Abstract
Retrotransposons can represent half of eukaryotic genomes. Retrotransposon dysregulation destabilizes genomes and has been linked to various human diseases. Emerging regulators of retromobility include RNA–DNA hybrid-containing structures known as R-loops. Accumulation of these structures at the transposons of yeast 1 (Ty1) elements has been shown to increase Ty1 retromobility through an unknown mechanism. Here, via a targeted genetic screen, we identified the rnh1Δ rad27Δ yeast mutant, which lacked both the Ty1 inhibitor Rad27 and the RNA–DNA hybrid suppressor Rnh1. The mutant exhibited elevated levels of Ty1 cDNA-associated RNA–DNA hybrids that promoted Ty1 mobility. Moreover, in this rnh1Δ rad27Δ mutant, but not in the double RNase H mutant rnh1Δ rnh201Δ, RNA–DNA hybrids preferentially existed as duplex nucleic acid structures and increased Ty1 mobility in a Rad52-dependent manner. The data indicate that in cells lacking RNA–DNA hybrid and Ty1 repressors, elevated levels of RNA-cDNA hybrids, which are associated with duplex nucleic acid structures, boost Ty1 mobility via a Rad52-dependent mechanism. In contrast, in cells lacking RNA–DNA hybrid repressors alone, elevated levels of RNA-cDNA hybrids, which are associated with triplex nucleic acid structures, boost Ty1 mobility via a Rad52-independent process. We propose that duplex and triplex RNA–DNA hybrids promote transposon mobility via Rad52-dependent or -independent mechanisms.
Highlights
Retrotransposons can represent half of eukaryotic genomes
We identified a novel mutant, rnh1Δ rad27Δ, which showed transposons of yeast 1 (Ty1) RNA–DNA hybrid accumulations that are comparable to the RNA–DNA hybrid build-ups in the rnh1∆ rnh201∆ control mutant (Fig. 1)
We examined S. cerevisiae deletion mutants in an attempt to identify the general process by which RNA–DNA hybrids promote Ty1 retromobility, and to assess if an interplay exists between known RNA–DNA hybrid modulators and Ty1 regulators
Summary
Retrotransposons can represent half of eukaryotic genomes. Retrotransposon dysregulation destabilizes genomes and has been linked to various human diseases. The data indicate that in cells lacking RNA–DNA hybrid and Ty1 repressors, elevated levels of RNA-cDNA hybrids, which are associated with duplex nucleic acid structures, boost Ty1 mobility via a Rad52-dependent mechanism. In cells lacking RNA–DNA hybrid repressors alone, elevated levels of RNA-cDNA hybrids, which are associated with triplex nucleic acid structures, boost Ty1 mobility via a Rad52-independent process. Retrotransposons are further divided based on the presence of flanking long terminal repeats (LTRs) such as in the transposons of yeast 1 (Ty1) elements of budding yeast and the non-LTR long interspersed nuclear elements (LINE-1) in h umans[3,4,5] Both Ty1 and LINE-1 elements are autonomous and have two open reading frames (TYA/TYB and ORF1/ORF2, respectively) that code for the proteins required for retrotransposition[2]. In the absence of both Rnh[1] and Rnh[201], RNA–DNA hybrid accumulation at Ty1 increases its transposition via an unknown m echanism[20]
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