Essential factors involved in the precise targeting and insertion of telomere-specific non-LTR retrotransposon, SART1Bm.

Telomere length maintenance is essential for most eukaryotes to ensure genome stability and integrity. A non-long terminal repeat (LTR) retrotransposon, SART1Bm, targets telomeric repeats (TTAGG)n of the silkworm Bombyx mori and is presumably involved in telomere length maintenance. However, how many telomeric repeats are required for its retrotransposition and how reverse transcription is initiated at the target site are not well understood. Here, using an ex vivo and trans-in vivo recombinant baculovirus retrotransposition system, we demonstrated that SART1Bm requires at least three (TTAGG) telomeric repeats and a longer poly(A) tail for its accurate retrotransposition. We found that SART1Bm retrotransposed only in the third (TTAGG) tract of three repeats and that the A residue of the (TTAGG) unit was essential for its retrotransposition. Interestingly, SART1Bm also retrotransposed into telomeric repeats of other species, such as human (TTAGGG)n repeats, albeit with low retrotransposition efficiency. We further showed that the reverse transcription of SART1Bm occurred inaccurately at the internal site of the 3' untranslated region (UTR) when using a short poly(A) tail but at the accurate site when using a longer poly(A) tail. These findings promote our understanding of the general mechanisms of site-specific retrotransposition and aid the development of a site-specific gene knock-in tool.

Sequence-specific retrotransposition of 28S rDNA-specific LINE R2Ol in human cells.

R2 is a long interspersed element (LINE) found in a specific sequence of the 28S rDNA among a wide variety of animals. Recently, we observed that R2Ol isolated from medaka fish, Oryzias latipes, retrotransposes sequence specifically into the target sequence of zebrafish. Because the 28S target and flanking regions are widely conserved among vertebrates, we examined whether R2Ol can also integrate in a sequence-specific manner in human cells. Using adenovirus-mediated expression of R2Ol constructs, we confirmed an accurate insertion of R2Ol into the 28S target of human 293T cells. However, the R2Ol mutant devoid of endonuclease (EN) activity showed no retrotransposition ability, suggesting that the sequence-specific integration of R2Ol into 28S rDNA occurs via the cleavage activity of EN. By introducing both R2Ol helper virus and donor plasmid in human cells, we succeeded in retrotransposing an exogenous EGFP gene into the 28S target site by the trans-complementation system, which enabled simplification of specific gene knock-in in a time-efficient manner. We believe that R2Ol may provide an alternative targeted gene knock-in method for practical applications such as gene therapy in future.

Targeted gene knockin in zebrafish using the 28S rDNA-specific non-LTR-retrotransposon R2Ol.

BACKGROUND: Although most of long interspersed elements (LINEs), one class of non-LTR-retrotransposons, are integrated into the host genome randomely, some elements are retrotransposed into the specific sequences of the genomic regions, such as rRNA gene (rDNA) clusters, telomeric repeats and other repetitive sequenes. Most of the sequence-specific LINEs have been reported mainly among invertebrate species and shown to retrotranspose into the specific sequences in vivo and in vitro systems. Recenlty, 28S rDNA-specific LINE R2 elements are shown to be distributed among widespread vertebrate species, but the sequence-specific retrotransposition of R2 has never been demonstrated in vertebrates. RESULTS: Here we cloned a full length unit of R2 from medaka fish Oryzias latipes, named R2Ol, and engineered it to a targeted gene integration tool in zebrafish. By injecting R2Ol-encoding mRNA into zebrafish embryos, R2Ol retrotransposed precisely into the target site at high efficiency (98%) and was transmitted to the next generation at high frequency (50%). We also generated transgenic zebrafish carrying the enhanced green fluorescent protein (EGFP) reporter gene in 28S rDNA target by the R2Ol retrotransposition system. CONCLUSIONS: Sequence-specific LINE retrotransposes into the precise sequence using target primed reverse transcription (TPRT), possibly providing an alternative and effective targeted gene knockin method in vertebrates.

Both the Exact Target Site Sequence and a Long Poly(A) Tail Are Required for Precise Insertion of the 18S Ribosomal DNA-Specific Non-Long Terminal Repeat Retrotransposon R7Ag.

Ribosomal elements (R elements) are site-specific non-long terminal repeat (LTR) retrotransposons that target ribosomal DNA (rDNA). To elucidate how R elements specifically access their target sites, we isolated and characterized the 18S rDNA-specific R element R7Ag from Anopheles gambiae Using an in vivo and ex vivo recombinant baculovirus retrotransposition system, we found that the exact host 18S rDNA sequence at the target site is essential for the precise insertion of R7Ag. In addition, a long poly(A) tail is necessary for the accurate initiation of R7Ag reverse transcription, a novel mechanism found in non-LTR elements. We further compared the subcellular localizations of proteins in R7Ag as well as R1Bm, another R element that targets 28S rDNA. Although the open reading frame 1 proteins (ORF1ps) of both R7Ag and R1Bm localized predominantly in the cytoplasm, ORF2 proteins (ORF2ps) colocalized in the nucleus with the nucleolar marker fibrillarin. The ORF1ps and ORF2ps of both R elements colocalized largely in the nuclear periphery and to a lesser extent within the nucleus. These results suggest that R7Ag and R1Bm proteins may access nucleolar rDNA targets in an ORF2p-dependent manner.