A family of Tc1-like transposons from the genomes of fishes and frogs: evidence for horizontal transmission.

Tc1-like transposons are very widely distributed within the genomes of animal species. They consist of an inverted repeat sequence flanking a transposase gene with homology to the mobile DNA element, Tc1 of the nematode Caenorhabditis elegans. These elements seem particularly to infest the genomes of fish and amphibian species where they can account for 1% of the total genome. However, all vertebrate Tc1-like elements isolated so far are non-functional in that they contain multiple frameshifts within their transposase coding regions. Here I describe a Tc1-like transposon (PPTN) from the genome of a marine flatfish species (Pleuronectes platessa) which bears conserved inverted repeats flanking an apparently intact transposase gene. Closely related, although degenerate, Tc1-like transposons were also isolated from the genomes of Atlantic salmon (SSTN, Salmo salar) and frog (RTTN, Rana temporaria). Consensual nucleic acid sequences were derived by comparing several individual isolates from each species and conceptual amino acid sequences were thence derived for their transposases. Phylogenetic analysis of these sequences with previously isolated Tc1-like transposases shows that the elements from plaice, salmon and frog comprise a new subfamily of Tc1-like transposons. Each member is distinct in that it is not found in the genomes of the other species tested. Plaice genomes contain about 300 copies of PPTN, salmon 1200 copies of SSTN and frog genomes about 500 copies of RTTN. The presence of these closely related elements in the genomes of fish and frog species, representing evolutionary lines, which diverged more than 400 million years ago, is not consistent with a vertical transmission model for their distributions.     

Transposon Tc1 of the nematode Caenorhabditis elegans jumps in human cells.

The transposon Tc1 of the nematode Caenorhabditis elegans is a member of the widespread family of Tc1/mariner transposons. The distribution pattern of virtually identical transposons among insect species that diverged 200 million years ago suggested horizontal transfer of the elements between species. Thishypothesis gained experimental support when it was shown that Tc1 and later also mariner transposons could be made to jump in vitro , with their transposase as the only protein required. Later it was shown that mariner transposons from one fruit fly species can jump in other fruit fly species and in a protozoan and, recently, that a Tc1-like transposon from the nematode jumps in fish cells and that a fish Tc1-like transposon jumps in human cells. Here we show that the Tc1 element from the nematode jumps in human cells. This provides further support for the horizontal spread hypothesis. Furthermore, it suggests that Tc1 can be used as vehicle for DNA integration in human gene therapy.     

maT--a clade of transposons intermediate between mariner and Tc1

A group of transposons, named maT, with characteristics intermediate between mariner and Tc1 transposons, is described. Two defective genomic copies of MdmaT from the housefly Musca domestica, with 85% identity, were found flanking and imbedded in the MdalphaE7 esterase gene involved in organophosphate insecticide resistance. Two cDNA clones, with 99% identity to each other and 72%-89% identity to the genomic copies were also obtained, but both represented truncated versions of the putative open reading frame. A third incomplete genomic copy of MdmaT was also identified upstream of the putative M. domestica period gene. The MdmaT sequences showed high identity to the transposable element Bmmar1 from the silkworm moth, Bombyx mori, and to previously unidentified sequences in the genome of Caenorhabditis elegans. A total of 16 copies of full-length maT sequences were identified in the C. elegans genome, representing three variants of the transposon, with 34%-100% identity amongst them. Twelve of the copies, named CemaT1, were virtually identical, with eight of them encoding a putative full length, intact transposase. Secondary structure predictions and phylogenetic analyses confirm that maT elements belong to the mariner-Tc1 superfamily of transposons, but their intermediate sequence and predicted structural characteristics suggest that they belong to a unique clade, distinct from either mariner-like or Tc1-like elements.     

Horizontal Escape of the Novel Tc1-Like Lepidopteran Transposon TCp3.2 into Cydia pomonella Granulovirus

We characterized an insertion mutant of the baculovirus Cydia pomonella granulovirus (CpGV), which contained a transposable element of 3.2 kb. This transposon, termed TCp3.2, has unusually long inverted terminal repeats (ITRs) of 756 bp and encodes a defective gene for a putative transposase. Amino acid sequence comparison of the defective transposase gene revealed a distant relationship to a putative transposon in Caenorhabditis elegans which also shares some similarity of the ITRs. Maximum parsimony analysis of the predicted amino acid sequences of Tc1- and mariner-like transposases available from the GenBank data base grouped TCp3.2 within the superfamily of Tc1-like transposons. DNA hybridization indicated that TCp3.2 originated from the genome of Cydia pomonella, which is the natural host of CpGV, and is present in less than 10 copies in the C. pomonella genome. The transposon TCp3.2 most likely was inserted into the viral genome during infection of host larvae. TCp3.2 and the recently characterized Tc1-like transposon TC14.7 (Jehle et al. 1995), which was also found in a CpGV mutant, represent a new family of transposons found in baculovirus genomes. The occasional horizontal escape of different types of host transposons into baculovirus genomes evokes the question about the possible role of baculoviruses as an interspecies vector in the horizontal transmission of insect transposons. Received: 27 February 1997 / Accepted: 16 May 1997     

Tdr2, a new zebrafish transposon of the Tc1 family.

We describe here Tdr2, a new class of Tc1-like transposons in zebrafish. Tdr2 was identified from the genomic sequence of a zebrafish PAC (P1 artificial chromosome) clone, and fragments of Tdr2 were found in several zebrafish EST (expressed sequence tag) sequences. Predicted translation of the Tdr2 transposase gene showed that it was most closely related to Caenorhabditis elegans Tc3A, suggesting an ancient origin of the Tdr2 transposon. Tdr2 spans 1. 1kb and is flanked by inverted repeats of approx. 100bp. The 5' repeat is itself composed of an inverted repeat, raising the possibility of the formation of a cruciform DNA structure. Tdr2 transposons may facilitate the development of novel transposon-based tools for the genetic analysis of zebrafish.     

CemaT1 is an active transposon within the Caenorhabditis elegans genome

The maT clade of transposons is a group of transposable elements intermediate in sequence and predicted protein structure to mariner and Tc transposons, with a distribution thus far limited to a few invertebrate species. In the nematode Caenorhabditis elegans, there are eight copies of CemaT1 that are predicted to encode a functional transposase, with five copies being >99% identical. We present evidence, based on searches of publicly available databases and on PCR-based mobility assays, that the CemaT1 transposase is expressed in C. elegans and that the CemaT transposons are capable of excising in both somatic and germline tissues. We also show that the frequency of CemaT1 excisions within the genome of the N2 strain of C. elegans is comparable to that of the Tc1 transposon. However, unlike Tc transposons in mutator strains of C. elegans, maT transposons do not exhibit increased frequencies of mobility, suggesting that maT is not regulated by the same factors that control Tc activity in these strains. Finally, we show that CemaT1 transposons are capable of precise transpositions as well as orientation inversions at some loci, and thereby become members of an increasing number of identified active transposons within the C. elegans genome.     

Tc7, a Tc1-hitch hiking transposon in Caenorhabditis elegans.

We have found a novel transposon in the genome of Caenorhabditis elegans. Tc7 is a 921 bp element, made up of two 345 bp inverted repeats separated by a unique, internal sequence. Tc7 does not contain an open reading frame. The outer 38 bp of the inverted repeat show 36 matches with the outer 38 bp of Tc1. This region of Tc1 contains the Tc1-transposase binding site. Furthermore, Tc7 is flanked by TA dinucleotides, just like Tc1, which presumably correspond to the target duplication generated upon integration. Since Tc7 does not encode its own transposase but contains the Tc1-transposase binding site at its extremities, we tested the ability of Tc7 to jump upon forced expression of Tc1 transposase in somatic cells. Under these conditions Tc7 jumps at a frequency similar to Tc1. The target site choice of Tc7 is identical to that of Tc1. These data suggest that Tc7 shares with Tc1 all the sequences minimally required to parasitize upon the Tc1 transposition machinery. The genomic distribution of Tc7 shows a striking clustering on the X chromosome where two thirds of the elements (20 out of 33) are located. Related transposons in C. elegans do not show this asymmetric distribution.     

Identification of 1088 new transposon insertions of Caenorhabditis elegans: a pilot study toward large-scale screens

We explored the feasibility of a strategy based on transposons to generate identified mutants of most Caenorhabditis elegans genes. A total of 1088 random new insertions of C. elegans transposons Tc1, Tc3, and Tc5 were identified by anchored PCR, some of which result in a mutant phenotype.     

Computer analyses reveal a hobo-like element in the nematode Caenorhabditis elegans,which presents a conserved transposase domain common with the Tc1-Mariner transposon family

The present report describes the use of computer analyses to reveal a hobo-like element in the genome of Caenorhabditis elegans. This hobo-like sequence is 3039 bp long, contains two inverted terminal repeats of 25–27 bp and probably does not encoded a functional transposase. Sequence comparisons suggest that each transposase of hobo elements probably has a D(D/S)E motif. Thus the transposases of the hAT superfamily of transposons appear to be close to the other transposases and intregrases.     

Tc8, a Tourist-like transposon in Caenorhabditis elegans.

Members of the Tourist family of miniature inverted-repeat transposable elements (MITEs) are very abundant among a wide variety of plants, are frequently found associated with normal plant genes, and thus are thought to be important players in the organization and evolution of plant genomes. In Arabidopsis, the recent discovery of a Tourist member harboring a putative transposase has shed new light on the mobility and evolution of MITEs. Here, we analyze a family of Tourist transposons endogenous to the genome of the nematode Caenorhabditis elegans (Bristol N2). One member of this large family is 7568 bp in length, harbors an ORF similar to the putative Tourist transposase from Arabidopsis, and is related to the IS5 family of bacterial insertion sequences (IS). Using database searches, we found expressed sequence tags (ESTs) similar to the putative Tourist transposases in plants, insects, and vertebrates. Taken together, our data suggest that Tourist-like and IS5-like transposons form a superfamily of potentially active elements ubiquitous to prokaryotic and eukaryotic genomes.     

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

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

Evidence that a family of miniature inverted-repeat transposable elements (MITEs) from the Arabidopsis thaliana genome has arisen from a pogo-like DNA transposon

Sequence similarities exist between terminal inverted repeats (TIRs) of some miniature inverted-repeat transposable element (MITE) families isolated from a wide range of organisms, including plants, insects, and humans, and TIRs of DNA transposons from the pogo family. We present here evidence that one of these MITE families, previously described for Arabidopsis thaliana, is derived from a larger element encoding a putative transposase. We have named this novel class II transposon Lemi1. We show that its putative product is related to transposases of the Tc1/mariner superfamily, being closer to the pogo family. A similar truncated element was found in a tomato DNA sequence, indicating an ancient origin and/or horizontal transfer for this family of elements. These results are reminiscent of those recently reported for the human genome, where other members of the pogo family, named Tiggers, are believed to be responsible for the generation of abundant MITE-like elements in an early primate ancestor. These results further suggest that some MITE families, which are highly reiterated in plant, insect, and human genomes, could have arisen from a similar mechanism, implicating pogo-like elements.     

Target sequences of Tc1, Tc3 and Tc5 transposons of Caenorhabditis elegans

We report here the consensus target sequence of transposons Tc1, Tc3 and Tc5 of Caenorhabditis elegans. These sequences were obtained by molecular analysis of 1008 random new insertions which have not been exposed to natural selection. This analysis reveals consensus target sites slightly different from those previously reported, and confirms that the mariner elements Tc1 and Tc3 insert in sites which are not preferentially palindromic.     

Target sequences for the C. elegans transposable element Tc1.

The target sequences for two independent insertions of the transposable element Tc1 from Caenorhabditis elegans show homology. Because both insertions are at palindromic TA/AT sequences, the exact boundaries of Tc1 cannot be distinguished; Tc1 could be 1610 bp and flanked by a 2-bp duplication of the target site or it could be 1612 bp and without target site duplication. The latter possibility implies a novel manner for insertion of a transposable element.     

Does the proposed DSE motif form the active center in the Hermes transposase?

Donor cleavage and strand transfer are two functions performed by transposases during transposition of class II transposable elements. Within transposable elements, the only active center described, to date, facilitating both functions, is the so-called DDE motif. A second motif, R-K-H/K-R-H/W-Y, is found in the site-specific recombinases of the tyrosine recombinase family. While present in many bacterial insertion sequences as well as in the eukaryotic family of mariner/Tc1 elements, the DDE motif was considered absent in other classes of eukaryotic class II elements such as P, and hAT and piggyBac. Based on sequence alignments of a hobo-like element from the nematode Caenorhabditis elegans, to a variety of other hAT transposases and several members of the mariner/Tc1 group, Bigot et al. [Gene 174 (1996) 265] proposed the presence of a DSE motif in hAT transposases. In the present study we tested if each of these three residues is required for transposition of the Hermes element, a member of the hAT family commonly used for insect transformation. While D402N and E572Q mutations lead to knock-out of Hermes function, mutations S535A and S535D did not affect transposition frequency or the choice of integration sites. These data give the first experimental support that D402 and E572 are indeed required for transposition of Hermes. Furthermore, this study indicates that the active center of the Hermes transposase differs from the proposed DSE motif. It remains to be shown if other residues also form the active site of this transposase.     

Shotgun cloning of transposon insertions in the genome of Caenorhabditis elegans

We present a strategy to identify and map large numbers of transposon insertions in the genome of Caenorhabditis elegans. Our approach makes use of the mutator strain mut-7, which has germline-transposition activity of the Tc1/mariner family of transposons, a display protocol to detect new transposon insertions, and the availability of the genomic sequence of C. elegans. From a pilot insertional mutagenesis screen, we have obtained 351 new Tc1 transposons inserted in or near 219 predicted C. elegans genes. The strategy presented provides an approach to isolate insertions of natural transposable elements in many C. elegans genes and to create a large-scale collection of C. elegans mutants.     

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

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

Continuous exchange of sequence information between dispersed Tc1 transposons in the Caenorhabditis elegans genome

In a genome-wide analysis of the active transposons in Caenorhabditis elegans we determined the localization and sequence of all copies of each of the six active transposon families. Most copies of the most active transposons, Tc1 and Tc3, are intact but individually have a unique sequence, because of unique patterns of single-nucleotide polymorphisms. The sequence of each of the 32 Tc1 elements is invariant in the C. elegans strain N2, which has no germline transposition. However, at the same 32 Tc1 loci in strains with germline transposition, Tc1 elements can acquire the sequence of Tc1 elements elsewhere in the N2 genome or a chimeric sequence derived from two dispersed Tc1 elements. We hypothesize that during double-strand-break repair after Tc1 excision, the template for repair can switch from the Tc1 element on the sister chromatid or homologous chromosome to a Tc1 copy elsewhere in the genome. Thus, the population of active transposable elements in C. elegans is highly dynamic because of a continuous exchange of sequence information between individual copies, potentially allowing a higher evolution rate than that found in endogenous genes.