From the Department of Biochemistry and Molecular Biology, Pennsylvania State University, University Park, Pennsylvania 16802
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ABSTRACT |
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We have performed a systematic, quantitative
analysis of the kinetics of nucleotide incorporation catalyzed by
poliovirus RNA-dependent RNA polymerase,
3Dpol. Homopolymeric primer/templates of defined
length were used to evaluate the contribution of primer and template
length and sequence to the efficiency of nucleotide incorporation
without the complication of RNA structure. Interestingly, thermodynamic
stability of the duplex region of these primer/templates was more
important for efficient nucleotide incorporation than either primer or
template length. Surprisingly, products greater than unit length formed in all reactions regardless of length or sequence. Neither a
distributive nor a processive slippage mechanism could be used to
explain completely the formation of long products. Rather, the data
were consistent with a template-switching mechanism. All of the
nucleotide could be polymerized during the course of the reaction.
However, very few primers could be extended, suggesting an inverse
correlation between the efficiency of primer utilization and that of
nucleotide incorporation. Therefore, the greatest fraction of
incorporated nucleotide derives from a small fraction of enzyme when
radioactive nucleotide and homopolymeric primer/template substrates are
employed. The impact of these results on mechanistic studies of
3Dpol-catalyzed nucleotide incorporation and RNA
recombination are discussed.
Positive-strand RNA viruses cause a variety of diseases in humans
ranging from the common cold (1) to chronic hepatitis (2). Critical to
the replication of the genomes of these viruses is the virus-encoded,
RNA-dependent RNA polymerase
(RdRP)1 (3). As this
enzymatic activity is unique to virus-infected cells, the viral RdRP
represents a very attractive target for the design of antiviral agents
to treat RNA virus infection. Most positive-strand RNA viruses are
thought to have the same general replication strategy, and this belief
is generally extended to include the mechanism of genome replication
(3). RdRPs from many viruses have been characterized to some extent
(3-9). However, in no instance is detailed, mechanistic information
available. This fact is even true for viruses, such as poliovirus, for
which genetic and biochemical systems to study genome replication have existed for many years (10).
Notwithstanding, poliovirus is one of the best understood systems with
respect to the biochemistry of genome replication and is, therefore, an
invaluable paradigm for all positive-strand RNA viruses (10).
Replication of poliovirus genome initiates within the poly(A)-tract at
the 3'-end of genomic RNA from a complex comprising viral factors (3AB,
3CD, 3B, and 3Dpol) (11-13) and possibly cellular factors
(14). 3AB and 3CD are required primarily to establish an initiation
complex, possibly by recruiting the polymerase, 3Dpol (13).
3AB is a RNA-binding protein capable of interacting with 3Dpol (15,16) that possibly stimulates the rate of
elongation of nascent RNA (17) or enhances the efficiency of primer
utilization (18). RNA synthesis is catalyzed by 3Dpol,
which initiates RNA synthesis from the protein primer, 3B. 3B is most
often referred to as VPg.
The recent solution of the crystal structure of poliovirus RdRP by the
Schultz laboratory has catapulted this enzyme, in terms of structure,
to the level of the other classes of nucleic acid polymerase (19).
Thus, a more precise understanding of the structure-function relationships of this enzyme is now possible. To be sure, an
understanding of the elementary steps employed by polymerases in
catalyzing nucleotide incorporation is essential in order to evaluate
accurately the effects of mutations. Unfortunately, the prevailing
absence of detailed, mechanistic information for 3Dpol
greatly limits the extent to which the structural information can be
exploited. This is due, primarily, to the inability to establish
stoichiometric complexes between 3Dpol, primer/template,
and nucleotide.
In this report, we have performed a systematic, quantitative analysis
of the kinetics of 3Dpol-catalyzed nucleotide incorporation
using homopolymeric substrates of defined length. These studies provide
insight into the properties of primer/template required for the
assembly of stoichiometric complexes between 3Dpol and
primer/template. This information should prove useful in the design of
heteropolymeric primer/templates to elaborate a detailed kinetic
mechanism for this enzyme and, perhaps, other RdRPs. In addition, these
studies revealed the unexpected ability of poliovirus 3Dpol
alone to undergo template switching in vitro.
Materials
[ Expression and Purification of 3Dpol
Construction of the plasmid directing the expression of
3Dpol with an authentic, glycine amino terminus and the
details of purification will be described
elsewhere.2 Briefly, the
plasmid contains a gene encoding a ubiquitin-3Dpol fusion
protein under control of the bacteriophage T7 RNA polymerase promoter
(20). Escherichia coli, BL21(DE3), co-transformed with the
3Dpol expression plasmid and plasmid pCG1, which directs
the expression of a ubiquitin protease (20), were grown to
A600 = 0.8 in NZCYM medium (Life Technologies,
Inc.), and expression was induced by addition of
isopropyl-1-thio- Purification of Synthetic Oligonucleotides
DNA and RNA oligonucleotides were purified by denaturing PAGE.
Gels consisted of: 18% acrylamide, 2% bisacrylamide, 7 M
urea, and 1× TBE (89 mM Tris base, 89 mM boric
acid, and 2 mM EDTA). The oligonucleotide ladder was
visualized by UV shadowing. A gel slice containing only the full-length
oligonucleotide was removed, and the nucleic acid was electroeluted
from the gel in 1× TBE by using an Elutrap apparatus (Schleicher & Schuell). Oligonucleotides were desalted on Sep-Pak columns (Millipore)
as specified by the manufacturer. Oligonucleotides were typically
suspended in TE (10 mM Tris, 1 mM EDTA, pH
8.0), aliquoted, and stored at Purity of [ [ 5'-32P Labeling of Oligonucleotides
DNA and RNA oligonucleotides were end-labeled by using
[ 5'-32P Labeling of DNA Ladder
Labeling of the DNA ladder was performed by using
[ 3Dpol Assays
Reactions contained 50 mM HEPES, pH 7.5, 10 mM 2-mercaptoethanol, 5 mM MgCl2,
60 µM ZnCl2, 0.2 µCi/µl
[ Product Analysis
DE81 Filter Binding--
10 µl of the quenched reaction was
spotted onto DE81 filter paper discs and dried completely. The discs
were washed three times for 10 min in 250 ml of 5% dibasic sodium
phosphate and rinsed in absolute ethanol. Bound radioactivity was
quantitated by liquid scintillation counting in 5 ml of Ecoscint
scintillation fluid (National Diagnostics).
Denaturing PAGE--
10 µl of the quenched reaction mixture
was added to an equal volume of loading buffer (80% formamide, 100 mM EDTA, 50 mM Tris borate, 0.15% bromphenol
blue, and 0.15% xylene cyanol) and heated to 70 °C for 1 min prior
to loading 5 µl on a 1× TBE polyacrylamide gel of the appropriate
percentage. Electrophoresis was performed in 1× TBE at 30 mA. Gels
were visualized and quantitated by using a PhosphorImager.
Primer Length and Sequence Composition Modulate the Rate of
3Dpol-catalyzed Nucleotide Incorporation--
The ability
to identify the individual steps employed by 3Dpol during a
single cycle of nucleotide incorporation requires the assembly of
stoichiometric complexes between 3Dpol and substrates:
primer/template and nucleotide. Formation of such complexes with
DNA-dependent DNA polymerases and reverse transcriptases is
an ordered process with primer/template binding prior to nucleotide
(22-26). In addition, stability of the initial binary complex depends
on the length of primer/template, and rate of nucleotide incorporation
depends on sequence (22). In order to evaluate rapidly the effect of
primer and template length and sequence composition on the efficiency
of nucleotide incorporation catalyzed by 3Dpol, without the
complication of nucleic acid structure, we have used combinations of a
variety of homopolymeric oligonucleotides and polynucleotides of
defined length as primer/template substrates for 3Dpol.
In the first series of experiments, poly(rA) was used as template and
DNA oligonucleotides ranging in size from 6 to 20 nt were used as
primers (Fig. 1A). As reported
previously, de novo synthesis is not observed on poly(rA)
(27). However, 3Dpol-catalyzed nucleotide incorporation was
observed with oligo(dT) primers 6 nt or longer (Fig. 1A). In
addition, a primer length of 15-20 nt was optimal for most efficient
nucleotide incorporation (Fig. 1A). By using a 15- or 20-nt
oligo(dT) primer, the amount of product formed was increased 5-25-fold
relative to that observed with either a 6- or 10-nt primer. This
apparent effect of primer length on 3Dpol-catalyzed
nucleotide incorporation was not due to changes in the fraction of
template coated by primer as this ratio was constant. In each case, a
primer concentration sufficient to coat 30% of the template was used.
It is worth noting, however, that maximal rates of nucleotide
incorporation were observed only when a primer concentration sufficient
to coat 30-100% of the template was used (Fig.
2).
When a similar series of experiments was performed using poly(rC) as
template, de novo synthesis was observed, albeit at a 5-10-fold lower efficiency relative to that observed in the presence of a primer (Fig. 1B). In contrast to oligo(dT)-primed
poly(rU) synthesis, a 6-nt oligo(dG) primer was optimal for most
efficient poly(rG) synthesis (Fig. 1B). Moreover, a 2-fold
decrease in the amount of nucleotide incorporated was noted as the
length of the primer was increased to 10 nt (Fig. 1B). The
level of nucleotide incorporation was essentially the same for
oligo(dG) primers 10, 15, or 20 nt in length (Fig. 1B). Experiments
were also performed using 15-nt oligo(rU) and oligo(rG) primers. No
significant difference in activity was observed with these RNA primers
relative to the corresponding 15-nt DNA primers (data not shown).
In order to assess more directly the effects of primer and template
length on the efficiency of nucleotide incorporation, steady-state
kinetic analysis was performed on the following primer/templates: dT15/rA400, dT15/rA30,
dT15/rA16, and
dT10/rA16; the data are presented in Table
I. The Km values
varied from 24.6 µM (dT15/rA30)
to 122 µM (dT10/rA16), and the
Vmax values varied from 1.1 µM/min
(dT15/rA16) to 13.1 µM/min
(dT15/rA400). Although no change in the
Km for primer/template was observed when the length
of the template was changed from 400 to 16 nt, a 3-5-fold increase in
the Km was observed by changing the primer length
from 15 to 10 nt. Interestingly, even under conditions of saturating
substrates, the kinetics of nucleotide incorporation varied from
substrate to substrate (Fig. 3). Both the
duration of linearity and the reaction end points differed substantially when the kinetics of nucleotide incorporation into dT15/rA16 (Fig. 3A) was compared
with that into dT15/rA30 (Fig. 3B)
or dG15/rC30 (Fig. 3C). The
Km of 3Dpol for
dG15/rC30 is in the 15 µM range
(data not shown). Therefore, in order to ensure accurate measurement of
reaction rates as a function of substrate or enzyme concentration,
reaction rates were determined from the linear phase of complete time
courses.
When the dependence of the reaction rate on enzyme concentration was
measured using the linear phase of complete time courses, no evidence
was obtained to support the hypothesis that oligomerization of
3Dpol is necessary for activity as suggested by Pata
et al. (28). Fig.
4A shows the linear phase of
time courses for reactions under conditions of saturating substrates
using concentrations of 3Dpol ranging from 0.5 µM to 2.0 µM. A plot of reaction rates,
obtained by linear regression of the data shown in Fig. 4A,
as a function of 3Dpol concentration showed a linear
relationship. Therefore, the cooperative transition in the 0.5-2.0
µM range observed by Pata et al. (28) may be a
reflection of the "snap-back" RNA substrate employed in that study.
Finally, the dependence of the rate of nucleotide incorporation on
3Dpol concentration was also linear in the 0.05-5
µM range (data not shown).
Products Greater than Unit Length Form Using
dT15/rA16,
dT15/rA30, and
dG15/rC30 Primer/Templates--
It has been
reported by several investigators studying the oligo(dT)-primed,
poly(rU)-polymerase activity of 3Dpol that this enzyme
extends, at best, 0.1-1% of primers in reactions which typically
contain a concentration of primer in the 1 µM range (28,
29). Such a low fraction of primer utilization is not surprising,
however, given a Km of 3Dpol for
dT15/rA400 of 45 µM. Therefore,
it was comforting to note that the concentration of UMP incorporated
was almost stoichiometric with respect to primer under saturating
conditions of dT15/rA16 (Fig. 3A).
This suggested that in this reaction a greater fraction of primers were
utilized. However, when products of reactions employing an end-labeled,
(dT)15 primer were resolved by denaturing PAGE and
visualized by phosphorimaging, extended primer was not observed (data
not shown).
In order to increase the limit of detection, products of reactions
employing [
The ability to form products greater than unit length was not unique to
the dT15/rA16 primer/template. Long products
were observed with dT15/rA30 and
dG15/rC30 primer/templates (Fig.
6). The efficiency of formation of
products greater than unit length was sensitive to sequence
composition. The magnitude of label incorporated into products from the
dG15/rC30 reaction was reduced by an order of
magnitude relative to that from the dT15/rA30
reaction (cf. Fig. 3, B and C).
Models for Formation of Products Greater than Unit
Length--
Because previous studies of 3Dpol employing
long, homopolymeric substrates appeared to produce unit-length products
(5, 6, 17), the formation of products greater than unit length on
short, homopolymeric substrates was not expected. However, this
phenomenon has been reported for most classes of nucleic acid
polymerase studied to date. Several mechanisms have been proposed to
explain formation of these products (30-33), and three possible
mechanisms are illustrated in Fig. 7. The
first possibility is a distributive slippage mechanism (Fig. 7,
i) in which the polymerase dissociates from primer/template,
the primer terminus realigns relative to template, and enzyme rebinds
and extends. Several iterations of this pathway would yield products
greater than unit length. A second possibility is a processive slippage
mechanism (Fig. 7, ii). Again, realignment of the primer
occurs relative to template; however, polymerase does not dissociate.
Finally, template switching (copy-choice recombination) may be the
mechanism of formation of products greater than unit length (Fig. 7,
iii). Polymerase, in complex with nascent chain, dissociates
from template (donor) and binds to another (acceptor). A permutation of
this mechanism would require polymerase to reach the end of template
for efficient template switching to occur (forced-copy-choice
recombination). Although template switching via a copy-choice mechanism
could occur before, during, or after polymerase reaches the end of
template, template switching would occur most frequently once
polymerase reaches the end of donor template via a forced copy-choice
mechanism. While a distributive slippage mechanism has been proposed
for DNA polymerase I to explain formation of long products from short primer/templates consisting of 3-nt repeats (33), a processive slippage
mechanism has been suggested for T7 DNA polymerase on the same
substrates (33). In the case of the reverse transcriptases from avian
myeloblastosis virus (30, 31) and human immunodeficiency virus (32), a
template-switching mechanism has been proposed to explain products
greater than unit length on a poly(rA) template.
Formation of Products Greater than Unit Length Does Not Occur by a
Distributive or Processive Slippage Mechanism--
As slippage was a
very probable explanation for formation of long products, our initial
experiments were designed to distinguish between a distributive and a
processive slippage mechanism. If slippage were occurring by a
distributive mechanism, then long products should not form in the
presence of a trap for free enzyme. In contrast to results obtained
with the encephalomyocarditis 3Dpol (34), heparin is a very
effective inhibitor of poliovirus 3Dpol with a
Ki in the 30 nM range (Fig.
8). When a reaction containing
dT15/rA30 primer/template,
[
Interestingly, complexes that were competent to form long products were
also sensitive, to some extent, to inhibition by heparin albeit at a
substantially higher concentration than that for free enzyme. Although
both 10 µM heparin and 100 µM heparin were
sufficient to trap free enzyme, the rate of the second phase of the
reaction was inhibited to a greater extent by 100 µM
heparin than by 10 µM heparin (Fig.
10). This observation may suggest that
complexes that form long products can exist in a form that is not
"free" but is accessible to heparin. Such a complex might be
expected if template switching occurred.
In order to test the processive slippage mechanism directly, the
following experiment was performed. Polymerase (5 µM),
dT15/rA30 (10 µM), and
UTP/[ Template Switching Is the Primary Pathway for Formation of Products
Greater than Unit Length--
The use of a template-switching
mechanism by 3Dpol to produce products greater than unit
length would be supported further by demonstrating a dependence of the
reaction rate on the concentration of acceptor template
(rA30) (31, 32). The presence of acceptor template in
reactions prior to assembly was inhibitory (Fig.
12A), and concentrations of
acceptor as high as 100 µM did not alter the ability of
heparin to act as a trap for free enzyme (Fig. 12A).
However, if elongation complexes are formed prior to addition of
acceptor template, acceptor-template-dependent stimulation of 3Dpol-catalyzed nucleotide incorporation was observed
(Fig. 12B). In addition, the observed stimulation by
acceptor template was concentration-dependent (Fig.
12B), saturating in the 10-50 µM range (Fig.
12C). Moreover, analysis of products formed in the presence
of acceptor template by denaturing PAGE showed that longer products
accumulated at a faster rate than in the absence of additional acceptor
template (Fig. 13, cf.
Long products also formed in the absence of additional acceptor
template. It is possible that these products are the result of
slippage. Alternatively, the rA30 in the
dT15/rA30 primer/template, which is not bound
by polymerase, may serve as acceptor template. In order to distinguish
between these two possibilities and obtain additional evidence to
support template switching, we replaced the oligo(rA)30
with oligo(dA)30. In Mg2+,
dT15/dA30 primer/templates do not support
poly(rU) synthesis (data not shown), suggesting that
oligo(dA)30 should not serve as an acceptor template. The
template-switching model suggests that a complex comprising
3Dpol and nascent chain dissociates from the donor template
and binds to the acceptor template. If the destination of the
"jumping" complex is dictated by base pairing, then
oligo(dA)30 might be expected to inhibit formation of long
products. In contrast, if slippage synthesis is the mechanism of
formation of long products, then oligo(dA)30 might be
expected to have no effect on formation of long products. As indicated
in Fig. 13 (+ dA30 Acceptor panel), oligo(dA)30 inhibited significantly the rate of
accumulation of long products. Therefore, we conclude that template
switching is the primary mechanism of long product formation in these reactions.
The fraction of complexes formed during the course of the reaction was
determined by primer-extension analysis of an end-labeled [32P]dT15/rA30 primer/template.
The data are shown in Fig. 14. Only 4%
of primers were extended, consistent with the steady-state data
presented in Table I. This result suggests that all of the nucleotide
incorporated derives from a very small fraction of polymerase-primer/template complexes when radioactive nucleotide is
used to follow reaction progress. Moreover, the fraction of the
extended primers competent for long product formation (i.e. products greater than 40 nt in length) represent only 8.7-23% of the
total during the course of the 30-min reaction.
Although homogeneous, active preparations of poliovirus
RNA-dependent RNA polymerase, 3Dpol, have been
available for several years (5, 6), very little is known about the
mechanism of nucleotide incorporation catalyzed by this enzyme. The
recent solution of the crystal structure of 3Dpol (19)
permits structure-function relationships to be defined for this class
of polymerase. However, interpretation of effects of mutations in
3Dpol-coding sequence on function is compromised greatly by
lack of information on the individual steps employed by this enzyme
during a catalytic cycle. One reason for this gap is that
stoichiometric complexes between 3Dpol, primer/template,
and nucleotide have yet to be established.
The initial goal of this study was to perform a systematic,
quantitative analysis of substrate utilization by 3Dpol,
thus facilitating the design of a primer/template useful for the
elaboration of the minimal kinetic mechanism for single nucleotide incorporation catalyzed by this enzyme. Unlike the
DNA-dependent DNA polymerases and reverse
transcriptases (22, 23, 32, 35), however, at equilibrium in the
presence of excess primer/template all of the poliovirus polymerase in
a reaction is not located at a primer/template junction. This
conclusion is based on the observation that at least 30% of template
nucleotides needed to be coated by primer to observe maximal rates of
nucleotide incorporation (Fig. 2). In the case of the Klenow fragment
of DNA polymerase I and human immunodeficiency virus reverse
transcriptase, a stoichiometry of one 15-20-nt primer/400-1000-nt
template can be used without observing any hysteretic effects on the
kinetics of nucleotide incorporation (32, 35).
Under conditions of optimal template coating using poly(rA) or poly(rC)
as template, differences in activity were observed as the length of
primer was varied. Although a 15-20-nt oligo(dT) primer was best for
poly(rU) synthesis, a 6-nt oligo(dG) primer was optimal for poly(rG)
synthesis. Therefore, the differences in optimal activity as a function
of primer length is most likely due to stability of annealed
primer/template. This conclusion is further supported by the fact that
the predicted Tm value for the best primers is
centered around 49 °C (36, 37). Interestingly, Tm values greater than 70 °C, as is the case
for dG primers greater than 10 nt in length, decreased significantly
the efficiency of nucleotide incorporation. Perhaps, after binding of
3Dpol to primer/template, disruption of the duplex is
required for efficient initiation of and/or elongation during RNA
synthesis. However, regardless of the molecular events governing the
differences described above, these differences should be considered in
the design of heteropolymeric RNA primers for 3Dpol and
other RdRPs.
In contrast to the pronounced effects on the rate of nucleotide
incorporation observed as primer length was varied, effects much less
than expected were observed as template length was varied. Under
saturating conditions of primer/template and nucleotide, one might
expect that as the template length is decreased a proportional reduction in the amount of nucleotide incorporated would occur. This
was not observed (Table I) because products greater than unit length
were being formed per initiation event during the course of the
reaction. The long products did not arise as a result of nucleic acid
contamination rather from the primers in the reaction (Fig. 5). By
performing reactions in the presence of heparin, a trap for free enzyme
(Fig. 8), it was shown that these products formed without enzyme
dissociation (Fig. 9). Although slippage may occur to some extent, a
template-switching mechanism appears to be the primary mechanism of
formation of long products. This conclusion is supported by the finding
that the rate and extent of accumulation of products greater than unit
length are diminished by dilution (Fig. 11), enhanced by addition of
(rA)30 acceptor template (Figs. 11-13), and inhibited by
(dA)30. Although complexes competent to form long products
are only a small fraction of the total, these complexes are the primary
source of nucleotide incorporated during the course of the reaction
(Fig. 14). Taken together, these data are consistent with the model
presented in Fig. 15.
INTRODUCTION
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Abstract
Introduction
References
EXPERIMENTAL PROCEDURES
-32P]GTP (>3,000 Ci/mmol) and
[
-32P]UTP (>6,000 Ci/mmol) were from NEN Life Science
Products; [
-32P]ATP (>7,000 Ci/mmol) was from ICN;
nucleoside 5'-triphosphates and poly(rA) were from Amersham Pharmacia
Biotech; poly(rC) and heparin 6000 were from Sigma; all DNA
oligonucleotides were from Operon Technologies, Inc. (Alameda, CA); all
RNA oligonucleotides were from Dharmacon Research, Inc. (Boulder, CO);
T4 polynucleotide kinase was from New England Biolabs; single-stranded
10-nucleotide ladder was from Life Technologies, Inc.; 2.5-cm DE81
filter paper discs were from Whatman. All other reagents were of the
highest grade available from Sigma or Fisher.
-D-galactopyranoside to 500 µM. Cells were harvested by centrifugation after 4 h. 3Dpol was purified to greater than 95% purity by using
a combination of ammonium sulfate precipitation and phosphocellulose
(Whatman), S-Sepharose (Amersham Pharmacia Biotech), and Q-Sepharose
(Amersham Pharmacia Biotech) chromatographies as described previously
(5, 6, 19). The final preparation was concentrated to 468 µM by using a second Q-Sepharose column. The protein
concentration was determined by Bio-Rad protein assay using bovine
serum albumin (Pierce) as a reference.
80 °C until use. Concentrations
were determined by measuring the absorbance at 260 nm by using
calculated extinction coefficients (21).
-32P]NTPs
-32P]NTPs were diluted to 0.1 µCi/µl in
distilled, deionized H2O, and 1 µl was spotted in
triplicate onto polyethyleneimine-cellulose TLC plates (EM Science).
TLC plates were developed in 0.3 M potassium phosphate, pH
7.0, dried, and exposed to a PhosphorImager screen. Imaging and
quantitation were performed by using the ImageQuant software from
Molecular Dynamics. The purity was used to correct the specific
activity of NTP in reactions in order to calculate accurate
concentrations of product. Purity was checked before or after each
experiment and ranged from 50% to 90%.
-32P]ATP and T4 polynucleotide kinase essentially as
specified by the manufacturer. Reactions typically contained 11 µM [
-32P]ATP, 10 µM DNA or
RNA oligonucleotide, and 0.4 units/µl T4 polynucleotide kinase.
Unincorporated nucleotide was removed by passing the sample over two
consecutive 1-ml Sephadex G-25 (Sigma) spun columns.
-32P]ATP and T4 polynucleotide kinase as specified by
Life Technologies, Inc.
-32P]NTP, 500 µM NTP, primer/template,
and 3Dpol. Reactions were quenched by the addition of EDTA
to a final concentration of 50 mM. Specific concentrations
of primer/template and 3Dpol, along with any deviations
from the above, are indicated in the appropriate figure legend.
RESULTS
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Fig. 1.
Primer length and sequence composition
modulate the rate of 3Dpol-catalyzed nucleotide
incorporation. A, reactions contained 0.5 µM 3Dpol, 0.2 µM poly(rA) (93.4 µM AMP), UTP (500 µM), and
oligo(dT)n (where n = 6, 10, 15, or 20) sufficient to coat 30% of the template ([AMP]/[TMP] = 3.33). Reactions were initiated by addition of 3Dpol and
incubated at 37 °C for 5 min. The reaction volume was 50 µl.
B, reactions were performed as described above with
poly(rC), oligo(dG)n, and GTP.
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Fig. 2.
An optimal primer:template ratio exists for
maximal rates of 3Dpol-catalyzed nucleotide
incorporation. Reactions contained 3Dpol (0.5 µM), poly(rA) (60 µM AMP), UTP (20 µM), and dT15 (0-20 µM).
Reactions were initiated by addition of 3Dpol and incubated
at 37 °C for 5 min. The different symbols represent two individual
experiments.
Steady-state kinetic analysis of dTn/rAn
primer/templates
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Fig. 3.
Kinetics of nucleotide incorporation by
3Dpol are substrate-dependent. A,
time course for nucleotide incorporation with
dT15/rA16. Reaction contained 3Dpol
(2 µM) and dT15/rA16 (122 µM). Reaction was initiated by addition of
3Dpol and incubated at 37 °C. B, time course
for nucleotide incorporation with dT15/rA30
(122 µM). C, time course for nucleotide
incorporation with dG15/rC30 (122 µM).
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Fig. 4.
The rate of nucleotide incorporation exhibits
a linear dependence on 3Dpol concentration.
A, time course for nucleotide incorporation with
dT15/rA30 (122 µM) using 0.5, 1.0, or 2.0 µM 3Dpol. Reaction was initiated
by addition of 3Dpol and incubated at 37 °C.
B, rate of nucleotide incorporation (as determined from
linear regression of time courses in A) plotted as a
function of 3Dpol concentration.
-32P]UTP were resolved by denaturing PAGE
and visualized by phosphorimaging. Surprisingly, products ranging in
length from 16 to 300 nt were apparent (data not shown). In order to
verify that the origin of the long products was not contaminating
nucleic acid, an experiment was performed in which 2 µM
3Dpol, 122 µM
dT15/rA16, and 0.5 µM
[
-32P]UTP were incubated at 37 °C for 30, 60, or
90 s and then either quenched by the addition of EDTA or chased by
the addition of 1000-fold molar excess of UTP and quenched after 10 min. Products were resolved by denaturing PAGE and visualized by
phosphorimaging (Fig. 5). The
pulse-quench experiment showed that the only products formed were those
consistent with utilization of the 15-nt oligo(dT) primer. Moreover,
the products labeled in the pulse were chased into the longer products
(Fig. 5).
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Fig. 5.
Primer-dependent products that
are greater than unit length form by using
dT15/rA16. Reaction contained
3Dpol (2 µM),
dT15/rA16 (122 µM), and 0.5 µM [ -32P]UTP. Reactions were initiated
by addition of 3Dpol and incubated at 37 °C for 30, 60, or 90 s (pulse), at which time the reactions were either quenched
by addition of EDTA or chased by addition of UTP to 500 µM and incubation continued an additional 10 min.
Products were resolved by electrophoresis on a denaturing 15%
polyacrylamide gel.
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Fig. 6.
Long products are observed with
dT15/rA30 and dG15/rC30
primer/templates. Reaction contained 3Dpol (0.5 µM) and dT15/rA30 (10 µM) or dG15/rC30 (10 µM). Reactions were initiated by addition of
3Dpol and incubated at 37 °C. Products were resolved by
electrophoresis on a denaturing 8% polyacrylamide gel. The size of
selected bands from the single-stranded DNA ladder is indicated as a
reference.
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Fig. 7.
Models for long product formation:
i, distributive slippage; ii,
processive slippage; iii, template switching. See
text for details.
-32P]UTP, and heparin was initiated by addition of
poliovirus polymerase, a significant level of nucleotide incorporation
was not observed during a 60 min incubation period (Fig.
9A, Pre-Trap).
However, when polymerase and primer/template were incubated for 5 min
at 37 °C, and the reaction initiated by addition of
[
-32P]UTP and heparin, the initial rate of nucleotide
incorporation was unchanged relative to a reaction performed in the
absence of trap (Fig. 9A, cf. Trap and No
Trap). The reaction terminated prematurely relative to that in the
absence of trap; therefore, products most likely result from complexes
that assembled during preincubation. Analysis of reaction products by
phosphorimaging after denaturing PAGE indicated that long products
formed in the presence of heparin, i.e. without dissociation
of polymerase (Fig. 9B). These data are consistent with a
processive slippage mechanism.
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Fig. 8.
3Dpol is inhibited by
heparin. Reaction contained 3Dpol (0.28 µM), poly(rA) (60 µM AMP), dT15
(1.5 µM), UTP (20 µM), and heparin 6000 (0-10 µM). Reaction was initiated by addition of
3Dpol and incubated at 37 °C for 10 min. The
solid line represents the fit of the data to the
quadratic equation that gives a Ki for heparin 6000 of 33 ± 4.5 nM.
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Fig. 9.
Heparin-resistant complexes produce long
products. A, reactions contained 3Dpol (0.5 µM) and dT15/rA30 (20 µM), with or without heparin 6000 (100 µM).
3Dpol was incubated with dT15/rA30
at 37 °C for 1 min and the reaction was initiated by addition of UTP
( , No Trap) or UTP and heparin (
,
Trap). In the control experiment (
),
Pre-Trap), heparin was included during the initial
incubation and the reaction initiated by addition of UTP. B,
reaction products resolved by electrophoresis on a denaturing 10%
polyacrylamide gel.
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Fig. 10.
Heparin concentration modulates the activity
of "heparin-resistant" complexes. Reactions contained
3Dpol (0.5 µM),
dT15/rA30 (20 µM), and heparin
6000 (0, 10, or 100 µM). 3Dpol was incubated
with dT15/rA30 at 37 °C for 1 min, and the
reaction was initiated by addition of UTP ( ), UTP and 10 µM heparin (
), or UTP and 100 µM heparin
(
). In the control experiments, heparin was included during the
initial incubation at either 10 µM (
) or 100 µM (
) and the reaction initiated by addition of
UTP.
-32P]UTP (500 µM) were incubated at
30 °C for 3 min to assemble stable elongation complexes and initiate
RNA synthesis. The elongating complexes were then diluted into
reactions containing heparin (10 µM) such that the
complexes were diluted 10- or 50-fold. Thus, in one reaction, the final
concentrations of polymerase and primer/template were 0.5 and 1 µM, respectively; in the other, the final concentrations of polymerase and primer/template were 0.1 and 0.2 µM,
respectively. Heparin was added to the reaction in order to preclude
reinitiation. Please note that the x axis (time) in this
experiment and subsequent experiments represents time after the initial
3-min incubation. Therefore, at t = 0 the product
formed is that formed during the initial 3-min incubation. Because
processive slippage is a first order process, this reaction should be
insensitive to dilution. Product formed per molecule of polymerase
should be independent of polymerase and primer/template concentration
if polymerase-primer/template-nucleotide complexes are preformed. As
shown in Fig. 11A, this was
not the case. The reaction was sensitive to dilution. In order to
demonstrate directly that the diminution in the amount of product
formed per molecule of polymerase observed upon dilution was a
consequence of a reduction in the concentration of acceptor RNA rather
than dissociation of polymerase-primer/template complexes, we performed the experiment described above and supplemented the diluted reaction mixtures with acceptor RNA. As shown in Fig. 11B, product
formed per molecule of polymerase was unchanged, thus confirming that the primary effect of dilution in the experiment shown in Fig. 11A was a reduction in the concentration of acceptor RNA.
Taken together, these data are consistent with a bimolecular reaction, such as template switching, contributing to formation of long products.
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Fig. 11.
Nucleotide incorporated per
3Dpol molecule is diminished by dilution.
A, reactions were initiated by mixing 3Dpol (5 µM), dT15/rA30 (10 µM), UTP (500 µM), and
[ -32P]UTP (0.2 µCi/µl) and incubated at 30 °C
for 3 min, at which time reactions were diluted such that UTP
concentration was not changed, heparin was added to a final
concentration of 10 µM, and the final concentrations of
3Dpol and dT15/rA30 were either 0.5 µM 3Dpol and 1 µM
dT15/rA30 (
) or 0.1 µM
3Dpol and 0.2 µM
dT15/rA30 (
). After dilution, reactions were
quenched at the indicated times by addition of EDTA to a final
concentration of 50 mM. B, reactions were
performed as described above; however, the diluted reactions were
supplemented with rA30 acceptor template to a final
concentration of 100 µM.
Acceptor and + rA30 Acceptor
panels). These effects are not a result of reinitiation as heparin
was added along with the acceptor template.
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Fig. 12.
Nucleotide incorporated by
3Dpol is stimulated by acceptor template.
A, reactions contained 0.5 µM
3Dpol, 1 µM
dT15/rA30, and either 0 µM
rA30 and 0 µM heparin ( ), 100 µM rA30 and 0 µM heparin (
),
or 100 µM rA30 and 10 µM
heparin (
). Reactions were initiated by addition of
3Dpol and incubated at 30 °C. B,
3Dpol (5 µM),
dT15/rA30 (10 µM), UTP (500 µM), and [
-32P]UTP (0.2 µCi/µl) were
incubated at 30 °C for 3 min, at which time reactions were diluted
such that the final concentrations of 3Dpol and
dT15/rA30 were 0.5 and 1 µM,
respectively, UTP concentration was not changed, heparin was added to a
final concentration of 10 µM, and rA30
acceptor template was added to a final concentration of 0 µM (
), 10 µM (
), 50 µM
(
), or 100 µM (
). After dilution, reactions were
quenched at the indicated times by addition of EDTA to a final
concentration of 50 mM. C, UMP incorporated as a
function of rA30 acceptor template concentration obtained
from reactions as described in B. The solid
line represents the fit of the data to a hyperbola with a
K0.5 for rA30 acceptor of 5.4 ± 2.6 µM.
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Fig. 13.
Product length is increased by an RNA
acceptor template and decreased by a DNA acceptor template.
Reactions were initiated by mixing 3Dpol (5 µM), dT15/rA30 (10 µM), and [ -32P]UTP (1 µM)
and incubated at 30 °C for 3 min, at which time heparin (10 µM), UTP (500 µM), and no acceptor
template, rA30 acceptor template (100 µM), or
dA30 acceptor template (100 µM) was added to
the reactions such that the final concentrations of 3Dpol
and dT15/rA30 were 0.5 and 1 µM,
respectively. After dilution, reactions were quenched at the indicated
times (
t) by addition of EDTA to a final concentration of
50 mM. Products were resolved by electrophoresis on a
denaturing 10% polyacrylamide gel. The size of selected bands from the
single-stranded, DNA ladder is indicated as a reference.
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Fig. 14.
Primer extension by 3Dpol on
dT15/rA30. Reaction was initiated by
mixing 3Dpol (5 µM), an end-labeled
[32P]dT15/rA30 (10 µM) primer/template, and UTP (1 µM) and
incubated at 30 °C for 3 min, at which time heparin (10 µM) and additional UTP (500 µM) was added
to the reaction such that the final concentrations of 3Dpol
and dT15/rA30 were 0.5 and 1 µM,
respectively. After dilution, the reaction was quenched at the
indicated times ( t) by addition of EDTA to a final
concentration of 50 mM. The lane indicated
by
is the end-labeled
[32P]-dT15/rA30 primer/template
alone. Products were resolved by electrophoresis on a denaturing 10%
polyacrylamide gel. The size of selected bands from the
single-stranded, DNA ladder is indicated as a reference.
DISCUSSION
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Fig. 15.
Model for 3Dpol-catalyzed
nucleotide incorporation on homopolymeric primer/templates. Upon
mixing 3Dpol and primer/template, one of two possible
complexes form. i, formation of unproductive complexes. This
would include binding of template in the primer-binding site and
binding of 3Dpol to single-stranded nucleic acid located
upstream or downstream of primer. ii, formation of
"heparin-resistant" complexes capable of slippage synthesis and
template switching. The initial binary complex is drawn to reflect a
more stable association between 3Dpol and primer than
3Dpol and template. An increase in formation of this
complex might occur by optimizing the stability of the duplex region of
primer/template, employing a protein primer, or initiating RNA
synthesis de novo.
The formation of products greater than unit length by polymerases when using templates consisting of "simple" sequences is not novel (30-33). The mechanism of formation of these products, however, appears to differ depending upon the class of polymerase being investigated (30-33). Regardless of the mechanism of formation of long products, the fact that the RdRPs from poliovirus, bovine viral diarrhea virus,3 and hepatitis C virus3,4 all share this property is quite important to note. The vast majority of biochemical studies performed to date on these enzymes have evaluated the synthesis of radioactive polymer from radioactive nucleotide and homopolymeric primer/template substrates. Therefore, the results from this type of analysis may be misinterpreted because a small fraction of enzyme in any reaction gives rise to the greatest fraction of polymerized nucleotide. Mutations in 3Dpol-coding sequence that alter the ability of the enzyme to form complexes competent to form long products might appear to have a significant decrease in activity on homopolymeric primer/templates relative to wild-type 3Dpol without any substantial change observed in activity on heteropolymeric primer/templates. Therefore, both quantitative and qualitative evaluation of reaction products should always be performed.
Why is such a small fraction of 3Dpol-primer/template complexes capable of forming products greater than unit length? This may be related to the fact that complexes which form these products have a very stable association with nascent chain as they are resistant to challenge by heparin. Formation of such stable complexes between polymerase and nascent chain may be similar to those that form with DNA-dependent RNA polymerases (38-40). However, formation of these complexes from a preformed primer/template may require disruption of base pairing between primer and template (Fig. 15, ii). This would explain the decrease in nucleotide incorporation as the thermodynamic stability of the primer/template is increased (Fig. 1). In vivo, however, RNA synthesis is initiated using protein primer, VPg, which would not present such a dilemma (10). VPg can also be used to initiate RNA synthesis in vitro (41). In fact, VPg-primed RNA synthesis on templates similar to those employed here also yields products greater than unit length.5
As illustrated in Fig. 15i, poliovirus 3Dpol that is not competent to form long products has one alternative fate. Given the stochastic nature of 3Dpol binding to primer/template and limited ability of the enzyme to recognize specifically a primer/template junction, enzyme is "lost" due to unproductive binding. This contrasts significantly with the biological scenario in which an elaborate array of structured RNA, virus-encoded factors and possibly cellular factors are thought to cooperate in the recruitment of 3Dpol to the appropriate site of initiation (11). Of course, the formation of long products in these reactions would sequester enzyme dissociating from the complex in this alternative pathway. Enzyme sequestration probably contributes to the biphasic nature of the kinetics of NMP incorporation (Figs. 3 and 9A, for example).
Is there a biological significance to formation of products greater than unit length? In the case of poliovirus, minus-strand RNA synthesis initiates within the A-tract at the 3' end of genomic RNA (10). As a result, the use of oligo(rA) (and perhaps poly(rA)) as a template may be reasonable. Studies of poliovirus minus-strand RNA have shown that the U-tract at the 5'-end of this RNA is the same length as the A-tract at the 3'-end of genomic RNA (42, 43). If slippage occurred readily in the A-tract, one might expect the expansion of these ends over time. However, this phenomenon has not been reported to date. It is also plausible that the presence of other viral proteins, such as 3AB or 3CD, prevent slippage from occurring.
Our data are most consistent with a template-switching mechanism. Template switching is thought to be the primary mechanism of recombination between viral genomes (44, 45). Furthermore, RNA recombination between viral genomes is thought to be necessary for repair of defective genomes and possibly for the acquisition of new virus-encoded functions (44, 45). In most cases, copy-choice recombination, i.e. switching from internal regions, occurs (44, 45). However, in order to repair genomes damaged by the action of ribonucleases, for example, forced-copy-choice recombination, or switching as a result of reaching the end of the template, may be necessary. Whether the template switching described herein reflects a copy-choice or a forced-copy-choice mechanism remains to be determined.
The ability to observe copy-choice recombination between poliovirus
genomes in a cell-free system has been demonstrated recently by
Kirkegaard (46) and Wimmer (47). Notwithstanding, these experiments
utilized a HeLa cell extract, and all of the poliovirus proteins were
present. Our results suggest that poliovirus RdRP alone may be
sufficient for template switching in vitro and, possibly, in vivo. Studies employing heteropolymeric donor and
acceptor templates should verify that template switching occurs.
Furthermore, the use of heteropolymeric substrates should permit the
elucidation of the elements of polymerase and nucleic acid required for
template switching in vitro thus providing greater insight
into the mechanism of RNA recombination in vivo.
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ACKNOWLEDGEMENTS |
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We thank Aniko Paul and Eckard Wimmer for providing us with the necessary reagents to initiate our work in this area. We are also grateful to Dr. Kevin Raney and members of the Cameron laboratory for their critical evaluation of the manuscript.
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FOOTNOTES |
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* This work was supported in part by Howard Temin Award CA75118 from the NCI, National Institutes of Health (to C. E. C.).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
To whom correspondence should be addressed. Tel.: 814-863-8705;
Fax: 814-863-7024; E-mail: cec9{at}psu.edu.
The abbreviations used are: RdRP, RNA-dependent RNA polymerase; PAGE, polyacrylamide gel electrophoresis; nt, nucleotide(s).
2 D. W. Gohara, J. J. Arnold, and C. E. Cameron, manuscript in preparation.
3 J. J. Arnold and C. E. Cameron, unpublished observations.
4 R. Bartenschlager, personal communication.
5 A. V. Paul, personal communication.
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REFERENCES |
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