Trypsin cleavage in the COOH terminus of the bacteriophage T4 gene 41 DNA helicase alters the primase-helicase activities of the T4 replication complex in vitro

The bacteriophage T4 gene 41 protein is a 5' to 3' DNA helicase which unwinds DNA ahead of the growing replication fork and, together with the T4 gene 61 protein, also functions as a primase to initiate DNA synthesis on the lagging strand. Proteolytic cleavage by trypsin approximately 20 amino acids from the COOH terminus of the 41 protein produces 41T, a 51,500-dalton fragment (possibly still associated with small COOH-terminal fragments) which still retains the ssDNA-stimulated GTPase (ATPase) activity, the 61 protein-stimulated DNA helicase activity, and the ability to act with 61 protein to synthesize pentaribonucleotide primers. In the absence of the T4 gene 32 ssDNA binding protein, the primase-helicase composed of the tryptic fragment (41T) and 61 proteins efficiently primes DNA synthesis on circular ssDNA templates by the T4 DNA polymerase and the three T4 polymerase accessory proteins. In contrast, the 41T protein is defective as a helicase or a primase component on 32 protein-covered DNA. Thus, unlike the intact protein, 41T does not support RNA-dependent DNA synthesis on 32 protein-covered ssDNA and does not stimulate strand displacement DNA synthesis on a nicked duplex DNA template. High concentrations of 32 protein strongly inhibit RNA primer synthesis with either 41 T or intact 41 protein. The 44/62 and 45 polymerase accessory proteins (and even the 44/62 proteins to some extent) substantially reverse the 32 protein inhibition of RNA primer synthesis with intact 41 protein but not with 41T protein. We propose that the COOH-terminal region of the 41 protein is required for its interaction with the T4 polymerase accessory proteins, permitting the synthesis and utilization of RNA primers and helicase function within the T4 replication complex. When this region is altered, as in 41T protein, the protein is unable to assemble a functional primase-helicase in the replication complex. An easy and rapid purification of T4 41 protein produced by a plasmid encoding this gene (Hinton, D. M., Silver, L. L., and Nossal, N. G. (1985) J. Biol. Chem. 260, 12851-12857) is also described.     

Prokaryotic DNA replication mechanisms

The three different prokaryotic replication systems that have been most extensively studied use the same basic components for moving a DNA replication fork, even though the individual proteins are different and lack extensive amino acid sequence homology. In the T4 bacteriophage system, the components of the DNA replication complex can be grouped into functional classes as follows: DNA polymerase (gene 43 protein), helix-destabilizing protein (gene 32 protein), polymerase accessory proteins (gene 44/62 and 45 proteins), and primosome proteins (gene 41 DNA helicase and gene 61 RNA primase). DNA synthesis in the in vitro system starts by covalent addition onto the 3'OH end at a random nick on a double-stranded DNA template and proceeds to generate a replication fork that moves at about the in vivo rate, and with approximately the in vivo base-pairing fidelity. DNA is synthesized at the fork in a continuous fashion on the leading strand and in a discontinuous fashion on the lagging strand (generating short Okazaki fragments with 5'-linked pppApCpXpYpZ pentaribonucleotide primers). Kinetic studies reveal that the DNA polymerase molecule on the lagging strand stays associated with the fork as it moves. Therefore the DNA template on the lagging strand must be folded so that the stop site for the synthesis of one Okazaki fragment is adjacent to the start site for the next such fragment, allowing the polymerase and other replication proteins on the lagging strand to recycle.     

Interactions of bacteriophage T4-coded primase (gp61) with the T4 replication helicase (gp41) and DNA in primosome formation.

One primase (gp61) and six helicase (gp41) subunits interact to form the bacteriophage T4-coded primosome at the DNA replication fork. In order to map some of the detailed interactions of the primase within the primosome, we have constructed and characterized variants of the gp61 primase that carry kinase tags at either the N or the C terminus of the polypeptide chain. These tagged gp61 constructs have been probed using several analytical methods. Proteolytic digestion and protein kinase protection experiments show that specific interactions with single-stranded DNA and the T4 helicase hexamer significantly protect both the N- and the C-terminal regions of the T4 primase polypeptide chain against modification by these procedures and that this protection becomes more pronounced when the primase is assembled within the complete ternary primosome complex. Additional discrete sites of both protection and apparent hypersensitivity along the gp61 polypeptide chain have also been mapped by proteolytic footprinting reactions for the binary helicase-primase complex and in the three component primosome. These studies provide a detailed map of a number of gp61 contact positions within the primosome and reveal interactions that may be important in the structure and function of this central component of the T4 DNA replication complex.     

Studies of the DNA helicase-RNA primase unit from bacteriophage T4. A trinucleotide sequence on the DNA template starts RNA primer synthesis

The purified DNA replication proteins encoded by genes 41 and 61 of bacteriophage T4 catalyze efficient RNA primer synthesis on a single-stranded DNA template. In the presence of additional T4 replication proteins, we demonstrate that the template sequences 5'-GTT-3' and 5'-GCT-3' serve as necessary and sufficient signals for RNA primer-dependent initiation of new DNA chains. These chains start with primers that have the sequences pppApCpNpNpN and pppGpCpNpNpN, where N can be any one of the four ribonucleotides. Each primer is initiated from the T (A-start primers) or C (G-start primers) in the center of the recognized template sequence. A subset of the DNA chain starts is observed when one of the four ribonucleoside triphosphates used as the substrates for primer synthesis is omitted; the starts observed reveal that both pentaribonucleotide and tetraribonucleotide primers can be used for efficient initiation of new DNA chains, whereas primers that are only 3 nucleotides long are inactive. It was known previously that, when 61 protein is present in catalytic amounts, the 41 and 61 proteins are both required for observing RNA primer synthesis. However, by raising the concentration of the 61 protein to a much higher level, a substantial amount of RNA-primed DNA synthesis is obtained in the absence of 41 protein. The DNA chains made are initiated by primers that seem to be identical to those made when both 41 and 61 proteins are present; however, only those template sites containing the 5'-GCT-3' sequence are utilized. The 61 protein is, therefore, the RNA primase, whereas the 41 protein should be viewed as a DNA helicase that is required (presumably via a 41/61 complex) for efficient primase recognition of both the 5'-GCT-3' and 5'-GTT-3' DNA template sequences.     

The oligomeric T4 primase is the functional form during replication

Replisome DNA primases are responsible for the synthesis of short RNA primers required for the initiation of repetitive Okazaki fragment synthesis on the lagging strand during DNA replication. In bacteriophage T4, the primase (gp61) interacts with the helicase (gp41) to form the primosome complex, an interaction that greatly stimulates the priming activity of gp61. Because gp41 is hexameric, a question arises as to whether gp61 also forms a hexameric structure during replication. Several results from this study support such a structure. Titration of the primase/single-stranded DNA binding followed by fluorescence anisotropy implicated a 6:1 stoichiometry. The observed rate constant, k(cat), for priming was found to increase with the primase concentration, implicating an oligomeric form of the primase as the major functional species. The generation of hetero-oligomeric populations of the hexameric primase by controlled mixing of wild type and an inactive mutant primase confirmed the oligomeric nature of the most active primase form. Mutant primases defective in either the N- or C-terminal domains and catalytically inactive could be mixed to create oligomeric primases with restored catalytic activity suggesting an active site shared between subunits. Collectively, these results provide strong evidence for the functional oligomerization of gp61. The potential roles of gp61 oligomerization during lagging strand synthesis are discussed.     

Essential lysine residues in the RNA polymerase domain of the gene 4 primase-helicase of bacteriophage T7.

At a replication fork DNA primase synthesizes oligoribonucleotides that serve as primers for the lagging strand DNA polymerase. In the bacteriophage T7 replication system, DNA primase is encoded by gene 4 of the phage. The 63-kDa gene 4 protein is composed of two major domains, a helicase domain and a primase domain located in the C- and N-terminal halves of the protein, respectively. T7 DNA primase recognizes the sequence 5'-NNGTC-3' via a zinc motif and catalyzes the template-directed synthesis of tetraribonucleotides pppACNN. T7 DNA primase, like other primases, shares limited homology with DNA-dependent RNA polymerases. To identify the catalytic core of the T7 DNA primase, single-point mutations were introduced into a basic region that shares sequence homology with RNA polymerases. The genetically altered gene 4 proteins were examined for their ability to support phage growth, to synthesize functional primers, and to recognize primase recognition sites. Two lysine residues, Lys-122 and Lys-128, are essential for phage growth. The two residues play a key role in the synthesis of phosphodiester bonds but are not involved in other activities mediated by the protein. The altered primases are unable to either synthesize or extend an oligoribonucleotide. However, the altered primases do recognize the primase recognition sequence, anneal an exogenous primer 5'-ACCC-3' at the site, and transfer the primer to T7 DNA polymerase. Other lysines in the vicinity are not essential for the synthesis of primers.     

Characterization of the bacteriophage T4 gene 41 DNA helicase

The T4 gene 41 protein and the gene 61 protein function together as a primase-helicase within the seven protein bacteriophage T4 multienzyme complex that replicates duplex DNA in vitro. We have previously shown that the 41 protein is a 5' to 3' helicase that requires a single-stranded region on the 5' side of the duplex to be unwound and is stimulated by the 61 protein (Venkatesan, M., Silver L. L., and Nossal, N. G. (1982) J. biol. Chem. 257, 12426-12434). The 41 protein, in turn, is required for pentamer primer synthesis by the 61 protein. We now show that the 41 protein helicase unwinds a partially duplex DNA molecule containing a performed fork more efficiently than a DNA molecule without a fork. Optimal helicase activity requires greater than 29 nucleotides of single-stranded DNA on the 3' side of the duplex (analogous to the leading strand template). This result suggests the 41 protein helicase interacts with the leading strand template as well as the lagging strand template as it unwinds the duplex region at the replication fork. As the single-stranded DNA on the 3' side of a short duplex (51 base pairs) is lengthened, the stimulation of the 41 protein helicase by the 61 protein is diminished. However, both the 61 protein and a preformed fork are essential for efficient unwinding of longer duplex regions (650 base pairs). These findings suggest that the 61 protein promotes both the initial unwinding of the duplex to form a fork and subsequent unwinding of longer duplexes by the 41 protein. A stable protein-DNA complex, detected by a gel mobility shift of phi X174 single-stranded DNA, requires both the 41 and 61 proteins and a rNTP (preferably rATP or rGTP, the nucleotides with the greatest effect on the helicase activity). In the accompanying paper, we report the altered properties of a proteolytic fragment of the 41 protein helicase and its effect on in vitro DNA synthesis in the T4 multienzyme replication system.     

The Escherichia coli primosome can translocate actively in either direction along a DNA strand

The primosome is a mobile multiprotein DNA replication-priming apparatus that requires seven Escherichia coli proteins (replication factor Y (protein n'), proteins n and n", and the products of the dnaB, dnaC, dnaT, and dnaG genes) for assembly at a specific site (termed a primosome assembly site) on single-stranded DNA binding protein-coated single-stranded DNA. Two of the protein components of the primosome have intrinsic DNA helicase activity. The DNA B protein acts in the 5'----3' direction, whereas factor Y acts in the 3'----5' direction. The primosome complex has DNA helicase activity when present at a replication fork in conjunction with the DNA polymerase III holoenzyme. In this report, evidence is presented that the multiprotein primosome per se can act as a DNA helicase in the absence of the DNA polymerase III holoenzyme. The primosome DNA helicase activity can be manifested in either direction along the DNA strand. The directionality of the primosome DNA helicase activity is modulated by the concentration and type of nucleoside triphosphate present in the reaction mixture. This DNA helicase activity requires all the preprimosomal proteins (the primosomal proteins minus the dnaG-encoded primase). Preprimosome complexes must assemble at a primosome assembly site in order to be loaded onto the single-stranded DNA and act subsequently as a DNA helicase. The 5'----3' primosome DNA helicase activity requires a 3' single-stranded tail on the fragment to be displaced, while the 3'----5' activity does not require a 5' single-stranded tail on the fragment to be displaced. Multienzyme preprimosomes moving in either direction are capable of associating with the primase to form complete primosomes that can synthesize RNA primers.     

Mechanisms of primer RNA synthesis and D-loop/R-loop-dependent DNA replication in Escherichia coli

In DNA replication, DNA chains are generally initiated from small pieces of ribonucleotides attached to DNA templates. These ‘primers’ are synthesized by various enzymatic mechanisms in Escherichia coli. Studies on primer RNA synthesis on single-stranded DNA templates containing specific ‘priming signals’ revealed the presence of two distinct modes, ie immobile and mobile priming. The former includes primer RNA synthesis by primase encoded by dnaG and by RNA polymerase containing a σ⁷⁰ subunit. Priming is initiated at a specific site in immobile priming. Novel immobile priming signals were identified from various plasmid replicaons, some of which function in initiation of the leading strand synthesis. The latter, on the other hand, involves a protein complex, primosome, which contains DnaB, the replicative helicase for E coli chromosomal replication. Utilizing the energy fueled by ATP hydrolysis of DnaB protein, primosomes are able to translocate on a template DNA and primase synthesizes primer RNAs at multiple sites. Two distinct primosomes. DnaA-dependent primosome supports normal chromosomal identified, which are differentially utilized for E coli chromosomal replication. Whereas DnaA-dependent primosome supports normal chromosomal replication from oriC, the PriA-dependent primosome functions in oriC-independent chromosomal replication observed in DNA-damaged cells or cells lacking RNaseH activity. In oriC-independent replication, PriA protein may recognize the D- or R-loop structure, respectively, to initiate assembly of a primosome which mediates primer RNA synthesis and replication fork progression.     

Characterization of the DNA-dependent GTPase activity of T4 gene 41 protein, an essential component of the T4 bacteriophage DNA replication apparatus

The product specified by T4 bacteriophage gene 41 is known from genetic analyses to be essential for phage DNA replication in vivo. Correspondingly, the purified gene 41 protein is an essential component of an efficient in vitro DNA replication system reconstructed from seven purified T4 replication proteins; it is required both for the synthesis of short RNA primers (in conjunction with the T4 gene 61 protein) and for the rapid unwinding of the double-helical DNA template at a replication fork. The purified gene 41 protein exhibits a DNA-dependent GTPase (and ATPase) activity. In this report, we have used this associated GTPase activity as a biochemical probe for the analysis of the interactions between DNA and the 41 protein. Our results suggest that, upon binding GTP, the 41 protein monomer is induced to form a dimer, which can them form a tight complex with single-stranded DNA. Driven by the repeated hydrolysis of GTP molecules, the 41 protein dimer appears to run rapidly along the bound DNA chain. Studies with the synthetic GTP analogue, GTP gamma S, suggest that GTP hydrolysis is required for this 41 protein movement, but that it is not essential for the function of the 41 protein in RNA primer synthesis. In sum, our observations suggest that a 41 protein dimer runs along the lagging strand template at a DNA replication fork; from this position, it functions as a DNA helicase and simultaneously interacts with the T4 gene 61 protein to make the pentaribonucleotide primers which initiate Okazaki pieces at specific primer initiation 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.     

Mechanism and stoichiometry of interaction of DnaG primase with DnaB helicase of Escherichia coli in RNA primer synthesis

Initiation and synthesis of RNA primers in the lagging strand of the replication fork in Escherichia coli requires the replicative DnaB helicase and the DNA primase, the DnaG gene product. In addition, the physical interaction between these two replication enzymes appears to play a role in the initiation of chromosomal DNA replication. In vitro, DnaB helicase stimulates primase to synthesize primers on single-stranded (ss) oligonucleotide templates. Earlier studies hypothesized that multiple primase molecules interact with each DnaB hexamer and single-stranded DNA. We have examined this hypothesis and determined the exact stoichiometry of primase to DnaB hexamer. We have also demonstrated that ssDNA binding activity of the DnaB helicase is necessary for directing the primase to the initiator trinucleotide and synthesis of 11-20-nucleotide long primers. Although, association of these two enzymes determines the extent and rate of synthesis of the RNA primers in vitro, direct evidence of the formation of primase-DnaB complex has remained elusive in E. coli due to the transient nature of their interaction. Therefore, we stabilized this complex using a chemical cross-linker and carried out a stoichiometric analysis of this complex by gel filtration. This allowed us to demonstrate that the primase-helicase complex of E. coli is comprised of three molecules of primase bound to one DnaB hexamer. Fluorescence anisotropy studies of the interaction of DnaB with primase, labeled with the fluorescent probe Ru(bipy)3, and Scatchard analysis further supported this conclusion. The addition of DnaC protein, leading to the formation of the DnaB-DnaC complex, to the simple priming system resulted in the synthesis of shorter primers. Therefore, interactions of the DnaB-primase complex with other replication factors might be critical for determining the physiological length of the RNA primers in vivo and the overall kinetics of primer synthesis.     

Bacteriophage T4 DNA replication protein 41. Cloning of the gene and purification of the expressed protein

The bacteriophage T4 primase, composed of the T4 proteins 41 and 61, synthesizes pentaribonucleotides used to prime DNA synthesis on single-stranded DNA in vitro. 41 protein is also a DNA helicase that opens DNA in the same direction as the growing replication fork. Previously, Mattson et al. (Mattson, T., Van Houwe, G., Bolle, A., Selzer, G., and Epstein, R. (1977) Mol. Gen. Genet. 154, 319-326) located part of gene 41 on a 3400-base pair EcoRI fragment of T4 DNA (map units 24.3 to 21.15). In this paper, we report the cloning of T4 DNA representing map units 24.3 to 20.06 in a multicopy plasmid vector. Extracts of cells containing this plasmid complement gene 41- extracts in a DNA synthesis assay, indicating that this region contains all the information necessary for the expression of active 41 protein. We located gene 41 more precisely between T4 map units 22.01 to 20.06 since our cloning of this region downstream of the strong lambda promoter PL results in the production of active 41 protein at a level 100-fold greater than after T4 infection. We have purified 133 mg of homogeneous 41 protein from 27 g of these cells. Like the 41 protein from T4 infected cells, the purified 41 protein in conjunction with the T4 gene 61 priming protein catalyzes primer formation (assayed by RNA primer-dependent DNA synthesis with T4 polymerase, the genes 44/62 and 45 polymerase accessory proteins, and the gene 32 helix-destabilizing protein) and is a helicase whose activity is stimulated by T4 61 protein.     

Primosome assembly site in Bacillus subtilis.

A single-strand initiation site was detected on the Enterococcus faecalis plasmid pAM beta 1 by its ability to prevent accumulation of single stranded DNA of a rolling circle plasmid, both in Bacillus subtilis and Staphylococcus aureus. This site, designated ssiA, is located on the lagging strand template, approximately 150 bp downstream from the replication origin. ssiA priming activity requires the DnaE primase, the DnaC replication fork helicase, as well as the products of the dnaB, dnaD and dnaI genes of B.subtilis, but not the RNA polymerase. The primase and the replication fork helicase requirements indicate that ssiA is a primosome assembly site. Interestingly, the pAM beta 1 lagging strand synthesis is inefficient when any of the proteins involved in ssiA activity is mutated, but occurs efficiently in the absence of ssiA. This suggests that normal plasmid replication requires primosome assembly and that the primosome can assemble not only at ssiA but also elsewhere on the plasmid. This work for the first time describes a primosome in a Gram-positive bacterium. Involvement of the B.subtilis proteins DnaB, DnaD and DnaI, which do not have any known analogue in Escherichia coli, raises the possibility that primosome assembly and/or function in B.subtilis differs from that in E.coli.     

Interaction of the bacteriophage T4 gene 59 helicase loading protein and gene 41 helicase with each other and with fork, flap, and cruciform DNA

Bacteriophage T4 gene 59 helicase loading protein accelerates the loading of T4 gene 41 DNA helicase and is required for recombination-dependent DNA replication late in T4 phage infection. The crystal structure of 59 protein revealed a two-domain alpha-helical protein, whose N-terminal domain has strong structural similarity to the DNA binding domain of high mobility group family proteins (Mueser, T. C., Jones, C. E., Nossal, N. G., and Hyde, C. C. (2000) J. Mol. Biol. 296, 597-612). We have previously shown that 59 protein binds preferentially to fork DNA. Here we show that 59 protein binds to completely duplex forks but cannot load the helicase unless there is a single-stranded gap of more than 5 nucleotides on the fork arm corresponding to the lagging strand template. Consistent with the roles of these proteins in recombination, we find that 59 protein binds to and stimulates 41 helicase activity on Holliday junction DNA, and on a substrate that resembles a strand invasion structure. 59 protein forms a stable complex with wild type 41 helicase and fork DNA in the presence of adenosine 5'-O-(thiotriphosphate). The unwinding activity of 41 helicase missing 20 C-terminal amino acids is not stimulated by 59 protein, and it does not form a complex with 59 protein on fork DNA.     

Conserved residues of the C-terminal p16 domain of primase are involved in modulating the activity of the bacterial primosome

The bacterial primosome comprises the replicative homo-hexameric ring helicase DnaB and the primase DnaG. It is an integral component of the replisome as it unwinds the parental DNA duplex to allow progression of the replication fork, synthesizes the initiation primers at the replication origin, oriC , and the primers required for Okazaki fragment synthesis during lagging strand replication. The interaction between the two component proteins is mediated by a distinct C-terminal domain (p16) of the primase. Both proteins mutually regulate each other's activities and a putative network of conserved residues has been proposed to mediate these effects. We have targeted 10 residues from this network. To investigate the functional contributions of these residues to the primase, ATPase and helicase activities of the primosome, we have used site-directed mutagenesis and in vitro functional assays. Five of these residues (E464, H494, R495, Y548 and R555) exhibited some functional significance while the remaining five (E483, R484, E506, D512 and E530) exhibited no effects. E464 participates in functional modulation of the primase activity, whereas H494, R495 and R555 participate in allosteric functional modulation of the ATPase and/or helicase activities. Y548 contributes directly to the structural interaction with DnaB.     

Sequence-specific pausing during in vitro DNA replication on double-stranded DNA templates

Sequence-specific pausing occurs during DNA synthesis catalyzed by the bacteriophage T4 DNA polymerase holoenzyme in the presence of the T4 helix destabilizing protein (gene 32 protein). Two of the six strongest pause sites on a double-stranded bacteriophage fd DNA template are in regions where hairpin helices are predicted to form when the DNA is single stranded. However, the other pause sites are in regions that are not obviously involved in secondary structure. The positions of the DNA chain ends produced at one pause site of each type were determined to within +/- 2 nucleotides. At this resolution, a clustering of sites is observed, suggesting that the polymerase holoenzyme may become destabilized when moving along selected regions of the DNA and then pause at one or more of several closely spaced positions. The addition of the T4 gene 41 protein (a DNA helicase that forms part of the T4 primosome) to the above replication system greatly increases the rate of fork movement and eliminates detectable pausing. In contrast, the addition of the T4 dda protein (a second DNA helicase that increases the rate of fork movement to a similar extent) has no affect on replication fork pausing. This difference could either be due to specific protein-protein interactions formed between the polymerase holoenzyme and the 41 protein or to the highly processive movement of the 41 protein along the displaced DNA strand.     

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).     

The crystal structure of the bifunctional primase-helicase of bacteriophage T7

Within minutes after infecting Escherichia coli, bacteriophage T7 synthesizes many copies of its genomic DNA. The lynchpin of the T7 replication system is a bifunctional primase-helicase that unwinds duplex DNA at the replication fork while initiating the synthesis of Okazaki fragments on the lagging strand. We have determined a 3.45 A crystal structure of the T7 primase-helicase that shows an articulated arrangement of the primase and helicase sites. The crystallized primase-helicase is a heptamer with a crown-like shape, reflecting an intimate packing of helicase domains into a ring that is topped with loosely arrayed primase domains. This heptameric isoform can accommodate double-stranded DNA in its central channel, which nicely explains its recently described DNA remodeling activity. The double-jointed structure of the primase-helicase permits a free range of motion for the primase and helicase domains that suggests how the continuous unwinding of DNA at the replication fork can be periodically coupled to Okazaki fragment synthesis.