Monomer/dimer ratios of replication protein modulate the DNA strand-opening in a replication origin.

DNA opening is an essential step in the initiation of replication via the Cairns mode of replication. The opening reaction was investigated in a gamma ori system by using hyperactive variants of plasmid R6K-encoded initiator protein, pi. Reactivity to KMnO4 (indicative of opening) within gamma ori DNA occurred in both strands of a superhelical template upon the combined addition of wt pi, DnaA and integration host factor (IHF), each protein known to specifically bind gamma ori. IHF, examined singly, enhanced reactivity to KMnO4. The IHF-dependent reactive residues, however, are distinct from those dependent on pi (wt and hyperactive variants). Remarkably, the DNA helix opening does not require IHF and/or DnaA when hyperactive variants of pi were used instead of wt protein. We present three lines of evidence consistent with the hypothesis that DNA strand separation is facilitated by pi monomers despite the fact that both monomers and dimers of the protein can bind to iterons (pi binding sites). Taken together, our data suggest that pi elicits its ability to modulate plasmid copy number at the DNA helix-opening step.

Involvement of the host initiator function dnaA in the replication of coliphage lambda.

We demonstrate that the initiation of coliphage lambda DNA replication is dependent on the host initiator function dnaA, provided that the lambdoid prophage Rac is absent. Presence of Rac compensated the absence of dnaA function, causing initiation of replication. In dnaAts rac+ cells at 43 degrees, most of parental phage DNA molecules, after one round of theta replication, switched to a replication with features of the sigma mode and produced progeny at high yield. Initiation of replication of the lambda Pts1 mutant at 43 degrees was blocked by dnaA function; however, under dnaA-rac+ conditions all parental phage DNA molecules, after one round of theta replication, switched to the sigma mode and produced progeny at high yield. Taking into account our recent finding that transcriptional activation of ori lambda seems to be dnaA-regulated (to be published elsewhere), we suggest that the DnaA-lambda Pts1 incompatibility occurs at the insertion of the ori lambda-bound lambda O-lambda P-DnaB preprimosome between the complementary lambda DNA strands. The role of Rac and the mechanism of the switch from theta to sigma mode of lambda phage DNA replication are discussed.

Calf thymus Hsc70 and Hsc40 can substitute for DnaK and DnaJ function in protein renaturation but not in bacteriophage DNA replication.

Calf thymus (ct) Hsc70 has been shown previously to reactivate heat-inactivated prokaryotic and eukaryotic enzymes, while DnaK was able to reactivate solely prokaryotic enzymes. Here, we report on isolation from calf thymus of a DnaJ homolog, ctHsc40, and on testing of its cooperative function in three different assays: (i) reactivation of heat-inactivated DNA polymerases, (ii) stimulation of the ATPase activity of ctHsc70 chaperone, and (iii) replication of bacteriophage lambda DNA. Surprisingly, ctHsc70/ctHsc40 chaperones were found to reactivate the denatured prokaryotic and eukaryotic enzymes but not to promote bacteriophage lambda DNA replication, suggesting species specificity in DNA replication.

Role of bacterial chaperones in DNA replication.

Studies on the involvement of chaperone proteins in DNA replication have been limited to a few replication systems, belonging primarily to the prokaryotic world. The insights gained from these studies have substantially contributed to our understanding of the eukaryotic DNA replication process as well. The finding that molecular chaperones can activate some initiation proteins before DNA synthesis has led to the more general suggestion that molecular chaperones can influence the DNA-binding activity of many proteins, including transcriptional factors involved in cell regulatory systems. The DnaK/DnaJ/GrpE molecular chaperone system became a paradigm of our understanding of fundamental processes, such as protein folding, translocation, selective proteolysis and autoregulation of the heat-shock response. Studies on the Clp ATPase family of molecular chaperones will help to define the nature of signals involved in chaperone-dependent proteins' refolding and the degradation of misfolded proteins.

The requirement for molecular chaperones in lambda DNA replication is reduced by the mutation pi in lambda P gene, which weakens the interaction between lambda P protein and DnaB helicase.

During the initiation of lambda DNA replication, the host DnaB helicase is complexed with phage lambda P protein in order to be properly positioned near the ori lambda-lambda O initiation complex. However, the lambda P-DnaB interaction inhibits the activities of DnaB. Thus, the concerted action of bacterial heat shock proteins, DnaK, DnaJ, and GrpE, is required to activate the helicase. Wild-type phage lambda cannot grow on the E. coli dnaB, dnaK, dnaJ, and grpE mutants. However, lambda phage with a mutation pi in the lambda P gene, is able to produce progeny in these mutants as well as in the wild-type bacteria. Purified mutant lambda pi protein reveals a much lower affinity to DnaB than wild-type lambda P, and the lambda pi-DnaB complex is unstable. Also, a very low concentration of DnaK protein is sufficient to activate the helicase in a replication system based on lambda dv dsDNA. In that system, the mutant DnaK756 protein, inactive in the lambda P-dependent replication, revealed its activity in the lambda pi-dependent reaction. The lambda O-lambda P-dependent replication system based on M13 ssDNA efficiently replicates DNA in the absence of any chaperone protein, unless lambda P is substituted by the lambda pi mutant protein. Data presented in this paper explain why lambda pi phage is able to grow on wild-type and dnaK756 bacteria.

Helicase delivery and activation by DnaA and TrfA proteins during the initiation of replication of the broad host range plasmid RK2.

Specific binding of the plasmid-encoded protein, TrfA, and the Escherichia coli DnaA protein to the origin region (oriV) is required for the initiation of replication of the broad host range plasmid RK2. It has been shown that the DnaA protein which binds to DnaA boxes upstream of the TrfA-binding sites (iterons) cannot by itself form an open complex, but it enhances the formation of the open complex by TrfA (Konieczny, I., Doran, K. S., Helinski, D. R., Blasina, A. (1997) J. Biol. Chem. 272, 20173). In this study an in vitro replication system is reconstituted from purified TrfA protein and E. coli proteins. With this system, a specific interaction between the DnaA and DnaB proteins is required for delivery of the helicase to the RK2 origin region. Although the DnaA protein directs the DnaB-DnaC complex to the plasmid replication origin, it cannot by itself activate the helicase. Both DnaA and TrfA proteins are required for DnaB-induced template unwinding. We propose that specific changes in the nucleoprotein structure mediated by TrfA result in a repositioning of the DnaB helicase within the open origin region and an activation of the DnaB protein for template unwinding.

The replication initiation protein of the broad-host-range plasmid RK2 is activated by the ClpX chaperone.

Initiation and control of replication of the broad-host-range plasmid RK2 requires two plasmid-encoded elements, the replication origin (oriV) and the initiation protein TrfA. Purified TrfA is largely in the form of a dimer; however, only the monomeric form of the protein can bind specifically to the direct repeats (iterons) at the RK2 origin. The largely dimeric form of wild-type TrfA is inactive in the initiation of replication of RK2 in an in vitro replication system reconstituted from purified components. However, preincubation of the TrfA protein with the ClpX molecular chaperone isolated from Escherichia coli activates the initiator protein for replication in the purified system. We further observed that ClpX, in an ATP-dependent reaction, greatly increases the proportion of TrfA monomers and, therefore, the ability of this protein to bind to iterons localized within RK2 origin. Finally, a copy-up mutant of the TrfA protein which is largely in the monomer form is active in the reconstituted in vitro replication system, and its activity is not affected by ClpX.

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.

Interactions of DnaA proteins from distantly related bacteria with the replication origin of the broad host range plasmid RK2.

Replication initiation of the broad host range plasmid RK2 requires binding of the host-encoded DnaA protein to specific sequences (DnaA boxes) at its replication origin (oriV). In contrast to a chromosomal replication origin, which functionally interacts only with the native DnaA protein of the organism, the ability of RK2 to replicate in a wide range of Gram-negative bacterial hosts requires the interaction of oriV with many different DnaA proteins. In this study we compared the interactions of oriV with five different DnaA proteins. DNase I footprint, gel mobility shift, and surface plasmon resonance analyses showed that the DnaA proteins from Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa bind to the DnaA boxes at oriV and are capable of inducing open complex formation, the first step in the replication initiation process. However, DnaA proteins from two Gram-positive bacteria, Bacillus subtilis and Streptomyces lividans, while capable of specifically interacting with the DnaA box sequences at oriV, do not bind stably and fail to induce open complex formation. These results suggest that the inability of the DnaA protein of a host bacterium to form a stable and functional complex with the DnaA boxes at oriV is a limiting step for plasmid host range.

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.

A critical DnaA box directs the cooperative binding of the Escherichia coli DnaA protein to the plasmid RK2 replication origin.

The requirement of DnaA protein binding for plasmid RK2 replication initiation the Escherichia coli was investigated by constructing mutations in the plasmid replication origin that scrambled or deleted each of the four upstream DnaA boxes. Altered origins were analyzed for replication activity in vivo and in vitro and for binding to the E. coli DnaA protein using a gel mobility shift assay and DNase I footprinting. Most strikingly, a mutation in one of the boxes, box 4, abolished replication activity and eliminated stable DnaA protein binding to all four boxes. Unlike DnaA binding to the E. coli origin, oriC, DnaA binding to two of the boxes (boxes 4 and 3) in the RK2 origin, oriV, is cooperative with box 4 acting as the "organizer" for the formation of the DnaA-oriV nucleoprotein complex. Interestingly, the inversion of box 4 also abolished replication activity, but did not result in a loss of binding to the other boxes. However, DnaA binding to this mutant origin was no longer cooperative. These results demonstrate that the sequence, position, and orientation of box 4 are crucial for cooperative DnaA binding and the formation of a nucleoprotein structure that is functional for the initiation of replication.

Replication origin of the broad host range plasmid RK2. Positioning of various motifs is critical for initiation of replication.

The 393-base pair minimal origin, oriV, of plasmid RK2 contains three iterated motifs essential for initiation of replication: consensus sequences for binding the bacterial DnaA protein, DnaA boxes, which have recently been shown to bind the DnaA protein; 17-base pair direct repeats, iterons, which bind the plasmid encoded replication protein, TrfA; and A + T-rich repeated sequences, 13-mers, which serve as the initial site of helix destabilization. To investigate how the organization of the RK2 origin contributes to the mechanism of replication initiation, mutations were introduced into the minimal origin which altered the sequence and/or spacing of each particular region relative to the rest of the origin. These altered origins were analyzed for replication activity in vivo and in vitro, for localized strand opening and for DnaB helicase mediated unwinding. Mutations in the region between the iterons and the 13-mers which altered the helical phase or the intrinsic DNA curvature prevented strand opening of the origin and consequently abolished replication activity. Insertions of more or less than one helical turn between the DnaA boxes and the iterons also inactivated the replication origin. In these mutants, however, strand opening appeared normal but the levels of DnaB helicase activity were substantially reduced. These results demonstrate that correct helical phasing and intrinsic DNA curvature are critical for the formation of an open complex and that the DnaA boxes must be on the correct side of the helix to load DnaB helicase.

Role of TrfA and DnaA proteins in origin opening during initiation of DNA replication of the broad host range plasmid RK2.

The Escherichia coli protein DnaA and the plasmid RK2-encoded TrfA protein are required for initiation of replication of the broad host range plasmid RK2. The TrfA protein has been shown to bind to five 17-base pair repeat sequences, referred to as iterons, at the minimal replication origin (oriV). Using DNase I footprinting and a gel mobility shift assay, purified DnaA protein was found to bind to four DnaA consensus binding sequences immediately upstream of the five iterons at the RK2 origin of replication. Binding of the TrfA protein to the iterons results in localized strand opening within the A+T-rich region of the replication origin as determined by reactivity of the top and bottom strands to potassium permanganate (KMnO4). The presence of either the E. coli DnaA or HU protein is required for the TrfA-mediated strand opening. Although the DnaA protein itself did not produce an RK2 open complex, it did enhance and/or stabilize the TrfA-induced strand opening.

A broad host range replicon with different requirements for replication initiation in three bacterial species.

Plasmid RK2 is unusual in its ability to replicate stably in a wide range of Gram-negative bacteria. The replication origin (oriV) and a plasmid-encoded initiation protein (TrfA; expressed as 33 and 44 kDa forms) are essential for RK2 replication. To examine initiation events in bacteria unrelated to Escherichia coli, the genes encoding the replicative helicase, DnaB, of Pseudomonas putida and Pseudomonas aeruginosa were isolated and used to construct protein expression vectors. The purified proteins were tested for activity along with E.coli DnaB at RK2 oriV. Each helicase could be recruited and activated at the RK2 origin in the presence of the host-specific DnaA protein and the TrfA protein. Escherichia coli or P.putida DnaB was active with either TrfA-33 or TrfA-44, while P.aeruginosa DnaB required TrfA-44 for activation. Moreover, unlike the E.coli DnaB helicase, both Pseudomonas helicases could be delivered and activated at oriV in the absence of an ATPase accessory protein. Thus, a DnaC-like accessory ATPase is not universally required for loading the essential replicative helicase at a replication origin.