Mechanism of loading the Escherichia coli DNA polymerase III sliding clamp: I. Two distinct activities for individual ATP sites in the gamma complex

The Escherichia coli DNA polymerase III gamma complex loads the beta clamp onto DNA, and the clamp tethers the core polymerase to DNA to increase the processivity of synthesis. ATP binding and hydrolysis promote conformational changes within the gamma complex that modulate its affinity for the clamp and DNA, allowing it to accomplish the mechanical task of assembling clamps on DNA. This is the first of two reports (Snyder, A. K., Williams, C. R., Johnson, A., O'Donnell, M., and Bloom, L. B. (2004) J. Biol. Chem. 279, 4386-4393) addressing the question of how ATP binding and hydrolysis modulate specific interactions with DNA and beta. Pre-steady-state rates of ATP hydrolysis were slower when reactions were initiated by addition of ATP than when the gamma complex was equilibrated with ATP and were limited by the rate of an intramolecular reaction, possibly ATP-induced conformational changes. Kinetic modeling of assays in which the gamma complex was incubated with ATP for different periods of time prior to adding DNA to trigger hydrolysis suggests a mechanism in which a relatively slow conformational change step (kforward = 6.5 s(-1)) produces a species of the gamma complex that is activated for DNA (and beta) binding. In the absence of beta, 2 of the 3 molecules of ATP are hydrolyzed rapidly prior to releasing DNA, and the 3rd molecule is hydrolyzed slowly. In the presence of beta, all 3 molecules of ATP are hydrolyzed rapidly. These results suggest that hydrolysis of 2 molecules of ATP may be coupled to conformational changes that reduce interactions with DNA, whereas hydrolysis of the 3rd is coupled to changes that result in release of beta.     

Slow Conformational Changes in MutS and DNA Direct Ordered Transitions between Mismatch Search,Recognition and Signaling of DNA Repair

MutS functions in mismatch repair (MMR) to scan DNA for errors, identify a target site and trigger subsequent events in the pathway leading to error removal and DNA re-synthesis. These actions, enabled by the ATPase activity of MutS, are now beginning to be analyzed from the perspective of the protein itself. This study provides the first ensemble transient kinetic data on MutS conformational dynamics as it works with DNA and ATP in MMR. Using a combination of fluorescence probes (on Thermus aquaticus MutS and DNA) and signals (intensity, anisotropy and resonance energy transfer), we have monitored the timing of key conformational changes in MutS that are coupled to mismatch binding and recognition, ATP binding and hydrolysis, as well as sliding clamp formation and signaling of repair. Significant findings include (a) a slow step that follows weak initial interaction between MutS and DNA, in which concerted conformational changes in both macromolecules control mismatch recognition, and (b) rapid, binary switching of MutS conformations that is concerted with ATP binding and hydrolysis and (c) is stalled after mismatch recognition to control formation of the ATP-bound MutS sliding clamp. These rate-limiting pre- and post-mismatch recognition events outline the mechanism of action of MutS on DNA during initiation of MMR.     

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.     

Functional studies on the candidate ATPase domains of Saccharomyces cerevisiae MutLalpha

Saccharomyces cerevisiae MutL homologues Mlh1p and Pms1p form a heterodimer, termed MutLalpha, that is required for DNA mismatch repair after mismatch binding by MutS homologues. Recent sequence and structural studies have placed the NH(2) termini of MutL homologues in a new family of ATPases. To address the functional significance of this putative ATPase activity in MutLalpha, we mutated conserved motifs for ATP hydrolysis and ATP binding in both Mlh1p and Pms1p and found that these changes disrupted DNA mismatch repair in vivo. Limited proteolysis with purified recombinant MutLalpha demonstrated that the NH(2) terminus of MutLalpha undergoes conformational changes in the presence of ATP and nonhydrolyzable ATP analogs. Furthermore, two-hybrid analysis suggested that these ATP-binding-induced conformational changes promote an interaction between the NH(2) termini of Mlh1p and Pms1p. Surprisingly, analysis of specific mutants suggested differential requirements for the ATPase motifs of Mlh1p and Pms1p during DNA mismatch repair. Taken together, these results suggest that MutLalpha undergoes ATP-dependent conformational changes that may serve to coordinate downstream events during yeast DNA mismatch repair.     

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     

ATP‐dependent DNA binding,unwinding, and resection by the Mre11/Rad50 complex

ATP‐dependent DNA end recognition and nucleolytic processing are central functions of the Mre11/Rad50 (MR) complex in DNA double‐strand break repair. However, it is still unclear how ATP binding and hydrolysis primes the MR function and regulates repair pathway choice in cells. Here, Methanococcus jannaschii MR‐ATPγS‐DNA structure reveals that the partly deformed DNA runs symmetrically across central groove between two ATPγS‐bound Rad50 nucleotide‐binding domains. Duplex DNA cannot access the Mre11 active site in the ATP‐free full‐length MR complex. ATP hydrolysis drives rotation of the nucleotide‐binding domain and induces the DNA melting so that the substrate DNA can access Mre11. Our findings suggest that the ATP hydrolysis‐driven conformational changes in both DNA and the MR complex coordinate the melting and endonuclease activity.     

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.     

A human topoisomerase II alpha heterodimer with only one ATP binding site can go through successive catalytic cycles

Eukaryotic DNA topoisomerase II is a dimeric nuclear enzyme essential for DNA metabolism and chromosome dynamics. It changes the topology of DNA by coupling binding and hydrolysis of two ATP molecules to the transport of one DNA duplex through a temporary break introduced in another. During this process the structurally and functionally complex enzyme passes through a cascade of conformational changes, which requires intra- and intersubunit communication. To study the importance of ATP binding and hydrolysis in relation to DNA strand transfer, we have purified and characterized a human topoisomerase II alpha heterodimer with only one ATP binding site. The heterodimer was able to relax supercoiled DNA, although less efficiently than the wild type enzyme. It furthermore possessed a functional N-terminal clamp and was sensitive to ICRF-187. This demonstrates that human topoisomerase II alpha can pass through all the conformations required for DNA strand passage and enzyme resetting with binding and hydrolysis of only one ATP. However, the heterodimer lacked the normal stimulatory effect of DNA on ATP binding and hydrolysis as well as the stimulatory effect of ATP on DNA cleavage. The results can be explained in a model, where efficient catalysis requires an extensive communication between the second ATP and the DNA segment to be cleaved.     

Adenosine 5'-O-(3-thio)triphosphate (ATPgammaS) promotes positive supercoiling of DNA by T. maritima reverse gyrase

Reverse gyrases are topoisomerases that catalyze ATP-dependent positive supercoiling of circular covalently closed DNA. They consist of an N-terminal helicase-like domain, fused to a C-terminal topoisomerase I-like domain. Most of our knowledge on reverse gyrase-mediated positive DNA supercoiling is based on studies of archaeal enzymes. To identify general and individual properties of reverse gyrases, we set out to characterize the reverse gyrase from a hyperthermophilic eubacterium. Thermotoga maritima reverse gyrase relaxes negatively supercoiled DNA in the presence of ADP or the non-hydrolyzable ATP-analog ADPNP. Nucleotide binding is necessary, but not sufficient for the relaxation reaction. In the presence of ATP, positive supercoils are introduced at temperatures above 50 degrees C. However, ATP hydrolysis is stimulated by DNA already at 37 degrees C, suggesting that reverse gyrase is not frozen at this temperature, but capable of undergoing inter-domain communication. Positive supercoiling by reverse gyrase is strictly coupled to ATP hydrolysis. At the physiological temperature of 75 degrees C, reverse gyrase binds and hydrolyzes ATPgammaS. Surprisingly, ATPgammaS hydrolysis is stimulated by DNA, and efficiently promotes positive DNA supercoiling, demonstrating that inter-domain communication during positive supercoiling is fully functional with both ATP and ATPgammaS. These findings support a model for communication between helicase-like and topoisomerase domains in reverse gyrase, in which an ATP and DNA-induced closure of the cleft in the helicase-like domain initiates a cycle of conformational changes that leads to positive DNA supercoiling.     

The study of interactions between DNA and PcrA DNA helicase by using targeted molecular dynamic simulations

DNA helicases are important enzymes involved in all aspects of nucleic acid metabolism, ranging from DNA replication and repair to recombination, rescue of stalled replication and translation. DNA helicases are molecular motors. Through conformational changes caused by ATP hydrolysis and binding, they move along the template double helix, break the hydrogen bonds between the two strands and separate the template chains, so that the genetic information can be accessed. In this paper, targeted molecular dynamic simulations were performed to study the important interactions between DNA and PcrA DNA helicase, which can not be observed from the crystal structures. The key residues on PcrA DNA helicase that have strong interactions with both double stranded DNA (ds-DNA) and single stranded DNA (ss-DNA) have been identified, and it was found that such interactions mostly exist between the protein and DNA backbone, which indicates that the translocation of PcrA is independent of the DNA sequence. The simulations indicate that the ds-DNA is separated upon ATP rebinding, rather than ATP hydrolysis, which suggests that the two strokes in the mechanism have two different major roles. Firstly, in the power stroke (ATP hydrolysis), most of the translocations of the bases from one pocket to the next occur. In the relaxation stroke (ATP binding), most of the ‘work’ is being done to ‘melt’ the DNA at the separation fork. Therefore, we propose a mechanism whereby the translocation of the ss-DNA is powered by ATP hydrolysis and the separation of the ds-DNA is powered by ATP binding.     

Mutations in the signature motif in MutS affect ATP-induced clamp formation and mismatch repair

MutS protein dimer recognizes and co-ordinates repair of DNA mismatches. Mismatch recognition by the N-terminal mismatch recognition domain and subsequent downstream signalling by MutS appear coupled to the C-terminal ATP catalytic site, Walker box, through nucleotide-mediated conformational transitions. Details of this co-ordination are not understood. The focus of this study is a conserved loop in Escherichia coli MutS that is predicted to mediate cross-talk between the two ATP catalytic sites in MutS homodimer. Mutagenesis was employed to assess the role of this loop in regulating MutS function. All mutants displayed mismatch repair defects in vivo . Biochemical characterization further revealed defects in ATP binding, ATP hydrolysis as well as effective mismatch recognition. The kinetics of initial burst of ATP hydrolysis was similar to wild type but the magnitude of the burst was reduced for the mutants. Given its proximity to the ATP bound in the opposing monomer in the crystal and its potential analogy with signature motif of ABC transporters, the results strongly suggest that the loop co-ordinates ATP binding/hydrolysis in trans by the two catalytic sites. Importantly, our data reveal that the loop plays a direct role in co-ordinating conformational changes involved in long-range communication between Walker box and mismatch recognition domains.     

A Computational Analysis of ATP Binding of SV40 Large Tumor Antigen Helicase Motor

Simian Virus 40 Large Tumor Antigen (LTag) is an efficient helicase motor that unwinds and translocates DNA. The DNA unwinding and translocation of LTag is powered by ATP binding and hydrolysis at the nucleotide pocket between two adjacent subunits of an LTag hexamer. Based on the set of high-resolution hexameric structures of LTag helicase in different nucleotide binding states, we simulated a conformational transition pathway of the ATP binding process using the targeted molecular dynamics method and calculated the corresponding energy profile using the linear response approximation (LRA) version of the semi-macroscopic Protein Dipoles Langevin Dipoles method (PDLD/S). The simulation results suggest a three-step process for the ATP binding from the initial interaction to the final tight binding at the nucleotide pocket, in which ATP is eventually “locked” by three pairs of charge-charge interactions across the pocket. Such a “cross-locking” ATP binding process is similar to the binding zipper model reported for the F1-ATPase hexameric motor. The simulation also shows a transition mechanism of Mg²⁺ coordination to form the Mg-ATP complex during ATP binding, which is accompanied by the large conformational changes of LTag. This simulation study of the ATP binding process to an LTag and the accompanying conformational changes in the context of a hexamer leads to a refined cooperative iris model that has been proposed previously.     

Conformational changes of the multifunction p97 AAA ATPase during its ATPase cycle

p97 (also called VCP), a member of the AAA ATPase family, is involved in several cellular processes, including membrane fusion and extraction of proteins from the endoplasmic reticulum for cytoplasmic degradation. We have studied the conformational changes that p97 undergoes during the ATPase cycle by cryo-EM and single-particle analysis. Three-dimensional maps show that the two AAA domains, D1 and D2, as well as the N-domains, experience conformational changes during ATP binding, ATP hydrolysis, P(i) release and ADP release. The N-domain is flexible in most nucleotide states except after ATP hydrolysis. The rings formed by D1 and D2 rotate with respect to each other, and the size of their axial openings fluctuates. Taken together, our results depict the movements that this and possibly other AAA ATPases can undergo during an ATPase cycle.     

Contribution of human mlh1 and pms2 ATPase activities to DNA mismatch repair

MutLalpha, a heterodimer composed of Mlh1 and Pms2, is the major MutL activity in mammalian DNA mismatch repair. Highly conserved motifs in the N termini of both subunits predict that the protein is an ATPase. To study the significance of these motifs to mismatch repair, we have expressed in insect cells wild type human MutLalpha and forms altered in conserved glutamic acid residues, predicted to catalyze ATP hydrolysis of Mlh1, Pms2, or both. Using an in vitro assay, we showed that MutLalpha proteins altered in either glutamic acid residue were each partially defective in mismatch repair, whereas the double mutant showed no detectable mismatch repair. Neither strand specificity nor directionality of repair was affected in the single mutant proteins. Limited proteolysis studies of MutLalpha demonstrated that both Mlh1 and Pms2 N-terminal domains undergo ATP-induced conformational changes, but the extent of the conformational change for Mlh1 was more apparent than for Pms2. Furthermore, Mlh1 was protected at lower ATP concentrations than Pms2, suggesting Mlh1 binds ATP with higher affinity. These findings imply that ATP hydrolysis is required for MutLalpha activity in mismatch repair and that this activity is associated with differential conformational changes in Mlh1 and Pms2.     

A two-site kinetic mechanism for ATP binding and hydrolysis by E. coli Rep helicase dimer bound to a single-stranded oligodeoxynucleotide.

Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA in reactions that are coupled to ATP binding and hydrolysis. We have investigated the kinetic mechanism of ATP binding and hydrolysis by a proposed intermediate in Rep-catalyzed DNA unwinding, the Rep "P2S" dimer (formed with the single-stranded (ss) oligodeoxynucleotide, (dT)16), in which only one subunit of a Rep homo-dimer is bound to ssDNA. Pre-steady-state quenched-flow studies under both single turnover and multiple turnover conditions as well as fluorescence stopped-flow studies were used (4 degrees C, pH 7.5, 6 mM NaCl, 5 mM MgCl2, 10 % (v/v) glycerol). Although steady-state studies indicate that a single ATPase site dominates the kinetics (kcat=17(+/-2) s-1; KM=3 microM), pre-steady-state studies provide evidence for a two-ATP site mechanism in which both sites of the dimer are catalytically active and communicate allosterically. Single turnover ATPase studies indicate that ATP hydrolysis does not require the simultaneous binding of two ATP molecules, and under these conditions release of product (ADP-Pi) is preceded by a slow rate-limiting isomerization ( approximately 0.2 s-1). However, product (ADP or Pi) release is not rate-limiting under multiple turnover conditions, indicating the involvement of a second ATP site under conditions of excess ATP. Stopped-flow fluorescence studies monitoring ATP-induced changes in Rep's tryptophan fluorescence displayed biphasic time courses. The binding of the first ATP occurs by a two-step mechanism in which binding (k+1=1.5(+/-0.2)x10(7) M-1 s-1, k-1=29(+/-2) s-1) is followed by a protein conformational change (k+2=23(+/-3) s-1), monitored by an enhancement of Trp fluorescence. The second Trp fluorescence quenching phase is associated with binding of a second ATP. The first ATP appears to bind to the DNA-free subunit and hydrolysis induces a global conformational change to form a high energy intermediate state with tightly bound (ADP-Pi). Binding of the second ATP then leads to the steady-state ATP cycle. As proposed previously, the role of steady-state ATP hydrolysis by the DNA-bound Rep subunit may be to maintain the DNA-free subunit in an activated state in preparation for binding a second fragment of DNA as needed for translocation and/or DNA unwinding. We propose that the roles of the two ATP sites may alternate upon binding DNA to the second subunit of the Rep dimer during unwinding and translocation using a subunit switching mechanism.     

Hindering the strand passage reaction of human topoisomerase IIalpha without disturbing DNA cleavage, ATP hydrolysis, or the operation of the N-terminal clamp

DNA topoisomerase II is an essential enzyme that releases a topological strain in DNA by introduction of transient breaks in one DNA helix through which another helix is passed. While changing DNA topology, ATP is required to drive the enzyme through a series of conformational changes dependent on interdomain communication. We have characterized a human topoisomerase IIalpha enzyme with a two-amino acid insertion at position 351 in the transducer domain. The mutation specifically abolishes the DNA strand passage event of the enzyme, probably because of a sterical hindrance of T-segment transport. Thus, the enzyme fails to decatenate and relax DNA, even though it is fully capable of ATP hydrolysis, closure of the N-terminal clamp, and DNA cleavage. The cleavage activity is increased, suggesting that the transducer domain has a role in regulating DNA cleavage. Furthermore, the enzyme has retained a tendency to increase DNA cleavage upon nucleotide binding and also responds to DNA with elevated ATP hydrolysis. However, the DNA-mediated increase in ATP hydrolysis is lower than that obtained with the wild-type enzyme but similar to that of a cleavage-deficient topoisomerase IIalpha enzyme. Our results strongly suggest that the strand passage event is required for efficient DNA stimulation of topoisomerase II-mediated ATP hydrolysis, whereas the stimulation occurs independent of the DNA cleavage reaction per se. A comparison of the strand passage deficient-enzyme described here and the cleavage-deficient enzyme may have applications in other studies where a clear distinction between strand passage and topoisomerase II-mediated DNA cleavage is desirable.     

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.