Conjugative Interaction Induces Transposition of ISPst9 in Pseudomonas stutzeri AN10

ISPst9 is an ISL3-like insertion sequence (IS) that was recently described in the naphthalene-degrading organism Pseudomonas stutzeri strain AN10. In this paper we describe a novel strong IS regulation stimulus; transposition of ISPst9 is induced in all P. stutzeri AN10 cells after conjugative interaction with Escherichia coli. Thus, we observed that in all P. stutzeri AN10 cells that received genetic material by conjugation the ISPst9 genomic dose and/or distribution was changed. Furthermore, ISPst9 transposition was also observed when P. stutzeri AN10 cells were put in contact with the plasmidless conjugative strain E. coli S17-1λ_pir, but not when they were put in contact with E. coli DH5α (a nonconjugative strain). The mechanism of ISPst9 transposition was analyzed, and transposition was shown to proceed by excision from the donor DNA using a conservative mechanism, which generated 3- to 10-bp deletions of the flanking DNA. Our results indicate that ISPst9 transposes, forming double-stranded DNA circular intermediates consisting of the IS and a 5-bp intervening DNA sequence probably derived from the ISPst9 flanking regions. The kinetics of IS circle formation are also described.     

Characterization of IS1474, an insertion sequence of the IS21 family isolated from Pseudomonas alcaligenes NCIB 9867

A new insertion sequence (IS) designated IS1474 was isolated from Pseudomonas alcaligenes NCIB 9867 (P25X). IS1474 is a 2632 bp element which showed a characteristic IS structure with 12 bp inverted repeats (IRs) flanking a 2608 bp central region. IS1474 contained four open reading frames (ORF1–ORF4), two in each orientation. Similarities were detected between ORF1 and ORF2 and the putative transposases of the IS21 family. Sequences upstream from IS1474 were found to display up to 89% homology with IS53 from Pseudomonas syringae suggesting that IS1474 had inserted into another related IS element designated IS1475. An open reading frame, ORF5, located at the junction of IS1474 and IS1475, showed similarities with the IstB protein of IS21 and could possibly be the transposase subunit of IS1475. Transposition assays showed that IS1474 transposed at a relatively low frequency leading to cointegration with target plasmids. Hybridization studies showed that IS1474 is present in at least 13 copies in the chromosome of P25X and one copy on its endogenous plasmid.     

Activation and Inactivation of Pseudomonas stutzeri Methylbenzene Catabolism Pathways Mediated by a Transposable Element

The arrangement of the genes involved in o-xylene, m-xylene, and p-xylene catabolism was investigated in three Pseudomonas stutzeri strains: the wild-type strain OX1, which is able to grow on o-xylene but not on the meta and para isomers; the mutant M1, which grows on m-xylene and p-xylene but is unable to utilize the ortho isomer; and the revertant R1, which can utilize all the three isomers of xylene. A 3-kb insertion sequence (IS) termed ISPs1, which inactivates the m-xylene and p-xylene catabolic pathway in P. stutzeri OX1 and the o-xylene catabolic genes in P. stutzeri M1, was detected. No IS was detected in the corresponding catabolic regions of the P. stutzeri R1 genome. ISPs1 is present in several copies in the genomes of the three strains. It is flanked by 24-bp imperfect inverted repeats, causes the direct duplication of 8 bp in the target DNA, and seems to be related to the ISL3 family.     

Three insertion sequences from the cyanobacterium Synechocystis PCC6803 support the occurrence of horizontal DNA transfer among bacteria

Three insertion sequences were characterized from the widely-used cyanobacterium Synechocystis PCC6803. They all harbored a putative transposase sequence flanked by two imperfect inverted repeats, seemed to have duplicated their target insertion site and occurred as multiple copies in the host genome. They exhibited no obvious homology with any other cyanobacterial ISs and were termed IS5S (871 bp), IS4S (1299 bp) and ISS1987 (949 bp) because they were, respectively, homologous to IS5- and IS4-bacterial elements, and to several members of the IS630-Tc1-mariner superfamily of IS elements occurring in a wide range of hosts. This suggests that these IS-elements were spread through horizontal transfer between evolutionary distant organisms. Three IS5S-copies were isolated as a rescue insertion into a replicating plasmid (IS5Sa), or subsequently cloned from a Synechocystis DNA-library probed with IS5Sa (IS5Sb and IS5Sc), and appeared to be almost identical. In the vicinity of IS5Sb, we found the ISS1987 element inserted into the IS4S element. This indicates that the ISS1987 element has been, and could still be, mobile since its transposase sequence is not interrupted with stop codons or translational frameshifts, unlike that which is found in most members of the IS630-Tc1-mariner superfamily of transposable elements.     

Characterization of Insertions of IS476 and Two Newly Identified Insertion Sequences, IS1478 and IS1479, in Xanthomonas campestris pv. campestris

Thirty-two plasmid insertion mutants were independently isolated from two strains of Xanthomonas campestris pv. campestris in Taiwan. Of the 32 mutants, 14 (44%), 8 (25%), and 4 (12%) mutants resulted from separate insertions of an IS3 family member, IS476, and two new insertion sequences (IS), IS1478 and IS1479. While IS1478 does not have significant sequence homology with any IS elements in the EMBL/GenBank/DDBJ database, IS1479 demonstrated 73% sequence homology with IS1051 in X. campestris pv. dieffenbachiae, 62% homology with IS52 in Pseudomonas syringae pv. glycinea, and 60% homology with IS5 in Escherichia coli. Based on the predicted transposase sequences as well as the terminal nucleotide sequences, IS1478 by itself constitutes a new subfamily of the widespread IS5 family, whereas IS1479, along with IS1051, IS52, and IS5, belongs to the IS5 subfamily of the IS5 family. All but one of the IS476 insertions had duplications of 4 bp at the target sites without sequence preference and were randomly distributed. An IS476 insertion carried a duplication of 952 bp at the target site. A model for generating these long direct repeats is proposed. Insertions of IS1478 and IS1479, on the other hand, were not random, and IS1478 and IS1479 each showed conservation of PyPuNTTA and PyTAPu sequences (Py is a pyrimidine, Pu is a purine, and N is any nucleotide) for duplications at the target sites. The results of Southern blot hybridization analysis indicated that multiple copies of IS476, IS1478, and IS1479 are present in the genomes of all seven X. campestris pv. campestris strains tested and several X. campestris pathovars.     

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.     

Detection of a novel active transposable element in Caldicellulosiruptor hydrothermalis and a new search for elements in this genus

We show that a previously annotated hypothetical protein is the transposase of a new and active IS element, ISCahy1, widespread in Caldicellulosiruptor species. Transposition generated an 11-bp direct repeat at the insertion site in Caldicellulosiruptor hydrothermalis, suggesting a cut-and-paste mechanism. The discovery of an active insertion sequence in Caldicellulosiruptor species led to a survey of potential IS elements in the genome sequences of eight Caldicellulosiruptor species that identified several new elements, including one novel to this genus.     

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.     

Bias between the left and right inverted repeats during IS911 targeted insertion

IS911 is a bacterial insertion sequence composed of two consecutive overlapping open reading frames (ORFs [orfA and orfB]) encoding the transposase (OrfAB) as well as a regulatory protein (OrfA). These ORFs are bordered by terminal left and right inverted repeats (IRL and IRR, respectively) with several differences in nucleotide sequence. IS911 transposition is asymmetric: each end is cleaved on one strand to generate a free 3′-OH, which is then used as the nucleophile in attacking the opposite insertion sequence (IS) end to generate a free IS circle. This will be inserted into a new target site. We show here that the ends exhibit functional differences which, in vivo, may favor the use of one compared to the other during transposition. Electromobility shift assays showed that a truncated form of the transposase [OrfAB(1-149)] exhibits higher affinity for IRR than for IRL. While there was no detectable difference in IR activities during the early steps of transposition, IRR was more efficient during the final insertion steps. We show here that the differential activities between the two IRs correlate with the different affinities of OrfAB(1-149) for the IRs during assembly of the nucleoprotein complexes leading to transposition. We conclude that the two inverted repeats are not equivalent during IS911 transposition and that this asymmetry may intervene to determine the ordered assembly of the different protein-DNA complexes involved in the reaction.     

The IS4 family of insertion sequences: evidence for a conserved transposase motif

The eight IS 231 variants characterized so far (IS 231 A-F, V and W) display similar transposases with an overall 40% identity. Comparison with all the proka-ryotic transposable elements sequenced so far revealed that the IS231 transposases share two conserved regions with those of 35 other insertion sequences of wide origins. These insertion sequences, defining the IS4 family, have a common bipartite organization of their ends and are divided into two similarity groups. Interestingly, the transposase domains conserved within this family display similarities with the well known integrase domain shared by transposases of the IS3 and IS15 families, and integrases of retroelements. This domain is also found in IS30- related elements and Tn7 TnsB protein. Amino acid residues conserved throughout all these prokaryotic and eukaryotic mobile genetic elements define a major transposase/integrase motif, likely to play an important role in the transposition process.     

High-Temperature-Induced Transposition of Insertion Elements in Burkholderia multivorans ATCC 17616

An efficient and quantitative method to analyze the transposition of various insertion sequence (IS) elements in Burkholderia multivorans ATCC 17616 was devised. pGEN500, a plasmid carrying a Bacillus subtilis-derived sacB gene, was introduced into ATCC 17616 cells, and 25% of their sucrose-resistant derivatives were found to carry various IS elements on pGEN500. A PCR-based experimental protocol, in which a mixture of several specific primer pairs was used, revealed that pGEN500 captured, in addition to five previously reported IS elements (IS401, IS402, IS406, IS407, and IS408), three novel IS elements, ISBmu1, ISBmu2, and ISBmu3. The global transposition frequency of these IS elements was enhanced more than sevenfold under a high-temperature condition (42°C) but not under oxidative stress or starvation conditions. To our knowledge, this is the first report demonstrating the elevated transposition activities of several IS elements at a high temperature. The efficient experimental protocol developed in this study will be useful in quantitatively and simultaneously investigating various IS elements, as well as in capturing novel functional mobile elements from a wide variety of bacteria.     

Putative Transposases Conserved in Exiguobacterium Isolates from Ancient Siberian Permafrost and from Contemporary Surface Habitats

Gram-positive bacteria of the genus Exiguobacterium have been repeatedly isolated from Siberian permafrost ranging in age from 20,000 to 2 to 3 million years and have been sporadically recovered from markedly diverse habitats, including microbial mats in Lake Fryxell (Antarctic), surface water, and food-processing environments. However, there is currently no information on genomic diversity of this microorganism or on the physiological strategies that have allowed its survival under prolonged freezing in the permafrost. Analysis of the genome sequence of the most ancient available Exiguobacterium isolate (Exiguobacterium sp. strain 255-15, from 2 to 3 million-year-old Siberian permafrost) revealed numerous putative transposase sequences, primarily of the IS200/IS605, IS30, and IS3 families, with four transposase families identified. Several of the transposase genes appeared to be part of insertion sequences. Southern blots with different transposase probes yielded high-resolution genomic fingerprints which differentiated the different permafrost isolates from each other and from the Exiguobacterium spp. type strains which have been derived from diverse surface habitats. Each of the Exiguobacterium sp. strain 255-15 transposases that were used as probes had highly conserved homologs in the genome of other Exiguobacterium strains, both from permafrost and from modern sites. These findings suggest that, prior to their entrapment in permafrost, Exiguobacterium isolates had acquired transposases and that conserved transposases are present in Exiguobacterium spp., which now can be isolated from various modern surface habitats.     

Characterization of the Transposase Encoded by IS256, the Prototype of a Major Family of Bacterial Insertion Sequence Elements

IS256 is the founding member of the IS256 family of insertion sequence (IS) elements. These elements encode a poorly characterized transposase, which features a conserved DDE catalytic motif and produces circular IS intermediates. Here, we characterized the IS256 transposase as a DNA-binding protein and obtained insight into the subdomain organization and functional properties of this prototype enzyme of IS256 family transposases. Recombinant forms of the transposase were shown to bind specifically to inverted repeats present in the IS256 noncoding regions. A DNA-binding domain was identified in the N-terminal part of the transposase, and a mutagenesis study targeting conserved amino acid residues in this region revealed a putative helix-turn-helix structure as a key element involved in DNA binding. Furthermore, we obtained evidence to suggest that the terminal nucleotides of IS256 are critically involved in IS circularization. Although small deletions at both ends reduced the formation of IS circles, changes at the left-hand IS256 terminus proved to be significantly more detrimental to circle production. Taken together, the data lead us to suggest that the IS256 transposase-mediated circularization reaction preferentially starts with a sequence-specific first-strand cleavage at the left-hand IS terminus.IS256 is an insertion sequence widespread in the genomes of multiresistant enterococci and staphylococci (3). The element, which is 1,324 bp in size, consists of a single open reading frame encoding a transposase protein flanked by noncoding regions (NCRs) harboring imperfect inverted repeats (IRs) (see Fig. ​Fig.1A).1A). IS256 occurs in multiple free copies in its host genomes but is also known to form the ends of composite transposon Tn4001 conferring aminoglycoside resistance (29). In Staphylococcus epidermidis, IS256 has been identified as a typical marker of hospital-acquired multiresistant and biofilm-forming clones causing opportunistic infections in immunocompromised patients (11, 20-22, 26, 34). The element has been shown to trigger heterogeneous biofilm expression by reversible transposition into biofilm-associated genes and regulators (4, 5, 19, 49, 56). Also, IS256 has the capacity to influence antibiotic resistance, either by insertion into regulatory genes or by modulating antibiotic resistance gene expression through formation of strong hybrid promoters resulting from transposition into the neighborhood of antibiotic resistance genes (6, 18, 31, 32). Finally, multiple genomic IS256 copies may serve as crossover points for homologous recombination events and thereby play an important role in genome flexibility, adaptation, and evolution of staphylococcal and enterococcal genomes (29, 42, 55).Open in a separate windowFIG. 1.IS256 transposase binding to IS termini. (A) Genetic organization of IS256. The transposase gene (tnp) is flanked by NCRs that harbor imperfect IRs (IR_L and IR_R) at the ends of the element. The nucleotide sequence of the IRs is indicated by uppercase boldface letters, with nucleotide numbering referring to GenBank accession no. {"type":"entrez-nucleotide","attrs":{"text":"M18086","term_id":"152946","term_text":"M18086"}}M18086. Insertion of IS256 into the S. epidermidis icaC gene on plasmid pIL2 (27) is shown, and black boxes mark the 8-bp target site duplications (TSDs) generated upon transposition of the element. Black bars at the top indicate localizations of DNA fragments used in the EMSAs presented in panels B to D. (B to D) EMSAs of purified IS256 transposase protein (CBP-Tnp) with various IS256-specific DNA fragments. A 15.5 nM concentration of an IS terminus (left)-carrying DNA fragment (B) or an IS terminus (right)-carrying DNA-fragment (C), as well as an interal IS256 fragment (D), were used with increasing amounts of protein. All experiments were performed in the presence of unspecific competitor [50 μg of poly(dI-dC) ml⁻¹]. Molar ratios between DNA and protein comprised a range of 1:3 (50 nM CBP-Tnp) to 1:52 (800 nM CBP-Tnp).Given its important biological role, it is surprising that very little is known about the molecular function of IS256 and its lifestyle. Empirical analyses of IS256 insertion sites in various bacterial genomes and loci did not reveal nucleotide sequence specificity for target site selection (3, 29, 56). Typically, IS256 generates 8- or 9-bp target site duplications (TSDs) upon transposition that are caused by staggered nicks of the target DNA and refill of the resulting gaps by the host repair system (43). In the course of phase variation events, IS256 TSDs can be completely removed, with the original host sequence being restored (56). Such precise IS256 excisions are caused by an illegitimate recombination event that requires fully intact TSDs but no functional IS256 transposase (14). IS256 transposition itself was found to involve the formation of double-stranded circular IS256 molecules in which the insertion sequence (IS) ends abut, bridged by a few base pairs of host DNA originating from the original insertion site (27, 39). IS256 circle formation is a strictly transposase-dependent process and IS circles are regarded as transposition intermediates which are likely to be relinearized during transposition. However, details of the transposition reaction, including circle formation, putative relinearization, target site selection, and insertion of the element are far from being understood at the molecular level. We experimentally addressed here, for the first time for a bacterial transposase of the IS256 family, the DNA-binding properties of this protein. We identified a DNA-binding domain in the N-terminal region of the protein. The domain contains a putative classical helix-turn-helix (HTH) motif that is demonstrated to be involved in sequence-specific interactions of the IS256 transposase with the IRs present in the NCRs of the element. Moreover, we suggest a role for the terminal nucleotides of the IS256 nucleotide sequence in first-strand cleavage and subsequent circularization of the element.     

ISPst9, an ISL3-like insertion sequence from Pseudomonas stutzeri AN10 involved in catabolic gene inactivation

A novel insertion sequence (IS), ISPst9, from Pseudomonas stutzeri AN10 was cloned and characterized. ISPst9 is a typical bacterial IS, consisting of a 2472-bp element flanked by 24-bp perfect inverted repeats that generates 8-bp AT-rich target duplications upon insertion. The sequence also contains a gene that encodes an active transposase (TnpA) with significant amino acid identity to members of the ISL3 family. Southern blot analysis of digested genomic DNA of strain AN10 and its 4-chlorosalicylate-degrading derivative strain AN142 demonstrated that native ISPst9 transposes in multiple copies, with one of them responsible for the nahH insertional inactivation observed in strain AN142. Precise excision of ISPst9 yielded NahH+ revertants of AN142 at high frequencies (up to 10-6). In vivo transposition, mainly in multiple copies, of an ISPst9 derivative containing a KmR cassette cloned into a suicide vector was also demonstrated. Hybridization experiments carried out with different strains of P. stutzeri and with 292 phylogenetically distinct environmental isolates suggested that the presence of an ISPst9-like IS occurs in diverse bacteria together with the presence of aromatic hydrocarbon-degrading determinants.     

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.     

IS1631 Occurrence in Bradyrhizobium japonicum Highly Reiterated Sequence-Possessing Strains with High Copy Numbers of Repeated Sequences RSα and RSβ

From Bradyrhizobium japonicum highly reiterated sequence-possessing (HRS) strains indigenous to Niigata and Tokachi in Japan with high copy numbers of the repeated sequences RSα and RSβ (K. Minamisawa, T. Isawa, Y. Nakatsuka, and N. Ichikawa, Appl. Environ. Microbiol. 64:1845–1851, 1998), several insertion sequence (IS)-like elements were isolated by using the formation of DNA duplexes by denaturation and renaturation of total DNA, followed by treatment with S1 nuclease. Most of these sequences showed structural features of bacterial IS elements, terminal inverted repeats, and homology with known IS elements and transposase genes. HRS and non-HRS strains of B. japonicum differed markedly in the profiles obtained after hybridization with all the elements tested. In particular, HRS strains of B. japonicum contained many copies of IS1631, whereas non-HRS strains completely lacked this element. This association remained true even when many field isolates of B. japonicum were examined. Consequently, IS1631 occurrence was well correlated with B. japonicum HRS strains possessing high copy numbers of the repeated sequence RSα or RSβ. DNA sequence analysis indicated that IS1631 is 2,712 bp long. In addition, IS1631 belongs to the IS21 family, as evidenced by its two open reading frames, which encode putative proteins homologous to IstA and IstB of IS21, and its terminal inverted repeat sequences with multiple short repeats.     

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.     

Target Choice and Orientation Preference of the Insertion Sequence IS903

We have examined the targeting preference of the bacterial insertion element IS903 by determining the sites of insertion of a large number of transposition events into the 55-kb conjugative plasmid pOX38. Despite the large target size, all the insertions were clustered in four small distinct regions associated with conjugal DNA transfer. Within these regions, many different sites were used for insertion; however, there were a few sites that IS903 inserted into more than once. Alignment of the insertion sites showed that there was no consensus sequence within the 9-bp target duplication but that there were preferred sequences located symmetrically on either side of the target. This is consistent with target recognition by a dimer or multimer of transposase, with either sequence-specific or structure-specific interactions on both sides of the target. We show further that when one of these preferred regions was cloned into a second conjugative plasmid, pUB307, it was still a preferred target, implying that all the sequences necessary for target selection are contained within this DNA segment. Also, we observed a very strong preference for insertion in a single orientation in pUB307. We examined the possibility that either DNA replication from the origin of vegetative replication, oriV, or the origin of transfer, oriT, might determine this orientation effect. We find that reversing the direction of vegetative replication had no effect on the orientation of transposon insertions; however, reversing the direction of DNA transfer abolished the orientation effect. This supports the idea that conjugal DNA transfer imparts a polarity on the target that is sensed by the transposon.