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.     

Association of the strA-strB genes with plasmids and transposons in the present-day bacteria and in bacterial strains from permafrost

Transposons closely related to the streptomycin resistance transposon of modem bacteria, Tn5393, were detected in the bacterial isolates from permafrost resistant to streptomycin. Many transposons studied were located on the medium-size plasmids with a narrow host range. None of the streptomycin-resistant strains isolated from permafrost contained small plasmids carrying the strA-strB genes and related to the broad host range plasmid RSF1010.     

Translocation of ampicillin transposon Tn1 in Escherichia coli cells during sexual reproduction

The efficiency of Tn1 transposition has been shown to increase considerably in course of bacterial conjugation. Usually, the frequency of Tn1 transposition from plasmid pSA2001, a derivative of RP4, into the chromosome never exceeded 0.1% per cell. Percentage of His+ transconjugants, marked by transposon Tn1 during conjugation between Hfr donor, carrying plasmid pSA2001, and auxotrophic recipient, was about 30%. Transposon Tn1 transfer into the recipient cells does not depend on the recA+ gene function in donor cells or on conjugative transfer of plasmid pSA2001. The transfer requires the recA+ gene function in recipients as well as the Hfr function in donor cells. Southern's blot-hybridization revealed the insertion of transposon Tn1 into the different sites of the chromosome of His+ transconjugants. The transposon inserted during conjugation retains the ability to potential further translocation into new sites on the chromosomal DNA.     

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.     

Molecular genetic analysis of the Tn5041 transposition system

A study was made of the transposition of the mercury resistance transposon Tn5041 which, together with the closely related toluene degradation transposon Tn4651, forms a separate group in the Tn3 family. Transposition of Tn5041 was host-dependent: the element transposed in its original host Pseudomonas sp. KHP41 but not in P. aeruginosa PAO-R and Escherichia coli K12. Transposition of Tn5041 in these strains proved to be complemented by the transposase gene (tnpA) of Tn4651. The gene region determining the host dependence of Tn5041 transposition was localized with the use of a series of hybrid (Tn5041 x Tn4651) tnpA genes. Its location in the 5'-terminal one-third of the transposase gene is consistent with the data that this region is involved in the formation of the transposition complex in transposons of the Tn3 family. As in other transposons of this family, transposition of Tn5041 occurred via cointegrate formation, suggesting its replicative mechanism. However, neither of the putative resolution proteins encoded by Tn5041 resolved the cointegrates formed during transposition or an artificial cointegrate in E. coli K12. Similar data were obtained with the mercury resistance transposons isolated from environmental Pseudomonas strains and closely related to Tn5041 (Tn5041 subgroup).     

Characteristics of transposition of Tn7-like elements determining resistance to trimethoprim and streptomycin

The transposing elements Tn7, Tn1824, controlling the resistance to trimethoprim and Tn1925, Tn1826, carrying the streptothricin resistance genes were classified as a new transposon family on the basis of their physical structure. The comparative genetic analysis of the frequency, specificity and insertion orientation in different replicons, obtained in independent research systems in this study, demonstrated the identity of transposition characteristics of the transposons. The latter makes it possible to classify them as an independent transposon family. The peculiar feature of the Tn7-like elements family is their RecA-dependent transposition into the chromosome of Escherichia coli stimulated by bacteriophage Plkc transduction of the transposons.     

The trimethoprim resistance transposon Tn7 contains a cryptic streptothricin resistance gene

The transposon Tn7 codes for a trimethoprim resistance and for a streptomycin/spectinomycin resistance function of the bacterial host cells. Cloning of a restriction fragment of Tn7 into the vector plasmid pUC19 reveals the presence in Tn7 of an additional potential resistance determinant. A streptothricin resistance gene, which appears cryptic in the original Tn7 context becomes activated in the recombinant plasmid upon supplying the promoter function of the lacZ system of pUC19. These results together with previously published sequence data further disclose the modular character in the resistance gene regions of Tn7-like transposons.     

Localization of insertion into E. coli chromosome of Tn7-like transposons controlling resistance to trimethoprim and streptothricin

To localize the insertion sites for Tn7-like transposons Tn1824, Tn1825 and Tn1826 the EcoRI-cleaved fragments of E. coli recA+ and recA- strains chromosome carrying the transposons were hybridized. It was shown that transposition of Tn7-like elements takes place in the strictly defined region of E. coli chromosome, like it had been previously described for transposon Tn7.     

Bacteroides fragilis transfer factor Tn5520: the smallest bacterial mobilizable transposon containing single integrase and mobilization genes that function in Escherichia coli

Many bacterial genera, including Bacteroides spp., harbor mobilizable transposons, a class of transfer factors that carry genes for conjugal DNA transfer and, in some cases, antibiotic resistance. Mobilizable transposons are capable of inserting into and mobilizing other, nontransferable plasmids and are implicated in the dissemination of antibiotic resistance. This paper presents the isolation and characterization of Tn5520, a new mobilizable transposon from Bacteroides fragilis LV23. At 4,692 bp, it is the smallest mobilizable transposon reported from any bacterial genus. Tn5520 was captured from B. fragilis LV23 by using the transfer-deficient shuttle vector pGAT400DeltaBglII. The termini of Tn5520 contain a 22-bp imperfect inverted repeat, and transposition does not result in a target site repeat. Tn5520 also demonstrates insertion site sequence preferences characterized by A-T-rich nucleotide sequences. Tn5520 has been sequenced in its entirety, and two large open reading frames whose predicted protein products exhibit strong sequence similarity to recombinase-integrase enzymes and mobilization proteins, respectively, have been identified. The transfer, mobilization, and transposition properties of Tn5520 have been studied, revealing that Tn5520 mobilizes plasmids in both B. fragilis and Escherichia coli at high frequency and also transposes in E. coli.     

ISPpy1, a novel mobile element of the ancient Psychrobacter maritimus permafrost strain: translocations in Escherichia coli K-12 cells and formation of composite transposons

It was shown that IS element ISPpyl isolated earlier in the permafrost strain Psychrobacter maritimus MR29-12 has a high level of functional activity in cells of the heterologous host Escherichia coli K-12. ISPpyl can be translocated in E. coli cells by itself and mobilize adjacent genes and can also form composite transposons flanked by two copies of this element. Apart from translocations between different plasmids, the composite ISPpyl-containing transposon Tn5080a is capable of translocation from the plasmid into the E. coli chromosome with high frequency and from the chromosome into the plasmid. Among products of Tn5080a transposition into plasmid R388, simple insertions were predominantly formed together with cointegrates. Upon mobilization of adjacent genes with the use of one ISPpyl copy, only cointegrates arise.     

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.     

Tn5253, the pneumococcal omega (cat tet) BM6001 element, is a composite structure of two conjugative transposons, Tn5251 and Tn5252.

Tn5253, carrying tetracycline and chloramphenicol resistance determinants, is a 65.5-kb conjugative transposon originally detected in the chromosome of Streptococcus pneumoniae BM6001. We have identified an 18-kb segment of DNA carrying the tet determinant within Tn5253 to be an independent conjugative transposon when removed from the context of the larger element. In vivo deletion of this DNA segment, now termed Tn5251, from within Tn5253 did not affect the conjugative transposition properties of the remaining sequences. Thus, Tn5253 is a composite element of two conjugative structures: Tn5252, constituting the sequences beyond Tn5251 within Tn5253, and Tn5251. The transfer properties of Tn5252 and Tn5251 suggest that these may belong to two different classes of mobile elements even though they were initially found associated. The notion that a tet-carrying transposon like Tn5251 may have been the ancestral element in the evolution of the larger streptococcal conjugative transposons must be reevaluated in the light of present observations.     

Conjugative transfer of Tn916 in Enterococcus faecalis: trans activation of homologous transposons.

Tn916 [carries tet(M)] is a 16.4-kb conjugative transposon that can establish itself in multiple copies in Enterococcus faecalis. To study the interaction of coresident homologous transposons during conjugation, an E. faecalis mutant defective in homologous recombination was utilized for construction of strains harboring Tn916 delta E (a derivative in which erm is substituted for tet) on the chromosome and Tn916 on a nonconjugative plasmid. When these strains were used as donors, the two transposons were able to transfer independently; however, they were found to transfer and become coestablished in the recipient up to 50% of the time. In contrast, cotransfer of a plasmid marker located outside the transposon occurred at a frequency of no greater than 0.5%. Separate experiments showed that mobilization of the nonconjugative plasmids pAM401 and pVA749 by chromosome-borne copies of Tn916 occurred only at low frequencies (generally less than 2% cotransfer). The data imply that the initiation of transposition of Tn916 results in a trans activation that is specific for homologous transposons present in the same cell.     

Structure of haloacetate-catabolic IncP-1beta plasmid pUO1 and genetic mobility of its residing haloacetate-catabolic transposon

The self-transmissible plasmid pUO1 from Delftia acidovorans strain B carries two haloacetate-catabolic transposons, TnHad1 and TnHad2, and the mer genes for resistance to mercury. The complete 67,066-bp sequence of pUO1 revealed that the mer genes were also carried by two Tn402/Tn5053-like transposons, Tn4671 and Tn4672, and that the pUO1 backbone regions shared 99% identity to those of the archetype IncP-1beta plasmid R751. Comparison of pUO1 with three other IncP-1beta plasmids illustrated the importance of transposon insertion in the diversity and evolution of this group of plasmids. Mutational analysis of the four outermost residues in the inverted repeats (IRs) of TnHad2, a Tn21-related transposon, revealed a crucial role of the second residue of its IRs in transposition.     

Absence of cis-acting transposition immunity with Tn7

It is possible in two steps to insert into the plasmid RP4 two copies of the transposon Tn7. This was demonstrated using a wild-type Tn7 in the first step, and a Tn7 derivative (carrying an additional marker), in the second step. The two successive transpositions occurred with the same polarity and frequency. The genetic structures of the resulting plasmids, predicted from the phenotypes of the bacterial host, were confirmed by direct analysis of the plasmid DNAs. Thus, the phenomenon of cis-acting transposition immunity, described with Tn1 or Tn3, does not take place in the case of Tn7.     

Tn5053 family transposons are res site hunters sensing plasmidal res sites occupied by cognate resolvases

DNA sequence database search revealed that most of Tn5053/Tn402 family transposons inserted into natural plasmids were located in putative res regions upstream of genes encoding various resolvase-like proteins. Some of these resolvase genes belonged to Tn3 family transposons and were closely related to the tnpR genes of Tn1721 and a recently detected Tn5044. Using recombinant plasmids containing fragments of Tn1721 or Tn5044 as targets in transposition experiments, we have demonstrated that Tn5053 displays striking insertional preference for the res regions of these transposons: more than 70% of Tn5053 insertion events occur in clusters inside the target res regions, while most remaining insertion events occur no further than 200 base pairs away from both sides of the res regions. We demonstrate that Tn5053 insertions (both into and outside a res region of the target plasmid) require the presence of a functional cognate resolvase gene either in cis or in trans. To our knowledge, this is the first case when a site-specific recombination system outside a transposon has been shown to be involved in transposition.     

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.     

Identification and characterization of Tn4656, a novel class II transposon carrying a set of toluene-degrading genes from TOL plasmid pWW53

It has been reported that the toluene-degrading (xyl) genes from Pseudomonas putida plasmid pWW53 are able to translocate to broad-host-range drug resistance plasmid RP4, and pWW53-4 is one of the smallest RP4 derivatives (H. Keil, S. Keil, R. W. Pickup, and P. A. Williams, J. Bacteriol. 164:887-895, 1985). Our investigation of pWW53-4 in this study demonstrated that such a translocated region that is 39 kb long is a transposon. This mobile element, Tn4656, was classified as a class II transposon since its transposition occurred by a two-step process: transposase (TnpA)-mediated formation of the cointegrate and resolvase (TnpR)-mediated site-specific resolution of the cointegrate at the two copies of the res site. The Tn4656 TnpA and TnpR functions encoded in the rightmost 4-kb region were found to be exchangeable with those specified by other Tn1721-related class II transposons, including another toluene transposon, Tn4653. Sequence analysis of the transposition-related genes and sites of Tn4656 also supported the hypothesis that this transposon is closely related to the Tn1721-related transposons. The lower transposition frequency of Tn4656 has been suggested to be due to the unique nucleotide sequence of one of the terminal 39-bp inverted repeats.     

New transposons to generate GFP protein fusions in Candida albicans

Transposon elements are important tools for gene function analysis, for example they can be used to easily create genome-wide collections of insertion mutants. Transposons may also carry sequences coding for an epitope or fluorescent marker useful for protein expression and localization analysis. We have developed three new Tn5-based transposons that incorporate a GFP (green fluorescent protein) coding sequence to generate fusion proteins in the important fungal pathogen Candida albicans. Each transposon also contains the URA3 and Kan(R) genes for yeast and bacterial selection, respectively. After in vitro transposition, the insertional allele is transferred to the chromosomal locus by homologous recombination. Transposons Tn5-CaGFP and Tn5-CaGFP-URA3::FLIP can generate C-terminal truncated GFP fusions. A URA3 flipper recycling cassette was incorporated into the transposon Tn5-CaGFP-URA3::FLIP. After the induction of Flip recombinase to excise the marker, the heterozygous strain is transformed again in order to obtain a GFP-tagged homozygous strains. In the Tn5-CaGFP-FL transposon the markers are flanked by a rare-cutting enzyme. After in vitro transposition into a plasmid-borne target gene, the markers are eliminated by restriction digestion and religation, resulting in a construct coding for full-length GFP-fusion proteins. This transposon can generate plasmid libraries of GFP insertions in proteins where N- or C-terminal tagging may alter localization. We tested our transposon system by mutagenizing the essential septin CDC3 gene. The results indicate that the Cdc3 C-terminal extension is important for correct septin filament assembly. The transposons described here provide a new system to obtain global gene expression and protein localization data in C. albicans.     

Characterization of a class II defective transposon carrying two haloacetate dehalogenase genes from Delftia acidovorans plasmid pUO1

The two haloacetate dehalogenase genes, dehH1 and dehH2, on the 65-kb plasmid pUO1 from Delftia acidovorans strain B were found to be located on transposable elements. The dehH2 gene was carried on an 8.9-kb class I composite transposon (TnHad1) that was flanked by two directly repeated copies of IS1071, IS1071L and IS1071R. The dehH1 gene was also flanked by IS1071L and a truncated version of IS1071 (IS1071N). TnHad1, dehH1, and IS1071N were located on a 15.6-kb class II transposon (TnHad2) whose terminal inverted repeats and res site showed high homology with those of the Tn21-related transposons. TnHad2 was defective in transposition because of its lacking the transposase and resolvase genes. TnHad2 could transpose when the Tn21-encoded transposase and resolvase were supplied in trans. These results demonstrated that Tn Had2 is a defective Tn21-related transposon carrying another class I catabolic transposon.