Ordered assembly of nucleoprotein structures at the bacteriophage lambda replication origin during the initiation of DNA replication

Replication of the chromosome of bacteriophage lambda depends on the cooperative action of two phage-coded proteins and seven replication and heat shock proteins from its Escherichia coli host. As previously described, the first stage in this process is the binding of multiple copies of the lambda O initiator to the lambda replication origin (ori lambda) to form the nucleosomelike O-some. The O-some serves to localize subsequent protein-protein and protein-DNA interactions involved in the initiation of lambda DNA replication to ori lambda. To study these interactions, we have developed a sensitive immunoblotting protocol that permits the protein constituents of complex nucleoprotein structures to be identified. Using this approach, we have defined a series of sequential protein assembly and protein disassembly events that occur at ori lambda during the initiation of lambda DNA replication. A second-stage ori lambda.O (lambda O protein).P (lambda P protein).DnaB nucleoprotein structure is formed when O, P, and E. coli DnaB helicase are incubated with ori lambda DNA. In a third-stage reaction the E. coli DnaJ heat shock protein specifically binds to the second-stage structure to form an ori lambda.O.P.DnaB.DnaJ complex. Each of the nucleoprotein structures formed in the first three stages was isolated and shown to be a physiological intermediate in the initiation of lambda DNA replication. The E. coli DnaK heat shock protein can bind to any of these early stage nucleoprotein structures, and in a fourth-stage reaction a complete ori lambda.O.P.DnaB.DnaJ.DnaK initiation complex is assembled. Addition of ATP to the reaction enables the DnaK and DnaJ heat shock proteins to mediate a partial disassembly of the fourth-stage complex. These protein disassembly reactions activate the intrinsic helicase activity of DnaB and result in localized unwinding of the ori lambda template. The protein disassembly reactions are described in the accompanying articles.     

Specialized nucleoprotein structures at the origin of replication of bacteriophage lambda. Protein association and disassociation reactions responsible for localized initiation of replication

Binding of the O protein of phage lambda to the replication origin (ori lambda) results in the formation of an organized nucleoprotein structure termed the O-some. The O-some serves to localize and initiate a six-protein sequential reaction that provides for localized unwinding of the origin region, the critical prepriming step for precise initiation of DNA replication. By the use of electron microscopy of gold-tagged antibody complexes, we have defined four stages of protein association and dissociation reactions that are involved in the prepriming pathway. First, as defined previously, O protein binds to multiple DNA sites and self-associates to form the O-some. Second, lambda P and host DnaB proteins add to the O-some to generate an O.P.DnaB.ori lambda complex. Addition of the DnaK and DnaJ proteins yields a third stage complex containing DnaK, DnaJ, O, P, and DnaB. With the addition of ATP and single-strand binding protein (SSB), the P protein is largely removed, and the DnaB acts as a helicase to generate locally unwound, SSB-coated single strand DNA. Thus, the initiation of lambda DNA replication requires ordered assembly and partial disassembly of specialized nucleoprotein structures. The disassembly activity of DnaK and DnaJ may be their general role in the heat shock response.     

Heat shock protein-mediated disassembly of nucleoprotein structures is required for the initiation of bacteriophage lambda DNA replication

Three Escherichia coli heat shock proteins, DnaJ, DnaK, and GrpE, are required for replication of the bacteriophage lambda chromosome in vivo. We show that the GrpE heat shock protein is not required for initiation of lambda DNA replication in vitro when the concentration of DnaK is sufficiently high. GrpE does, however, greatly potentiate the action of DnaK in the initiation process when the DnaK concentration is reduced to a subsaturating level. We demonstrate in the accompanying articles (Alfano, C. and McMacken, R. (1989) J. Biol. Chem. 264, 10699-10708; Dodson, M., McMacken, R., and Echols, H. (1989) J. Biol. Chem. 264, 10719-10725) that DnaJ and DnaK bind to prepriming nucleoprotein structures that are assembled at the lambda replication origin (ori lambda). Binding of DnaJ and DnaK completes the ordered assembly of an ori lambda initiation complex that also contains the lambda O and P initiators and the E. coli DnaB helicase. With the addition of ATP, the DnaJ and DnaK heat shock proteins mediate the partial disassembly of the initiation complex, and the P and DnaJ proteins are largely removed from the template. Concomitantly, on supercoiled ori lambda plasmid templates, the intrinsic helicase activity of DnaB is activated and DnaB initiates localized unwinding of the DNA duplex, thereby preparing the template for priming and DNA chain elongation. We infer from our results that DnaK and DnaJ function in normal E. coli metabolism to promote ATP-dependent protein unfolding and disassembly reactions. We also provide evidence that neither the lambda O and P initiators nor the E. coli DnaJ and DnaK heat shock proteins play a direct role in the propagation of lambda replication forks in vitro.     

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.     

Initiation of lambda DNA replication with purified host- and bacteriophage-encoded proteins: the role of the dnaK, dnaJ and grpE heat shock proteins.

Based on previous in vivo genetic analysis of bacteriophage lambda growth, we have developed two in vitro lambda DNA replication systems composed entirely of purified proteins. One is termed 'grpE-independent' and consists of supercoiled lambda dv plasmid DNA, the lambda O and lambda P proteins, as well as the Escherichia coli dnaK, dnaJ, dnaB, dnaG, ssb, DNA gyrase and DNA polymerase III holoenzyme proteins. The second system includes the E.coli grpE protein and is termed 'grpE-dependent'. Both systems are specific for plasmid molecules carrying the ori lambda DNA initiation site. The major difference in the two systems is that the 'grpE-independent' system requires at least a 10-fold higher level of dnaK protein compared with the grpE-dependent one. The lambda DNA replication process may be divided into several discernible steps, some of which are defined by the isolation of stable intermediates. The first is the formation of a stable ori lambda-lambda O structure. The second is the assembly of a stable ori lambda-lambda O-lambda P-dnaB complex. The addition of dnaJ to this complex also results in an isolatable intermediate. The dnaK, dnaJ and grpE proteins destabilize the lambda P-dnaB interaction, thus liberating dnaB's helicase activity, resulting in unwinding of the DNA template. At this stage, a stable DNA replication intermediate can be isolated, provided that the grpE protein has acted and/or is present. Following this, the dnaG primase enzyme recognizes the single-stranded DNA-dnaB complex and synthesizes RNA primers. Subsequently, the RNA primers are extended into DNA by DNA polymerase III holoenzyme. The proposed model of the molecular series of events taking place at ori lambda is substantiated by the many demonstrable protein-protein interactions among the various participants.     

DnaB helicase activity is modulated by DNA geometry and force

The replicative helicase for Escherichia coli is DnaB, a hexameric, ring-shaped motor protein that encircles and translocates along ssDNA, unwinding dsDNA in advance of its motion. The microscopic mechanisms of DnaB are unknown; further, prior work has found that DnaB's activity is modified by other replication proteins, indicating some mechanistic flexibility. To investigate these issues, we quantified translocation and unwinding by single DnaB molecules in three tethered DNA geometries held under tension. Our data support the following conclusions: 1), Unwinding by DnaB is enhanced by force-induced destabilization of dsDNA. 2), The magnitude of this stimulation varies with the geometry of the tension applied to the DNA substrate, possibly due to interactions between the helicase and the occluded ssDNA strand. 3), DnaB unwinding and (to a lesser extent) translocation are interrupted by pauses, which are also dependent on force and DNA geometry. 4), DnaB moves slower when a large tension is applied to the helicase-bound strand, indicating that it must perform mechanical work to compact the strand against the applied force. Our results have implications for the molecular mechanisms of translocation and unwinding by DnaB and for the means of modulating DnaB activity.     

Initiation protein induced helix destabilization at the lambda origin: a prepriming step in DNA replication

The interaction of the lambda phage initiator protein, O, with the lambda origin sequence, ori, has been investigated. Binding of O, or its amino-terminal fragment, causes a major structural change within a 60 bp AT-rich region just to the right of the O-binding site. ATP or other molecular energy sources are not required. The modification, as assayed by nuclease sensitivity, is reduced when certain ori mutant sequences, which bind O but fail to replicate, are substituted for the wild-type sequence. The modification of DNA structure caused by the interaction of O is absolutely dependent on the presence of superhelical tension at the lambda origin sequence, and has several properties consistent with a strand separation reaction. We propose that this modification is a fundamental prepriming event that is the first stage in initiation of bidirectional replication in lambda after O binding.     

Duplex opening by primosome protein PriA for replisome assembly on a recombination intermediate.

PriA and other primosome assembly proteins of Escherichia coli recruit the major replicative helicase DnaB for replisome assembly during bacteriophage Mu transposition and replication. MuA transposase catalyzes the transfer of Mu ends to target DNA, forming a potential replication fork that provides the assembly site for the replisome. However, this fork lacks the single-stranded DNA needed to load DnaB. Although no pre-existing primosome assembly sites that bind PriA were found within the Mu end sequences, PriA was able to bind to the forked DNA structure created by MuA. The helicase activity of PriA could then open the duplex to create the DnaB binding site. In a tightly coupled reaction on synthetic forked substrates, PriA promoted both the unwinding of the lagging strand arm and preprimosome assembly to load DnaB onto the lagging strand template. PriA apparently translocated 3' to 5' along the lagging strand template until sufficient single-stranded DNA was exposed for binding of DnaB, which then translocated 5' to 3' in the opposite direction. Mutant PriA lacking helicase activity was unable to promote this process, and loss of PriA helicase impaired Mu DNA replication in vivo and in vitro. This suggests that the opening of the duplex by PriA helicase is a critical step in the initiation of Mu DNA replication. Concerted helicase and primosome assembly functions would allow PriA to act as initiator on recombination intermediates and stalled replication forks. As part of the replisome, PriA may act as a mobile initiator that minimizes interruptions in chromosomal replication.     

Mcm4,6,7 uses a "pump in ring" mechanism to unwind DNA by steric exclusion and actively translocate along a duplex

Mcm4,6,7 is a ring-shaped heterohexamer and the putative eukaryotic replication fork helicase. In this study, we examine the mechanism of Mcm4,6,7. Mcm4,6,7 binds to only one strand of a duplex during unwinding, corresponding to the leading strand of a replication fork. Mcm4,6,7 unwinding stops at a nick in either strand. The Mcm4,6,7 ring also actively translocates along duplex DNA, enabling the protein to drive branch migration of Holliday junctions. The Mcm4,6,7 mechanism is very similar to DnaB, except the proteins translocate with opposite polarity along DNA. Mcm4,6,7 and DnaB have different structural folds and evolved independently; thus, the similarity in mechanism is surprising. We propose a "pump in ring" mechanism for both Mcm4,6,7 and DnaB, wherein a single-stranded DNA pump is situated within the central channel of the ring-shaped helicase, and unwinding is the result of steric exclusion. In this example of convergent evolution, the "pump in ring" mechanism was probably selected by eukaryotic and bacterial replication fork helicases in order to restrict unwinding to replication fork structures, stop unwinding when the replication fork encounters a nick, and actively translocate along duplex DNA to accomplish additional activities such as DNA branch migration.     

DnaA box sequences as the site for helicase delivery during plasmid RK2 replication initiation in Escherichia coli

DnaA box sequences are a common motif present within the replication origin region of a diverse group of bacteria and prokaryotic extrachromosomal genetic elements. Although the origin opening caused by binding of the host DnaA protein has been shown to be critical for the loading of the DnaB helicase, to date there has been no direct evidence presented for the formation of the DnaB complex at the DnaA box site. For these studies, we used the replication origin of plasmid RK2 (oriV), containing a cluster of four DnaA boxes that bind DnaA proteins isolated from different bacterial species (Caspi, R., Helinski, D. R., Pacek, M., and Konieczny, I. (2000) J. Biol. Chem. 275, 18454-18461). Size exclusion chromatography, surface plasmon resonance, and electron microscopy experiments demonstrated that the DnaB helicase is delivered to the DnaA box region, which is localized approximately 200 base pairs upstream from the region of origin opening and a potential site for helicase entry. The DnaABC complex was formed on both double-stranded superhelical and linear RK2 templates. A strict DnaA box sequence requirement for stable formation of that nucleoprotein structure was confirmed. In addition, our experiments provide evidence for interaction between the plasmid initiation protein TrfA and the DnaABC prepriming complex, formed at DnaA box region. This interaction is facilitated via direct contact between TrfA and DnaB proteins.     

Three-Dimensional Structure of N-Terminal Domain of DnaB Helicase and Helicase-Primase Interactions in Helicobacter pylori

Replication initiation is a crucial step in genome duplication and homohexameric DnaB helicase plays a central role in the replication initiation process by unwinding the duplex DNA and interacting with several other proteins during the process of replication. N-terminal domain of DnaB is critical for helicase activity and for DnaG primase interactions. We present here the crystal structure of the N-terminal domain (NTD) of H. pylori DnaB (HpDnaB) helicase at 2.2 Å resolution and compare the structural differences among helicases and correlate with the functional differences. The structural details of NTD suggest that the linker region between NTD and C-terminal helicase domain plays a vital role in accurate assembly of NTD dimers. The sequence analysis of the linker regions from several helicases reveals that they should form four helix bundles. We also report the characterization of H. pylori DnaG primase and study the helicase-primase interactions, where HpDnaG primase stimulates DNA unwinding activity of HpDnaB suggesting presence of helicase-primase cohort at the replication fork. The protein-protein interaction study of C-terminal domain of primase and different deletion constructs of helicase suggests that linker is essential for proper conformation of NTD to interact strongly with HpDnaG. The surface charge distribution on the primase binding surface of NTDs of various helicases suggests that DnaB-DnaG interaction and stability of the complex is most probably charge dependent. Structure of the linker and helicase-primase interactions indicate that HpDnaB differs greatly from E.coli DnaB despite both belong to gram negative bacteria.     

DnaA structure, function, and dynamics in the initiation at the chromosomal origin

Escherichia coli DnaA is the initiator of chromosomal replication. Multiple ATP-DnaA molecules assemble at the oriC replication origin in a highly regulated manner, and the resultant initiation complexes promote local duplex unwinding within oriC, resulting in open complexes. DnaB helicase is loaded onto the unwound single-stranded region within oriC via interaction with the DnaA multimers. The tertiary structure of the functional domains of DnaA has been determined and several crucial residues in the initiation process, as well as their unique functions, have been identified. These include specific DNA binding, inter-DnaA interaction, specific and regulatory interactions with ATP and with the unwound single-stranded oriC DNA, and functional interaction with DnaB helicase. An overall structure of the initiation complex is also proposed. These are important for deepening our understanding of the molecular mechanisms that underlie DnaA assembly, oriC duplex unwinding, regulation of the initiation reaction, and DnaB helicase loading. In this review, we summarize recent progress on the molecular mechanisms of the functions of DnaA on oriC. In addition, some members of the AAA+ protein family related to the initiation of replication and its regulation (e.g., DnaA) are briefly discussed.     

The helicase domain of phage P4 alpha protein overlaps the specific DNA binding domain.

Replication initiation depends on origin recognition, helicase, and primase activities. In phage P4, a second DNA region, the cis replication region (crr), is also required for replication initiation. The multifunctional alpha protein of phage P4, which is essential for DNA replication, combines the three aforementioned activities on a single polypeptide chain. Protein domains responsible for the activities were identified by mutagenesis. We show that mutations of residues G506 and K507 are defective in vivo in phage propagation and in unwinding of a forked helicase substrate. This finding indicates that the proposed P loop is essential for helicase activity. Truncations of gene product alpha (gp alpha) demonstrated that 142 residues of the C terminus are sufficient for specifically binding ori and crr DNA. The minimal binding domain retains gp alpha's ability to induce loop formation between ori and crr. In vitro and in vivo analysis of short C-terminal truncations indicate that the C terminus is needed for helicase activity as well as for specific DNA binding.     

Stoichiometry of DnaA and DnaB protein in initiation at the Escherichia coli chromosomal origin

Initiation of DNA replication at the Escherichia coli chromosomal origin, oriC, occurs through an ordered series of events that depend first on the binding of DnaA protein, the replication initiator, to DnaA box sequences within oriC followed by unwinding of an AT-rich region near the left border. The prepriming complex then forms, involving the binding of DnaB helicase at oriC so that it is properly positioned at each replication fork. We assembled and isolated the prepriming complexes on an oriC plasmid, then determined the stoichiometries of proteins in these complexes by quantitative immunoblot analysis. DnaA protein alone binds to oriC with a stoichiometry of 4-5 monomers per oriC DNA. In the prepriming complex, the stoichiometries are 10 DnaA monomers and 2 DnaB hexamers per oriC plasmid. That only two DnaB hexamers are bound, one for each replication fork, suggests that the binding of additional molecules of DnaA in forming the prepriming complex restricts the loading of additional DnaB hexamers that can bind at oriC.     

Mechanistic analysis of local ori melting and helicase assembly by the papillomavirus E1 protein

Preparation of DNA templates for replication requires opening of the duplex to expose single-stranded (ss) DNA. The locally melted DNA is required for replicative DNA helicases to initiate unwinding. How local melting is generated in eukaryotic replicons is unknown, but initiator proteins from a handful of eukaryotic viruses can perform this function. Here we dissect the local melting process carried out by the papillomavirus E1 protein. We characterize the melting process kinetically and identify mutations in the E1 helicase and in the ori that arrest the local melting process. We show that a subset of these mutants have specific defects for melting of the center of the ori containing the binding sites for E1 and demonstrate that these mutants fail to untwist the ori DNA. This understanding of how E1 generates local melting suggests possible mechanisms for local melting in other replicons.     

Structure and primase-mediated activation of a bacterial dodecameric replicative helicase

Replicative helicases are essential ATPases that unwind DNA to initiate chromosomal replication. While bacterial replicative DnaB helicases are hexameric, Helicobacter pylori DnaB (HpDnaB) was found to form double hexamers, similar to some archaeal and eukaryotic replicative helicases. Here we present a structural and functional analysis of HpDnaB protein during primosome formation. The crystal structure of the HpDnaB at 6.7 Å resolution reveals a dodecameric organization consisting of two hexamers assembled via their N-terminal rings in a stack-twisted mode. Using fluorescence anisotropy we show that HpDnaB dodecamer interacts with single-stranded DNA in the presence of ATP but has a low DNA unwinding activity. Multi-angle light scattering and small angle X-ray scattering demonstrate that interaction with the DnaG primase helicase-binding domain dissociates the helicase dodecamer into single ringed primosomes. Functional assays on the proteins and associated complexes indicate that these single ringed primosomes are the most active form of the helicase for ATP hydrolysis, DNA binding and unwinding. These findings shed light onto an activation mechanism of HpDnaB by the primase that might be relevant in other bacteria and possibly other organisms exploiting dodecameric helicases for DNA replication.