Tn10 mediated integration of the plasmid R100.1 into the bacterial chromosome: Inverse transposition

Summary Upon integration into the bacterial chromosome the drug resistance plasmid R100.1 often loses its tetracycline resistance character. We have analyzed an Hfr strain formed by such an integration and an R-prime plasmid derived from it. We find that integration took place within the Tn10 transposon, that the two IS10 sequences were retained, but that at least 80% of the transposon segment located between them, and carrying the tetracycline resistance genes, had been lost. We suggest that integration of R100.1 was mediated by an inverse transposition using the IS10 sequences.     

Transposon insertion mutagenesis of Pseudomonas aeruginosa with a Tn5 derivative: application to physical mapping of the arc gene cluster

For insertional mutagenesis of Pseudomonas aeruginosa, a derivative of the kanamycin-resistance (KmR) transposon Tn5 was constructed (Tn5-751) that carried the trimethoprim-resistance (TpR) determinant from plasmid R751 as an additional marker. Double selection for KmR and TpR avoided the isolation of spontaneous aminoglycoside-resistant mutants which occur at high frequencies in P. aeruginosa. As a delivery system for the recombinant transposon, plasmid pME305, a derivative of the broad-host-range plasma RP1, proved effective; pME305 is temperature-sensitive at 43 degrees C for maintenance in Escherichia coli and P. aeruginosa and deleted for IS21 and the KmR and primase genes. In matings with an E. coli donor carrying pME9(= pME305::Tn5-751), transposon insertion mutants of P. aeruginosa PAO were recovered at approx. 5 X 10(-7)/donor at 43 degrees C. Among Tn5-751 insertional mutants 0.9% were auxotrophs. A thr::Tn5-751 mutation near the recA-like locus rec-102 is useful for the construction of recombination-deficient strains. Several arc::Tn5-751 mutants could be isolated that were defective in anaerobic utilization of arginine as an energy source. From three of these mutants the arc gene region was cloned into an E. coli vector plasmid. Since Tn5-751 has a single EcoRI site between the TpR and KmR genes, EcoRI-generated fragments carrying either resistance determinant plus adjacent chromosomal DNA could be selected separately in E. coli. Thus, a restriction map of the arc region was constructed and verified by hybridization experiments. The arc genes were tightly clustered, confirming earlier genetic evidence.     

Protein expression in Escherichia coli minicells containing recombinant plasmids specifying trimethoprim-resistant dihydrofolate reductases.

Deoxyribonucleic acid fragments containing the structural genes for several trimethoprim-resistant dihydrofolate reductases from naturally occurring plasmids were inserted into small cloning vehicles. The genetic expression of these hybrid plasmids was studied in purified Escherichia coli minicells. The type I dihydrofolate reductase, encoded by plasmid R483 and residing within transposon 7 (Tn7), had a subunit molecular weight of 18,000. The type II dihydrofolate reductase, specified by plasmid R67, had a subunit molecular weight of 9,000. These two enzymes were antigenically distinct in that anti-type II dihydrofolate reductase (R67) antibody did not cross-react with the type I (R483) protein. The trimethoprim-resistant reductase specified by plasmid R388 had a subunit molecular weight of about 10,500 and was immunologically related to the type II (R67) enzyme. A 9,000 subunit of the dihydrofolate encoded by the transposition element Tn402 was also antigenically related to the R67 reductase.     

A mini-Mu transposon-based method for multiple DNA fragment integration into bacterial genomes

A method for construction of bacterial strains with multiple DNA inserted into their chromosomes has been developed based on the mini-Mu transposon and FLP/FRT recombination. Exogenous DNA can be integrated by Mu transposition with an FRT cassette containing selection marker and conditional replicative origin (R6Kγori). Subsequently, with the introduction of a helper plasmid bearing gene of FLP recombinase, drug-resistant selection marker is excised from the chromosome. Cells cured of the helper plasmid can undergo the next cycle of transposition and excision of selection marker. Each cycle can add further foreign gene(s) to the chromosome. As an example, resistance genes of chloramphenicol, tetracycline, and gentamicin were successively integrated into the chromosome of Escherichia coli BW25113 by three cycles of insertion and excision as described above. This method proved to be simple and time-saving, which could be applicable to a variety of microorganisms.     

Microarray analysis of Mu transposition in Salmonella enterica, serovar Typhimurium: transposon exclusion by high-density DNA binding proteins

All organisms contain transposons with the potential to disrupt and rearrange genes. Despite the presence of these destabilizing sequences, some genomes show remarkable stability over evolutionary time. Do bacteria defend the genome against disruption by transposons? Phage Mu replicates by transposition and virtually all genes are potential insertion targets. To test whether bacteria limit Mu transposition to specific parts of the chromosome, DNA arrays of Salmonella enterica were used to quantitatively measure target site preference and compare the data with Escherichia coli. Essential genes were as susceptible to transposon disruption as non‐essential ones in both organisms, but the correlation of transposition hot spots among homologous genes was poor. Genes in highly transcribed operons were insulated from transposon mutagenesis in both organisms. A 10 kb cold spot on the pSLT plasmid was near parS, a site to which the ParB protein binds and spreads along DNA. Deleting ParB erased the plasmid cold spot, and an ectopic parS site placed in the Salmonella chromosome created a new cold spot in the presence of ParB. Our data show that competition between cellular proteins and transposition proteins on plasmids and the chromosome is a dominant factor controlling the genetic footprint of transposons in living cells.     

Transfer of nitrate reductase genes of the cyanobacterium Nostoc muscorum into Rhizobium japonicum

Transformation of Rhizobium japonicum CB1809 was studied using DNA from the cyanobacterium Nostoc muscorum ATCC 27893. A spontaneous nitrate reductase deficient (Nar-) mutant (NR-6) of R. japonicum CB1809 was isolated with a frequency of 8.4 X 10(-7). Streptomycin (Sm) and Neomycin (Neo) resistance markers were introduced into strain NR-6, and the resulting strain was designated NR-6 SmR NeoR. Experiments with cyanobacterial DNA and live cells of strain NR-6 SmR NeoR indicated transformation of nitrate reductase (nar) genes of N. muscorum into this strain. This conclusion was supported by the reversion frequency of strain NR-6 SmR NeoR to Nar+ and the transformation frequency when recipient cells were exposed to N. muscorum DNA (with heat-treated DNA as control). Comparisons of growth, nitrate uptake, assimilatory nitrate reductase activity and nodulation of parent CB1809, NR-6 SmR NeoR and five transformant clones (Nar+) suggest that there may be considerable homology between the nar genes of R. japonicum CB1809 and N. muscorum.     

Localization of symbiotic mutations in Rhizobium meliloti

A total of 5 Nod- and 57 Fix- symbiotic mutants of Rhizobium meliloti strain 41 have been isolated after either nitrosoguanidine or Tn5 transposition mutagenesis. Chromosomal locations of mutations in 1 Nod- and 11 Fix- derivatives were ascertained by transferring the chromosome (mobilized by plasmid R68.45), in eight fragments, into symbiotically effective recipients and testing the recombinants for symbiotic phenotype. Alternatively, the kanamycin resistance marker of Tn5 was mapped. In five mutants the fix alleles were localized on different chromosomal regions, but six other fix mutations and one nod mutation tested did not map onto the chromosome. It was shown that the chromosome-mobilizing ability (Cma+) of R68.45 was not involved in the mobilization of genes located extrachromosomally. Moreover, Cma- derivatives of R68.45 could mobilize regions of the indigenous plasmid pRme41b but not chromosomal genes. Thus, mobilization of a marker by Cma- R68.45 indicates its extrachromosomal location. With a 32P-labeled DNA fragment carrying Tn5 as a hybridization probe, it was shown that in five extrachromosomally located Tn5-induced fix mutants and one nod mutant Tn5 was localized on plasmid pRme41b. This is in agreement with the genetic mapping data.     

Comparative analysis of the structure of incompatibility plasmids N, P and W

Evolutionary relationships of the IncN plasmid R15 and other broad host range plasmids (IncN plasmids N3 and R46, IncP plasmids RP4 and R906, IncW plasmids Sa and R388) were studied by Southern blot hybridization technique. The IncN plasmids were shown to harbour homologous determinants for replication and conjugation. No homology was found between the rep and tra genes in R15 and in the IncW and IncP plasmids, respectively. The second rep region of the N3 plasmid is distinctive from the corresponding determinants in the IncN plasmids. Homology was demonstrated for the plasmid genes that mediate restriction and modification in R15 and N3, mercury resistance in R15 and R906, sulfanilamide resistance in R15, N3, R46, Sa, R388, and R906, streptomycin resistance in R15, R46 and Sa. The latter genes are different from the R906 SmR gene. In addition to the three known mobile elements in the plasmid R15, the fourth one (IS46) that is a part of the transposon Tn2353 was identified in this study. Besides, the third copy of this insertion sequence was found in the N3 plasmid.     

Chromosome engineering in Saccharomyces cerevisiae by using a site-specific recombination system of a yeast plasmid.

We have developed an effective method to delete or invert a chromosomal segment and to create reciprocal recombination between two nonhomologous chromosomes in Saccharomyces cerevisiae, using the site-specific recombination system of pSR1, a circular cryptic DNA plasmid resembling 2 microns DNA of S. cerevisiae but originating from another yeast, Zygosaccharomyces rouxii. A 2.1-kilobase-pair DNA fragment bearing the specific recombination site on the inverted repeats of pSR1 was inserted at target sites on a single or two different chromosomes of S. cerevisiae by using integrative vectors. The cells were then transformed with a plasmid bearing the R gene of pSR1, which encodes the site-specific recombination enzyme and is placed downstream of the GAL1 promoter. When the transformants were cultivated in galactose medium, the recombination enzyme produced by expression of the R gene created the modified chromosome(s) by recombination between two specific recombination sites inserted on the chromosome(s).     

Intermolecular Transposition of Is10 Causes Coupled Homologous Recombination at the Transposition Site

Interplasmid and chromosome to plasmid transposition of IS10 were studied by assaying inactivation of the phage 434 cI gene, carried on a low copy number plasmid. This was detected by the activity of the tet gene expressed from the phage 434 P(R) promoter. Each interplasmid transposition resulted in the fusion of the donor and acceptor plasmids into cointegrate structure, with a 9-bp duplication of the target DNA at the insertion site. Cointegrate formation was abolished in δrecA strains, although simple insertions of IS10 were observed. This suggests a two-stage mechanism involving IS10 conservative transposition, followed by homologous recombination between the donor and the acceptor. Two plasmids carrying inactive IS10 sequences were fused to cointegrates at a 100-fold lower frequency, suggesting that homologous recombination is coupled to and stimulated by the transposition event. Each IS10 transposition from the chromosome to the acceptor plasmid involved replicon fusion, providing a mechanism for IS10-mediated integration of extrachromosomal elements into the chromosome. This was accompanied by the formation of an additional copy of IS10 in the chromosome. Thus, like replicative transposition, conservative transposition of IS10 is accompanied by cointegrate formation and results in duplication of the IS10.     

Excision and integration of degradative pathway genes from TOL plasmid pWW0.

WR211 is a transconjugant resulting from transfer of the 117-kilobase (kb) TOL degradative plasmid pWW0 into Pseudomonas sp. strain B13. The plasmid of this strain, pWW01211, is 78 kb long, having suffered a deletion of 39 kb. We show that WR211 contains the 39 kb that is missing from its plasmid, together with at least an additional 17 kb of pWW0 DNA integrated in another part of the genome, probably the chromosome. The ability of WR211 to grow on the TOL-specific substrate m-toluate is the result of expression of the TOL genes in this alternative location, whereas its inability to grow on m-xylene is caused by insertional mutagenesis by 3 kb of DNA of unknown origin in the xylR gene of this DNA. The resident plasmid pWW01211 plays no part in the degradative phenotype of WR211 since it can be expelled by mating in incompatible IncP9 resistance plasmid R2 or pMG18 without loss of the phenotype. This alternatively located DNA can be rescued back into the R2 and pMG18 plasmids as R2::TOL and pMG18::TOL recombinants by mating out into plasmid-free recipients and selecting for Mtol+ transconjugants. In all cases examined, these plasmids contained the entire R plasmid into which is inserted 59 kb of DNA, made up of 56 kb of pWW0 DNA and the 3-kb xylR insertion. Selection for faster growth on benzoate can lead to precise excision of the 39 kb from the TOL region of an R2::TOL recombinant, leaving a residual and apparently cryptic 17-kb segment of pWW0 DNA in the R plasmid.     

Properties of transposon Tn2555 carrying the genes for sucrose utilization

Tn2555, a new transposon coding for genes of sucrose utilization was studied. Tn2555 was shown to integrate into the plasmids RP4 and R6K, phage P1CmClr100 and Escherichia coli K12 chromosome. Tn2555 frequency of transposition to RP4 and R6K DNA is (2-5) X 10(-7) in Rec+-strain, (3-6) X 10(-8) in Rec--strain. Tn2555 integration site in phage P1CmClr100 Sac+-derivative studied has been localised within the C-segment of P1 DNA. In three independent cases of Tn2555 transposition to the chromosome the transposon was found to be integrated in the region between 29 and 32 min of Escherichia coli K12 linkage map. The restriction endonuclease analysis of seven independent isolates of RP4::Tn2555 has shown the grouping of Tn2555 integration sites in the Tn1 region of RP4. Frequent rearrangements occurring within Tn2555 have been revealed by the analysis. However, an invertible DNA segment of about 6-7 kb was preserved in all transposon structures.     

A multi-resistance plasmid isolated from commensal Neisseria species is closely related to the enterobacterial plasmid RSF1010

pFM739, an R plasmid from Neisseria sicca that encodes penicillin, streptomycin and sulphonamide resistance, and the enterobacterial IncQ(P-4) plasmid RSF1010, which encodes streptomycin and sulphonamide resistance, were incompatible, and were mobilized by the same conjugative plasmids. Restriction mapping confirmed a high degree of similarity between both R plasmids; pFM739 carried DNA fragments corresponding to the known replication and resistance regions of RSF1010. pFM739 also carried an extra segment with the same restriction map as that described for the beta-lactamase-coding region of transposon Tn3. It is suggested that the R plasmids isolated from commensal Neisseria sp. could have resulted from transposition of a Tn3-like genetic element to an RSF1010-like plasmid, and that they contain deletion derivatives of transposon Tn3.     

Selection of independent plasmids determining phenol degradation in Pseudomonas putida and the cloning and expression of genes encoding phenol monooxygenase and catechol 1,2-dioxygenase

Long-term cultivation of the Pseudomonas putida multiplasmid strain EST1020 on phenol resulted in the formation of individual PHE plasmids determining phenol degradation. Four types of PHE plasmids, pEST1024, pEST1026, pEST1028, and pEST1029, are characterized. They all contain a transferrable replicon similar to pWWO-8 with a partly duplicated DNA sequence of the 17-kb transposable element of this plasmid and include various amounts of DNA that carry genes encoding phenol degradation (phe genes). We cloned the genes determining phenol monooxygenase and catechol 1,2-dioxygenase from the Pseudomonas sp. parent strain plasmid DNA into the broad host range vector pAYC32 and studied the expression of the cloned DNA. The formation of a new hybrid metabolic plasmid, pEST1354, was demonstrated in P. putida PaW85 as the result of transposition of the 17-kb genetic element from the chromosome of PaW85 into the plasmid carrying cloned phe genes. The target site for the 17-kb transposon was localized in the vector DNA, just near the cloning site. In subcloning experiments we found two regions in the 17-kb DNA stretch that are involved in the expression of the cloned phe genes.     

Duplication insertion of drug resistance determinants in the radioresistant bacterium Deinococcus radiodurans.

Escherichia coli drug resistance plasmids were introduced into Deinococcus radiodurans by cloning D. radiodurans DNA into the plasmids prior to transformation. The plasmids were integrated into the chromosome of the transformants and flanked by a direct repeat of the cloned D. radiodurans segment. The plasmid and one copy of the flanking chromosomal segment constituted a unit ("amplification unit") which was found repeated in tandem at the site of chromosomal integration. Up to 50 copies of the amplification unit were present per chromosome, accounting for approximately 10% of the genomic DNA. Circular forms of the amplification unit were also present in D. radiodurans transformants. These circles were introduced into E. coli, where they replicated as plasmids. The drug resistance determinants which have been introduced into D. radiodurans in this fashion are cat (from Tn9) and aphA (from Tn903). Transformation of D. radiodurans to drug resistance was efficient when the donor DNA was from D. radiodurans or E. coli, but was greatly reduced when the donor DNA was linearized with restriction enzymes prior to transformation. In the course of the study, a plasmid, pS16, was discovered in D. radiodurans R1, establishing that all Deinococcus strains so far examined contain plasmids.     

Bacterial resistance evolution by recruitment of super-integron gene cassettes

The capture and spread of antibiotic resistance determinants by integrons underlies the rapid evolution of multiple antibiotic resistance among diverse Gram-negative clinical isolates. The association of multiple resistance integrons (MRIs) with mobile DNA elements facilitates their transit across phylogenetic boundaries and augments the potential impact of integrons on bacterial evolution. Recently, ancestral chromosomal versions, the super-integrons (SIs), were found to be genuine components of the genomes of diverse bacterial species. SIs possess evolutionary characteristics and stockpiles of adaptive functions, including cassettes related to antibiotic resistance determinants previously characterized in clinical isolates, which suggest that MRIs and their resistance genes were originally recruited from SIs and their pool of amassed genes. However, the recombination activity of integrons has never been demonstrated in a bacterium other than Escherichia coli. We introduced a naturally occurring MRI (TpR, SulR) on a conjugative plasmid into Vibrio cholerae, a species known to harbour a SI. We show that MRIs can randomly recruit genes directly from the cache of SI cassettes. By applying a selective constraint for the development of antibiotic resistance, we demonstrate bacterial resistance evolution through the recruitment a novel, but phenotypically silent, chloramphenicol acetyltransferase gene from the V. cholerae SI and its precise insertion into the MRI. The resulting resistance profile (CmR, TpR, SulR) could then be disseminated by conjugation to other clinically relevant pathogens at high frequency. These results demonstrate that otherwise phenotypically sensitive strains may still be a genetic source for the evolution of resistance to clinically relevant antibiotics through integron-mediated recombination events.     

Incorporation of the ampicillin resistance transposon into the Escherichia coli K-12 chromosome and into plasmids]

The mutant pEG1 of R-factor RP4 with temperature-sensitive defect in replication, carrying a transposable ampicillin resistance element Tn1 was used to define the frequency of insertion of this element into Escherichia coli K-12 chromosome and some other plasmids. Our results indicate that the frequency of colony forming by bacteria with pEG1-factor on ampicillin medium in non-permissive conditions corresponds to the frequency of Tn1 insertion into bacterial chromosome or some other plasmid (in case when the strains are carrying a second plasmid). The frequency of Tn1 insertion into the chromosome is about 4.10(-4). The defect in recA gene produce no serious change in the frequency of Tn1 insertion into the bacterial chromosome. The translocation of Tn1 element from pEG1-factor to R483, R6 and ColE1 plasmids occurs at 10 to 100-fold-higher frequency than from the plasmid to the chromosome. The insertion of Tn1 into the F'-factor KLF10 and R-factor R64-11 occurs at far lower frequency than that to plasmids R6, R483, or ColE1.     

A novel family of potentially mobile DNA elements encoding site-specific gene-integration functions: integrons

A family of novel mobile DNA elements is described, examples of which are found at several independent locations and encode a variety of antibiotic resistance genes. The complete elements consist of two conserved segments separated by a segment of variable length and sequence which includes inserted antibiotic resistance genes. The conserved segment located 3' to the inserted resistance genes was sequenced from Tn21 and R46, and the sequences are identical over a region of 2026 bases, which includes the sulphonamide resistance gene sull, and two further open reading frames of unknown function. The complete sequences of both the 3' and 5' conserved regions of the DNA element have been determined. A 59-base sequence element, found at the junctions of inserted DNA sequences and the conserved 3' segment, is also present at this location in the R46 sequence. A copy of one half of this 59-base element is found at the end of the sull gene, suggesting that sull, though part of the conserved region, was also originally inserted into an ancestral element by site-specific integration. Inverted or direct terminal repeats or short target site duplications, both of which are characteristics of class I and class II transposons, are not found at the outer boundaries of the elements described here. Furthermore, the conserved regions do not encode any proteins related to known transposition proteins, except the DNA integrase encoded by the 5' conserved region which is implicated in the gene insertion process. Mobilization of this element has not been observed experimentally; mobility is implied from the identification of the element in at least four independent locations, in Tn21, R46 (IncN), R388 (IncW) and Tn1696. The definitive features of these novel elements are (i) that they include site-specific integration functions (the integrase and the insertion site); (ii) that they are able to acquire various gene units and act as an expression cassette by supplying the promoter for the inserted genes. As a consequence of acquiring different inserted genes, the element exists in a variety of forms which differ in the number and nature of the inserted genes. This family of elements appears formally distinct from other known mobile DNA elements and we propose the name DNA integration elements, or integrons.     

Coupling and rec-independence of the processes of replication and transposition of Pseudomonas aeruginosa phage D3112. The effect of the phage genes controlling the replication of DNA of D3112

D3112 phage was shown to replicate via the process of coupled replication--transposition: the phage DNA is not excised from the chromosome after prophage induction and new phage copies insert into many different sites. The transposition is controlled by two D3112 early genes--A (mapped in the 1.5-3 kbp region) and B (3-4.5 kbp), and requires intact attL site (involvement of the phage right end attR not studied). D3112 is capable to transpose RP4 plasmid into the chromosome; both the D3112 and RP4 transpositions are rec-independent. The product of the early C gene which is not required for D3112 transposition has pleiotropic effect on the development of D3112 and is necessary for the process of D3112 DNA excision from the chromosome, for cell lysis as well as for mature phage production. We suggest that this gene is responsible for positive regulation of D3112 late genes expression, similar to the C gene of Mu phage or Q gene of lambda. Mutations in four D3112 late genes ts25, ts35, ts73 and ts110 do not affect transposition or excision processes. No detectable (less than 0.02 copies per cell) amount of linear or circular D3112 DNA is formed during the replication--transposition. Hence, in the course of replication and transposition processes D3112 genome has its ends permanently bound covalently to the chromosome. The excision of the D3112 DNA takes place at late stages.