCR.
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FIG. 8.
Specificity of T4 gene 32 protein interaction during
RT-PCR amplification of Nostoc nifH mRNA. +, RT present; ,
RT absent. Lanes: M, X174 × HaeIII molecular weight
marker. Lanes were assigned based upon template identification, as
indicated above each block of samples. Samples were also paired
according to T4 gene 32 protein treatment; A, no-gene 32 protein; B,
gene 32 protein added during the reverse transcription step of RT-PCR;
C, gene 32 protein added after the reverse transcription step, and
beginning of PCR. PCR-only controls were Nostoc genomic DNA;
lane 1, 20 pg; lane 2, 2 pg; lane 3, 200 fg; lane 4, no template.
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The importance of improved RT-PCR sensitivity was evident during an
analysis of cryptogamic crust mRNA (Fig.
9). In the absence of T4 gene 32 protein,
no amplification products were detected, whereas positive amplification
was observed at the two highest sample volumes when T4 gene 32 protein
was included in the RT-PCR mixture. Interestingly, Taq
polymerase was unable to function as an RT on the nifH mRNA
isolated from the crust material.
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FIG. 9.
Effect of T4 gene 32 protein on RT-PCR amplification of
Nostoc nifH mRNA isolated from cryptogamic crust. (A)
Samples included 1.5 µg of gene 32 protein per RT-PCR; (B) no gene 32 protein. +, RT present; , RT absent. Lanes: M, X174 × HaeIII molecular weight marker; 1, 2, 15, and 16, 10 µl of
mRNA as template; 3, 4, 17, and 18, 5 µl of mRNA; 5, 6, 19, and 20, 2 µl of mRNA; 7, 8, 21, and 22, no-template RT-PCR controls; 9, 10, 23, and 24, 200 pg of Nostoc genomic DNA RT-PCR controls; 11 to
14, PCR-only controls; 11, 20 pg of Nostoc genomic DNA; 12, 2 pg; 13, 200 fg; 14, no template.
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Prior investigations have suggested that exogenous nucleic acids can
relieve RT inhibition of the PCR (37). However, when either
1 µg of calf thymus DNA or 1 µg of yeast tRNA (5 × 102- to 5 × 106-fold excess) were
included in the RT-PCR mixtures containing genomic DNA, the inhibitory
effect of RT was not relieved (Fig. 10). An apparent 10-fold improvement in
RT-PCR sensitivity was observed in the presence of exogenous calf
thymus DNA, but the nonspecific amplification products indicate some
level of primer cross-reactivity, which would serve to increase the
effective copy number of the N. europaea 16S rDNA due to
titration of the RT. Addition of exogenous DNA, then, did not
significantly relieve RT inhibition of the PCR. Similarly, yeast tRNA
did not appear to improve RT-PCR sensitivity from the nifH
mRNA template (Fig. 11). While the data
from Fig. 11B suggest some relief of RT inhibition for the full RT-PCR,
the data from Fig. 11A indicate that RT-PCR was again more efficient in
the absence of RT and without exogenous template. The value of
exogenous template for improving RT-PCR sensitivity, then, is
questionable. Since the RT is heat inactivated prior to PCR (5 min at
100°C) and neither calf thymus DNA nor yeast tRNA significantly
improved RT-PCR performance at low template concentrations, we conclude
that RT inhibition of the PCR is mediated through a specific
interaction with the primer-template pair undergoing reverse
transcription rather than with Taq polymerase itself.
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FIG. 10.
Effects of nonspecific, noncompetitive templates on RT
inhibition of the PCR. N. europaea genomic DNA was used as
the template. (A) No added competitive template; (B) 1 µg of calf
thymus DNA added during the reverse transcription step; (C) 1 µg of
yeast tRNA added during the reverse transcription step. +, RT present;
, RT absent. Lanes: M, X174 × HaeIII molecular
weight marker; 1 and 2, 2 ng of DNA; 3 and 4, 200 pg; 5 and 6, 20 pg; 7 and 8, 2 pg; 9 and 10, 200 fg; 11 and 12, no template; 13, 20 pg of
DNA, PCR-only control; 14, 2 pg of DNA, PCR-only control; 15 to 26, same as lanes 1 to 12 except with calf thymus DNA as nonspecific
template; 27, 200 fg of DNA PCR-only control; 28, no-template PCR-only
control; 29 to 40, same as lanes 1 to 12 except with yeast tRNA as the
nonspecific template. Arrows show the position of calf thymus genomic
DNA (G), a nonspecific amplification product resulting from calf thymus
genomic DNA (NS), and primer artifacts (P).
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FIG. 11.
Effects of nonspecific template on RT-PCR from
Nostoc nifH mRNA. (A) No added nonspecific template; (B) 1 µg of yeast tRNA added during the reverse transcription step. +, RT
present; , RT absent. Lanes: M, X174 × HaeIII
molecular weight marker; 1 and 2, 2 µl of nifH mRNA
template; 3 and 4, 1 µl; 5 and 6, 0.5 µl; 7 and 8, no template; 9 and 10, 1 ng of Nostoc sp. genomic DNA, RT-PCR control; 11, 20 pg of genomic DNA, PCR-only control; 12, 2 pg of DNA; 13, 200 fg of
DNA; 14, no-template PCR-only control; 15 to 23, same as lanes 1 to 10 except with yeast tRNA during the reverse transcription step.
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DISCUSSION |
Taq polymerase as an RT.
The initial observations
of RT inhibition of the PCR were made on genomic DNA templates (ca.
1,000 copies) that were used as controls for RT-PCR (Fig. 1). Similar
results, however, were also obtained with an mRNA template (Fig. 2). We
initially viewed the mRNA data with suspicion, since Taq
polymerase is not normally considered or used as an RT itself. However,
pretreatment of the template with RNase abolished the signal (Fig. 2),
indicating some level of Taq polymerase RT activity. This
result is not new (21, 22, 38), although the efficiency of
reverse transcription by Taq polymerase is very low relative
to that of the true RT enzymes (<1% [21]). However,
Taq polymerase was unable to function as an RT on mRNA
isolated from cryptogamic crust (Fig. 8). We speculate that
Taq RT activity is more sensitive to copurified contaminants
associated with the nucleic acid or that Mg2+ ions are
sequestered by copurified contaminants, so that the RT-PCR conditions
applied to the crust mRNA were suboptimal for Taq RT
activity relative to the control mRNA template. The differential activity of Taq on a control mRNA template and test mRNA
template, however, may point to a qualitative difference between
"environmental" and "control" nucleic acid targets that might
also affect the true RT enzymes. This possibility warrants further
study within the context of quantitative RT-PCR studies (see below).
RT inhibition of the PCR.
Several reports indicate that RT
itself can interfere with PCR amplification of first-strand cDNA
(1, 29, 37), but the results are mixed and confusing.
Sellner et al. (37), for example, also observed that control
DNA in RT-PCRs was not amplified during PCR whereas standard PCR would
produce the desired product. An AMV RT-to-Taq ratio of 
3:2
appeared to be the threshold for Taq inactivation, but
addition of exogenous tRNA to the RT reaction mixture could alleviate
the effect of RT inhibition. Aatsinki et al. (1) describe a
one-tube RT-PCR system where the RT-PCR sensitivity was adversely
affected by enzyme ratios only at limiting (100 ng) RNA concentrations.
At higher RNA template concentrations, the ratio of RT to
Taq was inconsequential. Mallet et al. (29), however, observed PCR inhibition at an AMV RT-to-Taq ratio
of 20:2.5 when amplifying human immunodeficiency virus (HIV) mRNA from
1 of 100,000 infected cells.
These conflicting and confusing results suggest that the optimal
RT-to-
Taq enzyme ratio is determined by specific reaction
conditions or primer-template pairs. Part of the confusion and
disparate results also appear to be related to the abundance of
specific target mRNA in the total RNA pool, where inhibitory effects
become noticeable only at low (ca. 100-ng) total-RNA concentrations
(
1,
29). Much of the confusion and uncertainty surrounding
PCR inhibition by RT can be removed if we consider a more useful
barometer of template concentration, such as the template copy
number.
When previous studies are reevaluated with this normalized
scale of
template concentration, there is a clear contrast between
previous
investigations and the results presented here. In particular,
our data
suggest that at template concentrations of
10
5 to
10
6 copies in an uncoupled RT-PCR, all signs of RT
inhibition disappear.
Aatsinki et al. (
1) used 1 pg of
plasmid DNA as the lowest
concentration of template; assuming a
generous 10 kbp per plasmid,
1 pg is approximately 10
5
copies. Hence, the lowest concentration of template used in that
study
was at or above the threshold at which we would not expect
to see PCR
inhibition by the RT. An estimate of template copy
number cannot be
calculated from the study of Mallet et al. (
29),
but the
concentration of HIV-positive cells (1 in 10
5) in their
blood sample suggests that their specific template
was probably present
at
10
5 to 10
6 copies per PCR.
Sellner et al. (
37) reported RT inhibition of the PCR at a
plasmid DNA concentration of 100 pg (ca.
10
7 copies,
assuming 10 kbp per plasmid) in a one-tube, coupled RT-PCR.
One of the
conclusions in this work was that RT interacts directly
with
Taq polymerase to inhibit the PCR. At elevated ratios of
AMV
to
Taq (i.e., 14:2), some nonspecific protein-protein
interaction
may be inevitable and potentially lead to
Taq
inactivation. On
the other hand, prolonged incubation of
Taq
polymerase during
an RT incubation combined with a 5-min heat
denaturation at 95°C
may reduce
Taq activity such that the
amplification efficiency
during the PCR would be less than under
standard, optimal PCR
conditions. Conclusions from other experiments
were that primers,
template, or MgCl
2 alter RT enzyme
conformation so that it is
less susceptible to heat inactivation.
T4 gene 32 protein effects.
Several studies have shown that T4
gene 32 protein can improve PCR sensitivity during amplification of DNA
derived from environmental samples (24, 39, 43). T4 gene 32 protein has also improved the PCR amplification of long templates
(36), DNA-sequencing reactions (23), recovery of
mutated DNA sequences with pronounced secondary structure
(11), and PCR-based diagnostics in clinical material
(33). T4 gene 32 protein increases the fidelity of DNA
replication in vitro by interacting with DNA and proteins at the
replication fork (31, 40) and greatly reduces the
thermodynamic cost of helix melting in vivo (2). There is
evidence for a direct interaction between T4 gene 32 protein and RNA
(14), but this property has not been extensively studied or
exploited. An analogous protein isolated from chicken fibroblast cells
chronically infected with Rous sarcoma virus is also capable of binding
to all forms of nucleic acid, including dsDNA, ssDNA, dsRNA, ssRNA, and
DNA-RNA hybrids (19).
Our results suggests that T4 gene 32 protein is exerting its influence
on the mRNA or RNA-DNA duplex during reverse transcription,
in contrast
to but consistent with the traditional notion and
use of gene 32 protein as a ssDNA binding protein and helicase.
Most compelling is the
augmentation of
Taq RT activity, as the
inclusion of T4 gene
32 protein in the reverse transcription phase
of the reaction
consistently and significantly improved
nifH product
yield
relative to that in standard RT-PCRs. Since all RT-PCRs
were performed
under identical conditions and the results were
replicated on three
separate occasions, we conclude that first-strand
cDNA synthesis was
more efficient in the presence of T4 gene 32
protein than without it,
whether
Taq or SuperScriptII RT was the
primary source of RT
activity. Improved
N. europaea 16S rRNA RT-PCR
product yield
also conforms to this hypothesis, since 16S rRNA
contains extensive
secondary and tertiary structures (
45), which
are probably
maintained at the reverse transcription reaction
temperature of 42°C.
The increased yield of
nifH RT-PCR products
from cryptogamic
crust also support this hypothesis. The observation
that
Taq
polymerase could not function as an RT on mRNA isolated
from
cryptogamic crust (Fig.
8), however, suggests that inhibitory
effects
may not be uniformly operative on control RNA relative
to experimental
RNA.
While we postulate that T4 gene 32 protein is involved in RNA binding
and stabilization, a direct interaction with RT (MoMuLV
or
Taq) cannot be ruled out; other studies suggest that T4 gene
32 protein is multifunctional, including domains for interacting
with
DNA, DNA ligase, DNA polymerase, recombination nucleases,
and membrane
proteins (
31,
44). Considering the relative inefficiency
of
Taq RT activity (
21,
22) and the consistently
superior
performance of
Taq over the SuperScriptII RT during
amplification
of
nifH mRNA, a direct interaction between
gene 32 protein and
Taq DNA polymerase is plausible. In any
case, our results suggest
that T4 gene 32 protein is invaluable for
improving RT-PCR sensitivity,
and we therefore recommended its use in
uncoupled RT-PCRs.
Possible mechanism of RT inhibition.
Our data suggest that
interaction of RT with the template (DNA and RNA) is the mechanism for
PCR inhibition at low template concentrations. Increasing template
concentration alleviates the inhibition (Fig. 1 and 3), as does the
addition of T4 gene 32 ssDNA binding protein during the RT incubation
(Fig. 5 through 8). Altering the ratio of Superscript RT to
Taq to 50:2.5 did nothing to alleviate PCR inhibition below
105 to 106 copies of template, and the
inhibitory effect was evident with three different RT enzymes (AMV,
MoMuLV, and Superscript M-MLV RNAse H) used at or below
the recommended levels (data not shown). In addition, 1 µg of
exogenous yeast tRNA or calf thymus DNA was of limited value for
improving RT-PCR sensitivity with the recommended levels of RT in the
RT-PCR (Fig. 10 and 11).
Any RT has an inherent affinity for both DNA and RNA templates, since
both forms of nucleic acid are bound by the enzyme during
polymerization. Any nucleic acid present during an RT incubation,
then,
could serve as an RT substrate regardless of the sequence
or source of
nucleic acid. Since exogenous nucleic acid added
during the reverse
transcription step did not relieve PCR inhibition
at standard
RT-to-
Taq ratios (Fig.
10 and
11), the binding of RT
appears
to be specific for the primer-template combination under
investigation,
perhaps in conjunction with primer extension on
RNA and (at lower
levels) DNA templates. In addition to our own
data, many results
presented by Sellner et al. (
37) are also
explained by this
mechanism, and the reduced RT-to-
Taq molar ratio
required to
alleviate PCR inhibition in the latter case may simply
reflect
titration of RT enzyme on abundant targets,
Taq affinity
for
RNA templates (which may preclude RT binding to the target
site),
low-level
Taq RT ability (see above and references
21,
22, and
38), or more
efficient displacement of RT by
Taq during
repeated
amplification cycles. Furthermore, heat inactivation
of the RT is
normally used to eliminate RT and RT nuclease activity.
As such, the
use of heat to inactivate the RT enzyme does not
necessarily translate
into the release of template (DNA or RNA)
upon heat denaturation; the
very existence of hyperthermophilic
Archaea (
18)
demonstrates that extreme heat does not necessarily
result in complete
protein denaturation. Proteinase K digestion
(
37), however,
will fragment the RT into smaller peptides and
would therefore be
expected to release substrates (template, primer,
and Mg
2+)
otherwise sequestered by the RT. These results (
37) also
suggest
that RT is binding specifically to the nucleic acid target and
is not being released or displaced upon heat inactivation and
subsequent cycles of PCR. Thus, most of the previous accounts
of PCR
inhibition by RT can be described by a copy number effect,
and we
therefore conclude that RT inhibition of the PCR at low
template
concentrations is an inevitable feature of uncoupled
RT-PCRs.
Implications for quantitative RT-PCR studies.
The power of
RT-PCR to rapidly amplify RNA templates with exquisite sensitivity and
specificity has naturally led to the development of numerous
quantitative RT-PCR systems (4, 7, 15, 17, 20, 27, 34, 35).
Given the widespread use of quantitative RT-PCR in both clinical and
environmental applications, it is surprising that RT inhibition of the
PCR has not been more commonplace or widely recognized. As Sellner et
al. note (37), many investigators may have unwittingly
avoided this problem by using relatively high levels of template during
RT-PCR; we observed this phenomenon only because we naively used small
quantities of genomic DNA as a control template throughout the reverse
transcription and PCR steps of RT-PCR.
On the surface, the finding that RT can interfere with PCR
amplification appears to be a rather innocuous situation, one that
can
be easily overcome by performing RT-PCR at elevated template
concentrations. The question then becomes one of whether
10
5 to 10
6 copies is an experimentally
relevant concentration of target.
In many cases, detection of
10
5 to 10
6 RNA templates in a given sample,
such as the detection of HIV,
food and public health viruses and
pathogens, plant pathogens,
or other infectious agents in both humans
and animals, is extremely
relevant (
3,
10,
12,
16,
26,
41,
42). The detection
of certain mRNA transcripts in complex
environmental samples is
equally relevant, since the relatively low
recovery of nucleic
acids from soils and sediments (
27,
32)
and the inherent instability
of mRNA quickly deteriorate into problems
of low-copy-number nucleic
acid detection. For these reasons, RT-PCR
has become a primary
technique for detecting in situ gene expression
and viral RNA
genomes, and it is being used to enumerate RNAs in
numerous clinical
and environmental settings. However, small variations
in amplification
efficiency during early rounds of the PCR can result
in disparate
quantities of PCR product during the exponential phase of
amplification,
so the effect of RT inhibition on the PCR has important
consequences
for more quantitative attempts to detect
10
5
to 10
6 copies of RNA template.
Competitive, quantitative RT-PCR assays are normally assembled in one
of two formats: reverse transcription of test RNA is
carried out
independently of a competitive template and the competitive
template is
added during the PCR process, or a copied RNA (cRNA)
template is
synthesized and subject to both the reverse transcription
and PCR
amplification in the presence of the test RNA. Our initial
PCR
experiments with DNA templates are analagous to a quantitative
RT-PCR
assay in which the competitive cDNA is added after reverse
transcription. If RT inhibition of the PCR is true, as our data
suggest, then this quantitative RT-PCR design will clearly give
an
underestimate of the actual template concentration in the RNA
sample.
That is, the competitive template will not interact with
active RT and
will therefore be amplified with greater efficiency
than the test RNA
sample. Therefore, less competitor will be required
to obtain
equivalence between test RNA and competitor PCR product
concentrations.
In this respect, quantitative RT-PCR systems that
use an internal cRNA
competitor to account for RT inefficiency
and inhibition will be much
more accurate indicators of the actual
RNA copy number. However, our T4
gene 32 protein experiments show
that reverse transcription of RNA
targets may also be inhibited
at lower template concentrations and that
the extent or occurrence
of inhibition may be different on mRNAs
extracted from environmental
samples. Since the deduced quantity of
test RNA in these systems
is always relative to the internal standard,
the efficiency of
reverse transcription of the test RNA cannot be
determined directly,
and nucleic acids extracted from environmental
samples may contain
additional inhibitors that do not act equally on
the test RNA
and cRNA templates, enumerations of RNA templates in the
test
sample should not be considered "absolute" (
4,
5,
46).
Summary.
This study has established an inhibitory effect of RT
on the PCR, which manifests itself as reduced RT-PCR efficiency in
uncoupled RT-PCR systems below 105 to 106
copies of starting RNA. More importantly, however, these results imply
that uncoupled, competitive quantitative RT-PCR assays used in both
clinical and environmental settings will consistently underestimate the
actual target RNA concentration in a sample if the starting
concentration is below the 105- to 106-copy
threshold. The extent of inhibition can be estimated by performing
control RT-PCR amplifications of both DNA and RNA independently of the
amplifications of the test sample but under otherwise identical reaction conditions. Some of this inhibition can also be relieved by
incorporating 1.5 µg of T4 gene 32 protein during the initial template denaturation prior to reverse transcription, a property of
gene 32 protein that has not been previously reported. However, because
the outcome of quantitative RT-PCR can be significantly influenced by
minor variations in amplification efficiency during the early rounds of
PCR and because the extent of RT or PCR inhibition of test samples
cannot be determined directly, this study suggests that quantitative
RT-PCR enumerations of low-copy-number RNAs will underestimate mRNA
levels in test samples. Consequently, a more thorough molecular and
mechanistic understanding of RT-PCR and PCR at low template
concentrations is required to accurately implement RT-PCR systems for
quantifying low-abundance in situ RNA templates in both clinical and
environmental samples.
| |
ACKNOWLEDGMENTS |
This research was supported by the Program for Ecosystem
Research, Office of Health and Environmental Research, U.S. Department of Energy (DOE). Pacific Northwest National Laboratory is operated for
the DOE by Battelle Memorial Institute under contract DE-AC06-76RLO 1830.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Pacific
Northwest National Laboratory, Environmental Microbiology, 900 Battelle
Blvd., Mail Stop K4-06, Richland, WA 99352. Phone: (509) 375-2543. Fax: (509) 375-6666. E-mail: dp_chandler{at}pnl.gov.
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Abstract
Introduction
