Transposition of the Tourist-MITE mPing in yeast: an assay that retains key features of catalysis by the class 2 PIF/Harbinger superfamily

The most active DNA transposon identified to date in plants or animals is mPing, a rice Tourist-like MITE that is a deletion derivative of the autonomous Ping element. Ping and the closely related Pong are the only known naturally active PIF/Harbinger elements. Some rice strains accumulate ~40 new mPing insertions per plant per generation. In this study we report the development of a yeast transposition assay as a first step in deciphering the mechanism underlying the amplification of Tourist-MITEs.The ORF1 and TPase proteins encoded by Ping and Pong have been shown to mobilize mPing in rice and in transgenic Arabidopsis. Initial tests of the native proteins in a yeast assay resulted in very low transposition. Significantly higher activities were obtained by mutation of a putative nuclear export signal (NES) in the TPase that increased the amount of TPase in the nucleus. When introduced into Arabidopsis, the NES mutant protein also catalyzed higher frequencies of mPing excision from the gfp reporter gene. Our yeast assay retains key features of excision and insertion of mPing including precise excision, extended insertion sequence preference, and a requirement for two proteins that can come from either Ping or Pong or both elements.The yeast transposition assay provides a robust platform for analysis of the mechanism underlying transposition catalyzed by the two proteins of PIF/Harbinger elements. It recapitulates all of the features of excision and reinsertion of mPing as seen in plant systems. Furthermore, a mutation of a putative NES in the TPase increased transposition both in yeast and plants.Class 2 DNA transposons were discovered in maize over 60 years ago with the genetic characterization of the Ac/Ds family of autonomous and nonautonomous elements by McClintock [1]. Since then, DNA transposons have been found in all kingdoms of life and have been characterized into at least 10 superfamilies, based on the sequence of the element-encoded transposase protein [