Mobility and Generation of Mosaic Non-Autonomous Transposons by Tn3-Derived Inverted-Repeat Miniature Elements (TIMEs)

Functional transposable elements (TEs) of several Pseudomonas spp. strains isolated from black shale ore of Lubin mine and from post-flotation tailings of Zelazny Most in Poland, were identified using a positive selection trap plasmid strategy. This approach led to the capture and characterization of (i) 13 insertion sequences from 5 IS families (IS3, IS5, ISL3, IS30 and IS1380), (ii) isoforms of two Tn3-family transposons – Tn5563a and Tn4662a (the latter contains a toxin-antitoxin system), as well as (iii) non-autonomous TEs of diverse structure, ranging in size from 262 to 3892 bp. The non-autonomous elements transposed into AT-rich DNA regions and generated 5- or 6-bp sequence duplications at the target site of transposition. Although these TEs lack a transposase gene, they contain homologous 38-bp-long terminal inverted repeat sequences (IRs), highly conserved in Tn5563a and many other Tn3-family transposons. The simplest elements of this type, designated TIMEs (Tn3 family-derived Inverted-repeat Miniature Elements) (262 bp), were identified within two natural plasmids (pZM1P1 and pLM8P2) of Pseudomonas spp. It was demonstrated that TIMEs are able to mobilize segments of plasmid DNA for transposition, which results in the generation of more complex non-autonomous elements, resembling IS-driven composite transposons in structure. Such transposon-like elements may contain different functional genetic modules in their core regions, including plasmid replication systems. Another non-autonomous element “captured” with a trap plasmid was a TIME derivative containing a predicted resolvase gene and a res site typical for many Tn3-family transposons. The identification of a portable site-specific recombination system is another intriguing example confirming the important role of non-autonomous TEs of the TIME family in shuffling genetic information in bacterial genomes. Transposition of such mosaic elements may have a significant impact on diversity and evolution, not only of transposons and plasmids, but also of other types of mobile genetic elements.     

Formation of the tandem repeat (IS30)2 and its role in IS30-mediated transpositional DNA rearrangements

Plasmids carrying two IS30 elements in the same orientation, as in the composite transposon Tn2706, are structurally unstable in Escherichia coli. A primary segregation product is formed by site-specific deletion of the sequences carried between the two IS30 elements. The resulting covalently closed replicon carries the two IS30 elements as tandem repeats separated by only 2 bp. This (IS30)₂ structure is extremely unstable, but it can nevertheless be isolated on its vector plasmid and, after purification, can be reintroduced into host cells by transformation. Among the descendants of transformants of recA ^? bacteria, replicated copies of the introduced (IS30)₂ structure are still present, together with various kinds of segregation products which provide evidence for the efficient generation of DNA rearrangements. Most abundant is the product of another site-specific recombination between two identical ends of the IS30 elements involved, which results in the presence of just one intact IS30 on the plasmid. Apart from this, and depending on the presence of appropriate targets for IS30 transposition, various transposition products of (IS30)₂ are also seen. Intramolecular reactions lead to DNA inversions and deletions with breakpoints other than IS30 ends. In intermolecular reactions inverse transposition occurs at high frequency and one also obtains simple transposition and cointegration. A mutational study revealed the requirement in cis of one intact IS30 transposase gene and of both proximal ends of the two IS30 elements concerned not only for the formation of (IS30)₂, but also for its further rearrangement reactions, including the efficient formation of site-specific deletions. A model is proposed, which postulates that (IS30)₂ intermediates play a key role in IS30 transposition pathways in which the formation of (IS30)₂ may be rate-limiting. Once this structure is formed, it gives rise to a burst of transpositional rearrangements in the subclone carrying (IS30)₂. Evolutionary implications of these findings are discussed.     

Mobilization of vancomycin resistance by transposon-mediated fusion of a VanA plasmid with an Enterococcus faecium sex pheromone-response plasmid

A striking feature of recent outbreaks of vancomycin-resistant (Vm^R) enterococci is the apparent horizontal dissemination of resistance determinants. The plasmids pHKK702 and pHKK703 from Enterococcus faecium clinical isolate R7 have been implicated in the conjugal transfer of Vm^R. pHKK702 is a 41-kb plasmid that contains an element indistinguishable from the glycopeptide-resistance transposon Tn1546. pHKK703 is an approx. 55-kb putative sex pheromone-response plasmid that is required for conjugative mobilization of pHKK702. During experiments in which strain R7 was used as a donor, a highly conjugative Vm^R transconjugant was isolated that formed constitutive cellular aggregates. Restriction analyses and DNA hybridizations revealed that the transconjugant harbored a single plasmid of approx. 92 kb and this plasmid (pHKK701) was composed of DNA from both pHKK702 and pHKK703. Results from DNA sequence analyses showed that a 39-kb composite transposon (Tn5506) from pHKK702 had inserted into pHKK703. The left end of Tn5506 contained a single insertion sequence (IS) element, IS1216V2, whereas the right end was composed of a tandem IS structure consisting of the novel 1065-bp IS1252 nested within an IS1216V1 element. Transposition of Tn5506 from pHKK702 to pHKK703 created an 8-bp target sequence duplication at the site of insertion and interrupted an ORF (ORFX) that was 91% identical to that of prgX, a gene proposed to negatively regulate sex pheromone response of the E. faecalis plasmid, pCF10. We propose that the interruption of ORFX by Tn5506 led to the constitutive cellular aggregation phenotype and thereby enhanced the efficiency with which Vm^R was transferred. Similar IS1216V-mediated transposition events may contribute to the horizontal spread of glycopeptide resistance among enterococci in nature.     

Two Amino Acid Residues of Transposase Contributing to Differential Transposability of IS1 Elements in Escherichia coli

Escherichia coli W3110 contains four types of IS1 elements in the chromosome. Using an insertion element entrapping system, we collected 116 IS1 plasmid insertion mutants, which resulted from a minimum of 26 independent IS1 insertion events. All of them had insertions of IS1 of the IS1A (IS1E and IS1G) type. Inspection of the transposase sequences of the four IS1 types and the IS1 of the resistance plasmid R100 showed that two amino acid residues, His-193 and Leu-217 of transposase, might contribute to differential transposability of IS1 elements in W3110. The two amino acid residues of the transposase in IS1A (IS1E and IS1G) were altered separately by site-directed mutagenesis, and each mutant was found to mediate transposition at a frequency about 30-fold lower than that of IS1A (IS1E and IS1G). Thus, the assumption that His-193 and Leu-217 of transposase contribute to differential transposability of IS1 elements in W3110 was confirmed.     

A derivative of Tn5 with direct terminal repeats can transpose

The 5.7 kb⁴ transposable kanamycin resistance determinant Tn5 contains 1.5 kb terminal inverted repeats which we here call arms. Tn5's arms contain the genes and sites necessary for Tn5 transposition, and are not homologous to previously described transposable elements. To determine whether one or both arms is a transposable (IS) element, we transposed Tn5 to pBR322 and used restriction endonuclease digestion and ligation in vitro to generate plasmid derivatives designated pTn5-DR1 and pTn5-DR2 in which Tn5's arms were present in direct rather than in inverted orientation. Analysis of transposition products from dimeric forms of the pTn5-DR1 plasmid to phage λ showed that the outside and inside termini of right and of left arms could function in transposition. We conclude that both of Tn5's arms are transposable elements and name them IS50L (left) and IS50R (right). IS50R, which encodes transposase, was used several-fold more frequently than IS50L, which contain an ochre mutant allele of transposase: this implies that Tn5's transposase acts preferentially on the DNA segment which encodes it. Analysis of transpositions of the amp^rkan^r element Tn5-DR2 to the lac operon showed that Tn5-DR2, like Tn5 wild-type, exhibits regional preference without strict site specificity in the choice of insertion sites.     

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.     

Isolation of Auxotrophic Mutants of Methylophilus methylotrophus by Modified-Marker Exchange

A method for stabilizing a transposon (Tn5) has been developed which allows the isolation of stable auxotrophic mutants of Methylophilus methylotrophus ASI. Insertion of Tn5 into a cloned M. methylotrophus ASI DNA fragment encoding anthranilate synthase followed by transfer of the vector with the modified trpE gene to M. methylotrophus ASI resulted in unstable auxotrophs among the recombinants. Deletion of IS50R, which encodes transposase production from Tn5, stabilized the transposon after mobilization to M. methylotrophus ASI. When trpE genes with the modified Tn5 inserts were mobilized into M. methylotrophus ASI, stable, kanamycin-resistant tryptophan auxotrophs were obtained by double-crossover homologous recombination with the chromosome.     

Evidence that Tn5565, which includes the enterotoxin gene in Clostridium perfringens, can have a circular form which may be a transposition intermediate

The Clostridium perfringens enterotoxin gene is on a transposon-like element, Tn5565, integrated in the chromosome in human food poisoning strains. The flanking IS elements, IS1470 A and B, are related to IS30. The IS element found in the transposon, IS1469, is related to IS200 and has been found upstream of cpe in all Type A strains. PCR and sequencing studies from cell extracts and plasmid isolations of C. perfringens indicate that Tn5565 can form a circular form with the tandem repeat (IS1470)₂, similar to the transposition intermediates described for a number of IS elements.     

IS1-encoded proteins,InsA and the InsA-B′-InsB transframe protein (transposase): Functions deduced from their DNA-binding ability

Insertion sequence IS1 encodes a transframe protein, InsA-B′-InsB, which is produced from two out-of-phase reading frames, insA and B′-insB, by translational frameshifting at a run of adenines. Unless the frameshifting event occurs, the InsA protein is produced from IS1. We found that cells harboring a plasmid carrying an IS1 mutant with a single adenine insertion in the run of adenines contained miniplasmids. Cloning and DNA sequencing analyses of the miniplasmids revealed that they had a deletion extending from an inverted repeat (IR) at the left end of IS1. This indicates that they were generated by IS1-mediated deletion due to efficient production of the InsA-B′-InsB transframe protein that is IS1 transposase. Both the InsA protein and transposase were partially purified as a fusion protein with collagen-LacZ by LacZ-specific affinity column chromatography. The InsA¹ and the collagenolyzed InsA¹ were found to bind specifically to a 24-bp region within each of the IRs at the ends of IS1. The transposase Tnp¹ and the collagenolyzed Tnp¹ were found to bind to the sequence with or without IR, but preferentially to that with IR. The nonspecific DNA-binding ability of transposase may be involved in recognition of the target DNA, an important process of transposition of IS1. Both InsA and transposase have the IR-specific DNA binding ability and a common polypeptide segment containing the α-helix-turn-α-helix motif, supporting the previous indication that InsA competes with transposase to bind to IRs and thus becomes a transposition inhibitor. Based on the observations described in this article, we speculate that transposase of IS1 consists of at least two domains, the N-terminal half, which almost entirely overlaps InsA, and the C-terminal half, which almost entirely overlaps B′-InsB. The frameshifting event adds the latter domain to the former to give the transposase activity recognizing IRs and the target sequence to initiate the transposition reaction.     

Isolation of an IS1 flanked kanamycin resistance transposon from R1drd19

Summary We have isolated and identified an IS1-flanked transposon from the plasmid R1drd19. This transposon specifies resistance to kanamycin and is 10.4 kb long. It exhibits a frequency of transposition two orders of magnitude lower than that of the smaller, IS1-flanked transposon Tn9. We have named it Tn2350.     

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.     

The Tn5 bleomycin resistance gene confers improved survival and growth advantage on Escherichia coli

The bleomycin resistance gene (ble) of transposon Tn5 is known to decrease the death rate of Escherichia coli during stationary phase. Bleomycin is a DNA-damaging agent and bleomycin resistance is produced by improved DNA repair which also requires the host genes aidC and polA coding, respectively, for an alkylation-inducible gene product and DNA polymerase I. In the absence of the drug, this DNA repair system is believed to cause the slower death rate of bleomycin-resistant bacteria. In this study, the effect of ble and aidC genes on the viability of bacteria and their growth rate in chemostat competitions was studied. The results indicate, that bleomycin-resistant bacteria display greater fitness under these conditions. Another beneficial effect of transposon Tn5 had been previously attributed to the insertion sequence IS50R. We were not able to reproduce this result with IS50R, however, the complete transposon was beneficial under similar conditions. Moreover, we showed the Tn5 fitness effect to be aidC-dependent. The ble gene was discovered after the fitness effect of IS50R had been established; it has not previously been considered to mediate the beneficial effect of Tn5. This possibility is discussed based on the molecular mechanism of bleomycin resistance.     

Analysis of Tn5 inversion events inEscherichia coli plasmids

The ability of the bacterial transposon Tn5 to undergo sequence inversion in Rec⁺ Escherichia coli cells as a result of recombination between its duplicated IS50 elements was examined using specially designed plasmid constructs. Surprisingly, recombination events in the IS50 elements that led to crossover and therefore Tn5 inversion could be detected at a frequency of only 10^?5. This was approximately an order of magnitude lower than the frequency of IS50 recombination that led to conversion events (i.e. non-reciprocal recombination) without crossover, and at least two orders of magnitude lower than the frequency of intermolecular recombination between IS50 elements on two different plasmids. These rare conversion and inversion events in Tn5 appeared to be due to intramolecular recombination and not simply to multiple rounds of reciprocal crossing over, since the heterodimeric intermediates that would be generated during the latter process could be readily isolated but were shown to yield a completely different set of plasmid products upon resolution.     

Formation of the tandem repeat (IS30)2 and its role in IS30-mediated transpositional DNA rearrangements

Plasmids carrying two IS30 elements in the same orientation, as in the composite transposon Tn2706, are structurally unstable in Escherichia coli. A primary segregation product is formed by site-specific deletion of the sequences carried between the two IS30 elements. The resulting covalently closed replicon carries the two IS30 elements as tandem repeats separated by only 2 bp. This (IS30)₂ structure is extremely unstable, but it can nevertheless be isolated on its vector plasmid and, after purification, can be reintroduced into host cells by transformation. Among the descendants of transformants of recA ^– bacteria, replicated copies of the introduced (IS30)₂ structure are still present, together with various kinds of segregation products which provide evidence for the efficient generation of DNA rearrangements. Most abundant is the product of another site-specific recombination between two identical ends of the IS30 elements involved, which results in the presence of just one intact IS30 on the plasmid. Apart from this, and depending on the presence of appropriate targets for IS30 transposition, various transposition products of (IS30)₂ are also seen. Intramolecular reactions lead to DNA inversions and deletions with breakpoints other than IS30 ends. In intermolecular reactions inverse transposition occurs at high frequency and one also obtains simple transposition and cointegration. A mutational study revealed the requirement in cis of one intact IS30 transposase gene and of both proximal ends of the two IS30 elements concerned not only for the formation of (IS30)₂, but also for its further rearrangement reactions, including the efficient formation of site-specific deletions. A model is proposed, which postulates that (IS30)₂ intermediates play a key role in IS30 transposition pathways in which the formation of (IS30)₂ may be rate-limiting. Once this structure is formed, it gives rise to a burst of transpositional rearrangements in the subclone carrying (IS30)₂. Evolutionary implications of these findings are discussed.     

Base Flipping in Tn10 Transposition: An Active Flip and Capture Mechanism

The bacterial Tn5 and Tn10 transposases have a single active site that cuts both strands of DNA at their respective transposon ends. This is achieved using a hairpin intermediate that requires the DNA to change conformation during the reaction. In Tn5 these changes are controlled in part by a flipped nucleoside that is stacked on a tryptophan residue in a hydrophobic pocket of the transposase. Here we have investigated the base flipping mechanism in Tn10 transposition. As in Tn5 transposition, we find that base flipping takes place after the first nick and is required for efficient hairpin formation and resolution. Experiments with an abasic substrate show that the role of base flipping in hairpin formation is to remove the base from the DNA helix. Specific interactions between the flipped base and the stacking tryptophan residue are required for hairpin resolution later in the reaction. We show that base flipping in Tn10 transposition is not a passive reaction in which a spontaneously flipped base is captured and retained by the protein. Rather, it is driven in part by a methionine probe residue that helps to force the flipped base from the base stack. Overall, it appears that base flipping in Tn10 transposition is similar to that in Tn5 transposition.     

IS<Emphasis Type="Italic">Ppy1</Emphasis>, a novel mobile element of the ancient <Emphasis Type="Italic">Psychrobacter maritimus</Emphasis> permafrost strain: Translocations in <Emphasis Type="Italic">Escherichia coli</Emphasis> K-12 cells and formation of composite transposons

It was shown that IS element ISPpy1 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. ISPpy1 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 ISPpy1-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 ISPpy1 copy, only cointegrates arise.     

Insertion specificity and trans-activation of IS801

The transposable element IS801, isolated from plasmid pMMC7105 of Pseudomonas syringae pv. phaseolicola, transposes in Escherichia coli to plasmid targets, expressing a relatively relaxed target specificity. The target sequences are tetramers with homology with the left terminus (GAAC) of the transposing unit, the alternative targets being GAAC, GGAC, CAAG, and CGAC. In the areas flanking IS801 in 13 different locations, no similarities other than the target tetramer were observed. The transposase is physically and functionally separable from the transposing unit since transposition of constructs carrying marker genes occurs with the transposase expressed in trans. The IS801 transposase shows amino acid sequence homology to the transposases of the E. coli elements IS91 and IS1294. These tranposases contain conserved amino acid motifs found in the replicases of certain plasmids that replicate as rolling circles.     

Analysis of the Complete Nucleotide Sequence of the Tetracycline-Resistance Transposon Tn10

An analysis of the complete nucleotide sequence of the composite tetracycline-resistance transposon Tn10 (9147 bp) from the Salmonella typhi conjugative plasmid R27 is presented. A comparison of the protein sequences from IS10-right and IS10-left transposases has identified four amino acid differences. These residues appear to play an important role in normal transposase function and may account for the differences in exhibited transposition activities. The tetracycline determinants encoded by this version of Tn10 share >99% identity with those of Tn10^R100, demonstrating the conservation that exists between these transposons. A previously uncharacterized 3000-bp region of Tn10 contains four putative open reading frames. One of these open reading frames shares 55% identity with the glutamate permease protein sequence from Haemophilus influenzae although it was unable to complement an Escherichia coli glutamate permease mutant, with which it shares 51% identity. The three remaining putative open reading frames are arranged as a discrete genetic unit adjacent to the glutamate permease homolog and are transcribed in the opposite direction. Two of these open reading frames are homologous with Bacillus subtilis proteins of unknown functions while the other has no homologs in the database. The presence of an aminoacyl-tRNA synthetase class II motif in one of these open reading frames in combination with the glutamate permease homolog allows us to postulate that this region of Tn10 could once have played a role in amino acid metabolism.     

Efficient transposition of IS204-derived plasmids in Streptomyces coelicolor

In order to study functional gene expression in Streptomyces coelicolor, a mini-transposon encoding the apramycin resistance gene aac(3)IV within its inverted repeat (IR) boundaries was constructed based on IS204, which was previously identified in the genome of Nocardia asteroides YP21. The mini-transposon and IS204 transposase gene were then put on a kanamycin-resistant conjugative plasmid pDZY101 that can only replicate in Escherichia coli. After mating with S. coelicolor A3(2) M145, resistant colonies arose efficiently on both apramycin and kanamycin plates. Plasmid rescue indicated that entire plasmids were inserted into the M145 genome with cleavage at an inverted repeat junction formed by the right inverted repeat (IRR) and the last 18 bp of the transposase gene, while the left inverted repeat (IRL) was untouched. Southern blot analysis of the mutants using an aac(3)IV gene probe showed that transposition of plasmid pDZY101 was genetically stable, with a single-copy insertion within the S. coelicolor M145 genome. Several mutagenesis libraries of S. coelicolor M145 were constructed using plasmid pDZY101 derivatives and the transposon insertion site was determined. The correlation between novel mutant phenotypes and previously uncharacterized genes was established and these transposon locations were widely scattered around the genome.     

DNA insertion mutagenesis in a Pseudomonas aeruginosa R plasmid.

The transposons Tn501 and Tn7 were used to obtain transfer-deficient (Tra^?) and carbenicillin-sensitive (Cb^s) mutants of the narrow-host-range R plasmid R91-5 of Pseudomonas aeruginosa. In cells that are harboring R91-5 together with an unrelated transposon-donor plasmid and that have undergone 50–75 cell divisions (established donors), both transposons induced a very high frequency (87–93%) of mutations affecting Tra and Cb^r. However, when transconjugants inheriting the transposon are immediately assayed for mutations (recent transposition events) there is a marked difference in the yield of mutants. Although both transposons generated Cb^s mutants at the same frequency (0.1%), Tn7 induced Tra^? mutants at a frequency of 59% as compared to 0.23% by Tn501. Some Tra^? mutants induced by both transposons were leaky but retransfer tests showed that this was not due to reversion. Both transposons showed considerable specificity when mutations affecting transfer-related functions such as sensitivity to donor-specific phage, inhibition of the replication of phage G101, and entry exclusion were compared. Thirty-seven percent of the Tra^? mutants induced by Tn501 were also Cb^s. These double mutants were leaky with respect to all the properties tested and selection for Cb^r revertants restored Tra⁺ simultaneously. A number of hypotheses were considered as explanations including the possibility that tra (transfer genes) and bla (the β-lactamase gene for carbenicillin resistance) are closely linked in R91-5, that tra formed a number of operons with one of them encompassing bla, and the possible creation of a new promoter in the bla gene which impeded tra expression. Both transposons generated a high frequency (81–86%) of deletions of the bla gene as judged by nonrevertibility.