(Received for publication, February 19, 1997, and in revised form, April 30, 1997)
From the Department of Biological Chemistry and
Molecular Pharmacology, Harvard Medical School,
Boston, Massachusetts 02115 and the ¶ Biology Department,
Suffolk University, Boston, Massachusetts 02114
The gene 4 proteins of bacteriophage T7 provide both primase and helicase activities at the replication fork. Efficient DNA replication requires that the functions of the gene 4 protein be coordinated with the movement of the T7 DNA polymerase. We show that a carboxyl-terminal domain of the gene 4 protein is required for interaction with T7 DNA polymerase during leading strand DNA synthesis. The carboxyl terminus of the gene 4 protein is highly acidic: of the 17 carboxyl-terminal amino acids 7 are negatively charged. Deletion of the coding region for these 17 residues results in a gene 4 protein that cannot support the growth of T7 phage. The purified mutant gene 4 protein has wild-type levels of both helicase and primase activities; however, DNA synthesis catalyzed by T7 DNA polymerase on a duplex DNA substrate is stimulated by this mutant protein to only about 5% of the level of synthesis obtained with wild-type protein. The mutant gene 4 protein can form hexamers and bind single-stranded DNA, but as determined by native PAGE analysis, the protein cannot form a stable complex with the DNA polymerase. The mutant gene 4 protein can prime DNA synthesis normally, indicating that for lagging strand synthesis a different set of helicase/primase-DNA polymerase interactions are involved. These findings have implications for the mechanisms coupling leading and lagging strand DNA synthesis at the T7 replication fork.
The economy of proteins involved in the replication of the linear double-stranded DNA chromosome of bacteriophage T7 has made it an attractive model for dissecting the protein-protein interactions that are essential for coordination of the multiple reactions that occur at a replication fork (1). The four proteins that account for the basic reactions at the T7 replication fork are T7 gene 5 DNA polymerase, the host Escherichia coli thioredoxin, T7 gene 4 helicase/primase, and the T7 gene 2.5 single-stranded DNA (ssDNA)1 binding protein. The specific interactions that occur among these relatively few proteins are essential for T7 DNA replication and, hence, phage growth (1-3). For example, the binding of E. coli thioredoxin and T7 gene 5 protein forms a stable one-to-one complex with the ability to catalyze the template-directed polymerization of nucleotides in a highly processive manner (4-11). This dramatic effect of a specific protein-protein interaction has led to the identification of a unique 76-residue domain in the T7 gene 5 protein that is responsible for this interaction with its processivity factor (4-7).
In addition to the interaction of the gene 5 protein with thioredoxin, each of the three phage-encoded replication proteins interact with one another. The gene 5 protein interacts with the hexameric gene 4 protein that provides both helicase and primase activities at the replication fork (12). In turn, the essential gene 2.5 ssDNA binding protein interacts with both the polymerase and the gene 4 protein, interactions that enhance both polymerase and primase activities (12-14).
The interactions of the T7 DNA polymerase with the T7 gene 4 protein
warrants specific attention because these interactions are thought to
coordinate leading and lagging strand DNA synthesis at the replication
fork (3). In considering the interactions between these two proteins,
it is important to consider the multiple reactions catalyzed by the
gene 4 protein. Gene 4 encodes two colinear polypeptides of 56 and 63 kDa. The 56-kDa form is translated from an internal initiation codon
that is in-frame with the coding sequence for the 63-kDa protein (15).
Both forms of the protein have helicase activity, bind ssDNA in the
presence of a nucleoside triphosphate, and translocate 5 to 3
along
the DNA strand using the energy of nucleoside 5
-triphosphate
hydrolysis (15-18). Upon encountering duplex DNA, the gene 4 protein
separates the strands processively, provided that there are 6 to 7 unpaired nucleotides on the 3
strand (19). The T7 DNA
polymerase-thioredoxin complex by itself is unable to synthesize DNA if
it encounters double-stranded regions of DNA and so requires the strand
separation ability of the helicase to replicate a duplex template (20,
21).
The 63-kDa gene 4 protein has 63 amino acids at its amino terminus that are not found on the 56-kDa protein, and this domain contains a Cys4 zinc binding motif (22, 23). The 63-kDa gene 4 protein catalyzes the template-directed synthesis of oligoribonucleotides at specific recognition sites on ssDNA, a reaction that is dependent on the presence of the zinc binding motif (18, 22-26). T7 DNA polymerase then uses these oligoribonucleotides as primers to initiate synthesis on ssDNA templates. Inasmuch as the 63-kDa gene 4 protein has both helicase and primase activities, it alone is sufficient to support T7 DNA replication and phage growth (27, 28).
The quaternary structure of the active form of the gene 4 protein, with regard to both helicase and primase activities, is a hexamer (29-31). In vivo the hexamer is most likely composed of both small and large forms of the gene 4 protein (32). Bound ssDNA appears, in electron micrographs, to pass through the center of the ring-shaped gene 4 hexamer (33). It would not be an oversimplification to conclude that this observation most likely explains the requirement that gene 4 protein form a hexamer to bind ssDNA (29). Studies using a nucleotide binding site mutant have shown that translocation of the gene 4 protein on ssDNA is inhibited when the hexamer consists of a mixture of wild-type monomers and monomers of the nucleotide binding site mutant gene 4 protein (32). These latter studies show that the subunits within a hexamer must interact in a coordinated manner to translocate on ssDNA and to function as a helicase and a primase.
The potential interactions between the gene 4 protein and T7 DNA polymerase are numerous, as evidenced by the above considerations, and suggest that the gene 4 protein may play a pivotal role in coordinating leading and lagging strand DNA synthesis since it functions in both. First, an interaction of the two proteins would appear essential to coordinate the movement of the polymerase with that of the helicase as it unwinds the duplex during leading strand synthesis. Second, on the lagging strand the primase must stabilize the newly synthesized tetra-ribonucleotides until they are extended by the polymerase (26, 34, 35). The ability of the polymerase to use the oligoribonucleotides as primers is dependent on the presence of the gene 4 protein, a requirement that dictates an interaction between the two proteins. Finally, the coupling of leading and lagging strand DNA synthesis at the T7 replication fork (3) most likely relies on the ability of the gene 4 hexamer to interact with both the leading and lagging strand DNA polymerases.
Earlier studies demonstrated an interaction between T7 DNA polymerase and gene 4 protein in the presence and absence of M13 ssDNA (12, 36), and numerous studies have provided indirect evidence of physical interactions based on the activities of the two proteins (3, 20, 21, 26, 34, 35). In this report we show a direct interaction of the T7 DNA polymerase and the gene 4 protein and identify the acidic carboxyl terminus of the gene 4 protein as an essential domain for this interaction. Furthermore, we find that an altered gene 4 protein that cannot interact with T7 DNA polymerase is, nevertheless, capable of catalyzing the unwinding of duplex DNA. At a replication fork the helicase activity of the mutant protein is uncoupled from the polymerization reaction resulting in a cessation of DNA synthesis.
Materials
Bacterial Strains and BacteriophageE. coli
HMS174(DE3) was used for protein production (37), and E. coli DH5 (Life Technologies, Inc.) was used for subcloning and
complementation analysis. Bacteriophage T7 wild-type (38) and T7
4-1 lacking gene 4 have been described (39).
The mutant T7 gene 4 carboxyl-terminal
deletion protein was purified following the procedure described
previously for the wild-type gene 4 protein (29). The gene II
endonuclease of bacteriophage f1 was purified from E. coli
strain Dh5/plaqI-AH3/pDG117IIa-G73A (provided by K. Horiuchi, National
Institute of Genetics, Japan) as described (40). T7 DNA polymerase
(gene 5 protein-thioredoxin complex), native and 28, has been
described (41). The plasmid used as a substrate for the gene II
protein, pET24a(+) containing a bacteriophage f1 origin of replication
sequence, was purchased from Novagen. M13mp6 ssDNA was prepared as
described (42). Oligonucleotides were synthesized by the core facility
of the Department of Biological Chemistry and Molecular Pharmacology,
Harvard Medical School.
Methods
Mutagenesis and Complementation AnalysisIn
vitro mutagenesis of bacteriophage T7 gene 4 to delete the region
encoding the last 17 amino acids of the protein was accomplished using
T7 DNA as the template in the polymerase chain reaction. The following
oligonucleotides were used: (CTD)
5-AATCCAGCAGTTGGTTTACCCTGAGTAACTTGATGGTTCAAGCC-3
is complementary to T7 nucleotides 13186-13211 with a new termination codon (bold type) and an introduced PflMI site (underlined),
and (SN101) 5
CTGGGGTGGTGCTGGTCG-3
, which is complementary to T7 bases
12931-12948. Amplification of the DNA was performed using "Ultma"
DNA polymerase from Perkin-Elmer, and the resulting 301-bp DNA fragment
was purified, cleaved with PflMI and AflII, and
inserted into pGP4-G64S10 (32) that was cleaved with the
same restriction enzymes. The DNA sequence of the newly inserted region
was determined to confirm that no undesired changes were present. The
complementation analysis was preformed as described previously
(29).
The hydrolysis of dTTP by gene
4 protein in the presence of ssDNA was measured as described previously
(32). Each 20-µl reaction contained 200 nM gene 4 protein, 50 µM M13mp6 ssDNA (nucleotide equivalents), and
the indicated concentration of [32P]dTTP in dTTPase
buffer (40 mM Tris-HCl, pH 7.5, 50 mM NaCl, 10 mM MgCl2, and 10 mM DTT). The
reaction mixtures were incubated at 30 °C for 20 min, and the amount
of dTTP converted to dTDP was determined by polyethyleneimine-cellulose
thin layer chromatography and Phosphor-Image analysis (Molecular
Dynamics).
The DNA used as a substrate in
the helicase assay consisted of circular M13mp6 ssDNA annealed to a
36-base radiolabeled oligonucleotide, 5-[32P]-GGATCCGGGAATTCGTAATCGCCTAAGGCTAAACGG-3
. The 20 5
-bases of the oligonucleotide are complementary to M13mp6 ssDNA, and
the 16 3
-bases do not base pair, so that after annealing the
oligonucleotide has a 16-base 3
-single-stranded tail. T7 gene 4 helicase requires a 3
-tail of at least 8 nucleotides to initiate
strand separation (19). The 36-mer was 5
-end-labeled using
[
-32P]ATP and T4 polynucleotide kinase. The substrate
was assembled by incubating the M13 DNA with the radiolabeled
oligonucleotide in a slight molar excess, at 65 °C for 5 min, and
cooling to 30 °C over 20 min. The substrate was used in the helicase
reaction without further purification.
The helicase reaction mixture (60 µl) consisted of 20 nM helicase substrate, 10 nM gene 4 protein, 2 mM dTTP, and dTTPase buffer. The reaction mixture was incubated at 30 °C, samples were removed at the indicated time, and the reaction was stopped by adding EDTA to 20 mM. Helicase activity was measured by separation of the DNA in the reaction in a nondenaturing agarose gel followed by PhosphorImage analysis to quantify the amount of radiolabeled DNA in each band. Helicase activity was reported as the percentage of oligonucleotide displaced from the M13 DNA.
The primase activity of the gene 4 proteins was measured as
described previously (29). The reaction mixtures (20 µl)
contained dTTPase buffer, 50 mM potassium
glutamate, 40 µM M13mp6 ssDNA (nucleotide equivalents), 5 nM T7 DNA polymerase, 300 µM each nucleotide
(dATP, dCTP, dGTP, ATP, CTP, GTP, and UTP), 2 mM
[32P]dTTP, and the indicated concentrations of gene 4 protein. The reaction mixtures were incubated for 20 min at 30 °C,
and DNA synthesis was quantified by measuring the amount of radioactive dTMP incorporated into DNA using DEAE filter binding and scintillation counting.
The assay measuring the
synthesis of oligoribonucleotides by the T7 gene 4 protein has been
described (23, 24). Briefly, the reaction mixture (10 µl) contained
40 mM Tris-HCl, pH 7.5, 10 mM
MgCl2, 10 mM DTT, 100 mg/ml bovine serum
albumin, 50 mM potassium glutamate, pH 7.5, 0.6 mM each of dATP, dCTP, dGTP, and dTTP, 0.3 mM
each of ATP, [-32P]CTP, 10 nM M13 ssDNA,
and 60 nM gene 4 protein. After incubation at 30 °C for
5 or 10 min, the reaction was stopped by the addition of EDTA to 20 nM. The products of the reaction were examined by electrophoresis in a 25% polyacrylamide gel containing 2 M
urea.
DNA synthesis catalyzed by T7 DNA polymerase and gene 4 protein through regions of dsDNA was examined using two different DNA substrates. One assay used a double-stranded plasmid containing a single site-specific nick, and the second assay used a 70-nucleotide circular dsDNA molecule containing a preformed replication fork.
In the first assay the DNA substrate containing a site-specific nick was constructed by incubating plasmid DNA containing the cloned f1 origin of replication with the bacteriophage f1 gene II endonuclease. The gene II endonuclease introduces a single phosphodiester bond cleavage at a specific site within the f1 origin of replication (40). The nicking reaction (25 µl) containing 10 pmol of pET24a(+) plasmid DNA, 20 mM Tris-HCl, pH 8.0, 80 mM KCl, 5 mM MgCl2, 5 mM DTT, and 10 ng of gene II protein were incubated at 30 °C for 30 min. Control reactions indicated that these conditions were sufficient to nick all of the plasmid DNA as determined by agarose gel electrophoresis and ethidium bromide staining. The nicked plasmid was dispensed directly into the DNA synthesis reactions.
DNA synthesis was measured in reactions containing 2 mM
[-32P]dTTP, 300 µM dGTP, dATP, and dCTP,
40 nM T7 DNA polymerase
28, and the indicated
concentration of gene 4 protein in dTTPase buffer. The 20-µl reaction
mixtures were incubated at 30 °C for 10 min and then terminated by
the addition of 4 µl of 60 mM EDTA, 0.6% SDS, 10%
glycerol, and 0.01% bromphenol blue. The products of the reaction were
separated by electrophoresis in a 0.8% agarose gel, dried, and
analyzed by PhosphorImaging.
The second assay used a preformed replication fork, consisting of a
70-bp circular DNA molecule with a 5-single-stranded tail of 40 nucleotides, to examine strand displacement synthesis. This
mini-replication fork was synthesized by converting a 70-base oligonucleotide (AE06,
5
-GATCCAGACCATCCTAGCTCGTTTGGAGAGGTTAAGCTTACTACCTAGGTAACGTTAGCGATTGATGTAG-3
) into a single-strand circle using a 20-base oligonucleotide to splint
the ends together. The 70-mer, AE06, was first phosphorylated with T4
polynucleotide kinase in a standard reaction and then hybridized with a
20-mer (AE07 5
GGTCTGGATCCTACATCAAT-3
). The 20-base
oligonucleotide is complementary to the 5
-10 bases and 3
-10 bases of
the 70-mer so that, when the two oligonucleotides are annealed, the
ends of the 70-mer are brought together and can be covalently joined
into a circle by T4 DNA ligase. The single-stranded 70-nucleotide
circle was purified by separating the products of the ligation reaction
on a 6 M urea, 10% polyacrylamide gel and eluting the
circle from the corresponding region of the gel. The circular molecule
was then annealed to a partially complementary 110-base oligonucleotide
(AE10,
5
-(T)40CCAAACGAGCTAGGATGGTCTGGATCCTACATCAATCGCTAACGTTACCTAGGTAGTAAGCTTAACCTCT-3
) with a sequence such that the 5
-prime 40 bases form a
single-stranded tail. The annealing reaction contained the
70-nucleotide circle in a slight molar excess (1:0.8) over the
110-base oligonucleotide. Since the excess circular DNA cannot
contribute to the DNA synthesis reaction, the substrate was used
without further purification.
DNA synthesis using the mini-fork DNA substrate was assayed in a
reaction mixture (50 µl) containing, 40 mM Tris, pH 7.5, 10 mM MgCl2, 10 mM DTT, 100 mg/ml
bovine serum albumin, 50 mM potassium glutamate, pH 7.5, and 600 µM each of [-32P]dGTP, dATP,
dCTP, dTTP, and 100 nM DNA substrate. The DNA polymerase and gene 4 protein were mixed and preincubated for 5 min at 4 °C at
a concentration of 8.3 µM gene 4 protein, and 2.8 µM T7 DNA polymerase, and then diluted in dTTPase buffer
and added to the reaction mixture to a final concentration of 20 nM T7 DNA polymerase and 60 nM gene 4 protein.
Aliquots of 8 µl were taken at 1-min intervals for 5 min and the
reaction stopped with EDTA. The products of the reaction were examined
by agarose gel electrophoresis and PhosphorImage analysis.
The interaction of T7 gene 4 protein and T7
DNA polymerase was examined using a non-denaturing PAGE gel-shift
assay. The analysis was performed as described previously (29), with
the following changes. Each binding reaction contained 3 µM gene 4 protein, 0.8 µM DNA polymerase, 1 mM ,
-methylene dTTP, 40 mM Tris-HCl, pH
7.5, 150 mM NaCl, 10 mM MgCl2, 10 mM DTT, and 1.8 µM 5
-32P-labeled
26-mer (M13-1, 5
-GCTACTACTATTAGTAGAATTGATGC-3
). The reaction mixtures
were incubated at 30 °C for 10 min before they were applied to the
gel. To obtain adequate separation of the DNA-protein complexes
(380-450 kDa) and retain the unbound DNA (8.5 kDa) in the gel, we used
a step gradient polyacrylamide gel. The upper half of the 10 × 8 × 0.1-cm gel was 5% polyacrylamide and the lower portion was
15% polyacrylamide with 5% sucrose included to prevent extensive
mixing of the gel layers. Electrophoresis was at 8 V/cm for 1.5 h,
and the gel was then fixed in 7% trichloroacetic acid, dried, and
examined by PhosphorImage analysis.
The interaction of the
gene 4 proteins and DNA polymerase was also examined by surface plasmon
resonance using a BIAcore apparatus (Pharmacia Biosensor). The flow
buffer consisted of 10 mM Hepes, pH 7.5, 50 mM
NaCl, 10 mM magnesium acetate, 5 mM DTT, 1%
glycerol, and 0.05% Tween 20, with a flow rate of 5 µl/min for all
experiments. A 3-biotinylated 33-base oligonucleotide
(SN217, 5
-CCCCCCCCCCTTGGCACTCGCCGTCGTTTTCGA-biotin-3
) was bound to a streptavidin biosensor chip (SA5, Pharmacia
Biosensor) by a 4-min injection of a solution containing 240 nM oligonucleotide, 10 mM Tris-HCl, pH 7.5, 1 mM EDTA, 300 mM NaCl. Gene 4 protein was bound
to the DNA containing biosensor chip by a 45-µl injection of a
solution containing flow buffer, 240 nM gene 4 protein, 100 nM
,
-methylene dTTP, and 150 mM NaCl. T7
DNA polymerase
28 was applied to the chip by a 4-min injection at a
concentration of 180 mM in flow buffer. Proteins were
removed from the biosensor chip by a 4-µl injection of 0.5% SDS and
30 mM EDTA.
The
carboxyl-terminal 17 amino acids of T7 gene 4 protein are predominantly
negatively charged, of the terminal 17 amino acids, 7 residues (41%)
have acidic side chains (Table I). Overall only 13.2%
of the 566 residues of the gene 4 protein are negatively charged. To
determine the role this acidic region might play in the function of the
gene 4 protein, we created a gene 4A clone lacking the coding region
for the carboxyl-terminal 17 amino acids. To make this deletion a
275-bp polymerase chain reaction fragment with a new termination codon
was substituted for the corresponding region of the wild-type coding
sequence in a plasmid containing gene 4. The DNA sequence of this new
fragment was determined, and no undesired changes were found. The
resulting plasmid, pGP4-63Ct, encodes a carboxyl-terminal deleted
gene 4A helicase/primase with a molecular mass of approximately 60,400 (Fig. 1). In this report the gene 4A protein with the
17-amino acid carboxyl-terminal deletion will be referred to as the
"gene 4A-
Ct protein."
|
The gene 4A proteins used in this study, both wild-type and the gene
4A-Ct protein, contain the mutation Met-64 to Gly, which was
introduced to prevent synthesis of the 56-kDa gene 4B protein. This
mutation has no detectable affect on any of the activities of the
enzyme (28, 39). A similarly altered gene 4A protein, M64L, also
behaved as did the wild-type protein (27), and so in this report we
refer to the gene 4A M64G protein as "wild type."
A complementation assay was performed to assess the in vivo
function of the gene 4A protein with the carboxyl-terminal deletion mutation. The results of this assay demonstrate that the gene 4A-Ct
protein does not support the replication of a gene 4 deleted T7 phage,
T7
4-1 (Table I). No T7 phage suppressors of this mutant were
observed, even at phage titers of 108 plaque-forming
units/ml. These findings strongly indicate that the carboxyl terminus
of the gene 4 protein is essential for its role in vivo.
To determine the basis for the loss of
function in vivo, the gene 4A-Ct protein was purified for
biochemical analysis. The purified protein was homogeneous as
determined by the presence of a single protein band of 60-kDa in
SDS-PAGE (Fig. 1). The ability of the gene 4 protein to translocate on
ssDNA and unwind dsDNA is dependent on its ability to hydrolyze
nucleoside triphosphates, dTTP being the preferred nucleotide (17, 32,
43). Consequently, the nucleotide hydrolyzing activity of the gene
4A-
Ct protein was compared with that of the wild-type protein. With
M13 ssDNA as an effector, dTTP hydrolysis by the gene 4A-
Ct protein
is essentially the same as that of the wild-type protein (Fig.
2). Comparison of the kinetic constants derived from a
Lineweaver-Burk plot (not shown) of the data presented in Fig. 2 shows
very little difference between the dTTP hydrolysis activity of the two
proteins. The Km (dTTP) for the gene
4A-
Ct protein in the presence of ssDNA is 3.73 and 3.87 mM for the wild-type protein. The slight difference between
the estimated Vmax of the gene 4A-
Ct protein, 78.2 pmol·s
1, and the wild-type gene 4A protein, 85.3 pmol·s
1, is not significant and would not be expected
to prevent phage replication, especially since mutant gene 4 proteins
with less than 50% of the Vmax of the wild-type
protein have been shown to support phage growth (29). The gene 4 protein has a high affinity for dTTP, but it can hydrolyze other
nucleoside triphosphates as well. The ability of the mutant protein to
hydrolyze ATP was examined and found to be similar to that of the
wild-type protein (data not shown). Thus, the ability of the mutant
protein to hydrolyze nucleotides does not appear to be affected by this
carboxyl-terminal deletion.
Helicase Activity
Although the ability of the gene 4A-Ct
protein to hydrolyze nucleotides is intact, it could still be defective
in its ability to use the energy of nucleotide hydrolysis to
translocate on ssDNA and unwind dsDNA. We examined the helicase
activity of the mutant protein using the DNA substrate diagrammed in
the inset of Fig. 3A. The
substrate consists of a radiolabeled 36-base oligonucleotide with a
sequence such that when annealed to single-stranded M13 DNA it leaves
an unpaired 16-nucleotide 3
-tail. The gene 4 protein requires at least
8 unpaired 3
-nucleotides for strand separation to occur (19). As shown
in Fig. 3A the ability of the gene 4A-
Ct protein to
dissociate the DNA strands of the substrate is essentially the same as
that of wild-type protein.
This assay also demonstrates the ability of the gene 4 proteins to
translocate 5 to 3
on ssDNA. Since the gene 4 protein binds ssDNA
randomly (43), it must translocate along the M13 ssDNA to displace the
bound oligonucleotide. The average distance the gene 4 protein must
translocate to reach the oligonucleotide from its initial binding
location is half the number of nucleotides in M13 ssDNA or about 3,600 nucleotides. Consequently, the time course of strand separation on this
hybrid DNA substrate indicates that both the wild-type and gene
4A-
Ct protein translocate on ssDNA at approximately the same
rate.
The primase activity of the gene 4A protein
is required for the initiation of lagging strand DNA synthesis and is
essential for phage viability (27, 28). In the presence of
ribonucleoside 5-triphosphates, the T7 gene 4A protein catalyzes the
synthesis of oligoribonucleotides at specific primase recognition sites on ssDNA (22, 44). These oligoribonucleotides are then used as primers
by T7 DNA polymerase to initiate DNA synthesis. To assess the primase
activity of the gene 4A-
Ct protein, we measured both its ability to
prime DNA synthesis catalyzed by T7 DNA polymerase on M13 ssDNA and its
ability to synthesize the template-dependent oligoribonucleotides used as primers. The results of these assays demonstrate that the gene 4A-
Ct protein can perform both of these related functions as well as the wild-type protein (Fig. 3,
B and C). The ability of the mutant gene 4 protein to synthesize and present primers in a manner that they can be
used by the DNA polymerase is shown by the comparable levels of DNA
synthesis observed in the coupled assay (Fig. 3B). We also
demonstrate directly that the mutant gene 4 protein synthesizes levels
of tetrameric oligoribonucleotides equivalent to that of the wild-type
protein (Fig. 3C). Thus, the gene 4A-
Ct protein is not
defective in either its ability to catalyze the synthesis of
oligoribonucleotides or to prime lagging strand synthesis.
The
experiments presented so far demonstrate that the abilities of the gene
4A-Ct protein to hydrolyze nucleotides, translocate on ssDNA, unwind
duplex DNA, and prime lagging strand DNA synthesis are unaffected by
the carboxyl-terminal deletion. Nevertheless, this mutant protein
cannot support phage replication in vivo. It seemed likely
that the carboxyl-terminal deletion affects an essential
protein-protein interaction required for DNA replication.
The helicase activity of the gene 4 protein is required for T7 DNA
polymerase to catalyze synthesis on duplex DNA (21). In this reaction
there is a specific interaction between the T7 proteins, as
demonstrated by the fact that other DNA polymerases cannot
substitute for T7 DNA polymerase (21). Thus, we used plasmid dsDNA
containing a single site-specific nick to examine the ability of the
gene 4 protein to interact with T7 DNA polymerase and stimulate its
activity on a duplex template. The phage f1 gene II protein was used to
introduce a single nick at the f1 origin of replication contained in
plasmid pET24a(+) (refer to inset Fig.
4A). The gene 4 protein requires a
5-single-stranded tail to which it can bind and continue strand
separation. Thus T7 DNA polymerase
28 lacking 3
to 5
exonuclease
activity was used as this enzyme will initiate DNA synthesis at a nick
and catalyze strand displacement synthesis of approximately a hundred nucleotides (21). The gene 4 protein then enters the reaction by
binding to regions of ssDNA created by the DNA polymerase.
In the results shown in Fig. 4A there is essentially no DNA
synthesis on the nicked duplex template in the absence of gene 4 protein. The addition of wild-type gene 4 protein to the reaction leads
to a marked increase in DNA synthesis, but addition of the carboxyl-terminal deleted protein results in less than 10% the stimulation level of the wild-type protein. Examination of the products
of these reactions by agarose gel electrophoresis shows that the DNA
molecules synthesized in the presence of the gene 4A-Ct protein are
never more than a few hundred nucleotides long, whereas the wild-type
helicase permits the continuous addition of well over 50,000 nucleotides (Fig. 4B). Increases in the concentration of
wild-type gene 4A produce an increase in the amount of DNA synthesized,
not in the length of DNA synthesized.
We also used a preformed replication fork to compare the abilities of
the wild-type and gene 4A-Ct proteins to stimulate T7 DNA polymerase
activity (21). Beside using a different DNA substrate to confirm our
findings, this assay allowed us to determine if the inability of the
mutant gene 4 protein to stimulate DNA synthesis is due, in whole or
part, to the mutation in T7 DNA polymerase
28. The preformed
replication fork used in this experiment consists of a 70-bp circular
duplex DNA molecule with a 5
-single-stranded tail of 40 nucleotides
(diagrammed in the inset of Fig.
5A). The presence of the 5
-tail allows the
use of wild-type T7 DNA polymerase rather than the
28 deletion form
lacking exonuclease activity.
The data presented in Fig. 5 confirm that the gene 4A-Ct protein is
defective in its ability to support synthesis by the DNA polymerase
through duplex DNA. The time course reveals that the amount of DNA
synthesized is lower and the length of the product molecules is shorter
in reactions with the mutant gene 4A protein relative to that obtained
with the wild-type protein. Even at the longest reaction time (5 min)
the gene 4A-
Ct protein cannot support the synthesis of DNA molecules
as long as those synthesized with the wild-type gene 4 protein in 1 min
(Fig. 5B).
Considering
that the gene 4 protein and DNA polymerase have been shown to interact
(12) and that the gene 4A-Ct protein is equally as active as the
wild-type protein in translocation and unwinding dsDNA (Fig. 3), it
seems likely that the decreased stimulation of T7 DNA polymerase
activity by the carboxyl-terminal deleted gene 4A protein could be
caused a defect in its ability to interact properly with the polymerase
at a replication fork. The interaction of the gene 4 protein and DNA
polymerase was examined directly by a gel-shift assay and surface
plasmon resonance.
In the presence of the non-hydrolyzable nucleotide analog
,
-methylene dTTP the wild-type gene 4 hexamer binds a
single-stranded radiolabeled oligonucleotide resulting in decreased
mobility of the labeled oligonucleotide (Fig. 6,
lane 1, solid arrowhead). The gene 4A-
Ct
protein binds to single-stranded oligonucleotide equally as well as
does the wild-type protein (Fig. 6, lane 5). When DNA
polymerase is included in the reaction there is a further decrease in
the mobility of the wild-type gene 4A protein-oligonucleotide complex
indicating an increase in the size of the complex due to the
interaction of the polymerase with the gene 4 protein (Fig. 6,
lane 2, open arrowhead). In contrast, T7 DNA
polymerase has little effect on the mobility of the gene 4A-
Ct
protein-oligonucleotide complex, suggesting that the polymerase cannot
stably interact with the mutant gene 4 protein (Fig. 6, lane
4). Under the conditions used in this assay the T7 DNA polymerase
does not bind ssDNA (Fig. 6, lane 3) demonstrating that the
decrease in migration of the polymerase-wild-type gene 4 protein-DNA
complex (Fig. 6, lane 2) is due to protein-protein
interactions.
The interaction between the gene 4 proteins and DNA polymerase was also
examined using a biosensor and surface plasmon resonance measurements
(BIAcore, Pharmacia Biosensor). This analysis provides a second, direct
and independent method of assessing the effect of the carboxyl-terminal
deletion of the gene 4 protein on its ability to interact with DNA
polymerase. Plasmon resonance changes in direct proportion to the mass
of the molecules adsorbed on the surface of the biosensor chip,
providing a real-time measurement of protein-protein interactions under
native conditions (45). In these experiments a biosensor chip with
covalently attached avidin was used to bind a 3-biotinylated 33-base
oligonucleotide. Under the buffer and flow rate conditions used neither
T7 DNA polymerase
28 nor gene 4 protein binds the avidin biosensor
chip before ssDNA is applied (data not shown). After ssDNA is bound to
the chip the gene 4 proteins will bind only in the presence of
,
-methylene dTTP (Fig. 7, A and
B); DNA polymerase will not bind even when nucleoside
triphosphates are included in the injection solution (data not shown).
In the experiment shown in Fig. 7 equivalent amounts of wild-type and
mutant gene 4 proteins, in the presence of
,
-methylene dTTP, were
bound to the ssDNA on the chip (9512 RU ± 390). DNA polymerase
was then injected over the gene 4 protein-ssDNA complex bound to the
biosensor chip. As shown in Fig. 7A T7 DNA polymerase binds
to the wild-type gene 4 protein-ssDNA complex as evidenced by the
increased resonance response (810 RU) above the DNA polymerase base
line. In contrast, no binding (less than 30 RU) of T7 DNA polymerase to
the mutant gene 4 protein-ssDNA complex on the chip was observed (Fig.
7B). We conclude that the primary defect caused by the
deletion of the carboxyl terminus of the gene 4 protein is a loss of
the ability to form a stable complex with T7 DNA polymerase.
The gene 4 protein of bacteriophage T7 provides both helicase and primase functions at the replication fork (16, 21, 25, 34, 44). In this capacity the gene 4 protein interacts with T7 DNA polymerase on both the leading and lagging strands to unwind the duplex and synthesize primers, respectively. Through these interactions with DNA polymerases on each strand, the gene 4 protein coordinates leading and lagging strand synthesis at the replication fork (3). The dramatic and specific effects of the helicase and primase activities of the gene 4 protein on polymerase activity imply a direct interaction of the two proteins, and such an interaction has been demonstrated (12). The results presented in this report confirm this interaction and lead to the identification of the carboxyl terminus of the gene 4 protein as the domain responsible for its interaction with the T7 DNA polymerase during leading strand synthesis.
Interestingly, the carboxyl-terminal domain of the T7 gene 4 protein is
not essential for any of its multiple enzymatic activities but is
absolutely required for its function in vivo. The DNA
dependent nucleotide hydrolysis, helicase, and primase activities of
the gene 4A-Ct protein are essentially identical to those of the wild-type protein. Only when we examined the coupling of polymerase activity on duplex DNA to helicase activity of the gene 4 protein did
we detect a defect. In these assays, where DNA synthesis is dependent
on the coordinated activities of both proteins, the carboxyl-terminal
truncated gene 4 protein is at least 10-fold less effective in
stimulating DNA synthesis catalyzed by T7 DNA polymerase than is the
wild-type gene 4 protein.
To examine the ability of the gene 4 protein to enable T7 DNA
polymerase to catalyze synthesis through dsDNA, we used two assays,
each employing a distinct DNA template. One template was circular
duplex plasmid DNA containing a single site-specific nick. In this
instance, it was necessary to use T7 DNA polymerase 28, an altered
form of the polymerase lacking 3
to 5
exonuclease activity (46). Only
in the absence of exonuclease activity will the polymerase catalyze
strand displacement synthesis sufficient to create a single-stranded
tail, or lagging strand, to which the gene 4 protein can bind and
subsequently translocate to the replication fork where it can
presumably form a complex with the paused DNA polymerase (21).
Coincidentally, this same form of the polymerase was required in the
gel-shift assay to prevent the potent exonuclease activity of the
wild-type polymerase from hydrolyzing the oligonucleotides present in
the reaction mixture. The second DNA synthesis assay used a small
circular duplex DNA molecule containing a replication fork (21);
therefore, the wild-type T7 DNA polymerase could be used in the
reaction.
Together T7 DNA polymerase and wild-type gene 4 protein polymerize nucleotides processively on a duplex template at a rate of approximately 300 nucleotides per s at 30 °C (21). Furthermore, the ability of the gene 4 protein to function in this reaction is specific for T7 DNA polymerase because other enzymes such as the phage T4 DNA polymerase cannot substitute for T7 polymerase. Our data indicate that processive DNA synthesis depends on the formation and maintenance of a stable complex at the replication fork, and this is provided by the direct interaction of the gene 4 protein and DNA polymerase. This interaction prevents the proteins from outdistancing each other and thus losing their combined effectiveness. For example if the helicase out-paced the polymerase so that a duplex region formed between the two proteins, DNA synthesis would halt since the polymerase alone cannot catalyze strand displacement synthesis through even a single base pair (21).
Alternative scenarios relying on uniform rates of movement of the
enzymes along the DNA are, of course, conceivable. These situations
would not rely on direct physical interactions to maintain a
replication complex. For example, it is possible that the rate of
nucleotide polymerization is faster than that of helicase unwinding. This would prevent a functional separation of the two proteins since a
helicase moving ahead of the polymerase would be the rate-limiting step. Likewise, in a model where the polymerase is positioned in front
of the helicase the inability of the polymerase to catalyze strand
displacement synthesis would keep it in close proximity to the
helicase. Neither model, however, can account for our results since
polymerase activity would be expected to remain the same with either
the wild-type or mutant gene 4 protein. Our finding that the gene
4A-Ct protein is severely defective in stimulating T7 DNA
polymerase, in two different synthesis assays, even though it has
normal helicase activity suggests strongly that coordination of the two
proteins is lacking. The results, in fact, indicate that the
coordination normally occurs through a protein-protein interaction to
form a functional complex.
It is clear that the T7 DNA polymerase and the gene 4 protein form a complex. This interaction was shown indirectly in earlier studies (12) and is demonstrated directly in the gel-shift experiments and plasmon resonance measurements presented in this study. Furthermore, both these latter experiments demonstrate that the carboxyl-terminal truncated gene 4 protein is defective in its ability to form a complex with T7 DNA polymerase. In the gel shift assay the polymerase remains bound to the gene 4 protein through the preincubation period and subsequent gel electrophoresis, a total period of more than 2 h. In the plasmon resonance analysis the binding of DNA polymerase to the gene 4 hexamer-ssDNA complex was so tight that an off-rate could not be determined within the time course of the experiment. Formation of the gene 4 protein-DNA polymerase complex, however, is not dependent on the presence of ssDNA. Gel-shift experiments performed without oligonucleotide resulted in the formation of the same DNA polymerase-wild-type gene 4 protein complex as detected by silver staining of the gels (data not shown). This result was expected since, as shown in Fig. 6 (lane 3), T7 DNA polymerase does not bind ssDNA under the conditions used. Moreover, it is likely that the entire 26-base oligonucleotide is bound within the hexameric gene 4 protein (30, 31).
The ability of the gene 4 proteins to form hexamers and bind ssDNA was
also demonstrated by the gel-shift assay. In the presence of
,
-methylene dTTP both wild-type and the gene 4A-
Ct protein bind the radiolabeled oligonucleotide (Fig. 6, lanes 1 and
5). Since the gene 4 protein must form a hexamer to bind
ssDNA (29, 31), it is clear that hexamer formation was not affected by the carboxyl-terminal deletion. Furthermore, both proteins bound ssDNA
with a stoichiometry of approximately 1 mol of ssDNA per mol of gene 4 hexamer, indicating that DNA binding is not affected by the deletion
mutation.
Not only is an interaction of the gene 4 protein and DNA polymerase
required for strand displacement DNA synthesis, it is also required for
priming DNA synthesis on the lagging strand of the replication fork.
The gene 4A protein catalyzes the synthesis of tetra-ribonucleotides at
specific sequences on ssDNA in a template-mediated reaction. These
tetra-ribonucleotides are stabilized on the template by the gene 4A
protein until T7 DNA polymerase can use them as primers to initiate DNA
synthesis (36). Such short oligoribonucleotides prime T7 DNA polymerase
extremely poorly in the absence of the gene 4 protein
(26).2 The effective use of these
tetra-ribonucleotides by T7 DNA polymerase in the presence of the gene
4 protein implies that a specific protein-protein interaction is
required and, in fact, T7 gene 4 protein cannot provide functional
primers to bacteriophage T4 DNA polymerase.2 The finding
that wild-type and gene 4A-Ct protein provide essentially identical
levels of priming on M13 ssDNA (Fig. 3B) suggests the existence of a second domain of the gene 4 protein that mediates interactions with DNA polymerase during this reaction. Alternatively, a
more transient interaction may occur between the DNA polymerase and the
carboxyl terminus of the gene 4A helicase/primase during the priming
reaction. This transient or weaker priming interaction may be only
slightly, or not at all, affected by the carboxyl-terminal deletion.
No T7 phage suppressors of this gene 4 deletion mutation were detected in the complementation assays (Table I), a result that is most likely due to the severe nature of the deletion mutation. Site-directed mutagenesis of individual residues within this 17-amino acid carboxyl-terminal domain of the helicase/primase could be used to determine the specific residues involved in the interaction with T7 DNA polymerase. These mutant gene 4 proteins could then be used to detect suppressor mutations in the T7 DNA polymerase and thus identify the domain of the polymerase responsible for interactions with the helicase/primase. It is possible that alone no single residue of this region plays an essential role in the interaction with T7 DNA polymerase, rather that the region as a whole is required. In this regard, it is interesting to note that Rosenberg et al. (47) in a random mutagenesis of gene 4 failed to identify essential residues in this carboxyl-terminal region. They did, however, select a gene 4 mutant, Q507(Ochre), containing a termination codon positioned so that the last 60 residues of the protein were deleted. This mutant could not support the growth of a gene 4-deleted T7 phage. While this 60-amino acid deletion is more severe than the 17-residue deletion mutant studied in this report, it is likely that their mutant gene 4 protein was also defective in its ability to interact with DNA polymerase and may not have been defective in either helicase and primase activities, as suggested.
At least one other phage T7 replication protein has a negatively charged region that participates in protein-protein interactions. T7 gene 2.5 encodes a ssDNA binding protein that is required for phage replication (2). This protein has a negatively charged carboxyl terminus that functions in dimerization of the gene 2.5 protein and interactions with T7 DNA polymerase and gene 4 protein (48). It is not known if a single domain of the DNA polymerase interacts with the negatively charged carboxyl-terminal domains of both the gene 2.5 protein and the gene 4 helicase/primase. However, we were not able to detect any interactions between the gene 2.5 protein and either the T7 DNA polymerase or the gene 4 helicase/primase in the native PAGE system used for the gel-shift assays in this investigation (data not shown). This finding indicates that the gene 4 protein-DNA polymerase interaction is considerably stronger than that of the gene 2.5 protein-DNA polymerase interaction.
Bacteriophages T3 and SP6 are closely related to phage T7; the gene 4 proteins of these phage also have negatively charged carboxyl termini,
6 of the terminal 17 residues are negatively charged in both phage.
Presumably, these acidic domains also mediate interactions with the DNA
polymerase during replication. The phage T7 gene 4 helicase/primase
also shares regions of homology with DnaB, the replicative helicase of
E. coli (49). The carboxyl terminus of DnaB is not as
negatively charged as that of the T7 gene 4 helicase/primase, and this
may reflect the fact that a separate protein, the -protein, mediates
interactions between the helicase and the polymerase (50). The presence
of a protein that specifically functions as a link between the DNA
helicase and the DNA polymerase may be a more common replisome scheme
than the direct interaction between helicase and polymerase found in T7
phage, which has evolved a minimal set of highly efficient interdependent replication enzymes.
The interaction of gene 4 protein and the DNA polymerase at the
replication fork is an important aspect of the replication process.
Structural studies will be required to determine where on the gene 4 protein hexamer the carboxyl-terminal domain is located and how this
location orients the DNA polymerase at the replication fork.
Nevertheless, we present a model of the interaction between T7 DNA
polymerase and the gene 4 helicase/primase at a DNA replication fork
(Fig. 8). It is not clear from the data presented whether a single monomer of the gene 4 hexamer and the DNA polymerase are in constant contact at the replication fork or if the attraction between the proteins is dispersed over a continuous region of the
hexamer. If the helicase rotates around the DNA axis as it translocates
and unwinds dsDNA, the interaction with the polymerase may be changing
sequentially from one monomer in the hexamer to the next to relieve
torsional strain. In this case the polymerase is probably not in
constant contact with a single monomer of the gene 4 protein but more
likely contacts a region of the hexamer composed of the
carboxyl-terminal domains of each monomer. If, on the other hand, the
helicase moves along the DNA without any rotation relative to the DNA,
a constant interaction between a single gene 4 monomer and the DNA
polymerase may be all that is required to maintain a stable complex.
The model presented allows either the helicase or the polymerase some
rotational flexibility around the DNA as the replication fork moves
through the chromosome.
We thank Stan Tabor for suggesting the use of the mini DNA replication fork for examining DNA synthesis catalyzed by T7 DNA polymerase and gene 4 protein. We thank U. Ingrid Richardson and David Frick for critical reading of the manuscript.