Escherichia coli thioredoxin confers processivity on the DNA polymerase activity of the gene 5 protein of bacteriophage T7

Bacteriophage T7 gene 5 protein has been purified to apparent homogeneity from cells overexpressing its gene several hundred-fold. Gene 5 protein is a DNA polymerase with low processivity; it dissociates from the primer-template after catalyzing the incorporation of 1-50 nucleotides, depending on the salt concentration. Escherichia coli thioredoxin, a host protein that is tightly associated with the gene 5 protein in phage-infected cells, is not required for this activity. Thioredoxin acts as an accessory protein to bestow processivity on the polymerizing reaction; DNA synthesis catalyzed by the gene 5 protein-thioredoxin complex on a single-stranded DNA template can polymerize thousands of nucleotides without dissociation. Conditions that increase the stability of secondary structures in the template (i.e., low temperature or high ionic strength) decrease the processivity. E. coli single-stranded DNA-binding protein stimulates both the rate of elongation and the processivity of the gene 5 protein-thioredoxin complex.     

The effect of the T7 and Escherichia coli DNA-binding proteins at the replication fork of bacteriophage T7

In this paper we compare the effect of single-stranded DNA-binding proteins of bacteriophage T7 (gene 2.5 protein) and of Escherichia coli (SSB) at the T7 replication fork. The T7 gene 4 protein acts processively as helicase to promote leading strand synthesis and distributively as primase to initiate lagging strand synthesis by T7 DNA polymerase. On a nicked double-stranded template, the formation of a replication fork requires partial strand displacement so that gene 4 protein may bind to the displaced strand and unwind the helix catalytically. Both the T7 gene 2.5 protein and E. coli SSB act stoichiometrically to promote this initial strand displacement step. Once initiated, processive leading strand synthesis is not greatly stimulated by the single-stranded DNA-binding proteins. However, the T7 gene 2.5 protein, but not E. coli SSB, increases the frequency of initiation of lagging strand synthesis by greater than 10-fold. The results suggest a specific interaction of the T7 gene 2.5 protein with the T7 replication apparatus.     

Interactions of the DNA polymerase and gene 4 protein of bacteriophage T7. Protein-protein and protein-DNA interactions involved in RNA-primed DNA synthesis

Three proteins catalyze RNA-primed DNA synthesis on the lagging strand side of the replication fork of bacteriophage T7. Oligoribonucleotides are synthesized by T7 gene 4 protein, which also provides helicase activity. DNA synthesis is catalyzed by gene 5 protein of the phage, and processivity of DNA synthesis is conferred by Escherichia coli thioredoxin, a protein that is tightly associated with gene 5 protein. T7 DNA polymerase and gene 4 protein associate to form a complex that can be isolated by filtration through a molecular sieve. The complex is stable in 50 mM NaCl but is dissociated by 100 mM NaCl, a salt concentration that does not inhibit RNA-primed DNA synthesis. T7 DNA polymerase forms a stable complex with single-stranded M13 DNA at 50 mM NaCl as measured by gel filtration, and this complex requires 200 mM NaCl for dissociation, a salt concentration that inhibits RNA-primed DNA synthesis. Gene 4 protein alone does not bind to single-stranded DNA. In the presence of MgCl2 and dTTP or beta, gamma-methylene dTTP, a gene 4 protein-M13 DNA complex that is stable at 200 mM NaCl is formed. The affinity of DNA polymerase for both gene 4 protein and single-stranded DNA leads to the formation of a gene 4 protein-DNA polymerase-M13 DNA complex even in the absence of nucleoside triphosphates. However, the binding of each protein to DNA plays an important role in mediating the interaction of the proteins with each other. High concentrations of single-stranded DNA inhibit RNA-primed DNA synthesis by diluting the amount of proteins bound to each template and reducing the frequency of protein-protein interactions. Preincubation of gene 4 protein, DNA polymerase, and M13 DNA in the presence of dTTP forms protein-DNA complexes that most efficiently catalyze RNA-primed DNA synthesis in the presence of excess single-stranded competitor DNA.     

The C-terminal residues of bacteriophage T7 gene 4 helicase-primase coordinate helicase and DNA polymerase activities

The gene 4 protein of bacteriophage T7 plays a central role in DNA replication by providing both helicase and primase activities. The C-terminal helicase domain is not only responsible for DNA-dependent dTTP hydrolysis, translocation, and DNA unwinding, but it also interacts with T7 DNA polymerase to coordinate helicase and polymerase activities. The C-terminal 17 residues of gene 4 protein are critical for its interaction with the T7 DNA polymerase/thioredoxin complex. This C terminus is highly acidic; replacement of these residues with uncharged residues leads to a loss of interaction with T7 DNA polymerase/thioredoxin and an increase in oligomerization of the gene 4 protein. Such an alteration on the C terminus results in a reduced efficiency in strand displacement DNA synthesis catalyzed by gene 4 protein and T7 DNA polymerase/thioredoxin. Replacement of the C-terminal amino acid, phenylalanine, with non-aromatic residues also leads to a loss of interaction of gene 4 protein with T7 DNA polymerase/thioredoxin. However, neither of these modifications of the C terminus affects helicase and primase activities. A chimeric gene 4 protein containing the acidic C terminus of the T7 gene 2.5 single-stranded DNA-binding protein is more active in strand displacement synthesis. Gene 4 hexamers containing even one subunit of a defective C terminus are defective in their interaction with T7 DNA polymerase.     

Two Modes of Interaction of the Single-stranded DNA-binding Protein of Bacteriophage T7 with the DNA Polymerase-Thioredoxin Complex

The DNA polymerase encoded by bacteriophage T7 has low processivity. Escherichia coli thioredoxin binds to a segment of 76 residues in the thumb subdomain of the polymerase and increases the processivity. The binding of thioredoxin leads to the formation of two basic loops, loops A and B, located within the thioredoxin-binding domain (TBD). Both loops interact with the acidic C terminus of the T7 helicase. A relatively weak electrostatic mode involves the C-terminal tail of the helicase and the TBD, whereas a high affinity interaction that does not involve the C-terminal tail occurs when the polymerase is in a polymerization mode. T7 gene 2.5 single-stranded DNA-binding protein (gp2.5) also has an acidic C-terminal tail. gp2.5 also has two modes of interaction with the polymerase, but both involve the C-terminal tail of gp2.5. An electrostatic interaction requires the basic residues in loops A and B, and gp2.5 binds to both loops with similar affinity as measured by surface plasmon resonance. When the polymerase is in a polymerization mode, the C terminus of gene 2.5 protein interacts with the polymerase in regions outside the TBD. gp2.5 increases the processivity of the polymerase-helicase complex during leading strand synthesis. When loop B of the TBD is altered, abortive DNA products are observed during leading strand synthesis. Loop B appears to play an important role in communication with the helicase and gp2.5, whereas loop A plays a stabilizing role in these interactions.     

Deoxyribonucleic acid polymerase of bacteriophage T7. Characterization of the exonuclease activities of the gene 5 protein and the reconstituted polymerase.

Homogeneous gene 5 protein of bacteriophage T7, a subunit of T7 DNA polymerase, catalyzes the stepwise hydrolysis of single-stranded DNA in a 3' leads to 5' direction to yield nucleoside 5'-monophosphates. The gene 5 protein itself does not hydrolyze duplex DNA. However, in the presence of Escherichia coli thioredoxin, the host-specified subunit of T7 DNA polymerase, duplex DNA is hydrolyzed in a 3' leads to 5' direction to yield nucleoside 5'-monophosphates. The apparent Km for thioredoxin in the reaction is 4.8 x 10(-8) M, a value similar to that for the apparent Km of thioredoxin in the complementation assay with gene 5 protein to restore T7 DNA polymerase activity. Both exonuclease activities require Mg2+ and a sulfhydryl reagent for optimal activity, and both activities are sensitive to salt concentration. Deoxyribonucleoside 5'-triphosphates inhibit hydrolysis by both exonuclease activities; hydrolysis of single-stranded DNA by the gene 5 protein is inhibited even in the absence of thioredoxin where there is less than 2% active T7 DNA polymerase. E. coli DNA binding protein (helix destabilizing protein) stimulates the hydrolysis of duplex DNA up to 9-fold under conditions where the hydrolysis of the single-stranded DNA is inhibited 4-fold.     

A covalent linkage between the gene 5 DNA polymerase of bacteriophage T7 and Escherichia coli thioredoxin,the processivity factor: fate of thioredoxin during DNA synthesis

Gene 5 protein (gp5) of bacteriophage T7 is a non-processive DNA polymerase, which acquires high processivity by binding to Escherichia coli thioredoxin. The gene 5 protein-thioredoxin complex (gp5/trx) polymerizes thousands of nucleotides before dissociating from a primer-template. We have engineered a disulfide linkage between the gene 5 protein and thioredoxin within the binding surface of the two proteins. The polymerase activity of the covalently linked complex (gp5-S-S-trx) is similar to that of gp5/trx on poly(dA)/oligo(dT). However, gp5-S-S-trx has only one third the polymerase activity of gp5/trx on single-stranded M13 DNA. gp5-S-S-trx has difficulty polymerizing nucleotides through sites of secondary structure on M13 DNA and stalls at these sites, resulting in lower processivity. However, gp5-S-S-trx has an identical processivity and rate of elongation when E. coli single-stranded DNA-binding protein (SSB protein) is used to remove secondary structure from M13 DNA. Upon completing synthesis on a DNA template lacking secondary structure, both complexes recycle intact, without dissociation of the processivity factor, to initiate synthesis on a new DNA template. However, a complex stalled at secondary structure becomes unstable, and both subunits dissociate from each other as the polymerase prematurely releases from M13 DNA.     

Escherichia coli thioredoxin stabilizes complexes of bacteriophage T7 DNA polymerase and primed templates

The DNA polymerase activity induced after bacteriophage T7 infection of Escherichia coli is found in a complex of two proteins, the T7 gene 5 protein and a host protein, thioredoxin. Gene 5 protein is a DNA polymerase and a 3' to 5' exonuclease. Thioredoxin binds tightly to the gene 5 protein and increases the processivity of polymerization some 1000-fold. Gene 5 protein forms a short-lived complex with the primer-template, poly(dA).oligo(dT), in the absence of Mg2+ and nucleotides. Thioredoxin increases the half-life of the preformed primer-template-polymerase complex from less than a second to approximately 5 min. The dissociation is accelerated by excess single-stranded DNA in an apparent second order reaction, indicating direct transfer of polymerase between DNA fragments. Thioredoxin also reduces the equilibrium dissociation constant, Kd, of the gene 5 protein -poly(dA).oligo(dT) complex 20- to 80-fold. The salt dependence of Kd indicates that thioredoxin stabilizes the primer-template-polymerase complex mainly through additional charge-charge interactions, increasing the estimated number of interactions from 2 to 7. The affinity of gene 5 protein for single-stranded DNA is at least 1000-fold higher than for double-stranded DNA and is little affected by thioredoxin. Under conditions of steady state synthesis the effect of thioredoxin on the polymerization rate is determined by two competing factors, an increase in processivity and a decrease of the dissociation rate of polymerase and replicated template.     

Effect of single-stranded DNA-binding proteins on the helicase and primase activities of the bacteriophage T7 gene 4 protein

Gene 4 protein (gp4) of bacteriophage T7 provides two essential functions at the T7 replication fork, primase and helicase activities. Previous studies have shown that the single-stranded DNA-binding protein of T7, encoded by gene 2.5, interacts with gp4 and modulates its multiple functions. To further characterize the interactions between gp4 and gene 2.5 protein (gp2.5), we have examined the effect of wild-type and altered gene 2.5 proteins as well as Escherichia coli single-stranded DNA-binding (SSB) protein on the ability of gp4 to synthesize primers, hydrolyze dTTP, and unwind duplex DNA. Wild-type gp2.5 and E. coli SSB protein stimulate primer synthesis and DNA-unwinding activities of gp4 at low concentrations but do not significantly affect single-stranded DNA-dependent hydrolysis of dTTP. Neither protein inhibits the binding of gp4 to single-stranded DNA. The variant gene 2.5 proteins, gp2.5-F232L and gp2.5-Delta26C, inhibit primase, dTTPase, and helicase activities proportional to their increased affinities for DNA. Interestingly, wild-type gp2.5 stimulates the unwinding activity of gp4 except at very high concentrations, whereas E. coli SSB protein is highly inhibitory at relative low concentrations.     

A single-stranded DNA-binding protein of bacteriophage T7 defective in DNA annealing

The annealing of complementary strands of DNA is a vital step during the process of DNA replication, recombination, and repair. In bacteriophage T7-infected cells, the product of viral gene 2.5, a single-stranded DNA-binding protein, performs this function. We have identified a single amino acid residue in gene 2.5 protein, arginine 82, that is critical for its DNA annealing activity. Expression of gene 2.5 harboring this mutation does not complement the growth of a T7 bacteriophage lacking gene 2.5. Purified gene 2.5 protein-R82C binds single-stranded DNA with a greater affinity than the wild-type protein but does not mediate annealing of complementary strands of DNA. A carboxyl-terminal-deleted protein, gene 2.5 protein-Delta26C, binds even more tightly to single-stranded DNA than does gene 2.5 protein-R82C, but it anneals homologous strands of DNA as well as does the wild-type protein. The altered protein forms dimers and interacts with T7 DNA polymerase comparable with the wild-type protein. Gene 2.5 protein-R82C condenses single-stranded M13 DNA in a manner similar to wild-type protein when viewed by electron microscopy.     

The carboxyl-terminal domain of bacteriophage T7 single-stranded DNA-binding protein modulates DNA binding and interaction with T7 DNA polymerase

Gene 2.5 of bacteriophage T7 is an essential gene that encodes a single-stranded DNA-binding protein (gp2.5). Previous studies have demonstrated that the acidic carboxyl terminus of the protein is essential and that it mediates multiple protein-protein interactions. A screen for lethal mutations in gene 2.5 uncovered a variety of essential amino acids, among which was a single amino acid substitution, F232L, at the carboxyl-terminal residue. gp2.5-F232L exhibits a 3-fold increase in binding affinity for single-stranded DNA and a slightly lower affinity for T7 DNA polymerase when compared with wild type gp2.5. gp2.5-F232L stimulates the activity of T7 DNA polymerase and, in contrast to wild-type gp2.5, promotes strand displacement DNA synthesis by T7 DNA polymerase. A carboxyl-terminal truncation of gene 2.5 protein, gp2.5-Delta 26C, binds single-stranded DNA 40-fold more tightly than the wild-type protein and cannot physically interact with T7 DNA polymerase. gp2.5-Delta 26C is inhibitory for DNA synthesis catalyzed by T7 DNA polymerase on single-stranded DNA, and it does not stimulate strand displacement DNA synthesis at high concentration. The biochemical and genetic data support a model in which the carboxyl-terminal tail modulates DNA binding and mediates essential interactions with T7 DNA polymerase.     

Purification and characterization of the bacteriophage T7 gene 2.5 protein. A single-stranded DNA-binding protein.

Bacteriophage T7 gene 2.5 protein has been purified to homogeneity from cells overexpressing its gene. Native gene 2.5 protein consists of a dimer of two identical subunits of molecular weight 25,562. Gene 2.5 protein binds specifically to single-stranded DNA with a stoichiometry of approximately 7 nucleotides bound per monomer of gene 2.5 protein; binding appears to be noncooperative. Electron microscopic analysis shows that gene 2.5 protein is able to disrupt the secondary structure of single-stranded DNA. The single-stranded DNA is extended into a chain of gene 2.5 protein dimers bound along the DNA. In fluorescence quenching and nitrocellulose filter binding assays, the binding constants of gene 2.5 protein to single-stranded DNA are 1.2 x 10(6) M-1 and 3.8 x 10(6) M-1, respectively. Escherichia coli single-stranded DNA-binding protein and phage T4 gene 32 protein bind to single-stranded DNA more tightly by a factor of 25. Fluorescence spectroscopy suggests that tyrosine residue(s), but not tryptophan residues, on gene 2.5 protein interacts with single-stranded DNA.     

Reversibility of strand invasion promoted by recA protein and its inhibition by Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein

When recA protein promotes homologous pairing and strand exchange involving circular single strands and linear duplex DNA, the protein first polymerizes on the single-stranded DNA to form a nucleoprotein filament which then binds naked duplex DNA to form nucleoprotein networks, the existence of which is independent of homology, but requires the continued presence of recA protein (Tsang, S. S., Chow, S. A., and Radding, C. M. (1985) Biochemistry 24, 3226-3232). Further experiments revealed that within a few minutes after the beginning of homologous pairing and strand exchange, these networks began to be replaced by a distinct set of networks with inverse properties: their formation depended upon homology, but they survived removal of recA protein by a variety of treatments. Formation of this second kind of network required that homology be present specifically at the end of the linear duplex molecule from which strand exchange begins. Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein largely suppressed the formation of this second population of networks by inactivating the newly formed heteroduplex DNA, which, however, could be reactivated when recA protein was dissociated by incubation at 0 degrees C. We interpret these observations as evidence of reinitiation of strand invasion when recA protein acts in the absence of auxiliary helix-destabilizing proteins. These observations indicate that the nature of the nucleoprotein products of strand exchange determines whether pairing and strand exchange are reversible or not, and they further suggest a new explanation for the way in which E. coli single-stranded DNA-binding protein and gene 32 protein accelerate the apparent forward rate of strand exchange promoted by recA protein, namely by suppressing initiation of the reverse reaction.     

Purification of an SOS repressor from Bacillus subtilis.

We have identified in Bacillus subtilis a DNA-binding protein that is functionally analogous to the Escherichia coli LexA protein. We show that the 23-kDa B. subtilis protein binds specifically to the consensus sequence 5'-GAACN4GTTC-3' located within the putative promoter regions of four distinct B. subtilis DNA damage-inducible genes: dinA, dinB, dinC, and recA. In RecA+ strains, the protein's specific DNA binding activity was abolished following treatment with mitomycin C; the decrease in DNA binding activity after DNA damage had a half-life of about 5 min and was followed by an increase in SOS gene expression. There was no detectable decrease in DNA binding activity in B. subtilis strains deficient in RecA (recA1, recA4) or otherwise deficient in SOS induction (recM13) following mitomycin C treatment. The addition of purified B. subtilis RecA protein, activated by single-stranded DNA and dATP, abolished the specific DNA binding activity in crude extracts of RecA+ strains and strains deficient in SOS induction. We purified the B. subtilis DNA-binding protein more than 4,000-fold, using an affinity resin in which a 199-bp DNA fragment containing the dinC promoter region was coupled to cellulose. We show that B. subtilis RecA inactivates the DNA binding activity of the purified B. subtilis protein in a reaction that requires single-stranded DNA and nucleoside triphosphate. By analogy with E. coli, our results indicate that the DNA-binding protein is the repressor of the B. subtilis SOS DNA repair system.     

Interaction of mutant thioredoxins of Escherichia coli with the gene 5 protein of phage T7. The redox capacity of thioredoxin is not required for stimulation of DNA polymerase activity

DNA polymerase activity in Escherichia coli cells infected with bacteriophage T7 resides in a protein complex consisting of the T7 gene 5 protein and E. coli thioredoxin in a 1 to 1 stoichiometry. We have analyzed nine mutant thioredoxins, both in vivo and in vitro, for their ability to interact with the T7 gene 5 protein and stimulate the DNA polymerase and exonuclease activities inherent in gene 5 protein. The efficiency of plating of T7 on E. coli thioredoxin mutants depends strongly on the copy number of the respective mutant thioredoxin allele. Plating efficiencies at a constant copy number correlate well with the affinity of the purified mutant proteins for T7 gene 5 protein. The observed dissociation constant, Kobs, is increased between 5 and several hundredfold at 42 degrees C compared to wild-type thioredoxin. The maximum polymerase activity of the reconstituted gene 5 protein-thioredoxin complex at saturating concentrations of mutant thioredoxins, however, is reduced by less than 20%. Consequently, none of the mutant thioredoxins acts as a competitive inhibitor of wild-type thioredoxin. The active-site disulfide of thioredoxin is not essential for the activities of the gene 5 protein-thioredoxin complex. Both cysteines can be replaced without significantly affecting the maximum polymerase or exonuclease activities. Substitution or alkylation of either cysteine, however, reduces the affinity for gene 5 protein drastically, indicating that the active site is part of the thioredoxin surface involved in the protein-protein interaction.     

The DNA binding domain of the gene 2.5 single-stranded DNA-binding protein of bacteriophage T7

Gene 2.5 of bacteriophage T7 encodes a single-stranded DNA-binding protein that is essential for viral survival. Its crystal structure reveals a conserved oligosaccharide/oligonucleotide binding fold predicted to interact with single-stranded DNA. However, there is no experimental evidence to support this hypothesis. Recently, we reported a genetic screen for lethal mutations in gene 2.5 that we are using to identify functional domains of the gene 2.5 protein. This screen uncovered a number of mutations that led to amino acid substitutions in the proposed DNA binding domain. Three variant proteins, gp2.5-Y158C, gp2.5-K152E, and gp2.5-Y111C/Y158C, exhibit a decrease in binding affinity for oligonucleotides. A fourth, gp2.5-K109I, exhibits an altered mode of binding single-stranded DNA. A carboxyl-terminal truncation of gene 2.5 protein, gp2.5-Delta26C, binds single-stranded DNA 10-fold more tightly than the wild-type protein. The three altered proteins defective in single-stranded DNA binding cannot mediate the annealing of homologous DNA, whereas gp2.5-Delta26C mediates the reaction more effectively than does wild-type. Gp2.5-K109I retains this annealing ability, albeit slightly less efficiently. With the exception of gp2.5-Delta26C, all variant proteins form dimers in solution and physically interact with T7 DNA polymerase.     

Rapid isolation of homogeneous cloned T7 gene 5 protein and T7 DNA polymerase by affinity chromatography on immobilized thioredoxin.

Phage T7 DNA polymerase consists of a strong 1:1 complex of T7 gene 5 protein (80 kDa) and the reduced form of Escherichia coli thioredoxin (12 kDa). Immobilization of E. coli thioredoxin on the agarose matrix Affi-Gel retained both its redox activity and its ability to bind T7 gene 5 protein. This was used to develop a simple and fast high-yield purification method. Cloned T7 gene 5 protein, expressed in a thioredoxin-negative host cell, was isolated in pure and highly active form after elution from Affi-Gel--thioredoxin with a pH gradient from 10 to 12. This purification step separated gene 5 protein from variable amounts of two sets of reconstituting large polypeptide fragments without catalytic activity. Proteolytic cleavage in vivo probably gave rise to the fragments, the generation of which was mimicked by trypsin cleavage of pure gene 5 protein. The gene 5 protein preparation had an inherent low DNA polymerase and double-stranded 3'-exonuclease activity, which was stimulated at least 30-fold by the presence of reduced thioredoxin. Highly active and pure T7 DNA polymerase was obtained by reconstitution of gene 5 protein with thioredoxin and was isolated by phosphocellulose or FPLC Mono Q chromatography. The gene 5 protein and T7 DNA polymerase preparations are suitable for further physicochemical characterization and as reagents in DNA sequencing.     

Essential amino acid residues in the single-stranded DNA-binding protein of bacteriophage T7. Identification of the dimer interface

Gene 2.5 of bacteriophage T7 is an essential gene that encodes a single-stranded DNA-binding protein. T7 phage with gene 2.5 deleted can grow only on Escherichia coli cells that express gene 2.5 from a plasmid. This complementation assay was used to screen for lethal mutations in gene 2.5. By screening a library of randomly mutated plasmids encoding gene 2.5, we identified 20 different single amino acid alterations in gene 2.5 protein that are lethal in vivo. The location of these essential residues within the three-dimensional structure of gene 2.5 protein assists in the identification of motifs in the protein. In this study we show that a subset of these alterations defines the dimer interface of gene 2.5 protein predicted by the crystal structure. Recombinantly expressed and purified gene 2.5 protein-P22L, gene 2.5 protein-F31S, and gene 2.5 protein-G36S do not form dimers at salt concentrations where the wild-type gene 2.5 protein exists as a dimer. The basis of the lethality of these mutations in vivo is not known because altered proteins retain the ability to bind single-stranded DNA, anneal complementary strands of DNA, and interact with T7 DNA polymerase.     

A unique region in bacteriophage t7 DNA polymerase important for exonucleolytic hydrolysis of DNA

A crystal structure of the bacteriophage T7 gene 5 protein/Escherichia coli thioredoxin complex reveals a region in the exonuclease domain (residues 144-157) that is not present in other members of the E. coli DNA polymerase I family. To examine the role of this region, a genetically altered enzyme that lacked residues 144-157 (T7 polymerase (pol) Delta144-157) was purified and characterized biochemically. The polymerase activity and processivity of T7 pol Delta144-157 on primed M13 DNA are similar to that of wild-type T7 DNA polymerase implying that these residues are not important for DNA synthesis. The ability of T7 pol Delta144-157 to catalyze the hydrolysis of a phosphodiester bond, as judged from the rate of hydrolysis of a p-nitrophenyl ester of thymidine monophosphate, also remains unaffected. However, the 3'-5' exonuclease activity on polynucleotide substrates is drastically reduced; exonuclease activity on single-stranded DNA is 10-fold lower and that on double-stranded DNA is 20-fold lower as compared with wild-type T7 DNA polymerase. Taken together, our results suggest that residues 144-157 of gene 5 protein, although not crucial for polymerase activity, are important for DNA binding during hydrolysis of polynucleotides.