Intramolecular transposition by a synthetic IS50 (Tn5) derivative.

We report the formation of deletions and inversions by intramolecular transposition of Tn5-derived mobile elements. The synthetic transposons used contained the IS50 O and I end segments and the transposase gene, a contraselectable gene encoding sucrose sensitivity (sacB), antibiotic resistance genes, and a plasmid replication origin. Both deletions and inversions were associated with loss of a 300-bp segment that is designated the vector because it is outside of the transposon. Deletions were severalfold more frequent than inversions, perhaps reflecting constraints on DNA twisting or abortive transposition. Restriction and DNA sequence analyses showed that both types of rearrangements extended from one transposon end to many different sites in target DNA. In the case of inversions, transposition generated 9-bp direct repeats of target sequences.     

Isolating large nested deletions in bacterial and P1 artificial chromosomes by in vivo P1 packaging of products of Cre-catalysed recombination between the endogenous and a transposed loxP site.

A general approach for isolating large nested deletions in P1 artificial chromosomes (PACs) and bacterial artificial chromosomes (BACs) by retrofitting with a loxP site-containing Tn10 mini-transposon is described. Cre-mediated recombination between the loxP site existing in these clones and one introduced by transposition leads to deletions and inversions of the DNA between these sites. Large deletions are selectively recovered by transducing the retrofitted PAC or BAC clones with P1 phage. The requirement that both loxP sites in the cointegrate be packaged into a P1 head ensures that only large deletions are rescued. PCR analyses identified these deletions as products of legitimate recombination between loxP sites mediated by Cre protein. BACs produce deletions much more efficiently than PACs although the former cannot be induced to greater than unit copy in cells. Mammalian cell-responsive antibiotic resistance markers are introduced as part of the transposon into genomic clone deletions for subsequent functional analysis. Most importantly, the loxP site retrofitting and P1 transduction can be performed in the same bacterial host containing these clones directly isolated from PAC or BAC libraries. These procedures should facilitate physical and functional mapping of genes and regulatory elements in these large plasmids.     

Inversions and deletions generated by a mini-gamma delta (Tn1000) transposon.

Intramolecular transposition by an engineered derivative of the transposon gamma delta (Tn1000) is described. This 1-kb element contains inverted repeats of the 40 bp of the delta end of gamma delta, bracketing a kan gene, but it contains no resolution site. Transposition was analyzed in two plasmids; one contained two contraselectable (conditional lethal) genes (thyA and sacB) adjacent to the mini-gamma delta element in a 13.0-kb pBR322/pUC-based two-component plasmid (a heterodimer), and the other contained a different contraselectable gene (strA [rpsL]) in a 13.2-kb three-component plasmid (a heterotrimer). Selection for loss of function of a single contraselectable gene yielded inversions and deletions. Each inversion plasmid was 1 kb larger than the parent plasmid: it had a second copy of mini-gamma delta inserted in the contraselected gene, with that copy plus the intervening segment inverted, and the 5-bp target site duplicated. Each deletion plasmid was smaller than the parent plasmid and had a deletion that extended from one transposon end into or through the contraselected gene for distances of up to 9.4 kb. The frequencies of deletions versus inversions ending in a single target gene were similar, although overall, deletions outnumbered inversions because deletions, but not inversions, into sites beyond the contraselected gene inactivate it. This work also demonstrates that thyA (which encodes thymidylate synthetase) is a useful contraselectable marker.     

A transgenic system for generation of transposon Ac/Ds-induced chromosome rearrangements in rice

The maize Activator (Ac)/Dissociation (Ds) transposable element system has been used in a variety of plants for insertional mutagenesis. Ac/Ds elements can also generate genome rearrangements via alternative transposition reactions which involve the termini of closely linked transposons. Here, we introduced a transgene containing reverse-oriented Ac/Ds termini together with an Ac transposase gene into rice (Oryza sativa ssp. japonica cv. Nipponbare). Among the transgenic progeny, we identified and characterized 25 independent genome rearrangements at three different chromosomal loci. The rearrangements include chromosomal deletions and inversions and one translocation. Most of the deletions occurred within the T-DNA region, but two cases showed the loss of 72 kilobase pairs (kb) and 79 kb of rice genomic DNA flanking the transgene. In addition to deletions, we obtained chromosomal inversions ranging in size from less than 10 kb (within the transgene DNA) to over 1 million base pairs (Mb). For 11 inversions, we cloned and sequenced both inversion breakpoints; in all 11 cases, the inversion junctions contained the typical 8 base pairs (bp) Ac/Ds target site duplications, confirming their origin as transposition products. Together, our results indicate that alternative Ac/Ds transposition can be an efficient tool for functional genomics and chromosomal manipulation in rice.     

In vitro transposition of Tn552: a tool for DNA sequencing and mutagenesis.

We have explored the potential of the Tn 552 in vitro transposition reaction as a genetic tool. The reaction is simple (requiring a single protein component), robust and efficient, readily producing insertions into several percent of target DNA. Most importantly, Tn 552 insertions in vitro appear to be essentially random. Extensive analyses indicate that the transposon exhibits no significant regional or sequence specificity for target DNA and leaves no discernible 'cold' spots devoid of insertions. The utility of the in vitro reaction for DNA sequencing was demonstrated with a cosmid containing the Mycobacterium smegmatis recBCD gene cluster. The nucleotide sequence of the entire operon was determined using 71 independent Tn 552 insertions, which generated over 13.5 kb of unique sequence and simultaneously provided a comprehensive collection of insertion mutants. The relatively short ends of Tn 552 make construction of novel transposons a simple process and we describe several useful derivatives. The data presented suggest that Tn 552 transposition is a valuable addition to the arsenal of tools available for molecular biology and genomics.     

Insertional transposon mutagenesis by electroporation of released Tn5 transposition complexes

DNA transposition is an important biological phenomenon that mediates genome rearrangements, inheritance of antibiotic resistance determinants, and integration of retroviral DNA. Transposition has also become a powerful tool in genetic analysis, with applications in creating insertional knockout mutations, generating gene-operon fusions to reporter functions, providing physical or genetic landmarks for the cloning of adjacent DNAs, and locating primer binding sites for DNA sequence analysis. DNA transposition studies to date usually have involved strictly in vivo approaches, in which the transposon of choice and the gene encoding the transposase responsible for catalyzing the transposition have to be introduced into the cell to be studied (microbial systems and applications are reviewed in ref. 1). However, all in vivo systems have a number of technical limitations. For instance, the transposase must be expressed in the target host, the transposon must be introduced into the host on a suicide vector, and the transposase usually is expressed in subsequent generations, resulting in potential genetic instability. A number of in vitro transposition systems (for Tn5, Tn7, Mu, Himar1, and Ty1) have been described, which bypass many limitations of in vivo systems. For this purpose, we have developed a technique for transposition that involves the formation in vitro of released Tn5 transposition complexes (TransposomesTM) followed by introduction of the complexes into the target cell of choice by electroporation. In this report, we show that this simple, robust technology can generate high-efficiency transposition in all tested bacterial species (Escherichia coli, Salmonella typhimurium, and Proteus vulgaris) We also isolated transposition events in the yeast Saccharomyces cerevisiae.     

Triplet nucleotide removal at random positions in a target gene: the tolerance of TEM-1 beta-lactamase to an amino acid deletion

The deletion of amino acids is one of the evolutionary mechanisms by which nature adapts the function of proteins. A simple method has been developed that mimics this event in vitro by introducing a deletion of exactly three nucleotides at random positions in a target gene. The method involved the engineering of the mini-Mu transposon to introduce a recognition sequence for the restriction enzyme MlyI. The new transposon, MuDel, was capable of efficient insertion into a target DNA sequence. To determine the efficacy of the method, the bla gene that encodes the TEM-1 beta-lactamase was used as the target and a small library containing 22 different sequence variants was created. Of these 22 variants, 8 were identified that conferred resistance to ampicillin on Escherichia coli. Each of the TEM-1 variants possessed a distinct ampicillin minimum inhibitory concentration, ranging from 500 to >10,000 microg/ml. Sequence analysis revealed that active TEM-1 variants contained deletions not just in loops but also helices, and included regions known to be involved in catalysis, antibiotic resistance and inhibitor binding. This new technology is transferable to most genes, permitting an extensive analysis of deletion mutations on protein function.     

A simple and rapid nucleotide sequencing strategy and its application in analyzing a rice histone 3 gene

An improved rapid method for sequencing a target DNA is described. A new plasmid, pAA-PZ1, which contains the origin of replication from phage M13 and a portion of the Tn9 transposon was constructed. A long fragment of target DNA cloned into this vector is progressively shortened in vivo from one end by transposon-mediated deletions. The plasmids carrying different lengths of target DNA are then made into single-stranded DNA in the same host upon infection with an M13 phage and their sequence is determined using the dideoxynucleotide chain-termination method. This method bypasses the in vitro enzymatic manipulations for progressive deletions and requires no subcloning. Using this strategy, we sequenced 1.3 kb of rice DNA containing a histone 3 gene within three weeks.     

The <Emphasis Type="Italic">piggyBac</Emphasis> Transposon as a Tool in Genetic Engineering

Transposons are mobile genetic elements that are part of the genomic DNA of numerous organisms and belong to two classes. Unlike class I transposons, class II DNA transposons do not use the stage of RNA synthesis in their transition; they perform it by the cut-and-paste mechanism or with a replicative transposition. The integration of a DNA transposon in a new site results in the duplication of a target sequence on either side of a transposon, and its excision is, as a rule, associated with insertions and deletions. The piggyBac transposon isolated from the Trichoplusia ni moth differs from other mobile elements of its class. Due to its unique ability to leave no traces after excision from an insertion site and to perform successful transposition and transference of large DNA fragments, piggyBac is a convenient tool for the development of gene engineering approaches. The TTAA sequence serves as a target site for transposon integration: insertion in the AT-rich DNA regions is more frequent. The ability of piggyBac to be transferred to a new area independently of the cell apparatus and to restore a DNA site without error after excision lies in the mechanism of its transposition, which is discussed in detail in the present review. Along with other transposons and viruses, the piggyBac transposon is widely used in the transgenesis of various organisms; it also finds application in insertion mutagenesis and gene therapy.     

A comparison of intramolecular rearrangements promoted by transposons Tn5 and Tn10.

The bacterial transposon Tn10 has previously been shown to move to other genomic sites by a conservative mechanism, whereby the transposon is excised by double-strand breaks and inserted between a pair of staggered nicks at the target. Other transposons, like Tn3, have been shown to transpose by a replicative mechanism that involves symmetrical nicking of the element and formation of the 'Shapiro intermediate', which can mature into either a cointegrate or a simple insert. The situation with respect to Tn5 is unclear; it was originally reported to use a conservative mechanism, but other evidence suggests that the mechanism might be replicative. In this paper, rearrangements of adjacent DNA promoted by Tn10 and Tn5 have been compared using positive selection for galactose-resistance to detect such rearrangements. Tn10 promoted the formation of adjacent deletions (that started from an inside end of Tn10), deletion/inversions and simple IS10 insertions, but no cointegrates. This behaviour is fully consistent with a conservative mechanism. In contrast, Tn5 was found to promote formation of adjacent deletions (that started mainly from an outside end of Tn5), IS50 insertions (that were frequently accompanied by inversions of adjacent DNA) and cointegrates. These characteristics seem compatible with a replicative, rather than a conservative, mode of transposition. Clearly, Tn5 and Tn10 exhibit some significant differences in their transposition. These results, and results of some previous experiments, have been interpreted to mean that Tn5 could use a replicative mechanism for its transposition.     

Local DNA Sequence Control of Deletion Formation in Escherichia coli Plasmid Pbr322

The specificity of deletion formation was studied using tests involving reversion of palindromic insertion mutations. Insertions of a Tn5-related transposon at 13 sites in the ampicillin-resistance (amp) gene of plasmid pBR322 were shortened to a nested set of perfect palindromes, 22, 32 and 90 bp long. We monitored frequencies of reversion to Ampr, which is the result of deletion of the palindrome plus one copy of the flanking 9 bp direct repeats (which had been formed by transposition). Revertant frequencies were found to depend on the location and the sequence of the palindromic insert. Changing a 45-kb interrupted palindrome to a 22-bp perfect palindrome stimulated deletion formation by factors of from fourfold to 545-fold among the 13 sites, while elongation of the perfect palindrome from 22 to 90 bp stimulated deletion formation by factors of from eight- to 18,000-fold. We conclude that deletion formation is strongly affected by subtle features of DNA sequence or conformation, both inside and outside the deleted segment, and that these effects may reflect specific interactions of DNA processing proteins with template DNAs.     

In vitro transposition of ISY100, a bacterial insertion sequence belonging to the Tc1/mariner family

The Synechocystis sp. PCC6803 insertion sequence ISY100 (ISTcSa) belongs to the Tc1/mariner/IS630 family of transposable elements. ISY100 transposase was purified and shown to promote transposition in vitro. Transposase binds specifically to ISY100 terminal inverted repeat sequences via an N-terminal DNA-binding domain containing two helix-turn-helix motifs. Transposase is the only protein required for excision and integration of ISY100. Transposase made double-strand breaks on a supercoiled DNA molecule containing a mini-ISY100 transposon, cleaving exactly at the transposon 3' ends and two nucleotides inside the 5' ends. Cleavage of short linear substrates containing a single transposon end was less precise. Transposase also catalysed strand transfer, covalently joining the transposon 3' end to the target DNA. When a donor plasmid carrying a mini-ISY100 was incubated with a target plasmid and transposase, the most common products were insertions of one transposon end into the target DNA, but insertions of both ends at a single target site could be recovered after transformation into Escherichia coli. Insertions were almost exclusively into TA dinucleotides, and the target TA was duplicated on insertion. Our results demonstrate that there are no fundamental differences between the transposition mechanisms of IS630 family elements in bacteria and Tc1/mariner elements in higher eukaryotes.     

Genome rearrangements in maize induced by alternative transposition of reversed ac/ds termini

Alternative transposition can induce genome rearrangements, including deletions, inverted duplications, inversions, and translocations. To investigate the types and frequency of the rearrangements elicited by a pair of reversed Ac/Ds termini, we isolated and analyzed 100 new mutant alleles derived from two parental alleles that both contain an intact Ac and a fractured Ac (fAc) structure at the maize p1 locus. Mutants were characterized by PCR and sequencing; the results show that nearly 90% (89/100) of the mutant alleles represent structural rearrangements including deletions, inversions, translocations, or rearrangement of the intertransposon sequence (ITS). Among 37 deletions obtained, 20 extend into the external flanking sequences, while 17 delete portions of the intertransposon sequence. Interestingly, one deletion allele that contains only a single nucleotide between the retained Ac and fAc termini is not competent for further alternative transposition events. We propose a new model for the formation of intertransposon deletions through insertion of reversed transposon termini into sister-chromatid sequences. These results document the types and frequencies of genome rearrangements induced by alternative transposition of reversed Ac/Ds termini in maize.     

Efficient transposition of IS911 circles in vitro.

An in vitro system has been developed which supports efficient integration of transposon circles derived from the bacterial insertion sequence IS911. Using relatively pure preparations of IS911-encoded proteins it has been demonstrated that integration into a suitable target required both the transposase, OrfAB, a fusion protein produced by translational frameshifting between two consecutive open reading frames, orfA and orfB, and OrfA, a protein synthesized independently from the upstream orfA. Intermolecular reaction products were identified in which one or both transposon ends were used. The reaction also generated various intramolecular transposition products including adjacent deletions and inversions. The circle junction, composed of abutted left and right IS ends, retained efficient integration activity when carried on a linear donor molecule, demonstrating that supercoiling in the donor molecule is not necessary for the reaction. Both two-ended integration and a lower level of single-ended insertions were observed under these conditions. The frequency of these events depended on the spacing between the transposon ends. Two-ended insertion was most efficient with a natural spacing of 3 bp. These results demonstrate that transposon circles can act as intermediates in IS911 transposition and provide evidence for collaboration between the two major IS911-encoded proteins, OrfA and OrfAB.     

piggyBac can bypass DNA synthesis during cut and paste transposition

DNA synthesis is considered a defining feature in the movement of transposable elements. In determining the mechanism of piggyBac transposition, an insect transposon that is being increasingly used for genome manipulation in a variety of systems including mammalian cells, we have found that DNA synthesis can be avoided during piggyBac transposition, both at the donor site following transposon excision and at the insertion site following transposon integration. We demonstrate that piggyBac transposon excision occurs through the formation of transient hairpins on the transposon ends and that piggyBac target joining occurs by the direct attack of the 3'OH transposon ends on to the target DNA. This is the same strategy for target joining used by the members of DDE superfamily of transposases and retroviral integrases. Analysis of mutant piggyBac transposases in vitro and in vivo using a piggyBac transposition system we have established in Saccharomyces cerevisiae suggests that piggyBac transposase is a member of the DDE superfamily of recombinases, an unanticipated result because of the lack of sequence similarity between piggyBac and DDE family of recombinases.     

IS231A from Bacillus thuringiensis is functional in Escherichia coli: transposition and insertion specificity.

A kanamycin resistance gene was introduced within the insertion sequence IS231A from Bacillus thuringiensis, and transposition of the element was demonstrated in Escherichia coli. DNA sequencing at the target sites showed that IS231A transposition results in direct repeats of variable lengths (10, 11, and 12 bp). These target sequences resemble the terminal inverted repeats of the transposon Tn4430, which are the preferred natural insertion sites of IS231 in B. thuringiensis.     

The Bacteroides mobilizable transposon Tn4555 integrates by a site-specific recombination mechanism similar to that of the gram-positive bacterial element Tn916.

The Bacteroides mobilizable transposon Tn4555 is a 12.2-kb molecule that encodes resistance to cefoxitin. Conjugal transposition is hypothesized to occur via a circular intermediate and is stimulated by coresident tetracycline resistance elements and low levels of tetracycline. In this work, the ends of the transposon were identified and found to consist of 12-bp imperfect inverted repeats, with an extra base at one end. In the circular form, the ends were separated by a 6-bp "coupling sequence" which was associated with either the left or the right transposon terminus when the transposon was inserted into the chromosome. Tn4555 does not duplicate its target site upon insertion. Using a conjugation-based transposition assay, we showed that the coupling sequence originated from 6 bases of genomic DNA flanking either side of the transposon prior to excision. Tn4555 preferentially transposed into a 589-bp genomic locus containing a 207-bp direct repeat. Integration occurred before or after the repeated sequence, with one integration site between the two repeats. These observations are consistent with a transposition model based on site-specific recombination. In the bacteriophage lambda model for site-specific recombination, the bacteriophage recombines with the Escherichia coli chromosome via a 7-bp "crossover" region. We propose that the coupling sequence of Tn4555 is analogous in function to the crossover region of lambda but that unlike the situation in lambda, recombination occurs between regions of nonhomologous DNA. This ability to recombine into divergent target sites is also a feature of the gram-positive bacterial transposon Tn916.     

DNA sequence analysis of the transposon Tn3: three genes and three sites involved in transposition of Tn3.

The complete nucleotide sequence of the transposon Tn3 and of 20 mutations which affect its transposition are reported. The mutations, generated in vitro by random insertion of synthetic restriction sites, proved to contain small duplications or deletions immediately adjacent to the new restriction site. By determining the phenotype and DNA sequence of these mutations we were able to generate an overlapping phenotypic and nucleotide map. This 4957 bp transposon encodes three polypeptides which account for all but 350 bp of its total coding capacity. These proteins are the transposase, a high molecular weight polypeptide (1015 amino acids) encoded by the tnpA gene; the Tn3-specific repressor, a low molecular weight polypeptide (185 amino acids) encoded by the tnpR gene; and the 286 amino acid beta-lactamase. The 38 bp inverted repeats flanking Tn3 appear to be absolutely required in cis for Tn3 to transpose. Genetic data suggest that Tn3 contains a third site (Gill et al., 1978), designated IRS (internal resolution site), whose absence results in the insertion of two complete copies of Tn3 as direct repeats into the recipient DNA. We suggest that these direct repeats of complete copies of Tn3 are intermediates in transposition, and that the IRS site is required for recombination and subsequent segregation of the direct repeats to leave a single copy of Tn3 (Gill et al., 1978). A 23 nucleotide sequence within the amino terminus of the transposase which shares strong sequence homology with the inverted repeat may be the internal resolution site.