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.     

Replication of derivatives of the broad host range plasmid RK2 in two distantly related bacteria

A 0.7-kb segment of the broad host range plasmid RK2 containing the replication origin of this plasmid will replicate in Escherichia coli and Pseudomonas putida when this segment is joined to a 1.8-kb region of RK2 designated traA*. The presence of another region of RK2, designated trfB, that previously was implicated in RK2 replication had no effect on the maintenance of the RK2 trfA*-oriV replicon in these two organisms. These observations indicate a requirement for a minimal account of information for replication of this broad host range plasmid in two distantly related bacteria.     

Physical and genetic studies with restriction endonucleases on the broad host-range plasmid RK2.

The cleavage map of the plasmid RK2 was determined for the five restriction endonucleases EcoRI, HindIII, BamH-I, SalI and HpaI. DNA has been inserted into several of these sites and cloned in Escherichia coli. Efforts to obtain derivatives of RK2 reduced in size by restriction endonuclease digestion of the plasmid were not successful and indicated that genes required for the maintenance of this plasmid in E. coli are not tightly clustered. An RK2 derivative possessing an internal molecular rearrangement was obtained by transformation with restriction endonuclease digests of the plasmid.     

Multiple mechanisms for expression of incompatibility by broad-host-range plasmid RK2

By cloning fragments of plasmid DNA, we have shown that RK2 expresses incompatibility by more than one mechanism. One previously identified (R. J. Meyer, Mol. Gen, Genet. 177:155--161, 1979; Thomas et al., Mol. Gen. Genet. 181:1--7, 1981) determinant for incompatibility is linked to the origin of plasmid DNA replication. When cloned into a plasmid vector, this determinant prevents the stable inheritance of a coresident RK2. However, susceptibility to this mechanism of incompatibility requires an active RK2 replicon and is abolished if another replicator is provided. We have also cloned a second incompatibility determinant, encoded within the 54.1- to 56.4-kilobase region of RK2 DNA, which we call IncP-1(II). An RK2 derivative remains sensitive to IncP-1(II), even when it is not replicating by means of the RK2 replicon. The 54.1- to 56.4-kilobase DNA does not confer susceptibility to the IncP-1(II) mechanism, nor does it encode a detectable system for efficient plasmid partitioning. The incompatibility may be related to the expression of genes mapping in the 54.1- to 56.4-kilobase region, which are required for plasmid maintenance and suppression of plasmid-encoded killing functions.     

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.     

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.     

Location of the relaxation complex nick site within the minimal origin of transfer region of RK2

Transfer of plasmid DNA during bacterial conjugation begins at a specific site: the origin of transfer (oriT). The oriT region of the broad host range plasmid RK2 is located on a 250 bp fragment. Deletions involving either end of this region reduce transfer function, indicating that an extended sequence is required for optimal oriT activity. The single-strand nick induced by the RK2 DNA-protein relaxation complex is located adjacent to the 19 bp inverted repeat within the minimal oriT sequence. These results provide strong evidence that the plasmid relaxation event induced in vitro represents the nicking reaction that initiates DNA transfer at oriT during conjugation.     

Distribution of the partitioning protein KorB on the genome of IncP-1 plasmid RK2

The ParB family partitioning protein, KorB, of plasmid RK2 is central to a regulatory network coordinating replication, maintenance and transfer genes. Previous immunofluorescence microscopy indicated that the majority of KorB is localized in plasmid foci. The 12 identified KorB binding sites on RK2 are differentiated by: position relative to promoters; binding strength; and cooperativity with other repressors and so the distribution of KorB may be sequestered around a sub-set of sites. However, chromatin immunoprecipitation analysis showed that while RK2 DNA molecules appear to sequester KorB to create a higher local concentration, cooperativity between DNA binding proteins does not result in major differences in binding site occupancy. Thus under steady state conditions all operators are close to fully occupied and this correlates with gene expression on the plasmid being highly repressed.     

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.     

Conserved C-terminal region of global repressor KorA of broad-host-range plasmid RK2 is required for co-operativity between KorA and a second RK2 global regulator, KorB.

KorA and KorB proteins of IncP1 plasmid RK2 are encoded in the central control region (ccr) of the plasmid and act as global regulators of plasmid genes for replication, transfer and stable inheritance. KorA represses seven promoters on RK2, by binding to a defined operator site, OA, which always occurs in promoter regions. KorB recognises another operator, OB, which is found 12 times on the RK2 genome, but not always in promoter regions. At five of the KorA-regulated promoters, an OBsequence is also present. The presence of both KorA and KorB leads to severely decreased promoter activity. By measuring repression at different levels of KorA and KorB alone and in combination, we showed that there is at least 3. 4-fold co-operativity between them at korApin vivo. Testing the ability of previously isolated KorA mutants to act in a co-operative way in the presence of KorB in vivo or in vitro showed that the C-terminal part of KorA between amino acid positions 68 and 83 is required for this co-operativity. This region is part of a segment that is highly conserved between KorA and two other RK2 proteins, TrbA and KlcB. We propose that this conserved region may provide the basis for co-operativity with KorB either indirectly, by modulating DNA structure near the KorB binding site, or directly by serving as the "recognition" patch of each protein by KorB. It may thus serve as a key domain in allowing a sensitive response of the global circuits to changes in repressor concentration and thus modulation of replication, transfer and maintenance.     

The kilE locus of promiscuous IncP alpha plasmid RK2 is required for stable maintenance in Pseudomonas aeruginosa.

Eight coordinately regulated operons constitute the kor regulon of the IncP alpha plasmid RK2. Three operons specify functions required for replication initiation, conjugative transfer, and control of gene expression. The functions of the other operons, including those of the four coregulated operons that compose the kilA, kilC, and kilE loci, have not been determined. Here, we present the first evidence that a kil determinant is involved in IncP plasmid maintenance. Elevation of KorC levels specifically to reduce the expression of the KorC-regulated kilC and kilE operons severely affected the maintenance of both the IncP alpha plasmid RK2lac and the IncP beta plasmid R751 in Pseudomonas aeruginosa but had little effect on plasmid maintenance in Escherichia coli. Precise deletion of the two kilE operons from RK2lac was achieved with the VEX mutagenesis system for large genomes. The resulting plasmid showed significant loss of stability in P. aeruginosa only. The defect could be complemented by reintroduction of kilE at a different position on the plasmid. The instability of the RK2lac delta kilE mutant did not result from a reduction in average plasmid copy number, reduced expression of kilC, decreased conjugative transfer, or loss of the korE regulator. We found that both the par and kilE loci are required for full stability of RK2lac in P. aeruginosa and that the par and kilE functions act independently. These results demonstrate a critical role for the kilE locus in the stable inheritance of RK2 in P. aeruginosa.     

Physical and genetic studies with restriction endonucleases on the broad host-range plasmid RK2

Summary The cleavage map of the plasmid RK2 was determined for the five restriction endonucleases EcoRI, HindIII, Bam H-I, Sal I and Hpa I. DNA has been inserted into several of these sites and cloned in Escherichia coli. Efforts to obtain derivatives of RK2 reduced in size by restriction endonuclease digestion of the plasmid were not successful and indicated that genes required for the maintenance of this plasmid in E. coli are not tightly clustered. An RK2 derivative possessing an internal molecular rearrangement was obtained by transformation with restriction endonuclease digests of the plasmid.     

Complementation analysis of replication and maintenance functions of broad host range plasmids RK2 and RP1

It has previously been concluded that regions tentatively designated trfA and trfB, located at 16–18.7 and 54–56 kb, respectively, on the genome of broad host range plasmid RK2 provide trans-acting functions involved in plasmid replication and maintenance in Escherichia coli (Thomas et al., 1980). A third region, the replication origin, ori_RK2, located at 12 kb on the genome, is also required. A segment of DNA containing ori_RK2 can be linked to a nonreplicating selective marker and can replicate as an autonomous plasmid so long as DNA of RK2 carrying the gene for one or more trans-acting replication functions is present in the same cell on an independent plasmid or integrated into the chromosome. It is demonstrated here that the trfA region alone can provide the trans-acting functions necessary for replication from ori_RK2. Deletion of the trfB region in trans to an ori_RK2 plasmid does not correlate with alteration in copy number or stability of the ori_RK2 plasmid. Temperature-sensitive mutants defective in plasmid maintenance can apparently arise from mutations in both the trfA and trfB regions as indicated by complementation analysis of three different mutants. The trfA and trfB regions from two mutant plasmids have been cloned and used to allow a physically separate but functionally dependent ori_RK2 plasmid to replicate at 30 °C. When the source of trfA and trfB is a trfB mutant the ori_RK2 plasmid is temperature stable but is temperature sensitive when the source is a trfA mutant. This confirms that only trfA is essential for initiation at and elongation from ori_RK2 which is probably the primary event in RK2 replication and suggests that the trfB region plays some other role in plasmid maintenance in plasmids carrying all three regions, ori_RK2, trfA, and trfB.     

Genetic organization of the broad-host-range IncP-1 plasmid R751.

We have identified regions encoding conjugal transfer, plasmid maintenance, and trimethoprim resistance on the IncP-1 plasmid R751 by complementation tests with cloned deoxyribonucleic acid fragments and self-replicating derivatives constructed in vitro. The genes for replication and transfer show a scattered organization similar to that previously determined for RK2, another IncP-1 plasmid. Derivatives of RK2 are able to complement R751 derivatives defective in these functions. Restriction enzyme cleavage sites in R751 deoxyribonucleic acid are clustered in regions of the plasmid physical map. Neither region is required for plasmid maintenance or transfer, although one determines resistance to trimethoprim. A similar clustering of cleavage sites is seen with RK2, which nevertheless has a very different restriction map.     

Suppression of Co1E1 replication properties by the Inc P-1 plasmid RK2 in hybrid plasmids constructed in vitro.

Hybrid plasmids were constructed in vitro by linking the Inc P-1 broad host range plasmid RK2 to the colicinogenic plasmid ColE1 at their EcoRI endonuclease cleavage sites. These plasmids were found to be immune to colicin E1, non-colicin-producing, and to exhibit all the characteristics of RK2 including self-transmissibility. These joint replicons have a copy number of 5 to 7 per chromosome which is typical of RK2, but not ColE1. Unlike ColE1, the plasmids will not replicate in the presence of chloramphenicol and are maintained in DNA polymerase I mutants of Escherichia coli. In addition, only RK2 incompatibility is expressed, although functional ColE1 can be rescued from the hybrids by EcoRI cleavage. This suppression of ColE1 copy number and incompatibility was found to be a unique effect of plasmid size on ColE1 properties. However, the inhibition of ColE1 or ColE1-like plasmid replication in chloramphenicol-treated cells is a specific effect of RK2 or segments of RK2 (Cri⁺ phenotype). This phenomenon is not a function of plasmid size and requires covalent linkage of RK2 DNA to ColE1. A specific region of RK2 (50.4 to 56.4 × 10³ base-pairs) cloned in the ColE1-like plasmid pBR313 was shown to carry the genetic determinant(s) for expression of the Cri⁺ phenotype.     

Different relative importances of the par operons and the effect of conjugal transfer on the maintenance of intact promiscuous plasmid RK2.

The par region of the broad-host-range, IncP alpha plasmid RK2 has been implicated as a stability determinant by its ability to enhance the maintenance of mini-RK2 plasmids or heterologous replicons in a growing population of host cells. The region consists of two operons: parCBA, which encodes a multimer resolution system, and parDE, which specifies a postsegregational response mechanism that is toxic to plasmidless segregants. To assess the importance of this region to the stable maintenance of the complete RK2 plasmid in different hosts, we used the vector-mediated excision (VEX) deletion system to specifically remove the entire par region or each operon separately from an otherwise intact RK2 plasmid carrying a lacZ marker. The par region was found to be important to stable maintenance of RK2lac (pRK2526) in Escherichia coli and five other gram-negative hosts (Agrobacterium tumefaciens, Azotobacter vinelandii, Acinetobacter calcoaceticus, Caulobacter crescentus, and Pseudomonas aeruginosa). However, the relative importance of the parCBA and parDE operons varied from host to host. Deletion of parDE had no effect on the maintenance of pRK2526 in A. calcoaceticus, but it severely reduced pRK2526 maintenance in A. vinelandii and resulted in significant instability in the other hosts. Deletion of parCBA did not alter pRK2526 stability in E. coli, A. tumefaciens, or A. vinelandii but severely reduced plasmid maintenance in A. calcoaceticus and P. aeruginosa. In the latter two hosts and C. crescentus, the delta parCBA mutant caused a notable reduction in growth rate in the absence of selection for the plasmid, indicating that instability resulting from the absence of parCBA may trigger the postsegregational response mediated by parDE. We also examined the effect of the conjugal transfer system on RK2 maintenance in E. coli. Transfer-defective traJ and traG mutants of pRK2526 were stably maintained in rapidly growing broth cultures. On solid medium, which should be optimal for IncP-mediated conjugation, colonies from cells containing the pRK2526 tra mutants displayed significant numbers of white (Lac-) sectors on X-Gal (5-bromo-4-chloro-3-indolyl-beta-D-galactopyranoside) plates, whereas sectors appeared rarely in colonies from tra+ plasmid-containing cells. Both the traJ and traG mutations further reduced the maintenance of the already unstable deltapar derivative. Thus, these experiments with defined mutations in an intact RK2 plasmid have revealed (i) that the par region allows RK2 to adapt to the different requirements for stable maintenance in various hosts and (ii) that conjugal transfer can contribute to the maintenance of RK2 in a growing population, particularly under conditions that are favorable to RK2 transfer.     

Gram negative shuttle BAC vector for heterologous expression of metagenomic libraries

Bacterial artificial chromosome (BAC) vectors enable stable cloning of large DNA fragments from single genomes or microbial assemblages. A novel shuttle BAC vector was constructed that permits replication of BAC clones in diverse Gram-negative species. The "Gram-negative shuttle BAC" vector (pGNS-BAC) uses the F replicon for stable single-copy replication in E. coli and the broad-host-range RK2 mini-replicon for high-copy replication in diverse Gram-negative bacteria. As with other BAC vectors containing the oriV origin, this vector is capable of an arabinose-inducible increase in plasmid copy number. Resistance to both gentamicin and chloramphenicol is encoded on pGNS-BAC, permitting selection for the plasmid in diverse bacterial species. The oriT from an IncP plasmid was cloned into pGNS-BAC to enable conjugal transfer, thereby allowing both electroporation and conjugation of pGNS-BAC DNA into bacterial hosts. A soil metagenomic library was constructed in pGNS-BAC-1 (the first version of the vector, lacking gentamicin resistance and oriT), and recombinant clones were demonstrated to replicate in diverse Gram-negative hosts, including Escherichia coli, Pseudomonas spp., Salmonella enterica, Serratia marcescens, Vibrio vulnificus and Enterobacter nimipressuralis. This shuttle BAC vector can be utilized to clone genomic DNA from diverse sources, and then transfer it into diverse Gram-negative bacterial species to facilitate heterologous expression of recombinant pathways.     

The sequence encoding the 43-kilodalton trfA protein is required for efficient replication or maintenance of minimal RK2 replicons in Pseudomonas aeruginosa

The trfA gene of the broad-host-range plasmid RK2 encodes two proteins of 43- and 32-kDa by initiating translation at either of two in-phase AUG codons in a single open reading frame. At least one of these proteins is essential for replication of RK2 derivatives. In order to study the role of the 43-kDa protein, Bal31 deletions into the 5' end of the trfA gene were constructed and incorporated into minimal RK2 replicons. When examined in Escherichia coli, replication and maintenance properties of plasmids encoding only the 32-kDa protein were indistinguishable from those of plasmids encoding both the 43- and the 32-kDa proteins. In four other gram-negative hosts deletion of sequences encoding only the 43-kDa protein did not have a substantial effect on plasmid establishment or stable maintenance. However, in Pseudomonas aeruginosa, deletion of 43-kDa coding sequences greatly reduced the efficiency of plasmid maintenance, suggesting a host-specific role for the 43-kDa TrfA protein in RK2 replication.