Project description:Heterochromatin has crucial functions in protecting genome integrity. In mouse cells, heterochromatin is characterized by A/T-rich, 234 bp DNA repeat arrays, called the major satellite repeats (MSR). We investigated MSR expression in response to a variety of stress conditions by using small molecule compounds. We identified the isoflavone genistein to selectively derepress MSR transcription but not that of other DNA repeat elements. Genistein is a natural compound that is frequently used in dietary supplements and has been associated with reducing cancer risk. A 24 hrs exposure of mouse embryonic fibroblasts (MEF) to genistein results in a more than 100-fold induction of MSR transcripts. This derepression depends on the activity of RNA polymerase II and requires a cycling G1 cell population. Blocking the cell cycle at the G2/M stage significantly attenuates genistein- mediated derepression of MSR transcription. Mechanistically, DNA topoisomerase poisons phenocopy the genistein-dependent desilencing of MSR expression. Together, these data suggest that MSR transcriptional response is guided by an altered topology of the underlying A/T-rich MSR DNA repeat arrays. In addition, the data reveal a novel function for genistein in derepressing MSR transcription that may contribute to the growth inhibitory and anticancer properties of this natural compound.

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:Mouse heterochromatin is characterised by transcriptionally competent major satellite repeat (MSR) sequences and it has been proposed that MSR RNA contributes to the integrity of heterochromatin. We established an inducible dCas9-effector system in mouse embryonic fibroblasts, where we can modulate MSR transcription through the targeting of a dCas9-Repressor or a dCas9-Activator. With this system, we can define a threshold limit of >300-fold deregulation of MSR transcript levels, above which the structural organisation of heterochromatin becomes disrupted. MEF cells expressing MSR RNA above this threshold limit are not viable and the defects in heterochromatin organisation and chromosome segregation cannot be reverted. This study highlights the importance of restricting MSR RNA output to maintain heterochromatin integrity and relates MSR transcript levels to either physiological or pathological conditions. It also reveals that the structural organisation of heterochromatin is governed by the transcriptional chromatin state and associated MSR RNA of the MSR repeats.

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

Project description:Impaired DNA replication is a hallmark of cancer and a cause of genomic instability. We report that, in addition to causing genetic change, impaired DNA replication during embryonic development can have major epigenetic consequences for a genome. In a genome-wide screen, we identified impaired DNA replication as causing increased expression from a repressed transgene in Caenorhabditis elegans. The acquired expression state behaved as an “epiallele,” being inherited for multiple generations before fully resetting. Derepression was not restricted to the transgene but was caused by a global reduction in heterochromatin-associated histone modifications due to the impaired retention of modified histones on DNA during replication in the early embryo. Impaired DNA replication during development can therefore globally derepress chromatin, creating new intergenerationally inherited epigenetic expression states.

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

Project description:The assembly of repressive heterochromatin domains in eukaryotic genomes is crucial for silencing lineage-inappropriate genes and repetitive DNA elements. Paradoxically, transcription of repetitive elements within constitutive heterochromatin domains is required for RNA-based mechanisms, such as the RNAi pathway, to target heterochromatin assembly proteins. However, the mechanism by which heterochromatic repeat elements are transcribed has been unclear. Using fission yeast, we show that the conserved trimeric transcription factor (TF) PhpCNF-Y complex, which includes histone fold domain proteins, can infiltrate constitutive heterochromatin to transcribe repeat elements. PhpCNF-Y collaborates with a Zn-finger containing TF to bind heterochromatic repeat promoter regions with CCAAT boxes. Mutating either the TFs or the CCAAT binding site disrupts the transcription of heterochromatic repeats. Although repeat elements are transcribed from both strands, PhpCNF-Y-dependent transcripts originate from only one strand. These TF-driven transcripts contain cryptic introns that are processed via a mechanism requiring the spliceosome to generate small interfering RNAs (siRNAs) by the RNAi machinery. Our analyses show that siRNA production by this TF-mediated transcription pathway is critical for nucleation of heterochromatin at target repeat loci. This study reveals a mechanism by which heterochromatic repeats are transcribed, initiating their own silencing by triggering a primary cascade that produces siRNAs necessary for heterochromatin nucleation.

Project description:The aim of this study is to analyze the distribution of the modified histones in and around peri-centromeric heterochromatin at high resolutions for understanding the molecular nature of the heterochromatic genes and euchromatin-heterochromatin transition. Since heterochromatin is repeat-rich, stringent repeat-filtering was applied in the genome-tiling array design. When possible, parallel analyses were performed with two different types of reference controls, namely total genomic DNA and histone H3 C-terminus ChIP.

Project description:Gene expression profiling to identify genes significantly modulated by low and high doses of genistein in LNCaP cells. Significant genes were identified using StepMiner analysis and significantly altered pathways with Ingenuity Pathways analysis. Genistein significantly altered expression of transcripts involved in cell growth, carcinogen defenses and steroid signaling pathways. The effects of genistein on these pathways were confirmed by directly assessing dose-related effects on LNCaP cell growth, NQO-1 enzymatic activity and PSA protein expression. A compound treatment design type is where the response to administration of a compound or chemical (including biological compounds such as hormones) is assayed.

Project description:Histone H3 lysine 9 (H3K9) methylation is a central epigenetic modification that defines heterochromatin from unicellular to multicellular organisms. In mammalian cells, H3K9 methylation can be catalyzed by at least six distinct SET domain enzymes: Suv39h1/Suv39h2, Eset1/Eset2 and G9a/Glp. We used mouse embryonic fibroblasts (MEFs) with a conditional mutation for Eset1 and introduced progressive deletions for the other SET domain genes by CRISPR/Cas9 technology. Compound mutant MEFs for all 6 SET domain methyltransferase (KMT) genes lack all H3K9 methylation states, derepress nearly all families of repeat elements and display genomic instabilities. Strikingly, the 6KO H3K9 KMT MEFs no longer maintain heterochromatin organization and have lost electron-dense heterochromatin. This is the first analysis of H3K9 methylation deficient mammalian chromatin and reveals a crucial function for H3K9 methylation in protecting heterochromatin organization and genome integrity.