Project description:Using a TIP-seq protocol (specifically isolating transposon insertion junctions) we determined that the Ty1 retrotransposon targets tRNA genes and, in particular, we determined that the transposon inserts into nucleosomal DNA in an asymmetric pattern.

Project description:Using a TIP-seq protocol (specifically isolating transposon insertion junctions) we determined that the Ty1 retrotransposon targets tRNA genes and, in particular, we determined that the transposon inserts into nucleosomal DNA in an asymmetric pattern. TIP-seq recovery of transposon insertion junctions in haploid and diploid yeast

Project description:A small targeting domain in Ty1 integrase is sufficient to direct retrotransposon integration to tRNA genes

Project description:In budding yeast, the selective integration of the Ty1 LTR retrotransposon upstream of RNA polymerase III (Pol III)-transcribed genes requires the interaction between the AC40, a common subunit of Pol III and Pol I, and Ty1 integrase (IN1). The AC40/IN1 interaction involves a short sequence, the targeting domain (TD), present in the C-terminal part of IN1. Chip-seq analysis using WT or mutated Ty1 integrase demonstrated that TD is responsible for the recruitment of IN1 at both Pol I and Pol III-transcribed genes. Moreover, the introduction of the C-terminal residues of Ty1 in the Ty5 retrotransposon, which preferentially integrates in heterochromatin at silent mating loci (HMR and HML) and near telomeres, leads to its retargeting at Pol III-transcribed genes.

Project description:A stochastic simulation of yeast translation using Total Asymmetric Simple Exclusion Principle (TASEP) principles, representing ribosomes, tRNAs, mRNAs, and a tRNA re-charging process involving aminoacyl tRNA synthetases

Project description:Arrested replication forks guide retrotransposon integration

Project description:We report testis H3K4me3 and DMC1 enrichment at DSB hotspots in various mice to examine differences between infertile hybrid mice and mice that have been humanized at PRDM9, which have rescued fertility. We find that infertile mice have an excess of "asymmetric" DSB hotspots, where both H3K4me3 and DMC1 reads tend to originate from only one homologue. At these hotspots, we see an excess of DMC1 relative to H3K4me3, consistent with delayed DSB repair at these sites. See Davies et al. Nature 2016 for a complete summary.

Project description:Nucleosomes in active chromatin are dynamic, but whether they have distinct structural conformations is unknown. To identify nucleosomes with alternative structures genome-wide, we used H4S47C-anchored cleavage mapping, which revealed that nucleosomes at 5% of budding yeast nucleosome positions have asymmetric histone-DNA interactions. These asymmetric interactions are enriched at nucleosome positions that flank promoters. Micrococcal nuclease (MNase) sequence-based profiles of asymmetric nucleosome positions revealed a corresponding asymmetry in MNase protection near the dyad axis, suggesting that the loss of DNA contacts around H4S47 is accompanied by protection of the DNA from MNase. Chromatin immunoprecipitation mapping of selected nucleosome remodelers indicated that asymmetric nucleosomes are bound by the RSC chromatin remodeling complex, which is required for maintaining nucleosomes at asymmetric positions. These results imply that the asymmetric nucleosome-RSC complex is a metastable intermediate representing partial unwrapping and protection of nucleosomal DNA on one side of the dyad axis during chromatin remodeling. We have analyzed the chromatin landscape of the yeast genome using paired-end MNase-seq and the chromatin binding of yeast remodelers Swr1, Ino80 and RSC at base-pair resolution using native chromatin immunoprecipitation followed by sequencing (N-ChIP-seq).

Project description:To identify yeast proteins associated with Ty1 integrase (IN) that could regulate Ty1 replication, we co-purified IN partners using the tandem chromatin affinity purification procedure after in vivo cross-link (TChAP), which we developed previously (Nguyen et al. 2014). We first identified RNA Pol I and Pol III complexes and also a small subset of additional evolutionary conserved complexes, including PAF1 (Polymerase-Associated Factor 1),FACT (FAcilitates Chromatin Transcription), the proteasome and the CK2 kinase. We next confirmed that CK2 interacts with Ty1 integrase in vivo and repress Ty1 retromobility. We showed that Ty1 IN is a substrate of CK2 in vitro and identified 12 phosphorylated residues. In vivo approaches showed that only part of the protein was phosphorylated in the cells and did not demonstrate any direct evidence between Ty1 IN phosphorylation and retromobility inhibition.

Project description:Transposon reactivation is an inherent danger in cells that lose epigenetic silencing during developmental reprogramming. In the mouse, LTR-retrotransposons, or endogenous retroviruses (ERV), account for most novel insertions and are expressed in the absence of histone H3 Lysine 9 trimethylation in preimplantation stem cells. We found abundant, 18 nt tRNA-derived small RNA (tRF) in these cells, and ubiquitously expressed 22 nt tRFs, that include the 3' terminal CCA of mature tRNAs, and target the tRNA primer binding site (PBS) essential for ERV reverse transcription. We show that the two most active ERV families, IAP and MusD/ETn, are major targets and are strongly inhibited by tRFs in retrotransposition assays. 22 nt tRFs post-transcriptionally silence coding-competent ERVs, while 18 nt tRFs specifically interfere with reverse transcription and retrotransposon mobility. The PBS offers a unique target to specifically inhibit LTR-retrotransposons and tRF-targeting is a potentially highly conserved mechanism of small RNA-mediated transposon control.