Control of replication and segregation of R plasmid Rts1.

A mutant plasmid, pTW2, which was derived from the integrated Rst1 genome in the Escherichia coli chromosome, was studied as to its mode of replication at 30 degrees C. When Proteus mirabilis Pm17 harboring pTW2 was grown in broth at 30 degrees C, a considerable number of R- segregants (approximately 40%) were consistently observed. This indicates that pTW2 is unstable even at the permissive temperature for the replication of Rts1. The pTW2+ cells in a culture were heterogeneous with respect to the level of kanamycin resistance, ranging from 500 to 4,000 mug of the drug per ml. The amount of pTW2 deoxyribonucleic acid (DNA) relative to the Pm17 chromosomal DNA was about fivefold as large as that of Rts1 DNA in an exponentially growing culture. In addition, pTW2 in P. mirabilis continued to replicate after the chromosome had ceased to replicate, which was shown in the study of the inhibition of protein synthesis. Contrary to pTW2, the parent plasmid Rts1 is highly stable, and the relative percent Rts1 DNA is maintained at approximately 7% in any cultural conditions at a permissive temperature. These results suggest that copies of pTW2 may not segregate evenly into the host progeny upon cell division and that the replication of pTW2 does not coordinate with that of the chromosome. A remarkable instability of pTW2 as well as an increase in the relative percent pTW2 DNA was also shown when E. coli were used as the host cells. These results suggest the possibility that there is a gene or a gene cluster on the Rst1 genome responsible for the control of both replication and segregation of Rts1.     

Molecular cloning and mapping of a deletion derivative of the plasmid Rts 1

The plasmid pTW20 is a deletion derivative of the kanamycin resistance plasmid Rts1. By digesting pTW20 DNA with EcoRI endonuclease six fragments were generated, and each was cloned in the vector plasmid pACYC184. These cloned EcoRI fragments were further digested with various endonucleases, and the cleavage map of pTW20 was constructed. A SalI fragment (1.5 Md) in E1 (the largest EcoRI fragment; 11.5 Md) contained the genes kan (kanamycin resistance) and puv (uv sensitization of host). An electron microscopy study of a BamHI fragment containing kan revealed the presence of a transposon-like structure in the fragment. The smallest EcoRI fragment E6 (2.0 Md) was capable of autonomous replication in a polA host, indicating that E6 contained replication genes of pTW20. These genes were found to be located on a 1.1-Md HindIII fragment in E6. Two incompatibility genes were identified on the pTW20 genome, one located on each of the fragments E6 and E5 (3.5 Md), and expressed T incompatibility independently. The nature of the temperature sensitivity of pTW20 was discussed.     

Nucleotide sequence and copy control function of the extension of the incI region (incI-b) of Rts 1

An Rts1 derivative, pTW20, contains three incompatibility (inc) regions, incI-a (incI in previous studies), incII, and newly determined incI-b loci. By restriction analysis, we have located the incI-b adjacent to the incI-a region on the pTW20 map. Nucleotide sequence analysis of the minimal incI-b region revealed the presence of four repeated sequences, each consisting of 18 bp, which is similar to the incI-a and incII repeats existing on mini-Rts1. All four repeating units were required for expression of a strong incompatibility. In addition, RepA protein, essential for the replication of Rts1, bound specifically to the repeated sequences, suggesting that the repeats would titrate out RepA protein as do incI-a and IncII. Insertion of the incI-b to a mini-Rts1 plasmid in a natural arrangement decreases the copy number of mini-Rts1 to the same level as that of mini-F. The incI-a and incI-b might be a single constituent in incompatibility and copy number control of Rts1.     

Importance of the C terminus of plasmid Rts1 RepA protein for replication and incompatibility of the plasmid.

RepA protein, essential for replication of plasmid Rts1, was found to bind in vivo immediately upstream of the repA promoter in studies with mini-Rts1 derivatives with deletions in the upstream region of repA. We constructed another series of repA mutants that would encode RepA derivatives containing oligopeptide substitutions in place of the carboxyl-terminal six amino acids. These modified RepA proteins could not activate ori (Rts1) at all and showed various degrees of incompatibility, or no incompatibility, toward a mini-Rts1 plasmid. These results suggest that the carboxyl-terminal six (or fewer) amino acids of RepA are important for exerting replication and incompatibility functions. One of the RepA derivatives, which showed an evident incompatibility without initiating replication, was examined for its ability to repress the repA gene.     

Host-dependent, thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae.

The thermosensitive replication of an R plasmid, pJY5, isolated from Enterobacter cloacae, was studied. pJY5 consisted of 61 million daltons of covalently closed circular (CCC) deoxyribonucleic acid (DNA) with a buoyant density of 1.714 g/cm3 (55 mol % guanine plus cytosine). In Escherichia coli, this plasmid replicated stringently at 32 degrees C, but ceased its CCC DNA replication after a short incubation at 42 degrees C, resulting in production of R- segregants. The thermosensitive replication of pJY5 was not overcome by the coexistence of non-thermosensitive R plasmids. The plasmid manifested an inhibitory effect on host bacterial cell growth at 42 degrees C, although the effect was less prominent than that of R plasmids belonging to the T-incompatibility group, Rts1, R401, and R402. When the pJY5 plasmid was transferred into E. cloacae, however, no R- segregants were detected at any culture temperature, even 42 degrees C. Alkaline sucrose gradient analysis revealed that a significant amount of pJY5 CCC DNA was synthesized in E. cloacae at the high temperature but not in E. coli. Furthermore, the growth-inhibitory effect of pJY5 on hosts at 42 degrees C was not observed in E. cloacae. On the other hand, Rts1 and R401 were found to be thermosensitive in E. cloacae as well as in E. coli.     

Cloning of the replication and incompatibility regions of a plasmid derived from Rts1

A replication region, consisting of a 1.1-megadalton (Md) EcoRI/HindIII fragment, was isolated from an Rts1 derivative plasmid. This 1.1-Md fragment, designated as mini-Rts1, was ligated to either pBR322 or a nonreplicating DNA fragment specifying a drug resistance, and its replication properties were investigated. The mini-Rts1 plasmid was cured at a high frequency at 42 °C, while it was maintained stably at 37 °C despite it existed in low copy number. These behaviors are quite similar to those of Rts1. By dissecting the pBR322:mini-Rts1 chimeric plasmid with AccI endonuclease, an inc region of 0.34 Md in size was cloned, which expressed incompatibility toward Rts1. Proteins encoded on the mini-Rts1 genome were examined in the minicell system, and one specific product of 35,000 daltons in molecular weight was identified. Any polypeptides specific for the 0.34-Md inc⁺ region within mini-Rts1 were not detected.     

Effects of mutations in the repA gene of plasmid Rts1 on plasmid replication and autorepressor function.

We constructed a system in which wild-type RepA or RepAcop1 protein was supplied in trans in various amounts to coexisting mini-Rts1 plasmids by clones of the repA or repAcop1 gene under the control of the native promoter with or without its operator sequence. RepAcop1 protein which contains a single amino acid substitution (Arg-142 to Lys) within its 288 amino acids could initiate the replication of the mini-Rts1 plasmid efficiently at both 37 and 42 degrees C even if it was supplied in excess. In contrast, excess wild-type RepA inhibited plasmid replication at 37 degrees C but supported replication at 42 degrees C. Therefore, it appears that the initiator activity of RepA is not related to the incompatibility phenotype associated with an excess of RepA protein. An immunoblot analysis revealed that neither RepA nor RepAcop1 synthesis was temperature sensitive and that both were autogenously regulated to a similar extent because of the presence of an operator located immediately upstream of the promoter. Two mutant RepA proteins, each of which contains a 4-amino-acid insertion in the middle of the protein, maintained the autorepressor and incompatibility activities but lost the ori(Rts1)-activating function.     

Integration of R plasmid Rts1 to the gal region of the Escherichia coli chromosome.

An R plasmid Rts1 was integrated into the gal region of the chromosome of Escherichia coli XA-7012 (galE) strain by the directed transposition technique. The integration of the Rts1 genome was confirmed mainly by conjugation studies and also by transduction experiments using phage P1. As a result, it was found that the integrated genome contained genes responsible for kanamycin resistance, conjugal transferability, and for autonomous replication. As reported previously, Rts1 is temperature sensitive in replication and inhibits the growth of the host at nonpermissive temperature. However, although a plasmid derived from the integrated Rts1 genome still demonstrates temperature sensitivity upon transfer and high level of kanamycin resistance, this plasmid no longer displays temperature sensitivity in replication and the inhibitory effect on the host. These results indicate that the temperature sensitivity of replication of Rts1 and its inhibitory effect on the host cell are due to the presence of a gene or gene cluster on the Rts1 genome and that the gene(s) is clearly discriminated from the one responsible for the temperature sensitivity of transfer.     

Acceptance and transfer of plasmid Rts1 by bacteria of the genus Erwinia]

The ability of 13 Erwinia strains to accept, to inherit and to transmit the Rts1 factor by conjugation was studied. 11 strains accepted the Rts1 factor from Escherichia coli K-12 CSH-2 with the frequency of about 10(-7)--10(-3). The Rts1 factor was genetically stable in the Erwinia cells and was not eliminated by acriflavine and under the temperature of 37 and 42 degrees C. All the R+ exconjugants were characterized with more high degree of the resistance of kanamycin than E. coli cells harbouring the same R factor. Erwinia strains harbouring the Rts1 plasmid transferred it by conjugation into homologic (Erwinia) and heterologic (E. coli) bacteria. The study of kinetics of the transfer of the Rts1 factor in different mating systems showed that the transfer of this plasmid from R+ Erwinia into R- Erwinia and R- E. coli--in the liquid medium. It is concluded that Erwinia can be the host and the donor of the Rts1 factor.     

The region controlling the thermosensitive effect of plasmid Rts1 on host growth is separate from the Rts1 replication region.

Rts1 is a high-molecular-weight (126 x 10(6)) plasmid encoding resistance to kanamycin. It expresses unusual temperature-sensitive phenotypes, which affect plasmid maintenance and replication, as well as host cell growth. We have cloned the essential replication region of Rts1 from pAK8, a smaller derivative which is phenotypically similar to Rts1. Restriction endonuclease digests of isolated pAK8 deoxyribonucleic acid were allowed to "self-ligate" (ligation without an additional cloning vector) and subsequently were used to transform Escherichia coli strain 20SO to kanamycin resistance. Screening of these strains for the phenotypes of thermosensitive host growth and temperature-dependent plasmid elimination demonstrated that these two properties were expressed independently. Furthermore, it was shown that the Rts1 replication locus per se is not necessarily responsible for altered host growth at the nonpermissive temperature. The kanamycin resistance fragment of pAK8 was also cloned into pBR322. Electrophoretic analysis of BamHI restriction enzyme digests of this plasmid and similar digests of an Rts1 miniplasmid has allowed the identification of an 18.6-megadalton fragment carrying the replication locus and a 14.1-megadalton fragment carrying the kanamycin resistance gene.     

Site-directed mutations in the repA C-terminal region of plasmid Rts1: pleiotropic effects on the replication and autorepressor functions.

We induced site-directed mutations near the 3' terminus of the gene repA, which encodes the protein of 288 amino acid residues essential for plasmid Rts1 replication, and obtained seven repA mutants. Three of them contained small deletions at the 3' terminus. Mutant repAz delta C4, which encodes a RepA protein that lacks the C-terminal four amino acids, expressed a high-copy-number phenotype and had lost both autorepressor and incompatibility functions. Deletion of one additional amino acid residue to form the RepAz delta C5 protein caused restoration of the wild-type copy number and strong incompatibility. Studies of the remaining four repA mutants, each of which contained a single amino acid substitution near the RepA C terminus, suggested that Lys-268 is involved in both ori(Rts1) activation and autorepressor-incompatibility activities and that Arg-279 contributes to ori(Rts1) activation but not to incompatibility. Lys-268 is part of a dual-lysine sequence with Lys-267 and is located 21 amino acids upstream of the RepA C terminus. A dual-lysine sequence is also found at a similar position in both mini-F RepE and mini-P1 RepA proteins.     

Plasmid replication functions: two distinct segments of plasmid R1, RepA and RepD, express incompatibility and are capable of autonomous replication.

The genetic determinants for replication and incompatibility of plasmid R1 were investigated by gene cloning methods, and three types of R1 miniplasmid derivatives were generated. The first, exemplified by plasmid pKT300, consisted of a single BglII endonuclease-generated deoxyribonucleic acid fragment derived from the R1 region that is located between the determinants for conjugal transfer and antibiotic resistance. Two types of miniplasmids could be formed from PstI endonuclease-generated fragments of pKT300. One of these, which is equivalent to miniplasmids previously generated from plasmids R1-19 and R1-19B2, consisted of two adjacent PstI fragments that encode the RepA replication system of plasmid R1. The other type contained a segment of R1, designated the RepD replication region, that is adjacent to the RepA region and that has not been identified previously as having the capacity for autonomous replication. Plasmid R1, therefore, contained two distinct deoxyribonucleic acid segments capable of autonomous replication. The RepA-RepD miniplasmid pKT300 had a copy number about eightfold higher than that of R1 and hence lacked a determinant for the regulation of plasmid copy number. Like R1, it was maintained stably in dividing bacteria. RepA miniplasmids had copy numbers which were two- to fourfold higher than that of R1 (i.e., which were lower than that of pKT300) and were maintained slightly less stably than those of pKT300 and R1. The RepD miniplasmid was not maintained stably in dividing bacteria. Previous experiments have shown that incompatibility of IncFII group plasmids is specified by a plasmid copy control gene. Despite the fact that RepA miniplasmids of R1 were defective in copy control, they nevertheless expressed incompatibility. This suggests that two genes are responsible for plasmid copy control, one that specifies incompatibility and is located on RepA miniplasmids and another that is located outside of, but adjacent to, the RepA replication region. Hybrid plasmids composed of pBR322 and one PstI fragment from the RepA region, P-8, exhibited incompatibility towards R2 and RepA miniplasmids but not the RepD miniplasmid, whereas hybrids composed of pBR322 and the PstI fragment of the RepD region, P-3, exhibited incompatibility towards R1 and the RepD miniplasmid but not RepA miniplasmids. These results indicate that the two replication systems are functionally distinct and that, although the RepA system is the principal replication system of R1, the RepD system also plays a role in the maintenance of this plasmid.     

Chromosome-plasmid interaction in Escherichia coli K-12 carrying a thermosensitive plasmid, Rts1, in autonomous and in integrated states.

An Hfr strain of Escherichia coli K-12 was obtained by integrative suppression with a thermosensitive plasmid, Rts1. The R plasmid was integrated into the chromosome between rif and thr, and transfer of the chromosome occurred counterclockwise. The thermosensitivity of host cell growth due to the dnaA mutation was markedly but not completely reduced in this integratively suppressed Hfr strain. When the dnaA mutation was removed by transducing the dnaA+ genome to this Hfr, the thermosensitivity of cell growth due to existence of Rts1 was suppressed in contrast to strains carrying it autonomously. Thermosensitivity of cell growth appeared again when the plasmid was detached from the chromosome to exist autonomously. Contrary to the effect on cell growth, the transfer of the chromosome and the plasmid itself and the ability to "restrict" T-even phages were still thermosensitive in all of these strains carrying Rts1, irrespective of its state of existence. The detached plasmid as well as the original Rts1 were segregated upon growth at 42 C. These data are discussed in relation to chromosome-plasmid interaction. One of the most important conculusions is that some plasmid genes, related to their replication, are phenotypically suppressed by the chromosome when it is integrated.     

The incompatibility product of IncFII R plasmid NR1 controls gene expression in the plasmid replication region.

The incompatibility properties of IncFII R plasmid NR1 were compared with those of two of its copy number mutants, pRR12 and pRR21. pRR12 produced an altered incompatibility product and also had an altered incompatibility target site. The target site appeared to be located within the incompatibility gene, which is located more than 1,200 base pairs from the plasmid origin of replication. The incompatibility properties of pRR21 were indistinguishable from those of NR1. Lambda phages have been constructed which contain the incompatibility region of NR1 or of one of its copy mutants fused to the lacZ gene. In lysogens constructed with these phages, beta-galactosidase was produced under the control of a promoter located within the plasmid incompatibility region. Lysogens containing prophages with the incompatibility regions from pRR12 and pRR21 produced higher levels of beta-galactosidase than did lysogens containing prophages with the incompatibility region from the wild-type NR1. The introduction into these inc-lac lysogens of pBR322 plasmids carrying the incompatibility regions of the wild-type or mutant plasmids resulted in decreased levels of beta-galactosidase production. For a given lysogen, the decrease was greater when the pBR322 derivative expressed a stronger incompatibility toward the plasmid from which the fragment in the prophage was derived. This suggested that the incompatibility product acts on its target to repress gene expression in the plasmid replication region.     

DNA segments of the IncX plasmid R485 determining replication and incompatibility with plasmid R6K

The expression of incompatibility properties between the IncX plasmids R6K and R485 of Escherichia coli was examined. For small autonomously replicating derivatives of both plasmid elements, the requirements for incompatibility expression include a functional R485 replicon and an active R6K beta-origin region. Functional R6K alpha and gamma origins are not directly involved in incompatibility expression between R6K and R485. A trans-acting replication system was constructed for plasmid R485. It consists of a 3.2-(kb) DNA fragment of R485 that specifies a product(s) in trans which supports replication from an R485 origin plasmid. A minimal R485 origin region of 591 bp was derived utilizing this trans-acting replication system and the nucleotide sequence of this origin region determined. The most striking feature of the sequence is the presence of six tandem 22-bp nucleotide sequence direct repeats.     

Complete nucleotide sequence of plasmid Rts1: implications for evolution of large plasmid genomes

Rts1, a large conjugative plasmid originally isolated from Proteus vulgaris, is a prototype for the IncT plasmids and exhibits pleiotropic thermosensitive phenotypes. Here we report the complete nucleotide sequence of Rts1. The genome is 217,182 bp in length and contains 300 potential open reading frames (ORFs). Among these, the products of 141 ORFs, including 9 previously identified genes, displayed significant sequence similarity to known proteins. The set of genes responsible for the conjugation function of Rts1 has been identified. A broad array of genes related to diverse processes of DNA metabolism were also identified. Of particular interest was the presence of tus-like genes that could be involved in replication termination. Inspection of the overall genome organization revealed that the Rts1 genome is composed of four large modules, providing an example of modular evolution of plasmid genomes.     

Genes and sites involved in replication and incompatibility of an R100 plasmid derivative based on nucleotide sequence analysis

Summary The nucleotide sequence of the entire region required for autonomous replication and incompatibility of an R100 plasmid derivative, pSM1, has been determined. This region includes the replication region and all plasmid encoded information required for replication. Numerous reading frames for possible proteins can be found in this region. The existence of one of these proteins called RepA1 (285 amino acids; 33,000 daltons) which is encoded within the region known by cloning analysis to be required for replication is supported by several lines of evidence. These include an examination of the characteristic sequences on the proximal and distal ends of the coding region, a comparison of the sequence of the replication regions of pSM1 and the highly related R1 plasmid derivative Rsc13 as well as other biochemical and genetic evidence. The existence of two other proteins, RepA3 (64 amino acids; 7000 daltons) and RepA2 (103 amino acids; 11,400 daltons) is also consistent with most of the criteria mentioned above. However, the region encoding RepA3, which by cloning analysis is within the region responsible for both replication and incompatibility, has never been demonstrated to produce a 7,000 dalton polypeptide. Since a large secondary structure can be constructed in this region, it is possible that the region contains structure or other information that is responsible for incompatibility. RepA2, encoded entirely within the region identified by cloning analysis to be responsible for incompatibility but not for replication can be visualized in vivo and in vitro. However, the nucleotide sequence of the region encoding RepA2 is completely different in mutually incompatible plasmid derivatives of R1 and R100. It is therefore unlikely that RepA2 plays a major role in incompatibility. Thus, we predict that RepA1 is required to initiate DNA synthesis at the replication origin and that the region proximal to RepA1 either encodes a gene product or structure information that is responsible for incompatibility.     

A new IncQ plasmid R89S: Properties and genetic organization

The new small (8.18 kb) streptomycin-resistant multicopy plasmid R89S of the Q group incompatibility is described. In contrast to other IncQ plasmids, replication of R89S is dependent on DNA polymerase 1 and proceeds in the absence of de novo protein synthesis. According to our data up to now, the host spectrum of the plasmid R89S is limited to Enterobacteriaceae. A genetic map of the plasmid R89S has been prepared through the construction of deletion and insertion derivatives. Phenotypic analysis of these derivatives has identified the location of genes encoding resistance to streptomycin, and the region essential for mobilization of R89S. The origin of vegetative replication has been located within a 0.7-kb fragment. Another region highly homologous to oriV of the plasmid RSF1010, but not functioning as an origin of replication, was localized. Two regions involved in the expression of incompatibility have also been identified. The data from the restriction analyses, DNA-DNA hybridization, and genetic experiments enable us to assume that the plasmid R89S is a naturally occurring recombinant between part of an IncQ plasmid and another narrow host range replicon of unknown incompatibility group.     

Genetic analysis of the inter-relationship between plasmid replication and incompatibility

Summary The relationship between replication control and plasmid incompatibility has been investigated using a composite replicon, pPM1, which consists of the pSC101 plasmid ligated to another small multicopy plasmid, RSF1050. Since pPM1 can utilise the replication system of either of the two functionally distinct components, propagation of the composite plasmid can occur in the presence of a mutation of one of its moieties. Such mutants are detected by their inability to rescue the composite plasmid under conditions not permissive for replication of the other moiety. Mutations in incompatibility functions can be detected by the failure of the composite replicon to exclude co-existing plasmids carrying a replication system identical to the one on pPM1.The inability of the composite plasmid to replicate at 42° in a host synthesizing temperature-sensitive DNA polymerase I, which is required by the RSF1050 replication system, was used to isolate pPM1 mutants defective in replication of the pSC101 component. Mutants defective in the incompatibility functions of pSC101 were obtained by selecting derivatives that allow the stable coexistence of a second pSC101 replicon in the same cell. Analysis of these two classes of mutants indicates that plasmids selected for defective pSC101 replication ability nevertheless retain pSC101 incompatibility. In contrast, plasmid mutants that have lost incompatibility functions were found always to be defective in replication ability.     

Characterization of the maintenance functions of IncFIV plasmid R124

The genetic arrangement of the regions involved in R124 replication and incompatibility have been located and their homology to the IncFI basic replicons has been assessed. We show that R124 has homology with all three basic replicons, RepFIA, RepFIB, and RepFIC, and that these regions, FIVA, RepFIVB, and RepFIVC, are widely separated on the R124 genome. Cloning of autonomously replicating fragments has shown that RepFIVB and RepFIVC are functional in R124 and express incompatibility. The FIVA region was unable to form a functional replicon and when cloned into pUC8 lacked incompatibility activity. A fourth region of R124 was identified, which although not essential for replication stabilized mini-R124 plasmid replication and exhibited incompatibility with R124. This region, designated IncIV, showed no homology to RepFIA, RepFIB, or RepFIC. Incompatibility expression of IncIV required only the EcoRI fragment E13 but the strength of the reaction was modified in the presence of other fragments. The replication and incompatibility properties of an R124 deletion derivative indicated that R124 can switch its replication to either RepFIVB or RepFIVC when in the presence of an incompatible plasmid. The ambiguous incompatibility reactions reported for R124 is a result of the expression of the two functional replicons, RepFIVB and RepFIVC, and that expressed by IncIV.