Roles of the helicase and primase domain of the gene 4 protein of bacteriophage T7 in accessing the primase recognition site

Residues located in the primase domain of the bacteriophage T7 primase-helicase are essential for loading the hexameric complex onto DNA

The T7 primase-helicase plays a pivotal role in the replication of T7 DNA. Using affinity isolation of peptide–nucleic acid crosslinks and mass spectrometry, we identify protein regions in the primase-helicase and T7 DNA polymerase that form contacts with the RNA primer and DNA template. The contacts between nucleic acids and the primase domain of the primase-helicase are centered in the RNA polymerase subdomain of the primase domain, in a cleft between the N-terminal subdomain and the topoisomerase-primase fold. We demonstrate that residues along a beta sheet in the N-terminal subdomain that contacts the RNA primer are essential for phage growth and primase activity in vitro. Surprisingly, we found mutations in the primase domain that had a dramatic effect on the helicase. Substitution of a residue conserved in other DnaG-like enzymes, R84A, abrogates both primase and helicase enzymatic activities of the T7 primase-helicase. Alterations in this residue also decrease binding of the primase-helicase to ssDNA. However, mass photometry measurements show that these mutations do not interfere with the ability of the protein to form the active hexamer.

It seems like only yesterday

I spent my childhood and adolescence in North and South Carolina, attended Duke University, and then entered Duke Medical School. One year in the laboratory of George Schwert in the biochemistry department kindled my interest in biochemistry. After one year of residency on the medical service of Duke Hospital, chaired by Eugene Stead, I joined the group of Arthur Kornberg at Stanford Medical School as a postdoctoral fellow. Two years later I accepted a faculty position at Harvard Medical School, where I remain today. During these 50 years, together with an outstanding group of students, postdoctoral fellows, and collaborators, I have pursued studies on DNA replication. I have experienced the excitement of discovering a number of important enzymes in DNA replication that, in turn, triggered an interest in the dynamics of a replisome. My associations with industry have been stimulating and fostered new friendships. I could not have chosen a better career.

Novel interaction of the bacterial-Like DnaG primase with the MCM helicase in archaea

DNA priming and unwinding activities are coupled within bacterial primosome complexes to initiate synthesis on the lagging strand during DNA replication. Archaeal organisms contain conserved primase genes homologous to both the bacterial DnaG and archaeo-eukaryotic primase families. The inclusion of multiple DNA primases within a whole domain of organisms complicates the assignment of the metabolic roles of each. In support of a functional bacterial-like DnaG primase participating in archaeal DNA replication, we have detected an interaction of Sulfolobus solfataricus DnaG (SsoDnaG) with the replicative S. solfataricus minichromosome maintenance (SsoMCM) helicase on DNA. The interaction site has been mapped to the N-terminal tier of SsoMCM analogous to bacterial primosome complexes. Mutagenesis within the metal binding site of SsoDnaG verifies a functional homology with bacterial DnaG that perturbs priming activity and DNA binding. The complex of SsoDnaG with SsoMCM stimulates the ATPase activity of SsoMCM but leaves the priming activity of SsoDnaG unchanged. Competition for binding DNA between SsoDnaG and SsoMCM can reduce the unwinding ability. Fluorescent gel shift experiments were used to quantify the binding of the ternary SsoMCM-DNA-SsoDnaG complex. This direct interaction of a bacterial-like primase with a eukaryotic-like helicase suggests that formation of a unique but homologous archaeal primosome complex is possible but may require other components to stimulate activities. Identification of this archaeal primosome complex broadly impacts evolutionary relationships of DNA replication.

Mechanism of sequence-specific template binding by the DNA primase of bacteriophage T7

DNA primases catalyze the synthesis of the oligoribonucleotides required for the initiation of lagging strand DNA synthesis. Biochemical studies have elucidated the mechanism for the sequence-specific synthesis of primers. However, the physical interactions of the primase with the DNA template to explain the basis of specificity have not been demonstrated. Using a combination of surface plasmon resonance and biochemical assays, we show that T7 DNA primase has only a slightly higher affinity for DNA containing the primase recognition sequence (5′-TGGTC-3′) than for DNA lacking the recognition site. However, this binding is drastically enhanced by the presence of the cognate Nucleoside triphosphates (NTPs), Adenosine triphosphate (ATP) and Cytosine triphosphate (CTP) that are incorporated into the primer, pppACCA. Formation of the dimer, pppAC, the initial step of sequence-specific primer synthesis, is not sufficient for the stable binding. Preformed primers exhibit significantly less selective binding than that observed with ATP and CTP. Alterations in subdomains of the primase result in loss of selective DNA binding. We present a model in which conformational changes induced during primer synthesis facilitate contact between the zinc-binding domain and the polymerase domain.

Initiation of new DNA strands by the herpes simplex virus-1 primase-helicase complex and either herpes DNA polymerase or human DNA polymerase alpha

A key set of reactions for the initiation of new DNA strands during herpes simplex virus-1 replication consists of the primase-catalyzed synthesis of short RNA primers followed by polymerase-catalyzed DNA synthesis (i.e. primase-coupled polymerase activity). Herpes primase (UL5-UL52-UL8) synthesizes products from 2 to approximately 13 nucleotides long. However, the herpes polymerase (UL30 or UL30-UL42) only elongates those at least 8 nucleotides long. Surprisingly, coupled activity was remarkably inefficient, even considering only those primers at least 8 nucleotides long, and herpes polymerase typically elongated <2% of the primase-synthesized primers. Of those primers elongated, only 4-26% of the primers were passed directly from the primase to the polymerase (UL30-UL42) without dissociating into solution. Comparing RNA primer-templates and DNA primer-templates of identical sequence showed that herpes polymerase greatly preferred to elongate the DNA primer by 650-26,000-fold, thus accounting for the extremely low efficiency with which herpes polymerase elongated primase-synthesized primers. Curiously, one of the DNA polymerases of the host cell, polymerase alpha (p70-p180 or p49-p58-p70-p180 complex), extended herpes primase-synthesized RNA primers much more efficiently than the viral polymerase, raising the possibility that the viral polymerase may not be the only one involved in herpes DNA replication.

Identification of a DNA primase template tracking site redefines the geometry of primer synthesis

Primases are essential RNA polymerases required for the initiation of DNA replication, lagging strand synthesis and replication restart. Many aspects of primase function remain unclear, including how the enzyme associates with a moving nucleic acid strand emanating from a helicase and orients primers for handoff to replisomal components. Using a new screening method to trap transient macromolecular interactions, we determined the structure of the Escherichia coli DnaG primase catalytic domain bound to single-stranded DNA. The structure reveals an unanticipated binding site that engages nucleic acid in two distinct configurations, indicating that it serves as a nonspecific capture and tracking locus for template DNA. Bioinformatic and biochemical analyses show that this evolutionarily constrained region enforces template polarity near the active site and is required for primase function. Together, our findings reverse previous proposals for primer-template orientation and reconcile disparate studies to re-evaluate replication fork organization.

Oligomeric states of bacteriophage T7 gene 4 primase/helicase

Electron microscopic and crystallographic data have shown that the gene 4 primase/helicase encoded by bacteriophage T7 can form both hexamers and heptamers. After cross-linking with glutaraldehyde to stabilize the oligomeric protein, hexamers and heptamers can be distinguished either by negative stain electron microscopy or electrophoretic analysis using polyacrylamide gels. We find that hexamers predominate in the presence of either dTTP or beta,gamma-methylene dTTP whereas the ratio between hexamers and heptamers is nearly the converse in the presence of dTDP. When formed, heptamers are unable to efficiently bind either single-stranded DNA or double-stranded DNA. We postulate that a switch between heptamer to hexamer may provide a ring-opening mechanism for the single-stranded DNA binding pathway. Accordingly, we observe that in the presence of both nucleoside di- and triphosphates the gene 4 protein exists as a hexamer when bound to single-stranded DNA and as a mixture of heptamer and hexamer when not bound to single-stranded DNA. Furthermore, altering regions of the gene 4 protein postulated to be conformational switches for dTTP-dependent helicase activity leads to modulation of the heptamer to hexamer ratio.

DNA primase acts as a molecular brake in DNA replication

A hallmark feature of DNA replication is the coordination between the continuous polymerization of nucleotides on the leading strand and the discontinuous synthesis of DNA on the lagging strand. This synchronization requires a precisely timed series of enzymatic steps that control the synthesis of an RNA primer, the recycling of the lagging-strand DNA polymerase, and the production of an Okazaki fragment. Primases synthesize RNA primers at a rate that is orders of magnitude lower than the rate of DNA synthesis by the DNA polymerases at the fork. Furthermore, the recycling of the lagging-strand DNA polymerase from a finished Okazaki fragment to a new primer is inherently slower than the rate of nucleotide polymerization. Different models have been put forward to explain how these slow enzymatic steps can take place at the lagging strand without losing coordination with the continuous and fast leading-strand synthesis. Nonetheless, a clear picture remains elusive. Here we use single-molecule techniques to study the kinetics of a multiprotein replication complex from bacteriophage T7 and to characterize the effect of primase activity on fork progression. We observe the synthesis of primers on the lagging strand to cause transient pausing of the highly processive leading-strand synthesis. In the presence of both leading- and lagging-strand synthesis, we observe the formation and release of a replication loop on the lagging strand. Before loop formation, the primase acts as a molecular brake and transiently halts progression of the replication fork. This observation suggests a mechanism that prevents leading-strand synthesis from outpacing lagging-strand synthesis during the slow enzymatic steps on the lagging strand.

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.

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.

Dissociative Properties of the Proteins within the Bacteriophage T4 Replisome

DNA replication is a highly processive and efficient process that involves the coordination of at least eight proteins to form the replisome in bacteriophage T4. Replication of DNA occurs in the 5' to 3' direction resulting in continuous replication on the leading strand and discontinuous replication on the lagging strand. A key question is how a continuous and discontinuous replication process is coordinated. One solution is to avoid having the completion of one Okazaki fragment to signal the start of the next but instead to have a key step such as priming proceed in parallel to lagging strand replication. Such a mechanism requires protein elements of the replisome to readily dissociate during the replication process. Protein trapping experiments were performed to test for dissociation of the clamp loader and primase from an active replisome in vitro whose template was both a small synthetic DNA minicircle and a larger DNA substrate. The primase, clamp, and clamp loader are found to dissociate from the replisome and are continuously recruited from solution. The effect of varying protein concentrations (dilution) on the size of Okazaki fragments supported the protein trapping results. These findings are in accord with previous results for the accessory proteins but, importantly now, identify the primase as dissociating from an active replisome. The recruitment of the primase from solution during DNA synthesis has also been found for Escherichia coli but not bacteriophage T7. The implications of these results for RNA priming and extension during the repetitive synthesis of Okazaki fragments are discussed.

Modular architecture of the bacteriophage T7 primase couples RNA primer synthesis to DNA synthesis

DNA primases are template-dependent RNA polymerases that synthesize oligoribonucleotide primers that can be extended by DNA polymerase. The bacterial primases consist of zinc binding and RNA polymerase domains that polymerize ribonucleotides at templating sequences of single-stranded DNA. We report a crystal structure of bacteriophage T7 primase that reveals its two domains and the presence of two Mg(2+) ions bound to the active site. NMR and biochemical data show that the two domains remain separated until the primase binds to DNA and nucleotide. The zinc binding domain alone can stimulate primer extension by T7 DNA polymerase. These findings suggest that the zinc binding domain couples primer synthesis with primer utilization by securing the DNA template in the primase active site and then delivering the primed DNA template to DNA polymerase. The modular architecture of the primase and a similar mechanism of priming DNA synthesis are likely to apply broadly to prokaryotic primases.

Interaction of adjacent primase domains within the hexameric gene 4 helicase-primase of bacteriophage T7

The interaction of primase monomers within the hexameric gene 4 helicase-primase of bacteriophage T7 has been examined by using two genetically distinct gene 4 proteins. The T7 56-kDa gene 4 protein differs from the full-length 63-kDa protein in that it lacks the N-terminal zinc motif essential for the recognition of primase recognition sites. A second gene 4 protein, gp4-K122A, is unable to catalyze the synthesis of phosphodiester bonds as the result of an amino acid change in the catalytic site. Although each protein alone is inactive, the two together catalyze the synthesis of RNA primers. Reconstitution of activity depends on hexamer formation. We propose that the zinc motif of one subunit in the hexamer interacts with the catalytic sites of adjacent subunits.

Replisome-mediated DNA replication

The elaborate process of genomic replication requires a large collection of proteins properly assembled at a DNA replication fork. Several decades of research on the bacterium Escherichia coli and its bacteriophages T4 and T7 have defined the roles of many proteins central to DNA replication. These three different prokaryotic replication systems use the same fundamental components for synthesis at a moving DNA replication fork even though the number and nature of some individual proteins are different and many lack extensive sequence homology. The components of the replication complex can be grouped into functional categories as follows: DNA polymerase, helix destabilizing protein, polymerase accessory factors, and primosome (DNA helicase and DNA primase activities). The replication of DNA derives from a multistep enzymatic pathway that features the assembly of accessory factors and polymerases into a functional holoenzyme; the separation of the double-stranded template DNA by helicase activity and its coupling to the primase synthesis of RNA primers to initiate Okazaki fragment synthesis; and the continuous and discontinuous synthesis of the leading and lagging daughter strands by the polymerases. This review summarizes and compares and contrasts for these three systems the types, timing, and mechanism of reactions and of protein-protein interactions required to initiate, control, and coordinate the synthesis of the leading and lagging strands at a DNA replication fork and comments on their generality.

DNA primases

DNA primases are enzymes whose continual activity is required at the DNA replication fork. They catalyze the synthesis of short RNA molecules used as primers for DNA polymerases. Primers are synthesized from ribonucleoside triphosphates and are four to fifteen nucleotides long. Most DNA primases can be divided into two classes. The first class contains bacterial and bacteriophage enzymes found associated with replicative DNA helicases. These prokaryotic primases contain three distinct domains: an amino terminal domain with a zinc ribbon motif involved in binding template DNA, a middle RNA polymerase domain, and a carboxyl-terminal region that either is itself a DNA helicase or interacts with a DNA helicase. The second major primase class comprises heterodimeric eukaryotic primases that form a complex with DNA polymerase alpha and its accessory B subunit. The small eukaryotic primase subunit contains the active site for RNA synthesis, and its activity correlates with DNA replication during the cell cycle.

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.

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.

A zinc ribbon protein in DNA replication: primer synthesis and macromolecular interactions by the bacteriophage T4 primase

The gene product 61 primase protein from bacteriophage T4 was expressed as an intein fusion and purified to homogeneity. The primase binds one zinc ion, which is coordinated by four cysteine residues to form a zinc ribbon motif. Factors that influence the rate of priming were investigated, and a physiologically relevant priming rate of approximately 1 primer per second per primosome was achieved. Primase binding to the single-stranded binding protein (1 primase:4 gp32 monomers; K(d) approximately 860 nM) and to the helicase protein in the presence of DNA and ATP-gamma-S (1 primase:1 helicase monomer; K(d) approximately 100 nM) was investigated by isothermal titration calorimetry (ITC). Because the helicase is hexameric, the inferred stoichiometry of primase binding as part of the primosome is helicase hexamer:primase in a ratio of 1:6, suggesting that the active primase, like the helicase, might have a ring-like structure. The primase is a monomer in solution but binds to single-stranded DNA (ssDNA) primarily as a trimer (K(d) approximately 50-100 nM) as demonstrated by ITC and chemical cross-linking. Magnesium is required for primase-ssDNA binding. The minimum length of ssDNA required for stable binding is 22-24 bases, although cross-linking reveals transient interactions on oligonucleotides as short as 8 bases. The association is endothermic at physiologically relevant temperatures, which suggests an overall gain in entropy upon binding. Some possible sources of this gain in entropy are discussed.

The primase active site is on the outside of the hexameric bacteriophage T7 gene 4 helicase-primase ring

Gene 4 of bacteriophage T7 encodes a protein (gp4) that can translocate along single-stranded DNA, couple the unwinding of duplex DNA with the hydrolysis of dTTP, and catalyze the synthesis of short RNA oligoribonucleotides for use as primers by T7 DNA polymerase. Electron microscopic studies have shown that gp4 forms hexameric rings, and X-ray crystal structures of the gp4 helicase domain and of the highly homologous RNA polymerase domain of Escherichia coli DnaG have been determined. Earlier biochemical studies have shown that when single-stranded DNA is bound to the hexameric ring, the primase domain remains accessible to free DNA. Given these results, a model was suggested in which the primase active site in the gp4 hexamer is located on the outside of the hexameric ring. We have used electron microscopy and single-particle image analysis to examine T7 gp4, and have determined that the primase active site is located on the outside of the hexameric ring, and therefore provide direct structural support for this model.

Structure and function of hexameric helicases

Helicases are motor proteins that couple the hydrolysis of nucleoside triphosphate (NTPase) to nucleic acid unwinding. The hexameric helicases have a characteristic ring-shaped structure, and all, except the eukaryotic minichromosomal maintenance (MCM) helicase, are homohexamers. Most of the 12 known hexameric helicases play a role in DNA replication, recombination, and transcription. A human genetic disorder, Bloom's syndrome, is associated with a defect in one member of the class of hexameric helicases. Significant progress has been made in understanding the biochemical properties, structures, and interactions of these helicases with DNA and nucleotides. Cooperativity in nucleotide binding was observed in many, and sequential NTPase catalysis has been observed in two proteins, gp4 of bacteriophage T7 and rho of Escherichia coli. The crystal structures of the oligomeric T7 gp4 helicase and the hexamer of RepA helicase show structural features that substantiate the observed cooperativity, and both are consistent with nucleotide binding at the subunit interface. Models are presented that show how sequential NTP hydrolysis can lead to unidirectional and processive translocation. Possible unwinding mechanisms based on the DNA exclusion model are proposed here, termed the wedge, torsional, and helix-destabilizing models.

A ring-opening mechanism for DNA binding in the central channel of the T7 helicase-primase protein

We have investigated the mechanism of binding single-stranded DNA (ssDNA) into the central channel of the ring-shaped T7 gp4A' helicase-primase hexamer. Presteady-state kinetic studies show a facilitated five-step mechanism and provide understanding of how a ring-shaped helicase can be loaded on the DNA during the initiation of replication. The effect of a primase recognition sequence on the observed kinetics suggests that binding to the helicase DNA-binding site is facilitated by transient binding to the primase DNA-binding site, which is proposed to be a loading site. The proposed model involves the fast initial binding of the DNA to the primase site on the outside of the helicase ring, a fast conformational change, a ring-opening step, migration of the DNA into the central channel of the helicase ring, and ring closure. Although an intermediate protein-DNA complex is kinetically stable, only the last species in the five-step mechanism is poised to function as a helicase at the unwinding junction.

Patterns of regulation from mRNA and protein time series

The rapid advance of genome sequencing projects challenges biologists to assign physiological roles to thousands of unknown gene products. We suggest here that regulatory functions and protein-protein interactions involving specific products may be inferred from the trajectories over time of their mRNA and free protein levels within the cell. The level of a protein in the cytoplasm is governed not only by the level of its mRNA and the rate of translation, but also by the protein's folding efficiency, its biochemical modification, its complexation with other components, its degradation, and its transport from the cytoplasmic space. All these co- and post translational events cause the concentration of the protein to deviate from the level that would result if we only accounted for translation of its mRNA. The dynamics of such deviations can create patterns that reflect regulatory functions. Moreover, correlations among deviations highlight protein pairs involved in potential protein-protein interactions. We explore and illustrate these ideas here using a genetically structured simulation for the intracellular growth of bacteriophage T7.

DNA binding in the central channel of bacteriophage T7 helicase-primase is a multistep process. Nucleotide hydrolysis is not required

Many helicases assemble into ring-shaped hexamers and bind DNA in their central channel. This raises the question as to how the DNA gets into the central channel to form a topologically linked complex. We have used the presteady-state stopped-flow kinetic method and protein fluorescence changes to investigate the mechanism of single-stranded DNA (ssDNA) binding to the bacteriophage T7 helicase-primase, gp4A'. We have found that the kinetics of 30-mer ssDNA binding to a preformed gp4A' hexamer in the presence of both Mg-dTMP-PCP and Mg-dTTP are similar, indicating that Mg-dTTP binding is sufficient and hydrolysis is not necessary for efficient DNA binding. Multiple transient changes in gp4A' fluorescence revealed a four-step mechanism for DNA binding with Mg-dTTP. These transient changes were analyzed by global fitting and kinetic simulation to determine the intrinsic rate constants of this four-step mechanism. The initial steps, including the bimolecular encounter of the DNA with the helicase and a subsequent conformational change, were fast. We propose that these initial steps of DNA binding occur at a readily accessible site, which is likely to be on the outside of the hexamer ring. The binding of the 30-mer ssDNA at this loading site is followed by slower conformational changes that allow the DNA to transit into the central channel of gp4A' via a ring-opening or threading pathway.

Structure of the RNA polymerase domain of E. coli primase

All cellular organisms use specialized RNA polymerases called "primases" to synthesize RNA primers for the initiation of DNA replication. The high-resolution crystal structure of a primase, comprising the catalytic core of the Escherichia coli DnaG protein, was determined. The core structure contains an active-site architecture that is unrelated to other DNA or RNA polymerase palm folds, but is instead related to the "toprim" fold. On the basis of the structure, it is likely that DnaG binds nucleic acid in a groove clustered with invariant residues and that DnaG is positioned within the replisome to accept single-stranded DNA directly from the replicative helicase.

Structure of the zinc-binding domain of Bacillus stearothermophilus DNA primase

BACKGROUND

DNA primases catalyse the synthesis of the short RNA primers that are required for DNA replication by DNA polymerases. Primases comprise three functional domains: a zinc-binding domain that is responsible for template recognition, a polymerase domain, and a domain that interacts with the replicative helicase, DnaB.

RESULTS

We present the crystal structure of the zinc-binding domain of DNA primase from Bacillus stearothermophilus, determined at 1.7 A resolution. This is the first high-resolution structural information about any DNA primase. A model is discussed for the interaction of this domain with the single-stranded DNA template.

CONCLUSIONS

The structure of the DNA primase zinc-binding domain confirms that the protein belongs to the zinc ribbon subfamily. Structural comparison with other nucleic acid binding proteins suggests that the beta sheet of primase is likely to be the DNA-binding surface, with conserved residues on this surface being involved in the binding and recognition of DNA.

Interaction of bacteriophage T7 gene 4 primase with its template recognition site

The primase fragment of the bacteriophage T7 63-kDa gene 4 helicase/primase protein contains the 271 N-terminal amino acid residues and lacks helicase activity. The primase fragment catalyzes the synthesis of oligoribonucleotides at rates similar to those catalyzed by the full-length protein in the presence of a 5-nucleotide DNA template containing a primase recognition site (5'-GGGTC-3', 5'-TGGTC-3', 5'-GTGTC-3', or 5'-TTGTC-3'). Although it is not copied into the oligoribonucleotides, the cytosine at the 3'-position is essential for synthesis and template binding. Two nucleotides flanking the 3'-end of the recognition site are required for tight DNA binding and rapid oligoribonucleotide synthesis. Nucleotides added to the 5'-end have no effect on the rate of oligoribonucleotide synthesis or the affinity of the primase for DNA. The binding of either ATP or CTP significantly increases the affinity of the primase for its DNA template. DNA lacking a primase recognition site does not inhibit oligoribonucleotide synthesis, suggesting that the primase binds DNA in a sequence-specific manner. The affinity of the primase for templates is weak, ranging from 10 to 150 microM. The tight DNA binding (<1 microM) observed with the 63-kDa gene 4 protein occurs via interactions between DNA templates and the helicase domain.

Escherichia coli primase zinc is sensitive to substrate and cofactor binding

The ligation state of the single zinc site in primase from Escherichia coli changes when various substrates and cofactors are added alone or in combination as determined by X-ray absorption spectroscopy. X-ray absorption spectroscopy (XAS) provides information about the local structure (approximately 5 A) of atoms surrounding the metal and has been widely used to characterize metalloproteins. The zinc site in native primase and in primase bound to low (30 mM) magnesium acetate was found to be tetrahedrally ligated by three sulfurs at an average distance of 2.36 +/- 0.02 A and one histidine nitrogen located at a distance of 2.15 +/- 0.03 A. When ATP, ATP and (dT)17, or ATP, low magnesium acetate and (dT)17 was added to primase, one (or two) additional nitrogen/oxygen ligands were coordinated to the zinc together with the histidine nitrogen at an average distance of 2.15 +/- 0.03 A. These additional ligands are likely from adjacent phosphates from ATP. Another structure was observed for the primase-(dT)17 complex in which an additional nitrogen/oxygen ligand likely from the phosphate backbone together with the histidine nitrogen was located at a significantly shorter average distance of 2.05 +/- 0.03 A. High magnesium acetate (300 mM) completely inactivates primase in a reversible manner such that the region near the zinc ligands becomes accessible to proteolytic digestion [Urlacher, T. M., and Griep, M. A. (1995) Biochemistry 34, 16708-16714]. In this inactive complex, additional oxygen/nitrogen ligands from acetate as well as the histidine nitrogen are located at a distance of 2.20 +/- 0.03 A from the zinc site. To test whether the catalytic magnesium was binding within approximately 5 A of the zinc, we incubated primase with high (300 mM) manganese acetate. The functional properties of magnesium and manganese are similar, but the larger atomic number of manganese enhances the X-ray backscattering, making it possible to identify. Since no significant difference was observed from the manganese-incubated sample, the catalytic metal-binding site is likely located >5 A from the zinc. These studies clearly show that primase zinc ligation changes upon binding substrates.

DnaB from Thermus aquaticus unwinds forked duplex DNA with an asymmetric tail length dependence

DnaB helicase is a ring-shaped hexamer of 300 kDa that is essential for replication of the bacterial chromosome. The dnaB gene from Thermus aquaticus was isolated and cloned, and its gene product was expressed and purified to homogeneity. A helicase assay was developed, and optimal conditions for T. aquaticus DnaB activity were determined using a forked duplex DNA substrate. The activity required a hydrolyzable nucleoside triphosphate and both 5'- and 3'-single-stranded DNA tail regions. Under conditions of single enzymatic turnover, the lengths of the 5'- and 3'-single-stranded regions were varied, and 6-10 nucleotides of the 5'-single-stranded tail and 21-30 nucleotides of the 3'-single-stranded tail markedly stimulated the unwinding rate. These data suggest that DnaB from T. aquaticus interacts with both DNA single-stranded tails during unwinding and that a greater portion of the 3'-tail is in contact with the protein. Two models are consistent with these data. In one model, the 5'-single stranded region passes through the central hole of the DnaB ring, and the 3'-tail makes extensive contact with the outside of the protein. In the other model, the 3'-single-stranded region passes through the DnaB ring, and the outside of the protein contacts the 5'-tail.

An N-terminal fragment of the gene 4 helicase/primase of bacteriophage T7 retains primase activity in the absence of helicase activity

Primase and helicase activities of bacteriophage T7 are present in a single polypeptide coded by gene 4. Because the amino terminal region of the gene 4 protein contributes to primase activity, we constructed a truncated gene 4 encoding the N-terminal 271-aa residues. The truncated protein, purified from cells overexpressing the protein, is a dimer in solution; the full-length protein is a hexamer. Although the fragment is devoid of dTTPase and helicase activities, it catalyzes template-directed synthesis of di-, tri-, and tetranucleotides. The rates for tetraribonucleotide synthesis and for dinucleotide extension on a 20-nucleotide template are similar for the full-length and truncated proteins. However, the activity of the primase fragment is unaffected by dTTP whereas the primase activity of the full-length protein is stimulated >14-fold. The primase fragment is defective in the interaction with T7 DNA polymerase in that primer synthesis cannot be coupled to DNA synthesis.