Host components required for the replication of the resistance plasmid R124 and a copy mutant derivative

The replication of R124, and a copy mutant derivative of it, was measured with respect to dependence on the host DnaA, DnaB, DnaC, DnaE, DnaG, and PolA gene products. Both plasmids replicated under conditions where the DnaA gene product was inactivated or where the polymerising activity of the PolA gene product was reduced. In contrast, neither plasmid replicated to any appreciable extent, if the DnaB, DnaC, DnaE or DnaG gene products were inactivated. R124 integratively suppressed the lesion of the dnaA mutant but the copy mutant derivative had only a very weak suppressing effect. Neither plasmid suppressed the lesions of any of the other dna mutants.     

Host growth temperature and a conservative amino acid substitution in the replication protein of pPS10 influence plasmid host range.

pPS10 is a replicon isolated from Pseudomonas syringe pv. savastanoi that can be established at 37 degrees C efficiently in Pseudomonas aeruginosa but very inefficiently in Escherichia coli. The establishment of the wild-type pPS10 replicon in E. coli is favored at low temperatures (30 degrees C or below). RepA protein of pPS10 promotes in vitro plasmid replication in extracts from E. coli, and this replication depends on host proteins DnaA, DnaB, DnaG, and SSB. Mutant plasmids able to efficiently replicate in E. coli at 37 degrees C were obtained. Three of four mutants whose mutations were mapped show a conservative Ala-->Val change in the amino-terminal region of the replication protein RepA. Plasmids carrying this mutation maintain the capacity to replicate in P. aeruginosa and have a fourfold increase in copy number in this host. The mutation does not substantially alter the autoregulation mediated by RepA. These results show that the physiological conditions of the host as well as subtle changes in the plasmid replication protein can modulate the host range of the pPS10 replicon.     

DnaA protein binding to the plasmid origin region can substitute for primosome assembly during replication of pBR322 in vitro

We analyzed the significance of DnaA protein binding to the origin region of pBR322. Replication of pBR322 in vitro was stimulated by DnaA protein. Moreover, the primosomal component protein i was no longer essential for replication after addition of DnaA protein, whereas, among others, proteins DnaB and DnaG were still required. Complete replication products were synthesized under these conditions. We constructed pBR322 deletion derivatives missing the primosome assembly sites. Efficient replication of these deletion plasmids was dependent on the presence of DnaA protein and its binding site, but independent of protein i activity. We conclude that DnaA protein binding to the pBR322 origin region substitutes for primosome assembly by directing DnaB, DnaC, and DnaG proteins to the origin. We term this process DnaA-directed pre-replisome formation.     

Replication of mini RK2 plasmid in extracts of Escherichia coli requires plasmid-encoded protein TrfA and host-encoded proteins DnaA, B, G DNA gyrase and DNA polymerase III

Soluble extracts of Escherichia coli capable of carrying out replication of the mini-RK2 derivative pCT461 have been prepared from cells carrying this plasmid or from plasmid-free bacteria. The latter are dependent upon exogenously added plasmid-encoded replication protein (TrfA) and require additional DnaA protein for optimum activity. This dependence upon DnaA was confirmed by the failure of DnaA-deficient cell extracts to support replication of pCT461 in the absence of added DnaA protein. Replication is unidirectional and begins at or near oriV, the vegetative replication origin of RK2. DNase I protection studies with purified TrfA indicate that this protein acts by binding to short (17 base-pairs) directly repeated DNA sequences present in oriV. The in vitro replication is resistant to rifampicin but can be abolished by antibodies against DnaG protein (E. coli primase) or DnaB protein (helicase) and by DNA gyrase inhibitors. Inhibition by arabinosyl-CTP suggests that DNA polymerase III is responsible for elongation of nascent DNA strands. These results are discussed in relation to the mechanism of RK2 replication and in the context of the host range of the plasmid.     

Plasmid RSF1010 DNA replication in vitro promoted by purified RSF1010 RepA, RepB and RepC proteins.

We have constructed and analyzed an in vitro system that will efficiently replicate plasmid RSF1010 and its derivatives. The system contains a partially purified extract from E.coli cells and three purified RSF1010-encoded proteins, the products of genes repA, repB (or mobA/repB), and repC. Replication in this system mimics the in vivo mechanism in that it (i) is initiated at oriV, the origin of vegetative DNA replication, (ii) proceeds in a population of plasmid molecules in both directions from this 396-base-pair origin region, and (iii) is absolutely dependent on the presence of each of the three rep gene products. In addition, we find that E.coli DNA gyrase, DnaZ protein (gamma subunit of poIIII holoenzyme) and SSB are required for in vitro plasmid synthesis. The bacterial RNA polymerase, the initiation protein DnaA, and the primosomal proteins DnaB, DnaC, DnaG and DnaT are not required. Furthermore, the replicative intermediates seen in the electron microscope suggest that replication in vitro begins with the simultaneous or non-simultaneous formation of two displacement loops that expand for a short stretch of DNA toward each other, and form a theta-type structure when the two displacing strands pass each other.     

DnaA dependent replication of plasmid R1 occurs in the presence of point mutations that disrupt the dnaA box of oriR.

We have found that DnaA dependent replication of R1 still occurred when 5 of the 9 bases in the dnaA box present in oriR were changed by site directed mutagenesis although the replication efficiency decreased to 20% and 70% of the wild-type origin in vitro and in vivo respectively. Additional mutation of a second dnaA box, 28 bp upstream oriR, that differs in only one base from the consensus sequence, did not affect the level of replication whereas polyclonal antibodies against DnaA totally abolished in vitro replication in the absence of the dnaA box. Wild-type RepA as well as a RepA mutant, RepA2623, that binds to oriR but that is inactive in promoting in vitro replication of plasmid R1, induce efficient binding of DnaA to the dnaA box. However, specific binding of DnaA to oriR was not detected by DNase I protection experiments in the absence of the dnaA box. These results suggest that the entrance of the DnaA protein in oriR is promoted initially by interactions with a RepA-oriR pre-initiation complex and that, in the absence of the dnaA box, these interactions can support, with reduced efficiency, DnaA dependent replication of plasmid R1.     

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.     

Interaction of initiator proteins with the origin of replication of an IncL/M plasmid

The origin of replication of the IncL/M plasmid pMU604 was analyzed to identify sequences important for binding of initiator proteins and origin activity. A thrice repeated sequence motif 5'-NANCYGCAA-3' was identified as the binding site (RepA box) of the initiator protein, RepA. All three copies of the RepA box were required for in vivo activity and binding of RepA to these boxes appeared to be cooperative. A DnaA R box (box 1), located immediately upstream of the RepA boxes, was not required for recruitment of DnaA during initiation of replication by RepA of pMU604 unless a DnaA R box located at the distal end of the origin (box 3) had been inactivated. However, DnaA R box 1 was important for recruitment of DnaA to the origin of replication of pMU604 when the initiator RepA was that from a distantly related plasmid, pMU720. A mutation which scrambled DnaA R boxes 1 and 3 and one which scrambled DnaA R boxes 1, 3 and 4 had much more deleterious effects on initiation by RepA of pMU720 than on initiation by RepA of pMU604. Neither Rep protein could initiate replication from the origin of pMU604 in the absence of DnaA, suggesting that the difference between them might lie in the mechanism of recruitment of DnaA to this origin. DnaA protein enhanced the binding and origin unwinding activities of RepA of pMU604, but appeared unable to bind to a linear DNA fragment bearing the origin of replication of pMU604 in the absence of other proteins.     

Open-complex formation by the host initiator, DnaA, at the origin of P1 plasmid replication.

Replication of P1 plasmid requires both the plasmid-specific initiator, RepA, and the host initiator, DnaA. Here we show that DnaA can make the P1 origin reactive to the single-strand specific reagents KMnO4 and mung bean nuclease. Addition of RepA further increased the KMnO4 reactivity of the origin, although RepA alone did not influence the reaction. The increased reactivity implies that the two initiators interact in some way to alter the origin conformation. The KMnO4 reactivity was restricted to one strand of the origin. We suggest that the roles of DnaA in P1 plasmid and bacterial replication are similar: origin opening and loading of the DnaB helicase. The strand-bias in chemical reactivity at the P1 origin most likely indicates that only one of the strands is used for the loading of DnaB, a scenario consistent with the unidirectional replication of the plasmid.     

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.     

Interaction of the initiator protein of an IncB plasmid with its origin of DNA replication

The replication initiator protein RepA of the IncB plasmid pMU720 was purified and used in DNase I protection assays in vitro. RepA protected a 68-bp region of the origin of replication of pMU720. This region, which lies immediately downstream of the DnaA box, contains four copies of the sequence motif 5'AANCNGCAA3'. Mutational analyses identified this sequence as the binding site specifically recognized by RepA (the RepA box). Binding of RepA to the RepA boxes was ordered and sequential, with the box closest to the DnaA binding site (box 1) occupied first and the most distant boxes (boxes 3 and 4) occupied last. However, only boxes 1, 2, and 4 were essential for origin activity, with box 3 playing a lesser role. Changing the spacing between box 1 and the other three boxes affected binding of RepA in vitro and origin activity in vivo, indicating that the RepA molecules bound to ori(B) interact with one another.     

Yeast Two-Hybrid Analysis of PriB-Interacting Proteins in Replication Restart Primosome: A Proposed PriB–SSB Interaction Model

PriB is one of the components of the replication restart primosome. The activity mediated by the primosomal proteins, including PriB, is required for reinitiating chromosomal DNA replication in bacteria after DNA damage. As such, the study of the interactions between PriB and members in the primosome is essential to better understand their mechanism of action. In this study, we investigated PriB-interacting proteins in the primosome through the yeast two-hybrid system. Yeast two-hybrid analysis using two strains, Y187 and AH109, revealed that PriB interacts with PriA, DnaT, SSB, and itself and does not interact with DnaA, DnaB, DnaC, or DnaG. In addition, mutational analysis showed that PriB may bind to SSB via K82, K84, and K89 in the L₄₅ loop. Based on these preliminary data, we proposed a PriB–SSB interaction model. Further work can focus on determination of how PriB binds to the PriA–SSB complex in replication restart.     

Two replication regions in the pJM1 virulence plasmid of the marine pathogen Vibrio anguillarum

Vibrio anguillarum is a fish pathogen that causes vibriosis, a serious hemorrhagic septicemia, in wild and cultured fish. Many serotype O1 strains of this bacterium harbor the 65kb plasmid pJM1 carrying the majority of genes encoding the siderophore anguibactin iron transport system that is one of the most important virulence factors of this bacterium. We previously identified a replication region of the pJM1 plasmid named ori1. In this work we determined that ori1 can replicate in Escherichia coli and that the chromosome-encoded proteins DnaB, DnaC and DnaG are essential for its replication whereas PolI, IHF and DnaA are not required. The copy number of the pJM1 plasmid is 1-2, albeit cloned smaller fragments of the ori1 region replicate with higher copy numbers in V. anguillarum while in E. coli we did not observe an obvious difference of the copy numbers of these constructs which were all high. Furthermore, we were able to delete the ori1 region from the pJM1 plasmid and identified a second replication region in pJM1 that we named ori2. This second replication region is located on ORF25 that is within the trans-acting factor (TAFr) region, and showed that it can only replicate in V. anguillarum.     

Fine balance in the regulation of DnaB helicase by DnaC protein in replication in Escherichia coli.

The DnaC protein of Escherichia coli is essential for replication in vivo and in vitro. In the initiation of replication of a minichromosome at its origin, DnaC delivers the DnaB helicase from a DnaB.DnaC complex to the future replication fork and then departs. However, if an excess of DnaC was present in subsequent steps, it severely inhibited replication by slowing the DnaB helicase at the replication fork. When DnaB was present at a level equimolar with the excess DnaC, the inhibition was relieved, implying that the ratio of DnaC to DnaB is critical for achieving optimal replication activity and avoiding inhibition by DnaC. In vivo, overproduction of DnaC slowed cell growth. This slowing was alleviated by overproducing DnaB at the same time. E. coli strains with a dnaCts gene defective in chromosomal initiation were complemented by the wild-type gene in trans. On the other hand, strains with an elongation-defective dnaCts gene were not complemented by the wild-type dnaC gene. The dominance of the mutant protein suggests that it remains tightly complexed with DnaB at the replication fork, inhibiting elongation even in the presence of the wild-type DnaC.     

The box VII motif of Escherichia coli DnaA protein is required for DnaA oligomerization at the E. coli replication origin

Escherichia coli DnaA protein initiates DNA replication from the chromosomal origin, oriC, and regulates the frequency of this process. Structure-function studies indicate that the replication initiator comprises four domains. Based on the structural similarity of Aquifex aeolicus DnaA to other AAA+ proteins that are oligomeric, it was proposed that Domain III functions in oligomerization at oriC (Erzberger, J. P., Pirruccello, M. M., and Berger, J. M. (2002) EMBO J. 21, 4763-4773). Because the Box VII motif within Domain III is conserved among DnaA homologues and may function in oligomerization, we substituted conserved Box VII amino acids of E. coli DnaA with alanine by site-directed mutagenesis to examine the role of this motif. All mutant proteins are inactive in initiation from oriC in vivo and in vitro, but they support RK2 plasmid DNA replication in vivo. Thus, RK2 requires only a subset of DnaA functions for plasmid DNA replication. Biochemical studies on a mutant DnaA carrying an alanine substitution at arginine 281 (R281A) in Box VII show that it is inactive in in vitro replication of an oriC plasmid, but this defect is not from the failure to bind to ATP, DnaB in the DnaB-DnaC complex, or oriC. Because the mutant DnaA is also active in the strand opening of oriC, whereas DnaB fails to bind to this unwound region, the open structure is insufficient by itself to load DnaB helicase. Our results show that the mutant fails to form a stable oligomeric DnaA-oriC complex, which is required for the loading of DnaB.     

Purification and characterization of DnaC810, a primosomal protein capable of bypassing PriA function

Escherichia coli strains lacking PriA are severely compromised in their ability to repair UV-damaged DNA and to perform homologous recombination. These phenotypes arise because of a lack of PriA-directed replication fork assembly at recombination intermediates such as D-loops. Naturally arising suppressor mutations in dnaC restore strains carrying the priA2::kan null allele to wild-type function. We have cloned one such gene, dnaC810, and overexpressed, purified, and characterized the DnaC810 protein. DnaC810 can support a PriA-independent synthesis of phiX174 complementary strand DNA. This can be attributed to its ability, unlike wild-type DnaC, to catalyze a SSB-insensitive general priming reaction with DnaB and DnaG on any SSB-coated single-stranded DNA. Gel mobility shift analysis revealed that DnaC810 could load DnaB directly to SSB-coated single-stranded DNA as well as to D loop DNA. This explains the ability of DnaC810 to bypass the requirement for PriA, PriB, PriC, and DnaT during replication fork assembly at recombination intermediates.     

Host-dependent requirement for specific DnaA boxes for plasmid RK2 replication

The replication origin of the broad-host-range plasmid RK2, oriV, contains four DnaA boxes, which bind the DnaA protein isolated from Escherichia coli. Using a transformation assay, mutational analysis of these boxes showed a differential requirement for replication in different Gram-negative bacteria. DnaA boxes 3 and 4 were required in E. coli and Pseudomonas putidabut not as strictly in Azotobacter vinelandii and not at all in P. aeruginosa. In vitro replication results using an extract prepared from E. coli demonstrated that the activity of origin derivatives containing mutations in boxes 3 or 4 or a deletion of all four DnaA boxes could be restored by the addition of increasing amounts of purified DnaA protein. High levels of DnaA protein in the presence of the TrfA protein also resulted in the stimulation of open complex formation and DnaB helicase loading on oriV, even in the absence of the four DnaA boxes. These observations at least raise the possibility that an alternative mechanism of initiation of oriV is being used in the absence of the four DnaA boxes and that this mechanism may be similar to that used in P. aeruginosa, which does not require these four DnaA boxes for replication.     

Deletion analysis of the mini-P1 plasmid origin of replication and the role of Escherichia coli DnaA protein

The mini-P1 plasmid origin of replication is contained on a 246 base pair (bp) piece of DNA. At one end there are five 19-bp binding sites for the P1 initiator protein, RepA, and near the other end there are two 9-bp DnaA protein-binding sites. To further define the limits of the origin, we cloned the origin region in M13 and constructed deletions of either end. We sequenced the DNA and tested the replicative form I DNA of the deletion phages for their ability to support RepA-dependent DNA replication in an in vitro system. The origin that is functional in vitro could be reduced to 202 bp. It includes three intact and one incomplete RepA-binding sites at one end and the two DnaA-binding sites at the other end. When the two naturally occurring DnaA-binding sites were replaced with one or two synthetic sites, only the construction containing two sites was active in vitro. We found that the minimal origin that is functional in vivo contains all of the five RepA and the two DnaA-binding sites. Mini-P1 plasmid replication both in vivo and in vitro requires two initiator proteins, the Escherichia coli DnaA protein and the P1 RepA protein. We have found that the ADP form of DnaA is as active as the ATP form of the protein in the in vitro replication of mini-P1. In contrast, only the ATP form is active for in vitro replication of plasmids carrying the E. coli origin (Bramhill, D., and Kornberg, A. (1988) Cell 52, 743-755).     

The interaction domains of the DnaA and DnaB replication proteins of Escherichia coli

The initiation of chromosome replication in Escherichia coli requires the recruitment of the replicative helicase DnaB from the DnaBC complex to the unwound region within the replication origin oriC, supported by the oriC-bound initiator protein DnaA. We defined physical contacts between DnaA and DnaB that involve residues 24-86 and 130-148 of DnaA and residues 154-210 and 1-156 of DnaB respectively. We propose that contacts between DnaA and DnaB occur via two interaction sites on each of the proteins. Interaction domain 24-86 of DnaA overlaps with its N-terminal homo-oligomerization domain (residues 1-86). Interaction domain 154-210 of DnaB overlaps or is contiguous with the domains known to interact with plasmid initiator proteins. Loading of the DnaBC helicase in vivo can only be performed by DnaA derivatives containing (in addition to residues 24-86 and the DNA-binding domain 4) a structurally intact domain 3. Nucleotide binding by domain 3 is, however, not required. The parts of DnaA required for replication of pSC101 were clearly different from those used for helicase loading. Domains 1 and 4 of DnaA, but not domain 3, were found to be involved in the maintenance of plasmid pSC101.     

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.