The integration-excision system of the conjugative transposon Tn 1545 is structurally and functionally related to those of lambdoid phages

Excision of Tn1545 and related conjugative transposons of Gram-positive bacteria occurs by reciprocal site-specific recombination between non-homologous regions of the transposon-target junctions. Excisive recombination requires two transposon-encoded proteins designated Xis-Tn and Int-Tn. We have shown that, following excision, Tn1545 is a circular structure with ends separated by either of the two hexanucleotides that were present at the transposon-target junctions. Using a trans-complementation assay, we have demonstrated that Int-Tn is able to catalyse in vivo integration of a circular intermediate of Tn1545 defective for integration and excision. comparison of integration sites suggests that limited sequence homology at the vicinity of the recombining sites is required for integration of the element. These data support the hypothesis that the integration/excision systems of conjugative transposons from Gram-positive cocci and of lambdoid phages from Gram-negative bacilli have evolved from a common ancestor.     

Control of Tn7 transposition

Summary Our isolate of Tn7 (named Tn7S) contains an IS1 insertion, and this IS1 can be converted into Tn9. In vitro and in vivo deletions of Tn7S and Tn7S:: Tn9 define regions of the transposon required for antibiotic resistance and transposition. Complementation of deletion mutants by cloned Tn7 fragments indicates the existence of two regions, denoted tnp7A and tnp7B, required for all transposition events. Another region, denoted tnp7C, is required for transposition from the chromosome to RP1 but not for transposition from a small IncP-1 replicon to the chromosome. The presence of Tn7S terminal sequences in an RP1 replicon reduces the transposition of a second Tn7S derivative from the chromosome by about one order of magnitude. The measured frequency of Tn7S transpositions from a small IncP-1 replicon to the chromosome depends on the particular incompatibility system used to eliminate that replicon. Genetic and physical data indicate that high frequencies of Tn7S transposition to the chromosome (40%) are triggered by the IncP-1 incompatibility reaction, thus suggesting the existence of a Tn7 mechanism for sensing the state of the carrier replicon.     

Characterization of the transposon carrying the STII gene of enterotoxigenic Escherichia coli

Summary The Escherichia coli enterotoxin STII gene is carried by Tn4521. The terminal repeats of Tn4521 are composed of IS2 sequences; however, neither repeat is a complete IS2. In order to determine how this seemingly defective transposon could transpose, mutations were generated within Tn4521 to determine the regions essential for transposition. The left terminal repeat region was found to be non-essential, but the right terminal repeat area was demonstrated to be crucial for transposition. Within the right terminal repeat area is an open reading frame (ORF), capable of encoding a 159 amino acid protein, which was shown by frameshift mutation analysis to be required for transposition. This protein may be the transposase of Tn4521. A pair of 11 bp repeat sequences flanking the ORF was also found to be important. The right 11 bp repeat is part of the left IS2 terminal sequence, and the left 11 bp repeat is located about 300 bp upstream from the right IS2 terminal sequence located within the right terminal repeat region. The results of this study suggest that Tn4521 is a functional transposon and that the sequence including this pair of 11 bp sequences plus the intervening sequence is a transposable element which may be responsible for Tn4521 transposition.     

Genetic analysis of a transposon carrying toluene degrading genes on a TOL plasmid pWWO

Summary Toluene degrading (xyl) genes on a Pseudomonas TOL plasmid pWWO are located within a 39-kb DNA portion. The 56-kb region including these xyl genes and its 17-kb derivative with a deletion of the internal 39-kb portion transposed to various sites on target replicons such as pACYC184 and R388 in escherichia coli recA strains. Thus the 56- and 17-kb regions were designated Tn4651 and Tn4652, respectively. Genetic analysis of Tn4652 demonstrated that its transposition occurs by a two-step process, namely, cointegrate formation and its subsequent resolution. The presence in cis of DNA sequences of no more than 150 bp at both ends of Tn4652 was prerequisite for cointegrate formation, and this step was mediated by a trans-acting factor, transposase, which was encoded in a 3.0-kb segment at one end of the transposon. Cointegrate resolution took place site-specifically within a 200-bp fragment, which was situated 10 kb away from the transposase gene. Based on the stability of cointegrates formed by various mini-Tn4652 derivatives, it was shown that the cointergrate resolution requires two trans-acting factors encoded within 1.0- and 1.2-kb fragments that encompass the recombination site involved in the resolution.     

Resolution of a hybrid cointegrate between transposons Tn501 and Tn1721 defines the recombination site

Summary The related transposons Tn501 and Tn1721 have a 3.8 kb region in common that contains two genes (tnpA and tnpR) and a resolution site (res) required for transposition. Resolvase, the product of tnpR, catalyses site-specific recombination at res, a 186 base pair (bp) sequence located adjacent to tnpR at one end of the homology region. We describe here identification of the crossover site within res. It involved the construction of a plasmid containing copies of res (Tn501) and res (Tn1721) in direct orientation and tnpR-mediated intramolecular recombination between the two homologous (but non-identical) sites. The resulting hybrid contained Tn501 and Tn1721 fused at the crossover point. DNA sequence analysis of the recombinant indicates that recombination occurs in an 11 bp region of exact homology between Tn501 and Tn1721. The recombination site lies 161–172 bp upstream of tnpR at the transition from homology to non-homology between Tn501 and Tn1721 suggesting that site-specific recombination may have played a role in the evolution of these elements.     

Conjugative transposition of the vancomycin resistance carrying Tn1549: enzymatic requirements and target site preferences

Rapid spread of resistance to vancomycin has generated difficult to treat bacterial pathogens worldwide. Though vancomycin resistance is often conferred by the conjugative transposon Tn1549, it is yet unclear whether Tn1549 moves actively between bacteria. Here we demonstrate, through development of an in vivo assay system, that a mini‐Tn1549 can transpose in E. coli away from its natural Gram‐positive host. We find the transposon‐encoded INT enzyme and its catalytic tyrosine Y380 to be essential for transposition. A second Tn1549 protein, XIS is important for efficient and accurate transposition. We further show that DNA flanking the left transposon end is critical for excision, with changes to nucleotides 7 and 9 impairing movement. These mutations could be partially compensated for by changing the final nucleotide of the right transposon end, implying concerted excision of the two ends. With changes in these essential DNA sequences, or without XIS, a large amount of flanking DNA transposes with Tn1549. This rescues mobility and allows the transposon to capture and transfer flanking genomic DNA. We further identify the transposon integration target sites as TTTT‐N6‐AAAA. Overall, our results provide molecular insights into conjugative transposition and the adaptability of Tn1549 for efficient antibiotic resistance transfer.     

Sequence requirements of Escherichia coli attTn7, a specific site of transposon Tn7 insertion.

Transposon Tn7 transposes at high frequency to a specific site, attTn7, in the Escherichia coli chromosome. We devised a quantitative assay for Tn7 transposition in which Tn7-end derivatives containing the cis-acting transposition sequences of Tn7 transpose from a bacteriophage lambda vector upon infection into cells containing the Tn7-encoded transposition proteins. We used this assay to identify a 68-base-pair DNA segment containing the sequences essential for attTn7 target activity. This segment is positioned asymmetrically with respect to the specific point of Tn7 insertion in attTn7 and lacks obvious homology to the sequences at the ends of Tn7 which participate directly in transposition. We also show that some sequences essential for attTn7 target activity are contained within the protein-coding sequence of a bacterial gene.     

Tn5 insertion specificity is not influenced by IS50 end sequences in target DNA.

Summary The bacterial transposon Tn5 inserts into dozens of sites in a gene, some of which are used preferentially (hotspots). Features of certain sites and precedents provided by several other transposons had suggested that sequences in target DNA corresponding to the ends of Tn5 or of its component IS50 elements might facilitate transposition to these sites. We tested this possibility using derivatives of plasmid pBR322 carrying IS50 I or O end sequences. Tn5 inserted frequently into an IS50 I end at the major hotspot in pBR322, but not into either an I end or an O end 230 by away from this hotspot. Adenine (dam) methylation at GATC sequences in the I end segment interferes with its use as the end of a transposon, but a dam ^– mutation did not affect Tn5 insertion relative to an I end sequence in target DNA. These results support models in which the ability of Tn5 to find its preferred sites depends on several features of DNA sequence and conformation, and in which target selection is distinct from recognition of the element ends during transposition.     

The cis-acting DNA sequences required in vivo for bacteriophage Mu helper-mediated transposition and packaging

The 37,000 bp double-stranded DNA genome of bacteriophage Mu behaves as a plaque-forming transposable element of Escherichia coli. We have defined the cis-acting DNA sequences required in vivo for transposition and packaging of the viral genome by monitoring the transposition and maturation of Mu DNA-containing pSC101 and pBR322 plasmids with an induced helper Mu prophage to provide the trans-acting functions. We found that nucleotides 1 to 54 of the Mu left end define an essential domain for transposition, and that sequences between nucleotides 126 and 203, and between 203 and 1,699, define two auxiliary domains that stimulate transposition in vivo. At the right extremity, the essential sequences for transposition require not more than the first 62 base pairs (bp), although the presence of sequences between 63 and 117 bp from the right end increases the transposition frequency about 15-fold in our system. Finally, we have delineated the pac recognition site for DNA maturation to nucleotides 32 to 54 of the Mu left end which reside inside of the first transposase binding site (L1) located between nucleotides 1–30. Thus, the transposase binding site and packaging domains of bacteriophage Mu DNA can be separated into two well-defined regions which do not appear to overlap.Abbreviations attL attachment site left - attR attachment site right - bp base pairs - Kb kilobase pair - nt nucleotide - Pu Purine - Py pyrimidine - Tn transposable element State University of New York, Downstate Medical Center, Brooklyn, NY 11204 USA     

Transposon Tn951 (TnLac) is defective and related to Tn3

Summary Tn951 is flanked by two perfect inverted repeats of 41 bp which include the 38 bp sequence of the IR of Tn3. Tn951 also contains the last 100 bp of the tnpA gene but with at least two mutations. However, beyond nucleotide 137 the sequences diverge and hybridization experiments show that Tn951 lacks at least the first two thirds of the tnpA gene.In agreement with these observations Tn951 does not transpose by itself at a detectable frequency but can be complemented by the tnpA gene of Tn801 or Tn3. Tn501, Tn1721 and gamma delta do not complement Tn951 transposition.Transposition of Tn951 duplicates 5 bp of target DNA sequence.     

Inter- and intramolecular transposition of Tn903.

Summary We have performed a detailed analysis of intra-and intermolecular endproducts of transposition of the compound transposon Tn903 and we show that, in our system, the transposition activity is almost entirely driven by one of the flanking insertion sequences, IS903L. The relatively inactive state of IS903R can be conferred on IS903L by changing the orientation of the internal Tn region. IS903L mediates the formation of the majority of adjacent deletions, insertion/inversions nd cointegrates, all of which are representative of replicative transposition; only a very low level of conservative transposition can be observed. Our results are discussed in relation to those showing that Tn903 uses predominantly the conservative pathway.     

Tn1545: a conjugative shuttle transposon

Summary Tn1545, from Streptococcus pneumoniae BM4200, confers resistance to kanamycin (aphA-3), erythromycin (ermAM) and tetracycline (tetM). The 25.3 kb element is self-transferable to various Gram-positive bacterial genera where it transposes. Tn1545 was cloned in its entirety in the recombination deficient Escherichia coli HB101 where it was unstable. The three resistance genes aphA-3, ermAM and tetM were expressed but were not transferable to other E. coli cells. Tn1545 transposed from the hybrid plasmid to multiple sites of the chromosome of its new host. The element re-transposed, at a frequency of 5×10^-9, from the chromosome to various sites of a conjugative plasmid where it could be lost by apparently clean excision. The element transformed and transposed to the chromosome of Bacillus subtilis. The properties of the conjugative shuttle transposon Tn1545 may account for the recent emergence of genes from Gram-positive bacteria in Gramnegative organisms.     

Tn916 target DNA sequences bind the C-terminal domain of integrase protein with different affinities that correlate with transposon insertion frequency.

The conjugative transposon Tn916 inserts with widely different frequencies into a variety of target sites with related nucleotide sequences. The binding of chimeric proteins, consisting of maltose-binding protein fused to Tn916 integrase, to three different target sequences for Tn916 was examined by DNase I protection experiments. The C-terminal DNA binding domain of the Tn916 integrase protein was shown to protect approximately 40 bp, spanning target sites in the orfA and cat genes of the plasmid pIP501 and in the cylA gene of the plasmid pAD1. Competition binding assays showed that the affinities of the three target sites for Tn916 integrase varied over a greater than 3- but less than 10-fold range and that the cat target site bound integrase at a lower affinity than did the other two target sites. A PCR-based assay for transposition in Escherichia coli was developed to assess the frequency with which a defective minitransposon inserted into each target site. In these experiments, integrase provided in trans from a plasmid was the sole transposon-encoded protein present. This assay detected transposition into the orfA and cylA target sites but not into the cat target site. Therefore, the frequency of transposon insertion into a particular target site correlated with the affinity of the target for the integrase protein. Sequences within the target fragments similar to known Tn916 insertion sites were not protected by integrase protein. Analysis ot he electrophoretic behavior of circularly permuted sets of DNA fragments showed that all three target sites contained structural features consistent with the presence of a static bend, suggesting that these structural features in addition to the primary nucleotide sequence are necessary for integrase binding and, thus, target site activity.     

Genetic analysis of Tn7 transposition

Summary The purpose of this work was to localize the DNA regions necessary for the transposition of Tn7. Several deletions of Tn7 were constructed by the excision of DNA fragments between restriction sites. The ability of these deleted Tn7s to transpose onto the recipient plasmid RP4 was examined. All the deleted Tn7s isolated in this work had lost their transposing capability. The possibility of complementing them was studied using plasmids containing all or part of Tn7. Two deleted Tn7s could not be complemented by an entire Tn7 indicating that a DNA sequence greater than the 42 bp terminal sequence is needed for recognition of the transposon by a transposition function. Four other deleted Tn7s could be complemented by Tn7. One of these was studied intensively in complementation experiments using different parts of Tn7 to obtain transposition. The results obtained allow us to propose that all genes needed for transposition of Tn7 onto plasmids are contained in a DNA segment of between 6.0 and 7.4 kb. Furthermore, one essential function must be contained in a DNA fragment longer than 2.5 kb on the right-hand end of Tn7. The classification of Tn7 with regard to the other transposable elements is discussed.     

Specificity of Transposon Tn5 Insertion

Genetic mapping studies had shown that the bacterial transposon Tn5 can insert into many sites in a gene, but that some sites are preferred. To begin understanding Tn5's insertion specificity at the molecular level, we selected transpositions of Tn5 from the Escherichia coli chromosome to the plasmid pBR322 and analyzed the resultant pBR322::Tn5 plasmids by restriction endonuclease digestion and DNA sequencing. Seventy-five insertions in the tet gene were found at 28 sites including one major hotspot (with 21 insertions) and four lesser hotspots (with four to ten insertions each). All five hotspots are within the first 300 of the 1250-base pair (bp) tet gene. In contrast, 31 independent insertions in the amp gene were found in at least 27 distinct sites.—Tn5 generates 9 bp target sequence duplications when it transposes. Such transposon-induced duplications are generally taken to indicate that cleavages of complementary target DNA strands are made 9 bp apart during transposition. DNA sequence analysis indicated that GC base pairs occupy positions 1 and 9 in the duplications at each of the five hotspots examined, suggesting a GC-cutting preference during Tn5 transposition.     

Nucleotide sequence of the ends of the conjugative shuttle transposon Tn1545

Summary The conjugative shuttle transposon Tn1545 from Streptococcus pneumoniae transposes in various gram-positive bacterial genera following self-transfer and in Escherichia coli after cloning. Analysis of the junction fragments and of the targets before insertion and after excision of the element by DNA hybridization and sequencing indicated that Tn1545 (1) is not flanked by terminal repeated sequences in either direct or opposite orientation, (2) is flanked, in an asymmetric fashion, by terminal variable base pairs, one at the left and three at the right of the element, (3) inserts in a target DNA consensus sequence, (4) does not generate duplication of the target DNA upon insertion, and (5) excises precisely.