The N-terminal zinc finger domain of Tgf2 transposase contributes to DNA binding and to transposition activity.

Active Hobo/Activator/Tam3 (hAT) transposable elements are rarely found in vertebrates. Previously, goldfish Tgf2 was found to be an autonomously active vertebrate transposon that is efficient at gene-transfer in teleost fish. However, little is known about Tgf2 functional domains required for transposition. To explore this, we first predicted in silico a zinc finger domain in the N-terminus of full length Tgf2 transposase (L-Tgf2TPase). Two truncated recombinant Tgf2 transposases with deletions in the N-terminal zinc finger domain, S1- and S2-Tgf2TPase, were expressed in bacteria from goldfish cDNAs. Both truncated Tgf2TPases lost their DNA-binding ability in vitro, specifically at the ends of Tgf2 transposon than native L-Tgf2TPase. Consequently, S1- and S2-Tgf2TPases mediated gene transfer in the zebrafish genome in vivo at a significantly (p < 0.01) lower efficiency (21%-25%), in comparison with L-Tgf2TPase (56% efficiency). Compared to L-Tgf2TPase, truncated Tgf2TPases catalyzed imprecise excisions with partial deletion of TE ends and/or plasmid backbone insertion/deletion. The gene integration into the zebrafish genome mediated by truncated Tgf2TPases was imperfect, creating incomplete 8-bp target site duplications at the insertion sites. These results indicate that the zinc finger domain in Tgf2 transposase is involved in binding to Tgf2 terminal sequences, and loss of those domains has effects on TE transposition.

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.

[Cloning of goldfish hAT transposon Tgf2 and its structure].

The hAT transposon family, including hobo of Drosophila, Ac of maize (Zea mays L.) and Tam3 of snapdragon (Ceratophyllum demersum L.), is proposed to be involved in transposition between genomic DNAs in "cut and paste" patterns. In 1996, a transposon of Tol2, the first autonomous transposon in vertebrate, was identified from the genome of albino medaka fish (Oryzias latipes). Since then, a new transgenic and gene trap system based on Tol2 has been developed and widely used in zebrafish. In this study, we designed gene-specific primers based on the conserved regions of amino acid sequences between medaka Tol2 and maize Ac. Meanwhile, PCR was carried out in 19 fish species or strains including goldfish. Finally, another similar hAT transposon, termed as Tgf2, was identified in the genomes from different strains of goldfish. Goldfish Tgf2 is 4720 bp in length including 4 exons and shares an identity of 97% with medaka Tol2. Distinct differences were observed in the terminal inverted repeat (TIR) and subterminal repeat (STR) regions between Tgf2 and Tol2. In addition, the internal inverted repeat (IIR) region of Tgf2 (1453 bp-2091 bp) tended to form a "+" crossing structure, rather than a stem-loop structure in medaka Tol2. The regions, including TIR, STR, and IIR, were supposed to be closely related to the transposing activities of hAT transposon family members. From these sequence differences, we may expect a probably high activity of goldfish Tgf2 in transposition and it could be further used as a tool for transgenesis and gene trap in aquaculture fish in future.