Tn5 in vitro transposition

Identification of ZipA, a signal recognition particle-dependent protein from Neisseria gonorrhoeae

A genetic screen designed to identify proteins that utilize the signal recognition particle (SRP) for targeting in Escherichia coli was used to screen a Neisseria gonorrhoeae plasmid library. Six plasmids were identified in this screen, and each is predicted to encode one or more putative cytoplasmic membrane (CM) proteins. One of these, pSLO7, has three open reading frames (ORFs), two of which have no similarity to known proteins in GenBank other than sequences from the closely related N. meningitidis. Further analyses showed that one of these, SLO7ORF3, encodes a protein that is dependent on the SRP for localization. This gene also appears to be essential in N. gonorrhoeae since it was not possible to generate null mutations in the gene. Although appearing unique to Neisseria at the DNA sequence level, SLO7ORF3 was found to share some features with the cell division gene zipA of E. coli. These features included similar chromosomal locations (with respect to linked genes) as well as similarities in the predicted protein domain structures. Here, we show that SLO7ORF3 can complement an E. coli conditional zipA mutant and therefore encodes a functional ZipA homolog in N. gonorrhoeae. This observation is significant in that it is the first ZipA homolog identified in a non-rod-shaped organism. Also interesting is that this is the fourth cell division protein (the others are FtsE, FtsX, and FtsQ) shown to utilize the SRP for localization, which may in part explain why the genes encoding the three SRP components are essential in bacteria.

Tn5 as a model for understanding DNA transposition

Tn5 is an excellent model system for understanding the molecular basis of DNA-mediated transposition. Mechanistic information has come from genetic and biochemical investigations of the transposase and its interactions with the recognition DNA sequences at the ends of the transposon. More recently, molecular structure analyses of catalytically active transposase; transposon DNA complexes have provided us with unprecedented insights into this transposition system. Transposase initiates transposition by forming a dimeric transposase, transposon DNA complex. In the context of this complex, the transposase then catalyses four phosphoryl transfer reactions (DNA nicking, DNA hairpin formation, hairpin resolution and strand transfer into target DNA) resulting in the integration of the transposon into its new DNA site. The studies that elucidated these steps also provided important insights into the integration of retroviral genomes into host DNA and the immune system V(D)J joining process. This review will describe the structures and steps involved in Tn5 transposition and point out a biologically important although surprising characteristic of the wild-type Tn5 transposase. Transposase is a very inactive protein. An inactive transposase protein ensures the survival of the host and thus the survival of Tn5.

Tn5 transposase active site mutations suggest position of donor backbone DNA in synaptic complex

Tn5 transposase (Tnp), a 53.3-kDa protein, enables the movement of transposon Tn5 by a conservative mechanism. Within the context of a protein and DNA synaptic complex, a single Tnp molecule catalyzes four sequential DNA breaking and joining reactions at the end of a single transposon. The three amino acids of the DDE motif (Asp-97, Asp-188, and Glu-326), which are conserved among transposases and retroviral integrases, have been shown previously to be absolutely required for all catalytic steps. To probe the effect of active site geometry on the ability to form synaptic complexes and perform catalysis, single mutations at each position of the DDE motif were constructed. The aspartates were changed to glutamates, and the glutamate was changed to an aspartate. These mutants were studied by performing in vitro binding assays using short oligonucleotide substrates simulating the natural substrates for the synaptic complex formation and subsequent transposition steps. The results indicate that the aspartate to glutamate mutations restrict synaptic complex formation with substrates resembling the natural transposon prior to transferred strand nicking. This suggests a structural model in which the donor backbone DNA, prior to nicking, occupies the same space that is invaded by the longer side chains present in the aspartate to glutamate mutants. Additionally, catalytic assays support the previous proposal that the active site coordinates two divalent metal ions.

A direct transposon insertion tool for modification and functional analysis of viral genomes

Advances in DNA transposition technology have recently generated efficient tools for various types of functional genetic analyses. We demonstrate here the power of the bacteriophage Mu-derived in vitro DNA transposition system for modification and functional characterization of a complete bacterial virus genome. The linear double-stranded DNA genome of Escherichia coli bacteriophage PRD1 was studied by insertion mutagenesis with reporter mini-Mu transposons that were integrated in vitro into isolated genomic DNA. After introduction into bacterial cells by electroporation, recombinant transposon-containing virus clones were identified by autoradiography or visual blue-white screening employing alpha-complementation of E. coli beta-galactosidase. Additionally, a modified transposon with engineered NotI sites at both ends was used to introduce novel restriction sites into the phage genome. Analysis of the transposon integration sites in the genomes of viable recombinant phage generated a functional map, collectively indicating genes and genomic regions essential and nonessential for virus propagation. Moreover, promoterless transposons defined the direction of transcription within several insert-tolerant genomic regions. These strategies for the analysis of viral genomes are of a general nature and therefore may be applied to functional genomics studies in all prokaryotic and eukaryotic cell viruses.

Establishment of uncharacterized plasmids in Escherichia coli by in vitro transposition

We present a simple approach that permits any circular plasmid, such as uncharacterized plasmids from diverse prokaryotes, to be established in Escherichia coli, thereby facilitating subsequent structural and functional studies. An in vitro transposition reaction is used to introduce a well-characterized replicon and selectable marker into purified plasmids, which are then used to transform E. coli. The approach was demonstrated using a small 3.4-kb archaeal plasmid and a large 60-kb uncharacterized plasmid from a Gram-negative bacterium. Replicon function in E. coli was tested for each plasmid, and direct sequencing of the large plasmid revealed similarity to restriction-modification systems.

Production of combinatorial libraries of fused genes by sequential transposition reactions

The use of in vivo and in vitro transposition reactions to perform non-combinatorial manipulation of DNAs in molecular biology is widespread. In this work we describe a technique that utilizes two sequential, directed transposition reactions in order to carry out combinatorial DNA manipulations. The methodology relies on the use of two different mutant Tn5 transposase proteins that have different transposon end recognition specificities. We demonstrate that the technique can be used to create large libraries of random fusions between two genes. These transpositional fusions are defined by insertion of a 32 bp linker sequence. We applied the technique to a model system, chloramphenicol acetyl transferase, to create functional fusions from N- and C-terminally truncated, non-functional genes. Comparative structural analysis suggests that both sides of the linker are inserted into disordered regions in functional proteins.

Construction and characterization of transposon insertion mutations in Corynebacterium diphtheriae that affect expression of the diphtheria toxin repressor (DtxR)

Transcription of the bacteriophage-borne diphtheria toxin gene tox is negatively regulated, in response to intracellular Fe(2+) concentration, by the chromosomally encoded diphtheria toxin repressor (DtxR). Due to a scarcity of tools, genetic analysis of Corynebacterium diphtheriae has primarily relied on analysis of chemically induced and spontaneously occurring mutants and on the results of experiments with C. diphtheriae genes cloned in Escherichia coli or analyzed in vitro. We modified a Tn5-based mutagenesis technique for use with C. diphtheriae, and we used it to construct the first transposon insertion libraries in the chromosome of this gram-positive pathogen. We isolated two insertions that affected expression of DtxR, one 121 bp upstream of dtxR and the other within an essential region of the dtxR coding sequence, indicating for the first time that dtxR is a dispensable gene in C. diphtheriae. Both mutant strains secrete diphtheria toxin when grown in medium containing sufficient iron to repress secretion of diphtheria toxin by wild-type C. diphtheriae. The upstream insertion mutant still produces DtxR in decreased amounts and regulates siderophore secretion in response to iron in a manner similar to its wild-type parent. The mutant containing the transposon insertion within dtxR does not produce DtxR and overproduces siderophore in the presence of iron. Differences in the ability of the two mutant strains to survive oxidative stress also indicated that the upstream insertion retained slight DtxR activity, whereas the insertion within dtxR abolished DtxR activity. This is the first evidence that DtxR plays a role in protecting the cell from oxidative stress.

Common physical properties of DNA affecting target site selection of sleeping beauty and other Tc1/mariner transposable elements

Sleeping Beauty (SB) is the most active Tc1/mariner-type transposable element in vertebrates, and is therefore a valuable vector for transposon mutagenesis in vertebrate models and for human gene therapy. We have analyzed factors affecting target site selection of SB in mammalian cells, by generating transposition events from extrachromosomal plasmids to chromosomes. In contrast to the local hopping observed when transposition is induced from a chromosomal context, mapping of 138 unique SB insertions on human chromosomes showed a fairly random genomic distribution, and a 35% occurrence of transposition into genes. Inspection of the DNA flanking the sites of element integration revealed significant differences from random DNA in both primary sequence and physical properties. The consensus sequence of SB target sites was found to be a palindromic AT-repeat, ATATATAT, in which the central TA is the canonical target site. We found however, that target site selection is determined primarily on the level of DNA structure, and not by specific base-pair interactions. Computational analyses revealed that insertion sites tend to have a bendable structure and a palindromic pattern of potential hydrogen-bonding sites in the major groove of the DNA. These features appear conserved in the Tc1/mariner family of transposons and in other, distantly related elements that share a common catalytic domain of the transposase, and integrate fairly randomly. No similar target site preference was found for non-randomly integrating elements. Our results suggest common factors influencing target site selection of a wide range of transposable elements.

Evidence for "unseen" transposase--DNA contacts

In this study, evidence of novel, important interactions between a hyperactive Tn5 transposon recognition end sequence and hyperactive Tn5 transposase (Tnp) are presented. A hyperactive Tn5 end sequence, the mosaic end (ME), was isolated previously. The ME and a wild-type end sequence, the outside end (OE), differ at only three positions, yet transposition on the ME is tenfold higher than on the OE in vivo. Also, transposition on the ME is much more efficient than transposition on the OE in vitro. Here, we show that the decreased activity observed for the OE is caused by a defect in paired ends complex (PEC) formation resulting from the orientation of the A-T base-pair at position 4 of this end. Efficient PEC formation requires an interaction between the C5-methyl group (C5-Me) on the non-transferred strand thymine base at position 4 (T4) and Tnp. PEC formation on nicked substrates is much less affected by the orientation of the A-T base-pair at position 4, indicating that the C5-Me group is important only for steps preceding nicking. A recently determined co-crystal structure of Tn5 Tnp with the ME is discussed and a model explaining possible roles for the base-pair at position 4 is explored.

Development of an in vitro integration assay for the Bacteroides conjugative transposon CTnDOT

Integrated self-transmissible elements called conjugative transposons (CTns) are responsible for the transfer of antibiotic resistance genes in many different species of bacteria. One of the best characterized of these newly recognized elements is the Bacteroides CTn, CTnDOT. CTnDOT is thought to have a circular transfer intermediate that transfers to and integrates into the genome of the recipient cell. Previous investigations of the mechanism of CTnDOT integration have been hindered by the lack of an in vitro system for checking this model of integration and determining whether the CTnDOT integrase alone was sufficient to catalyze the integration reaction or whether host factors might be involved. We report here the development of an in vitro system in which a plasmid containing the joined ends of CTnDOT integrates into a plasmid carrying a CTnDOT target site. To develop this in vitro system, a His-tagged version of the integrase gene of CTnDOT was cloned and shown to be active in vivo. The protein produced by this construct was partially purified and then added to a reaction mixture that contained the joined ends of the circular form of CTnDOT and a plasmid carrying one of the CTnDOT target sites. Integration was demonstrated by using a fairly simple mixture of components, but integration was stimulated by a Bacteroides extract or by purified Escherichia coli integration host factor. The results of this study demonstrate both that the circular form of CTnDOT is the form that integrates into the target site and that host factors are involved in the integration process.

Prevotella intermedia native plasmid can be mobilized by an Escherichia coli conjugal IncP plasmid

We have determined the nucleotide sequence of a small Prevotella intermedia cryptic plasmid, pYHBi1, which consisted of sequences that were highly homologous to the amino acid sequence of the replication and mobilization proteins found in related organisms. We have also demonstrated that chimeric plasmids derived from this P. intermedia native plasmid can be mobilized between Escherichia coli strains by using a broad-host-range E. coli conjugative plasmid, IncP plasmid RP4. The results suggest that pYHBi1 possesses gene(s) responsible for conjugal transfer.

Rational identification of new antibacterial drug targets that are essential for viability using a genomics-based approach

In the last two decades, the search for completely novel antibacterial agents has acquired a new sense of urgency due to the remarkable rise of antibiotic resistance among key bacterial pathogens. More recently, the advent of bacterial genomics has provided investigators with the data and bioinformatic tools to rationally identify novel antibacterial targets and the genome-scaled methodologies to validate them. Only 6 years have elapsed since the publication of the first complete bacterial genome sequence, but more than 50 complete microbial genome sequences are now available. This review will discuss the advantages and limitations of the existing bacterial genome dataset for the rational identification of novel antibacterial targets. Since the ability to rapidly identify essential genes where loss of function is coincident with loss of viability is the most important task of genomics-based target validation, essentiality testing methodologies (in which molecular genetic techniques are used to determine whether or not a gene product is required for viability of the parent cell) will be surveyed and their amenability to genome-scaled analysis assessed. Finally, we will discuss the impact of bacterial genomics to date on the development of novel and effective antibiotics.

Functional analysis and regulation of the divergent spuABCDEFGH-spuI operons for polyamine uptake and utilization in Pseudomonas aeruginosa PAO1

A multiple-gene locus for polyamine uptake and utilization was discovered in Pseudomonas aeruginosa PAO1. This locus contained nine genes designated spuABCDEFGHI (spu for spermidine and putrescine utilization). The physiological functions of the spu genes in utilization of two polyamines (putrescine and spermidine) were analyzed by using Tn5 transposon-mediated spu knockout mutants. Growth and uptake experiments support that the spuDEFGH genes specify components of a major ABC-type transport system for spermidine uptake, and enzymatic measurements indicated that spuC encodes putrescine aminotransferase with pyruvate as the amino group receptor. Although spuA and spuB mutants showed an apparent defect in spermidine utilization, the biochemical functions of the gene products have yet to be elucidated. Assays of lacZ fusions demonstrated the presence of agmatine-, putrescine-, and spermidine-inducible promoters for the spuABCDEFGH operon and the divergently transcribed spuI gene of unknown function. Since the observed induction effect of agmatine was abolished in an aguA mutant where conversion of agmatine into putrescine was blocked, putrescine or spermidine, but not agmatine, serves as the inducer molecule of the spuA-spuI divergent promoters. S1 nuclease mappings confirmed further the induction effects of the polyamines on transcription of the divergent promoters and localized the transcription initiation sites. Gel retardation assays with extracts from the cells grown on putrescine or spermidine demonstrated the presence of a polyamine-responsive regulatory protein interacting with the divergent promoter region. Finally, the absence of the putrescine-inducible spuA expression and putrescine aminotransferase (spuC) formation in the cbrB mutant indicated that the spu operons are regulated by the global CbrAB two-component system perhaps via the putative polyamine-responsive transcriptional activator.

A new way to rapidly create functional, fluorescent fusion proteins: random insertion of GFP with an in vitro transposition reaction

BACKGROUND

The jellyfish green fluorescent protein (GFP) can be inserted into the middle of another protein to produce a functional, fluorescent fusion protein. Finding permissive sites for insertion, however, can be difficult. Here we describe a transposon-based approach for rapidly creating libraries of GFP fusion proteins.

RESULTS

We tested our approach on the glutamate receptor subunit, GluR1, and the G protein subunit, alphas. All of the in-frame GFP insertions produced a fluorescent protein, consistent with the idea that GFP will fold and form a fluorophore when inserted into virtually any domain of another protein. Some of the proteins retained their signaling function, and the random nature of the transposition process revealed permissive sites for insertion that would not have been predicted on the basis of structural or functional models of how that protein works.

CONCLUSION

This technique should greatly speed the discovery of functional fusion proteins, genetically encodable sensors, and optimized fluorescence resonance energy transfer pairs.

Systematic sequencing of cDNA clones using the transposon Tn5

In parallel with the production of genomic sequence data, attention is being focused on the generation of comprehensive cDNA-sequence resources. Such efforts are increasingly emphasizing the production of high-accuracy sequence corresponding to the entire insert of cDNA clones, especially those presumed to reflect the full-length mRNA. The complete sequencing of cDNA clones on a large scale presents unique challenges because of the generally small, yet heterogeneous, sizes of the cloned inserts. We have developed a strategy for high-throughput sequencing of cDNA clones using the transposon Tn5. This approach has been tailored for implementation within an existing large-scale 'shotgun-style' sequencing program, although it could be readily adapted for use in virtually any sequencing environment. In addition, we have developed a modified version of our strategy that can be applied to cDNA clones with large cloning vectors, thereby overcoming a potential limitation of transposon-based approaches. Here we describe the details of our cDNA-sequencing pipeline, including a summary of the experience in sequencing more than 4200 cDNA clones to produce more than 8 million base pairs of high-accuracy cDNA sequence. These data provide both convincing evidence that the insertion of Tn5 into cDNA clones is sufficiently random for its effective use in large-scale cDNA sequencing as well as interesting insight about the sequence context preferred for insertion by Tn5.

Tn5 transposase active site mutants

Tn5 transposase (Tnp) is a 53.3-kDa protein that is encoded by and facilitates movement of transposon Tn5. Tnp monomers contain a single active site that is responsible for catalyzing a series of four DNA breaking/joining reactions at one transposon end. Based on primary sequence homology and protein structural information, we designed and constructed a series of plasmids that encode for Tnps containing active site mutations. Following Tnp expression and purification, the active site mutants were tested for their ability to form protein-DNA complexes and perform each of the four catalytic steps in the transposition pathway in vitro. The results demonstrate that Asp-97, Asp-188, and Glu-326, visible in the active site of Tn5 crystal structures, are absolutely required for all catalytic steps. Mutations within a series of amino acid residues that are conserved in the IS4 family of transposases and retroviral integrases also impair Tnp catalytic activity. Mutations at either Tyr-319 or Arg-322 reduce both hairpin resolution and strand transfer activity within protein-DNA complexes. Mutations at Lys-333 reduce the ability of Tnps to form protein-DNA complexes, whereas mutations at the less strongly conserved Lys-330 have less of an effect on both synaptic complex formation and catalytic activity.

SGS1 is a multicopy suppressor of srs2: functional overlap between DNA helicases

Sgs1 is a member of the RecQ family of DNA helicases, which have been implicated in genomic stability, cancer and ageing. Srs2 is another DNA helicase that shares several phenotypic features with Sgs1 and double sgs1srs2 mutants have a severe synthetic growth phenotype. This suggests that there may be functional overlap between these two DNA helicases. Consistent with this idea, we found the srs2Delta mutant to have a similar genotoxin sensitivity profile and replicative lifespan to the sgs1Delta mutant. In order to directly test if Sgs1 and Srs2 are functionally interchangeable, the ability of high-copy SGS1 and SRS2 plasmids to complement the srs2Delta and sgs1Delta mutants was assessed. We report here that SGS1 is a multicopy suppressor of the methyl methanesulphonate (MMS) and hydroxyurea sensitivity of the srs2Delta mutant, whereas SRS2 overexpression had no complementing ability in the sgs1Delta mutant. Domains of Sgs1 directly required for processing MMS-induced DNA damage, most notably the helicase domain, are also required for complementation of the srs2Delta mutant. Although SGS1 overexpression was unable to rescue the shortened mean replicative lifespan of the srs2Delta mutant, maximum lifespan was significantly increased by multicopy SGS1. We conclude that Sgs1 is able to partially compensate for the loss of Srs2.

Efficient insertion mutagenesis strategy for bacterial genomes involving electroporation of in vitro-assembled DNA transposition complexes of bacteriophage mu

An efficient insertion mutagenesis strategy for bacterial genomes based on the phage Mu DNA transposition reaction was developed. Incubation of MuA transposase protein with artificial mini-Mu transposon DNA in the absence of divalent cations in vitro resulted in stable but inactive Mu DNA transposition complexes, or transpososomes. Following delivery into bacterial cells by electroporation, the complexes were activated for DNA transposition chemistry after encountering divalent metal ions within the cells. Mini-Mu transposons were integrated into bacterial chromosomes with efficiencies ranging from 10(4) to 10(6) CFU/microg of input transposon DNA in the four species tested, i.e., Escherichia coli, Salmonella enterica serovar Typhimurium, Erwinia carotovora, and Yersinia enterocolitica. Efficiency of integration was influenced mostly by the competence status of a given strain or batch of bacteria. An accurate 5-bp target site duplication flanking the transposon, a hallmark of Mu transposition, was generated upon mini-Mu integration into the genome, indicating that a genuine DNA transposition reaction was reproduced within the cells of the bacteria studied. This insertion mutagenesis strategy for microbial genomes may be applicable to a variety of organisms provided that a means to introduce DNA into their cells is available.

Transposable dual reporters for studying the structure-function relationships in membrane proteins: permissive sites in R. prowazekii ATP/ADP translocase

A new approach to studying membrane topology and permissive sites in membrane proteins expressed in Escherichia coli is described. The method is based on in vitro transposition of mini-Tn5 derivatives bearing dual pho-lac reporters [Alexeyev, M. F., and Winkler, H. H. (1999) J. Mol. Biol. 285, 1503-1513]. Two mini-Tn5 transposons, Tnpholac1 and Tnpholac2, were designed in such a way that their insertions can be converted either by restriction-ligation or by in vivo Cre-lox recombination into either sandwich reporter fusions or short amino acid (aa) tags (25 or 42 aa long). A set of 48 unique insertions in the gene coding for the Rickettsia prowazekii ATP/ADP translocase (Tlc) was generated using Tnpholac2. The topological information generated by these insertions was found in to be in good agreement with the existing topological model. Subsequently, these insertions were converted into both 25 and 42 aa tags, and the activity of the resulting mutants was determined. Also, site-directed mutagenesis was used to construct insertions in the loops, where no transposon hops were discovered. Of 13 extramembrane domains in Tlc, only 3 (loops 7, 10, and 13) were found to be permissive, which is in marked contrast to previous observations in the E. coli lactose permease (LacY), where most insertions in extramembrane domains were demonstrated to be permissive. The permissiveness of the insertion after I368 in TM IX lead us to reconsider the boundaries for this TM by placing I368 on the interface between TM IX and loop 10. Interestingly, the 25 aa insertions consistently have 2-fold higher activity than the corresponding 42 aa insertions, which is also in contrast with observations made on LacY. Finally, in this study we report, for the first time, the frequency of 10 base pair target duplications generated by in vitro Tn5 transposition.

Tn5 transposase with an altered specificity for transposon ends

Tn5 is a composite bacterial transposon that encodes a protein, transposase (Tnp), required for movement of the transposon. The initial step in the transposition pathway involves specific binding of Tnp to 19-bp end recognition sequences. Tn5 contains two different specific end sequences, termed outside end (OE) and inside end (IE). In Escherichia coli, IE is methylated by Dam methylase (IE(ME)). This methylation greatly inhibits recognition by Tnp and greatly reduces the ability of transposase to facilitate movement of IE defined transposons. Through use of a combinatorial random mutagenesis technique (DNA shuffling), we have isolated an IE(ME)-specific hyperactive form of Tnp, Tnp sC7v.2.0, that is able to promote high levels of transposition of IE(ME) defined transposons in vivo and in vitro while functioning at wild-type levels with OE transposons. This protein contains a critical glutamate-to-valine mutation at amino acid 58 that is responsible for this change in end specificity.

Finishing a whole-genome shotgun: release 3 of the Drosophila melanogaster euchromatic genome sequence

BACKGROUND

The Drosophila melanogaster genome was the first metazoan genome to have been sequenced by the whole-genome shotgun (WGS) method. Two issues relating to this achievement were widely debated in the genomics community: how correct is the sequence with respect to base-pair (bp) accuracy and frequency of assembly errors? And, how difficult is it to bring a WGS sequence to the accepted standard for finished sequence? We are now in a position to answer these questions.

RESULTS

Our finishing process was designed to close gaps, improve sequence quality and validate the assembly. Sequence traces derived from the WGS and draft sequencing of individual bacterial artificial chromosomes (BACs) were assembled into BAC-sized segments. These segments were brought to high quality, and then joined to constitute the sequence of each chromosome arm. Overall assembly was verified by comparison to a physical map of fingerprinted BAC clones. In the current version of the 116.9 Mb euchromatic genome, called Release 3, the six euchromatic chromosome arms are represented by 13 scaffolds with a total of 37 sequence gaps. We compared Release 3 to Release 2; in autosomal regions of unique sequence, the error rate of Release 2 was one in 20,000 bp.

CONCLUSIONS

The WGS strategy can efficiently produce a high-quality sequence of a metazoan genome while generating the reagents required for sequence finishing. However, the initial method of repeat assembly was flawed. The sequence we report here, Release 3, is a reliable resource for molecular genetic experimentation and computational analysis.

New Mos1 mariner transposons suitable for the recovery of gene fusions in vivo and in vitro

The Drosophila Mos1 element can be mobilized in species ranging from prokaryotes to protozoans and vertebrates, and the purified transposase can be used for in vitro transposition assays. In this report we developed a 'mini-Mos1' element and describe a number of useful derivatives suitable for transposon mutagenesis in vivo or in vitro. Several of these allow the creation and/or selection of tripartite protein fusions to a green fluorescent protein-phleomycin resistance (GFP-PHLEO) reporter/selectable marker. Such X-GFP-PHLEO-X fusions have the advantage of retaining 5' and 3' regulatory information and N- and C-terminal protein targeting domains. A Mos1 derivative suitable for use in transposon-insertion mediated linker insertion (TIMLI) mutagenesis is described, and transposons bearing selectable markers suitable for use in the protozoan parasite Leishmania were made and tested. A novel 'negative selection' approach was developed which permits in vitro assays of transposons lacking bacterial selectable markers. Application of this assay to several Mos1 elements developed for use in insects suggests that the large mariner pM[cn] element used previously in vivo is poorly active in vitro, while the Mos1-Act-EGFP transposon is highly active.

An in vitro transposon system for highly regulated gene expression: construction of Escherichia coli strains with arabinose-dependent growth at low temperatures

Placing a gene of interest under the control of an inducible promoter greatly aids the purification, localization and functional analysis of proteins but usually requires the sub-cloning of the gene of interest into an appropriate expression vector. Here, we describe an alternative approach employing in vitro transposition of Tn Omega P(BAD) to place the highly regulable, arabinose inducible P(BAD) promoter upstream of the gene to be expressed. The method is rapid, simple and facilitates the optimization of expression by producing constructs with variable distances between the P(BAD) promoter and the gene. To illustrate the use of this approach, we describe the construction of a strain of Escherichia coli in which growth at low temperatures on solid media is dependent on threshold levels of arabinose. Other uses of the transposable promoter are also discussed.

Molecular characterization and regulation of the aguBA operon, responsible for agmatine utilization in Pseudomonas aeruginosa PAO1

Pseudomonas aeruginosa PAO1 utilizes agmatine as the sole carbon and nitrogen source via two reactions catalyzed successively by agmatine deiminase (encoded by aguA; also called agmatine iminohydrolase) and N-carbamoylputrescine amidohydrolase (encoded by aguB). The aguBA and adjacent aguR genes were cloned and characterized. The predicted AguB protein (M(r) 32,759; 292 amino acids) displayed sequence similarity (< or =60% identity) to enzymes of the beta-alanine synthase/nitrilase family. While the deduced AguA protein (M(r) 41,190; 368 amino acids) showed no significant similarity to any protein of known function, assignment of agmatine deiminase to AguA in this report discovered a new family of carbon-nitrogen hydrolases widely distributed in organisms ranging from bacteria to Arabidopsis. The aguR gene encoded a putative regulatory protein (M(r) 24,424; 221 amino acids) of the TetR protein family. Measurements of agmatine deiminase and N-carbamoylputrescine amidohydrolase activities indicated the induction effect of agmatine and N-carbamoylputrescine on expression of the aguBA operon. The presence of an inducible promoter for the aguBA operon in the aguR-aguB intergenic region was demonstrated by lacZ fusion experiments, and the transcription start of this promoter was localized 99 bp upstream from the initiation codon of aguB by S1 nuclease mapping. Experiments with knockout mutants of aguR established that expression of the aguBA operon became constitutive in the aguR background. Interaction of AguR overproduced in Escherichia coli with the aguBA regulatory region was demonstrated by gel retardation assays, supporting the hypothesis that AguR serves as the negative regulator of the aguBA operon, and binding of agmatine and N-carbamoylputrescine to AguR would antagonize its repressor function.

Mutagenesis in the post genomics era: tools for generating insertional mutations in the lactic acid bacteria

The increasing availability of whole genome sequences has increased the demand for effective tools to generate insertional mutations in the lactic acid bacteria (LAB). Several novel approaches, such as shuttle-, transposome- and intron-based mutagenesis methods, are possible additions to the existing repertoire of transposon- and recombination-based tools available for mutagenesis of LAB.

Functional characterization of arginine 30, lysine 40, and arginine 62 in Tn5 transposase

Three N-terminal basic residues of Tn5 transposase, which are associated with proteolytic cleavages by Escherichia coli proteinases, were mutated to glutamine residues with the goal of producing more stable transposase molecules. Mutation of either arginine 30 or arginine 62 to glutamine produced transposase molecules that were more stable toward E. coli proteinases than the parent hyperactive Tn5 transposase, however, they were inactive in vivo. In vitro analysis revealed these mutants were inactive, because both Arg(30) and Arg(62) are required for formation of the paired ends complexes when the transposon is attached to the donor backbone. These results suggest Arg(30) and Arg(62) play critical roles in DNA binding and/or synaptic complex formation. Mutation of lysine 40 to glutamine did not increase the overall stability of the transposase to E. coli proteinases. This mutant transposase was only about 1% as active as the parent hyperactive transposase in vivo; however, it retained nearly full activity in vitro. These results suggest that lysine 40 is important for a step in the transposition mechanism that is bypassed in the in vitro assay system, such as the removal of the transposase molecule from DNA following strand transfer.

Tipping the balance between replicative and simple transposition

The bacterial insertion sequence IS903 has the unusual ability to transpose both replicatively and non-replicatively. The majority of products are simple insertions, while co-integrates, the product of replicative transposition, occur at a low frequency (<0.1% of simple insertions). In order to define the critical steps that determine the outcome of IS903 transposition, we have isolated mutants that specifically increase the rate of replicative transposition. Here we show that the nucleotide immediately flanking the transposon influences both overall transposition frequency and co-integrate formation. In particular, when the 3'-flanking nucleotide is A, co-integrates are increased 500-fold compared with a 3' C. In addition, we have isolated five transposase mutants that increase replicative transposition. These residues are close to the catalytic residues and are thus likely to be part of the active site. These are the first transposase mutations described that affect the product of transposition. Our results are consistent with the hypothesis that a delay in cleavage of the 5'-flanking DNA will increase the effective half-life of the 3'-nicked transposon intermediate and consequently enhance co-integrate formation.

Transposon mutagenesis of Xylella fastidiosa by electroporation of Tn5 synaptic complexes

Pierce's disease, a lethal disease of grapevine, is caused by Xylella fastidiosa, a gram-negative, xylem-limited bacterium that is transmitted from plant to plant by xylem-feeding insects. Strains of X. fastidiosa also have been associated with diseases that cause tremendous losses in many other economically important plants, including citrus. Although the complete genome sequence of X. fastidiosa has recently been determined, the inability to transform or produce transposon mutants of X. fastidiosa has been a major impediment to understanding pathogen-, plant-, and insect-vector interactions. We evaluated the ability of four different suicide vectors carrying either Tn5 or Tn10 transposons as well as a preformed Tn5 transposase-transposon synaptic complex (transposome) to transpose X. fastidiosa. The four suicide vectors failed to produce any detectable transposition events. Electroporation of transposomes, however, yielded 6 x 10(3) and 4 x 10(3) Tn5 mutants per microg of DNA in two different grapevine strains of X. fastidiosa. Molecular analysis showed that the transposition insertions were single, independent, stable events. Sequence analysis of the Tn5 insertion sites indicated that the transpositions occur randomly in the X. fastidiosa genome. Transposome-mediated mutagenesis should facilitate the identification of X. fastidiosa genes that mediate plant pathogenicity and insect transmission.

The terminal inverted repeats of IS911: requirements for synaptic complex assembly and activity

The bacterial insertion sequence IS911 transposes via a covalently closed circular intermediate. Circle formation involves transposase-mediated pairing of both insertion sequence ends. While full-length transposase, OrfAB, binds poorly in vitro to IS911 DNA fragments carrying a copy of the IS911 end, truncated protein derivatives carrying the first 135 (OrfAB[1-135]) or 149 (OrfAB[1-149]) amino acid residues bind efficiently. They generate a paired-end complex containing two such fragments which resembles that expected for the first synaptic complex. Shorter protein derivatives lacking a region involved in multimerisation do not form these complexes but modify the binding of OrfAB[1-135] and OrfAB[1-149]. DNaseI footprinting demonstrated that OrfAB[1-149] protects a sub-terminal (internal) region of the inverted repeats which includes two blocks of sequence (beta and gamma) conserved between the left (IRL) and right (IRR) ends. DNA binding assays in vitro and measurement of recombination activity in vivo of sequential deletion derivatives of the two inverted repeats suggested a model in which the N-terminal region of OrfAB binds the conserved boxes beta and gamma in a sequence-specific manner and anchors the two insertion sequence ends into a paired-end complex. The external region of the inverted repeat is proposed to contact the C-terminal transposase domain carrying the catalytic site.

Gene discovery and gene function assignment in filamentous fungi

Filamentous fungi are a large group of diverse and economically important microorganisms. Large-scale gene disruption strategies developed in budding yeast are not applicable to these organisms because of their larger genomes and lower rate of targeted integration (TI) during transformation. We developed transposon-arrayed gene knockouts (TAGKO) to discover genes and simultaneously create gene disruption cassettes for subsequent transformation and mutant analysis. Transposons carrying a bacterial and fungal drug resistance marker are used to mutagenize individual cosmids or entire libraries in vitro. Cosmids are annotated by DNA sequence analysis at the transposon insertion sites, and cosmid inserts are liberated to direct insertional mutagenesis events in the genome. Based on saturation analysis of a cosmid insert and insertions in a fungal cosmid library, we show that TAGKO can be used to rapidly identify and mutate genes. We further show that insertions can create alterations in gene expression, and we have used this approach to investigate an amino acid oxidation pathway in two important fungal phytopathogens.

Recent advances in large-scale transposon mutagenesis

Transposons were identified as mobile genetic elements over fifty years ago and subsequently became powerful tools for molecular-genetic studies. Recently, transposon-mutagenesis strategies have been developed to identify essential and pathogenicity-related genes in pathogenic microorganisms. Also, a number of in vitro transposition systems have been used to facilitate genome sequence analysis. Finally, transposon mutagenesis of yeast and complex eukaryotes has provided valuable functional genomic information to complement genome-sequencing projects.

Genetic transformation systems in insects

The past 5 years have witnessed the emergence of techniques that permit the stable genetic transformation of a number of non-drosophilid insect species. These transposable-element-based strategies, together with virus-based techniques that allow the expression of genes to be quickly examined in insects, provide insect scientists with a first generation of genetic tools that can begin to be harnessed to further increase our understanding of gene function and regulation in insects. We review and compare the characteristics of these gene transfer systems and conclude that, although significant progress has been made, these systems still do not meet the requirements of robust genetic tools. We also review risk assessment issues arising from the generation and probable release of genetically engineered insects.

Construction of gene-targeting vectors: a rapid Mu in vitro DNA transposition-based strategy generating null, potentially hypomorphic, and conditional alleles

Gene targeting into mammalian genomes by means of homologous recombination is a powerful technique for analyzing gene function through generation of transgenic animals. Hundreds of mouse strains carrying targeted alleles have already been created and recent modifications of the technology, in particular generation of conditional alleles, have extended the usefulness of the methodology for a variety of special purposes. Even though the standard protocols, including the construction of gene-targeting vector plasmids, are relatively straightforward, they typically involve time-consuming and laborious gene mapping and/or sequencing steps. To produce various types of gene-targeting constructions rapidly and with minimum effort, we developed a strategy, that utilizes a highly efficient in vitro transposition reaction of phage Mu, and tested it in a targeting of the mouse Kcc2 gene locus. A vast number and different types of targeting constructions can be generated simultaneously with little or no prior sequence knowledge of the gene locus of interest. This quick and efficient general strategy will facilitate easy generation of null, potentially hypomorphic, and conditional alleles. Especially useful it will be in the cases when effects of several exons within a given gene are to be studied, a task that necessarily will involve generation of multiple constructions. The strategy extends the use of diverse recombination reactions for advanced genome engineering and complements existing recombination-based approaches for generation of gene-targeting constructions.

Sialylation of lipooligosaccharide cores affects immunogenicity and serum resistance of Campylobacter jejuni

Three genes involved in biosynthesis of the lipooligosaccharide (LOS) core of Campylobacter jejuni MSC57360, the type strain of the HS:1 serotype, whose structure mimics GM(2) ganglioside, have been cloned and characterized. Mutation of genes encoding proteins with homology to a sialyl transferase (cstII) and a putative N-acetylmannosamine synthetase (neuC1), part of the biosynthetic pathway of N-acetylneuraminic acid (NeuNAc), have identical phenotypes. The LOS cores of these mutants display identical changes in electrophoretic mobility, loss of reactivity with cholera toxin (CT), and enhanced immunoreactivity with a hyperimmune polyclonal antiserum generated against whole cells of C. jejuni MSC57360. Loss of sialic acid in the core of the neuC1 mutant was confirmed by fast atom bombardment mass spectrometry. Mutation of a gene encoding a putative beta-1,4-N-acetylgalactosaminyltransferase (Cgt) resulted in LOS cores intermediate in electrophoretic mobility between that of wild type and the mutants lacking NeuNAc, loss of reactivity with CT, and a reduced immunoreactivity with hyperimmune antiserum. Chemical analyses confirmed the loss of N-acetylgalactosamine (GalNAc) and the presence of NeuNAc in the cgt mutant. These data suggest that the Cgt enzyme is capable of transferring GalNAc to an acceptor with or without NeuNAc and that the Cst enzyme is capable of transferring NeuNAc to an acceptor with or without GalNAc. A mutant with a nonsialylated LOS core is more sensitive to the bactericidal effects of human sera than the wild type or the mutant lacking GalNAc.

It takes two transposons to tango: transposable-element-mediated chromosomal rearrangements

Transposable elements (TEs) promote various chromosomal rearrangements more efficiently, and often more specifically, than other cellular processes(1-3). One explanation of such events is homologous recombination between multiple copies of a TE present in a genome. Although this does occur, strong evidence from a number of TE systems in bacteria, plants and animals suggests that another mechanism - alternative transposition - induces a large proportion of TE-associated chromosomal rearrangements. This paper reviews evidence for alternative transposition from a number of unrelated but structurally similar TEs. The similarities between alternative transposition and V(D)J recombination are also discussed, as is the use of alternative transposition as a genetic tool.

Characterization of a Tn5 pre-cleavage synaptic complex

Protein catalyzed DNA rearrangements typically require assembly of complex nucleoprotein structures. In transposition and integration reactions, these structures, termed synaptic complexes, are mandatory for catalysis. We characterize the Tn5 pre-cleavage synaptic complex, the simplest transposition complex described to date. We identified this complex by gel retardation assay using short, linear fragments and have shown that it contains a dimer of transposase, two DNA molecules, and is competent for DNA cleavage in the presence of Mg(2+). We also used hydroxyl radical footprinting and interference techniques to delineate the protein-DNA contacts made in the Tn5 synaptic and monomer complexes. All positions (except position 1) of the end sequence are contacted by transposase in the synaptic complex. We have determined that positions 2-5 of the end sequence are specifically required for synaptic complex formation as they are not required for monomer complex formation. In addition, in the synaptic complex, there is a strong, local distortion centered around position 1 which likely facilitates cleavage.

Genomewide insertional mutagenesis in Streptomyces coelicolor reveals additional genes involved in morphological differentiation

The filamentous soil bacterium Streptomyces coelicolor undergoes a complex cycle of morphological differentiation involving the formation of an aerial mycelium and the production of pigmented antibiotics. We have developed a procedure for generating insertional mutants of S. coelicolor based on in vitro transposition of a plasmid library of cloned S. coelicolor DNAs. The insertionally mutated library was introduced into S. coelicolor, and transposon insertions were recovered at widely scattered locations around the chromosome. Many of the insertions revealed previously uncharacterized genes, and several caused novel mutant phenotypes, such as altered pigment production, enhanced antibiotic sensitivity, delayed or impaired formation of aerial hyphae, and a block in spore formation. The sporulation mutant harbored an insertion in one of three adjacent genes that are apparently unique to Streptomyces but are each represented by at least 20 paralogs at dispersed locations in the chromosome. Individual members of the three families often are found grouped together in a characteristic arrangement, suggesting that they have a common function.

Trans catalysis in Tn5 transposition

Synaptic complexes in prokaryotic transposons occur when transposase monomers bind to each of two specific end-binding sequences and then associate to bring the proteins and the two ends of the transposon together. It is within this complex of proteins and DNA that identical catalytic reactions are carried out by transposase on each of the ends of the transposon. In this study, we perform in vitro transposition reactions by combining the methylated inside end (IE(ME)) biased hyperactive Tn5 transposase, Tnp sC7 version 2.0, and the outside end (OE) biased hyperactive Tn5 transposase, Tnp EK/LP, with plasmid DNA containing a transposon defined by one IE(ME) and one OE. These two proteins cooperate to facilitate double end cleavage of the transposon from the plasmid and conversion into transposition products via strand transfer. When one of the hyperactive Tnps is replaced with a catalytically inactive version containing the mutation EA326 (DDE mutant), the predominant reaction product is a linearized plasmid resulting from single end cleavage. Restriction analysis of these linear products reveals that cleavage is occurring on the end distal to that which is bound by the transposase with an intact active site or in trans. Similar in vitro experiments performed with precut transposons and a supercoiled target plasmid demonstrated that the strand transfer reaction is also facilitated by a trans active DDE motif.

The C-terminal alpha helix of Tn5 transposase is required for synaptic complex formation

An important step in Tn5 transposition requires transposase-transposase homodimerization to form a synaptic complex competent for cleavage of transposon DNA free from the flanking sequence. We demonstrate that the C-terminal helix of Tn5 transposase (residues 458-468 of 476 total amino acids) is required for synaptic complex formation during Tn5 transposition. Specifically, deletion of eight amino acids or more from the C terminus greatly reduces or abolishes synaptic complex formation in vitro. Due to this impaired synaptic complex formation, transposases lacking eight amino acids are also defective in the cleavage step of transposition. Interactions within the synaptic complex dimer interface were investigated by site-directed mutagenesis, and residues required for synaptic complex formation include amino acids comprising the dimer interface in the Tn5 inhibitor x-ray crystal structure dimer. Because the crystal structure dimer was hypothesized to be the inhibitory complex and not a synaptic complex, this result was surprising. Based on these data, models for both in vivo and in vitro synaptic complex formation are presented.

Three-dimensional structure of the Tn5 synaptic complex transposition intermediate

Genomic evolution has been profoundly influenced by DNA transposition, a process whereby defined DNA segments move freely about the genome. Transposition is mediated by transposases, and similar events are catalyzed by retroviral integrases such as human immunodeficiency virus-1 (HIV-1) integrase. Understanding how these proteins interact with DNA is central to understanding the molecular basis of transposition. We report the three-dimensional structure of prokaryotic Tn5 transposase complexed with Tn5 transposon end DNA determined to 2.3 angstrom resolution. The molecular assembly is dimeric, where each double-stranded DNA molecule is bound by both protein subunits, orienting the transposon ends into the active sites. This structure provides a molecular framework for understanding many aspects of transposition, including the binding of transposon end DNA by one subunit and cleavage by a second, cleavage of two strands of DNA by a single active site via a hairpin intermediate, and strand transfer into target DNA.

IS1294, a DNA element that transposes by RC transposition

IS1294, found on the ColD-like resistance plasmid pUB2380, is IS91-like. It is an active 1.7-kb insertion sequence that lacks terminal inverted repeats, displays insertion-site specificity, and does not generate direct repeats of the target site. The element has one large open reading frame, tnp(1294), encoding a transposase of 351 amino acids, related to members of the REP family of replication proteins used by RC-plasmids of gram-positive bacteria. IS1294 transposes using rolling-circle replication, initiated at one end of the element, oriIS, and terminated at the other, terIS. oriIS and terIS are highly conserved among like IS elements. oriIS resembles the leading strand replication origins of RC-plasmids; terIS resembles a rho-independent transcription terminator. IS1294 mediates not only its own transposition, but also sequences adjacent to terIS. A transposition model for IS1294 and related elements, involving rolling-circle replication and single-strand DNA intermediates, is presented.

cis and trans factors affecting Mos1 mariner evolution and transposition in vitro, and its potential for functional genomics

Mos1 and other mariner / Tc1 transposons move horizon-tally during evolution, and when transplanted into heterologous species can transpose in organisms ranging from prokaryotes to protozoans and vertebrates. To further develop the Drosophila Mos1 mariner system as a genetic tool and to probe mechanisms affecting the regulation of transposition activity, we developed an in vitro system for Mos1 transposition using purified transposase and selectable Mos1 derivatives. Transposition frequencies of nearly 10(-3)/target DNA molecule were obtained, and insertions occurred at TA dinucleotides with little other sequence specificity. Mos1 elements containing only the 28 bp terminal inverted repeats were inactive in vitro, while elements containing a few additional internal bases were fully active, establishing the minimal cis -acting requirements for transposition. With increasing transposase the transposition frequency increased to a plateau value, in contrast to the predictions of the protein over-expression inhibition model and to that found recently with a reconstructed Himar1 transposase. This difference between the 'natural' Mos1 and 'reconstructed' Himar1 transposases suggests an evolutionary path for down-regulation of mariner transposition following its introduction into a naïve population. The establishment of the cis and trans requirements for optimal mariner transposition in vitro provides key data for the creation of vectors for in vitro mutagenesis, and will facilitate the development of in vivo systems for mariner transposition.

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.

Tn5: A molecular window on transposition

DNA transposition is an underlying process involved in the remodeling of genomes in all types of organisms. We analyze the multiple steps in cut-and-paste transposition using the bacterial transposon Tn5 as a model. This system is particularly illuminating because of the existence of structural, genetic, and biochemical information regarding the two participating specific macromolecules: the transposase and the 19-bp sequences that define the ends of the transposon. However, most of the insights should be of general interest because of similarities to other transposition-like systems such as HIV-1 DNA integration into the host genome.

Hairpin formation in Tn5 transposition

The initial chemical steps in Tn5 transposition result in blunt end cleavage of the transposon from the donor DNA. We demonstrate that this cleavage occurs via a hairpin intermediate. The first step is a 3' hydrolytic nick by transposase. The free 3'OH then attacks the phosphodiester bond on the opposite strand, forming a hairpin at the transposon end. In addition to forming precise hairpins, Tn5 transposase can form imprecise hairpins. This is the first example of imprecise hairpin formation on transposon end DNA. To undergo strand transfer, the hairpin must to be resolved by a transposase-catalyzed hydrolytic cleavage. We show that both precise and imprecise hairpins are opened by transposase. A transposition mechanism utilizing a hairpin intermediate allows a single transposase active site to cleave both 3' and 5' strands without massive protein/DNA rearrangements.

Integrating DNA: transposases and retroviral integrases

Transposable elements appear quite disparate in their organization and in the types of genetic rearrangements they promote. In spite of this diversity, retroviruses and many transposons of both prokaryotes and eukaryotes show clear similarities in the chemical reactions involved in their transposition. This is reflected in the enzymes, integrases and transposases, that catalyze these reactions and that are essential for the mobility of the elements. In this chapter, we examine the structure-function relationships between these enzymes and the different ways in which the individual steps are assembled to produce a complete transposition cycle.

Hyperactive transposase mutants of the Himar1 mariner transposon

Mariner-family transposable elements are active in a wide variety of organisms and are becoming increasingly important genetic tools in species lacking sophisticated genetics. The Himar1 element, isolated from the horn fly, Haematobia irritans, is active in Escherichia coli when expressed appropriately. We used this fact to devise a genetic screen for hyperactive mutants of Himar1 transposase that enhance overall transposition from approximately 4- to 50-fold as measured in an E. coli assay. Purified mutant transposases retain their hyperactivity, although to a lesser degree, in an in vitro transposition assay. Mutants like those described herein should enable sophisticated analysis of the biochemistry of mariner transposition and should improve the use of these elements as genetic tools, both in vivo and in vitro.