Conjugal mobility of the multicopy plasmids NTP1 and NTP16

Mobilization of the multicopy plasmid NTP16, like that of ColE1, is promoted by a range of conjugal plasmids. However, the mechanisms employed for NTP16 mobilization differ between groups. Mobilization by the IncI1 plasmid R64 requires trans-acting products from NTP16 plus a cis-acting region of the small plasmid. In contrast, this system is used inefficiently by the F plasmid and instead, a high-frequency conduction process occurs. Analysis of exconjugant cells reveals that F-mediated mobilization of NTP16 frequently involves rearrangements of NTP16 DNA, promoted by the Tn1000 transposon of F and/or by the kanamycin resistance transposon (Tn4352) of NTP16. Possible mechanisms for the high-frequency F-mediated mobilization of NTP16 are discussed. The plasmid NTP1, which is closely related to NTP16, is also mobilized efficiently by R64. It is not however efficiently mobilized by F, demonstrating the requirement for the Tn4352 element, which is not present in this plasmid, for effective F-mediated transfer.     

Complete nucleotide sequence and gene organization of plasmid NTP16.

We have determined the complete nucleotide sequence of the 8.3-kb multicopy plasmid NTP16 and produced a functional map of its gene organization. Sixty percent of the plasmid DNA comprises transposon-derived sequences; in the remaining 3320 bp, we have identified three protein coding regions. NTP16 has a ColE1-type replication system, a cis-acting stability locus and a mobilization system comprising an oriT site and one mobilization protein. The roles of the other two protein products of this plasmid are unknown, but they are possibly involved in the plasmid incompatibility system.     

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.     

Mapping of RNA polymerase binding sites in R12 derived plasmids carrying the replication-incompatibility region and the insertion element IS1.

Interactions between Escherichia coli RNA polymerase holoenzyme and three small plasmid DNAs (pSM1, pSM2, and pSM15) derived from the drug resistant factor R12 have been studied. These plasmids carry the copy number and incompatibility determinants, the origin of DNA replication and the rep gene(s) necessary for plasmid replication. They also contain the insertion element IS1 and the putative finO cistron. Thirteen DNA segments within the largest of the three plasmids (pSM2) were able to form either a binary and/or ternary complex with RNA polymerase. A unique strong binding site was mapped within the left end of IS1. Five binding sites were found within the rep-cop-inc region. Four of these are weak binding sites whereas the fifth does not form a stable binary complex and was detected by ternary complex formation. A strong binding site was located in the putative finO region whereas the remaining six binding sites are located in regions with unidentified genetic functions.     

Cloning and characterization of a replicon region of the IncHII plasmid pHH1457

A replicative region of the large conjugative plasmid pHH1457 (incompatibility group HII (IncHII)) was cloned. A 1.4-kbp region, in a stable pSBII14 clone, containing a PolI-independent replicon and determinants for the HII incompatibility phenotype, was selected and characterized. High incompatibility with IncHII plasmids was corroborated. Independent replication of the insert was demonstrated by ligation to an antibiotic resistance cassette. pSBII14 was used as a probe to identify IncHII plasmids from other members of the H complex: IncHI (IncHI1, IncHI2 and IncHI3 subgroups). Hybridization experiments revealed a high homology with the replication region of IncHII plasmids, but not with IncHI1 or IncHI3 plasmid prototypes. Homology with IncHI2 plasmids was observed, suggesting the presence of IncHII-like replicons among this subgroup of plasmids. This is the first report of the characterization of an IncHII plasmid maintenance region.     

A method of plasmid classification by integrative incompatibility

A method of plasmid classification by integrative incompatibility has been developed. The characteristics of this system are as follows: (i) The conventional plasmids usually used as standards for incompatibility grouping were integrated into the host chromosome to increase stability and to minimize recombination with the superinfecting plasmid. Strains were constructed by integrative suppression which was in some cases facilitated by the introduction of Tn5 into the plasmid. (ii) The resulting Hfr strains were made deficient in the rec A function to eliminate homologous recombination between the resident and the superinfecting plasmids. A test plasmid is introduced into these rec A Hfr test strains in the stationary phase of growth. In an incompatible cross, the number of transconjugant colonies was usually less than 10^?2 of that in a compatible cross. Occasionally, an inhibitory mechanism, other than incompatibility was coded by the resident plasmid [e.g., restriction in R124 (inc FIV)]. This complicated the interpretation, but did not invalidate the experiment. The colonies arising in incompatible crosses were shown to carry drug resistance determinants coded by both the resident and superinfecting plasmids. These were presumably the result of rec-independent integration of all or part of the superinfecting plasmid into the host chromosome. Thus the reduced frequency of superinfectant formation in an incompatible cross is usually the consequence of incompatibility between the resident and the superinfecting plasmids. This integrative incompatibility system should be useful for epidemiological studies of R plasmids.     

Restriction endonuclease mapping of the HI2 incompatibility group plasmid R478.

A restriction map of the 272-kb IncHI2 plasmid R478 was constructed by using the enzymes ApaI, XbaI, SalI, and XhoI. The map was derived from cloned restriction fragments from R478 inserted into cosmid and plasmid vectors as well as from double-digestion analysis of R478 and R478 miniplasmids. All previously known resistance determinants were cloned from R478, and their positions were located on the restriction map. A region involved in incompatibility was cloned and mapped. The location of a previously unreported arsenite resistance gene was also determined. The genes encoding tellurite resistance, colicin B resistance, and phage inhibition were found to be associated with a 6.7-kb SalI fragment of R478.     

Repair in E. coli of transforming plasmid DNA damaged by psoralen plus near-ultraviolet irradiation

Treatment of DNA with psoralen plus near-ultraviolet irradiation gives rise to both monoadducts and cross-links. We have examined the repair of plasmid NTP16 DNA treated in this way in vitro and then used to transform E. coli. Monoadducts are found to be potentially lethal, and can be repaired by uvr-dependent and recA-dependent pathways. The presence of a related resident plasmid in the transformed cells can enhance the survival of the incoming damaged NTP16 DNA. This effect is not recA-dependent, and a similar effect (designated "resident enhanced repair") has been observed previously with UV-irradiated plasmids of this particular incompatibility group. Removal of unbound psoralen from the plasmid DNA and exposure to further NUV is known to increase the ratio of cross-links to monoadducts, and we demonstrate that such cross-linked plasmid DNA is not readily repaired following transformation. However in the presence of homologous DNA (related resident plasmid) there is evidence for the repair, and hence uptake by the cell, of cross-linked DNA.     

Stable inheritance of plasmid R1 requires two different loci.

The largest EcoRI fragment from plasmid R1 mediates a stability phenotype which is required to ensure the stable inheritance of this low-copy-number plasmid. When covalently linked to small, unstable R1 derivatives, this fragment makes the plasmids as stable as the wild-type R1 plasmid. A genetic analysis showed that two independently acting stabilization functions are encoded by this EcoRI fragment, both of which have the potential of partial stabilization of mini-R1 plasmids. The two loci are located at opposite ends of the fragment. Stabilization was also obtained by inserting these regions in unrelated, unstable plasmids from the p15 group. One of the two functions was very efficient in stabilizing such foreign replicons. Besides the stability phenotype, these genes exert incompatibility in an allele-specific manner. The stability functions do not seem to interfere seriously with the copy number of the plasmid.     

Mapping of RP4 plasmid using deletion mutants of pAS8 hybrid (RP4-ColE1)

Summary We used the hybrid plasmid pAS8 in order to conduct the genetic analysis of RP4 plasmid. The presence of two replicons in the hybrid plasmid permitted to expand the spectrum of deletion mutants of RP4 isolated, which are capable to autonomous replication. The shortening of the hybrid plasmid was achieved by P22 transduction, by induction of deletion mutants using mitomycin C, as well as by selection of Tra^- mutants on the basis of resistance of cells to P-specific phages. These techniques have lead to isolation of clones possessing different combinations of plasmid resistance determinants.Comparison of phenotypic characteristics of deletion plasmids pAS9, pAS10, pAS11, pAS12 and pAS10-2 permitted to propose the map for pAS8 plasmid with the following sequence of markers: trakan-ColE1-amp-tet...Heteroduplex analysis of deletion mutants of pAS8 permitted to construct a physical map and to elaborate in greater detail the functional map of RP4 plasmid. The correlation between the ability of mutants to replicate in polA (TS) strain at nonpermissive conditions and the length of the deleted segment permitted to map rep genes of RP4 on a region with coordinates 9.8–17.3 kb. A relationship between the manifestation of incompatibility of mutants with Inc P-1 plasmids and the length of deletions points out that inc genes are located on DNA region with coordinates 2.1–9.8 kb. The analysis of replication of deletion mutants and the manifestation of incompatibility just as of the data about the size of appropriate deletions permitted to make the conclusion about the functional and genetic independence of the replication control and incompatibility control in RP4 plasmid.     

A pathway for the evolution of the plasmid NTP16 involving the novel kanamycin resistance transposon Tn4352

The kanamycin resistance determinant of the drug resistance plasmid NTP16 has been characterized by DNA sequencing and has been shown to possess all of the structural features of a transposable element. It is made up of a 1040-bp central region encoding a protein identical to the aminoglycoside 3'-phosphotransferase of Tn903, flanked by direct repeats of an element identical to IS26. This novel transposon has been designated Tn4352. Analysis of the host sequences flanking the transposon reveal that they are derived from a Tn3-like element, and contain no 8 base pair target size duplications which are normally created by the insertion of IS26-like elements. Comparison to the Tn3 sequence shows that the flanking sequences are noncontiguous within Tn3, with the clear implication that NTP16 has evolved from a similar plasmid encoding only ampicillin resistance (presumably NTP1) by the insertion of Tn4352 into the Tn3-like element, followed by a substantial deletion. The sequence analysis suggests that the initial insertion was into the tnpR gene of the ampicillin transposon, followed by a deletion extending to a specific site within tnpA.     

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.     

Replication and incompatibility properties of plasmid pE194 in Bacillus subtilis.

pE194, a 3.5-kilobase multicopy plasmid, confers resistance to the macrolide-lincosamide-streptogramin B antibiotics in Bacillus subtilis. By molecular cloning and deletion analysis we have identified a replication segment on the physical map of this plasmid, which consists of about 900 to 1,000 base pairs. This segment contains the replication origin. It also specifies a trans-acting function (rep) required for the stable replication of pE194 and a negatively acting copy control function which is the product of the cop gene. The target sites for the rep and cop gene products are also within this region. Two incompatibility determinants have been mapped on the pE194 genome and their properties are described. One (incA) resides within the replication region and may be identical to cop. incB, not located in the replication region, expresses incompatibility toward a copy control mutant (cop-6) but not toward the wild-type replicon.     

Identification and characterization of a native Dichelobacter nodosus plasmid, pDN1

The gram-negative anaerobe Dichelobacter nodosus is the primary causative agent of ovine footrot, a mixed bacterial infection of the hoof. We report here the characterization of a novel native plasmid, pDN1, from D. nodosus. Sequence analysis has revealed that pDN1 has a high degree of similarity to broad-host-range plasmids belonging, or related, to Escherichia coli incompatibility group Q. However, in contrast to these plasmids, pDN1 encodes no antibiotic resistance determinants, lacks genes E and F, and hence is smaller than all previously reported IncQ plasmids. In addition, pDN1 belongs to a different incompatibility group than the IncQ plasmids to which it is related. However, pDN1 does contain the replication and mobilization genes that are responsible for the extremely broad host range characteristic of IncQ plasmids, and derivatives of pDN1 replicate in E. coli. In addition, the mobilization determinants of pDN1 are functional, since derivatives of pDN1 are mobilized by the IncPalpha plasmid RP4 in E. coli.