Prokaryotic expression and purification of soluble goldfish Tgf2 transposase with transposition activity

Functional analysis of the catalytic triad of the hAT-family transposase TcBuster

TcBuster is a hAT-family DNA transposon from the red flour beetle, Tribolium castaneum. The TcBuster transposase is of interest for genome engineering as it is highly active in insect and mammalian cells. To test the predicted catalytic triad of TcBuster, each residue of the catalytic triad of a haemagglutinin-tagged TcBuster transposase was individually mutated to a structurally conserved amino acid. Using a drug-resistant colony assay for transposon integration, we found that the D223N, D289N, and E589Q mutants of TcBuster transposase were inactive in human cells. We used a modified chromatin immunoprecipitation assay to determine that each mutant maintained binding to TcBuster transposon inverted repeat elements. Although the catalytic mutants retained their transposon binding properties, mutants displayed altered expression and localization in human cells. None of the catalytic mutants formed characteristic TcBuster transposase rodlet structures, and the D223N and D289N mutants were not able to be detected by immunofluorescence microscopy. Immunoblot analysis demonstrated that the E589Q mutant is less abundant than wild-type TcBuster transposase. Cells transfected with either TcBuster or TcBuster-E589Q transposase were imaged by structured illumination microscopy to quantify differences in the length of the transposase rodlets. The average length of the TcBuster transposase rodlets (N = 39) was 3.284 μm while the E589Q rodlets (N = 33) averaged 1.157 μm (p < 0.0001; t-test). The catalytic triad mutations decreased overall protein levels and disrupted transposase rodlet formation while nuclear localization and DNA binding to the inverted repeat elements were maintained. Our results may have broader implications for the overproduction inhibition phenomenon observed for DNA transposons.

Identification of nuclear localization signal within goldfish Tgf2 transposase

The structure of goldfish (Carassius auratus) Tgf2 transposase is still poorly understood, although it can mediate efficient gene transfer in teleost fish. We hypothesized the existence of a nuclear localization signal (NLS) within Tgf2 transposase to assist transport into the nucleus. To explore this, 15 consecutive amino acid residues (656-670 aa) within the C-terminus of Tgf2 transposase were predicted in silico to be a NLS domain. The pEGFP-C1-Tgf2TP(△31C) plasmid encoding the NLS-domain-deleted Tgf2 transposase fused to EGFP was constructed, and transfected into 293T cells. After transfection with pEGFP-C1-Tgf2TP(△31C), EGFP was not detected in the nucleus alone, while 67.0% of cells expressed EGFP only in the cytoplasm. In contrast, after transfection with control plasmids containing C- or N-terminal truncated Tgf2 transposases with an intact NLS domain, EGFP was not detected in the cytoplasm alone, while approximately 40% of cells expressed EGFP only in the nucleus, and the remaining 60% expressed EGFP in both the nucleus and cytoplasm. Our results demonstrated that loss of the NLS domain results in expression in the cytoplasm but not in the nucleus. These findings suggest that 15 aa residues located from 656 to 670 aa within the C-terminus of Tgf2 transposase can function as a NLS to assist the transfer of the transposase into the nucleus where it mediates DNA transposition.

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.