Effect of transposons Tn1 and Tn9 on the genetic regulation system of transfer and incompatibility functions of Col-plasmid pAP19-1

F-like pAP19-1 Col-plasmid was labeled with transposons Tn1 and Tn9 and transfer functions of its derepressed mutants were investigated. The plasmid indicated was compatible with reference plasmids of 9 F-like incompatibility groups. Thus it belongs to the new incompatibility group FX. The ability of Tn9 to change the incompatibility of the plasmid investigated was discovered.     

Identification of the number of mutant copies of the genetic transfer factor AP42

The copy number mutant of genetic transfer factor pAP42 (incFIX) was induced by the treatment of E. coli AP115 cells carrying the plasmid by N-methyl-N-nitro-N-nitrosoguanidine. The copy number mutant pAP42::Tn1cop1 is characterized by the increased copy number. The cells carrying the copy number mutant have a higher ampicillin resistance and higher beta-lactamase activity. Mutant plasmid pAP42: :Tn1cop1 is incompatible with plasmid pAP42 and compatible with plasmids of the other inc-groups of F-like plasmids.     

The systems of the genetic regulation of plasmid transfer fin K, fin L, fin M and fin N]

F-like plasmids pAP19-1::Tn9, pAP20::Tn9, pAP22-1::Tn1, pAP27 characterized by the presence of unique genetic plasmid transfer regulatory systems in their genomes have been found. These systems were named fin K, fin L, fin M, finN, consequently. They were characterized from the point of view of specificity of their action on F-factor and F-like conjugative function. Dependence of fin N-system expression on host-cell and on the order of plasmid entering into host-cell was shown.     

Conjugativity and incompatibility of derepressed pAP11-2 plasmid

It has been demonstrated during investigation of Colplasmid pAP11-2 and its varieties labeled with transpozone (Tn1 and Tn9) that this plasmid is a derepressed one in terms of transfer functions in E. coli strain K-12 cells as well as in some of serologically typed strains of this type. The plasmid under study is incompatible with reference plasmids belonging to two different groups (FI and FIV) and is marked by a number of the properties common to the system of genetic control over Tra-functions.     

Characterisation of plasmids purified from Acetobacter pasteurianus 2374

Four cryptic plasmids pAP1, pAP2, pAP3, and pAP4 with their replication regions AP were isolated from Gram-negative bacteria Acetobacter pasteurianus 2374 and characterised by sequence analyses. All plasmids were carrying the kanamycin resistance gene. Three of four plasmids pAP2, pAP3, and pAP4 encode an enzyme that confers ampicillin resistance to host cells. Moreover, the tetracycline resistance gene was identified only in pAP2 plasmid. All plasmids are capable to coexist with each other in Acetobacter cells. On the other hand, the coexistence of more than one plasmid is excluded in Escherichia coli. The nucleotide sequence of replication regions showed significant homology. The nucleotide and protein sequence analyses of resistance genes of all plasmids were compared with transposons Tn3, Tn10, and Tn903 which revealed significant differences in the primary structure, however no functional changes of gene were obtained.     

Compatibility between F-like genetic transfer factors

A study has been made of compatibility among four F-like factors of genetic transfer (pAP22-4, pAP38, pAP39 and pAP41) labeled separately by transpozones Tn1 and Tn9. It has been established that pAP38 transfer factor is compatible with plasmids pAP22-4, pAP39 and pAP412, while pAP41 transfer factor is compatible with plasmids pAP22-4 and pAP38 but is incompatible with plasmid pAP39.     

Genetic characteristics of plasmid pAP53 derepressed in transfer functions detected in the cells of an opportunistic E. coli strain

A study was made of plasmid pAP53 derepressed as regards transfer functions (Tra-functions) detected in E. coli strain cells, serogroup 0128, after its labeling with transpozones Tn1 and Tn9. The compatibility tests demonstrated that the plasmid belongs to the incompatibility group FIII and is partially incompatible with the group FII reference-plasmid. Plasmid pAP53 is unable to inhibit Tra-functions of plasmid F'lac and is not inhibited by the fin type genetic regulation on the OP group plasmids under study. At the same time Tra-functions of plasmid pAP53 are inhibited in the presence of pAP41 plasmid, which indicates that this plasmid has a special type of genetic regulation.     

Molecular genetic study of the changes in the incompatibility and regulation of the transfer of the F-like pAP18-1 plasmid induced by nitrosoguanidine and the Tn5 and Tn9 transposons

Relation between induced mutations of plasmid pAP18-1 (Tc, Col) and alterations in it's restriction map was studied. Nitrosoguanidine induced mutations of transfer regulation system and incompatibility of this plasmid related with alteration in the situation of recognition sites for restrictases EcoR1 and Sal1 in map positions 42.2-4.3 and 12.9-17.9 MD. Insertions of transposons Tn5 and Tn9 into the plasmid DNA resulted in a decrease of incompatibility level.     

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 properties of transposons Tn6-1, Tn6-2 and Tn19-1

The level and range transposition of the transposons Tn6-1, Tn6-2, Tn19-1, and their ability to influence plasmid transfer has been studied. The widest range of transposition was shown for transposon Tn6-2. Insertions of each of the studied transposons into different conjugative plasmids genomes resulted in change of frequencies of plasmids transfer and change of plasmids mobilization activity.     

Range of the transmissivity of the genetic transfer factors pAP38, pAP39, pAP41 and pAP42

A study was made of the transmissivity range of the genetic transfer factors pAP38, pAP39, pAP41 and pAP42 identified in E. coli. It was demonstrated that these factors are not capable of transfer to the cells of P. putida, P. fluorescens, R. leguminosarum, A. lipoferum, A. tumefaciens. Factor pAP42 is mobilized to transfer to P. putida and R. leguminosarum with the aid of plasmid RP4. It is assumed that in the course of mobilization, the cointegrative structures are formed between plasmids pAP42 and RP4.     

Mutations of the genetic region Fin of the F-like plasmid pAP18-1]

With help of nitrosoguanidine 60 mutants of F-like plasmids pAP18-1 drd::Tn 5 and pAP18-1::Tn 9 were induced which determined resistance of E. coli cells of specific phage MS2. Mutational changes in fin-locus of those plasmids were accompanied by phenotypic reversion Fin(-)-Fin+.     

Use of transposons for studying the genetic organization of Vibrio cholerae non 01]

The nonagglutinating vibrions having Tn-elements inserted into the chromosome were obtained as a result of conjugal transfer of vector plasmids carrying the different transposons (Tn9, Tn10, Tn601, Tn5-Mob) and of the consequent isolation of plasmid-free clones of Vibrio cholerae non OI. Identification of auxotrophic mutations induced by the transposons inserted into the bacterial genome made possible the construction of the primary chromosomal map of Vibrio cholerae non OI. The efficient donor strains of Vibrio cholerae non OI were constructed by introducing the transposon Tn5-Mob and the helper plasmid RP-4. The donors are capable of oriented conjugal transfer of chromosome.     

Region-specific insertion of transposons in combination with selection for high plasmid transferability and stability accounts for the structural similarity of IncP-1 plasmids

The overall architecture of IncP-1 plasmids is very conserved in that the accessory genes are typically located in one or two specific regions: between oriV and trfA and between the tra and trb operons. Various hypotheses have been formulated to explain this, but none have been tested experimentally. We investigated whether this structural similarity is due to region-specific transposition alone or also is reliant on selection for plasmids with insertions limited to these two regions. We first examined the transposition of Tn21Km into IncP-1beta plasmid pBP136 and found that most Tn21Km insertions (67%) were located around oriV. A similar experiment using the oriV region of IncP-1beta plasmid pUO1 confirmed these results. We then tested the transferability, stability, and fitness cost of different pBP136 derivatives to determine if impairment of these key plasmid characters explained the conserved plasmid architecture. Most of the pBP136 derivatives with insertions in transfer genes were no longer transferable. The plasmids with insertions in the oriV-trfA and tra-trb regions were more stable than other plasmid variants, and one of these also showed a significantly lower fitness cost. In addition, our detailed sequence analysis of IncP-1 plasmids showed that Tn402/5053-like transposons are situated predominantly between the tra and trb operons and close to the putative resolution site for the ParA resolvase, a potential hot spot for those transposons. Our study presents the first empirical evidence that region-specific insertion of transposons in combination with selection for transferable and stable plasmids explains the structural similarity of IncP-1 plasmids.     

Construction of transposons carrying the transfer functions of RP4

The transfer genes and origin of transfer of the wide host range plasmid RP4 have been cloned into the transposons Tn1 and Tn5. The newly constructed transposons can be used to mutagenize bacterial plasmids or the chromosome in species such as Escherichia coli or Rhizobium. It is then possible to mobilize the plasmid or chromosome using the transfer functions provided in cis by the transposon. These constructs may aid chromosome mapping in many gram-negative species by allowing the wider use of the RP4 conjugal transfer system combined with the potential ability to select the site of insertion and thus the site of the origin of transfer.     

Transfer and properties of some natural and suicide replicons in Pasteurella multocida

We tested the transfer of several plasmids and transposons from Escherichia coli to Pasteurella multocida by filter mating. Two plasmids, pRKTV5 (pRK2013::Tn7) and pUW964 (pRKTV5::Tn5), were derived from pRK2013--a narrow-host-range plasmid with the broad-host-range IncP conjugation genes. Most P. multocida transconjugants obtained with pRKTV5 had Tn7 insertions in the chromosome but some had insertions of the whole plasmid. By contrast, all the transconjugants obtained with pUW964 had insertions of this plasmid or a deleted variant. pUW964 mediated low-frequency transfer of Tn7 or chromosomal markers between P. multocida strains. Broad-host-range IncP plasmid RP4 (RK2) did not yield selectable transconjugants in P. multocida but two plasmids derived by Tn5 insertion into a kanamycin-sensitive derivative of RP4 did yield transconjugants. pSUP1011, a narrow-host-range p15A replicon with the RP4 mob region allowing mobilization by the IncP conjugation genes also yielded transconjugants while several other plasmids tested did not transfer markers to P. multocida.     

Nucleotide sequences of mercury resistance determinants in bacteria isolated from mercury mines: detection of a family of recombinant mercury transposons in plasmids from Acinetobacter species

Partial nucleotide sequences were determined for mer operons located on large and small plasmids previously described in Acinetobacter spp. isolated from different mercury mines of the USSR. Inspection of the sequences shows that: 1. All Acinetobacter mer operons studied belong to a family of transposons homologous to transposons found in clinical isolates. 2. The transposons located on the small plasmids originated by recombinations between the transposons from the large plasmids and Tn501, a transposon found in a Pseudomonas hospital strain isolated in Australia. The left arm of each hybrid transposon was donated by a transposon of a large Acinetobacter plasmid and the right arm - by the Tn501.     

Maintenance of broad-host-range incompatibility group P and group Q plasmids and transposition of Tn5 in Bartonella henselae following conjugal plasmid transfer from Escherichia coli.

The first demonstration of conjugal plasmid transfer from Escherichia coli to Bartonella henselae is reported. Transconjugants bearing plasmids of incompatibility groups P (IncP) and Q (IncQ), expressing various resistance markers, were generated. Tn5 transposons delivered on suicide plasmids by conjugation showed transpositional insertion into random chromosomal sites.     

Isolation of Yersinia pestis plasmids with transposon markers

Transposons Tn1, Tn7, Tn9, Tn10 have been inserted into each of three known plasmids in Yersinia pestis and have been shown to mutagenize the different plasmid genes. The marked plasmids are shown to be transduced by bacteriophage P1 cml clr 100 ts in intrageneric crosses. The genes of 61-65 Md plasmid were found to be impaired with high frequencies by Tn9 and Tn10 insertions blocking the synthesis of fraction I antigen. The genes are also impaired in course of transduction of transposon marked plasmids.     

Transposition of DNA fragments flanked by two inverted Tn1 sequences: translocation of the plasmid RP4::Tn1 region harboring the Tcr marker

We have demonstrated the possibility of transposition of the plasmid RP4::Tn1 fragment (21.2 kb) carrying the tetracycline resistance (Tcr) gene and flanked by two Tn1 copies. The new transposon, designated Tn1756, bears lethal genes that kill host cells. Therefore, its transposition can only be revealed in the presence of lethality-compensating helper regions of the plasmid RP4. Thus, RP4::Tn1 consists of two transposons, Tn1755 (Tn1-Kmr-Tn1) and Tn1756 (Tn1-Tcr-Tn1), sharing the Tn1 sequences. Both of these transposons are capable of recA-independent translocation to other plasmids. Therefore, transposition of DNA fragments flanked by two inverted Tn1 sequences does not depend on Tn1 orientation.