Escherichia coli DNA polymerase III holoenzyme subunits alpha, beta, and gamma directly contact the primer-template

The Macromolecular Machines that Duplicate the Escherichia coli Chromosome as Targets for Drug Discovery

DNA replication is an essential process. Although the fundamental strategies to duplicate chromosomes are similar in all free-living organisms, the enzymes of the three domains of life that perform similar functions in DNA replication differ in amino acid sequence and their three-dimensional structures. Moreover, the respective proteins generally utilize different enzymatic mechanisms. Hence, the replication proteins that are highly conserved among bacterial species are attractive targets to develop novel antibiotics as the compounds are unlikely to demonstrate off-target effects. For those proteins that differ among bacteria, compounds that are species-specific may be found. Escherichia coli has been developed as a model system to study DNA replication, serving as a benchmark for comparison. This review summarizes the functions of individual E. coli proteins, and the compounds that inhibit them.

Single-molecule mechanochemical characterization of E. coli pol III core catalytic activity

Pol III core is the three‐subunit subassembly of the E. coli replicative DNA polymerase III holoenzyme. It contains the catalytic polymerase subunit α, the 3′ → 5′ proofreading exonuclease ε, and a subunit of unknown function, θ. We employ optical tweezers to characterize pol III core activity on a single DNA substrate. We observe polymerization at applied template forces F < 25 pN and exonucleolysis at F > 30 pN. Both polymerization and exonucleolysis occur as a series of short bursts separated by pauses. For polymerization, the initiation rate after pausing is independent of force. In contrast, the exonucleolysis initiation rate depends strongly on force. The measured force and concentration dependence of exonucleolysis initiation fits well to a two‐step reaction scheme in which pol III core binds bimolecularly to the primer‐template junction, then converts at rate k₂ into an exo‐competent conformation. Fits to the force dependence of k_init show that exo initiation requires fluctuational opening of two base pairs, in agreement with temperature‐ and mismatch‐dependent bulk biochemical assays. Taken together, our results support a model in which the pol and exo activities of pol III core are effectively independent, and in which recognition of the 3′ end of the primer by either α or ε is governed by the primer stability. Thus, binding to an unstable primer is the primary mechanism for mismatch recognition during proofreading, rather than an alternative model of duplex defect recognition.

The interplay of primer-template DNA phosphorylation status and single-stranded DNA binding proteins in directing clamp loaders to the appropriate polarity of DNA

Sliding clamps are loaded onto DNA by clamp loaders to serve the critical role of coordinating various enzymes on DNA. Clamp loaders must quickly and efficiently load clamps at primer/template (p/t) junctions containing a duplex region with a free 3′OH (3′DNA), but it is unclear how clamp loaders target these sites. To measure the Escherichia coli and Saccharomyces cerevisiae clamp loader specificity toward 3′DNA, fluorescent β and PCNA clamps were used to measure clamp closing triggered by DNA substrates of differing polarity, testing the role of both the 5′phosphate (5′P) and the presence of single-stranded binding proteins (SSBs). SSBs inhibit clamp loading by both clamp loaders on the incorrect polarity of DNA (5′DNA). The 5′P groups contribute selectivity to differing degrees for the two clamp loaders, suggesting variations in the mechanism by which clamp loaders target 3′DNA. Interestingly, the χ subunit of the E. coli clamp loader is not required for SSB to inhibit clamp loading on phosphorylated 5′DNA, showing that χ·SSB interactions are dispensable. These studies highlight a common role for SSBs in directing clamp loaders to 3′DNA, as well as uncover nuances in the mechanisms by which SSBs perform this vital role.

Replication clamps and clamp loaders

To achieve the high degree of processivity required for DNA replication, DNA polymerases associate with ring-shaped sliding clamps that encircle the template DNA and slide freely along it. The closed circular structure of sliding clamps necessitates an enzyme-catalyzed mechanism, which not only opens them for assembly and closes them around DNA, but specifically targets them to sites where DNA synthesis is initiated and orients them correctly for replication. Such a feat is performed by multisubunit complexes known as clamp loaders, which use ATP to open sliding clamp rings and place them around the 3' end of primer-template (PT) junctions. Here we discuss the structure and composition of sliding clamps and clamp loaders from the three domains of life as well as T4 bacteriophage, and provide our current understanding of the clamp-loading process.

Architecture and conservation of the bacterial DNA replication machinery, an underexploited drug target

New antibiotics with novel modes of action are required to combat the growing threat posed by multi-drug resistant bacteria. Over the last decade, genome sequencing and other high-throughput techniques have provided tremendous insight into the molecular processes underlying cellular functions in a wide range of bacterial species. We can now use these data to assess the degree of conservation of certain aspects of bacterial physiology, to help choose the best cellular targets for development of new broad-spectrum antibacterials.

DNA replication is a conserved and essential process, and the large number of proteins that interact to replicate DNA in bacteria are distinct from those in eukaryotes and archaea; yet none of the antibiotics in current clinical use acts directly on the replication machinery. Bacterial DNA synthesis thus appears to be an underexploited drug target. However, before this system can be targeted for drug design, it is important to understand which parts are conserved and which are not, as this will have implications for the spectrum of activity of any new inhibitors against bacterial species, as well as the potential for development of drug resistance. In this review we assess similarities and differences in replication components and mechanisms across the bacteria, highlight current progress towards the discovery of novel replication inhibitors, and suggest those aspects of the replication machinery that have the greatest potential as drug targets.

DNA replicases from a bacterial perspective

Bacterial replicases are complex, tripartite replicative machines. They contain a polymerase, polymerase III (Pol III), a β₂ processivity factor, and a DnaX complex ATPase that loads β₂ onto DNA and chaperones Pol III onto the newly loaded β₂. Bacterial replicases are highly processive, yet cycle rapidly during Okazaki fragment synthesis in a regulated way. Many bacteria encode both a full-length τ and a shorter γ form of DnaX by a variety of mechanisms. γ appears to be uniquely placed in a single position relative to two τ protomers in a pentameric ring. The polymerase catalytic subunit of Pol III, α, contains a PHP domain that not only binds to a prototypical ε Mg²⁺-dependent exonuclease, but also contains a second Zn²⁺-dependent proofreading exonuclease, at least in some bacteria. This review focuses on a critical evaluation of recent literature and concepts pertaining to the above issues and suggests specific areas that require further investigation.

The rate of polymerase release upon filling the gap between Okazaki fragments is inadequate to support cycling during lagging strand synthesis

Upon completion of synthesis of an Okazaki fragment, the lagging strand replicase must recycle to the next primer at the replication fork in under 0.1 s to sustain the physiological rate of DNA synthesis. We tested the collision model that posits that cycling is triggered by the polymerase encountering the 5'-end of the preceding Okazaki fragment. Probing with surface plasmon resonance, DNA polymerase III holoenzyme initiation complexes were formed on an immobilized gapped template. Initiation complexes exhibit a half-life of dissociation of approximately 15 min. Reduction in gap size to 1 nt increased the rate of dissociation 2.5-fold, and complete filling of the gap increased the off-rate an additional 3-fold (t(1/2)~2 min). An exogenous primed template and ATP accelerated dissociation an additional 4-fold in a reaction that required complete filling of the gap. Neither a 5'-triphosphate nor a 5'-RNA terminated oligonucleotide downstream of the polymerase accelerated dissociation further. Thus, the rate of polymerase release upon gap completion and collision with a downstream Okazaki fragment is 1000-fold too slow to support an adequate rate of cycling and likely provides a backup mechanism to enable polymerase release when the other cycling signals are absent. Kinetic measurements indicate that addition of the last nucleotide to fill the gap is not the rate-limiting step for polymerase release and cycling. Modest (approximately 7 nt) strand displacement is observed after the gap between model Okazaki fragments is filled. To determine the identity of the protein that senses gap filling to modulate affinity of the replicase for the template, we performed photo-cross-linking experiments with highly reactive and non-chemoselective diazirines. Only the α subunit cross-linked, indicating that it serves as the sensor.

Parallel multiplicative target screening against divergent bacterial replicases: identification of specific inhibitors with broad spectrum potential

Typically, biochemical screens that employ pure macromolecular components focus on single targets or a small number of interacting components. Researches rely on whole cell screens for more complex systems. Bacterial DNA replicases contain multiple subunits that change interactions with each stage of a complex reaction. Thus, the actual number of targets is a multiple of the proteins involved. It is estimated that the overall replication reaction includes up to 100 essential targets, many suitable for discovery of antibacterial inhibitors. We have developed an assay, using purified protein components, in which inhibitors of any of the essential targets can be detected through a common readout. Use of purified components allows each protein to be set within the linear range where the readout is proportional to the extent of inhibition of the target. By performing assays against replicases from model Gram-negative and Gram-positive bacteria in parallel, we show that it is possible to distinguish compounds that inhibit only a single bacterial replicase from those that exhibit broad spectrum potential.

Insights into the replisome from the structure of a ternary complex of the DNA polymerase III alpha-subunit

The crystal structure of the catalytic alpha-subunit of the DNA polymerase III (Pol IIIalpha) holoenzyme bound to primer-template DNA and an incoming deoxy-nucleoside 5'-triphosphate has been determined at 4.6-A resolution. The polymerase interacts with the sugar-phosphate backbone of the DNA across its minor groove, which is made possible by significant movements of the thumb, finger, and beta-binding domains relative to their orientations in the unliganded polymerase structure. Additionally, the DNA and incoming nucleotide are bound to the active site of Pol IIIalpha nearly identically as they are in their complex with DNA polymerase beta, thereby proving that the eubacterial replicating polymerase, but not the eukaryotic replicating polymerase, is homologous to DNA polymerase beta. Finally, superimposing a recent structure of the clamp bound to DNA on this Pol IIIalpha complex with DNA places a loop of the beta-binding domain into the appropriate clamp cleft and supports a mechanism of polymerase switching.

The Structure of T. aquaticus DNA Polymerase III Is Distinct from Eukaryotic Replicative DNA Polymerases

The crystal structure of Thermus aquaticus DNA polymerase III alpha subunit reveals that the structure of the catalytic domain of the eubacterial replicative polymerase is unrelated to that of the eukaryotic replicative polymerase but rather belongs to the Polbeta-like nucleotidyltransferase superfamily. A model of the polymerase complexed with both DNA and beta-sliding clamp interacting with a reoriented binding domain and internal beta binding site was constructed that is consistent with existing biochemical data. Within the crystal, two C-terminal domains are interacting through a surface that is larger than many dimer interfaces. Since replicative polymerases of eubacteria and eukaryotes/archaea are not homologous, the nature of the replicative polymerase in the last common ancestor is unknown. Although other possibilities have been proposed, the plausibility of a ribozyme DNA polymerase should be considered.

Cellular DNA replicases: components and dynamics at the replication fork

DNA replicases are multicomponent machines that have evolved clever strategies to perform their function. Although the structure of DNA is elegant in its simplicity, the job of duplicating it is far from simple. At the heart of the replicase machinery is a heteropentameric AAA+ clamp-loading machine that couples ATP hydrolysis to load circular clamp proteins onto DNA. The clamps encircle DNA and hold polymerases to the template for processive action. Clamp-loader and sliding clamp structures have been solved in both prokaryotic and eukaryotic systems. The heteropentameric clamp loaders are circular oligomers, reflecting the circular shape of their respective clamp substrates. Clamps and clamp loaders also function in other DNA metabolic processes, including repair, checkpoint mechanisms, and cell cycle progression. Twin polymerases and clamps coordinate their actions with a clamp loader and yet other proteins to form a replisome machine that advances the replication fork.

Biochemical characterization of DNA damage checkpoint complexes: clamp loader and clamp complexes with specificity for 5' recessed DNA

The cellular pathways involved in maintaining genome stability halt cell cycle progression in the presence of DNA damage or incomplete replication. Proteins required for this pathway include Rad17, Rad9, Hus1, Rad1, and Rfc-2, Rfc-3, Rfc-4, and Rfc-5. The heteropentamer replication factor C (RFC) loads during DNA replication the homotrimer proliferating cell nuclear antigen (PCNA) polymerase clamp onto DNA. Sequence similarities suggest the biochemical functions of an RSR (Rad17–Rfc2–Rfc3–Rfc4–Rfc5) complex and an RHR heterotrimer (Rad1–Hus1–Rad9) may be similar to that of RFC and PCNA, respectively. RSR purified from human cells loads RHR onto DNA in an ATP-, replication protein A-, and DNA structure-dependent manner. Interestingly, RSR and RFC differed in their ATPase activities and displayed distinct DNA substrate specificities. RSR preferred DNA substrates possessing 5′ recessed ends whereas RFC preferred 3′ recessed end DNA substrates. Characterization of the biochemical loading reaction executed by the checkpoint clamp loader RSR suggests new insights into the mechanisms underlying recognition of damage-induced DNA structures and signaling to cell cycle controls. The observation that RSR loads its clamp onto a 5′ recessed end supports a potential role for RHR and RSR in diverse DNA metabolism, such as stalled DNA replication forks, recombination-linked DNA repair, and telomere maintenance, among other processes.

A cell cycle checkpoint complex is shown to bind preferentially to DNA with 5'recessed ends. This activity suggests that the complex might be involved in various DNA maintenance pathways

A binary system of photoreagents for high-efficiency labeling of DNA polymerases

To increase the efficiency of photoaffinity labeling of DNA polymerases, a binary system of photoaffinity reagents was applied. Photoreactive radioactive primers were synthesized by DNA polymerases beta (pol beta) or DNA polymerase from Thermus thermophilus (pol Tte) using a template-primer duplex in the presence of a dTTP analogue containing 4-azidotetrafluorobenzoyl group linked via spacers of varying length to 5-position of uridine ring- 5-[N-(2,3,5,6-tetrafluoro-4-azidobenzoyl)-amino-trans-propenyl-1]-2'-deoxyuridine-5'-triphosphate (FAB-4-dUTP) or 5-[N-[[(2,3,5,6-tetrafluoro-4-azidobenzoyl)-butanoyl]-amino]-trans-3-aminopropenyl-1]-2'-deoxyuridine-5'-triphosphate (FAB-9-dUTP). The reaction mixtures were UV irradiated (lambda = 365-450 nm) in the absence or presence of a dTTP analog, containing a pyrene moiety-5-[N-(4-(1-pyrenyl)-butylcarbonyl)-amino-trans-propenyl-1]-2'-deoxyuridine-5'-triphosphate (Pyr- 8-dUTP) or 5-[N-(4-(1-pyrenyl)-ethylcarbonyl)-amino-trans-propenyl-1]-2'-deoxyuridine-5'-triphosphate (Pyr-6-dUTP). The most efficient crosslinking of both DNA polymerases was observed in the case of photoreactive DNA primer, carrying the FAB-4-dUMP moiety at the 3'-end, and Pyr-6-dUTP as a sensitizer. The binary system of photoaffinity reagents allows increasing photoaffinity labeling of the both DNA polymerases in comparison to the primer crosslinking without photosensitizer.

The delta and delta ' subunits of the DNA polymerase III holoenzyme are essential for initiation complex formation and processive elongation

delta and delta' are required for assembly of the processivity factor beta(2) onto primed DNA in the DNA polymerase III holoenzyme-catalyzed reaction. We developed protocols for generating highly purified preparations of delta and delta'. In holoenzyme reconstitution assays, delta' could not be replaced by delta, tau, or gamma, even when either of the latter were present at a 10,000-fold molar excess. Likewise, delta could not be replaced by delta', tau, or gamma. Bacterial strains bearing chromosomal knockouts of either the holA(delta) or holB(delta') genes were not viable, demonstrating that both delta and delta' are essential. Western blots of isolated initiation complexes demonstrated the presence of both delta and delta'. However, in the absence of chipsi and single-stranded DNA-binding protein, a stable initiation complex lacking deltadelta' was isolated by gel filtration. Lack of delta-delta' decreased the rate of elongation about 3-fold, and the extent of processive replication was significantly decreased. Adding back delta-delta' but not chipsi, delta, or delta' alone restored the diminished activity, indicating that in addition to being key components required for the beta loading activity of the DnaX complex, deltadelta' is present in initiation complex and is required for processive elongation.

DNA structure requirements for the Escherichia coli gamma complex clamp loader and DNA polymerase III holoenzyme

The Escherichia coli chromosomal replicase, DNA polymerase III holoenzyme, is highly processive during DNA synthesis. Underlying high processivity is a ring-shaped protein, the beta clamp, that encircles DNA and slides along it, thereby tethering the enzyme to the template. The beta clamp is assembled onto DNA by the multiprotein gamma complex clamp loader that opens and closes the beta ring around DNA in an ATP-dependent manner. This study examines the DNA structure required for clamp loading action. We found that the gamma complex assembles beta onto supercoiled DNA (replicative form I), but only at very low ionic strength, where regions of unwound DNA may exist in the duplex. Consistent with this, the gamma complex does not assemble beta onto relaxed closed circular DNA even at low ionic strength. Hence, a 3'-end is not required for clamp loading, but a single-stranded DNA (ssDNA)/double-stranded DNA (dsDNA) junction can be utilized as a substrate, a result confirmed using synthetic oligonucleotides that form forked ssDNA/dsDNA junctions on M13 ssDNA. On a flush primed template, the gamma complex exhibits polarity; it acts specifically at the 3'-ssDNA/dsDNA junction to assemble beta onto the DNA. The gamma complex can assemble beta onto a primed site as short as 10 nucleotides, corresponding to the width of the beta ring. However, a protein block placed closer than 14 base pairs (bp) upstream from the primer 3' terminus prevents the clamp loading reaction, indicating that the gamma complex and its associated beta clamp interact with approximately 14-16 bp at a ssDNA/dsDNA junction during the clamp loading operation. A protein block positioned closer than 20-22 bp from the 3' terminus prevents use of the clamp by the polymerase in chain elongation, indicating that the polymerase has an even greater spatial requirement than the gamma complex on the duplex portion of the primed site for function with beta. Interestingly, DNA secondary structure elements placed near the 3' terminus impose similar steric limits on the gamma complex and polymerase action with beta. The possible biological significance of these structural constraints is discussed.

Architecture of the active DNA polymerase delta.proliferating cell nuclear antigen.template-primer complex

The relative positions of components of the DNA-dependent DNA polymerase delta (pol delta).proliferating cell nuclear antigen (PCNA).DNA complex were studied. We have shown that pol delta incorporates nucleotides close to a template biotin-streptavidin complex located 5' (downstream) to the replicating complex in the presence or absence of PCNA. PCNA-dependent synthesis catalyzed by pol delta was nearly totally (95%) inhibited by a biotin. streptavidin complex located at the 3'-end of a template with a 15-mer primer (upstream of the replicating complex), but was only partially inhibited with a 19-mer primer. With either primer, PCNA-independent synthesis was not affected by the biotin. streptavidin complex. Quantification of results with primers of varying length suggested that pol delta interacts with between 8 and 10 nucleotides of duplex DNA immediately proximal to the 3'-OH primer terminus. Using UV photocross-linking, we determined that the 125-kDa subunit of pol delta, but not the 50-kDa subunit, interacted with a photosensitive residue of a substrate oligonucleotide. Interaction apparently takes place through the C terminus of p125. Based on these results, we conclude that PCNA is located "behind" pol delta in the polymerization complex during DNA synthesis and that only the large subunit of pol delta (two-subunit form) interacts directly with DNA. A detailed model of the enzymatically active complex is proposed.

Modified oligonucleotides: synthesis and strategy for users

Synthetic oligonucleotide analogs have greatly aided our understanding of several biochemical processes. Efficient solid-phase and enzyme-assisted synthetic methods and the availability of modified base analogs have added to the utility of such oligonucleotides. In this review, we discuss the applications of synthetic oligonucleotides that contain backbone, base, and sugar modifications to investigate the mechanism and stereochemical aspects of biochemical reactions. We also discuss interference mapping of nucleic acid-protein interactions; spectroscopic analysis of biochemical reactions and nucleic acid structures; and nucleic acid cross-linking studies. The automation of oligonucleotide synthesis, the development of versatile phosphoramidite reagents, and efficient scale-up have expanded the application of modified oligonucleotides to diverse areas of fundamental and applied biological research. Numerous reports have covered oligonucleotides for which modifications have been made of the phosphodiester backbone, of the purine and pyrimidine heterocyclic bases, and of the sugar moiety; these modifications serve as structural and mechanistic probes. In this chapter, we review the range, scope, and practical utility of such chemically modified oligonucleotides. Because of space limitations, we discuss only those oligonucleotides that contain phosphate and phosphate analogs as internucleotidic linkages.

ATP binding to the Escherichia coli clamp loader powers opening of the ring-shaped clamp of DNA polymerase III holoenzyme

The Escherichia coli gamma complex serves as a clamp loader, catalyzing ATP-dependent assembly of beta protein clamps onto primed DNA templates during DNA replication. These ring-shaped clamps tether DNA polymerase III holoenzyme to the template, facilitating rapid and processive DNA synthesis. This report focuses on the role of ATP binding and hydrolysis catalyzed by the gamma complex during clamp loading. We show that the energy from ATP binding to gamma complex powers several initial events in the clamp loading pathway. The gamma complex (gamma2 delta delta'chi psi) binds two ATP molecules (one per gamma subunit in the complex) with high affinity (Kd = 1-2. 5 x 10(-6) M) or two adenosine 5'-O-(3-thiotriphosphate)(ATPgammaS) molecules with slightly lower affinity (Kd = 5-6.5 x 10(-6) M). Experiments performed prior to the first ATP turnover (kcat = 4 x 10(-3) s-1 at 4 degreesC), or in the presence of ATPgammaS (kcat = 1 x 10(-4) s-1 at 37 degreesC), demonstrate that upon interaction with ATP the gamma complex undergoes a change in conformation. This ATP-bound gamma complex binds beta and opens the ring at the dimer interface. Still prior to ATP hydrolysis, the composite of gamma complex and the open beta ring binds with high affinity to primer-template DNA. Thus ATP binding powers all the steps in the clamp loading pathway leading up to the assembly of a gamma complex. open beta ring.DNA intermediate, setting the stage for ring closing and turnover of the clamp loader, steps that may be linked to subsequent hydrolysis of ATP.

Photoaffinity labeling as an approach to study supramolecular nucleoprotein complexes

The modern approaches for studying the detailed structure of nucleoprotein complexes involved in replication and transcription, based on the use of nucleic acids with photoreactive groups incorporated into definite positions of polynucleotide chain, are considered. Methods of preparation of photoreactive nucleic acids of this type are presented. Their use for positioning of RNA polymerase III and transcription factors as well as of the main participants of the replication machinery at the respective templates is described. A survey of the data concerning the amino acid residues modified in the course of photoaffinity labeling of proteins is also presented and some complications are discussed.

The initiator function of DnaA protein is negatively regulated by the sliding clamp of the E. coli chromosomal replicase

The beta subunit of DNA polymerase III is essential for negative regulation of the initiator protein, DnaA. DnaA inactivation occurs through accelerated hydrolysis of ATP bound to DnaA; the resulting ADP-DnaA fails to initiate replication. The ability of beta subunit to promote DnaA inactivation depends on its assembly as a sliding clamp on DNA and must be accompanied by a partially purified factor, IdaB protein. DnaA inactivation in the presence of IdaB and DNA polymerase III is further stimulated by DNA synthesis, indicating close linkage between initiator inactivation and replication. In vivo, DnaA predominantly takes on the ADP form in a beta subunit-dependent manner. Thus, the initiator is negatively regulated by action of the replicase, a mechanism that may be key to effective control of the replication cycle.

Comparison of the efficiency of synthesis past single bulky DNA adducts in vivo and in vitro by the polymerase III holoenzyme

Previous studies from our laboratory revealed that site-specific and stereospecific styrene oxide (SO) lesions in M13 DNA were readily bypassed when transfected into Escherichia coli cells, but these same lesions blocked the progress of several purified polymerases in vitro when situated in oligodeoxynucleotide templates (Latham, G. J., et al. (1993) J. Biol. Chem. 268, 23427-23434; Latham, G. J., et al. (1995) Chem. Res. Toxicol. 8, 422-430). To resolve this apparent discrepancy, we constructed single-stranded M13 genomes containing single SO adducts and compared their replication efficiencies in E. coli cells to the extent of bypass synthesis in vitro using three different complexes of the purified E. coli polymerase III (Pol III) holoenzyme. The transformation efficiencies of the SO-adducted M13 templates were comparable to those of the nonadducted controls, indicating facile bypass in E. coli. When the identical adducted M13 vectors were replicated in vitro with the reconstituted complexes of the Pol III holoenzyme, the results were consistent with the in vivo data: Synthesis past two of the three SO adducts in M13 was unhindered relative to synthesis on the unadducted M13 control template. Since our previous in vitro assays indicated that SO adducts in 33-mer templates largely blocked polymerases other than Pol III, we repeated these studies using reconstituted Pol III. Significantly, Pol III replication was poorly processive and strongly terminated by SO lesions in 33-mer templates. This result was in stark contrast to the efficient bypass in vitro of the same adducts in M13 DNA. In fact, Pol III-mediated bypass was enhanced to > 75-fold on adducted circular M13 templates as compared to adducted linear oligodeoxynucleotides. The implications of the effects of polymerase processivity and template-primer structure upon lesion bypass are discussed.

Identification of the beta-binding domain of the alpha subunit of Escherichia coli polymerase III holoenzyme

Rapid and processive DNA synthesis by Escherichia coli DNA polymerase III holoenzyme is achieved by the direct interaction between the alpha subunit of DNA polymerase III core and the beta sliding clamp (LaDuca, R. J., Crute, J. J., McHenry, C. S., and Bambara, R. A. (1986) J. Biol. Chem. 261, 7550-7557; Stukenberg, T. P., Studwell-Vaughan, P. S., and O'Donnell, M. (1991) J. Biol. Chem. 266, 11328-11334). In this study, we localized the beta-binding domain of alpha to a carboxyl-terminal region by quantifying the interaction of beta with a series of alpha deletion proteins. Purification and binding analysis was facilitated by insertion of hexahistidine and short biotinylation sequences on the deletion terminus of alpha. Interaction of beta with alpha deletion proteins was studied by gel filtration and surface plasmon resonance. alpha lacking 169 COOH-terminal residues still possessed beta-binding activity; whereas deletion of 342 amino acids from the COOH terminus abolished beta binding. Deletion of 542 amino acids from the NH2 terminus of the 1160 residue alpha subunit resulted in a protein that bound beta 10-20-fold more strongly than native alpha. Hence, portions of alpha between residues 542 and 991 are involved in beta binding. DNA binding to alpha apparently triggers an increased affinity for beta (Naktinis, V., Turner, J., and O'Donnell, M. (1996) Cell 84, 137-145). Our findings extend this observation by implicating the amino-terminal polymerase domain in inducing a low affinity taut conformation in the carboxyl-terminal beta-binding domain. Deletion of the polymerase domain (or, presumably, its occupancy by DNA) relaxes the COOH-terminal domain, permitting it to assume a conformation with high affinity for beta.

Biotin tagging deletion analysis of domain limits involved in protein-macromolecular interactions. Mapping the tau binding domain of the DNA polymerase III alpha subunit

The tau subunit dimerizes DNA polymerase III via interaction with the alpha subunit, allowing DNA polymerase III holoenzyme to synthesize both leading and lagging strands simultaneously at the DNA replication fork. Here, we report a general method to map the limits of domains required for heterologous protein-protein interactions using surface plasmon resonance. The method employs fusion of a short biotinylation sequence at either the NH2 or COOH terminus of the protein to be immobilized on streptavidin-derivatized biosensor chips. Inclusion of a hexahistidine sequence permits rapid purification and separation of the fusion protein from the endogenous Escherichia coli biotin carboxyl carrier protein. Ten deletions of the alpha subunit were constructed and purified by Ni2+-nitrilotriacetic acid chromatography and, when required, monomeric avidin chromatography. Each alpha deletion protein was captured by streptavidin immobilized on a Pharmacia Biosensor BIAcore chip, and the tau binding activity of each alpha deletion was analyzed using surface plasmon resonance. The tau subunit bound very tightly to a full-length amino-terminal fusion of the biotinylation sequence with alpha (KD approximately 70 pm). Four additional NH2-terminal alpha deletion proteins (60, 240, 360, and 542 residues deleted) retained strong binding activity to the tau subunit (KD = 0.19-0.39 nM), whereas deletion of 705 residues or more from the NH2 terminus of the alpha subunit abolished tau binding activity. Full-length alpha that contained a carboxyl-terminal fusion with the biotinylation sequence bound tau strongly (KD = 0.37 nM). However, deletion of 48 amino acids from the COOH terminus totally eliminated tau binding. These results indicate that the COOH-terminal half of the alpha subunit is involved in tau interaction.

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.

A molecular switch in a replication machine defined by an internal competition for protein rings

Replication machines use ring-shaped clamps that encircle DNA to tether the polymerase to the chromosome. The clamp is assembled on DNA by a clamp loader. This report shows that the polymerase and clamp loader coordinate their actions with the clamp by competing for it through overlapping binding sites. The competition is modulated by DNA. In the absence of DNA, the clamp associates with the clamp loader. But after the clamp is placed on DNA, the polymerase develops a tight grip on the clamp and out-competes the clamp loader. After replication of the template, the polymerase looses affinity for the clamp. Now the clamp loader regains access to the clamp and removes it from DNA thus recycling it for future use.