Characterization of the Helicase and Primase Activities of the 63-kDa Component of the Bacteriophage T7 Gene 4 Protein

History of DNA Helicases

Since the discovery of the DNA double helix, there has been a fascination in understanding the molecular mechanisms and cellular processes that account for: (i) the transmission of genetic information from one generation to the next and (ii) the remarkable stability of the genome. Nucleic acid biologists have endeavored to unravel the mysteries of DNA not only to understand the processes of DNA replication, repair, recombination, and transcription but to also characterize the underlying basis of genetic diseases characterized by chromosomal instability. Perhaps unexpectedly at first, DNA helicases have arisen as a key class of enzymes to study in this latter capacity. From the first discovery of ATP-dependent DNA unwinding enzymes in the mid 1970's to the burgeoning of helicase-dependent pathways found to be prevalent in all kingdoms of life, the story of scientific discovery in helicase research is rich and informative. Over four decades after their discovery, we take this opportunity to provide a history of DNA helicases. No doubt, many chapters are left to be written. Nonetheless, at this juncture we are privileged to share our perspective on the DNA helicase field - where it has been, its current state, and where it is headed.

Methods to study the coupling between replicative helicase and leading-strand DNA polymerase at the replication fork

Replicative helicases work closely with the replicative DNA polymerases to ensure that the genomic DNA is copied in a timely and error free manner. In the replisomes of prokaryotes, mitochondria, and eukaryotes, the helicase and DNA polymerase enzymes are functionally and physically coupled at the leading strand replication fork and rely on each other for optimal DNA strand separation and synthesis activities. In this review, we describe pre-steady state kinetic methods to quantify the base pair unwinding-synthesis rate constant, a fundamental parameter to understand how the helicase and polymerase help each other during leading strand replication. We describe a robust method to measure the chemical step size of the helicase-polymerase complex that determines how the two motors are energetically coupled while tracking along the DNA. The 2-aminopurine fluorescence-based method provide structural information on the leading strand helicase-polymerase complex, such as the distance between the two enzymes, their relative positions at the replication fork, and their roles in fork junction melting. The combined information garnered from these methods informs on the mutual dependencies between the helicase and DNA polymerase enzymes, their stepping mechanism, and their individual functions at the replication fork during leading strand replication.

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.

Alternative molecular tests for virological diagnosis

Several nucleic acid amplification techniques (NAATs), particularly PCR and real-time PCR, are currently used in the routine clinical laboratories. Such approaches have allowed rapid diagnosis with a high degree of sensitivity and specificity. However, conventional PCR methods have several intrinsic disadvantages such as the requirement for temperature cycling apparatus, and sophisticated and costly analytical equipments. Therefore, amplification at a constant temperature is an attractive alternative method to avoid these requirements. A new generation of isothermal amplification techniques are gaining a wide popularity as diagnostic tools due to their simple operation, rapid reaction and easy detection. The main isothermal methods reviewed here include loop-mediated isothermal amplification, nucleic acid sequence-based amplification, and helicase-dependent amplification. In this review, design criteria, potential of amplification, and application of these alternative molecular tests will be discussed and compared to conventional NAATs.

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.

Heterohexamer of 56- and 63-kDa Gene 4 Helicase-Primase of Bacteriophage T7 in DNA Replication

Bacteriophage T7 expresses two forms of gene 4 protein (gp4). The 63-kDa full-length gp4 contains both the helicase and primase domains. T7 phage also express a 56-kDa truncated gp4 lacking the zinc binding domain of the primase; the protein has helicase activity but no DNA-dependent primase activity. Although T7 phage grow better when both forms are present, the role of the 56-kDa gp4 is unknown. The two molecular weight forms oligomerize by virtue of the helicase domain to form heterohexamers. The 56-kDa gp4 and any mixture of 56- and 63-kDa gp4 show higher helicase activity in DNA unwinding and strand-displacement DNA synthesis than that observed for the 63-kDa gp4. However, single-molecule measurements show that heterohexamers have helicase activity similar to the 63-kDa gp4 hexamers. In oligomerization assays the 56-kDa gp4 and any mixture of the 56- and 63-kDa gp4 oligomerize to form more hexamers than does the 63-kDa gp4. The zinc binding domain of the 63-kDa gp4 interferes with hexamer formation, an inhibition that is relieved by the insertion of the 56-kDa species. Compared with the 63-kDa gp4, heterohexamers synthesize a reduced amount of oligoribonucleotides, mediated predominately by the 63-kDa subunits via a cis mode. During coordinated DNA synthesis 7% of the tetraribonucleotides synthesized are used as primers by both heterohexamers and hexamers of the 63-kDa gp4. Overall, an equimolar mixture of the two forms of gp4 shows the highest rate of DNA synthesis during coordinated DNA synthesis.

Bypass of a nick by the replisome of bacteriophage T7

DNA polymerase and DNA helicase are essential components of DNA replication. The helicase unwinds duplex DNA to provide single-stranded templates for DNA synthesis by the DNA polymerase. In bacteriophage T7, movement of either the DNA helicase or the DNA polymerase alone terminates upon encountering a nick in duplex DNA. Using a minicircular DNA, we show that the helicase · polymerase complex can bypass a nick, albeit at reduced efficiency of 7%, on the non-template strand to continue rolling circle DNA synthesis. A gap in the non-template strand cannot be bypassed. The efficiency of bypass synthesis depends on the DNA sequence downstream of the nick. A nick on the template strand cannot be bypassed. Addition of T7 single-stranded DNA-binding protein to the complex stimulates nick bypass 2-fold. We propose that the association of helicase with the polymerase prevents dissociation of the helicase upon encountering a nick, allowing the helicase to continue unwinding of the duplex downstream of the nick.

A257T linker region mutant of T7 helicase-primase protein is defective in DNA loading and rescued by T7 DNA polymerase

The helicase and primase activities of the hexameric ring-shaped T7 gp4 protein reside in two separate domains connected by a linker region. This linker region is part of the subunit interface between monomers, and point mutations in this region have deleterious effects on the helicase functions. One such linker region mutant, A257T, is analogous to the A359T mutant of the homologous human mitochondrial DNA helicase Twinkle, which is linked to diseases such as progressive external opthalmoplegia. Electron microscopy studies show that A257T gp4 is normal in forming rings with dTTP, but the rings do not assemble efficiently on the DNA. Therefore, A257T, unlike the WT gp4, does not preassemble on the unwinding DNA substrate with dTTP without Mg(II), and its DNA unwinding activity in ensemble assays is slow and limited by the DNA loading rate. Single molecule assays measured a 45 times slower rate of A257T loading on DNA compared with WT gp4. Interestingly, once loaded, A257T has almost WT-like translocation and DNA unwinding activities. Strikingly, A257T preassembles stably on the DNA in the presence of T7 DNA polymerase, which restores the ensemble unwinding activity of A257T to ∼75% of WT, and the rescue does not require DNA synthesis. The DNA loading rate of A257T, however, remains slow even in the presence of the polymerase, which explains why A257T does not support T7 phage growth. Similar types of defects in the related human mitochondrial DNA helicase may be responsible for inefficient DNA replication leading to the disease states.

Direct role for the RNA polymerase domain of T7 primase in primer delivery

Gene 4 protein (gp4) encoded by bacteriophage T7 contains a C-terminal helicase and an N-terminal primase domain. After synthesis of tetraribonucleotides, gp4 must transfer them to the polymerase for use as primers to initiate DNA synthesis. In vivo gp4 exists in two molecular weight forms, a 56-kDa form and the full-length 63-kDa form. The 56-kDa gp4 lacks the N-terminal Cys(4) zinc-binding motif important in the recognition of primase sites in DNA. The 56-kDa gp4 is defective in primer synthesis but delivers a wider range of primers to initiate DNA synthesis compared to the 63-kDa gp4. Suppressors exist that enable the 56-kDa gp4 to support the growth of T7 phage lacking gene 4 (T7Delta4). We have identified 56-kDa DNA primases defective in primer delivery by screening for their ability to support growth of T7Delta4 phage in the presence of this suppressor. Trp69 is critical for primer delivery. Replacement of Trp69 with lysine in either the 56- or 63-kDa gp4 results in defective primer delivery with other functions unaffected. DNA primase harboring lysine at position 69 fails to stabilize the primer on DNA. Thus, a primase subdomain not directly involved in primer synthesis is involved in primer delivery. The stabilization of the primer by DNA primase is necessary for DNA polymerase to initiate synthesis.

Isothermal DNA amplification in vitro: the helicase-dependent amplification system

Since the development of polymerase chain reaction, amplification of nucleic acids has emerged as an elemental tool for molecular biology, genomics, and biotechnology. Amplification methods often use temperature cycling to exponentially amplify nucleic acids; however, isothermal amplification methods have also been developed, which do not require heating the double-stranded nucleic acid to dissociate the synthesized products from templates. Among the several methods used for isothermal DNA amplification, the helicase-dependent amplification (HDA) is discussed in this review with an emphasis on the reconstituted DNA replication system. Since DNA helicase can unwind the double-stranded DNA without the need for heating, the HDA system provides a very useful tool to amplify DNA in vitro under isothermal conditions with a simplified reaction scheme. This review describes components and detailed aspects of current HDA systems using Escherichia coli UvrD helicase and T7 bacteriophage gp4 helicase with consideration of the processivity and efficiency of DNA amplification.

Structure-function defects of the twinkle amino-terminal region in progressive external ophthalmoplegia

TWINKLE is a DNA helicase needed for mitochondrial DNA replication. In lower eukaryotes the protein also harbors a primase activity, which is lost from TWINKLE encoded by mammalian cells. Mutations in TWINKLE underlie autosomal dominant progressive external ophthalmoplegia (adPEO), a disorder associated with multiple deletions in the mtDNA. Four different adPEO-causing mutations (W315L, K319T, R334Q, and P335L) are located in the N-terminal domain of TWINKLE. The mutations cause a dramatic decrease in ATPase activity, which is partially overcome in the presence of single-stranded DNA. The mutated proteins have defects in DNA helicase activity and cannot support normal levels of DNA replication. To explain the phenotypes, we use a molecular model of TWINKLE based on sequence similarities with the phage T7 gene 4 protein. The four adPEO-causing mutations are located in a region required to bind single-stranded DNA. These mutations may therefore impair an essential element of the catalytic cycle in hexameric helicases, i.e. the interplay between single-stranded DNA binding and ATP hydrolysis.

Mechanisms of a ring shaped helicase

Bacteriophage T7 helicase (T7 gene 4 helicase-primase) is a prototypical member of the ring-shaped family of helicases, whose structure and biochemical mechanisms have been studied in detail. T7 helicase assembles into a homohexameric ring that binds single-stranded DNA in its central channel. Using RecA-type nucleotide binding and sensing motifs, T7 helicase binds and hydrolyzes several NTPs, among which dTTP supports optimal protein assembly, DNA binding and unwinding activities. During translocation along single stranded DNA, the subunits of the ring go through dTTP hydrolysis cycles one at a time, and this probably occurs also during DNA unwinding. Interestingly, the unwinding speed of T7 helicase is an order of magnitude slower than its translocation rate along single stranded DNA. The slow unwinding rate is greatly stimulated when DNA synthesis by T7 DNA polymerase is coupled to DNA unwinding. Using the T7 helicase as an example, we highlight critical findings and discuss possible mechanisms of helicase action.

Acidic residues in the nucleotide-binding site of the bacteriophage T7 DNA primase

DNA primases catalyze the synthesis of oligoribonucleotides to initiate lagging strand DNA synthesis during DNA replication. Like other prokaryotic homologs, the primase domain of the gene 4 helicase-primase of bacteriophage T7 contains a zinc motif and a catalytic core. Upon recognition of the sequence, 5'-GTC-3' by the zinc motif, the catalytic site condenses the cognate nucleotides to produce a primer. The TOPRIM domain in the catalytic site contains several charged residues presumably involved in catalysis. Each of eight acidic residues in this region was replaced with alanine, and the properties of the altered primases were examined. Six of the eight residues (Glu-157, Glu-159, Asp-161, Asp-207, Asp-209, and Asp-237) are essential in that altered gene 4 proteins containing these mutations cannot complement T7 phage lacking gene 4 for T7 growth. These six altered gene 4 proteins can neither synthesize primers de novo nor extend an oligoribonucleotide. Despite the inability to catalyze phosphodiester bond formation, the altered proteins recognize the sequence 5'-GTC-3' in the template and deliver preformed primer to T7 DNA polymerase. The alterations in the TOPRIM domain result in the loss of binding affinity for ATP as measured by surface plasmon resonance assay together with ATP-agarose affinity chromatography.

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.

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.

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.

A unique loop in the DNA-binding crevice of bacteriophage T7 DNA polymerase influences primer utilization

The three-dimensional structure of bacteriophage T7 DNA polymerase reveals the presence of a loop of 4 aa (residues 401-404) within the DNA-binding groove; this loop is not present in other members of the DNA polymerase I family. A genetically altered T7 DNA polymerase, T7 polDelta401-404, lacking these residues, has been characterized biochemically. The polymerase activity of T7 polDelta401-404 on primed M13 single-stranded DNA template is one-third of the wild-type enzyme and has a 3'-to-5' exonuclease activity indistinguishable from that of wild-type T7 DNA polymerase. T7 polDelta401-404 polymerizes nucleotides processively on a primed M13 single-stranded DNA template. T7 DNA polymerase cannot initiate de novo DNA synthesis; it requires tetraribonucleotides synthesized by the primase activity of the T7 gene 4 protein to serve as primers. T7 primase-dependent DNA synthesis on single-stranded DNA is 3- to 6-fold less with T7 polDelta401-404 compared with the wild-type enzyme. Furthermore, the altered polymerase is defective (10-fold) in its ability to use preformed tetraribonucleotides to initiate DNA synthesis in the presence of gene 4 protein. The location of the loop places it in precisely the position to interact with the tetraribonucleotide primer and, presumably, with the T7 gene 4 primase. Gene 4 protein also provides helicase activity for the replication of duplex DNA. T7 polDelta401-404 and T7 gene 4 protein catalyze strand-displacement DNA synthesis at nearly the same rate as does wild-type polymerase and T7 gene 4 protein, suggesting that the coupling of helicase and polymerase activities is unaffected.

DNA replication at high resolution

Several decades of research have delineated the roles of many proteins central to DNA replication. Here we present a structural perspective of this work spanning the past 15 years and highlight several recent advances in the field.

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.

Interaction of ribonucleoside triphosphates with the gene 4 primase of bacteriophage T7

The primase fragment of bacteriophage T7 gene 4 protein catalyzes the synthesis of oligoribonucleotides in the presence of ATP, CTP, Mg(2+) (or Mn(2+)), and DNA containing a primase recognition site. During chain initiation, ATP binds with a K(m) of 0.32 mM, and CTP binds with a K(m) of 0.85 mM. Synthesis of the dinucleotides proceeds at a rate of 3.8/s. The dinucleotide either dissociates or is extended to a tetranucleotide. The primase preferentially inserts ribonucleotides forming Watson-Crick base pairs with the DNA template >200-fold more rapidly than other ribo- or deoxynucleotides. 3'-dCTP binds the primase with a similar affinity as CTP and is incorporated as a chain terminator at a rate (1)/(100) that of CTP. ATP analogues alpha,beta-methylene ATP, beta,gamma-methylene ATP, and beta,gamma-imido ATP are incorporated by the primase fragment at the 5'-ends of the oligoribonucleotides but not at the 3'-ends. A model is presented in which the primase fragment utilizes two nucleotide-binding sites, one for the initiating ATP and one for the nucleoside triphosphate which elongates the primer on the 3'-end. The initiation site binds ATP or oligoribonucleotides, whereas the elongation site binds ATP or CTP as directed by the template.

The linker region between the helicase and primase domains of the bacteriophage T7 gene 4 protein is critical for hexamer formation

The gene 4 protein of bacteriophage T7, a functional hexamer, comprises DNA helicase and primase activities. Both activities depend on the unidirectional movement of the protein along single-stranded DNA in a reaction coupled to the hydrolysis of dTTP. We have characterized dTTPase activity and hexamer formation for the full-length gene 4 protein (gp4) as well as for three carboxyl-terminal fragments starting at residues 219 (gp4-C219), 241 (gp4-C241), and 272 (gp4-C272). The region between residues 242 and 271, residing between the primase and helicase domains, is critical for oligomerization of the gene 4 protein. A functional TPase active site is dependent on oligomerization. During native gel electrophoresis, gp4, gp4-C219, and gp4-C241 migrate as oligomers, whereas gp4-C272 is monomeric. The steady-state k(cat) for dTTPase activity of gp4-C272 increases sharply with protein concentration, indicating that it forms oligomers only at high concentrations. gp4-C219 and gp4-C241 both form a stable complex with gp4, whereas gp4-C272 interacts only weakly with gp4. Measurements of surface plasmon resonance indicate that a monomer of T7 DNA polymerase binds to a dimer of gp4, gp4-C219, or gp4-C241 but to a monomer of gp4-C272. Like the homologous RecA and F(1)-ATPase proteins, the oligomerization domain of the gene 4 protein is adjacent to the amino terminus of the NTP-binding domain.

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.

Formation of a DNA loop at the replication fork generated by bacteriophage T7 replication proteins

Intermediates in the replication of circular and linear M13 double-stranded DNA by bacteriophage T7 proteins have been examined by electron microscopy. Synthesis generated double-stranded DNA molecules containing a single replication fork with a linear duplex tail. A complex presumably consisting of T7 DNA polymerase and gene 4 helicase/primase molecules was present at the fork together with a variable amount of single-stranded DNA sequestered by gene 2.5 single-stranded DNA binding protein. Analysis of the length distribution of Okazaki fragments formed at different helicase/primase concentrations was consistent with coupling of leading and lagging strand replication. Fifteen to forty percent of the templates engaged in replication have a DNA loop at the replication fork. The loops are fully double-stranded with an average length of approximately 1 kilobase. Labeling with biotinylated dCTP showed that the loops consist of newly synthesized DNA, and synchronization experiments using a linear template with a G-less cassette demonstrated that the loops are formed by active displacement of the lagging strand. A long standing feature of models for coupled leading/lagging strand replication has been the presence of a DNA loop at the replication fork. This study provides the first direct demonstration of such loops.

Asymmetric interactions of hexameric bacteriophage T7 DNA helicase with the 5'- and 3'-tails of the forked DNA substrate

Bacteriophage T7 DNA helicase requires two noncomplementary single-stranded DNA (ssDNA) tails next to a double-stranded DNA (dsDNA) region to initiate DNA unwinding. The interactions of the helicase with the DNA were investigated using a series of forked DNAs. Our results show that the helicase interacts asymmetrically with the two tails of the forked DNA. When the helicase was preassembled on the forked DNA before the start of unwinding, a DNA with 15-nucleotide (nt) 3'-tail and 35-nt 5'-tail was unwound with optimal rates close to 60 base pairs/s at 18 degrees C. When the helicase was not preassembled on the DNA, a >65-nt long 5'-tail was required for maximal unwinding rates of 12 base pairs/s. We show that the helicase interacts specifically with the ssDNA region and maintains contact with both ssDNA strands during DNA unwinding, since conversion of the two ssDNA tails to dsDNA structures greatly inhibited unwinding, and the helicase was unable to unwind past a nick in the dsDNA region. These studies have provided new insights into the mechanism of DNA unwinding. We propose an exclusion model of DNA unwinding in which T7 helicase hexamer interacts mainly with the ssDNA strands during DNA unwinding, encircling the 5'-strand and excluding the 3'-strand from the hole.

The acidic carboxyl terminus of the bacteriophage T7 gene 4 helicase/primase interacts with T7 DNA polymerase

The gene 4 proteins of bacteriophage T7 provide both primase and helicase activities at the replication fork. Efficient DNA replication requires that the functions of the gene 4 protein be coordinated with the movement of the T7 DNA polymerase. We show that a carboxyl-terminal domain of the gene 4 protein is required for interaction with T7 DNA polymerase during leading strand DNA synthesis. The carboxyl terminus of the gene 4 protein is highly acidic: of the 17 carboxyl-terminal amino acids 7 are negatively charged. Deletion of the coding region for these 17 residues results in a gene 4 protein that cannot support the growth of T7 phage. The purified mutant gene 4 protein has wild-type levels of both helicase and primase activities; however, DNA synthesis catalyzed by T7 DNA polymerase on a duplex DNA substrate is stimulated by this mutant protein to only about 5% of the level of synthesis obtained with wild-type protein. The mutant gene 4 protein can form hexamers and bind single-stranded DNA, but as determined by native PAGE analysis, the protein cannot form a stable complex with the DNA polymerase. The mutant gene 4 protein can prime DNA synthesis normally, indicating that for lagging strand synthesis a different set of helicase/primase-DNA polymerase interactions are involved. These findings have implications for the mechanisms coupling leading and lagging strand DNA synthesis at the T7 replication fork.

Biochemical analysis of mutant T7 primase/helicase proteins defective in DNA binding, nucleotide hydrolysis, and the coupling of hydrolysis with DNA unwinding

We characterized nine helicase-deficient mutants of bacteriophage T7 helicase-primase protein (4A') prepared by random mutagenesis as reported in the accompanying paper (Rosenberg, A. H., Griffin, K., Washington, M. T., Patel, S. S., and Studier, F. W. (1996) J. Biol. Chem. 271, 26819-26824). Mutants were selected from each of the helicase-conserved motifs for detailed analysis to understand better their function. In agreement with the in vivo results, the mutants were defective in helicase activity but were active in primase function. dTTP hydrolysis, DNA binding, and hexamer formation were examined. Three classes of defective mutants were observed. Group A mutants (E348K, D424N, and S496F), defective in dTTP hydrolysis, lie in motifs 1a, 2, and 4 and are possibly involved in NTP binding/hydrolysis. Group B mutants (R487C and G488D), defective in DNA binding, lie in motif 4 and are responsible directly or indirectly for DNA binding. Group C mutants (G116D, A257T, S345F, and G451E) were not defective in any of the activities except the helicase function. These mutants, scattered throughout the protein, appear defective in coupling dTTPase activity to helicase function. Secondary structural predictions of 4A' and DnaB helicases resemble the known structures of RecA and F1-ATPase enzymes. Alignment shows a striking correlation in the positions of the amino acids that interact with NTP and DNA.

Coupling of a replicative polymerase and helicase: a tau-DnaB interaction mediates rapid replication fork movement

The E. coli replication fork synthesizes DNA at the rate of nearly 1000 nt/s. We show here that an interaction between the tau subunit of the replicative polymerase (the DNA polymerase III holoenzyme) and the replication fork DNA helicase (DnaB) is required to mediate this high rate of replication fork movement. In the absence of this interaction, the polymerase follows behind the helicase at a rate equal to the slow (approximately 35 nt/s) unwinding rate of the helicase alone, whereas upon establishing a tau-DnaB contact, DnaB becomes a more effective helicase, increasing its translocation rate by more than 10-fold. This finding establishes the existence of both a physical and communications link between the two major replication machines in the replisome: the DNA polymerase and the primosome.

Mechanisms of DNA expansion

Unstable transmission of repeating segments in genes is now recognized as a new class of mutations causing human disease. Genetic instability observed in disease is termed an "expansion mutation" when the mutation is an increase in the copy number of a repeated unit, commonly a di- or trinucleotide. While the expansion mutation is well characterized in disease, the mechanism by which expansion occurs is not clear. This article focuses on physical properties of expansion at repeating nucleotides that may provide clues to the mechanism. Both biochemical and genetic data indicate that DNA structure is part of the mechanism and the underlying cause for expansion.

A domain of the gene 4 helicase/primase of bacteriophage T7 required for the formation of an active hexamer

The bacteriophage T7 gene 4 protein, like a number of helicases, is believed to function as a hexamer. The amino acid sequence of the T7 gene 4 protein from residue 475 to 491 is conserved in the homologous proteins of the related phages T3 and SP6. In addition, part of this region is conserved in DNA helicases such as Escherichia coli DnaB protein and phage T4 gp41. Mutations within this region of the T7 gene 4 protein can reduce the ability of the protein to form hexamers. The His475-->Ala and Asp485-->Gly mutant proteins show decreases in nucleotide hydrolysis, single-stranded DNA binding, double-stranded DNA unwinding, and primer synthesis in proportion to their ability to form hexamers. The mutation Arg487-->Ala has little effect on oligomerization, but nucleotide hydrolysis by this mutant protein is inhibited by single-stranded DNA, and it has a higher affinity for dTTP, suggesting that this protein is defective in the protein-protein interactions required for efficient nucleotide hydrolysis and translocation on single-stranded DNA. Gene 4 protein can form hexamers in the absence of a nucleotide, but dTTP increases hexamer formation, as does dTDP, to a lesser extent, demonstrating that the protein self-association affinity is influenced by the nucleotide bound. Together, the data demonstrate that this region of the gene 4 protein is important for the protein-protein contacts necessary for both hexamer formation and the interactions between the subunits of the hexamer required for coordinated nucleotide hydrolysis, translocation on single-stranded DNA, and unwinding of double-stranded DNA. The fact that the gene 4 proteins form dimers, but not monomers, even while hexamer formation is severely diminished by some of the mutations, suggests that the proteins associate in a manner with two separate and distinct protein-protein interfaces.

Evolutionary role of abortive transcript as a primer for DNA replication

Abortive cycling features transcription initiation by RNA polymerase in both prokaryote and eukaryote. It is known that T7 RNA polymerase produces abortive transcripts up to eight ribonucleotides in length depending on the initial sequence of the DNA message. On the other hand, T7 RNA polymerase initiates DNA replication from the T7 primary origin by synthesizing primers. And the shortest primer from the phi l.lB promoter in the primary origin also seems to be eight ribonucleotides in length. Therefore, it is likely that the longest abortive transcript serves as the shortest primer for T7 DNA replication from the primary origin. Considering that promoters often exist in DNA replication origins for example, E. coli oriC and many eukaryotic origins, the early DNA replication system appears to have taken advantage of the abortive cycling of RNA-dependent RNA polymerase that already existed before the emergence of DNA world. The evolutionary primitive RNA polymerase could do both transcription and priming of DNA replication. Accordingly, abortive cycling would play an important role in evolution at the emergence of DNA world. The priming activity of the primitive RNA polymerase would be taken over by primase later, which seems to be a specialized RNA polymerase for abortive cycling.

Coordination of leading and lagging strand DNA synthesis at the replication fork of bacteriophage T7

We have used the T7 DNA replication system to examine coordination of leading and lagging strand synthesis at a replication fork. The 63 kd gene 4 protein provides both helicase and primase activities; we demonstrate that primer synthesis inhibits helicase activity on a synthetic replication fork. Lagging strand DNA synthesis by a complex of gene 4 protein and T7 DNA polymerase decreases the rate of leading strand synthesis. Both leading and lagging strand synthesis are resistant to dilution of the replication proteins, and to challenge with heparin. Furthermore, dilution does not increase the average length of Okazaki fragments. We propose that leading and lagging strand synthesis at a T7 replication fork are coupled and that the replication proteins are recycled.

Interactions of bacteriophage T7 DNA primase/helicase protein with single-stranded and double-stranded DNAs

Protein-DNA interactions of bacteriophage T7 DNA primase/helicase protein 4A' with small synthetic oligodeoxynucleotides were investigated using a 20-base-paired hairpin duplex, and 10-, 30-, and 60-base-long single-stranded DNA. The effect of nucleotide cofactors on DNA binding was examined using membrane binding assays which showed that 4A' binds DNA optimally only in the presence of MgdTMP-PCP, the nonhydrolyzable analog of dTTP. About 20% of single-stranded DNA binding was observed in the presence of MgdTDP, but none was detectable in the absence of nucleotides. Native polyacrylamide gel electrophoresis showed that the DNAs bind predominantly to the hexameric form of 4A'. Larger oligomers of 4A' can bind DNA, but no DNA binding was observed to species smaller than the hexamer. Quantitative equilibrium binding studies at increasing 4A' concentrations and at increasing DNA concentrations showed tight binding of one 10-mer or 30-mer per hexamer. The 4A' hexamer can bind a second strand of DNA, but with a 50-fold weaker affinity than the first strand. The 60-mer showed tight binding to two 4A' hexamers, suggesting that a hexamer may interact with only 30-40 bases of single-stranded DNA. This was corroborated by nuclease protection experiments where the smallest length of DNA protected by 4A' or 4B protein was found to be about 30 bases. Equilibrium binding studies and competitive DNA binding data are consistent with a weaker affinity of 4A' for the duplex DNA. Only 20-25% of duplex DNA binding was observed at increasing 4A' protein in the presence of MgdTMP-PCP. About four duplex DNAs can bind each 4A' hexamer at increasing DNA concentrations, but their weaker binding was evident from their facile dissociation from 4A' in the presence of competing single-stranded DNA.

Organization and evolution of bacterial and bacteriophage primase-helicase systems

Amino acid sequences of primases and associated helicases involved in the DNA replication of eubacteria and bacteriophages T7, T3, T4, P4, and P22 were compared by computer-assisted methods. There are two types of such systems, the first one represented by distinct helicase and primase proteins (e.g., DnaB and DnaG proteins of Escherichia coli), and the second one by single polypeptides comprising both activities (gp4 of bacteriophages T7 and T3, and alpha protein of bacteriophage P4). Pronounced sequence similarity was revealed between approximately 250 amino acid residue N-terminal domains of stand-alone primases and the primase-helicase proteins of T7(T3) and P4. All these domains contain, close to their N-termini, a conserved Zn-finger pattern that may be implicated in template DNA recognition by the primases. In addition, they encompass five other conserved motifs some of which may be involved in substrate (NTP) binding. Significant similarity was also observed between the primase-associated helicases (DnaB, gp12 and P22 and gp41 of T4) and the C-terminal domain of T7(T3) gp4. On the other hand the C-terminal domain of P-alpha of P4 is related to another group of DNA and RNA helicases. Tentative phylogenetic trees generated for the primases and the associated helicases showed no grouping of the phage proteins, with the exception of the primase domains of bacteriophages T4 and P4. This may indicate a common origin for one-component primase-helicase systems. Two scenarios for the evolution of primase-helicase systems are discussed.(ABSTRACT TRUNCATED AT 250 WORDS)

Escherichia coli DNA helicases: mechanisms of DNA unwinding

DNA helicases are ubiquitous enzymes that catalyse the unwinding of duplex DNA during replication, recombination and repair. These enzymes have been studied extensively; however, the specific details of how any helicase unwinds duplex DNA are unknown. Although it is clear that not all helicases unwind duplex DNA in an identical way, many helicases possess similar properties, which are thus likely to be of general importance to their mechanism of action. For example, since helicases appear generally to be oligomeric enzymes, the hypothesis is presented in this review that the functionally active forms of DNA helicases are oligomeric. The oligomeric nature of helicases provides them with multiple DNA-binding sites, allowing the transient formation of ternary structures, such that at an unwinding fork, the helicase can bind either single-stranded and duplex DNA simultaneously or two strands of single-stranded DNA. Modulation of the relative affinities of these binding sites for single-stranded versus duplex DNA through ATP binding and hydrolysis would then provide the basis for a cycling mechanism for processive unwinding of DNA by helicases. The properties of the Escherichia coli DNA helicases are reviewed and possible mechanisms by which helicases might unwind duplex DNA are discussed in view of their oligomeric structures, with emphasis on the E. coli Rep, RecBCD and phage T7 gene 4 helicases.