Novel one-step cloning vector with a transposable element: application to the Myxococcus xanthus genome.

A new strategy was developed for rapid cloning of genes with a transposon mutation library. We constructed a transposon designated TnV that was derived from Tn5 and consists of the gene coding for neomycin phosphotransferase II as well as the replication origin of an Escherichia coli plasmid, pSC101, flanked by Tn5 inverted repeats (IS50L and IS50R). TnV can transpose to many different sites of DNA in E. coli and Myxococcus xanthus and confers kanamycin resistance (Kmr) to the cells. From the Kmr cells, one-step cloning of a gene which is mutated as a result of TnV insertion can be achieved as follows. Chromosomal DNA isolated from TnV-mutagenized cells is digested with an appropriate restriction enzyme, ligated, and transformed into E. coli cells with selection for Kmr. The plasmids isolated contain TnV in the target gene. The plasmid DNA can then be used as a probe for characterization of the gene and screening of clones from a genomic library. We used this vector to clone DNA fragments containing genes involved in the development of M. xanthus.     

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.     

Properties of transposon Tn2555 carrying the genes for sucrose utilization

Tn2555, a new transposon coding for genes of sucrose utilization was studied. Tn2555 was shown to integrate into the plasmids RP4 and R6K, phage P1CmClr100 and Escherichia coli K12 chromosome. Tn2555 frequency of transposition to RP4 and R6K DNA is (2-5) X 10(-7) in Rec+-strain, (3-6) X 10(-8) in Rec--strain. Tn2555 integration site in phage P1CmClr100 Sac+-derivative studied has been localised within the C-segment of P1 DNA. In three independent cases of Tn2555 transposition to the chromosome the transposon was found to be integrated in the region between 29 and 32 min of Escherichia coli K12 linkage map. The restriction endonuclease analysis of seven independent isolates of RP4::Tn2555 has shown the grouping of Tn2555 integration sites in the Tn1 region of RP4. Frequent rearrangements occurring within Tn2555 have been revealed by the analysis. However, an invertible DNA segment of about 6-7 kb was preserved in all transposon structures.     

Four different integrative recombination events involved in the mobilization of the gonococcal 5.2 kb beta-lactamase plasmid pSJ5.2 in Escherichia coli

We identified and characterized four different recombination mechanisms involved in the cointegrative transfer of the Neisseria gonorrhoeae beta-lactamase plasmid pSJ5.2 by the gonococcal 41 kb tet(M) and the Gram negative self-transmissible plasmids N3 and R64 drd-33 using an Escherichia colirecA-background. Mobilization of pSJ5.2 by the tet(M) plasmid occurred by cointegration through a replicative transposition of two IS1 elements inserted upstream from the beta-lactamase gene of pSJ5.2 and creating a IS1::beta-lactamase hybrid promoter. Two types of recombinational events occurred within the 1.8 kb BamH1-HindIII fragment of pSJ5.2 with the N3 and R64 plasmids. A non-homologous recombination was found at coordinates 1817 and 2849 of pSJ5.2 with sequences from R64. A non-homologous recombination combined with an IS26-mediated one-ended transposition was found at coordinates 1817 and 3010 of pSJ5.2 with N3. In both recombinational events, a deletion of over 1 kb of pSJ5.2 occurred. The fourth recombination event was detected in the 1.0 kb BamH1-HindIII fragment of pSJ5.2 by homologous recombination between DNA from the truncated Tn3 resolvase gene of pSJ5.2 and the resolvase sequences from R64 and N3.     

Transposition of Tn4551 in Bacteroides fragilis: identification and properties of a new transposon from Bacteroides spp.

Tn4551, a clindamycin resistance (Ccr) transposon from the R plasmid pBI136, was cloned onto an Escherichia coli-Bacteroides shuttle vector which could replicate normally in E. coli but was maintained unstably in Bacteroides fragilis. To aid in cloning and to ensure maintenance of Tn4551 in E. coli, a kanamycin resistance determinant (Kmr) was inserted in the transposon. The transposon-bearing shuttle vector pFD197 was transformed into B. fragilis 638, and putative insertions of Tn4551::Kmr were identified by screening for resistance to clindamycin and plasmid content. Southern hybridization analyses were used to verify integration of the transposon in the B. fragilis chromosome, and the frequency of insertion was estimated at 7.8 X 10(-5) events per generation. In 57% of the isolates tested a second integration event also occurred. This second insertion apparently involved just a single copy of the 1.2-kilobase repeat sequence which flanks the transposon. In addition, Tn4551::Kmr appeared to function as a transposon in E. coli. Evidence for this was obtained by the isolation of transposon insertions into the bacteriophage P1 genome. Finally, the transposon vector, pFD197, could be mobilized to other B. fragilis strains in which transposition was detected. Mobilization from the strain 638 background was via a conjugation like process, but occurred in the absence of known conjugative elements or other detectable plasmids. This result suggested the presence of a host-encoded transfer system in this B. fragilis strain.     

Specificity of Tn9 insertion into the genome of bacteriophage lambda att80 depending on its preceding location

It was shown that the site of previous integration (the donor site) of Tn9 affects the specificity of its next integration into the target molecule--phage lambda att80 DNA. The transposon integration sites were mapped by restriction and heteroduplex analysis following Tn9 transposition from chromosomal sites of Escherichia coli K-12 differing in location and Tn9 stability. When transposed from chromosomal galT::IS1 gene, Tn9 inserted into the site with coordinates 44,5 +/- 2 kb of lambda att80; when transposed from chromosomal attTn9A site, the transposon inserted into the sites with coordinates 31 +/- 0,7 kb or 33,3 +/- 0,5 kb. In the course of transposition of Tn9 from chromosomal attTn9N site the transposon inserted into the lambda att80 site with coordinates 26,5 +/- 5 kb. In the latter case, the increase of Tn9 single-stranded loop and the appearance of two new HindIII cleavage sites were observed in heteroduplex experiments. The data were interpreted as indicating structural rearrangements of Tn9 or linked sequences in the course of transposition.     

LexA protein of Escherichia coli represses expression of the Tn5 transposase gene.

The LexA protein of Escherichia coli represses expression of a variety of genes that, by definition, constitute the SOS regulon. Genetic evidence suggests that Tn5 transposition is also regulated by the product of the lexA gene (C.-T. Kuan, S.-K. Liu, and I. Tessman, Genetics 128:45-57, 1991). We now show that the LexA protein represses expression of the tnp gene, located in the IS50R component of Tn5, which encodes a transposase, and that LexA does not repress expression of the IS50R inh gene, which encodes an inhibitor of transposition. Elimination of LexA resulted in increased expression of the tnp gene by a factor of 2.7 +/- 0.4, as indicated by the activity of a lacZ gene fused to the tnp gene. LexA protein retarded the electrophoretic movement of a 101-bp segment of IS50R DNA that contained a putative LexA protein-binding site in the tnp promoter; the interaction between the LexA repressor and the promoter region of the tnp gene appears to be relatively weak. These features show that the IS50R tnp gene is a member of the SOS regulon.     

Regulation of Tn5 by the right-repeat proteins: Control at the level of the transposition reaction?

The transposon Tn5 consists of inverted repeats, called IS50R and IS50L, each of which encode two proteins. We show here that the larger protein encoded on IS50R, protein 1, is absolutely required for transposition. Deletion or insertion mutants that fail to make this protein fail to promote gene movement. In addition, this protein acts in cis preferentially. We also show that the smaller protein encoded on IS50R, protein 2, is competent to inhibit transposition of a Tn5 freshly introduced into the cell on a λ phage. In contrast, the proteins from IS50L possess neither of these two activities. By assaying expression of proteins that are hybrids between β-galactosidase and IS50R proteins, we find that the regulation of transposition cannot be due to the inhibitor repressing synthesis of Tn5 proteins. Control experiments, in which we assay synthesis of IS50 proteins synthesized from a λ::IS50R that has been infected into cells carrying the transposition inhibitor, confirm this conclusion.     

Characterization of in vitro constructed IS30-flanked transposons

In order to facilitate functional studies on the mobile genetic element IS30, a resident of the Escherichia coli chromosome, transposon structures with two copies of IS30 flanking the chloramphenicol-resistance gene cat were constructed in vitro. Transposons containing IS30 as direct repeats (Tn2700 and Tn2702) transpose from multicopy plasmids into the genome of phage P1-15, thus giving rise to special transduction for cat with frequencies between 10(-5) and 10(-8)/plaque-forming unit. In contrast, transposon structures with IS30 in inverted repeat (Tn2701 and Tn2703) showed no detectable (less than 10(-9] transposition activity in vivo. By restriction analysis, two insertion sites of Tn2700 and Tn2702 on the phage P1-15 genome were indistinguishable from those observed earlier with a single copy of the IS30 element. These two insertion sites were used several times independently by Tn2700 and Tn2702. This confirms the non-random target selection by the element and it indicates that transposition of Tn2700 and Tn2702 follows the same rules as that of IS30.     

Insertional specificity of transposon Tn5 in Acinetobacter sp.

Suicide plasmid pJB4JI, containing transposon Tn5 and phage Mu, was introduced from Escherichia coli 1830 into Acinetobacter sp. strain HO1-N and Acinetobacter calcoaceticus BD413. Kanamycin-resistant (Kmr) exconjugants of HO1-N and BD413, isolated on complex medium, were screened for auxotrophic requirements. Over 10,000 Kmr clones were examined, but no auxotrophs were detected. Several Kmr exconjugants of BD413 and HO1-N, obtained from independent matings, were chosen for further study. All Tn5-containing strains exhibited kanamycin phosphotransferase activity. Kmr strains lacked plasmid DNA as determined by three plasmid screening procedures, and the Kmr phenotype was not transferable by conjugal matings to kanamycin-sensitive BD413, HO1-N, or E. coli HB101. The chromosomal location of Tn5 insertions in independently isolated Kmr exconjugants of BD413 and HO1-N was characterized by restriction endonuclease mapping and hybridization studies. Results obtained from Southern hybridization studies were consistent with a single Tn5-specific insertion site in HO1-N and two such sites in BD413. Phage Mu sequences were not detected in Tn5-containing Acinetobacter sp.     

Mechanism of Is1 Transposition in E. COLI: Choice between Simple Insertion and Cointegration

Insertion element IS1 and IS1-based transposon Tn9 generate cointegrates (containing vector and target DNAs joined by duplicate copies of IS1 or Tn9) and simple insertions (containing IS1 or Tn9 detached from vector sequences). Based on studies of transposon Tn5 we had proposed a conservative (non-replicative) model for simple insertion. Others had proposed that all transposition is replicative, occurring in a rolling circle structure, and that the way DNA strands are joined when replication terminates determines whether a simple insertion or a cointegrate is formed.--We selected for the transposition of amp and cam resistance markers from pBR322::Tn9 plasmids to an F factor in recA-E. coli and identified products containing three and four copies of IS1, corresponding to true cointegrates (from monomeric plasmids), and simple insertions (from dimeric plasmids). The simple insertions with four copies of IS1 outnumbered those with three by a ratio of about 3:1, whereas true cointegrates containing three copies of IS1 were more numerous than those with four.--A straightforward rolling circle model had predicted that the simple insertions containing three copies of IS1 should be more frequent than those with four. Because we obtained the opposite result we propose that simple insertions only arise when the element fails to replicate or if replication starts but then terminates prematurely. The two classes of products, simple insertions and cointegrates, reflect alternative conservative and replicative fates, respectively, of an early intermediate in transposition.     

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.     

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.     

Study of the role of the insA open reading frame in the IS1 insertion element structure during transposition and resolution of the IS1 mediated cointegrates

In order to elucidate the function of the IS1 insA gene derivatives of plasmid pUC19::Tn9' with insertions of synthetic oligonucleotides were obtained. The latter are equal or multiple of 9 b.p. in length and are located in the Pst1 site within each of the two IS1 copies of the Tn9' transposon. The insertions of the nine base oligonucleotides code for the neutral amino acids and do not shift the reading frame. One of the mutant transposon obtained - Tn9'/X was studied on the ability to form simple insertions and plasmid cointegrates. For this purpose the pUC19 derivatives carrying the wild type and mutant transposon were mobilized by conjugative plasmid pRP3.1. It was found that the damage of the insA gene does not influence the ability of transposon to form simple insertions and plasmid cointegrates in both recA - and rec+ cells of E. coli. However, the frequency of the cointegrate formation in the subsequent transposition of the mutant transposon from pRP3.1::Tn9'/X to pBR322 was by 10-20 times lower in comparison to the wild type transposon. Instable (dissociating) Tn9'/X-mediated plasmid cointegrates formed by interaction pUC19::Tn9'/X and pRP3.1 were obtained. It was shown that in the E. coli recA-cells such cointegrates dissociate, as a rule, "correctly", i.e. they segregate mainly plasmids of types pUC19::Tn9'/X and pUC19::IS1/X. The data obtained correspond with the notion that the gene insA product is not essential for transposition, but is, possibly, involved in the formation of the IS1-generated deletions.     

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.     

Structure and stability of transposon 5-mediated cointegrates

We have determined the structure of a set of independently derived, Tn5-mediated cointegrates and examined the stability of several examples. A variety of cointegrate structures was found, including those mediated by the entire compound transposon, and those mediated by a single flanking IS50 element, which was always IS50-R, and never IS50-L. IS50-R but not IS50-L is reported to code for a protein(s) required for transposition. This finding confirms that IS50-L is relatively inactive and suggests that the active transposition protein(s) acts largely in cis on IS50-R. Another class of cointegrate was created by inverse transposition of Tn5 (using the inside ends of the flanking elements). In addition, we found an unexpectedly large set of cointegrates, in which the joint between the two plasmids was not adjacent to the transposon. All cointegrates analysed were found to be stable. This suggests that Tn5, unlike the transposon Tn3, does not transpose via an obligate cointegrate intermediate. This finding is compared to previous results with Tn5 and Tn9, and is discussed in terms of current models of transposition.     

Function of the InsA gene in the IS1 element of the Tn9' transposon: influence of oligonucleotide inserts in the InsA gene on formation of simple insertions and plasmid cointegrates]

To elucidate the role of the insA reading frame in transposition of the IS1 element of the Tn9' transposon, the derivatives of plasmids pUC19::Tn9' and pUC19::IS1 have been obtained using oligonucleotide inserts of the length equal or exceeding 9 bp and equal to 10 bp. The ability of mutant variants of the Tn9' transposon and the IS1 element to form simple insertions and plasmid cointegrates was studied. To this end, experiments were performed on mobilization of the derivatives of pUC19 containing mutant variants of the IS1 element and Tn9' as well as of the plasmids pUC19::Tn9' by the conjugative plasmid pRP3.1. According to the data obtained, mutations (inserts) in the insA gene have no influence on the frequency of transposition of the IS1 element and Tn9' from the plasmid pUC19 to pRP3.1. At the same time, the frequency of transposition events of mutant variants of Tn9' from the plasmid pRP3.1 to pBR322 is more than 10 times lower in comparison with the wild type transposon. The data obtained are in accordance with the assumption that the insA gene is not essential for transposition. A hypothesis is put forward explaining the role of the insA gene product in the process of bringing together short inverted repeats of the IS1, which are the sites for the transposase to be recognized at first stages of transposition.     

Transposition of Tn4351 in Porphyromonas gingivalis.

Genetic analysis of Porphyromonas gingivalis, an obligately anaerobic gram-negative bacterium, has been hindered by the apparent lack of naturally occurring bacteriophages, transposable elements, and plasmids. Plasmid R751::*omega 4 has previously been used as a suicide vector to demonstrate transposition of Tn4351 in B. uniformis. The erythromycin resistance gene on Tn4351 functions in Bacteroides and Porphyromonas. Erythromycin-resistant transconjugants were obtained at a mean frequency of 1.6 x 10(-7) from matings between Escherichia coli HB101 containing R751::*omega 4 and P. gingivalis 33277. Southern blot hybridization analysis indicated that about half of the erythromycin-resistant P. gingivalis transconjugants contained simple insertions of Tn4351 and half contained both Tn4351 and R751 sequences. The presence of R751 sequences in some P. gingivalis transconjugants most likely occurred from Tn4351-mediated cointegration of R751, since we were unable to detect autonomous plasmid in these P. gingivalis transconjugants. The P. gingivalis-Tn4351 DNA junction fragments from different transconjugants varied in size. These results are consistent with transposition of Tn4351 and with insertion at several different locations in the P. gingivalis chromosome. Tn4351 may be useful as a mutagen to isolate well-defined mutants of P. gingivalis.