Relationships among the streptothricin resistance transposons Tn1825 and Tn1826 and the trimethoprim resistance transposon Tn7

The streptothricin resistance transposons Tn1825 and Tn1826 are closely related, based on physical and genetic characteristics, to the trimethoprim resistance transposon Tn7. These transposons may be considered to be members of a transposon family sharing in common the transposition functions and a basic streptomycin/spectinomycin resistance determinant but differing from one another with respect to particular additional resistance genes inserted to the left of the aadA gene.     

The trimethoprim resistance transposon Tn7 contains a cryptic streptothricin resistance gene

The transposon Tn7 codes for a trimethoprim resistance and for a streptomycin/spectinomycin resistance function of the bacterial host cells. Cloning of a restriction fragment of Tn7 into the vector plasmid pUC19 reveals the presence in Tn7 of an additional potential resistance determinant. A streptothricin resistance gene, which appears cryptic in the original Tn7 context becomes activated in the recombinant plasmid upon supplying the promoter function of the lacZ system of pUC19. These results together with previously published sequence data further disclose the modular character in the resistance gene regions of Tn7-like transposons.     

Characteristics of transposition of Tn7-like elements determining resistance to trimethoprim and streptomycin

The transposing elements Tn7, Tn1824, controlling the resistance to trimethoprim and Tn1925, Tn1826, carrying the streptothricin resistance genes were classified as a new transposon family on the basis of their physical structure. The comparative genetic analysis of the frequency, specificity and insertion orientation in different replicons, obtained in independent research systems in this study, demonstrated the identity of transposition characteristics of the transposons. The latter makes it possible to classify them as an independent transposon family. The peculiar feature of the Tn7-like elements family is their RecA-dependent transposition into the chromosome of Escherichia coli stimulated by bacteriophage Plkc transduction of the transposons.     

Highly preferred site of insertion of Tn7 into the chromosome of Vibrio anguillarum.

The possible usefulness of Tn7 as a tool for genetic studies in Vibrio anguillarum was examined. Using the plasmid pRK2073 as the transposon donor, Tn7 transposes at high frequency into the chromosome of V. anguillarum. However, hybridization analysis of the mutants DNA digested with different enzymes revealed that all isolates have the insertions in the same site. This indicates that like in many other gram-negative bacteria, Tn7 shows a specificity of transposition in the chromosome of V. anguillarum. Plasmid pRK2013 proved to be a very useful delivery vector for transposon mutagenesis in V. anguillarum.     

Mutagenesis by insertion of drug resistance transposon Tn7 into a vibrio species

A halotolerant, collagenolytic strain of Vibrio sp. was conjugated with an Escherichia coli strain carrying plasmid RP4. The plasmid was transferred to and maintained in the Vibrio and could be subsequently transferred in matings to suitably marked stains of the same species. After conjugation with an E. coli carrying the cointegrate plasmid RP4::Mu cts61::Tn7, Vibrio transconjugants were selected that carried Tn7 inserted into the bacterial chromosome. A large proportion of these transconjugants were auxotrophic, showing that plasmid suicide by Mu can be used to isolate Tn7-derived mutants in Vibrio. Approximately half of the auxotrophs isolate Tn7-derived mutants in Vibrio. Approximately half of the auxotrophs isolated were ilv mutants, all of which exhibited the same phenotype. Thus, although Tn7 insertion can induce auxotrophy, including trp, thy, his and ura, in Vibrio, there does appear to be a hot spot for integration in the ilv operon.     

Survival of enterococci and Tn916-like conjugative transposons in soil

The persistence of Enterococcus faecalis, fecal enterococci from swine waste, and Tn916-like elements was determined following inoculation into autoclaved and native soil microcosms. When cells of E. faecalis CG110 (Tn916) were inoculated into native microcosms, enterococcal viability in the soil decreased approximately 5 orders of magnitude (4.8 x 10(5) CFU/g soil to < 10 CFU/g) after 5 weeks. In autoclaved microcosms, the viability of E. faecalis decreased by only 20% in 5 weeks. In contrast, the content of Tn916, based on PCR of DNA extracts from soil microcosms, decreased by about 20% in both native and autoclaved microcosms. Similar results were obtained when the source of fecal enterococci and Tn916-like elements was swine waste. Because the concentration of Tn916-independent E. faecalis DNA (the D-alanine D-alanine ligase gene), based on PCR, decreased to nearly undetectable levels (at least 3 orders of magnitude) after 5 weeks in the native microcosms, the evidence suggests Tn916 stability in the soil results from en masse transfer of the transposon to the normal soil microflora and not survival of E. faecalis DNA in the soil system. Results from denaturing gradient gel electrophoresis suggest that multiple forms of Tn916 occur in swine waste, but only forms most like Tn916 exhibit stability in the soil.     

Translocation of transposons Tn10 and Tn5 in the Yersinia pestis chromosome

The possibility of translocation of the transposons Tn5 and Tn10 into the genome of Yersinia pestis, with the subsequent mutagenic effect was demonstrated. We revealed transposon harbouring clones at frequency 10(-4) to 10(-2). Derivatives of P1cml clr100ts phage served as vectors. Insertion of Tn10 transposon induced mutations in ilv, ser, arg, pur, pro, leu, nic, tyr, gua genes. The number of the insertion sites on the chromosome obtained for Tn5 was the same, these being arg, ade, pyr, leu, gua, trp, his, pan, ilv. The majority of auxotrophs did not revert. Occasionally, revertants were observed at frequencies 10(-8) to 10(-6). Unlike Escherichia coli, reversion was not accompanied by the loss of transposons. The rearrangements induced by transposons, presumably, near the insertion site, as well as duplications of transposons followed by incorporation of copies into novel sites, led to the appearance of additional defective genes, which made it possible to select various types of polyauxotrophs. Based on reiteration of coinciding double and triple mutant markers, we proposed a linkage group of genes within a segment of Y. pestis chromosome: lys ... tyr - ser - arg - ilv - leu - gua - ade(pur) - pro ... his ... pyr ... trp. The reasons for peculiarities of the behaviour of transposons in Y. pestis bacteria are discussed.     

Identification of Tn4451 and Tn4452, chloramphenicol resistance transposons from Clostridium perfringens.

The recombinant plasmids pJIR45 and pJIR97 contain the chloramphenicol resistance determinants derived from the Clostridium perfringens R plasmids pIP401 and pJIR27, respectively. Escherichia coli cultures which harbored these recombinant plasmids rapidly became chloramphenicol sensitive when grown in the absence of chloramphenicol. The loss of resistance was associated with the loss of 6.2-kilobase (kb) segments from both plasmids. Detailed restriction analysis of E. coli- and C. perfringens-derived deletion plasmids indicated that deletion of these segments was essentially precise. Transposition of the 6.2-kb segments was demonstrated by cloning the determinants into a temperature-sensitive plasmid, curing the recombinant plasmids, and selecting chloramphenicol-resistant, plasmid-free clones. Southern hybridization analysis of chromosomal DNA isolated from these recA E. coli clones indicated that the 6.2-kb segments had transposed to different sites on the chromosome. Heteroduplex analysis and restriction mapping indicated that the transposons, Tn4451 (pIP401) and Tn4452 (pJIR27), were closely related and did not contain large inverted or directly repeated sequences. These transposons represent the first transposable elements from the clostridia to be identified and characterized.     

Genomic analysis of insertion behavior and target specificity of mini-Tn7 and Tn3 transposons in Saccharomyces cerevisiae

Transposons are widely employed as tools for gene disruption. Ideally, they should display unbiased insertion behavior, and incorporate readily into any genomic DNA to which they are exposed. However, many transposons preferentially insert at specific nucleotide sequences. It is unclear to what extent such bias affects their usefulness as mutagenesis tools. Here, we examine insertion site specificity and global insertion behavior of two mini-transposons previously used for large-scale gene disruption in Saccharomyces cerevisiae: Tn3 and Tn7. Using an expanded set of insertion data, we confirm that Tn3 displays marked preference for the AT-rich 5 bp consensus site TA[A/T]TA, whereas Tn7 displays negligible target site preference. On a genome level, both transposons display marked non-uniform insertion behavior: certain sites are targeted far more often than expected, and both distributions depart drastically from Poisson. Thus, to compare their insertion behavior on a genome level, we developed a windowed Kolmogorov–Smirnov (K–S) test to analyze transposon insertion distributions in sequence windows of various sizes. We find that when scored in large windows (>300 bp), both Tn3 and Tn7 distributions appear uniform, whereas in smaller windows, Tn7 appears uniform while Tn3 does not. Thus, both transposons are effective tools for gene disruption, but Tn7 does so with less duplication and a more uniform distribution, better approximating the behavior of the ideal transposon.     

Discovery and characterization of novel type I-D CRISPR-guided transposons identified among diverse Tn7-like elements in cyanobacteria

CRISPR-Cas defense systems have been naturally coopted for guide RNA-directed transposition by Tn7 family bacterial transposons. We find cyanobacterial genomes are rich in Tn7-like elements, including most of the known guide RNA-directed transposons, the type V-K, I-B1, and I-B2 CRISPR-Cas based systems. We discovered and characterized an example of a type I-D CRISPR-Cas system which was naturally coopted for guide RNA-directed transposition. Multiple novel adaptations were found specific to the I-D subtype, including natural inactivation of the Cas10 nuclease. The type I-D CRISPR-Cas transposition system showed flexibility in guide RNA length requirements and could be engineered to function with ribozyme-based self-processing guide RNAs removing the requirement for Cas6 in the heterologous system. The type I-D CRISPR-Cas transposon also has naturally fused transposase proteins that are functional for cut-and-paste transposition. Multiple attributes of the type I-D system offer unique possibilities for future work in gene editing. Our bioinformatic analysis also revealed a broader understanding of the evolution of Tn7-like elements. Extensive swapping of targeting systems was identified among Tn7-like elements in cyanobacteria and multiple examples of convergent evolution, including systems targeting integration into genes required for natural transformation.     

Interaction of related Tn916-like transposons: analysis of excision events promoted by Tn916 and Tn5386 integrases

In recent work, we described the excision of a large genomic region from Enterococcus faecium D344R in which the sequence from "joint" regions suggested that excision resulted from the interaction of conjugative transposon Tn916 and the related mobile element Tn5386. In the present study, we examined the ability of integrases and integrase-excisase combinations from Tn916 and Tn5386 to promote the excision of constructs consisting of the termini of Tn916, Tn5386, and the VanB mobile element Tn5382. Integrases alone from either Tn916 or Tn5386 promoted the circularization of constructs from the three different transposons, even when the different termini used in the constructs were discordant in their transposon of origin. The termini of Tn916 and Tn5382 found in all joints were consistent with previously identified Tn916 and Tn5382 termini. Substantial variation was seen in the integrase terminus of Tn5386 used to form joints, regardless of the integrase that was responsible for circularization. Variability was observed in joints formed from Tn5386 constructs, in contrast to joints observed with the termini of Tn916 or Tn5382. The coexpression of excisase yielded some variability in the joint regions observed. These data confirm that integrases from some Tn916-like elements can promote circularization with termini derived from heterologous transposons and, as such, could promote excision of large genomic regions flanked by such elements. These findings also raise interesting questions about the sequence specificities of the C terminals of Tn916-like integrases, which bind to the ends and facilitate strand exchange.