Project description:H3K9me3-heterochromatin, compacted by HP1 proteins, restricts transcription factor binding and functions as a barrier to cell fate changes in development and reprogramming1,2. To investigate principles underlying H3K9me3-heterochromatin maintenance in mammalian cells, we applied degron engineering3,4 on mouse ESCs to conditionally deplete all three H3K9me3-methyltransferases within one hour and found an unexpectedly dynamic nature of heterochromatin maintenance. Following H3K9me3 methyltransferases degradation, HP1β dissociates from heterochromatin within three hours, and transcription factors quickly access the de-compacted heterochromatin, activating transcription of their targets, which then promotes H3K9me3 decay. Both passive dilution and active removal contribute to the H3K9me3 decay. Mathematical modeling reveals distinct H3K9me3 heterochromatin states with diverse chromatin features which influence initial H3K9me3 levels and the stability of H3K9me3 domains, thereby expanding our understanding of distinct heterochromatin domains. Rampant transposable element de-repression interferes with transcription of poised early developmental and signaling genes outside H3K9me3-domains, highlighting the intricate roles of dynamic H3K9me3-heterochromatin maintenance in safeguarding developmental programs. Our findings deconvolve the hierarchical relationships between H3K9me3 marks, methyltransferases, HP1 and transcription factors to reveal principles of H3K9me3-heterochromatin maintenance and how its remodeling enables transcription and cell fate change.

Project description:H3K9me3-heterochromatin, compacted by HP1 proteins, restricts transcription factor binding and functions as a barrier to cell fate changes in development and reprogramming1,2. To investigate principles underlying H3K9me3-heterochromatin maintenance in mammalian cells, we applied degron engineering3,4 on mouse ESCs to conditionally deplete all three H3K9me3-methyltransferases within one hour and found an unexpectedly dynamic nature of heterochromatin maintenance. Following H3K9me3 methyltransferases degradation, HP1β dissociates from heterochromatin within three hours, and transcription factors quickly access the de-compacted heterochromatin, activating transcription of their targets, which then promotes H3K9me3 decay. Both passive dilution and active removal contribute to the H3K9me3 decay. Mathematical modeling reveals distinct H3K9me3 heterochromatin states with diverse chromatin features which influence initial H3K9me3 levels and the stability of H3K9me3 domains, thereby expanding our understanding of distinct heterochromatin domains. Rampant transposable element de-repression interferes with transcription of poised early developmental and signaling genes outside H3K9me3-domains, highlighting the intricate roles of dynamic H3K9me3-heterochromatin maintenance in safeguarding developmental programs. Our findings deconvolve the hierarchical relationships between H3K9me3 marks, methyltransferases, HP1 and transcription factors to reveal principles of H3K9me3-heterochromatin maintenance and how its remodeling enables transcription and cell fate change.

Project description:H3K9me3-heterochromatin, compacted by HP1 proteins, restricts transcription factor binding and functions as a barrier to cell fate changes in development and reprogramming1,2. To investigate principles underlying H3K9me3-heterochromatin maintenance in mammalian cells, we applied degron engineering3,4 on mouse ESCs to conditionally deplete all three H3K9me3-methyltransferases within one hour and found an unexpectedly dynamic nature of heterochromatin maintenance. Following H3K9me3 methyltransferases degradation, HP1β dissociates from heterochromatin within three hours, and transcription factors quickly access the de-compacted heterochromatin, activating transcription of their targets, which then promotes H3K9me3 decay. Both passive dilution and active removal contribute to the H3K9me3 decay. Mathematical modeling reveals distinct H3K9me3 heterochromatin states with diverse chromatin features which influence initial H3K9me3 levels and the stability of H3K9me3 domains, thereby expanding our understanding of distinct heterochromatin domains. Rampant transposable element de-repression interferes with transcription of poised early developmental and signaling genes outside H3K9me3-domains, highlighting the intricate roles of dynamic H3K9me3-heterochromatin maintenance in safeguarding developmental programs. Our findings deconvolve the hierarchical relationships between H3K9me3 marks, methyltransferases, HP1 and transcription factors to reveal principles of H3K9me3-heterochromatin maintenance and how its remodeling enables transcription and cell fate change.

Project description:Domains of transcriptionally repressed heterochromatin, decorated by histone 3 lysine 9 trimethylation (H3K9me3), are reduced in embryonic stem cells compared to fully differentiated cells. However, the establishment and dynamics of closed regions of chromatin at protein coding genes, in natural embryologic development, has not been described. We developed a novel, antibody-independent method to isolate and map compacted heterochromatin from low cell number samples. Unexpectedly, we uncovered extensive high levels of H3K9me3-decorated, compacted heterochromatin at protein coding genes in early, uncommitted cells in the three germ layers, undergoing profound rearrangements and reduction upon differentiation, concomitant with cell type-specific gene expression. Perturbation of the three H3K9me3-related methyltransferases revealed that H3K9me3 heterochromatin is required to maintain cell lineage fidelity. We propose a key role for chromatin-based restriction of gene activity via H3K9me3 during embryologic development

Project description:Domains of transcriptionally repressed heterochromatin, decorated by histone 3 lysine 9 trimethylation (H3K9me3), are reduced in embryonic stem cells compared to fully differentiated cells. However, the establishment and dynamics of closed regions of chromatin at protein coding genes, in natural embryologic development, has not been described. We developed a novel, antibody-independent method to isolate and map compacted heterochromatin from low cell number samples. Unexpectedly, we uncovered extensive high levels of H3K9me3-decorated, compacted heterochromatin at protein coding genes in early, uncommitted cells in the three germ layers, undergoing profound rearrangements and reduction upon differentiation, concomitant with cell type-specific gene expression. Perturbation of the three H3K9me3-related methyltransferases revealed that H3K9me3 heterochromatin is required to maintain cell lineage fidelity. We propose a key role for chromatin-based restriction of gene activity via H3K9me3 during embryologic development

Project description:Domains of transcriptionally repressed heterochromatin, decorated by histone 3 lysine 9 trimethylation (H3K9me3), are reduced in embryonic stem cells compared to fully differentiated cells. However, the establishment and dynamics of closed regions of chromatin at protein coding genes, in natural embryologic development, has not been described. We developed a novel, antibody-independent method to isolate and map compacted heterochromatin from low cell number samples. Unexpectedly, we uncovered extensive high levels of H3K9me3-decorated, compacted heterochromatin at protein coding genes in early, uncommitted cells in the three germ layers, undergoing profound rearrangements and reduction upon differentiation, concomitant with cell type-specific gene expression. Perturbation of the three H3K9me3-related methyltransferases revealed that H3K9me3 heterochromatin is required to maintain cell lineage fidelity. We propose a key role for chromatin-based restriction of gene activity via H3K9me3 during embryologic development

Project description:Histone H3 trimethylation of lysine 9 (H3K9me3) and heterochromatin proteins 1 (HP1) are hallmarks of heterochromatin, a state of compacted DNA essential for genome stability and long-term transcriptional silencing. The mechanisms by which H3K9me3 and HP1 contribute to chromatin compaction have been speculative and controversial. We demonstrate that mammalian HP1β is a prototypic HP1 protein exemplifying most basal chromatin binding and effects. These are caused by dimeric and dynamic interaction with highly enriched H3K9me3 and are modulated by various electrostatic interfaces. Via internucleosomal bridging HP1β specifically interacts with condensed chromatin, which we postulate stabilizes the compacted state. In agreement, HP1β genome-wide localization follows enrichment of H3K9me3 and bridging of chromatin fibers in a cellular context is sufficient for maintaining heterochromatic conformation. Overall, our findings define a fundamental mechanism for chromatin higher order structural changes caused by HP1 proteins, which may contribute to the plastic nature of condensed chromatin.

Project description:Both RNAi-dependent and -independent mechanisms have been implicated in the establishment of heterochromatin domains, which may be stabilized by feedback loops involving chromatin proteins and modifications of histones and DNA. Neurospora crassa sports features of heterochromatin found in higher eukaryotes, namely cytosine methylation (5mC), methylation of histone H3 lysine9 (H3K9me) and HETEROCHROMATIN PROTEIN-1 (HP1), and provides a model to investigate heterochromatin establishment and maintenance. We mapped the distribution of HP1, 5mC, H3K9me3 and H3K4me2 at 100bp-resolution and explored their interplay. HP1, H3K9me3 and DNA methylation were extensively colocalized and defined 44 heterochromatic domains on linkage group VII, all relics of repeat-induced point mutation (RIP). Interestingly, the centromere was found in a striking ~350kb heterochromatic domain with no detectable H3K4me2. 5mC was not found in genes, in contrast to the situation in plants and animals. H3K9me3 is required for HP1 localization and DNA methylation. Here, we show that localization of H3K9me3 is independent of 5mC or HP1 at virtually all heterochromatin regions. In addition, we observed complete restoration of DNA methylation patterns after depletion and reintroduction of the H3K9 methylation machinery, indicating that the signals for de novo heterochromatin formation lie upstream of H3K9 methylation. These data show that A:T rich RIP’d DNA efficently directs methylation of H3K9, which in turn, directs methylation of associated cytosines. Immunoprecipitation experiments using antibodies to 5mC, H3K9me3, epitope-tagged HP1, and H3K4me2 were performed. The immunoprecipitate fraction was labeled with Cy5 and the total input was labeled with Cy3. Samples were hybridized to a N. crassa LGVII tiling path microarray.

Project description:Gene silencing by heterochromatin plays crucial roles in cell identity and development. However, the function of heterochromatin components is not fully understood. Here, we characterize the localization, the biogenesis and the function of an atypical heterochromatin, which is simultaneously enriched in the typical heterochromatin mark H3K9me3 as well as in H3K36me3, histone mark usually associated with gene expression. This dual heterochromatin forms on 3,015 regions in the genome of mouse embryonic stem cells and relies on the histone methyltransferases SET Domain Bifurcated 1 (SETDB1) and Nuclear Set Domain containing proteins (NSD) to generate H3K9me3 and H3K36me3, respectively. Upon SETDB1 removal, dual domains loose both trimethyl marks, gain epigenomic signatures of active enhancers, and come into long range contact with upregulated genes, suggesting that it is a major pathway by which gene expression is controlled by heterochromatin. In differentiated tissues, a large subset of these dual domains is destabilized and become enriched in active enhancer marks, providing a mechanistic insight into the involvement of heterochromatin in development and the maintenance of cell identity.

Project description:Both RNAi-dependent and -independent mechanisms have been implicated in the establishment of heterochromatin domains, which may be stabilized by feedback loops involving chromatin proteins and modifications of histones and DNA. Neurospora crassa sports features of heterochromatin found in higher eukaryotes, namely cytosine methylation (5mC), methylation of histone H3 lysine9 (H3K9me) and HETEROCHROMATIN PROTEIN-1 (HP1), and provides a model to investigate heterochromatin establishment and maintenance. We mapped the distribution of HP1, 5mC, H3K9me3 and H3K4me2 at 100bp-resolution and explored their interplay. HP1, H3K9me3 and DNA methylation were extensively colocalized and defined 44 heterochromatic domains on linkage group VII, all relics of repeat-induced point mutation (RIP). Interestingly, the centromere was found in a striking ~350kb heterochromatic domain with no detectable H3K4me2. 5mC was not found in genes, in contrast to the situation in plants and animals. H3K9me3 is required for HP1 localization and DNA methylation. Here, we show that localization of H3K9me3 is independent of 5mC or HP1 at virtually all heterochromatin regions. In addition, we observed complete restoration of DNA methylation patterns after depletion and reintroduction of the H3K9 methylation machinery, indicating that the signals for de novo heterochromatin formation lie upstream of H3K9 methylation. These data show that A:T rich RIP’d DNA efficently directs methylation of H3K9, which in turn, directs methylation of associated cytosines.