Three-partner conversion induced by the P-element transposase in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

Conversion of one P-derived transposon into another has already been shown to occur with a measurable frequency. However, the mechanism responsible for such replacements has remained controversial. We previously proposed a mechanism involving three partners. We assumed that after excision of the P-element inserted at the target site, the double-strand break was repaired using, first, the homologous P sequences on the sister chromatid, and second, a remote template, the donor P-derived transposon. However, two other mechanisms have been proposed. The first involves two partners only, the broken end and the remote template, while the second involves transposition of the donor into the target P-element, followed by a double recombination event. Here we describe the conversion of a defective P-element using as a remote template an enhancer-trap element that is itself unable to transpose because it lacks 21?bp at its 5′ end. This result makes it possible to exclude the possibility that this conversion event occurred after transposition. The new allele was molecularly and genetically characterized. The occurrence of a polymorphism at position 33 of the P-element sequence and of an imperfect copy of the template on the 3′ side of the converted transposon confirmed that the sister chromatid was absolutely necessary as a partner for repair. Our results show that targeting of a marked P-element is possible, even when this element is unable to transpose. This provides a means of improving recovery of conversion events by eliminating unwanted transpositions catalyzed by the P transposase.     

Is10 Promotes Adjacent Deletions at Low Frequency

Some transposable elements move by a replicative mechanism involving cointegrate formation. Intramolecular cointegration can generate a product called an ``adjacent deletion' in which a contiguous chromosomal segment adjacent to the transposon is deleted while the element responsible remains intact. Insertion sequence IS10 is thought to transpose by a nonreplicative mechanism. In the simplest models, nonreplicative transposition cannot give rise to an adjacent deletion because an intrinsic feature of such transposition is excision of the IS element from the donor location. We report here that IS10 can generate adjacent deletions, but at a frequency which is approximately 1/30th the frequency of transposition for the same element. We suggest that these deletions might arise either by nonreplicative transposition events that involve two IS10 elements located on sister chromosomes or by aberrant nonreplicative events involving cleavage and ligation at only one end of the element.     

Uncoupling of transpositional immunity from gamma delta transposition by a mutation at the end of gamma delta.

The transposon gamma delta, in common with other members of the Tn3 family, confers transpositional immunity, a phenomenon by which plasmids containing a single transposon end show reduced activity as targets for further insertion by the same element. We found that a copy of a mutant delta end, in which the two terminal base pairs (5' GG) were substituted with cytosines, conferred the same degree of immunity as the unaltered delta end. However, a transposon analog with the mutant delta end as its termini could not transpose. These results suggest that the binding of transposase to a site on a target replicon is sufficient to confer immunity and that immunity does not involve subsequent DNA transactions at the bound target site, analogous to the catalytic processes that occur at the transposon ends during transposition.     

P Element Transposition in Drosophila Melanogaster: An Analysis of Sister-Chromatid Pairs and the Formation of Intragenic Secondary Insertions during Meiosis

The gap-repair model proposes that P elements move via a conservative, ``cut-and-paste' mechanism followed by double-strand gap repair, using either the sister chromatid or homolog as the repair template. We have tested this model by examining meiotic purturbations of an X-linked ry(+) transposon during the meiotic cycle of males, employing the mei-S332 mutation, which induces high frequency equational nondisjunction. This system permits the capture of both sister-X chromatids in a single patroclinous daughter. In the presence of P-transposase, transpositions within the immediate proximity of the original site are quite frequent. These are readily detectible among the patroclinous daughters, thereby allowing the combined analysis of the transposed element, the donor site and the putative sister-strand template. Molecular analysis of 22 meiotic transposition events provide results that support the gap-repair model of P element transposition. Prior to this investigation, it was not known whether transposition events were exclusively or predominantly premeiotic. The results of our genetic analysis revealed that P elements mobilize at relatively high frequencies during meiosis. We estimated that approximately 4% of the dysgenic male gametes have transposon perturbations of meiotic origin; the proportion of gametes containing lesions of premeiotic origin was estimated at 32%.     

Tn7 Transposition Creates a Hotspot for Homologous Recombination at the Transposon Donor Site

Homologous recombination at the bacterial transposon Tn7 donor site is stimulated 10-fold when Tn7 is activated to transpose at high frequency in RecD(-) Escherichia coli, where recombination is focused near the ends of double-chain breaks. This is observed as an increase in recombination between two lacZ heteroalleles when one copy of lacZ carries within it a Tn7 that is transposing at high frequency. This stimulation of recombination is dependent upon the presence of homology with the donor site, is independent of SOS induction, and is not due to a global stimulation of recombination. When stimulated by Tn7 transposition, the conversion events giving rise to Lac(+) recombinants occur preferentially at the site of Tn7, suggesting that transposition is stimulating gene conversion at the donor site. These results support the model that Tn7 transposition occurs by a ``cut and paste' mechanism, leaving a double-chain break at the donor site that is repaired by the host homologous recombination machinery; normally, repair would use homology in a sister chromosome to regenerate a copy of the transposon. This proposed series of events allows transposition that is nonreplicative, per se, to be effectively replicative.     

Genetic evidence that Tn10 transposes by a nonreplicative mechanism

We present genetic evidence that the tetracycline resistance element Tn10 transposes by a nonreplicative mechanism. Heteroduplex Tn10 elements containing three single base pair mismatches were constructed on lambda phage genomes and allowed to transpose from lambda into the bacterial chromosome. Analysis of TetR colonies resulting from such transpositions suggests that information from both strands of the transposing Tn10 element is transmitted faithfully to its transposition product. The simplest interpretation of these results is that the transposing element is excised from the donor molecule and inserted into the target molecule without being replicated. A mismatch 70 base pairs from one end of the transposon is preserved, suggesting that there is little or no replication, even at the termini of the element, during transposition in vivo.     

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.     

Genetic Evidence against Intramolecular Rejoining of the Donor DNA Molecule following Is10 Transposition

Tn10 and IS10 transpose by a nonreplicative mechanism in which the transposon is excised from the donor molecule and integrated into a target DNA site, leaving behind a break at the original donor site. The fate of this broken donor DNA molecule is not known. We describe here two experiments that address this issue. One experiment demonstrates that a polar IS10 element gives rise to polarity-relief revertants at less than 1% the frequency of transposition of the same element in the same culture. In a second experiment, transpositions of an IS10 element from one site in the bacterial genome to another are selected and the resulting isolates examined for alterations at the donor site; none of 1088 such isolates exhibited a detectable change at the donor locus. These results are compatible with two possible fates of the transposon donor molecule: degradation (``donor suicide'), or restoration of the original information at the donor site by a recombinational repair mechanism analogous to double-strand break repair. These results argue against the possibility that the donor molecule gap is simply resealed by intramolecular rejoining.     

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.     

Tn7 transposition in vitro proceeds through an excised transposon intermediate generated by staggered breaks in DNA.

We have developed a cell-free system in which the bacterial transposon Tn7 inserts at high frequency into its preferred target site in the Escherichia coli chromosome, attTn7; Tn7 transposition in vitro requires ATP and Tn7-encoded proteins. Tn7 transposes via a cut and paste mechanism in which the element is excised from the donor DNA by staggered double-strand breaks and then inserted into attTn7 by the joining of 3' transposon ends to 5' target ends. Neither recombination intermediates nor products are observed in the absence of any protein component or DNA substrate. Thus, we suggest that Tn7 transposition occurs in a nucleoprotein complex containing several proteins and the substrate DNAs and that recognition of attTn7 within this complex provokes strand cleavages at the Tn7 ends.     

Regulation of activator/dissociation transposition by replication and DNA methylation

In maize the transposable elements Activator/Dissociation (Ac/Ds) transpose shortly after replication from one of the two resulting chromatids ("chromatid selectivity"). A model has been suggested that explains this phenomenon as a consequence of different affinity for Ac transposase binding to holo-, hemi-, and unmethylated transposon ends. Here we demonstrate that in petunia cells a holomethylated Ds is unable to excise from a nonreplicating vector and that replication restores excision. A Ds element hemi-methylated on one DNA strand transposes in the absence of replication, whereas hemi-methylation of the complementary strand causes a >6.3-fold inhibition of Ds excision. Consistently in the active hemi-methylated state, the Ds ends have a high binding affinity for the transposase, whereas binding to inactive ends is strongly reduced. These results provide strong evidence for the above-mentioned model. Moreover, in the absence of DNA methylation, replication enhances Ds transposition in petunia protoplasts >8-fold and promotes formation of a predominant excision footprint. Accordingly, replication also has a methylation-independent regulatory effect on transposition.     

Protected P-Element Termini Suggest a Role for Inverted-Repeat-Binding Protein in Transposase-Induced Gap Repair in Drosophila Melanogaster

P-element transposition is thought to occur by a cut-and-paste mechanism that generates a double-strand break at the donor site, the repair of which can lead to internally deleted elements. We have generated a series of both phenotypically stronger and weaker allelic derivatives of vg(21), a vestigial mutant caused by a P-element insertion in the 5' region of the gene. Virtually all of the new alleles arose by internal deletion of the parental element in vg(21), and we have characterized a number of these internally deleted P elements. Depending upon the selection scheme used, we see a very different spectrum of amount and source of P-element sequences in the resultant derivatives. Strikingly, most of the breakpoints occur within the inverted-repeats such that the last 15-17 bp of the termini are retained. This sequence is known to bind the inverted-repeat-binding protein (IRBP). We propose that the IRBP may act to preserve the P-element ends when transposition produces a double-strand gap. This allows the terminus to serve as a template upon which DNA synthesis can act to repair the gap. Filler sequences found at the breakpoints of the internally deleted P elements resemble short stretches, often in tandem arrays, of these terminal sequences. The structure of the filler sequences suggests replication slippage may occur during the process of gap repair.     

Functional dissection of the Tol2 transposable element identified the minimal cis-sequence and a highly repetitive sequence in the subterminal region essential for transposition

The Tol2 element is a naturally occurring active transposable element found in vertebrate genomes. The Tol2 transposon system has been shown to be active from fish to mammals and considered to be a useful gene transfer vector in vertebrates. However, cis-sequences essential for transposition have not been characterized. Here we report the characterization of the minimal cis-sequence of the Tol2 element. We constructed Tol2 vectors containing various lengths of DNA from both the left (5') and the right (3') ends and tested their transpositional activities both by the transient excision assay using zebrafish embryos and by analyzing chromosomal transposition in the zebrafish germ lineage. We demonstrated that Tol2 vectors with 200 bp from the left end and 150 bp from the right end were capable of transposition without reducing the transpositional efficiency and found that these sequences, including the terminal inverted repeats (TIRs) and the subterminal regions, are sufficient and required for transposition. The left and right ends were not interchangeable. The Tol2 vector carrying an insert of >11 kb could transpose, but a certain length of spacer, <276 but >18 bp, between the left and right ends was necessary for excision. Furthermore, we found that a 5-bp sequence, 5'-(A/G)AGTA-3', is repeated 33 times in the essential subterminal region. Mutations in the repeat sequence at 13 different sites in the subterminal region, as well as mutations in TIRs, severely reduced the excision activity, indicating that they play important roles in transposition. The identification of the minimal cis-sequence of the Tol2 element and the construction of mini-Tol2 vectors will facilitate development of useful transposon tools in vertebrates. Also, our study established a basis for further biochemical and molecular biological studies for understanding roles of the repetitive sequence in the subterminal region in transposition.     

Mini-Mu mediates deletion-inversions in vivo by intra-transposon transposition

We have shown that a mini-Mu can transpose into itself in vivo to generate a circle containing only transposon sequences. This deletion-inversion product, which has previously been observed in vitro, is formed by non-replicative transposition and has directly repeated Mu ends. It therefore cannot undergo further rounds of transposition and retains the two copies of the target sequence duplicated in the event. Thus we have been able to confirm that a mini-Mu can undergo non-replicative reactions in vivo and that these generate a 5 bp target site duplication, as has been shown to occur following replicative transposition and lysogenization with Mu.     

Asymmetric processing of human immunodeficiency virus type 1 cDNA in vivo: implications for functional end coupling during the chemical steps of DNA transposition

Retroviral integration, like all forms of DNA transposition, proceeds through a series of DNA cutting and joining reactions. During transposition, the 3' ends of linear transposon or donor DNA are joined to the 5' phosphates of a double-stranded cut in target DNA. Single-end transposition must be avoided in vivo because such aberrant DNA products would be unstable and the transposon would therefore risk being lost from the cell. To avoid suicidal single-end integration, transposons link the activity of their transposase protein to the combined functionalities of both donor DNA ends. Although previous work suggested that this critical coupling between transposase activity and DNA ends occurred before the initial hydrolysis step of retroviral integration, work in the related Tn10 and V(D)J recombination systems had shown that end coupling regulated transposase activity after the initial hydrolysis step of DNA transposition. Here, we show that integrase efficiently hydrolyzed just the wild-type end of two different single-end mutants of human immunodeficiency virus type 1 in vivo, which, in contrast to previous results, proves that two functional DNA ends are not required to activate integrase's initial hydrolysis activity. Furthermore, despite containing bound protein at their processed DNA ends, these mutant viruses did not efficiently integrate their singly cleaved wild-type end into target DNA in vitro. By comparing our results to those of related DNA recombination systems, we propose the universal model that end coupling regulates transposase activity after the first chemical step of DNA transposition.     

The piggyBac element is capable of precise excision and transposition in cells and embryos of the mosquito, Anopheles gambiae

The piggyBac transposable element was tested for transposition activity in plasmid-based excision and inter-plasmid transposition assays to determine if this element would function in Anopheles gambiae cells and embryos. In the Mos55 cell line, precise excision of the piggyBac element was observed only in the presence of a helper plasmid. Excision occurred at a rate of 1 event per 1000 donor plasmids screened. Precise excision of the piggyBac element was also observed in injected An. gambiae embryos, but at a lower rate of 1 excision per 5000 donor plasmids. Transposition of the marked piggyBac element into a target plasmid occurred in An. gambiae cells at a rate of 1 transposition event per 24,000 donor plasmids. The piggyBac element transposed in a precise manner, with the TTAA target site being duplicated upon insertion, in 56% of transpositions observed, and only in the presence of the piggyBac helper. The remaining transpositions resulted in a deletion of target sequence, a novel observation for the phenomenon of piggyBac element insertion. 'Hot spots' for insertion into the target plasmid were observed, with 25 of 34 events involving one particular site. These results are the first demonstration of the precise mobility of piggyBac in this malaria vector and suggest that the lepidopteran piggyBac transposon is a candidate element for germline transformation of anopheline mosquitoes.     

IS911 transposon circles give rise to linear forms that can undergo integration in vitro

High levels of expression of the transposase OrfAB of bacterial insertion sequence IS911 leads to the formation of excised transposon circles, in which the two abutted ends are separated by 3 bp. Initially, OrfAB catalyses only single-strand cleavage at one 3' transposon end and strand transfer of that end to the other. It is believed that this molecule, in which both transposon ends are held together in a single-strand bridge, is then converted to the circular form by the action of host factors. The transposon circles can be integrated efficiently into an appropriate target in vivo and in vitro in the presence of OrfAB and a second IS911 protein OrfA. In the results reported here, we have identified linear transposon forms in vivo from a transposon present in a plasmid, raising the possibility that IS911 can also transpose using a cut-and-paste mechanism. However, the linear species appeared not to be derived directly from the plasmid-based copy by direct double-strand cleavages at both ends, but from preformed excised transposon circles. This was confirmed further by the observation that OrfAB can cleave a cloned circle junction both in vivo and in vitro by two single-strand cleavages at the 3' transposon ends to generate a linear transposon form with a 3'-OH and a three-nucleotide 5' overhang at the ends. Moreover, while significantly less efficient than the transposon circle, a precleaved linear transposon underwent detectable levels of integration in vitro. The possible role of such molecules in the IS911 transposition pathway is discussed.     

Transitory Cis Complementation: A Method for Providing Transposition Functions to Defective Transposons

A genetic complementation system is described in which the complementing components are close together in a single linear DNA fragment; the complementation situation is temporary. This system is useful for providing transposition functions to transposition-defective transposons, since transposition functions act preferentially in cis. The basic procedure involves placing a transposition-defective transposon near the gene(s) for its transposition functions on a single DNA fragment. This fragment is introduced, here by general transduction, into a new host. The transposase acts in cis to permit the defective element to transpose from the introduced fragment into the recipient chromosome. The helper genes do not transpose and are lost by degradation and segregation. The method yields single insertion mutants that lack transposase and are not subject to further transposition or chromosome rearrangement. The general procedure is applicable to other sorts of transposable elements and could be modified for use in other genetic systems.     

Targeted Transposition at the Vestigial Locus of Drosophila Melanogaster

Targeted transposition is the replacement of one P element with another. We are exploiting this unique property of P elements to study the complex regulatory domain of the Dopa decarboxylase (Ddc) gene in Drosophila melanogaster. P element constructs targeted to the same site in the genome will be subjected to the same position effect. This allows the subtle effects typical of most mutations in the Ddc regulatory region to be measured in the absence of the variable influences of position effects which are associated with the current method of germline transformation. We have investigated some of the parameters affecting targeted transposition of a Ddc transposon, P[Ddc], into a P element allele at the vestigial locus. These events were detected by an increased mutant vg phenotype. The location of the donor transposon in cis or in trans to the target had little effect on the frequency of targeting. Likewise, the mobility of different donor elements, as measured by their rate of transposition to a different chromosome, varied nearly 20-fold, while the rate of targeted transposition was very similar between them. All targeted alleles were precise replacements of the target P element by P[Ddc], but in several cases the donor was inserted in the opposite orientation. The targeted alleles could be described as the result of a replicative, conversion-like event.