Adjacent sequences influence DNA repair accompanying transposon excision in maize

Mobile elements transposing via DNA intermediates often leave small rearrangements, or "transposon footprints," at sites where they excise. Each excision event leaves its own footprint and, at any given site, these vary in size and sequence. Footprint formation involves DNA repair of sequences flanking the element. We have analyzed the footprints formed by a 2-kb Ds element excising from six different sites in exons of the maize waxy (Wx) gene. We find that groups of footprints left at individual sites are surprisingly nonrandom; different excision products predominate consistently at each site. Less frequent footprints left by each insertion appear related to the predominant type. The data suggest that flanking sequences affect the DNA repair processes associated with element excision. Two models have been proposed to explain footprint formation, one featuring a 5' exonuclease and the other featuring hairpin loop formation and an endonuclease. Our data have interesting implications for both these models. Evidence is also presented to support the presence of a separate excision mechanism that can remove Ac/Ds elements without leaving any footprint and that operates in parallel with the footprint-forming mechanism.     

Transposition without transposase: a spontaneous mutation in bacteria

Transposition mutations are typically associated with the activities of transposable elements such as transposons and insertion sequences, whose mobility is dependent upon transposase enzymes that catalyze exchanges between element ends and target sites. We describe a single transposition event in which a block of donor sequence is inserted at a target site without the involvement of any known transposase or the ends of any known transposable element. We propose that this is a new type of spontaneous mutation which may be difficult to detect in standard mutant hunts but may be of evolutionary importance.     

The Tn7 transposase is a heteromeric complex in which DNA breakage and joining activities are distributed between different gene products

The bacterial transposon Tn7 translocates by a cut and paste mechanism: excision from the donor site results from double-strand breaks at each end of Tn7 and target insertion results from joining of the exposed 3' Tn7 tips to the target DNA. Through site-directed mutagenesis of the Tn7-encoded transposition proteins TnsA and TnsB, we demonstrate that the Tn7 transposase is a heteromeric complex of these proteins, each protein executing different DNA processing reactions. TnsA mediates DNA cleavage reactions at the 5' ends of Tn7, and TnsB mediates DNA breakage and joining reactions at the 3' ends of Tn7. Thus the double-strand breaks that underlie Tn7 excision result from a collaboration between two active sites, one in TnsA and one in TnsB; the same (or a closely related) active site in TnsB also mediates the subsequent joining of the 3' ends to the target. Both TnsA and TnsB appear to be members of the retroviral integrase superfamily: mutation of their putative DD(35)E motifs blocks catalytic activity. Recombinases of this class require a divalent metal cofactor that is thought to interact with these acidic residues. Through analysis of the metal ion specificity of a TnsA mutant containing a sulfur (cysteine) substitution, we provide evidence that a divalent metal actually interacts with these acidic amino acids.     

Tiggers and DNA transposon fossils in the human genome

We report several classes of human interspersed repeats that resemble fossils of DNA transposons, elements that move by excision and reintegration in the genome, whereas previously characterized mammalian repeats all appear to have accumulated by retrotransposition, which involves an RNA intermediate. The human genome contains at least 14 families and > 100,000 degenerate copies of short (180-1200 bp) elements that have 14- to 25-bp terminal inverted repeats and are flanked by either 8 bp or TA target site duplications. We describe two ancient 2.5-kb elements with coding capacity, Tigger1 and -2, that closely resemble pogo, a DNA transposon in Drosophila, and probably were responsible for the distribution of some of the short elements. The deduced pogo and Tigger proteins are related to products of five DNA transposons found in fungi and nematodes, and more distantly, to the Tc1 and mariner transposases. They also are very similar to the major mammalian centromere protein CENP-B, suggesting that this may have a transposase origin. We further identified relatively low-copy-number mariner elements in both human and sheep DNA. These belong to two subfamilies previously identified in insect genomes, suggesting lateral transfer between diverse species.     

Two classes of Tn10 transposase mutants that suppress mutations in the Tn10 terminal inverted repeat

Tn10 transposition requires IS10 transposase and essential sequences at the two ends of the element. Mutations in terminal basepairs 6-13 confer particularly strong transposition defects. We describe here the identification of transposase mutations that suppress the transposition defects of such terminus mutations. These mutations are named "SEM" for suppression of ends mutations. All of the SEM mutations suppress more than a single terminus mutation and thus are not simple alterations of transposase/end recognition specificity. The mutations identified fall into two classes on the basis of genetic tests, location within the protein and nature of the amino acid substitution. Class I mutations, which are somewhat allele specific, appear to define a small structural and functional domain of transposase in which hydrophobic interactions are important at an intermediate stage of the transposition reaction, after an effective interaction between the ends but before transposon excision. Class II mutations, which are more general in their effects, occur at a single residue in a small noncritical amino-terminal proteolytic domain of transposase and exert their affects by altering a charge interaction; these mutations may affect act early in the reaction, before or during establishment of an effective interaction between the ends.     

Infrequent transposition of Ac in lettuce, Lactuca sativa

The maize transposable element Activator (Ac) is being used to develop a transposon mutagenesis system in lettuce, Lactuca sativa. Two constructs containing the complete Ac from the waxy-m7 locus of maize were introduced into lettuce and monitored for activity using Southern analysis and PCR amplification of the excision site. No transposition of Ac was detected in over 32 transgenic R1 plants, although these constructs were known to provide frequent transposition in other species. Also, no transposition was observed in later generations. In subsequent experiments, transposition was detected in lettuce calli using constructs that allowed selection for excision events. In these constructs, the neomycin phosphotransferase II gene was interrupted by either Ac or Ds. Excision was detected as the ability of callus to grow on kanamycin. Synthesis of the transposase from the cDNA of Ac expressed from the T-DNA 2' promoter resulted in more frequent excision of Ds than was observed with the wild-type Ac. No excision was observed with Ds in the absence of the transposase. The excision events were confirmed by amplification of the excision site by PCR followed by DNA sequencing. Excision and reintegration were also confirmed by Southern analysis. Ac/Ds is therefore capable of transposition in at least calli of lettuce.     

Factors responsible for target site selection in Tn10 transposition: a role for the DDE motif in target DNA capture

Tn10, like several other transposons, exhibits a marked preference for integration into particular target sequences. Such sequences are referred to as integration hotspots and have been used to define a consensus target site in Tn10 transposition. We demonstrate that a Tn10 hotspot called HisG1, which was identified originally in vivo, also functions as an integration hotspot in vitro in a reaction where the HisG1 sequence is present on a short DNA oligomer. We use this in vitro system to define factors which are important for the capture of the HisG1 target site. We demonstrate that although divalent metal ions are not essential for HisG1 target capture, they greatly facilitate capture of a mutated HisG1 site. Analysis of catalytic transposase mutants further demonstrates that the DDE motif plays a critical role in 'divalent metal ion-dependent' target capture. Analysis of two other classes of transposase mutants, Exc+ Int- (which carry out transposon excision but not integration) and ATS (altered target specificity), demonstrates that while a particular ATS transposase binds HisG1 mutants better than wild-type transposase, Exc+ Int- mutants are defective in HisG1 capture, further defining the properties of these classes of mutants. Possible mechanisms for the above observations are considered.     

Imprecise excision of the Caenorhabditis elegans transposon Tc1 creates functional 5' splice sites

Imprecise excision of the Caenorhabditis elegans transposon Tc1 from a specific site of insertion within the unc-54 myosin heavy chain gene generates either wild-type or partial phenotypic revertants. Wild-type revertants and one class of partial revertants contain insertions of four nucleotides in the unc-54 third exon (Tc1 "footprints"). Such revertants express large amounts of functional unc-54 myosin despite having what would appear to be frameshifting insertions in the unc-54 third exon. We demonstrate that these Tc1 footprints act as efficient 5' splice sites for removal of the unc-54 third intron. Splicing of these new 5' splice sites to the normal third intron splice acceptor removes the Tc1 footprint from the mature mRNA and restores the normal translational reading frame. Partial revertant unc-54(r661), which contains a single nucleotide substitution relative to the wild-type gene, is spliced similarly, except that the use of its new 5' splice site creates a frameshift in the mature mRNA rather than removing one. In all of these revertants, two alternative 5' splice sites are available to remove intron 3. We determined the relative efficiency with which each alternative 5' splice site is used by stabilizing frameshifted mRNAs with smg(-) genetic backgrounds. In all cases, the upstream member of the two alternative sites is used preferentially (> 75% utilization). This may reflect an inherent preference of the splicing machinery for the upstream member of two closely spaced 5' splice sites. Creation of new 5' splice sites may be a general characteristic of Tc1 insertion and excision events.     

Reduced germline mobility of a mariner vector containing exogenous DNA: effect of size or site?

Germline mobilization of the transposable element mariner is severely inhibited by the insertion of a 4.5- to 11.9-kb fragment of exogenous DNA into a unique SacI site approximately in the middle of the 1286-bp element. In the presence of transposase driven by the germline-specific hsp26-sgs3 promoter, mobilization of the MlwB construct (containing a 11.9-kb insertion) is detected at low frequency. Analysis of a mobilized MlwB element indicated that mobilization is mediated by the mariner transposase. However, transposed MlwB elements are also defective in germline mobilization. Rare, transposase-induced germline excision events were also recovered for such vectors. The estimated rate of excision is < 0.1% per chromosome per generation. Excision appears to be accompanied by gap repair if a suitable template is available. The data imply that the reduced mobility of mariner vectors with exogenous DNA in the SacI site results from disruption of sequences necessary for efficient mobilization. The relative stability may be a valuable property in the uses of mariner-like elements in genetic engineering of insects of economic importance.     

Delayed development of hypertension after short-term nitrendipine treatment

In its natural host, Bacillus thuringiensis, the insertion sequence IS231A is preferentially inserted into the terminal inverted repeats of the transposon Tn4430. Using a novel transposition assay, we demonstrate that the Tn4430 ends behave as insertion hot spots for IS231A in Escherichia coli. Sequence analysis reveals that IS231A insertion sites match the 5'-GGG(N)5CCC-3' consensus. However, this consensus is not the only determinant of IS231A insertion specificity. Although both Tn4430 ends have identical sequences, one is strongly preferred to the other and the orientation of insertion into this end is not random. We demonstrate that this preference is determined by the flanking regions of the site. These regions display a conserved periodic organization of their sequence which, by conferring anisotropic flexibility, would induce the DNA to bend in a roughly 'S'-shaped structure centered on the target consensus. DNA conformation analysis by polyacrylamide gel electrophoresis indeed shows that the preferred target site of IS231A is flanked by DNA segments curved in opposite directions. We present a model in which DNA bendability and curvature would contribute to the positioning of IS231A transposase on the target DNA.     

Prevalence of localized rearrangements vs. transpositions among events induced by Drosophila P element transposase on a P transgene

We have studied P transposase-induced events on a P[w] transgene, P[wd1], harboring the whole white gene with a 3.44-kb direct duplication of its 5' regulatory sequences (containing the ZESTE-binding region, ZBR). We have recovered mutations leading to an increase or a decrease of zeste1 repression, generally as the consequence of modifications of number of ZBR in close physical proximity and/or jumps to other sites. We describe mutants displaying deletions of the original duplicated sequence or increases in the number of repeats from two to three or four. Internal deletions are more frequent than amplifications. Both require the integrity of P-element ends. We have also observed a high frequency of double P elements localized at the original P[wd1] insertion site. These double P elements are arranged in nonrandom configurations. We discuss the frequencies and the possible mechanisms leading to the various types of derivatives, in light of the current models for P excision and transposition. We propose that the P transposase induces mainly localized events. Some of these could result from frequent changes of template during gap-repair DNA synthesis, and/or from abortive transposition.     

Division of labor among monomers within the Mu transposase tetramer

A single tetramer of Mu transposase (MuA) pairs the recombination sites, cleaves the donor DNA, and joins these ends to a target DNA by strand transfer. Analysis of C-terminal deletion derivatives of MuA reveals that a 30 amino acid region between residues 575 and 605 is critical for these three steps. Although inactive on its own, a deletion protein lacking this region assembles with the wild-type protein. These mixed tetramers carry out donor cleavage but do not promote strand transfer, even when the donor cleavage stage is bypassed. These data suggest that the active center of the transposase is composed of the C-terminus of four MuA monomers; one dimer carries out donor cleavage while all four monomers contribute to strand transfer.     

Functional characterization of the Tn5 transposase by limited proteolysis

The 476 amino acid Tn5 transposase catalyzes DNA cutting and joining reactions that cleave the Tn5 transposon from donor DNA and integrate it into a target site. Protein-DNA and protein-protein interactions are important for this tranposition process. A truncated transposase variant, the inhibitor, decreases transposition rates via the formation of nonproductive complexes with transposase. Here, the inhibitor and the transposase are shown to have similar secondary and tertiary folding. Using limited proteolysis, the transposase has been examined structurally and functionally. A DNA binding region was localized to the N-terminal 113 amino acids. Generally, the N terminus of transposase is sensitive to proteolysis but can be protected by DNA. Two regions are predicted to contain determinants for protein-protein interactions, encompassing residues 114-314 and 441-476. The dimerization regions appear to be distinct and may have separate functions, one involved in synaptic complex formation and one involved in nonproductive multimerization. Furthermore, predicted catalytic regions are shown to lie between major areas of proteolysis.     

Extensive, nonrandom diversity of excision footprints generated by Ds-like transposon Ascot-1 suggests new parallels with V(D)J recombination

Upon insertion, transposable elements can disrupt or alter gene function in various ways. Transposons moving through a cut-and-paste mechanism are in addition often mutagenic when excising because repair of the empty site seldom restores the original sequence. The characterization of numerous excision events in many eukaryotes indicates that transposon excision from a given site can generate a high degree of DNA sequence and phenotypic variation. Whether such variation is generated randomly remains largely to be determined. To this end, we have exploited a well-characterized system of genetic instability in the fungus Ascobolus immersus to perform an extensive study of excision events. We show that this system, which produces many phenotypically and genetically distinct derivatives, results from the excision of a novel Ds-like transposon, Ascot-1, from the spore color gene b2. A unique set of 48 molecularly distinct excision products were readily identified from a representative sample of excision derivatives. Products varied in their frequency of occurrence over 4 orders of magnitude, yet most showed small palindromic nucleotide additions. Based on these and other observations, compelling evidence was obtained for intermediate hairpin formation during the excision reaction and for strong biases in the subsequent processing steps at the empty site. Factors likely to be involved in these biases suggest new parallels between the excision reaction performed by transposons of the hAT family and V(D)J recombination. An evaluation of the contribution of small palindromic nucleotide additions produced by transposon excision to the spectrum of spontaneous mutations is also presented.     

Simple and efficient generation in vitro of nested deletions and inversions: Tn5 intramolecular transposition

We have exploited the intramolecular transposition preference of the Tn 5 in vitro transposition system to test its effectiveness as a tool for generation of nested families of deletions and inversions. A synthetic transposon was constructed containing an ori, an ampicillin resistance (Ampr) gene, a multi-cloning site (MCS) and two hyperactive end sequences. The donor DNA that adjoins the transposon contains a kanamycin resistance (Kanr) gene. Any Amprreplicating plasmid that has undergone a transposition event (Kans) will be targeted primarily to any insert in the MCS. Two different size targets were tested in the in vitro system. Synthetic transposon plasmids containing either target were incubated in the presence of purified transposase (Tnp) protein and transformed. Transposition frequencies (Ampr/Kans) for both targets were found to be 30-50%, of which >95% occur within the target sequence, in an apparently random manner. By a conservative estimate 10(5) or more deletions/inversions within a given segment of DNA can be expected from a single one-step 20 microl transposition reaction. These nested deletions can be used for structure-function analysis of proteins and for sequence analysis. The inversions provide nested sequencing templates of the opposite strand from the deletions.     

Target choice and orientation preference of the insertion sequence IS903

We have examined the targeting preference of the bacterial insertion element IS903 by determining the sites of insertion of a large number of transposition events into the 55-kb conjugative plasmid pOX38. Despite the large target size, all the insertions were clustered in four small distinct regions associated with conjugal DNA transfer. Within these regions, many different sites were used for insertion; however, there were a few sites that IS903 inserted into more than once. Alignment of the insertion sites showed that there was no consensus sequence within the 9-bp target duplication but that there were preferred sequences located symmetrically on either side of the target. This is consistent with target recognition by a dimer or multimer of transposase, with either sequence-specific or structure-specific interactions on both sides of the target. We show further that when one of these preferred regions was cloned into a second conjugative plasmid, pUB307, it was still a preferred target, implying that all the sequences necessary for target selection are contained within this DNA segment. Also, we observed a very strong preference for insertion in a single orientation in pUB307. We examined the possibility that either DNA replication from the origin of vegetative replication, oriV, or the origin of transfer, oriT, might determine this orientation effect. We find that reversing the direction of vegetative replication had no effect on the orientation of transposon insertions; however, reversing the direction of DNA transfer abolished the orientation effect. This supports the idea that conjugal DNA transfer imparts a polarity on the target that is sensed by the transposon.     

Negative and positive regulation of Tn10/IS10-promoted recombination by IHF: two distinguishable processes inhibit transposition off of multicopy plasmid replicons and activate chromosomal events that favor evolution of new transposons

Tn10 is a composite transposon; inverted repeats of insertion sequence IS10 flank a tetracycline-resistance determinant. Previous work has identified several regulatory processes that modulate the interaction between Tn10 and its host. Among these, host-specified DNA adenine methylation, an IS10-encoded antisense RNA and preferential cis action of transposase are particularly important. We now find that the accessory host protein IHF and the sequences that encode the IHF-binding site in IS10 are also important regulators of the Tn10 transposition reaction in vivo and that these determinants are involved in two distinguishable regulatory processes. First, IHF and the IHF-binding site of IS10, together with other host components (e.g., HU), negatively regulate the normal intermolecular transposition process. Such negative regulation is prominent only for elements present on multicopy plasmid replicons. This multicopy plasmid-specific regulation involves effects both on the transposition reaction per se and on transposase gene expression. Second, specific interaction of IHF with its binding site stimulates transposon-promoted chromosome rearrangements but not transposition of a short Tn10-length chromosomal element. However, additional considerations predict that IHF action should favor chromosomal transposition for very long composite elements. On the basis of these and other observations we propose that, for chromosomal events, the major role of IHF is to promote the evolution of new IS10-based composite transposons.     

Tn5 in vitro transposition

This communication reports the development of an efficient in vitro transposition system for Tn5. A key component of this system was the use of hyperactive mutant transposase. The inactivity of wild type transposase is likely to be related to the low frequency of in vivo transposition. The in vitro experiments demonstrate the following: the only required macromolecules for most of the steps in Tn5 transposition are the transposase, the specific 19-bp Tn5 end sequences, and target DNA; transposase may not be able to self-dissociate from product DNAs; Tn5 transposes by a conservative "cut and paste" mechanism; and Tn5 release from the donor backbone involves precise cleavage of both 3' and 5' strands at the ends of the specific end sequences.     

DNA binding by the Xis protein of the conjugative transposon Tn916

We purified the Xis protein of the conjugative transposon Tn916 and showed by nuclease protection experiments that Xis bound specifically to sites close to each end of Tn916. These specific binding sites are close to, and in the same relative orientation to, binding sites for the N-terminal domain of Tn916 integrase protein. These results suggest that Xis is involved in the formation of nucleoprotein structures at the ends of Tn916 that help to correctly align the ends so that excision can occur.