Mechanism of loading the Escherichia coli DNA polymerase III sliding clamp: II. Uncoupling the beta and DNA binding activities of the gamma complex

Sliding clamps tether DNA polymerases to DNA to increase the processivity of synthesis. The Escherichia coli gamma complex loads the beta sliding clamp onto DNA in an ATP-dependent reaction in which ATP binding and hydrolysis modulate the affinity of the gamma complex for beta and DNA. This is the second of two reports (Williams, C. R., Snyder, A. K., Kuzmic, P., O'Donnell, M., and Bloom, L. B. (2004) J. Biol. Chem. 279, 4376-4385) addressing the question of how ATP binding and hydrolysis regulate specific interactions with DNA and beta. Mutations were made to an Arg residue in a conserved SRC motif in the delta' and gamma subunits that interacts with the ATP site of the neighboring gamma subunit. Mutation of the delta' subunit reduced the ATP-dependent beta binding activity, whereas mutation of the gamma subunits reduced the DNA binding activity of the gamma complex. The gamma complex containing the delta' mutation gave a pre-steady-state burst of ATP hydrolysis, but at a reduced rate and amplitude relative to the wild-type gamma complex. A pre-steady-state burst of ATP hydrolysis was not observed for the complex containing the gamma mutations, consistent with the reduced DNA binding activity of this complex. The differential effects of these mutations suggest that ATP binding at the gamma1 site may be coupled to conformational changes that largely modulate interactions with beta, whereas ATP binding at the gamma2 and/or gamma3 site may be coupled to conformational changes that have a major role in interactions with DNA. Additionally, these results show that the "arginine fingers" play a structural role in facilitating the formation of a conformation that has high affinity for beta and DNA.     

Division of labor--sequential ATP hydrolysis drives assembly of a DNA polymerase sliding clamp around DNA.

The beta sliding clamp encircles DNA and enables processive replication of the Escherichia coli genome by DNA polymerase III holoenzyme. The clamp loader, gamma complex, assembles beta around DNA in an ATP-fueled reaction. Previous studies have shown that gamma complex opens the beta ring and also interacts with DNA on binding ATP. Here, a rapid kinetic analysis demonstrates that gamma complex hydrolyzes two ATP molecules sequentially when placing beta around DNA. The first ATP is hydrolyzed fast, at 25-30 s(-1), while the second ATP hydrolysis is limited to the steady-state rate of 2 s(-1). This step-wise reaction depends on both primed DNA and beta. DNA alone promotes rapid hydrolysis of two ATP molecules, while beta alone permits hydrolysis of only one ATP. These results suggest that beta inserts a slow step between the two ATP hydrolysis events in clamp assembly, during which the clamp loader may perform work on the clamp. Moreover, one ATP hydrolysis is sufficient for release of beta from the gamma complex. This implies that DNA-dependent hydrolysis of the other ATP is coupled to a separate function, perhaps involving work on DNA. A model is presented in which sequential ATP hydrolysis drives distinct events in the clamp-assembly pathway. We also discuss underlying principles of this step-wise mechanism that may apply to the workings of other ATP-fueled biological machines.     

Molecular mechanism and energetics of clamp assembly in Escherichia coli. The role of ATP hydrolysis when gamma complex loads beta on DNA

Escherichia coli DNA polymerase III holoenzyme is a multisubunit composite containing the beta sliding clamp and clamp loading gamma complex. The gamma complex requires ATP to load beta onto DNA. A two-color fluorescence spectroscopic approach was utilized to study this system, wherein both assembly (red fluorescence; X-rhodamine labeled DNA anisotropy assay) and ATP hydrolysis (green fluorescence; phosphate binding protein assay) were simultaneously measured with millisecond timing resolution. The two temporally correlated stopped-flow signals revealed that a preassembled beta. gamma complex composite rapidly binds primer/template DNA in an ATP hydrolysis independent step. Once bound, two molecules of ATP are rapidly hydrolyzed (approximately 34 s(-1)). Following hydrolysis, gamma complex dissociates from the DNA ( approximately 22 s(-1)). Once dissociated, the next cycle of loading is severely compromised, resulting in steady-state ATP hydrolysis rates with a maximum of only approximately 3 s(-1). Two single-site beta dimer interface mutants were examined which had impaired steady-state rates of ATP hydrolysis. The pre-steady-state correlated kinetics of these mutants revealed a pattern essentially identical to wild type. The anisotropy data showed that these mutants decrease the steady-state rates of ATP hydrolysis by causing a buildup of "stuck" binary-ternary complexes on the primer/template DNA.     

Mechanism of loading the Escherichia coli DNA polymerase III beta sliding clamp on DNA. Bona fide primer/templates preferentially trigger the gamma complex to hydrolyze ATP and load the clamp

The Escherichia coli DNA polymerase III gamma complex clamp loader assembles the ring-shaped beta sliding clamp onto DNA. The core polymerase is tethered to the template by beta, enabling processive replication of the genome. Here we investigate the DNA substrate specificity of the clamp-loading reaction by measuring the pre-steady-state kinetics of DNA binding and ATP hydrolysis using elongation-proficient and deficient primer/template DNA. The ATP-bound clamp loader binds both elongation-proficient and deficient DNA substrates either in the presence or absence of beta. However, elongation-proficient DNA preferentially triggers gamma complex to release beta onto DNA with concomitant hydrolysis of ATP. Binding to elongation-proficient DNA converts the gamma complex from a high affinity ATP-bound state to an ADP-bound state having a 10(5)-fold lower affinity for DNA. Steady-state binding assays are misleading, suggesting that gamma complex binds much more avidly to non-extendable primer/template DNA because recycling to the high affinity binding state is rate-limiting. Pre-steady-state rotational anisotropy data reveal a dynamic association-dissociation of gamma complex with extendable primer/templates leading to the diametrically opposite conclusion. The strongly favored dynamic recognition of extendable DNA does not require the presence of beta. Thus, the gamma complex uses ATP binding and hydrolysis as a mechanism for modulating its interaction with DNA in which the ATP-bound form binds with high affinity to DNA but elongation-proficient DNA substrates preferentially trigger hydrolysis of ATP and conversion to a low affinity state.     

Ordered ATP hydrolysis in the gamma complex clamp loader AAA+ machine

The gamma complex couples ATP hydrolysis to the loading of beta sliding clamps onto DNA for processive replication. The gamma complex structure shows that the clamp loader subunits are arranged as a circular heteropentamer. The three gamma motor subunits bind ATP, the delta wrench opens the beta ring, and the delta' stator modulates the delta-beta interaction. Neither delta nor delta' bind ATP. This report demonstrates that the delta' stator contributes a catalytic arginine for hydrolysis of ATP bound to the adjacent gamma(1) subunit. Thus, the delta' stator contributes to the motor function of the gamma trimer. Mutation of arginine 169 of gamma, which removes the catalytic arginines from only the gamma(2) and gamma(3) ATP sites, abolishes ATPase activity even though ATP site 1 is intact and all three sites are filled. This result implies that hydrolysis of the three ATP molecules occurs in a particular order, the reverse of ATP binding, where ATP in site 1 is not hydrolyzed until ATP in sites 2 and/or 3 is hydrolyzed. Implications of these results to clamp loaders of other systems are discussed.     

Analysis of the ATPase subassembly which initiates processive DNA synthesis by DNA polymerase III holoenzyme.

The gamma complex (gamma delta delta' chi psi) subassembly of DNA polymerase III holoenzyme transfers the beta subunit onto primed DNA in a reaction which requires ATP hydrolysis. Once on DNA, beta is a "sliding clamp" which tethers the polymerase to DNA for highly processive synthesis. We have examined beta and the gamma complex to identify which subunit(s) hydrolyzes ATP. We find the gamma complex is a DNA dependent ATPase. The beta subunit, which lacks ATPase activity, enhances the gamma complex ATPase when primed DNA is used as an effector. Hence, the gamma complex recognizes DNA and couples ATP hydrolysis to clamp beta onto primed DNA. Study of gamma complex subunits showed no single subunit contained significant ATPase activity. However, the heterodimers, gamma delta and gamma delta', were both DNA-dependent ATPases. Only the gamma delta ATPase was stimulated by beta and was functional in transferring the beta from solution to primed DNA. Similarity in ATPase activity of DNA polymerase III holoenzyme accessory proteins to accessory proteins of phage T4 DNA polymerase and mammalian DNA polymerase delta suggests the basic strategy of chromosome duplication has been conserved throughout evolution.     

The internal workings of a DNA polymerase clamp-loading machine.

Replicative DNA polymerases are multiprotein machines that are tethered to DNA during chain extension by sliding clamp proteins. The clamps are designed to encircle DNA completely, and they are manipulated rapidly onto DNA by the ATP-dependent activity of a clamp loader. We outline the detailed mechanism of gamma complex, a five-protein clamp loader that is part of the Escherichia coli replicase, DNA polymerase III holoenzyme. The gamma complex uses ATP to open the beta clamp and assemble it onto DNA. Surprisingly, ATP is not needed for gamma complex to crack open the beta clamp. The function of ATP is to regulate the activity of one subunit, delta, which opens the clamp simply by binding to it. The delta' subunit acts as a modulator of the interaction between delta and beta. On binding ATP, the gamma complex is activated such that the delta' subunit permits delta to bind beta and crack open the ring at one interface. The clamp loader-open clamp protein complex is now ready for an encounter with primed DNA to complete assembly of the clamp around DNA. Interaction with DNA stimulates ATP hydrolysis which ejects the gamma complex from DNA, leaving the ring to close around the duplex.     

A model for Escherichia coli DNA polymerase III holoenzyme assembly at primer/template ends. DNA triggers a change in binding specificity of the gamma complex clamp loader

The gamma complex of the Escherichia coli DNA polymerase III holoenzyme assembles the beta sliding clamp onto DNA in an ATP hydrolysis-driven reaction. Interactions between gamma complex and primer/template DNA are investigated using fluorescence depolarization to measure binding of gamma complex to different DNA substrates under steady-state and presteady-state conditions. Surprisingly, gamma complex has a much higher affinity for single-stranded DNA (K(d) in the nM range) than for a primed template (K(d) in the microM range) under steady-state conditions. However, when examined on a millisecond time scale, we find that gamma complex initially binds very rapidly and with high affinity to primer/template DNA but is converted subsequently to a much lower affinity DNA binding state. Presteady-state data reveals an effective dissociation constant of 1.5 nM for the initial binding of gamma complex to DNA and a dissociation constant of 5.7 microM for the low affinity DNA binding state. Experiments using nonhydrolyzable ATPgammaS show that ATP binding converts gamma complex from a low affinity "inactive" to high affinity "active" DNA binding state while ATP hydrolysis has the reverse effect, thus allowing cycling between active and inactive DNA binding forms at steady-state. We propose that a DNA-triggered switch between active and inactive states of gamma complex provides a two-tiered mechanism enabling gamma complex to recognize primed template sites and load beta, while preventing gamma complex from competing with DNA polymerase III core for binding a newly loaded beta.DNA complex.     

A function for the psi subunit in loading the Escherichia coli DNA polymerase sliding clamp

Crystal structures of an Escherichia coli clamp loader have provided insight into the mechanism by which this molecular machine assembles ring-shaped sliding clamps onto DNA. The contributions made to the clamp loading reaction by two subunits, chi and psi, which are not present in the crystal structures, were determined by measuring the activities of three forms of the clamp loader, gamma(3)deltadelta', gamma(3)deltadelta'psi, and gamma(3)deltadelta'psichi. The psi subunit is important for stabilizing an ATP-induced conformational state with high affinity for DNA, whereas the chi subunit does not contribute directly to clamp loading in our assays lacking single-stranded DNA-binding protein. The psi subunit also increases the affinity of the clamp loader for the clamp in assays in which ATPgammaS is substituted for ATP. Interestingly, the affinity of the gamma(3)deltadelta' complex for beta is no greater in the presence than in the absence of ATPgammaS. A role for psi in stabilizing or promoting ATP- and ATPgammaS-induced conformational changes may explain why large conformational differences were not seen in gamma(3)deltadelta' structures with and without bound ATPgammaS. The beta clamp partially compensates for the activity of psi when this subunit is not present and possibly serves as a scaffold on which the clamp loader adopts the appropriate conformation for DNA binding and clamp loading. Results from our work and others suggest that the psi subunit may introduce a temporal order to the clamp loading reaction in which clamp binding precedes DNA binding.     

Examination of the role of the clamp-loader and ATP hydrolysis in the formation of the bacteriophage T4 polymerase holoenzyme

Transient kinetic analyses further support the role of the clamp-loader in bacteriophage T4 as a catalyst which loads the clamp onto DNA through the sequential hydrolysis of two molecules of ATP before and after addition of DNA. Additional rapid-quench and pulse-chase experiments have documented this stoichiometry. The events of ATP hydrolysis have been related to the opening/closing of the clamp protein through fluorescence resonance energy transfer (FRET). In the absence of a hydrolysable form of ATP, the distance across the subunit interface of the clamp does not increase as measured by intramolecular FRET, suggesting gp45 cannot be loaded onto DNA. Therefore, ATP hydrolysis by the clamp-loader appears to open the clamp wide enough to encircle DNA easily. Two additional molecules of ATP then are hydrolyzed to close the clamp onto DNA. The presence of an intermolecular FRET signal indicated that the dissociation of the clamp-loader from this complex occurred after guiding the polymerase onto the correct face of the clamp bound to DNA. The final holoenzyme complex consists of the clamp, DNA, and the polymerase. Although this sequential assembly mechanism can be generally applied to most other replication systems studied to date, the specifics of ATP utilization seem to vary across replication systems.     

Dissection of the ATP-driven reaction cycle of the bacteriophage T4 DNA replication processivity clamp loading system

Processive DNA replication requires the loading of a multisubunit ring-shaped protein complex, known as a sliding or processivity clamp, onto the primer-template (p/t) DNA. This clamp then binds to the replication polymerase to form a processive polymerase holoenzyme. The processivity of the holoenzyme derives from the topological properties of the clamp, which encircles the DNA without actually binding to it. Multisubunit complexes known as clamp-loaders utilize ATP to drive the placement of this ring around the DNA. To further understand the role of ATP binding and hydrolysis in driving clamp-loading in the DNA replication system of bacteriophage T4, we report the results of a series of presteady-state and steady-state kinetic ATPase experiments involving the various components of the reconstituted system. The results obtained are consistent with a mechanism in which a slow step, which involves the binary ATP-bound clamp-clamp loader complex, activates this complex and permits p/t DNA to bind and stimulate ATP hydrolysis. ATP hydrolysis itself, as well as the subsequent (after clamp-loading) dissociation of the clamp-loader and the slippage of the loaded clamp from the p/t DNA construct, are shown to be fast steps. A second slow step occurs after ATP hydrolysis. This step involves the dissociated clamp loader complex and may reflect ADP release. Only one molecule of ATP is hydrolyzed per clamp-loading event. Rate constants for each step, and an overall reaction mechanism for the T4 clamp-loading system, are derived from these data and from other results in the literature. The principles that emerge fit into a general framework that can apply to many biological processes involving ATP-driven reaction cycles.     

An alternative clamp loading pathway via the T4 clamp loader gp44/62-DNA complex

In bacteriophage T4, a clamp loading pathway that utilizes the T4 clamp loader (gp44/62) and ATP hydrolysis initially to form a complex with the clamp (gp45) has been demonstrated, followed by interaction with DNA and closing of the clamp. However, the recent observation that gp45 exists as an opened form in solution raises the possibility of other pathways for clamp loading. In this study, an alternative clamp loading sequence is evaluated in which gp44/62 first recognizes the DNA substrate and then sequesters the clamp from solution and loads it onto DNA. This pathway differs in terms of the initial formation of a gp44/62-DNA complex that is capable of loading gp45. In this work, we demonstrate ATP-dependent DNA binding by gp44/62. Among various DNA structures that were tested, gp44/62 binds specifically to primer-template DNA but not to single-stranded DNA or blunt-end duplex DNA. By tracing the dynamic clamp closing with pre-steady-state FRET measurements, we show that the clamp loader-DNA complex is functional in clamp loading. Furthermore, pre-steady-state ATP hydrolysis experiments suggest that 1 equiv of ATP is hydrolyzed when gp44/62 binds to DNA, and additional ATP hydrolysis is associated with the completion of the clamp loading process. We also investigated the detailed kinetics of binding of MANT-nucleotide to gp44/62 through stopped-flow FRET and demonstrated a conformational change as the result of ATP, but not ADP binding. The collective kinetic data allowed us to propose and evaluate a sequence of steps describing this alternative pathway for clamp loading and holoenzyme formation.     

Mechanism of the delta wrench in opening the beta sliding clamp

The beta sliding clamp encircles DNA and tethers DNA polymerase III holoenzyme to the template for high processivity. The clamp loader, gamma complex (gamma 3 delta delta'chi psi), assembles beta around DNA in an ATP-fueled reaction. The delta subunit of the clamp loader opens the beta ring and is referred to as the wrench; ATP modulates contact between beta and delta among other functions. Crystal structures of delta.beta and the gamma 3 delta delta' minimal clamp loader make predictions of the clamp loader mechanism, which are tested in this report by mutagenesis. The delta wrench contacts beta at two sites. One site is at the beta dimer interface, where delta appears to distort the interface by via a steric clash between a helix on delta and a loop near the beta interface. The energy for this steric clash is thought to derive from the other site of interaction, in which delta binds to a hydrophobic pocket in beta. The current study demonstrates that rather than a simple steric clash with beta, delta specifically contacts beta at this site, but not through amino acid side chains, and thus is presumably mediated by peptide backbone atoms. The results also imply that the interaction of delta at the hydrophobic site on beta contributes to destabilization of the beta dimer interface rather than acting solely as a grip of delta on beta. Within the gamma complex, delta' is proposed to prevent delta from binding to beta in the absence of ATP. This report demonstrates that one or more gamma subunits also contribute to this role. The results also indicate that delta' acts as a backboard upon which the gamma subunits push to attain the ATP induced change needed for the delta wrench to bind and open the beta ring.     

Multiple ATP binding is required to stabilize the "activated" (clamp open) clamp loader of the T4 DNA replication complex

Most DNA replication systems include a sliding clamp that encircles the genomic DNA and links the polymerase to the template to control polymerase processivity. A loading complex is required to open the clamp and place it onto the DNA. In phage T4 this complex consists of a trimeric clamp of gp45 subunits and a pentameric loader assembly of four gp44 and one gp62 subunit(s), with clamp loading driven by ATP binding. We measure this binding as a function of input ligand concentration and show that four ATPs bind to the gp44/62 complex with equal affinity. In contrast, the ATPase rate profile of the clamp-clamp loader complex exhibits a marked peak at an input ATP concentration close to the overall Kd (approximately 30 microm), with further increases in bound ATP decreasing the ATPase rate to a much lower level. Thus the progressive binding of the four ATPs triggers a conformational change in the complex that markedly inhibits ATPase activity. This inhibition is related to ring opening by using a clamp that is covalently cross-linked across its subunit interfaces and thus rendered incapable of opening. Binding of this clamp abolishes substrate inhibition of the ATPase but leaves ATP binding unchanged. We show that four ATP ligands must bind to the T4 clamp loader before the loader can be fully "activated" and the clamp opened, and that ATP hydrolysis is required only for release of the loader complex after clamp loading onto the replication fork has been completed.     

Interplay of clamp loader subunits in opening the beta sliding clamp of Escherichia coli DNA polymerase III holoenzyme

The Escherichia coli beta dimer is a ring-shaped protein that encircles DNA and acts as a sliding clamp to tether the replicase, DNA polymerase III holoenzyme, to DNA. The gamma complex (gammadeltadelta'chipsi) clamp loader couples ATP to the opening and closing of beta in assembly of the ring onto DNA. These proteins are functionally and structurally conserved in all cells. The eukaryotic equivalents are the replication factor C (RFC) clamp loader and the proliferating cell nuclear antigen (PCNA) clamp. The delta subunit of the E. coli gamma complex clamp loader is known to bind beta and open it by parting one of the dimer interfaces. This study demonstrates that other subunits of gamma complex also bind beta, although weaker than delta. The gamma subunit like delta, affects the opening of beta, but with a lower efficiency than delta. The delta' subunit regulates both gamma and delta ring opening activities in a fashion that is modulated by ATP interaction with gamma. The implications of these actions for the workings of the E. coli clamp loading machinery and for eukaryotic RFC and PCNA are discussed.     

ATP binding and hydrolysis-driven rate-determining events in the RFC-catalyzed PCNA clamp loading reaction

The multi-subunit replication factor C (RFC) complex loads circular proliferating cell nuclear antigen (PCNA) clamps onto DNA where they serve as mobile tethers for polymerases and coordinate the functions of many other DNA metabolic proteins. The clamp loading reaction is complex, involving multiple components (RFC, PCNA, DNA, and ATP) and events (minimally: PCNA opening/closing, DNA binding/release, and ATP binding/hydrolysis) that yield a topologically linked clamp·DNA product in less than a second. Here, we report pre-steady-state measurements of several steps in the reaction catalyzed by Saccharomyces cerevisiae RFC and present a comprehensive kinetic model based on global analysis of the data. Highlights of the reaction mechanism are that ATP binding to RFC initiates slow activation of the clamp loader, enabling it to open PCNA (at ~2 s(-1)) and bind primer-template DNA (ptDNA). Rapid binding of ptDNA leads to formation of the RFC·ATP·PCNA(open)·ptDNA complex, which catalyzes a burst of ATP hydrolysis. Another slow step in the reaction follows ATP hydrolysis and is associated with PCNA closure around ptDNA (8 s(-1)). Dissociation of PCNA·ptDNA from RFC leads to catalytic turnover. We propose that these early and late rate-determining events are intramolecular conformational changes in RFC and PCNA that control clamp opening and closure, and that ATP binding and hydrolysis switch RFC between conformations with high and low affinities, respectively, for open PCNA and ptDNA, and thus bookend the clamp loading reaction.     

Fluorescence energy transfer between the primer and the beta subunit of the DNA polymerase III holoenzyme.

We report here our initial success in using fluorescence energy transfer to map the position of the subunits of the DNA polymerase III holoenzyme within initiation complexes formed on primed DNA. Using primers containing a fluorescent derivative 3 nucleotides from the 3'-terminus and acceptors of fluorescence energy transfer located on Cys333 of the beta subunit, a donor-acceptor distance of 65 A was measured. Coupling this distance with other information enabled us to propose a model for the positioning of beta within initiation complexes. Examination of the fluorescence properties of a labeled primer with the unlabeled beta subunit and other assemblies of DNA polymerase III holoenzyme subunits allowed us to distinguish all of the known intermediates of the holoenzyme-catalyzed reaction. Specific fluorescence changes could be assigned for primer annealing, Escherichia coli single-stranded DNA-binding protein binding, 3'----5' exonucleolytic hydrolysis of the primer, DNA polymerase III* binding, initiation complex formation upon the addition of beta in the presence of ATP, and DNA elongation. These fluorescence changes are sufficiently large to support future detailed kinetic studies. Particularly interesting was the difference in fluorescence changes accompanying initiation complex formation as compared to binding of DNA polymerase III holoenzyme subunit assemblies. Initiation complex formation resulted in a strong fluorescence enhancement. Binding of DNA polymerase III* led to a fluorescence quenching, and transfer of beta to primed DNA by the gamma delta complex did not change the fluorescence. This demonstrates a rearrangement of subunits accompanying initiation complex formation. Monitoring fluorescence changes with labeled beta, we have determined that beta binds with a stoichiometry of one monomer/primer terminus.     

Conformational dynamics of DnaB helicase upon DNA and nucleotide binding: analysis by intrinsic tryptophan fluorescence quenching

DnaB helicase of E. coli unwinds duplex DNA in the replication fork using the energy of ATP hydrolysis. We have analyzed structural and conformational changes in the DnaB protein in various nucleotides and DNA bound intermediate states by fluorescence quenching analysis of intrinsic fluorescence of native tryptophan (Trp) residues in DnaB. Fluorescence quenching analysis indicated that Trp48 in domain alpha is in a hydrophobic environment and resistant to fluorescence quenchers such as potassium iodide (KI). In domain beta, Trp294 was found to be in a partially hydrophobic environment, whereas Trp456 in domain gamma appeared to be in the least hydrophobic environment. Binding of oligonucleotides to DnaB helicase resulted in a significant attenuation of the fluorescence quenching profile, indicating a change in conformation. ATPgammaS or ATP binding appeared to lead to a conformation in which Trp residues had a higher degree of solvent exposure and fluorescence quenching. However, the most dramatic increase of Trp fluorescence quenching was observed with ADP binding with a possible conformational relaxation. Site-specific Trp --> Cys mutants of DnaB helicase demonstrated that conformational change upon ADP binding could be attributed exclusively to a conformational transition in the alpha domain leading to an increase in the solvent exposure of Trp48. However, formation of DnaB.ATPgammaS.DNA ternary complex led to a conformation with a fluorescence quenching profile similar to that observed with DnaB alone. The DnaB.ADP.DNA ternary complex produced a quenching curve similar to that of DnaB.ADP complex pointing to a change in conformation due to ATP hydrolysis. There are at least four identifiable structural/conformational states of DnaB helicase that are likely important in the helicase activity. The noncatalytic alpha domain in the N-terminus appeared to undergo the most significant conformational changes during nucleotide binding and hydrolysis. This is the first reported elucidation of the putative role of domain alpha, which is essential for DNA helicase action. We have correlated these results with partial structural models of alpha, beta, and gamma domains     

Mechanisms of conformational change for a replicative hexameric helicase of SV40 large tumor antigen

The large tumor antigen (LTag) of simian virus 40, an AAA(+) protein, is a hexameric helicase essential for viral DNA replication in eukaryotic cells. LTag functions as an efficient molecular machine powered by ATP binding and hydrolysis for origin DNA melting and replication fork unwinding. To understand how ATP binding and hydrolysis are coupled to conformational changes, we have determined high-resolution structures ( approximately 1.9 A) of LTag hexamers in distinct nucleotide binding states. The structural differences of LTag in various nucleotide states detail the molecular mechanisms of conformational changes triggered by ATP binding/hydrolysis and reveal a potential mechanism of concerted nucleotide binding and hydrolysis. During these conformational changes, the angles and orientations between domains of a monomer alter, creating an "iris"-like motion in the hexamer. Additionally, six unique beta hairpins on the channel surface move longitudinally along the central channel, possibly serving as a motor for pulling DNA into the LTag double hexamer for unwinding.     

The delta subunit of DNA polymerase III holoenzyme serves as a sliding clamp unloader in Escherichia coli

In Escherichia coli, the circular beta sliding clamp facilitates processive DNA replication by tethering the polymerase to primer-template DNA. When synthesis is complete, polymerase dissociates from beta and DNA and cycles to a new start site, a primed template loaded with beta. DNA polymerase cycles frequently during lagging strand replication while synthesizing 1-2-kilobase Okazaki fragments. The clamps left behind remain stable on DNA (t(12) approximately 115 min) and must be removed rapidly for reuse at numerous primed sites on the lagging strand. Here we show that delta, a single subunit of DNA polymerase III holoenzyme, opens beta and slips it off DNA (k(unloading) = 0.011 s(-)(1)) at a rate similar to that of the multisubunit gamma complex clamp loader by itself (0.015 s(-)(1)) or within polymerase (pol) III* (0.0065 s(-)(1)). Moreover, unlike gamma complex and pol III*, delta does not require ATP to catalyze clamp unloading. Quantitation of gamma complex subunits (gamma, delta, delta', chi, psi) in E. coli cells reveals an excess of delta, free from gamma complex and pol III*. Since pol III* and gamma complex occur in much lower quantities and perform several DNA metabolic functions in replication and repair, the delta subunit probably aids beta clamp recycling during DNA replication.