Pili determined by the tra genes of F-like plasmids

The study of structural and functional features of plasmid-specific pili synthetized by E. coli cells under control of 27 F-like plasmids was performed. All the plasmids determined the pili of "flexible" type which were classified into 3 groups on the basis of difference in cell sensitivity to pili-specific phages f1, f2, Q. The possible role of transposons in the variation of pili functional properties was supposed.     

Systems regulating the tra genes of derepressed F-like plasmids

A study was made of the ability of reference plasmids of the 6 known Fin-groups to inhibit the functions of transfer genes (tra-genes) of the 4 derepressed F-like plasmids (pAP22-2, pAP38, pAP43, pAP53). It was shown that unlike the derepressed Flac plasmid, the conjugation transfer of pAP38 and pAP53 plasmids was inhibited only by, the FinV plasmid, whereas pAP22-2 plasmids by Fin V and Fin V plasmids. The formation of donor-specific pili in case of pAP38 plasmid was inhibited by Fin Q, Fin U and Fin V plasmids, in case of pAP43 plasmid by Fin U Fin V and Fin W plasmids.     

Genetic region of incompatibility of the F-like plasmid pAP-18-1]

With help of molecular cloning the genetic region controlling incompatibility of plasmid pAP18-1 (Inc FXI) was localized in EcoR1-fragment f5 (3.6 MD). The genetic region of incompatibility of its derepressed mutant pAP18-1drd (Inc FVII) is situated in EcoR1-fragment f2 (7,2 MD).     

Atypical incompatibility of the F-like factors of pA22-4, pAP39 and pA41 genetic transfer with the F-group incompatibility plasmids

A study was made of compatibility of three F-like factors of the genetic transfer (pAP22-4, pAP39, pAP41) identified in the cells of serologically typed E. coli strains with F-group incompatibility reference plasmids. The factors of pAP22-4 and pAP41 transfer are partly incompatible with groups FII, FIII, FIV, and FI, FIV, respectively, while the factors of pAP39 transfer are completely incompatible both with groups FI and FIV plasmids.     

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.     

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.     

Curing of four different plasmids in Yersinia pestis using plasmid incompatibility

Aims: Plasmids are critical for the pathogenicity of Yersinia pestis. In order to carry out a systematic investigation of their role in pathogenesis, we cured plasmids from Y. pestis. Methods and Results: Each plasmid’s replicon of Y. pestis was cloned into plasmid pEX18Gm containing a counter‐selectable sacB gene, and was then introduced into Y. pestis strain 201 by electroporation. Strains containing recombinant plasmids were cultivated under antibiotic selection. The resultant plasmid‐curing colonies, identified by specific polymerase chain reactions, were then cured off pEX18Gm under sucrose pressure. This method was used to successfully cure all four plasmids of Y. pestis, singly or in different combinations. Conclusions: Naturally evolving plasmids in Y. pestis are difficult to remove by conventional curing methods. We employed a method based on plasmid incompatibility to cure the plasmids from Y. pestis, which confirmed the efficacy of this method for curing plasmids with different types of replicons from one bacterium. Significance and Impact of the Study: There have been no reports on the curing of multiple plasmids by using replication mechanisms from one bacterium with this technique. In the present study, we were able to successfully apply this methodology to cure four plasmids from Y. pestis, confirming its feasibility.     

Random replication and random assortment model for plasmid incompatibility in bacteria

To understand the incompatibility between two related plasmids, both of which replicate in an autonomous state under a common control mechanism, we have developed a model that assumes a random choice mechanism for replication of plasmid copies and their random assortment into daughter cells upon cell division. Segregation kinetics by this model is analyzed mathematically and the number of generations required for segregation is calculated as a function of plasmid copy number per cell. The results obtained offer enough quantitative data to make our model reasonably realistic.     

Structural elements required for replication and incompatibility of the Rhizobium etli symbiotic plasmid

The symbiotic plasmid of Rhizobium etli CE3 belongs to the RepABC family of plasmid replicons. This family is characterized by the presence of three conserved genes, repA, repB, and repC, encoded by the same DNA strand. A long intergenic sequence (igs) between repB and repC is also conserved in all members of the plasmid family. In this paper we demonstrate that (i) the repABC genes are organized in an operon; (ii) the RepC product is essential for replication; (iii) RepA and RepB products participate in plasmid segregation and in the regulation of plasmid copy number; (iv) there are two cis-acting incompatibility regions, one located in the igs (incalpha) and the other downstream of repC (incbeta) (the former is essential for replication); and (v) RepA is a trans-acting incompatibility factor. We suggest that incalpha is a cis-acting site required for plasmid partitioning and that the origin of replication lies within incbeta.     

A mathematical model of the incompatibility of plasmids using a mechanism of master replication

A mathematical model of incompatibility for plasmids that use master-replication was worked out. Formulas for calculating the segregation velocity of two incompatible plasmids and for determining the number of cell generations (l gamma), necessary to achieve a gamma-share of polyplasmid cells are given. It is shown that l gamma strives to -8 lg gamma with the increase of the copy number N, i.e. it does not depend on N. This is the main distinction of model presented from those by Novick at al. and Ishii et al., who consider the mechanisms of regular and random replication. For these mechanisms l gamma increases proportional to N. So, at N greater than 30, the difference between l gamma, calculated for the master-replication and the random replication exceeds 10. This allows to determine the mechanism of replication used by the plasmid by measuring the velosity of incompatible plasmids segregation.     

Compatibility of the F-like plasmid FB1drd with standard F-group plasmids in E. coli K12 strains]

Compatibility of depressed F-like plasmid FB1drd integrated into E. coli K12 cell chromosome with standard plasmids of FI-FVI compatibility groups was studied. The results obtained show that such plasmids can stably coexist in the same cell with plasmid FB1drd. On these grounds it is supposed that the latter belongs to the new compatibility group (FVII).     

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.     

Nucleotide sequence of the replication region of plasmid R401 and its incompatibility function

The plasmids R401 and Rtsl belong to the same incompatibility group, IncT. The nucleotide sequence of the basic replicon of R401 consisting of 1,857 base pairs was determined and compared with that of mini-Rtsl previously reported. The mini-R401 was found to be composed of two clusters of direct repeated sequences flanking a large open reading frame that could encode a 33,000 Mr protein (RepA protein) consisting of 288 amino acids. This structure of mini-R401 is quite similar to that of mini-Rtsl. Furthermore, the nucleotide sequence of mini-R401 is identical to that of mini-Rtsl except for eleven nucleotides; three are located near the carboxyl terminus portion of the RepA coding region (repA) and four are in the repeated sequences (incI) located downstream from repA. Incompatibility study showed that mini-R401 plasmid coexisted stably with the cloned incI repeats of mini-Rtsl, suggesting that mini-R401 RepA protein binds to incI repeats of mini-Rtsl less efficiently than does mini-Rtsl RepA protein.     

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.     

Site-specific proteolysis of mini-F plasmid replication protein RepE destroys initiator function and generates an incompatibility substance.

Plasmid F replication is controlled by a plasmid-specified Rep protein with both autorepressor and initiator functions. The mechanism by which these two functions of a Rep protein are balanced to achieve stable replication is unknown; however, we speculated in prior work that Rep protein modification could be involved. We report here that naturally proteolyzed F RepE protein has been detected and characterized. The processed molecule lost the first 17 N-terminal aminoacyl residues and initiator function but acquired increased specific DNA-binding affinity in the presence of Escherichia coli chromosomal DNA. When supplied in trans, the altered protein acts as an incompatibility substance and eliminates maintenance of F'lac. These findings indicate that protein processing has the potential to contribute to the overall control of DNA replication.     

Functional characterization of replication and stability factors of an incompatibility group P-1 plasmid from Xylella fastidiosa

Xylella fastidiosa strain riv11 harbors a 25-kbp plasmid (pXF-RIV11) belonging to the IncP-1 incompatibility group. Replication and stability factors of pXF-RIV11 were identified and used to construct plasmids able to replicate in X. fastidiosa and Escherichia coli. Replication in X. fastidiosa required a 1.4-kbp region from pXF-RIV11 containing a replication initiation gene (trfA) and the adjacent origin of DNA replication (oriV). Constructs containing trfA and oriV from pVEIS01, a related IncP-1 plasmid of the earthworm symbiont Verminephrobacter eiseniae, also were competent for replication in X. fastidiosa. Constructs derived from pXF-RIV11 but not pVEIS01 replicated in Agrobacterium tumefaciens, Xanthomonas campestris, and Pseudomonas syringae. Although plasmids bearing replication elements from pXF-RIV11 or pVEIS01 could be maintained in X. fastidiosa under antibiotic selection, removal of selection resulted in plasmid extinction after 3 weekly passages. Addition of a toxin-antitoxin addiction system (pemI/pemK) from pXF-RIV11 improved plasmid stability such that >80 to 90% of X. fastidiosa cells retained plasmid after 5 weekly passages in the absence of antibiotic selection. Expression of PemK in E. coli was toxic for cell growth, but toxicity was nullified by coexpression of PemI antitoxin. Deletion of N-terminal sequences of PemK containing the conserved motif RGD abolished toxicity. In vitro assays revealed a direct interaction of PemI with PemK, suggesting that antitoxin activity of PemI is mediated by toxin sequestration. IncP-1 plasmid replication and stability factors were added to an E. coli cloning vector to constitute a stable 6.0-kbp shuttle vector (pXF20-PEMIK) suitable for use in X. fastidiosa.     

Naturally occurring plasmids exhibiting incompatibility with members of incompatibility groups I and P

From a group of naturally occurring antibiotic resistance plasmids, a number of plasmids were identified which were incompatible with members of incompatibility group P and also incompatibility group I alpha or I gamma. These plasmids also exhibited strong entry exclusion with members of group P only and showed a host range which resembled that of plasmids of group I rather than those of group P. Segregants of a number of these plasmids appeared to have lost some of the incompatability and/or surface exclusion functions. Studies of nucleic acid homology indicated that these plasmids were very similar to one another. They exhibited 15 to 20% nucleic acid homology with representatives of the I alpha and I gamma groups, yet showed less than 2% homology with the group P plasmid RP4.     

Novel incompatibility and partition loci for the REPI replication region of plasmid ColV-K30.

The minimum pColV-K30 REPI region necessary for replication was located within a ca. 1.3-kilobase DNA segment. Adjacent to the essential replication sequences, there are two DNA regions that express incompatibility with plasmids containing the F secondary replicon of the F EcoRI fragment f7. One of these regions corresponds to incE, already described in that F plasmid fragment which expresses incompatibility with f7-containing plasmids. The other is a novel sequence that we designated incF, which confers incompatibility with REPI, P307, and f7 derivatives, cis-acting pColV-K30 sequences conferring stability to REPI-containing plasmids were also identified and localized noncontiguous to REPI, ca. 20 kilobases downstream from the aerobactin iron transport genes, which were thus flanked by REPI and its partition (par) sequences.     

Further characterization of the R plasmid Rts1 and its mutant pTW2: replication and incompatibility of the plasmid.

Incompatibility of the R plasmid Rts1 and its replication mutant pTW2 was studied in recA host cells of Escherichia coli. When the R plasmid R401, belonging to the same incompatibility group as Rts1, was used as a test plasmid, R401 was eliminated preferentially from (Rts-R401)+ cells irrespective of the direction of transfer. In contrast, pTW2 and R401 were mutually excluded. The decreased incompatibility of pTW2 was confirmed by a direct incompatibility test in which a derivative of Rts1 expelled pTW2 exclusively. Alkaline sucrose gradients of pTW2 and Rts1 DNA indicated that approximately one-fourth of the Rts1 genome was deleted in pTW2. In addition, both the various temperature-dependent properties of Rts1 and the inhibitory effect on phage T4 development were also lost in pTW2. A possible mechanism that regulates the stringent replication of Rts1 is discussed.     

Study of the incompatibility and replication of the 70-kb virulence plasmid of Yersinia

The 70-kb virulence plasmid, vir, from four Yersinia enterocolitica and one Y. pseudotuberculosis strains are incompatible with IncFI plasmids FLac and R386 while they are compatible with plasmids representing nine other incompatibility groups. Hybridization experiments carried out on one of these virulence plasmids showed that it contains the F incompatibility determinant D, incD. This determinant was cloned onto pACYC184 and the recombinant clone expressed incompatibility with FLac. We conclude that the incompatibility observed between F or R386 and the 70-kb virulence plasmid of Y. enterocolitica and Y. pseudotuberculosis is mediated by incD. Replication genes (rep) from the same plasmid were cloned independently in Escherichia coli. Rep and incD map on two different BamHI fragments. Surprisingly, the replicon isolated is not sensitive to inc D incompatibility. Apart from incD, vir and F share extremely little homology. In particular, there is no evidence for the presence of an F-like transfer operon on vir.