Replication and partitioning of the broad-host-range plasmid RK2

The broad-host-range plasmid RK2 has been a model for studying DNA metabolism in bacteria for many years. It is used as a vector allowing genetic manipulations in numerous bacterial species. The RK2 genome encodes several genes providing the plasmid with diverse functions allowing for its stable maintenance in a variety of bacterial hosts. This review will focus on two processes indispensable for plasmid DNA maintenance. We will summarize recent understanding of the molecular mechanisms contributing to the RK2 DNA replication and partitioning.     

Regions of broad-host-range plasmid RK2 which are essential for replication and maintenance.

The sites of cleavage on the map of the broad-host-range plasmid RK2 (56 kilobases) were determined for the BglII, PstI, and SmaI restriction enzymes, and the determinants for tetracycline and ampicillin resistance were localized. The cleavage sites were clustered at or near the drug resistance genes. To localize regions required for plasmid replication and maintenance in Escherichia coli, we deleted nonessential regions of RK2 by partial digestion with the restriction endonuclease HaeII to produce small derivatives. The smallest stable replicon obtained contained five HaeII fragments of RK2 which total 5.4 kilobases. These fragments were derived from three regions of RK2 that are separated from each other by antibiotic resistance genes. One of these HaeII fragments (0.75 kilobases) has the properties expected of the origin of replication. The outer four fragments, located in two separate regions of RK2, were found to provide, in trans, functions that permit the replication of the HaeII fragment carrying the origin of the replication. These results indicate that at least two plasmid-encoded genes, capable of acting in trans, and a replication origin are required for RK2 replication and maintenance.     

Mutations in the trfA replication gene of the broad-host-range plasmid RK2 result in elevated plasmid copy numbers.

Mutated forms of trfA, the replication protein gene of plasmid RK2, that support a minimal RK2 origin plasmid in Escherichia coli at copy numbers up to 23-fold higher than normal have been isolated. Six such high-copy-number (copy-up) mutations were mapped and sequenced. In each case, a single base transition led to an amino acid substitution in the TrfA protein primary sequence. The six mutations affected different residues of the protein and were located within a 69-base-pair region encoding 24 amino acids. Dominance tests showed that each of the mutants can be suppressed by wild-type trfA in trans, but suppression is highly dependent on the amount of wild-type protein produced. Excess mutant TrfA protein provided in trans significantly increased the copy number of RK2 and other self-replicating derivatives of RK2 that contain a wild-type trfA gene. These observations suggest that the mutations affect a regulatory activity of the TrfA replication protein that is a key factor in the control of initiation of RK2 replication.     

Identification of a potential membrane-targeting region of the replication initiator protein (TrfA) of broad-host-range plasmid RK2

Plasmid RK2 codes for two species of the replication initiator protein TrfA (33 and 44 kDa). Both polypeptides are strongly associated with membrane fractions of Escherichia coli host cells (W. Firshein and P. Kim, Mol. Microbiol. 23, 1-10, 1997). We investigated the role of a 12-amino-acid hydrophobic region (HR) in the membrane association of TrfA. Epitope-tagged polypeptide fragments of TrfA that contained HR were expressed and found to be associated with membrane fractions. Site-directed mutagenesis of trfA revealed that changes of specific amino acids in HR can affect both TrfA association with the membrane and its ability to support replication of an RK2 oriV plasmid in vivo. These results are consistent with the hypothesis that membrane association of TrfA is functionally relevant and that the HR region of TrfA is involved in membrane association and DNA replication in vivo.     

Broad-host-range properties of plasmid RK2: importance of overlapping genes encoding the plasmid replication initiation protein TrfA.

The trfA gene, encoding the essential replication initiation protein of the broad-host-range plasmid RK2, possesses an in-frame overlapping arrangement. This results in the production of TrfA proteins of 33 and 44 kDa, respectively. Utilizing deletion and site-specific mutagenesis to alter the trfA operon, we compared the replication of an RK2-origin plasmid in several distantly related gram-negative bacteria when supported by both TrfA-44 and TrfA-33, TrfA-33 alone, or TrfA-44/98L (a mutant form of the TrfA-44 protein) alone. TrfA-44/98L is identical to wild-type TrfA-44 with the exception of a single conservative amino acid alteration from methionine to leucine at codon 98; this alteration removes the translational start codon for the TrfA-33 protein. Copy number and stability were virtually identical for plasmids containing both TrfA-44 and TrfA-33 proteins or TrfA-44/98L alone in Pseudomonas aeruginosa and Agrobacterium tumefaciens, two unrelated bacteria in which TrfA-33 is poorly functional. This, along with recent in vitro studies comparing TrfA-44, TrfA-33, and TrfA-44/98L, suggests that the functional activity of TrfA-44 is not significantly affected by the 98L mutation. Analysis of minimal RK2 derivatives in certain gram-negative bacterial hosts suggests a role of the overlapping arrangement of trfA in facilitating the broad host range of RK2. RK2 derivatives encoding TrfA-44/98L alone demonstrated decreased copy number and stability in Escherichia coli and Azotobacter vinelandii when compared with derivatives specifying both TrfA-44 and TrfA-33. A strategy employing the trfA-44/98L mutant gene and in vivo homologous recombination was used to eliminate the internal translational start codon of trfA in the intact RK2 plasmid. The mutant intact RK2 plasmid produced only TrfA-44/98L. A small reduction in copy number and beta-lactamase expression resulted in E. coli, suggesting that overlapping trfA genes also enhance the efficiency of replication of the intact RK2 plasmid.     

Replication control in promiscuous plasmid RK2: kil and kor functions affect expression of the essential replication gene trfA.

We previously reported that broad-host-range plasmid RK2 encodes multiple host-lethal kil determinants (kilA, kilB1, kilB2, and kilC) which are controlled by RK2-specified kor functions (korA, korB, and korC). Here we show that kil and kor determinants have significant effects on RK2 replication control. First, korA and korB inhibit the replication of certain RK2 derivatives, unless plasmid replication is made independent of the essential RK2 gene trfA. Second, kilB1 exerts a strong effect on this interaction. If the target plasmid is defective in kilB1, sensitivity to korA and korB is enhanced at least 100-fold. Thus, korA and korB act negatively on RK2 replication, whereas kilB1 acts in a positive manner to counteract this effect. A mutant RK2 derivative, resistant to korA and korB, was found to have fused a new promoter to trfA, indicating that the targets for korA and korB are at the 5' end of the trfA gene. We constructed a trfA-lacZ fusion and found that synthesis of beta-galactosidase is inhibited by korA and korB. Thus korA, korB, and kilB1 influence RK2 replication by regulating trfA expression. We conclude that the network of kil and kor determinants is part of a replication control system for RK2.     

Analysis of mutations in trfA, the replication initiation gene of the broad-host-range plasmid RK2.

Plasmids with mutations in trfA, the gene encoding the replication initiation protein of the broad-host-range plasmid RK2, were isolated and characterized. Mutants identified from a nitrosoguanidine bank were defective in supporting the replication of a wild-type RK2 origin in Escherichia coli. Most of the mutations were clustered in a region of trfA corresponding to the carboxy-terminal quarter of the TrfA protein. 5' and 3' deletion mutants of trfA were also constructed. A C-terminal deletion of three amino acids of the Tr A protein was completely nonfunctional for RK2 replication. However, a deletion of 25 amino acids from the start of the 33-kDa TrfA protein was still competent for replication. Further characterization of the point and deletion trfA mutants in vivo revealed that a subset was capable of supporting RK2 replication in other gram-negative bacteria, including Pseudomonas putida, Agrobacterium tumefaciens, and Azotobacter vinelandii. Selected mutant TrfA proteins were partially purified and characterized in vitro. Velocity sedimentation analysis of these partially purified TrfA proteins indicated that the wild-type protein and all mutant TrfA proteins examined exist as dimers in solution. Results from in vitro replication assays corroborated the experimental findings in vivo. Gel retardation results clearly indicated that the point mutant TrfA-33:151S, which was completely defective in replication of an RK2 origin in all of the bacterial hosts tested in vivo, and a carboxy-terminal deletion mutant, TrfA-33:C delta 305, were not able to bind iterons in vitro. In addition to the partially defective or could not be distinguished from the wild-type protein in binding to the origin region. The mutant proteins with apparently normal DNA-binding activity in vitro either were inactive in all four gram-negative bacteria tested or exhibited differences in functionality depending on the host organism. These mutant TrfA proteins may be altered in the ability to interact with the replication proteins of the specific host bacterium.     

Conjugative transfer functions of broad-host-range plasmid RK2 are coregulated with vegetative replication

The kilB locus (which is unclonable in the absence of korB) of broad-host-range plasmid RK2 (60 kb) lies between the trfA operon (co-ordinates 16.4 to 18.2 kb), which encodes a protein essential for vegetative replication, and the Tra2 block of conjugative transfer genes (co-ordinates 20.0 to 27.0 kb). Promoter probe studies indicated that kilB is transcribed clockwise from a region containing closely spaced divergent promoters, one of which is the trfA promoter. The repression of both promoters by korB suggested that kilB may also play a role in stable maintenance of RK2. We have sequenced the region containing kilB and analysed it by deletion and insertion mutagenesis. Loss of the KilB+ phenotype does not result in decreased stability of mini RK2 plasmids. However insertion in ORFI (kilBI) of the region analysed results in a Tra- phenotype in plasmids which are otherwise competent for transfer, demonstrating that this locus is essential for transfer and is probably the first gene of the Tra2 region. From the kilBI DNA sequence KilBI is predicted to be 34995 Da, in line with M(r) = 36,000 observed by sodium dodecyl sulphate/polyacrylamide gel electrophoresis, and contains a type I ATP-binding motif. The purified product was used to raise antibody which allowed the level of KilBI produced from RK2 to be estimated at approximately 2000 molecules per bacterium. Protein sequence comparisons showed the highest homology score with VirB11, which is essential for the transfer of the Agrobacterium tumefaciens Ti plasmid DNA from bacteria to plant cells. The sequence similarity of both KilBI and VirB11 to a family of protein export functions suggested that KilBI may be involved in assembly of the surface-associated Tra functions. The data presented in this paper provide the first demonstration of coregulation of genes required for vegetative replication and conjugative transfer on a bacterial plasmid.     

DnaA boxes in the P1 plasmid origin: the effect of their position on the directionality of replication and plasmid copy number.

The DnaA protein is essential for initiation of DNA replication in a wide variety of bacterial and plasmid replicons. The replication origin in these replicons invariably contains specific binding sites for the protein, called DnaA boxes. Plasmid P1 contains a set of DnaA boxes at each end of its origin but can function with either one of the sets. Here we report that the location of origin-opening, initiation site of replication forks and directionality of replication do not change whether the boxes are present at both or at one of the ends of the origin. Replication was bidirectional in all cases. These results imply that DnaA functions similarly from the two ends of the origin. However, origins with DnaA boxes proximal to the origin-opening location opened more efficiently and maintained plasmids at higher copy numbers. Origins with the distal set were inactive unless the adjacent P1 DNA sequences beyond the boxes were included. At either end, phasing of the boxes with respect to the remainder of the origin influenced the copy number. Thus, although the boxes can be at either end, their precise context is critical for efficient origin function.     

Interactions of the origin of replication (oriV) and initiation proteins (TrfA) of plasmid RK2 with submembrane domains of Escherichia coli.

It has been possible to locate a submembrane domain representing less than 10% of the total membrane that appears to be responsible for sequestering some essential components required for plasmid RK2 DNA replication. This subfraction, whose cellular location in the membrane prior to extraction is still unknown, is derived from the inner membrane fraction, since it possesses enzyme marker activity (NADH oxidase) exclusively associated with the inner membrane. The subfraction was detected by a modification of the methods of Ishidate et al. (K. Ishidate, E. S. Kreeger, J. Zrike, S. Deb, B. Glauner, T. MacAlister, and L. I. Rothfield, J. Biol. Chem. 261:428-443, 1986) in which low pressure in a French pressure cell and lysozyme were used to preserve the supercoil plasmid DNA template during cell disruption. This was followed by successive cycles of sucrose gradient sedimentation and flotation density gradient centrifugation to reveal a number of subfractions, including the one of interest. The characteristics of plasmid interaction with the subfraction include the presence of supercoil DNA after extraction, the binding of the origin of plasmid replication (oriV) in vitro, and the association of the two plasmid-encoded initiation (TrfA) proteins (encoded by overlapping genes). However, another peak, the outer membrane fraction, also binds oriV in vitro, contains plasmid DNA in vivo, and associates with the TrfA initiation proteins. Nevertheless, it contains much less of the initiation proteins, and the specific activity of binding oriV is also much reduced compared with the other subfraction. There is a strong correlation between the association of the TrfA initiation proteins with a particular membrane fraction and the binding of oriV in vitro or plasmid DNA in vivo. Since the proteins are known to bind to repeated sequences in oriV (S. Perri, D. R. Helinski, and A. Toukdarian, J. Biol. Chem. 266:12536-1254, 1991; M. Pinkney, R. Diaz, E. Lanka, and C. M. Thomas, J. Mol. Biol. 203: 927-938, 1988), it appears that the initiation proteins themselves could be responsible, at least in part, for the association of plasmid DNA to the membrane.     

Analysis of copy number control elements in the region of the vegetative replication origin of the broad host range plasmid RK2.

Broad host-range plasmid RK2 is able to replicate in a controlled manner in most Gram negative bacterial species. To analyze the elements of its control mechanism, we have measured the copy number in Escherichia coli of mini-RK2 replicons isogenic except for defined deletions in regions adjacent to the vegetative replication origin, oriVRK2, which have previously been implicated in copy number control because of their expression of plasmid incompatibility. The results indicate that while the previously defined 700-bp HaeII oriVRK2 fragment carries one copy control element (copA), a second (copB) lies at least partly outside this fragment towards the tetracycline resistance genes of RK2. Deletions affecting both these regions give a mini replicon with a copy number of 35-40 compared with 4-7 for parental RK2. Further incompatibility experiments indicate that targets for both incA (copA) and incB (copB) lie within the 700-bp HaeII oriVRK2 fragment.     

Unidirectional replication of the P-group plasmid RK2.

The mode of replication of the broad host-range plasmid RK2 has been determined from examination of molecular replicative forms cleaved with the restriction endonucleases EcoRI and Hind III. Replication is unidirectional, and proceeds from a unique origin. The location of the origin and other evidence suggests that genes involved in plasmid maintenance are not tightly clustered.     

Regions of broad-host-range plasmid RK2 involved in replication and stable maintenance in nine species of gram-negative bacteria.

The replication and maintenance properties of the broad-host-range plasmid RK2 and its derivatives were examined in nine gram-negative bacterial species. Two regions of RK2, the origin of replication (oriV) and a segment that encodes for a replication protein (trfA delta kilD, designated trfA*), are sufficient for replication in all nine species tested. However, stable maintenance of this minimal replicon (less than 0.3% loss per generation under nonselection conditions) is observed only in Escherichia coli, Pseudomonas aeruginosa, Pseudomonas putida, and Azotobacter vinelandii. Maintenance of this minimal replicon is unstable in Rhizobium meliloti, Agrobacterium tumefaciens, Caulobacter crescentus, Acinetobacter calcoaceticus, and Rhodopseudomonas sphaeroides. A maintenance function has been localized to a 3.1-kilobase (kb) region of RK2 encoding three previously described functions: korA (trfB korB1 korD), incP1-(II), and korB. The 3.1-kb maintenance region can increase or decrease the stability of maintenance of RK2 derivatives dependent on the host species and the presence or absence of the RK2 origin of conjugal transfer (oriT). In the case of A. calcoaceticus, stable maintenance requires an RK2 segment that includes the promoter and the kilD (kilB1) functions of the trfA operon in addition to the 3.1-kb maintenance region. The broad-host-range maintenance requirements of plasmid RK2, therefore, are encoded by multiple functions, and the requirement for one or more of these functions varies among gram-negative bacterial species.     

New broad-host-range promoter probe vectors based on the plasmid RK2 replicon

Broad-host-range plasmid RK2-based promoter probe vectors with a known nucleotide sequence were constructed. In the absence of an upstream promoter, the expression of two tested reporter genes (luc and lacZ) in Escherichia coli was virtually zero, while insertion of the Ptrc promoter resulted in strong inducer-dependent expression. The lacZ-based vectors were mobilized into Pseudomonas fluorescens ST, Pseudomonas putida KT2442, Sphingomonas spp. and Burkholderia spp. LB400, and expression analyses indicated that the properties observed in E. coli are maintained across the species barriers. In addition, the previously established knowledge of RK2 molecular biology allows easy manipulations of features such as plasmid copy number, further extending the application potential of the vectors.     

DnaA protein is required for replication of the minimal replicon of the broad-host-range plasmid RK2 in Escherichia coli.

The minimal origin of replication of the broad-host-range plasmid RK2 has two potential recognition sequences for the DnaA protein of Escherichia coli. DNA transfer by transformation into a dnaA-null mutant of E. coli showed that DnaA protein is needed for replication or maintenance of mini-RK2. We isolated and purified DnaA protein as a chimeric protein, covalently attached to a piece of collagen and beta-galactosidase. The hybrid protein specifically bound to restriction fragments from the oriV region of RK2, which contained the two dnaA boxes. Deletion of the second dnaA box inactivated the origin and abolished the binding of the hybrid protein to the DNA fragment that had suffered the deletion. When the second dnaA box was replaced with an EcoRI linker of identical length, origin activity was restored. Binding experiments showed that the linker provided a weak dnaA box. An alternative explanation was that the linker restored proper spacing between sequences on either side of the deleted box, thus restoring origin activity.