Induction of transposon Tn1 translocations as affected by different mutagens

Transposition of ampicillin Tn1 transposon is repressed under normal conditions and occurs with low frequency (10(-4) per cell). Treatment of Escherichia coli cells with 22 c+mytomycin C, nitrosoguanidine and UV light induced transposition of Tn1 into different replicons. The degree of induction depended upon the strain of bacteria and the replicon which the transposon was inserted into. Mutation recA did not influence spontaneous translocation of the transposon but fully repressed induction of transposition during the period of mutagen treatment. In the present paper, the connection of inducible transposition process with the recA and lexA inducible functions of E. coli is discussed.     

Translocation of ampicillin transposon Tn1 in Escherichia coli cells during sexual reproduction

The efficiency of Tn1 transposition has been shown to increase considerably in course of bacterial conjugation. Usually, the frequency of Tn1 transposition from plasmid pSA2001, a derivative of RP4, into the chromosome never exceeded 0.1% per cell. Percentage of His+ transconjugants, marked by transposon Tn1 during conjugation between Hfr donor, carrying plasmid pSA2001, and auxotrophic recipient, was about 30%. Transposon Tn1 transfer into the recipient cells does not depend on the recA+ gene function in donor cells or on conjugative transfer of plasmid pSA2001. The transfer requires the recA+ gene function in recipients as well as the Hfr function in donor cells. Southern's blot-hybridization revealed the insertion of transposon Tn1 into the different sites of the chromosome of His+ transconjugants. The transposon inserted during conjugation retains the ability to potential further translocation into new sites on the chromosomal DNA.     

Characteristics of the het mutations in the Escherichia coli chromosome causing an increase in Tn1 transposition frequency

Four mutations were studied which lead to increasing the frequency of transposon Tn1 translocation into different replicons. These mutations (het1, het2, het3 and het4) increase the frequency of Tn1 translocation 10-20-fold. The het1 mutation is recessive and has been localized in the 90-94.5 min region of the bacterial chromosome. The mutation effects Tn1 transposition in the presence of F plasmid only. As we have demonstrated recently, F-plasmid inhibits Tn1 transposition in Escherichia coli cells. The het1 mutation eliminates this inhibition. Unlike het2, het3 and het4 mutations, het1 is responsible for resistance to male phages f1, f2, MS2 and inhibition of conjugative transfer in F+ bacteria.     

A system of transposon mutagenesis for bacteriophage T4

We have developed a system of transposon mutagenesis for bacteriophage T4. The transposon is a plasmid derivative of Tn5 which contains the essential T4 gene 24, permitting a direct selection for transposition events into a gene 24-deleted phage. The transposition occurred at a frequency of only 10(-7) per progeny phage, even though a dam- host was used to increase transposition frequency. Phage strains with a transposon insert were distinguished from most pseudorevertants of the gene 24 deletion by plaque hybridization using a transposon-specific probe. Mapping analysis showed that the transposon inserts into a large number of sites in the T4 genome, probably with a preference for certain regions. The transposon insertions in four strains were analysed by DNA sequencing using primers that hybridize to each end of the transposon and read out into the T4 genome. In each case, a 9 bp T4 target sequence had been duplicated and the insertions had occurred exactly at the IS50 ends of the transposon, demonstrating that bona fide transposition had occurred. Finally, the transposon insert strains were screened on the TabG Escherichia coli strain, which inhibits the growth of T4 motA mutants, and a motA transposon insert strain was found.     

Cis requirements for transposition of Tc1-like transposons in C. elegans

The Caenorhabditis elegans transposons Tc1 and Tc3 are able to transpose in heterologous systems such as human cell lines and zebrafish. Because these transposons might be useful vectors for transgenesis and mutagenesis of diverse species, we determined the minimal cis requirements for transposition. Deletion mapping of the transposon ends shows that fewer than 100?bp are sufficient for transposition of Tc3. Unlike Tc1, Tc3 has a second, internal transposase binding site at each transposon end. We found that these binding sites play no major role in the transposition reaction, since they can be deleted without reduction of the transposition frequency. Site-directed mutagenesis was performed on the conserved terminal base pairs at the Tc3 ends. The four terminal base pairs at the ends of the Tc3 inverted repeats were shown to be required for efficient transposition. Finally, increasing the length of the transposon from 1.9?kb to 12.5 kb reduced the transposition frequency by 20-fold, both in vivo and in vitro.     

Cis requirements for transposition of Tc1-like transposons in C. elegans

The Caenorhabditis elegans transposons Tc1 and Tc3 are able to transpose in heterologous systems such as human cell lines and zebrafish. Because these transposons might be useful vectors for transgenesis and mutagenesis of diverse species, we determined the minimal cis requirements for transposition. Deletion mapping of the transposon ends shows that fewer than 100 bp are sufficient for transposition of Tc3. Unlike Tc1, Tc3 has a second, internal transposase binding site at each transposon end. We found that these binding sites play no major role in the transposition reaction, since they can be deleted without reduction of the transposition frequency. Site-directed mutagenesis was performed on the conserved terminal base pairs at the Tc3 ends. The four terminal base pairs at the ends of the Tc3 inverted repeats were shown to be required for efficient transposition. Finally, increasing the length of the transposon from 1.9 kb to 12.5 kb reduced the transposition frequency by 20-fold, both in vivo and in vitro. Received: 21 April 1999 / Accepted: 10 June 1999     

Sleeping beauty transposase has an affinity for heterochromatin conformation

The Sleeping Beauty (SB) transposase reconstructed from salmonid fish has high transposition activity in mammals and has been a useful tool for insertional mutagenesis and gene delivery. However, the transposition efficiency has varied significantly among studies. Our previous study demonstrated that the introduction of methylation into the SB transposon enhanced transposition, suggesting that transposition efficiency is influenced by the epigenetic status of the transposon region. Here, we examined the influence of the chromatin status on SB transposition in mouse embryonic stem cells. Heterochromatin conformation was introduced into the SB transposon by using a tetracycline-controlled transrepressor (tTR) protein, consisting of a tetracycline repressor (TetR) fused to the Kruppel-associated box (KRAB) domain of human KOX1 through tetracycline operator (tetO) sequences. The excision frequency of the SB transposon, which is the first step of the transposition event, was enhanced by approximately 100-fold. SB transposase was found to be colocalized with intense DAPI (4',6'-diamidino-2-phenylindole) staining and with the HP1 family by biochemical fractionation analyses. Furthermore, chromatin immunoprecipitation analysis revealed that SB transposase was recruited to tTR-induced heterochromatic regions. These data suggest that the high affinity of SB transposase for heterochromatin conformation leads to enhancement of SB transposition efficiency.     

Development of a transposon mutagenesis system for Mycobacterium avium subsp. paratuberculosis

Mycobacterium avium subspecies paratuberculosis, a slow-growing Mycobacterium, is the causative agent of Johne's disease. Although M. paratuberculosis is difficult to manipulate genetically, our laboratory has recently demonstrated the ability to introduce DNA into these bacteria by transformation and phage infection. In the current study we develop the first transposon mutagenesis system for M. paratuberculosis using the conditionally replicating mycobacteriophage phAE94 to introduce the mycobacterial transposon Tn5367. Southern blotting and sequence analysis demonstrated that the transposon insertion sites are distributed relatively randomly throughout the M. paratuberculosis genome. We constructed a comprehensive bank of 5620 insertion mutants using this transposon. The transposition frequency obtained using this delivery system was 1.0 x 10(-6) transposition events per recipient cell. Auxotrophic mutants were observed in this library at a frequency of 0.3%.     

Counterselection and Co-Delivery of Transposon and Transposase Functions for <Emphasis Type="Italic">Sleeping Beauty</Emphasis>-Mediated Transposition in Cultured Mammalian Cells

Sleeping Beauty (SB) is a gene-insertion system reconstructed from transposon sequences found in teleost fish and is capable of mediating the transposition of DNA sequences from transfected plasmids into the chromosomes of vertebrate cell populations. The SB system consists of a transposon, made up of a gene of interest flanked by transposon inverted repeats, and a source of transposase. Here we carried out a series of studies to further characterize SB-mediated transposition as a tool for gene transfer to chromosomes and ultimately for human gene therapy. Transfection of mouse 3T3 cells, HeLa cells, and human A549 lung carcinoma cells with a transposon containing the neomycin phosphotransferase (NEO) gene resulted in a several-fold increase in drug-resistant colony formation when co-transfected with a plasmid expressing the SB transposase. A transposon containing a methotrexate-resistant dihydrofolate reductase gene was also found to confer an increased frequency of methotrexate-resistant colony formation when co-transfected with SB transposase-encoding plasmid. A plasmid containing a herpes simplex virus thymidine kinase gene as well as a transposon containing a NEO gene was used for counterselection against random recombinants (NEO+TK+) in medium containing G418 plus ganciclovir. Effective counterselection required a recovery period of 5 days after transfection before shifting into medium containing ganciclovir to allow time for transiently expressed thymidine kinase activity to subside in cells not stably transfected. Southern analysis of clonal isolates indicated a shift from random recombination events toward transposition events when clones were isolated in medium containing ganciclovir as well as G418. We found that including both transposon and transposase functions on the same plasmid substantially increased the stable gene transfer frequency in Huh7 human hepatoma cells. The results from these experiments contribute technical and conceptual insight into the process of transposition in mammalian cells, and into the optimal provision of transposon and transposase functions that may be applicable to gene therapy studies.     

Characterization and mapping of Ds—GUS-T-DNA lines for targeted insertional mutagenesis

The transposition patterns of the Ds —GUS transposon T-DNA in 23 independent single-copy lines have been characterized and the map positions of 10 of them on three of the five Arabidopsis chromosomes are reported. Using overexpressed Activator ( Ac ) elements as a transposase source, it was found that the primary determinant of transposition frequency is the insertion site of the Ac -T-DNA. Neither the structure of the transposon T-DNA nor, in most cases, its insertion site have a significant effect on transposition frequency. Both the frequency and timing of transposition are influenced by the parent through which the transposon and transposase T-DNAs are transmitted. Overall, nearly 75% of plants in which excision has occurred bear a reinserted element and very short-range transpositions predominate, underlining the advantage of using mapped transposons for insertional mutagenesis.     

Enhancement of Sleeping Beauty transposition by CpG methylation: possible role of heterochromatin formation

The Sleeping Beauty (SB) transposase is the most active transposase in vertebrate cells, and the SB transposon system has been used as a tool for insertional mutagenesis and gene delivery. Previous studies have indicated that the frequency of chromosomal transposition is considerably higher in mouse germ cells than in mouse embryonic stem cells, suggesting the existence of unknown mechanisms that regulate SB transposition. Here, we demonstrated that CpG methylation of the transposon region enhances SB transposition. The transposition efficiencies of a methylated transposon and an unmethylated transposon which had been targeted in the same genomic loci by recombination-mediated cassette exchange in mouse erythroleukemia cells were compared, and at least a 100-fold increase was observed in the methylated transposon. CpG methylation also enhanced transposition from plasmids into the genome. Chromatin immunoprecipitation assays revealed that histone H3 methylated at lysine-9, a hallmark of condensed heterochromatin, was enriched at the methylated transposon, whereas the unmethylated transposon formed a relaxed euchromatin structure, as evidenced by enrichment of acetylated histone H3 and reporter gene expression. Possible roles of heterochromatin formation in the transposition reaction are discussed. Our findings indicate a novel relationship between CpG methylation and transposon mobilization.     

Transposition of DNA fragments flanked by two inverted Tn1 sequences: translocation of the plasmid RP4::Tn1 region harboring the Tcr marker

We have demonstrated the possibility of transposition of the plasmid RP4::Tn1 fragment (21.2 kb) carrying the tetracycline resistance (Tcr) gene and flanked by two Tn1 copies. The new transposon, designated Tn1756, bears lethal genes that kill host cells. Therefore, its transposition can only be revealed in the presence of lethality-compensating helper regions of the plasmid RP4. Thus, RP4::Tn1 consists of two transposons, Tn1755 (Tn1-Kmr-Tn1) and Tn1756 (Tn1-Tcr-Tn1), sharing the Tn1 sequences. Both of these transposons are capable of recA-independent translocation to other plasmids. Therefore, transposition of DNA fragments flanked by two inverted Tn1 sequences does not depend on Tn1 orientation.     

The Mod(mdg4) component of the Su(Hw) insulator inserted in the P transposon can repress its mobility in Drosophila melanogaster

Transposable element P of Drosophila melanogaster is one of the best-characterized eukaryotic transposons. Successful transposition requires the interaction between transposase complexes at both termini of the P element. Here we found that insertion of one or two copies of the Su(Hw) insulator in the P transposon reduces the frequency of its transposition. Inactivation of a Mod(mdg4) component of the Su(Hw) insulator suppresses the insulator effect. Thus, the Su(Hw) insulator can modulate interactions between transposase complexes bound to the ends of the P transposon in germ cells.     

The Frequency of Conjugative Transposition of Tn916 Is Not Determined by the Frequency of Excision

Excision and formation of a covalently closed circular transposon molecule are required for conjugative transposition of Tn916 but are not the only factors that limit the frequency of conjugative transposition from one host to another. We found that in gram-positive bacteria, an increase in the frequency of excision and circularization of Tn916 caused by expression of integrase (Int) and excisionase (Xis) from a xylose-inducible promoter does not lead to an increase in the frequency of conjugative transposition. We also found that the concentration of Int and Xis in the recipient cell does not limit the frequency of conjugative transposition and that increased excision does not result in increased expression of transfer functions required to mobilize a plasmid containing the Tn916 origin of transfer. We conclude that in gram-positive hosts in which the Tn916 functions Int and Xis are overexpressed, the frequency of conjugative transposition is limited by the availability of transfer functions.     

Excision and transposition of piggyBac transposable element in tobacco budworm embryos

The TTAA-specific lepidopteran transposon piggyBac has already proved useful as a gene-transfer vector for efficient transformation of a wide variety of insects. Transposable element excision and transposition assays are useful indicators of an element's ability to be mobilized in vivo and, thus, potentially serve as a transforming vector. Here, we report that this transposon is capable of excision and transposition in tobacco budworm embryos with relatively low frequency.     

Effects of deletions in transposon Tn7 on its frequency of transposition.

Deletions in transposon Tn7 either abolished transposition or reduced transposition frequency. Except for a deletion in the right-hand terminus, these deletions could be complemented in trans. A 2.1-kilobase fragment of Tn7 encodes a diffusible gene product which stimulates transposition above the wild-type frequency. No cointegrate formation was detected.     

Alternative conformations of a nucleic acid four-way junction

Sleeping Beauty (SB), a member of the Tc1/mariner superfamily of transposable elements, is the only active DNA-based transposon system of vertebrate origin that is available for experimental manipulation. We have been using the SB element as a research tool to investigate some of the cis and trans-requirements of element mobilization, and mechanisms that regulate transposition in vertebrate species. In contrast to mariner transposons, which are regulated by overexpression inhibition, the frequency of SB transposition was found to be roughly proportional to the amount of transposase present in cells. Unlike Tc1 and mariner elements, SB contains two binding sites within each of its terminal inverted repeats, and we found that the presence of both of these sites is a strict requirement for mobilization. In addition to the size of the transposon itself, the length as well as sequence of the DNA outside the transposon have significant effects on transposition. As a general rule, the closer the transposon ends are, the more efficient transposition is from a donor molecule. We have found that SB can transform a wide range of vertebrate cells from fish to human. However, the efficiency and precision of transposition varied significantly among cell lines, suggesting potential involvement of host factors in SB transposition. A positive-negative selection assay was devised to enrich populations of cells harboring inserted transposons in their chromosomes. Using this assay, of the order of 10,000 independent transposon insertions can be generated in human cells in a single transfection experiment. Sleeping Beauty can be a powerful alternative to other vectors that are currently used for the production of transgenic animals and for human gene therapy.     

Development of a mariner-based transposon for use in Sorangium cellulosum

In order to generate marked insertions in the myxobacterium Sorangium cellulosum, a transposon based on the eukaryotic mariner transposon was developed. The transposition frequency was increased with the use of a mutated tnp gene. The transposon randomly inserts into the chromosome, as demonstrated by targeted mutagenesis of the epoK gene.     

Postexcision transposition of the transposon Tn10 in Escherichia coli K12

An experimental analysis of the fate of transposon Tn10 after excision from a proA::Tn10 site localized on the plasmid F' leads to the conclusions: 1. The precise excision is a progressive process. Its probability is estimated per time unit. 2. An excised Tn10 is always integrated into a different genetic locus. 2. An excised Tn10 is always integrated into a different genetic locus. 3. The kinetics of postexcision transposition are sometimes very slow. The excised transposon is inherited in one cell line in spite of cell multiplication. 4. The processes of excision and secondary insertion have no absolute requirement for the recA+ genotype but they are strongly enhanced in recA+ cells. 5. The kinetics of postexcision transposition are strongly dependent on the genetic site from which the transposon was excised. 6. The probability of postexcision transposition is fully determined by the probability of excision and depends on the genotype of the host and many other factors.