Project description:Mouse heterochromatin is characterized by transcriptionally competent major satellite repeat (MSR) sequences and it has been proposed that MSR repeat RNA contributes to the integrity of heterochromatin. We established an inducible dCas9-effector system in mouse embryonic fibroblasts, where we can target dCas9-VPR (transcriptional activator) and dCas9-KM (transcriptional repressor) to MSR repeat sequences. We show that induction of dCas9-VPR forces significant MSR RNA output, while induction of dCas9-KM silences MSR transcription. Both approaches perturb heterochromatin organization, where the dCas9-VPR leads to an immediate dispersion of heterochromatin and dCas9-KM induction results in a delayed aggregation of heterochromatin. MEF cells with the forced expression of MSR RNA are not viable and the defects in heterochromatin organization cannot be reverted. This study highlights the importance of restricting MSR RNA output to maintain heterochromatin integrity and also reveals that the structural organization of heterochromatin is governed by the transcriptional state of the underlying MSR repeats.

Project description:Forced expression of MSR repeat transcripts above a threshold limit breaks heterochromatin organization

Project description:Forced expression of MSR repeat transcripts breaks heterochromatin organization

Project description:To establish effective multitargeted KRAS pathway therapy, we analyzed mediators of acquired resistance to chronic momelotinib and MEK inhibitor exposure in A549 cells. Since inhibitor resistance was completely reversible after drug withdrawal for several passages, suggesting epigenetic reprogramming, we investigated whole mRNA expression profiles in A549, momelotinib and selumetinib resistant (MSR)-A549 cells and MSR-A549 cells following drug withdrawal for 10 days. In parallel, we also examined mRNA expression profiles of MSR-A549 cells treated with the BET inhibitor JQ1, to identify specific targets regulated by H3K27 acetylation.

Project description:Magnetospirillum gryphiswaldense MSR-1 - Genome resequencing and assembly

Project description:A549 cells and MSR-A549 cells

Project description:Transcriptome analysis of Magnetospirillum gryphiswaldense MSR-1 cultivated under aerobic and microaerobic condition

Project description:To establish effective multitargeted KRAS pathway therapy, we analyzed mediators of acquired resistance to chronic momelotinib and MEK inhibitor exposure in A549 cells. Since inhibitor resistance was completely reversible after drug withdrawal for several passages, suggesting epigenetic reprogramming, we examined genome-wide H3K27 histone acetylation in parental A549 and momelotinib and selumetinib resistant (MSR)-A549 cells.

Project description:Engineered mischarged transfer RNAs for correcting pathogenic missense mutations [MSR-seq]

Project description:Antigen Ki-67 is a nuclear protein expressed in proliferating mammalian cells. It is widely used in cancer histopathology but its functions remain unclear. Here, we show that Ki-67 controls heterochromatin organisation. Altering Ki-67 expression levels did not significantly affect cell proliferation in vivo. Ki-67 mutant mice developed normally and cells lacking Ki-67 proliferated efficiently. Conversely, upregulation of Ki-67 expression in differentiated tissues did not inhibit cell cycle arrest. Ki-67 interactors included proteins involved in nucleolar processes and chromatin regulators. Ki-67 depletion disrupted nucleologenesis but did not inhibit pre-rRNA processing. In contrast, it altered gene expression. Ki-67 silencing also had wide-ranging effects on chromatin organisation, disrupting heterochromatin compaction and long-range genomic interactions. Trimethylation of histone H3K9 and H4K20 at heterochromatin was strongly reduced. Overexpression of human or Xenopus Ki-67 induced ectopic heterochromatin formation. Altogether, our results suggest that Ki-67 expression in proliferating cells spatially organises heterochromatin, thereby controlling gene expression.