Different DNA repair pathways support intact or truncated insertions by R2 retrotransposon protein
Summary
Non-long terminal repeat (non-LTR) retrotransposon proteins copy their RNA template into a genome through coordinated nicking and reverse transcriptase activities of target-primed reverse transcription. Mechanisms by which the first-strand complementary DNA (cDNA) becomes a stably inserted duplex, including requirements for junction formation at the cDNA 3' end and second-strand synthesis, are unknown. We screened for cellular factors that influence site-specific transgene synthesis into t
Content
# Different DNA repair pathways support intact or truncated insertions by R2 retrotransposon protein
*Published: 2026 Feb 26*
Non-long terminal repeat (non-LTR) retrotransposon proteins copy their RNA
template into a genome through coordinated nicking and reverse transcriptase
activities of target-primed reverse transcription. Mechanisms by which the
first-strand complementary DNA (cDNA) becomes a stably inserted duplex,
including requirements for junction formation at the cDNA 3' end and
second-strand synthesis, are unknown. We screened for cellular factors that
influence site-specific transgene synthesis into the human genome by an R2
retrotransposon protein. We discovered that insertion lengths and junction
signatures differ based on alternative repair processes involving ATR-dependent
polymerase θ end joining, 53BP1-directed shieldin and CST-polymerase α-primase
fill-in synthesis, or limited strand annealing dependent on CtIP-MRN. These
insights shed light on how genome-primed cDNA synthesis by a non-LTR
retrotransposon protein can support stable new gene insertion, with major
implications for native retrotransposon mobility and genome engineering.
DOI: 10.1126/science.adz3121