Fis plays a role in Tn5 and IS50 transposition.

The Fis (factor for inversion stimulation) protein of Escherichia coli was found to influence the frequency of transposon Tn5 and insertion sequence IS50 transposition. Fis stimulated both Tn5 and IS50 transposition events and also inhibited IS50 transposition in Dam-bacteria. This influence was not due to regulation by Fis of the expression of the Tn5 transposition proteins. We localized, by DNase I footprinting, one Fis site overlapping the inside end of IS50 and give evidence to strongly suggest that when Fis binds to this site, IS50 transposition is inhibited. The Fis site at the inside end overlaps three Dam GATC sites, and Fis bound efficiently only to the unmethylated substrate. Using a mobility shift assay, we also identified another potential Fis site within IS50. Given the growth phase-dependent expression of Fis and its differential effect on Tn5 versus IS50 transposition in Dam-bacteria, we propose that the high levels of Fis present during exponential growth stimulate transposition events and might bias those events toward Tn5 and away from IS50 transposition.     

Integration host factor plays a role in IS50 and Tn5 transposition.

In Escherichia coli, the frequencies of IS50 and Tn5 transposition are greater in Dam- cells than in isogenic Dam+ cells. IS50 transposition is increased approximately 1,000-fold and Tn5 transposition frequencies are increased about 5- to 10-fold in the absence of Dam methylation. However, in cells that are deficient for both integration host factor (IHF) and Dam methylase, the transposition frequencies of IS50 and Tn5 approximate those found in wild-type cells. The absence of IHF alone has no effect on either IS50 or Tn5 transposition. These results suggest that IHF is required for the increased transposition frequencies of IS50 and Tn5 that are observed in Dam- cells. It is also shown that the level of expression of IS50-encoded proteins, P1 and P2, required for IS50 and Tn5 transposition and its regulation does not decrease in IHF- or in IHF- Dam- cells. This result suggests that the effects of IHF on IS50 and Tn5 transposition are not at the level of IS50 gene expression. Finally, IHF is demonstrated to significantly retard the electrophoretic mobility of a 289-base-pair segment of IS50 DNA that contains a putative IHF protein-binding site. The physiological role of this IHF binding site remains to be determined.     

Intramolecular transposition by Tn10

Transposon Tn10 promotes the formation of a circular product containing only transposon sequences. We show that these circles result from an intramolecular transposition reaction in which all of the strand cleavage and ligation events have occurred but newly created transposon/target junctions have not undergone repair. The unligated strand termini at these junctions are those expected according to a simple model in which the target DNA is cleaved by a pair of staggered nicks 9 bp apart, transposon sequences are separated from flanking donor DNA by cleavage at the terminal nucleotides on both strands (at both ends) of the element, and 3' transposon strand ends are ligated to 5' target strand ends. The stability of the unligated junctions suggests that they are protected from cellular processing by transposase and/or host proteins. We propose that the nonreplicative nature of Tn10 transposition is determined by the efficiency with which the nontransferred transposon strand is separated from flanking donor DNA and by the nature of the protein-DNA complexes present at the strand transfer junctions.     

Induction of the SOS response in Escherichia coli inhibits Tn5 and IS50 transposition.

In response to DNA damage or the inhibition of normal DNA replication in Escherichia coli, a set of some 20 unlinked operons is induced through the RecA-mediated cleavage of the LexA repressor. We examined the effect of this SOS response on the transposition of Tn5 and determined that the frequency of transposition is reduced 5- to 10-fold in cells that constitutively express SOS functions, e.g., lexA(Def) strains. Furthermore, this inhibition is independent of recA function, is fully reversed by a wild-type copy of lexA, and is not caused by an alteration in the levels of the Tn5 transposase or inhibitor proteins. We isolated insertion mutations in a lexA(Def) background that reverse this transposition defect; all of these mapped to a new locus near 23 min on the E. coli chromosome.     

Duplication of insertion element IS50 associated with Tn5 transposition in Azospirillum brasilense

The characterization of a DNA fragment with a Tn5 insertion in a regulatory nif gene of Azospirillum brasilense is reported. Restriction endonuclease mapping, Southern hybridization with a Tn5 probe, and nucleotide sequencing revealed that IS50 had duplicated in Tn5. The duplication of an IS50 element suggests the occurrence of a replicative mechanism of transposition. A strategy, based on the bacterial ability of homologous recombination that was used to precisely eliminate Tn5 along with the duplicated IS50 element, is presented.     

Intramolecular transposition of IS102

It has been postulated that deletions mediated by transposable elements are intramolecular transposition events. An implication of this hypothesis is that the deleted fragment may be recovered if it is capable of autonomous replication. We report here the characterization of the products of intramolecular transposition of the element IS102 in bireplicons. We show that when two origins (ori's) (of pSC101 and R6-5) generate the same copy numbers, two dissociated replicons are recovered as well as the inversions. On the contrary, when two ori's (of pSC101 and pBR322) have different copy numbers, intramolecular transposition results essentially in inversions. However, the very low frequency (5 X 10(-8)) at which intramolecular transpositions in the bireplicons occurs, as compared to the single replicon (10(-4)), suggests that a complete transposition reaction may not be necessary to generate deletions.     

Role of the IS50 R proteins in the promotion and control of Tn5 transposition

IS50R, the inverted repeat sequence of Tn5 which is responsible for supplying functions that promote and control Tn5 transposition, encodes two polypeptides that differ at their N terminus. Frameshift, in-frame deletion, nonsense, and missense mutations within the N terminus of protein 1 (which is not present in protein 2) were isolated and characterized. The properties of these mutations demonstrate that protein 1 is absolutely required for Tn5 transposition. None of these mutations affected the inhibitory activity of IS50, confirming that protein 2 is sufficient to mediate inhibition of Tn5 transposition. The effects on transposition of increasing the amount of protein 2 (the inhibitor) relative to protein 1 (the transposase) were also analyzed. Relatively large amounts of protein 2 were required to see a significant decrease in the transposition frequency of an element. In addition, varying the co-ordinate synthesis of the IS50 R proteins over a 30-fold range had little effect on the transposition frequency. These studies suggest that neither the wild-type synthesis rate of protein 2 relative to protein 1 nor the amount of synthesis of both IS50 R proteins is the only factor responsible for controlling the transposition frequency of a wild-type Tn5 element in Escherichia coli.     

High frequency of independent IS50 transposition during Tn5 mutagenesis of Bordetella pertussis virulence-associated genes

Transposon Tn5-generated mutants of Bordetella pertussis were selected on the basis of their inability to bind the dye Congo red (Crb-). No mutants which were solely Crb- were found. Ten mutants were phenotypically equivalent to previously described strains with mutations in the virulence regulatory (bvg) locus and failed to express a range of virulence-associated factors. Two of these mutants were shown to have Tn5 insertions within the bvg locus, while another two mutants showed deletions in this regulatory region. Complementation studies indicated that the other six mutants had spontaneous mutations in the bvg locus, but with Tn5 inserted elsewhere in the chromosome. Several of the mutants, besides having a single Tn5 insertion, also showed additional IS50 insertions, indicating that the IS50 element contained within Tn5 had transposed independently. Such additional insertion events, which themselves would have the potential to cause mutation, could complicate the interpretation of mutant phenotypes which could thus arise from the insertional inactivation of more than one gene.     

Orientation of IS50 transposase gene and IS50 transposition.

Reversal of transposase gene orientation with respect to the nonidentical ends of IS50 strongly decreased IS50 transposition in both Dam- and Dam+ hosts. In either orientation, IS50 transposase expression was unaffected. These effects were independent of the surrounding DNA context. This shows that the efficiency of IS50 transposition is dependent on transposase gene orientation. The transposition frequencies of transposons utilizing inverted IS50 inside ends (IE), IE-IE transposons, were lower than either outside end (OE)-IE or OE-OE transposons.     

Comparative sequence analysis of IS50/Tn5 transposase

Comparative sequence analysis of IS50 transposase-related protein sequences in conjunction with known structural, biochemical, and genetic data was used to determine domains and residues that play key roles in IS50 transposase function. BLAST and ClustalW analyses have been used to find and analyze six complete protein sequences that are related to the IS50 transposase. The protein sequence identity of these six homologs ranged from 25 to 55% in comparison to the IS50 transposase. Homologous motifs were found associated with each of the three catalytic residues. Residues that play roles in transposase-DNA binding, protein autoregulation, and DNA hairpin formation were also found to be conserved in addition to other residues of unknown function. On the other hand, some homologous sequences did not appear to be competent to encode the inhibitor regulatory protein. The results were also used to compare the IS50 transposase with the more distantly related transposase encoded by IS10.     

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.     

Kinetics of Tn5 transposition

The kinetics of Tn5 transposition and gene expression were studied. For about 2 h after infection with lambda Tn5, Tn5 transpositions accumulate, reaching a level of about 1.5% of the infected cells. After 2 h transposition is essentially turned off. In cells carrying a resident Tn5, transposition is undetectable after infection. The synthesis of the Tn5-specific proteins p58 and p54 and the kanamycin-resistance protein were studied in pre-irradiated cells infected with lambda Tn5. The synthesis of p58 and p54 peaked early after infection and was significantly reduced, relative to pneo, by 2 h after infection. Moreover, p54 appeared to reach a maximum later than p58. These kinetic data put new constraints on models for the regulation of Tn5 transposition.     

Use of a Tn5 derivative that creates lacZ translational fusions to obtain a transposition mutant

We constructed a derivative of Tn5, Tn5 ORFlac, that is capable of creating lacZ translational fusions upon transposition. Lac- strains carrying this construct formed red papillae when plated on MacConkey-lactose media. Lac+ cells isolated from independent papillae expressed distinct beta-galactosidase fusion proteins, suggesting that the Lac+ phenotype resulted from transposition. In support of this, analysis of plasmids carrying Tn5 ORFlac prepared from these cells indicated that the Lac+ phenotypes arose as a result of intermolecular rearrangements. Furthermore, a derivative of Tn5 ORFlac that contains an ochre mutation in the transposase gene formed papillae only in a supB strain. Tn5 ORFlac is useful for obtaining mutants that affect Tn5 transposition and for creating lacZ fusions. We used the papillation phenotype to isolate a spontaneous revertant of IS50L that promotes transposition at a 3.6-fold higher rate than IS50R. The mutation altered the amino acid sequence of both transposase and inhibitor.     

Hairpin formation in Tn5 transposition

The initial chemical steps in Tn5 transposition result in blunt end cleavage of the transposon from the donor DNA. We demonstrate that this cleavage occurs via a hairpin intermediate. The first step is a 3' hydrolytic nick by transposase. The free 3'OH then attacks the phosphodiester bond on the opposite strand, forming a hairpin at the transposon end. In addition to forming precise hairpins, Tn5 transposase can form imprecise hairpins. This is the first example of imprecise hairpin formation on transposon end DNA. To undergo strand transfer, the hairpin must to be resolved by a transposase-catalyzed hydrolytic cleavage. We show that both precise and imprecise hairpins are opened by transposase. A transposition mechanism utilizing a hairpin intermediate allows a single transposase active site to cleave both 3' and 5' strands without massive protein/DNA rearrangements.     

Macroevolution by transposition: drastic modification of DNA recognition by a type I restriction enzyme following Tn5 transposition.

We have characterized a novel mutant of EcoDXXI, a type IC DNA restriction and modification (R-M) system, in which the specificity has been altered due to a Tn5 insertion into the middle of hsdS, the gene which encodes the polypeptide that confers DNA sequence specificity to both the restriction and the modification reactions. Like other type I enzymes, the wild type EcoDXXI recognizes a sequence composed of two asymmetrical half sites separated by a spacer region: TCA(N7)RTTC. Purification of the EcoDXXI mutant methylase and subsequent in vitro DNA methylation assays identified the mutant recognition sequence as an interrupted palindrome, TCA(N8)TGA, in which the 5' half site of the wild type site is repeated in inverse orientation. The additional base pair in the non-specific spacer of the mutant recognition sequence maintains the proper spacing between the two methylatable adenine groups. Sequencing of both the wild type and mutant EcoDXXI hsdS genes showed that the Tn5 insertion occurred at nucleotide 673 of the 1221 bp gene. This effectively deletes the entire carboxyl-terminal DNA binding domain which recognizes the 3' half of the EcoDXXI binding site. The truncated hsdS gene still encodes both the amino-terminal DNA binding domain and the conserved repeated sequence that defines the length of the recognition site spacer region. We propose that the EcoDXXI mutant methylase utilizes two truncated hsdS subunits to recognize its binding site. The implications of this finding in terms of subunit interactions and the malleability of the type I R-M systems will be discussed.     

Transposition of IS1-lambdaBIO-IS1 from a bacteriophage lambda derivative carrying the IS1-cat-IS1 transposon (Tn9)

Summary Tn9 is a transposable element in which a gene (cat) determining chloramphenicol resistance is flanked by directly repeated sequences that are homologous to the insertion sequence IS1. We show here that infection of Escherichia coli K12 (under Rec^- Red^- Int^- conditions) with a bio transducing phage carrying Tn9 results in the formation of bio transductants as frequently as cat transductants (about 1 per 10⁶ to 10⁷ infected cells). Most of the bio transductants do not carry cat, just as most of the cat transductants do not carry bio. In spite of the absence of cat, the bio prophage can transpose a second time, from the E. coli chromosome to different sites on an F gal plasmid. Analysis of the structure of the transposed bio element, by restriction nuclease digestion and by electron microscopy, demonstrates that the integrated bio prophage is flanked by directly repeated IS1 elements. We conclude that there is no genetic information for the ability to transpose encoded in the non-repeated portion of Tn9, i.e. that the directly repeated IS1 elements alone are responsible for Tn9 transposition.     

Sequences essential for IS50 transposition. The first base-pair

Sequences near the ends of the insertion element IS50 are essential for its transposition, probably because they serve as sites upon which the IS50-encoded transposase protein acts. To determine if these essential sequences include the first base-pair at each end of IS50 we generated 5'C to 5'G transversions at these positions. Each mutation reduced the transposition frequency to 1% to 2% of wild-type. DNA sequence analyses showed that the mutant 5'G is preserved during transposition.