Dynamics of loading the Escherichia coli DNA polymerase processivity clamp

Sliding clamps and clamp loaders are processivity factors required for efficient DNA replication. Sliding clamps are ring-shaped complexes that tether DNA polymerases to DNA to increase the processivity of synthesis. Clamp loaders assemble these ring-shaped clamps onto DNA in an ATP-dependent reaction. The overall process of clamp loading is dynamic in that protein-protein and protein-DNA interactions must actively change in a coordinated fashion to complete the mechanical clamp-loading reaction cycle. The clamp loader must initially have a high affinity for both the clamp and DNA to bring these macromolecules together, but then must release the clamp on DNA for synthesis to begin. Evidence is presented for a mechanism in which the clamp-loading reaction comprises a series of binding reactions to ATP, the clamp, DNA, and ADP, each of which promotes some change in the conformation of the clamp loader that alters interactions with the next component of the pathway. These changes in interactions must be rapid enough to allow the clamp loader to keep pace with replication fork movement. This review focuses on the measurement of dynamic and transient interactions required to assemble the Escherichia coli sliding clamp on DNA.     

Crystal structure of the DNA polymerase processivity factor of T4 bacteriophage

The protein encoded by gene 45 of T4 bacteriophage (gene 45 protein or gp45), is responsible for tethering the catalytic subunit of T4 DNA Polymerase to DNA during high-speed replication. Also referred to as a sliding DNA clamp, gp45 is similar in its function to the processivity factors of bacterial and eukaryotic DNA polymerases, the beta-clamp and PCNA, respectively. Crystallographic analysis has shown that the beta-clamp and PCNA form highly symmetrical ring-shaped structures through which duplex DNA can be threaded. Gp45 shares no sequence similarity with beta-clamp or PCNA, and sequence comparisons have not been able to establish whether it adopts a similar structure. We have determined the crystal structure of gp45 from T4 bacteriophage at 2.4 A resolution, using multiple isomorphous replacement. The protein forms a trimeric ring-shaped assembly with overall dimensions that are similar to those of the bacterial and eukaryotic processivity factors. Each monomer of gp45 contains two domains that are very similar in chain fold to those of beta-clamp and PCNA. Despite an overall negative charge, the inner surface of the ring is in a region of positive electrostatic potential, consistent with a mechanism in which DNA is threaded through the ring.     

Evaluating the effects of enhanced processivity and metal ions on translesion DNA replication catalyzed by the bacteriophage T4 DNA polymerase

The fidelity of DNA replication is achieved in a multiplicative process encompassing nucleobase selection and insertion, removal of misinserted nucleotides by exonuclease activity, and enzyme dissociation from primer/templates that are misaligned due to mispairing. In this study, we have evaluated the effect of altering these kinetic processes on the dynamics of translesion DNA replication using the bacteriophage T4 replication apparatus as a model system. The effect of enhancing the processivity of the T4 DNA polymerase, gp43, on translesion DNA replication was evaluated using a defined in vitro assay system. While the T4 replicase (gp43 in complex with gp45) can perform efficient, processive replication using unmodified DNA, the T4 replicase cannot extend beyond an abasic site. This indicates that enhancing the processivity of gp43 does not increase unambiguously its ability to perform translesion DNA replication. Surprisingly, the replicase composed of an exonuclease-deficient mutant of gp43 was unable to extend beyond the abasic DNA lesion, thus indicating that molecular processes involved in DNA polymerization activity play the predominant role in preventing extension beyond the non-coding DNA lesion. Although neither T4 replicase complex could extend beyond the lesion, there were measurable differences in the stability of each complex at the DNA lesion. Specifically, the exonuclease-deficient replicase dissociates at a rate constant, k(off), of 1.1s(-1) while the wild-type replicase remains more stably associated at the site of DNA damage by virtue of a slower measured rate constant (k(off) 0.009s(-1)). The increased lifetime of the wild-type replicase suggests that idle turnover, the partitioning of the replicase from its polymerase to its exonuclease active site, may play an important role in maintaining fidelity. Further attempts to perturb the fidelity of the T4 replicase by substituting Mn(2+) for Mg(2+) did not significantly enhance DNA synthesis beyond the abasic DNA lesion. The results of these studies are interpreted with respect to current structural information of gp43 alone and complexed with gp45.     

Dual functions of single-stranded DNA-binding protein in helicase loading at the bacteriophage T4 DNA replication fork

Semi-conservative DNA synthesis reactions catalyzed by the bacteriophage T4 DNA polymerase holoenzyme are initiated by a strand displacement mechanism requiring gp32, the T4 single-stranded DNA (ssDNA)-binding protein, to sequester the displaced strand. After initiation, DNA helicase acquisition by the nascent replication fork leads to a dramatic increase in the rate and processivity of leading strand DNA synthesis. In vitro studies have established that either of two T4-encoded DNA helicases, gp41 or dda, is capable of stimulating strand displacement synthesis. The acquisition of either helicase by the nascent replication fork is modulated by other protein components of the fork including gp32 and, in the case of the gp41 helicase, its mediator/loading protein gp59. Here, we examine the relationships between gp32 and the gp41/gp59 and dda helicase systems, respectively, during T4 replication using altered forms of gp32 defective in either protein-protein or protein-ssDNA interactions. We show that optimal stimulation of DNA synthesis by gp41/gp59 helicase requires gp32-gp59 interactions and is strongly dependent on the stability of ssDNA binding by gp32. Fluorescence assays demonstrate that gp59 binds stoichiometrically to forked DNA molecules; however, gp59-forked DNA complexes are destabilized via protein-protein interactions with the C-terminal "A-domain" fragment of gp32. These and previously published results suggest a model in which a mobile gp59-gp32 cluster bound to lagging strand ssDNA is the target for gp41 helicase assembly. In contrast, stimulation of DNA synthesis by dda helicase requires direct gp32-dda protein-protein interactions and is relatively unaffected by mutations in gp32 that destabilize its ssDNA binding activity. The latter data support a model in which protein-protein interactions with gp32 maintain dda in a proper active state for translocation at the replication fork. The relationship between dda and gp32 proteins in T4 replication appears similar to the relationship observed between the UL9 helicase and ICP8 ssDNA-binding protein in herpesvirus replication.     

RNA priming of DNA replication by bacteriophage T4 proteins

Bacteriophage T4 DNA replication proteins have been shown previously to require ribonucleoside triphosphates to initiator new DNA chains on unprimed single-stranded DNA templates in vitro. This DNA synthesis requires a protein controlled by T4 gene 61, as well as the T4 gene 41, 43 (DNA polymerase), 44, 45, and 62 proteins, and is stimulated by the gene 32 (helix-destabilizing) protein. In this paper, the nature of the RNA primers involved in DNA synthesis by the T4 proteins has been determined, using phi X174 and f1 DNA as model templates. The T4 41 and "61" proteins synthesize pentanucleotides with the sequence pppA-C(N)3 where N in positions 3 and 4 can be G, U, C, or A. The same group of sequences is found in the RNA at the 5' terminus of the phi X174 DNA product made by the seven T4 proteins. The DNA product chains begin at multiple discrete positions on the phi X174 DNA template. The characteristics of the T4 41 and "61" protein priming reaction are thus appropriate for a reaction required to initiate the synthesis of discontinuous "Okazaki" pieces on the lagging strand during the replication of duplex DNA.     

DNA replication and head assembly in bacteriophage T4.

Phage DNA was accumulated in cells of E. coli B, infected with the phage T4DtsLB3 (gene 42), without the synthesis of late proteins (in the presence of chloramphenicol). Then (stage II), chloramphenicol was removed and further replication of the phage DNA suppressed with hydroxyurea and by simultaneously raising the temperature to 40 degrees. The media M9 or M9 with 1% amino acid were used; the times of addition of chloramphenicol and the hydroxyurea concentration were also varied. It was also shown that in medium M9, at stage II, chiefly early proteins were synthesized. In the medium containing amino acids, at stage II the following was observed: 1) DNA synthesis was entirely suppressed and a degradation of DNA occurred; 2) both early and late proteins were synthesized, with a predominance of the latter; 3) an assembly of the elements of the phage tails and capsids occurred without the neck and flagellum, and a small number of phage particles were also found; 4) the capsids, isolated in a sucrose density gradient after lysis with chloroform, contained the proteins Palt, P20, P23, P24, several unidentified proteins, and did not contain Pwac, P23, and P22, 5) the yield of viable phage varied from 0.05 to 15% per cell. Thus, the entire morphogenesis of T4 phage can occur without accompanying replication of phage DNA.     

DNA helicase requirements for DNA replication during bacteriophage T4 infection.

The lytic bacteriophage T4 uses multiple mechanisms to initiate the replication of its DNA. Initiation occurs predominantly at replication origins at early times of infection, but there is a switch to genetic recombination-dependent initiation at late times of infection. The T4 insertion-substitution system was used to create a deletion in the T4 dda gene, which encodes a 5'-3' DNA helicase that stimulates both DNA replication and recombination reactions in vitro. The deletion caused a delay in T4 DNA synthesis at early times of infection, suggesting that the Dda protein is involved in the initiation of origin-dependent DNA synthesis. However, DNA synthesis eventually reached nearly wild-type levels, and the final number of phages produced per bacterium was similar to that of the wild type. When the dda mutant phage also contained a mutation in T4 gene 59 (a gene normally required only for recombination-dependent DNA replication), essentially no DNA was synthesized. Recent in vitro studies have shown that the gene 59 protein loads a component of the primosome, the T4 gene 41 DNA helicase, onto DNA. A molecular model for replication initiation is presented that is based on our genetic data.     

Characterization of a defective phage system for the analysis of bacteriophage T4 DNA replication origins

We have developed a defective phage system for the isolation and analysis of phage T4 replication origins based on the T4-mediated transduction of plasmid pBR322. During the initial infection of a plasmid-containing cell, recombinant plasmids with T4 DNA inserts are converted into fully modified linear DNA concatamers that are packaged into T4 phage particles, to create defective phage (transducing particles). In order to select T4 replication origins from genomic libraries of T4 sequences cloned into the plasmid pBR322, we searched for recombinant plasmids that transduce with an unusually high efficiency, reasoning that this should select for T4 sequences that function as origins on plasmid DNA after phage infection. We also selected for defective phage that can propagate efficiently with the aid of a coinfecting helper phage during subsequent rounds of phage infection. which should select for T4 sequences that can function as origins on the linear DNA present in the defective phage. Several T4 inserts were isolated repeatedly in one or both of these selective procedures, and these were mapped to particular locations on the T4 genome. When plasmids were selected in this way from genomic libraries constructed using different restriction nucleases, they contained overlapping segments of the T4 genome, indicating that the same T4 sequences were selected. The inserts in two of the selected plasmids permit a very high frequency of transduction from circular plasmids: these have been shown to contain a special type of T4 replication origin.     

Choreography of bacteriophage T7 DNA replication

The replication system of phage T7 provides a model for DNA replication. Biochemical, structural, and single-molecule analyses together provide insight into replisome mechanics. A complex of polymerase, a processivity factor, and helicase mediates leading strand synthesis. Establishment of the complex requires an interaction of the C-terminal tail of the helicase with the polymerase. During synthesis the complex is stabilized by other interactions to provide for a processivity of 5 kilobase (kb). The C-terminal tail also interacts with a distinct region of the polymerase to captures dissociating polymerase to increase the processivity to >17kb. The lagging strand is synthesized discontinuously within a loop that forms and resolves during each cycle of Okazaki fragment synthesis. The synthesis of a primer as well as the termination of a fragment signal loop resolution.     

On the processivity of DNA replication

In this paper we describe the nature and importance of processive enzymatic reactions in biological processes. A model is set up to describe the processive synthetic process in DNA replication, and experiments are presented to define and test the model, using the components of the T4 phage-coded five-protein (in vitro) DNA replication system of Alberts. Nossal and coworkers. These experiments are performed either with a homogeneous oligo dT-poly dA primer-template system, or with a natural primer-template system using phage M13 DNA. The results are used to define some molecular aspects of the microscopic "processivity cycle".     

Early intermediates in bacteriophage T4 DNA replication and recombination.

We investigated, by density gradients and subsequent electron microscopy, vegetative T4 DNA after single or multiple infection of Escherichia coli with wild-type T4. Our results can be summarized as follows. (i) After single infection (i.e., when early intermolecular recombination could not occur), most, if not all, T4 DNA molecules initiated the first round of replication with a single loop. (ii) After multiple infection, recombinational intermediates containing label from both parents first appeared as early as 1 min after the onset of replication, long before all parental DNA molecules had finished their first round and before secondary replication was detectable. (iii) At the same time, in multiple infections only, complex, highly branched concatemeric T4 DNA first appeared. (iv) Molecules in which two loops or several branches were arranged in tandem were only found after multiple infections. (v) Secondary loops within primary loops were seen after both single and multiple infections, but they were rare and many appeared off center. Thus, recombination in wild-type T4-infected cells occurred very early, and the generation of multiple tandem loops or branches in vegetative T4 DNA depended on recombination. These results are consistent with the previous finding (A. Luder and G. Mosig, Proc. Natl. Acad. Sci. U.S.A. 79:1101-1105, 1982) that most secondary growing points of T4 are not initiated from origin sequences but from recombinational intermediates. By these and previous results, the various DNA molecules that we observed are most readily explained as intermediates in DNA replication and recombination according to a model proposed earlier to explain various other aspects of T4 DNA metabolism (Mosig et al., p. 277-295, in D. Ray, ed., The Initiation of DNA Replication, Academic Press, Inc., New York, 1981).     

Development of an in vitro bacteriophage N4 DNA replication system

An in vitro DNA replication system from bacteriophage N4-infected Escherichia coli has been developed. It requires MgCl2, all four deoxyribonucleoside triphosphates, and exogenously added N4 phage DNA; other DNAs are used inefficiently or not at all. Ribonucleoside triphosphates are not required, although they stimulate DNA synthesis. In vitro replication starts at the ends of the N4 genome and moves progressively inward. Initiation occurs through hairpin priming at the 3' ends of the genome, but shows a strong preference for the right end. Three N4 gene products (dnp, dbp, and exo) required in vivo for N4 DNA synthesis are absolutely required in the in vitro system. These findings are discussed with respect to the mode of N4 DNA replication.     

Tracking sliding clamp opening and closing during bacteriophage T4 DNA polymerase holoenzyme assembly

The bacteriophage T4 DNA polymerase holoenzyme, consisting of the DNA polymerase (gp43), the sliding clamp (gp45), and the clamp loader (gp44/62), is loaded onto DNA in an ATP-dependent, multistep reaction. The trimeric, ring-shaped gp45 is loaded onto DNA such that the DNA passes through the center of the ring. gp43 binds to this complex, thereby forming a topological link with the DNA and increasing its processivity. Using stopped-flow fluorescence-resonance energy transfer, we have investigated opening and closing of the gp45 ring during the holoenzyme assembly process. Two amino acids that lie on opposite sides of the gp45 subunit interface, W91 and V162C labeled with coumarin, were used as the fluorescence donor and acceptor, respectively. Free in solution, gp45 has two closed subunit interfaces with W91 to V162-coumarin distances of 19 A and one open subunit interface with a W91 to V162C-coumarin distance of 40 A. Making the assumption that the distance across the two closed subunit interfaces is unchanged during the holoenzyme assembly process, we have found that the distance across the open subunit interface is first increased to greater than 45 A and is then decreased to 30 A during a 10-step assembly mechanism. The gp45 ring is not completely closed in the holoenzyme complex, consistent with previous evidence suggesting that the C-terminus of gp43 is inserted into the gp45 subunit interface. Unexpectedly, ATP-hydrolysis events are coupled to only a fraction of the total distance change, with conformational changes linked to binding DNA and gp43 coupled to the majority of the total distance change. Using the nonhydrolyzable ATP analogue ATP-gamma-S results in formation of a nonproductive gp45 x gp44/62 complex; however, adding an excess of ATP to this nonproductive complex results in rapid ATP/ATP-gamma-S exchange to yield a productive gp45 x gp44/62 complex within seconds.     

Recombination-dependent DNA replication stimulated by double-strand breaks in bacteriophage T4.

We analyzed the mechanism of recombination-dependent DNA replication in bacteriophage T4-infected Escherichia coli using plasmids that have sequence homology to the infecting phage chromosome. Consistent with prior studies, a pBR322 plasmid, initially resident in the infected host cell, does not replicate following infection by T4. However, the resident plasmid can be induced to replicate when an integrated copy of pBR322 vector is present in the phage chromosome. As expected for recombination-dependent DNA replication, the induced replication of pBR322 required the phage-encoded UvsY protein. Therefore, recombination-dependent plasmid replication requires homology between the plasmid and phage genomes but does not depend on the presence of any particular T4 DNA sequence on the test plasmid. We next asked whether T4 recombination-dependent DNA replication can be triggered by a double-strand break (dsb). For these experiments, we generated a novel phage strain that cleaves its own genome within the nonessential frd gene by means of the I-TevI endonuclease (encoded within the intron of the wild-type td gene). The dsb within the phage chromosome substantially increased the replication of plasmids that carry T4 inserts homologous to the region of the dsb (the plasmids are not themselves cleaved by the endonuclease). The dsb stimulated replication when the plasmid was homologous to either or both sides of the break but did not stimulate the replication of plasmids with homology to distant regions of the phage chromosome. As expected for recombination-dependent replication, plasmid replication triggered by dsbs was dependent on T4-encoded recombination proteins. These results confirm two important predictions of the model for T4-encoded recombination-dependent DNA replication proposed by Gisela Mosig (p. 120-130, in C. K. Mathews, E. M. Kutter, G. Mosig, and P. B. Berget (ed.), Bacteriophage T4, 1983). In addition, replication stimulated by dsbs provides a site-specific version of the process, which should be very useful for mechanistic studies.     

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).