Tdr2, a new zebrafish transposon of the Tc1 family

Goldfish transposase Tgf2 presumably from recent horizontal transfer is active

Hobo/Activator/Tam3 (hAT) superfamily transposons occur in plants and animals and play a role in genomic evolution. Certain hAT transposons are active and have been developed as incisive genetic tools. Active vertebrate elements are rarely discovered; however, Tgf2 transposon was recently discovered in goldfish (Carassius auratus). Here, we found that the endogenous Tgf2 element can transpose in goldfish genome. Seven different goldfish mRNA transcripts, encoding three lengths of Tgf2 transposase, were identified. Tgf2 transposase mRNA was detected in goldfish embryos, mainly in epithelial cells; levels were high in ovaries and mature eggs and in all adult tissues tested. Endogenous Tgf2 transposase mRNA is active in mature eggs and can mediate high rates of transposition (>30%) when injected with donor plasmids harboring a Tgf2 cis-element. When donor plasmid was coinjected with capped Tgf2 transposase mRNA, the insertion rate reached >90% at 1 yr. Nonautonomous copies of the Tgf2 transposon with large-fragment deletions and low levels of point mutations were also detected in common goldfish. Phylogenetic analysis indicates the taxonomic distribution of Tgf2 in goldfish is not due to vertical inheritance. We propose that the goldfish Tgf2 transposon originated by recent horizontal transfer and maintains a highly native activity.

Expression of DNA transposable elements during nervous system development

Transposable elements (retrotransposons and DNA transposons) comprise a large proportion of animal genomes, for example 20% in D. melanogaster, 36% in X. tropicalis and 45% in humans. After invading a new genome, the transposable element increases its copy number and subsequently accumulates mutations. These may eventually result in inactive copies. Until recent days transposons have been considered “junk” DNA and no clear function have been assigned for this important amount of information on genomes.

Expression of transposable elements in neural tissues during Xenopus development

Transposable elements comprise a large proportion of animal genomes. Transposons can have detrimental effects on genome stability but also offer positive roles for genome evolution and gene expression regulation. Proper balance of the positive and deleterious effects of transposons is crucial for cell homeostasis and requires a mechanism that tightly regulates their expression. Herein we describe the expression of DNA transposons of the Tc1/mariner superfamily during Xenopus development. Sense and antisense transcripts containing complete Tc1-2_Xt were detected in Xenopus embryos. Both transcripts were found in zygotic stages and were mainly localized in Spemann's organizer and neural tissues. In addition, the Tc1-like elements Eagle, Froggy, Jumpy, Maya, Xeminos and TXr were also expressed in zygotic stages but not oocytes in X. tropicalis. Interestingly, although Tc1-2_Xt transcripts were not detected in Xenopus laevis embryos, transcripts from other two Tc1-like elements (TXr and TXz) presented a similar temporal and spatial pattern during X. laevis development. Deep sequencing analysis of Xenopus tropicalis gastrulae showed that PIWI-interacting RNAs (piRNAs) are specifically derived from several Tc1-like elements. The localized expression of Tc1-like elements in neural tissues suggests that they could play a role during the development of the Xenopus nervous system.

Repeat structure of the catfish genome: a genomic and transcriptomic assessment of Tc1-like transposon elements in channel catfish (Ictalurus punctatus)

We have assessed the distribution and diversity of members of the Tc1/mariner superfamily of transposable elements in the channel catfish (Ictalurus punctatus) genome as well as evaluating the extent of transcription of Tc1 transposases in the species. Through use of PCR amplification and sequencing, assessment of random BAC end sequences (BES) equivalent to 1.2% genome coverage, and screening of over 45,000 catfish ESTs, a significant proportion of Tc1-like elements and their associated transcripts were captured. Up to 4.2% of the catfish genome in base pairs appears to be composed of Tc1-like transposon-related sequences and a significant fraction of the catfish cellular mRNA, approximately 0.6%, was transcribed from transposon-related sequences in both sense and antisense orientations. Based on results of repeat-masking, as much as 10% of BAC end sequences from catfish, which is a random survey of the genome, contain some remnant of Tc1 elements, suggesting that these elements are present in the catfish genome as numerous, small remnants of the transposons. Phylogenetic analysis allowed comparison of catfish Tc1 transposase types with those found in other vertebrate and invertebrate species. In spite of the existence of many types of Tc1-like sequences that are not yet able to be placed in clades with strong statistical support, it is clear that multiple families of Tc1-like elements exist in channel catfish.

Family of Tc1-like elements from fish genomes and horizontal transfer

The involvement of horizontal transfer (HT) in the evolution of vertebrate transposable elements (TEs) is a matter of an ongoing debate. The phylogenetic relationships between Tc1 TEs, based on limited dataset have been previously used to infer a case of Tc1 HT between the genomes of fish and frogs. Here this hypothesis has been critically evaluated by the experimental approach including comparative data on the range of fish species available today. The distribution of a Tc1 subfamily of TE in selected fish species was investigated by PCR with a single primer complementary to ITRs and showed that they are widespread in the studied 17 fish species. They belong to five different subfamilies of Tc1 TEs, as revealed by the comparison with current genomic data for fish and amphibians. The original hypothesis would get much weaker support from the current data, although at least one novel potential and more convincing case of HT was identified between genomes of Perciformes fish. An interesting case of recombination-driven mobilisation of a degenerated TE by distantly related TE from different subfamily was discovered in the genome of pike. The occurrence of such cases widens the range of TE elements identifiable with the employed experimental approach. Further similar studies would help to explain the evolution of the multiple Tc1 lineages including species for which full genome sequences will not be available soon.

Fish transposons and their potential use in aquaculture

A large part of repetitive DNA of vertebrate genomes have been identified as transposon elements (TEs) or mobile sequences. Although TEs detected to date in most vertebrates are inactivated, active TEs have been found in fish and a salmonid TE has been successfully reactivated by molecular genetic manipulation from inactive genomic copies (Sleeping Beauty, SB). Progress in the understanding of the dynamics, control and evolution of fish TEs will allow the insertion of selected sequences into the fish genomes of germ cells to obtain transgenics or to identify genes important for growth and/or of somatic cells to improve DNA vaccination. Expectations are high for new possible applications to fish of this well developed technology for mammals. Here, we review the present state of knowledge of inactive and active fish TEs and briefly discuss how their possible future applications might be used to improve fish production in aquaculture.

Characterization of multiple lineages of Tc1-like elements within the genome of the amphibian Xenopus tropicalis

We have used genomic sequencing data extracted from the first assembly of the Xenopus tropicalis genome combined with a degenerated PCR approach to identify multiple lineages of Tc1 related transposable elements. Full-length elements were isolated in each lineage and were characterized. Most of them exhibit the typical characteristics of Tc1-like elements (TLEs). An open reading frame (ORF) encoding a 340-350 aa transposase containing a [D, D(34)E] signature was found as well as conserved inverted terminal repeats (ITRs) at each extremities. These ITRs could vary in length, depending on the TLE lineage. These new TLEs were named Eagle, Froggy, Jumpy, Maya, Xeminos, XtTXr and XtTXz. Phylogenetic analyses indicate that their closest relatives are present in the genomes of actinopterygian and amphibian. Interestingly, Maya and Xeminos share remarkable characteristics. Maya contains a [D,D(36)E] motif but is not related to any described TLE so far. Xeminos is the first vertebrate TLE strongly related to an invertebrate lineage. Finally, we have identified for most of these TLEs, copies containing an intact transposase ORF suggesting that these elements may still be active.

The Tol2 transposable element of the medaka fish: an active DNA-based element naturally occurring in a vertebrate genome

Several DNA-based transposable elements are known to be present in vertebrate genomes, but few of them have been demonstrated to be active. The Tol2 element of the medaka fish is one such element and, therefore, is potentially useful for developing a gene tagging system and other molecular biological tools applicable to vertebrates. Towards this goal, analyses of the element at the molecular, cellular and population levels are in progress. Results so far obtained are described here.

A novel repeated sequence DNA originated from a Tc1-like transposon in water green frog Rana esculenta

We have identified and characterized a highly repetitive family, called R.e./Tc1 in the genome of the green water frog Rana esculenta. This family consists of tandemly repeated sequences, localized at the centromeric regions of chromosomes as shown by Southern blot and 'in situ' hybridization. The repeat unit contains a residue of a Tc1-like transposon by Haematobia irritans fly, bordered by two short direct repeats of 9 bp. Tc1 remnant lays near a sequence identical to Homo sapiens Werner syndrome gene stretch. These sequence data suggest that R.e./Tc1 element was probably originated from a transposition event and a duplication via DNA mechanism of the R.e./Tc1 unit that could give rise to the observed tandem array.