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.     

Replication and incompatibility properties of segments of the origin region of replication of the broad host range plasmid RK2

Summary Replication and incompatibility properties in Escherichia coli of DNA segments from the replication origin region of plasmid RK2 have been investigated. A 393 bp HpaII fragment, derived from the region of the RK2 origin of replication, carries an active origin when essential RK2 encoded functions are provided in trans and will form a mini RK2 replicon when linked to a non-replicating selective fragment. This small ori _RK2 plasmid cannot stably coexist with other functional RK2 replicons and is thus incompatible with RK2 replicons. However, the 393 bp ori _RK2 segment when cloned into a high copy number plasmid, where plasmid maintenance is no longer dependent on ori _RK2, does not interfere with maintenance of a resident RK2 replicon. This is in contrast to larger segments from the origin region that, when cloned at high copy number, cause the loss of a resident RK2 replicon. The apparent ability of the small HpaII ori_RK2 plasmid to displace resident RK2 replicons may indicate the turning on of one incompatibility mechanism only when replication from ori _RK2is required or may simply reflect the strong selective pressure for establishment of the incoming ori _RK2 plasmid and poor ability of the HpaII ori _RK2 plasmid to replicate in the presence of another RK2 replicon. The incompatibility expressed by the functional HpaII ori _RK2 may be designated inc ₁. The activity of a segment of RK2, cloned at high copy number, to eliminate a resident RK2 plasmid has been localized to a region of RK2 DNA, designated the inc ₂ region, to distinguish it from inc ₁, above, that overlaps but does not coincide with the 393 bp HpaII ori _RK2. This inc ₂ region also appears to be involved in segregation of RK2 derivatives since removal of a portion of this region results in both higher copy number and increased instability of the RK2 derivative. In addition to defining the region of the RK2 origin of replication, these results indicate that the ability to eliminate a resident RK2 replicon can be expressed by fragments, cloned at high copy number, that do not contain the complete ori _RK2. Also, only part of the inc ₂ region that appears to be responsible for efficient elimination of RK2 replicons by fragments cloned at high copy number is required for ori _RK2.     

Conditional lethal mutants of the kilB determinant of broad host range plasmid RK2

We have examined the relationship of kilB to the other known determinants which map in the 14'-22' region of RK2. These are trfA, which encodes a diffusible replication function, and tra3, which specifies a function required for plasmid transmissibility. We found that, in addition to kilB, both tra3 and trfA functions are expressed by the cloned 14'-22' region of RK2. Four temperature-sensitive mutants of kilB were isolated by in vitro mutagenesis of the cloned segment. At 42 degrees C these mutant plasmids can be maintained in Escherichia coli cells which lack a korB+ helper plasmid. At 30 degrees C the helper plasmid is required. Our analysis of these mutants revealed that kilB function is distinct from those of trfA and tra3. One mutant plasmid was temperature-sensitive for maintenance of an RK2 ori plasmid, but this phenotype was shown to be independent of the KilB(ts) phenotype. Thus, kilB appears to be a separate new locus in this portion of the RK2 genome. In addition, these mutants allowed us to test for the existence of an essential replication determinant (trfB) in the 50.4'-56.4' region of RK2. Our results demonstrate that this region is non-essential for replication from the RK2 ori in E. coli. We propose an alternative hypothesis to explain the role of the RK2 trfB region for plasmid maintenance in E. coli.     

Proteins encoded by the trans-acting replication and maintenance regions of broad host range plasmid RK2

The broad host range plasmid RK2 has previously been found to contain three separate regions of the genome involved in replication and maintenance in Escherichia coli (C. M. Thomas, R. Meyer, D. R. Helinski, 1980, J. Bacteriol.141, 213–222). They include the origin of replication (ori_RK2) and the trfA region which encodes a trans-acting function required for replication. The third region (trfB), although not essential for replication, supplies a function involved in the maintenance of plasmid RK2. Using the maxicell system of labeling plasmid-specific proteins, we have identified all of the proteins encoded by two miniplasmid derivatives of RK2 which contain only the regions ori_RK2, trfA, and trfB. To determine which region specifies each protein, RK2/mini-ColE1 hybrid plasmids were used which contain various restriction fragments of the mini-RK2 replicon. The trfA region appears to encode three proteins designated A1 (39,000 MW), A2 (31,000 MW), and A3 (14,000 MW). Analysis of proteins synthesized by plasmids containing deleted forms of the trfA region indicates that the A2 protein is the essential trfA-encoded replication protein of plasmid RK2. The proteins A1 and A3 may be the products specified by the genes tra3 (involved in transmissibility) and kilB1 (involved in host-cell viability) which also map in the trfA region. The trfB region specifies two proteins designated B1 (36,000 MW) and B2 (30,000 MW). These may be the products of the two kil-override (kor) genes located in the trfB region which have been implicated in plasmid maintenance.     

Nucleotide sequence of the region of the origin of replication of the broad host range plasmid RK2

Summary A DNA sequence cosisting of 617 base pairs (bp) from the region of the origin of replication of the broad-host range plasmid RK2 has been determined. Included within this sequence is a 393 bp HpaII restriction fragment that provides a functional origin or replication when other essential RK2 specified functions are provided in trans. Also contained in this sequence is a region, distinguished functionally from the replication origin, which is involved in the expression of inc ₂ incompatibility, i.e., the ability of derivatives of RK2 to eliminate a resident RK2 plasmid. The 617 bp sequence includes eight 17 base pair direct repeats with 5 located within the region required for a functional replication origin and 3 within the region involved in inc ₂ incompatibility. In addition, a 40 bp region rich in A-T followed by a 60 bp stretch having a high G+C content is present. Deletion evidence indicates that the A-T rich and possibly the G+C regions are required for a functional replication origin. Based on the evidence contained in this and the preceding paper (Thomas et al. 1980 b) a model will be presented for the involvement of these specific sequences in the initiation of RK2 DNA replication, plasmid maintenance and plasmid incompatibility.     

Isolation and properties of temperature-sensitive mutants of the trfA gene of the broad host range plasmid RK2

Two small plasmid RK2 derivatives, pSV6 and pSV16, were constructed and used for the isolation and characterization of trfA mutants temperature-sensitive (ts) for replication in Escherichia coli. Four of the mutants were examined for their ability to initiate replication from the RK2 replication origin in E. coli when present in cis with respect to the origin and in trans when present on a multicopy pBR322 replicon. Each of the mutant trfA genes exhibited temperature-sensitivity in supporting replication from the RK2 origin when present in cis, and the lowest nonpermissive temperature varied depending on the mutant. When the mutant trfA genes were present on the multicopy replicon (in trans), three of the four mutant genes could support replication of the RK2-oriV plasmid pSV16 at all temperatures tested. However, with the exception of one of the mutants, the activity was reduced when compared to wild-type. The increased activity in trans possibly is the result of the increased cellular level of the TrfA protein when compared with the in cis situation where the mutant trfA gene is at a much lower copy-number. Two of the mutants also were tested in cis for temperature sensitivity in Pseudomonas aeruginosa. One of the mutants did not exhibit temperature sensitivity under the conditions employed. The second mutant showed some temperature sensitivity but the nonpermissive temperature pattern was different than that found in E. coli.     

Instability of a high-copy-number mutant of a miniplasmid derived from broad host range IncP plasmid RK2

Mini-RK2 plasmids pCT460 and pCT461 which contain the oriVRK2, trfA and trfB regions of RK2 in addition to tetracycline and kanamycin resistance determinants, have copy numbers of 17 and 35 copies per chromosome equivalent, respectively. The difference in copy number is due to a 56-bp deletion in oriVRK2 in pCT461. In Escherichia coli only pCT461 is markedly unstable in batch culture while both are unstable (although pCT461 is more so) in bacteria on stock plates. The instability of pCT461 in bacteria on stock plates is recA+ dependent and appears to involve loss of plasmid DNA from bacteria rather than selective cell death. After storage of recA+ bacteria carrying pCT461 for a few weeks the remaining antibiotic-resistant bacteria carry a mixture of plasmid DNA species including parental pCT461, transposable element insertion derivatives, and, by far the majority, deletion derivatives. It appears that one particular plasmid region, which includes the kilD gene (which inhibits plasmid maintenance in the absence of korD which, however, is present on pCT460 and pCT461), is responsible for this instability in a gene dosage-dependent way. Most of these deletion derivatives are dependent on pCT461-specified trfA gene (essential for replication) so that they do not displace pCT461 entirely. Their presence reduces the copy number of pCT461, thus reducing the instability, and is probably ultimately responsible for pCT461 survival on stock plates. In many bacteria the same process which gives rise to deletion derivatives may result in degradation of plasmid DNA extensive enough to cause loss of pCT461.     

Interactions of plasmid-encoded replication initiation proteins with the origin of DNA replication in the broad host range plasmid RK2

The TrfA proteins, encoded by the broad host range plasmid RK2, are required for replication of this plasmid in a variety of Gram-negative bacteria. Two TrfA proteins, 33 and 44 kDa in molecular mass (designated TrfA-33 and TrfA-44, respectively), are expressed from the trfA gene of RK2 through the use of two alternative in-frame start codons within the same open reading frame. The two proteins have been purified from Escherichia coli to near homogeneity as a mixture of wild-type TrfA-44/33, as TrfA-33 alone and as a functional variant form of TrfA-44, designated TrfA-44(98L), which contains a leucine in place of the TrfA-33 methionine start codon. Cross-linking experiments demonstrated that TrfA-33 can multimerize in solution. By using gel mobility shift and DNase I footprinting techniques the binding properties of TrfA-33, TrfA-44(98L), and TrfA-44/33 to the origin of replication of plasmid RK2 were analyzed. All three protein preparations were able to bind very specifically to the cluster of five direct repeats (iterons) contained in the minimal origin of replication. Each protein preparation produced a ladder of TrfA/minimal oriV complexes of decreasing electrophoretic mobility. The DNase I protection pattern on the five iterons was identical for all three protein preparations and extended from the beginning of the first iteron to 5 base pairs upstream of the fifth iteron. Studies on the affinity of the proteins for DNA fragments containing one, two, or all five iterons of the origin revealed a strong preference of TrfA protein for DNA containing at least two iterons. To study the stability of TrfA.DNA complexes, association and dissociation rates of TrfA-33 and DNA fragments with one, two, or five iterons were measured. This analysis showed that unlike complexes involving two or five iterons the TrfA/one iteron complexes were highly unstable, suggesting some form of cooperativity between proteins or iterons in the formation of stable complexes and/or the requirement of specific sequences bordering the iterons at the RK2 origin of replication for the stabilization of TrfA/DNA complexes.     

Deletion mapping of kil and kor functions in the trfA and trfB regions of broad host range plasmid RK2

Figurski et al. (1982) have reported that certain loci on the broad host range plasmid RK2 (kil functions) can be cloned only in the presence of other trans-acting segments of the plasmid genome (kor functions). They have suggested that the presence of these functions may in part account for the structure of mini RK2 replicons which were constructed in order to define the regions of the plasmid which encode replication/maintenance functions (Thomas et al. 1980). We have therefore investigated the relationship between these two sets of kil and kor loci and the loci implicated in the replication/maintenance of RK2. We find that, whilst the three kil loci reported by Figurski et al. (1982) are absent from these derivatives, a fourth such locus (kilD) is closely linked to trfA, a gene essential for RK2 replication. The kilD locus was probably responsible for the inclusion in mini replicons of a segment of RK2 DNA which carries both korD and korA in addition to trfB, a gene defined by a temperature-sensitive maintenance defect, but which can be deleted leaving a functional RK2 replicon (Thomas 1981 b). The kilB locus is situated on the opposite side of kilD from trfA, all three loci lying within a 3.6 kb segment of RK2 DNA. The korA, korD and trfB functions all map within a 900 bp segment of DNA, while korB requires sequence information at least 1.5 kb from this segment.     

The trfA and trfB promoter regions of broad host range plasmid RK2 share common potential regulatory sequences

The positions of the trfA and trfB promoters of broad host range IncP plasmid RK2 (identical to RP1, RP4, R68 and R18 ) were identified by RNA polymerase protection studies, and the nucleotide sequences of the promoter regions determined. A mutation within the trfA promoter sequence is associated with loss of kilD activity. In addition a probable promoter region for the kilB locus was identified. The three promoter regions share common palindromic sequences which may serve as sites for the coordinate regulation of replication and kil functions.     

Generation in vitro of deletions in the broad host range plasmid RK2 using phage Mu insertions and a restriction endonuclease

Several non-lethal deletions of the broad host range plasmid RK2 (molecular weight of 37.6 . 10(6) have been produced in vitro. The method employed relied on the single HindIII restriction nuclease site in RK2 and the ability of phage Mu to insert and thereby add new HindIII restriction sites at various positions in the plasmid. The deleted plasmids have in each case lost kanamycin (Km) resistance, and in two cases are defective in self-transmissibility. The method used to reduce the size of the RK2 plasmid also results in the cloning of each of the two ends of the Mu phage DNA on the plasmid derivatives.     

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.     

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.