Essential amino acids of Escherichia coli DnaC protein in an N-terminal domain interact with DnaB helicase

Escherichia coli DnaC protein bound to ATP forms a complex with DnaB protein. To identify the domain of DnaC that interacts with DnaB, a genetic selection was used based on the lethal effect of induced dnaC expression and a model that inviability arises by the binding of DnaC to DnaB to inhibit replication fork movement. The analysis of dnaC alleles that preserved viability under elevated expression revealed an N-terminal domain of DnaC involved in binding to DnaB. Mutant proteins bearing single amino acid substitutions (R10P, L11Q, L29Q, S41P, W32G, and L44P) that reside in regions of predicted secondary structure were inert in DNA replication activity because of their inability to bind to DnaB, but they retained ATP binding activity, as indicated by UV cross-linking to [alpha-(32)P]ATP. These alleles also failed to complement a dnaC28 mutant. Other selected mutations that map to regions carrying Walker A and B boxes are expected to be defective in ATP binding, a required step in DnaB-DnaC complex formation. Lastly, we found that the sixth codon from the N terminus encodes aspartate, resolving a reported discrepancy between the predicted amino acid sequence based on DNA sequencing data and the results from N-terminal amino acid sequencing (Nakayama, N., Bond, M. W., Miyajima, A., Kobori, J., and Arai, K. (1987) J. Biol. Chem. 262, 10475-10480).     

Quantitative analysis of binding of single-stranded DNA by Escherichia coli DnaB helicase and the DnaB x DnaC complex

DnaB helicase is responsible for unwinding duplex DNA during chromosomal DNA replication and is an essential component of the DNA replication apparatus in Escherichia coli. We have analyzed the mechanism of binding of single-stranded DNA (ssDNA) by the DnaB x DnaC complex and DnaB helicase. Binding of ssDNA to DnaB helicase was significantly modulated by nucleotide cofactors, and the modulation was distinctly different for its complex with DnaC. DnaB helicase bound ssDNA with a high affinity [Kd = (5.09 +/- 0.32) x 10(-8) M] only in the presence of ATPgammaS, a nonhydrolyzable analogue of ATP, but not other nucleotides. The binding was sensitive to ionic strength but not to changes in temperature in the range of 30-37 degrees C. On the other hand, ssDNA binding in the presence of ADP was weaker than that observed with ATPgammaS, and the binding was insensitive to ionic strength. DnaC protein hexamerizes to form a 1:1 complex with the DnaB hexamer and loads it onto the ssDNA by forming a DnaB6 x DnaC6 dodecameric complex. Our results demonstrate that the DnaB6 x DnaC6 complex bound ssDNA with a high affinity [Kd = (6.26 +/- 0.65) x 10(-8) M] in the presence of ATP, unlike the DnaB hexamer. In the presence of ATPgammaS or ADP, binding of ssDNA by the DnaB6 x DnaC6 complex was a lower-affinity process. In summary, our results suggest that in the presence of ATP in vivo, the DnaB6 x DnaC6 complex should be more efficient in binding DNA as well as in loading DnaB onto the ssDNA than DnaB helicase itself.     

Replication initiation at the Escherichia coli chromosomal origin

To initiate DNA replication, DnaA recognizes and binds to specific sequences within the Escherichia coli chromosomal origin (oriC), and then unwinds a region within oriC. Next, DnaA interacts with DnaB helicase in loading the DnaB-DnaC complex on each separated strand. Primer formation by primase (DnaG) induces the dissociation of DnaC from DnaB, which involves the hydrolysis of ATP bound to DnaC. Recent evidence indicates that DnaC acts as a checkpoint in the transition from initiation to the elongation stage of DNA replication. Freed from DnaC, DnaB helicase unwinds the parental duplex DNA while interacting the cellular replicase, DNA polymerase III holoenzyme, and primase as it intermittently forms primers that are extended by the replicase in duplicating the chromosome.     

Interactions of the Escherichia coli DnaB helicase hexamer with the replication factor the DnaC protein. Effect of nucleotide cofactors and the ssDNA on protein-protein interactions and the topology of the complex

Quantitative studies of interactions between the Escherichia coli replication factor DnaC protein and the DnaB helicase have been performed using sedimentation velocity and fluorescence energy transfer techniques. The applied novel analysis of the sedimentation data allows us to construct thermodynamic rigorous binding isotherms without any assumption as to the relationship between the observed molecular property of the complexes formed, the average sedimentation coefficient, or the degree of binding. Experiments have been performed with the fluorescein-modified DnaB helicase, which allows an exclusive monitoring of the DnaB-DnaC complex formation. The DnaC binding to the unmodified helicase has been characterized in competition experiments. The data establish that, in the presence of the ATP analog AMP-PNP, or ADP, a maximum of six DnaC monomers bind cooperatively to the DnaB hexamer. The positive cooperative interactions are limited to the two neighboring DnaC molecules. Analyses using a statistical thermodynamic hexagon model indicate that, under the solution conditions examined, the affinity is characterized by the intrinsic binding constant K=1.4(+/-0.5)x10(5)M(-1) and cooperativity parameter sigma=21+/-5. These data suggest strongly that the DnaC-DnaB complex exists in vivo as a mixture of complexes with a different number of bound DnaC molecules, although the complex with six DnaC molecules bound dominates the distribution. The DnaC nucleotide-binding site is not involved in the stabilization of the complex. Moreover, the hydrolysis of NTP bound to the helicase or the DnaC is not required for the release of the DnaC protein from the complex. The single-stranded DNA (ssDNA) bound to the helicase does not affect the DnaC protein binding. However, in the presence of the DNA, there is a significant difference in the energetics and structure of the ternary complex, DnaC-DnaB-ssDNA, formed in the presence of AMP-PNP as compared to ADP. The topology of the ternary complex DnaC-DnaB-ssDNA has been determined using the fluorescence energy transfer method. In solution, the DnaC protein-binding site is located on the large 33 kDa domain of the DnaB helicase. The significance of the results in the functioning of the DnaB helicase-DnaC protein complex is discussed.     

The DnaC helicase loader is a dual ATP/ADP switch protein

Helicases are transferred to replication origins by helicase loading factors. The Escherichia coli DnaC and eukaryotic Cdc6/18 helicase loaders contain ATP sites and are both members of the AAA+ family. One might expect that ATP is required for helicase loading; however, this study on DnaC illustrates that ATP is not actually needed for DnaC to load helicase onto single-strand DNA (ssDNA). In fact, it seems to be a paradox that after transfer of helicase to DNA, DnaC-ATP inhibits helicase action. In addition, ATP is required for DnaC function at an early step in oriC replication in which ATP stimulates ssDNA binding by DnaC, leading to expansion of the ssDNA bubble at the origin. Two cofactors, ssDNA and DnaB, trigger hydrolysis of ATP, converting DnaC to the ADP form that no longer inhibits DnaB. These observations have led to the idea that DnaC is a 'dual' switch protein, where both the ATP and the ADP forms are sequentially required for replication. This dual switching process may underlie the sensitivity of DnaB to even small fluctuations in DnaC levels.     

The speed of the Escherichia coli fork in vivo depends on the DnaB:DnaC ratio

The DnaC protein is required for loading the DnaB helicase at oriC . Thus DnaC promotes the formation of the pre-replication complex, but must leave the complex in order for the DnaB protein to function as a helicase. In vitro , a slight excess of DnaC inhibits the movement of replication forks by inhibiting DnaB helicase activity (Allen and Kornberg, 1991). Here we show that inhibition of DNA replication by excess DnaC also occurs in vivo . The rate of replication-fork movement was measured by flow cytometry. Initiation of replication was inhibited with rifampicin and the rate of fork movement monitored during replication run-out by measuring the increase in the fraction of the cell population with fully replicated chromosomes. The replication rate was inversely related to the amount of excess DnaC protein. Initiation of replication was also inhibited. Co-overexpression of DnaB protein alleviated the inhibition of replication caused by moderate excess of DnaC. The results show that DnaC interacts with replication forks during elongation in vivo , probably by binding to DnaB and inhibiting its helicase activity. Therefore, the ratio of DnaC to DnaB and the affinity of DnaC for a helicase hexamer at an established replication fork are of great importance for the rate of replication fork movement also in vivo .     

A two-protein strategy for the functional loading of a cellular replicative DNA helicase

The delivery of a ring-shaped hexameric helicase onto DNA is a fundamental step of DNA replication, conserved in all cellular organisms. We report the biochemical characterization of the bacterial hexameric replicative helicase DnaC of Bacillus subtilis with that of the two replication initiation proteins DnaI and DnaB. We show that DnaI and DnaB interact physically and functionally with the DnaC helicase and mediate its functional delivery onto DNA. Thus, DnaB and DnaI form a pair of helicase loaders, revealing a two-protein strategy for the loading of a replicative helicase. We also present evidence that the DnaC helicase loading mechanism appears to be of the ring-assembly type, proceeding through the recruitment of DnaC monomers and their hexamerization around single-stranded DNA by the coordinated action of DnaI and DnaB.     

Escherichia coli DnaA protein loads a single DnaB helicase at a DnaA box hairpin

The molecular engine that drives bidirectional replication fork movement from the Escherichia coli replication origin (oriC) is the replicative helicase, DnaB. At oriC, two and only two helicase molecules are loaded, one for each replication fork. DnaA participates in helicase loading; DnaC is also involved, because it must be in a complex with DnaB for delivery of the helicase. Since DnaA induces a local unwinding of oriC, one model is that the limited availability of single-stranded DNA at oriC restricts the number of DnaB molecules that can bind. In this report, we determined that one DnaB helicase or one DnaB-DnaC complex is bound to a single-stranded DNA in a biologically relevant DNA replication system. These results indicate that the availability of single-stranded DNA is not a limiting factor and support a model in which the site of entry for DnaB is altered so that it cannot be reused. We also show that 2-4 DnaA monomers are bound on the single-stranded DNA at a specific site that carries a DnaA box sequence in a hairpin structure.     

The DnaB.DnaC complex: a structure based on dimers assembled around an occluded channel

Replicative helicases are motor proteins that unwind DNA at replication forks. Escherichia coli DnaB is the best characterized member of this family of enzymes. We present the 26 A resolution three-dimensional structure of the DnaB hexamer in complex with its loading partner, DnaC, obtained from cryo-electron microscopy. Analysis of the volume brings insight into the elaborate way the two proteins interact, and provides a structural basis for control of the symmetry state and inactivation of the helicase by DnaC. The complex is arranged on the basis of interactions among DnaC and DnaB dimers. DnaC monomers are observed for the first time to arrange as three dumb-bell-shaped dimers that interlock into one of the faces of the helicase. This could be responsible for the freezing of DnaB in a C(3) architecture by its loading partner. The central channel of the helicase is almost occluded near the end opposite to DnaC, such that even single-stranded DNA could not pass through. We propose that the DnaB N-terminal domain is located at this face.     

Functional interplay between the Bacillus subtilis DnaD and DnaB proteins essential for initiation and re-initiation of DNA replication

Initiation and re-initiation of chromosomal DNA replication in bacteria rely on divergent multiprotein assemblies, which direct the functional delivery of the replicative helicase on single-stranded DNA (ssDNA) at specific sites. These two processes are triggered either at the single chromosomal origin oriC or at arrested forks by the conserved DnaA and PriA proteins respectively. In Bacillus subtilis, these two pathways further require the three essential proteins DnaB, DnaD and DnaI, restrictively encoded in Gram positive bacteria of low GC content. We have recently shown that DnaI and DnaB act as a pair of loaders of the DnaC replicative helicase. The role of DnaD appeared more enigmatic. It was previously shown to interact with DnaA and to display weak ssDNA binding activity. Here, we report that purified DnaD can interact physically with PriA and with DnaB. We show that the lethality of the temperature-sensitive dnaD23 mutant can be suppressed by different DnaB point mutants, which were found to be identical to the suppressors of priA null mutants. The DnaD23 protein displays lower ssDNA binding activity than DnaD. Conversely, the DnaB75 protein, the main dnaD23 suppressor, has gained affinity for ssDNA. Finally, we observed that this interplay between DnaD and DnaB is crucial for their concerted interaction with SSB-coated ssDNA, which is the expected substrate for the loading of the replicative helicase in vivo. Altogether, these results highlight the need for both DnaD and DnaB to interact individually and together with ssDNA during the early stages of initiation and re-initiation of chromosomal DNA replication. They also point at a main structural role of DnaD in the multiprotein assemblies built during these two essential processes.     

Mechanism and stoichiometry of interaction of DnaG primase with DnaB helicase of Escherichia coli in RNA primer synthesis

Initiation and synthesis of RNA primers in the lagging strand of the replication fork in Escherichia coli requires the replicative DnaB helicase and the DNA primase, the DnaG gene product. In addition, the physical interaction between these two replication enzymes appears to play a role in the initiation of chromosomal DNA replication. In vitro, DnaB helicase stimulates primase to synthesize primers on single-stranded (ss) oligonucleotide templates. Earlier studies hypothesized that multiple primase molecules interact with each DnaB hexamer and single-stranded DNA. We have examined this hypothesis and determined the exact stoichiometry of primase to DnaB hexamer. We have also demonstrated that ssDNA binding activity of the DnaB helicase is necessary for directing the primase to the initiator trinucleotide and synthesis of 11-20-nucleotide long primers. Although, association of these two enzymes determines the extent and rate of synthesis of the RNA primers in vitro, direct evidence of the formation of primase-DnaB complex has remained elusive in E. coli due to the transient nature of their interaction. Therefore, we stabilized this complex using a chemical cross-linker and carried out a stoichiometric analysis of this complex by gel filtration. This allowed us to demonstrate that the primase-helicase complex of E. coli is comprised of three molecules of primase bound to one DnaB hexamer. Fluorescence anisotropy studies of the interaction of DnaB with primase, labeled with the fluorescent probe Ru(bipy)3, and Scatchard analysis further supported this conclusion. The addition of DnaC protein, leading to the formation of the DnaB-DnaC complex, to the simple priming system resulted in the synthesis of shorter primers. Therefore, interactions of the DnaB-primase complex with other replication factors might be critical for determining the physiological length of the RNA primers in vivo and the overall kinetics of primer synthesis.     

DNA Structure Specificity Conferred on a Replicative Helicase by Its Loader

Prokaryotic and eukaryotic replicative helicases can translocate along single-stranded and double-stranded DNA, with the central cavity of these multimeric ring helicases being able to accommodate both forms of DNA. Translocation by such helicases along single-stranded DNA results in the unwinding of forked DNA by steric exclusion and appears critical in unwinding of parental strands at the replication fork, whereas translocation over double-stranded DNA has no well-defined role. We have found that the accessory factor, DnaC, that promotes loading of the Escherichia coli replicative helicase DnaB onto single-stranded DNA may also act to confer DNA structure specificity on DnaB helicase. When present in excess, DnaC inhibits DnaB translocation over double-stranded DNA but not over single-stranded DNA. Inhibition of DnaB translocation over double-stranded DNA requires the ATP-bound form of DnaC, and this inhibition is relieved during translocation over single-stranded DNA indicating that stimulation of DnaC ATPase is responsible for this DNA structure specificity. These findings demonstrate that DnaC may provide the DNA structure specificity lacking in DnaB, limiting DnaB translocation to bona fide replication forks. The ability of other replicative helicases to translocate along single-stranded and double-stranded DNA raises the possibility that analogous regulatory mechanisms exist in other organisms.     

Host virus interactions in the initiation of bacteriophage lambda DNA replication. Recruitment of Escherichia coli DnaB helicase by lambda P replication protein

The bacteriophage lambda P protein promoters replication of the phage chromosome by recruiting a key component of the cellular replication machinery to the viral origin. Specifically, P protein delivers one or more molecules of Escherichia coli DnaB helicase to a nucleoprotein structure formed by the lambda O initiator at the lambda replication origin. Using purified proteins, we have examined the features of the pivotal host virus interaction between P and DnaB. These two proteins interact in vitro to form a P.DnaB protein complex that can be resolved by sedimentation or by chromatography on DEAE-cellulose from the individual free proteins. The sedimentation coefficient of the P.DnaB complex, 13 S, suggests a size larger than that of free DnaB hexamer (Mr = 313,600). The P.DnaB complex isolated by glycerol gradient sedimentation contains approximately three protomers of P/DnaB hexamer, consistent with a molecular weight of 393,000. The isolated P.DnaB complex functions in vitro in the initiation of lambda DNA replication. Interaction of P with DnaB strongly suppressed both the intrinsic DNA-dependent ATPase activity of DnaB, as well as the capacity of DnaB to assist E. coli primase in the general priming reaction. Formation of a P.DnaB protein complex also blocked DnaB from functioning in the initiation of E. coli DNA replication in vitro. The physical and functional properties of lambda P protein suggest that it is a viral analogue of the E. coli DnaC replication protein. Like P, DnaC also binds to DnaB (Wickner, S., and Hurwitz, J. (1975) Proc. Natl. Acad. Sci. U. S. A. 72, 921-925), but unlike P, DnaC stimulates DnaB-mediated general priming. When viral P and bacterial DnaC replication proteins were placed in direct competition with one another for binding to DnaB, the viral protein was clearly predominant. For example, a 5-fold molar excess of DnaC protein only partially reversed the inhibitory effect of P on general priming. Furthermore, when a preformed DnaC.DnaB protein complex was incubated briefly with P protein, it was readily converted into a P.DnaB protein complex and the bulk of the bound DnaC was released as free protein. It is likely that the capacity of the lambda P protein to outcompete the analogous host protein for binding to the bacterial DnaB helicase is the critical molecular event enabling infecting phage to recruit cellular replication proteins required for initiation of DNA synthesis at the viral origin.     

pH-controlled quaternary states of hexameric DnaB helicase

DnaB is the major helicase in the Escherichia coli replisome. It is a homohexameric enzyme that interacts with many other replisomal proteins and cofactors. It is usually loaded onto a single strand of DNA at origins of replication from its complex with its loading partner DnaC, then translocates in the 5' to 3' direction, unwinding duplex DNA in an NTP-driven process. Quaternary polymorphism has been described for the DnaB oligomer, a feature it has in common with some other hexameric helicases. In the present work, electron microscopy and in- depth rotational analysis studies of negatively stained specimens has allowed the establishment of conditions that govern the transition between the two different rotational symmetry states (C(3) and C(6)) of DnaB. It is shown: (a) that the pH value of the sample buffer, within the physiological range, dictates the quaternary organisation of the DnaB oligomer; (b) that the pH-induced transition is fully reversible; (c) that the type of adenine nucleotide complexed to DnaB, whether hydrolysable or not, does not affect its quaternary architecture; (d) that the DnaB.DnaC complex exists only as particles with C(3) symmetry; and (e) that DnaC interacts only with DnaB particles that have C(3) symmetry. Structural consequences of this quaternary polymorphism, as well as its functional implications for helicase activity, are discussed.     

‘Modulation of the enzymatic activities of replicative helicase (DnaB) by interaction with Hp0897: a possible mechanism for helicase loading in Helicobacter pylori’

DNA replication in Helicobacter pylori is initiated from a unique site (oriC) on its chromosome where several proteins assemble to form a functional replisome. The assembly of H. pylori replication machinery is similar to that of the model gram negative bacterium Escherichia coli except for the absence of DnaC needed to recruit the hexameric DnaB helicase at the replisome assembly site. In the absence of an obvious DnaC homologue in H. pylori, the question arises as to whether HpDnaB helicase is loaded at the Hp-replication origin by itself or is assisted by other unidentified protein(s). A high-throughput yeast two-hybrid study has revealed two proteins of unknown functions (Hp0897 and Hp0340) that interact with HpDnaB. Here we demonstrate that Hp0897 interacts with HpDnaB helicase in vitro as well as in vivo. Furthermore, the interaction stimulates the DNA binding activity of HpDnaB and modulates its adenosine triphosphate hydrolysis and helicase activities significantly. Prior complex formation of Hp0897 and HpDnaB enhances the binding/loading of DnaB onto DNA. Hp0897, along with HpDnaB, colocalizes with replication complex at initiation but does not move with the replisome during elongation. Together, these results suggest a possible role of Hp0897 in loading of HpDnaB at oriC.     

Global conformation of the Escherichia coli replication factor DnaC protein in absence and presence of nucleotide cofactors

Global conformational and oligomeric states of the Escherichia coli replicative factor DnaC protein in the absence and presence of magnesium and nucleotide cofactors, ATP and ADP, and their fluorescent analogues, MANT-ATP and MANT-ADP, have been examined using analytical sedimentation velocity and time-dependent fluorescence anisotropy techniques. In solution, the DnaC protein exists exclusively as a monomer over a large protein concentration range. The value of s(degrees) (20, w)= 2.45 +/- 0.07 S indicates that the protein molecule has an elongated shape. When modeled as a prolate ellipsoid of revolution, the hydrated DnaC protein has an axial ratio of 4.0 +/- 0.6 with long axis a = 112 A and the short axis b = 28 A, respectively. The presence of magnesium or nucleotide cofactors, ATP or ADP, does not affect the global conformation of the protein and its monomeric state. These data indicate that recently found cooperative interactions between the DnaC molecules, in the complex with the DnaB helicase, are induced by the binding to the helicase, i.e., they are not the intrinsic property of the DnaC protein. Fluorescence anisotropy decays of the DnaC-MANT-ATP and DnaC-MANT-ADP complexes indicate that the protein has a rigid global structure on the nanosecond time scale, little affected by the nucleotide cofactors. Nevertheless, the complex with ATP has a more flexible structure, while the complex with ADP is more rigid, with the protein molecule assuming a more elongated shape. Magnesium exerts control only on the complex with the ATP analogue. In the absence of magnesium, the ATP analogue is firmly held in the binding site. In the presence of Mg(2+), this fixed location is released and the analogue is allowed to assume a flexible conformational state. The significance of the results for the functioning of the DnaC protein is discussed.     

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     

Molecular Interplay between the Replicative Helicase DnaC and Its Loader Protein DnaI from Geobacillus kaustophilus

Helicase loading factors are thought to transfer the hexameric ring-shaped helicases onto the replication fork during DNA replication. However, the mechanism of helicase transfer onto DNA remains unclear. In Bacillus subtilis, the protein DnaI, which belongs to the AAA+ family of ATPases, is responsible for delivering the hexameric helicase DnaC onto DNA. Here we investigated the interaction between DnaC and DnaI from Geobacillus kaustophilus HTA426 (GkDnaC and GkDnaI, respectively) and determined that GkDnaI forms a stable complex with GkDnaC with an apparent stoichiometry of GkDnaC₆-GkDnaI₆ in the absence of ATP. Surface plasmon resonance analysis indicated that GkDnaI facilitates loading of GkDnaC onto single-stranded DNA (ssDNA) and supports complex formation with ssDNA in the presence of ATP. Additionally, the GkDnaI C-terminal AAA+ domain alone could bind ssDNA, and binding was modulated by nucleotides. We also determined the crystal structure of the C-terminal AAA+ domain of GkDnaI in complex with ADP at 2.5 Å resolution. The structure not only delineates the binding of ADP in the expected Walker A and B motifs but also reveals a positively charged region that may be involved in ssDNA binding. These findings provide insight into the mechanism of replicative helicase loading onto ssDNA.     

Functional characterization of Helicobacter pylori DnaB helicase

Helicobacter pylori causes gastric ulcer diseases and gastric adenocarcinoma in humans. Not much is known regarding DNA replication in H.pylori that is important for cell survival. Here we report the cloning, expression and characterization of H.pylori DnaB (HpDnaB) helicase both in vitro and in vivo. Among the DnaB homologs, only Escherichia coli DnaB has been studied extensively. HpDnaB showed strong 5′ to 3′ helicase and ATPase activity. Interestingly, H.pylori does not have an obvious DnaC homolog which is essential for DnaB loading on the E.coli chromosomal DNA replication origin (oriC). However, HpDnaB can functionally complement the E.coli DnaB temperature-sensitive mutant at the non-permissive temperature, confirming that HpDnaB is a true replicative helicase. Escherichia coli DnaC co-eluted in the same fraction with HpDnaB following gel filtration analysis suggesting that these proteins might physically interact with each other. It is possible that a functional DnaC homolog is present in H.pylori. The complete characterization of H.pylori DnaB helicase will also help the comparative analysis of DnaB helicases among bacteria.     

Regulation of minichromosome maintenance helicase activity by Cdc6

Genetic studies, together with amino acid and structural similarities to the clamp loaders of DNA polymerase sliding clamps, have suggested that the Cdc6 protein may function as a loader for the eukaryotic replicative helicase, the minichromosome maintenance (MCM) complex. Thus, Cdc6 may act as the functional homologue of the bacterial DnaC that utilizes ATP hydrolysis to assemble the DnaB helicase at the origin. This report shows that the helicase activity of an MCM homologue from the archaeon Methanothermobacter thermautotrophicus is inhibited in the presence of the Cdc6 homologues. This inhibitory activity is dependent, as for DnaC, on ATP binding to Cdc6. Moreover, an intact Cdc6 winged helix domain is required for efficient inhibition. Two-hybrid analyses indicated that MCM and Cdc6 interact and that the interaction is mediated by the winged helix domain. Analysis of Cdc6 and MCM homologues from several archaea exhibited differences in the inhibitory activity suggesting divergence in function in Cdc6 and MCM homologues among the archaea.