Characterization of strand displacement synthesis catalyzed by bacteriophage T7 DNA polymerase

The DNA polymerase induced after infection of Escherichia coli by bacteriophage T7 can exist in two forms. One distinguishing property of Form I, the elimination of nicks in double-stranded DNA templates, strongly suggests that this form of the polymerase catalyzes limited DNA synthesis at nicks, resulting in displacement of the downstream strand. In this paper, we document this reaction by a detailed characterization of the DNA product. DNA synthesis on circular, duplex DNA templates containing a single site-specific nick results in circular molecules bearing duplex branches. Analysis of newly synthesized DNA excised from the product shows that the majority of the branches are less than 500 base pairs in length and that they arise from a limited number of sites. The branches have fully base-paired termini but are attached by two noncomplementary DNA strands that have a combined length of less than 30 nucleotides. The product molecules are topologically constrained as a result of the duplex branch. DNA sequence analysis has provided an unequivocal structure of one such product molecule. We conclude that strand displacement synthesis catalyzed by Form I of T7 DNA polymerase is terminated by a template-switching reaction. We propose two distinct models for template-switching that we call primer relocation and rotational strand exchange. Strand displacement synthesis catalyzed by Form I of T7 DNA polymerase effectively converts T7 DNA circles that are held together by hydrogen bonds in their 160-nucleotide-long terminal redundancy to T7-length linear molecules. We suggest that strand displacement synthesis catalyzed by T7 DNA polymerase is essential in vivo to the processing of a T7 DNA concatemer to mature T7 genomes.     

Dissection of RNA-primed DNA synthesis catalyzed by gene 4 protein and DNA polymerase of bacteriophage T7. Coupling of RNA primer and DNA synthesis

Gene 4 protein and DNA polymerase of bacteriophage T7 catalyze RNA-primed DNA synthesis on single-stranded DNA templates. T7 DNA polymerase exhibits an affinity for both gene 4 protein and single-stranded DNA, and gene 4 protein binds stably to single-stranded DNA in the presence of dTTP (Nakai, H. and Richardson, C. C. (1986) J. Biol. Chem. 261, 15208-15216). Gene 4 protein-T7 DNA polymerase-template complexes may be formed in both the presence and absence of nucleoside 5'-triphosphates. The protein-template complexes may be isolated free of unbound proteins and nucleotides by gel filtration and will catalyze RNA-primed DNA synthesis in the presence of ATP, CTP, and the four deoxynucleoside 5'-triphosphates. RNA-primed DNA synthesis may be dissected into separate reactions for primer synthesis and DNA synthesis. Upon incubation of gene 4 protein with single-stranded DNA, ATP, and CTP, a primer-template complex is formed; it is likely that gene 4 protein mediates stable binding of the oligonucleotide to the template. The complex, purified free of unbound proteins and nucleotides, supports DNA synthesis upon addition of DNA polymerase and deoxynucleoside 5'-triphosphates. Association of primers with the template is increased by the presence of dTTP or DNA polymerase during primer synthesis. DNA synthesis supported by primer-template complexes initiates predominantly at gene 4 recognition sequences, indicating that primers are bound to the template at these sites.     

Leading and lagging strand synthesis at the replication fork of bacteriophage T7. Distinct properties of T7 gene 4 protein as a helicase and primase

Reactions at the replication fork of bacteriophage T7 have been reconstituted in vitro on a preformed replication fork. A minimum of three proteins is required to catalyze leading and lagging strand synthesis. The T7 gene 4 protein, which exists in two forms of molecular weight 56,000 and 63,000, provides helicase and primase activities. A tight complex of the T7 gene 5 protein and Escherichia coli thioredoxin provides DNA polymerase activity. Gene 4 protein and DNA polymerase catalyze processive leading strand synthesis. Gene 4 protein molecules serving as helicase remain bound to the template as leading strand synthesis proceeds greater than 40 kilobases. Primer synthesis for lagging strand synthesis is catalyzed by additional gene 4 protein molecules that undergo multiple association/dissociation steps to catalyze multiple rounds of primer synthesis. The smaller molecular weight form of gene 4 protein has been purified from an equimolar mixture of both forms. Removal of the large form results in the loss of primase activity but not of helicase activity. Submolar amounts of the large form present in a mixture of both forms are sufficient to restore high specific activity of primase characteristic of an equimolar mixture of both forms. These results suggest that the gene 4 primase is an oligomer which is composed of both molecular weight forms. The large form may be the distributive component of the primase which dissociates from the template after each round of primer synthesis.     

Requirements for synthesis of ribonucleic acid primers during lagging strand synthesis by the DNA polymerase and gene 4 protein of bacteriophage T7.

DNA polymerase and gene 4 protein of bacteriophage T7 catalyze DNA synthesis on duplex DNA templates. Synthesis is initiated at nicks in the DNA template, and this leading strand synthesis results in displacement of one of the parental strands. In the presence of ribonucleoside 5'-triphosphates the gene 4 protein catalyzes the synthesis of oligoribonucleotide primers on the displaced single strand, and their extension by T7 dna polymerase accounts for lagging strand synthesis. Since all the oligoribonucleotide primers bear adenosine 5'-triphosphate residues at their 5' termini, [gamma 32P]ATP is incorporated specifically into the product molecule, thus providing a rapid and sensitive assay for the synthesis of the RNA primers. Both primer synthesis and DNA synthesis are stimulated 3- to 5-fold by the presence of either Escherichia coli or T7 helix-destabilizing protein (DNA binding protein). ATP and CTP together fully satisfy the requirement for rNTPs and provide maximum synthesis of primers and DNA. Provided that T7 DNA polymerase is present, RNA-primed DNA synthesis occurs on either duplex or single-stranded DNA templates and to equal extents on either strand of T7 DNA. No primer-directed DNA synthesis occurs on poly(dT) or poly(dG) templates, indicating that synthesis of primers is template-directed.     

Characterization of the stimulatory effect of T4 gene 45 protein and the gene 4462 protein complex on DNA synthesis by T4 DNA polymerase

On a variety of single-stranded DNA templates, the overall rate of in vitro DNA synthesis catalyzed by the bacteriophage T4 DNA polymerase is increased about fourfold by addition of the T4 gene $\text{44}\text{62}$ and 45 proteins. Several different methods suggest that this stimulation reflects an increase in the average DNA polymerase “sticking distance”, or processivity, from 800 to about 3000 nucleotides per initiation event. Both the $\text{44}\text{62}$ protein complex and the 45 protein must be present to obtain this effect, and either ATP or dATP hydrolysis is required. Rapid-mixing experiments indicate that the polymerase stimulation is maximized within a few seconds after addition of these “polymerase accessory proteins.”     

Herpes simplex virus DNA synthesis at a preformed replication fork in vitro.

Proteins from herpes simplex virus (HSV)-infected cells were used to reconstitute DNA synthesis in vitro on a preformed replication fork. The preformed replication fork consisted of a nicked, double-stranded, circular DNA molecule with a 5' single-strand tail that was noncomplementary to the template. The products of DNA synthesis on this substrate were rolling-circle molecules, as demonstrated by electron microscopy and alkaline agarose gel electrophoresis. The tails contained double-stranded regions, indicating that both leading- and lagging-strand DNA syntheses occurred. Rolling-circle DNA replication was dependent upon HSV DNA polymerase and ATP and was stimulated by a crude fraction containing ICP8 (HSV DNA-binding protein). Similar protein fractions from mock-infected cells were unable to support rolling-circle DNA replication. This in vitro DNA replication system should prove useful in the identification and characterization of the enzymatic activities required at the HSV replication fork.     

Effects of the bacteriophage T4 dda protein on DNA synthesis catalyzed by purified T4 replication proteins

The T4 bacteriophage dda protein is a DNA-dependent ATPase and DNA helicase that is the product of an apparently nonessential T4 gene. We have examined its effects on in vitro DNA synthesis catalyzed by a purified, multienzyme T4 DNA replication system. When DNA synthesis is catalyzed by the T4 DNA polymerase on a single-stranded DNA template, the addition of the dda protein is without effect whether or not other replication proteins are present. In contrast, on a double-stranded DNA template, where a mixture of the DNA polymerase, its accessory proteins, and the gene 32 protein is required, the dda protein greatly stimulates DNA synthesis. The dda protein exerts this effect by speeding up the rate of replication fork movement; in this respect, it acts identically with the other DNA helicase in the T4 replication system, the T4 gene 41 protein. However, whereas a 41 protein molecule remains bound to the same replication fork for a prolonged period, the dda protein seems to be continually dissociating from the replication fork and rebinding to it as the fork moves. Some gene 32 protein is required to observe DNA synthesis on a double-stranded DNA template, even in the presence of the dda protein. However, there is a direct competition between this helix-destabilizing protein and the dda protein for binding to single-stranded DNA, causing the rate of replication fork movement to decrease at a high ratio of gene 32 protein to dda protein. As shown elsewhere, the dda protein becomes absolutely required for in vitro DNA synthesis when E. coli RNA polymerase molecules are bound to the DNA template, because these molecules otherwise stop fork movement (Bedinger, P., Hochstrasser, M., Jongeneel, C.V., and Alberts, B. M. (1983) Cell 34, 115-123).     

Characterization of DNA synthesis catalyzed by bacteriophage T4 replication complexes reconstituted on synthetic circular substrates

Replication complexes were reconstituted using the eight purified bacteriophage T4 replication proteins and synthetic circular 70-, 120- or 240-nt DNA substrates annealed to a leading-strand primer. To differentiate leading strands from lagging strands, the circular parts of the substrates lacked dCMP; thus, no dCTP was required for leading-strand synthesis and no dGTP for lagging-strand synthesis. The size of the substrates was crucial, the longer substrates supporting much more DNA synthesis. Leading and lagging strands were synthesized in a coupled manner. Specifically targeting leading-strand synthesis by decreasing the concentration of dGTP decreased the rate of extension of leading strands. However, blocking lagging-strand synthesis by lowering the dCTP concentration, by omitting dCTP altogether, by adding ddCTP, or with a single abasic site had no immediate effect on the rate of extension of leading strands.     

Crystallization of the gene 45 protein from the DNA replication fork of bacteriophage T4

The gene 45 protein from bacteriophage T4 has been purified and is crystallized. This protein is part of the T4 DNA replication complex. The crystallized protein is active in complementation assays. X-ray diffraction analysis is in progress; data are measured for the native and several heavy atom derivatives. The crystals diffract to about 3.5-A resolution.     

Dynamics of translesion DNA synthesis catalyzed by the bacteriophage T4 exonuclease-deficient DNA polymerase

The mechanism and dynamics of translesion DNA synthesis were evaluated using primer/templates containing a tetrahydrofuran moiety designed to mimic an abasic site. Steady-state kinetic analysis reveals that the T4 DNA polymerase preferentially incorporates dATP across from the abasic site with 100-fold higher efficiency than the other nucleoside triphosphates. Under steady-state conditions, the catalytic efficiency of dATP incorporation across from an abasic site is only 220-fold lower than that across from T. Surprisingly, misincorporation across from T is favored 4-6-fold versus replication across an abasic site, suggesting that the dynamics of the polymerization cycle are differentially affected by formation of aberrant base pairs as opposed to the lack of base-pairing capabilities afforded by the abasic site. Linear pre-steady-state time courses were obtained for the incorporation of any dNTP across from an abasic site, indicating that chemistry or a step prior to chemistry is rate-limiting for the polymerization cycle. Low elemental effects (<3) measured by substituting the alpha-thiotriphosphate analogues for dATP, dCTP, and dGTP indicate that chemistry is not solely rate-limiting. Single-turnover experiments yield kpol/Kd values that are essentially identical to kcat/Km values and provide further evidence that the conformational change preceding chemistry is rate-limiting. Extension beyond an A:abasic mispair is approximately 20-fold and 100-fold faster than extension beyond a G:abasic mispair or C:abasic mispair, respectively. Extension from the G:abasic or A:abasic site mispair generates significant elemental effects (between 5 and 20) and suggests that chemistry is at least partially rate-limiting for extension beyond either mispair.     

Effects of T antigen and replication protein A on the initiation of DNA synthesis by DNA polymerase alpha-primase.

Studies of simian virus 40 (SV40) DNA replication in a reconstituted cell-free system have established that T antigen and two cellular replication proteins, replication protein A (RP-A) and DNA polymerase alpha-primase complex, are necessary and sufficient for initiation of DNA synthesis on duplex templates containing the SV40 origin of DNA replication. To better understand the mechanism of initiation of DNA synthesis, we analyzed the functional interactions of T antigen, RP-A, and DNA polymerase alpha-primase on model single-stranded DNA templates. Purified DNA polymerase alpha-primase was capable of initiating DNA synthesis de novo on unprimed single-stranded DNA templates. This reaction involved the synthesis of a short oligoribonucleotide primer which was then extended into a DNA chain. We observed that the synthesis of ribonucleotide primers by DNA polymerase alpha-primase is dramatically stimulated by SV40 T antigen. The presence of T antigen also increased the average length of the DNA product synthesized on primed and unprimed single-stranded DNA templates. These stimulatory effects of T antigen required direct contact with DNA polymerase alpha-primase complex and were most marked at low template and polymerase concentrations. We also observed that the single-stranded DNA binding protein, RP-A, strongly inhibits the primase activity of DNA polymerase alpha-primase, probably by blocking access of the enzyme to the template. T antigen partially reversed the inhibition caused by RP-A. Our data support a model in which DNA priming is mediated by a complex between T antigen and DNA polymerase alpha-primase with the template, while RP-A acts to suppress nonspecific priming events.     

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.     

Lagging strand synthesis in coordinated DNA synthesis by bacteriophage t7 replication proteins

The proteins of bacteriophage T7 DNA replication mediate coordinated leading and lagging strand synthesis on a minicircle template. A distinguishing feature of the coordinated synthesis is the presence of a replication loop containing double and single-stranded DNA with a combined average length of 2600 nucleotides. Lagging strands consist of multiple Okazaki fragments, with an average length of 3000 nucleotides, suggesting that the replication loop dictates the frequency of initiation of Okazaki fragments. The size of Okazaki fragments is not affected by varying the components (T7 DNA polymerase, gene 4 helicase-primase, gene 2.5 single-stranded DNA binding protein, and rNTPs) of the reaction over a relatively wide range. Changes in the size of Okazaki fragments occurs only when leading and lagging strand synthesis is no longer coordinated. The synthesis of each Okazaki fragment is initiated by the synthesis of an RNA primer by the gene 4 primase at specific recognition sites. In the absence of a primase recognition site on the minicircle template no lagging strand synthesis occurs. The size of the Okazaki fragments is not affected by the number of recognition sites on the template.     

The control mechanism for lagging strand polymerase recycling during bacteriophage T4 DNA replication

Given the polarity of DNA duplex, replication by the leading strand polymerase is continuous whereas that by the lagging strand polymerase is discontinuous proceeding through Okazaki fragments. Yet the respective polymerases act processively, implying that the recycling of the lagging strand polymerase is a controlled process. We demonstrate that the rate of the lagging strand polymerase relative to that of fork movement affects Okazaki fragment size and generates ssDNA gaps. We show by using a substrate with limited priming sites that Okazaki fragments can be shifted to shorter lengths by varying the rate of the primase. We find that clamp and clamp loader levels affect both primer utilization and Okazaki fragment size, possibly implicating clamp loading onto the RNA primer in the mechanism of lagging strand polymerase recycling. We formulate a signaling model capable of rationalizing the distribution of Okazaki fragments under various conditions for this and possibly other replisomes.     

Interactions of gene 2.5 protein and DNA polymerase of bacteriophage T7.

Bacteriophage T7 gene 2.5 protein has been shown to interact with T7 DNA polymerase (the complex of T7 gene 5 protein and Escherichia coli thioredoxin) by affinity chromatography and fluorescence emission anisotropy. T7 DNA polymerase binds specifically to a resin coupled to gene 2.5 protein and elutes from the resin when the ionic strength of the buffer is raised to 250 mM NaCl. In contrast, T7 gene 5 protein alone binds more weakly to gene 2.5 protein, eluting when the ionic strength of the buffer is 50 mM NaCl. Thioredoxin does not bind to gene 2.5 protein. Steady-state fluorescence emission anisotropy gives a dissociation constant of 1.1 +/- 0.2 microM for the complex of gene 2.5 protein and T7 DNA polymerase, with a ratio of gene 2.5 protein to T7 DNA polymerase in the complex of 1:1. Nanosecond emission anisotropic analysis suggests that the complex contains one monomer each of gene 2.5 protein, gene 5 protein, and thioredoxin. The ability of T7 gene 2.5 protein to stimulate the activity and processivity of T7 DNA polymerase is compared with the ability of three other single-stranded DNA-binding proteins: E. coli single-stranded DNA-binding protein, T4 gene 32 protein, and E. coli recA protein. All except E. coli recA protein stimulate the activity and processivity of T7 DNA polymerase; E. coli recA protein inhibits these activities.     

Characterization of the ribonucleic acid primers and the deoxyribonucleic acid product synthesized by the DNA polymerase and gene 4 protein of bacteriophage T7.

The DNA polymerase and gene 4 protein of phage T7, in the presence of helix-destabilizing protein (DNA binding protein), catalyze DNA synthesis on duplex templates. As has been previously shown (Kolodner, R. D., and Richardson, C. C. (1978) 4. Biol. Chem. 253, 574-584), in the absence of ribonucleoside 5'-triphosphates DNA synthesis is initiated at nicks, and all of the newly synthesized DNA is covalently attached to the template. In this paper we characterize the DNA synthesized in the presence of ribonucleoside 5'-triphophates and show that, in contrast, the major portion of the newly synthesized DNA is not attached to the template, having an average chain length of 5000 to 6000 nucleotides. In addition, each chain of newly synthesized DNA is terminated at its 5'-end by a covalently attached tetranucleotide RNA primer whose sequence is predominantly pppApCpCpC and pppApCpCpA. The results of isotope transfer experiments are in agreement with the number of initiation events determined by the incorporation of [gamma-32P]ATP and indicate that each of the four deoxyribonucleotides is present at the RNA-DNA junction.     

A molecular handoff between bacteriophage T7 DNA primase and T7 DNA polymerase initiates DNA synthesis

The T7 DNA primase synthesizes tetraribonucleotides that prime DNA synthesis by T7 DNA polymerase but only on the condition that the primase stabilizes the primed DNA template in the polymerase active site. We used NMR experiments and alanine scanning mutagenesis to identify residues in the zinc binding domain of T7 primase that engage the primed DNA template to initiate DNA synthesis by T7 DNA polymerase. These residues cover one face of the zinc binding domain and include a number of aromatic amino acids that are conserved in bacteriophage primases. The phage T7 single-stranded DNA-binding protein gp2.5 specifically interfered with the utilization of tetraribonucleotide primers by interacting with T7 DNA polymerase and preventing a productive interaction with the primed template. We propose that the opposing effects of gp2.5 and T7 primase on the initiation of DNA synthesis reflect a sequence of mutually exclusive interactions that occur during the recycling of the polymerase on the lagging strand of the replication fork.