Project description:We characterize the Polycomb system that assembles repressive subtelomeric domains of H3K27 methylation (H3K27me) in the yeast Cryptococcus neoformans. Purification of this PRC2-like protein complex reveals orthologs of animal PRC2 components as well as a chromodomain-containing subunit, Ccc1, which recognizes H3K27me. Whereas removal of either the EZH or EED ortholog eliminates H3K27me, disruption of mark recognition by Ccc1 causes H3K27me to redistribute. Strikingly, the resulting pattern of H3K27me coincides with domains of heterochromatin marked by H3K9me. Indeed, additional removal of the C. neoformans H3K9 methyltransferase Clr4 results in loss of both H3K9me and the redistributed H3K27me marks. These findings indicate that the anchoring of a chromatin-modifying complex to its product suppresses its attraction to a different chromatin type, explaining how enzymes that act on histones, which often harbor product recognition modules, may deposit distinct chromatin domains despite sharing a highly abundant and largely identical substrate—the nucleosome.

Project description:The protein Fused in Sarcoma undergoes liquid-liquid phase separation. To investigate whether this phase transition alters the RNA interactome we purified phase-separated FUS droplets and soluble FUS from HEK 293T cells transfected with GFP-tagged WT FUS or P525L FUS. Phase separated FUS was purified by fluorescence-activated particle sorting (droplets) and soluble FUS by co-Immunoprecipitation (IP) respectively followed by isolation of co-purified RNA. Here we show that phase separation affects the RNA interactome of FUS.

Project description:Gene expression is controlled by transcription factors (TFs) that consist of DNA-binding domains (DBDs) and activation domains (ADs). The DBDs have been well- characterized, but little is known about the mechanisms by which ADs effect gene activation. Here we report that diverse ADs form phase-separated condensates with the Mediator coactivator. For the OCT4 and GCN4 TFs, we show that the ability to form phase-separated droplets with Mediator in vitro and the ability to activate genes in vivo are dependent on the same amino acid residues. For the estrogen receptor (ER), a ligand-dependent activator, we show that estrogen enhances phase separation with Mediator, again linking phase separation with gene activation. These results suggest that diverse TFs can interact with Mediator through the phase-separating capacity of their ADs and that formation of condensates with Mediator is involved in gene activation.

Project description:Gene expression is controlled by transcription factors (TFs) that consist of DNA-binding domains (DBDs) and activation domains (ADs). The DBDs have been well- characterized, but little is known about the mechanisms by which ADs effect gene activation. Here we report that diverse ADs form phase-separated condensates with the Mediator coactivator. For the OCT4 and GCN4 TFs, we show that the ability to form phase-separated droplets with Mediator in vitro and the ability to activate genes in vivo are dependent on the same amino acid residues. For the estrogen receptor (ER), a ligand-dependent activator, we show that estrogen enhances phase separation with Mediator, again linking phase separation with gene activation. These results suggest that diverse TFs can interact with Mediator through the phase-separating capacity of their ADs and that formation of condensates with Mediator is involved in gene activation.

Project description:Heterochromatin Protein 1 (HP1) is a major regulator of chromatin structure and function. In animals, the network of proteins interacting with HP1 is mainly associated with constitutive heterochromatin marked by H3K9me3. HP1 physically interacts with the putative orthologue of the SNF2 chromatin remodeler ATRX, which controls deposition of the histone variant H3.3 in mammals. In Arabidopsis thaliana, we show that the orthologue of ATRX participates in H3.3 deposition and characterize the function of conserved domains of plant ATRX. We show that the plant Like HP1 (LHP1) interacts with ATRX through domains that evolved specifically in land plants ancestors. Interaction between ATRX and LHP1 affects the expression of a limited subset of genes controlled by the POLYCOMB REPRESSIVE COMPLEX 2 (PRC2), including the flowering time regulator FLC. In the context of flowering time, ATRX function requires the novel LHP1-interacting domain and the ATPase of the ATRX SNF2 helicase. We conclude that distinct evolutionary pathways led to interaction between ATRX and HP1 in mammals or its counterpart LHP1 in plants, resulting in distinct modes of transcriptional regulation.

Project description:Although Kdm1a is the most expressed histone demethylase in neurons, its molecular function in the adult brain remains unknown. Here, we found that inducible and forebrain-restricted knockout (ifKO) mice, in which Kdm1a is specifically eliminated in forebrain excitatory neurons during adulthood, display a prominent transcriptional and epigenomic dysregulation signature characterized by the neuronal expression of nonneuronal genes. The combination of super-resolution microscopy images and multi-omic analysis integrating transcriptome, epigenome and chromatin conformation data showed that these genes are target of the polycomb repressor complex 2 (PRC2) and locate in H3K27me3-microdomains encapsulated within the euchromatin compartment. Furthermore, functional assays revealed that both the catalytic activity and the N-terminus intrinsically disordered region of Kdm1a, which provides phase separation properties, are needed to maintain the boundaries between these silent micro-domains and the active chromatin environment. As a result, Kdm1a loss led to the spreading of active histone modifications into the PRC2-repressed genes causing their de-repression. Intriguingly, the investigation of aged mice suggested that these boundaries may also weaken during natural aging. Overall, these results underscore the role of Kdm1a safeguarding chromatin compartmentalization, nuclear phase separation and gene silencing in the adult and aging brain.

Project description:Liquid-liquid phase separation has drawn great attention as a physical process that mediates the formation of membraneless organelles in cells to coordinate biological reactions in space and time. Previously, it was proposed that the formation of phase-separated droplets is a unique property of HP1α. Here, we show that HP1β, but not HP1α and HP1ɤ, forms nucleosome dependent phase separated droplets. We demonstrate that H3K9me3 is required for HP1β dependent phase separation. Importantly, HP1β dependent phase separation regulates heterochromatin formation, thus controlling embryonic stem cells differentiation. In response to pluripotency exit, HP1β is phosphorylated at serine 89 recruiting KAP1, a pluripotency regulator, and sequestering it in the heterochromatin compartment. This induces changes in the level of pluripotency factors and triggers pluripotency exit. We propose that such a trapping mechanism creates a fast and dynamic mode of remote control of gene expression to regulate cell fate decisions solely based on membraneless organelles.

Project description:Components of the transcription machinery can undergo liquid-liquid phase separation, but the functional importance of phase-separated condensates in transcriptional control is not well understood. Here we report that disease-causing mutations in several transcription factors (TFs) alter the phase separation capacity of those TFs. We first demonstrate that the Hoxd13 TF, and its intrinsically disordered N-terminus form phase-separated condensates. Expansions of a polyalanine repeat, which cause hereditary synpolydactyly in humans, facilitate phase separation of Hoxd13, and alter the transcriptional program of several cell types in a cell-specific manner in vivo. Disease-associated expansions of aminoacid repeats in intrinsically disordered regions of other TFs were similarly found to alter phase separation. These results suggest that aberrant phase separation of transcriptional regulators may underlie a spectrum of human pathologies. The paper is available at https://doi.org/10.1016/j.cell.2020.04.018

Project description:Polycomb Repressive Complex 2 (PRC2) plays an essential role in development by catalysing trimethylation of histone H3 lysine 27 (H3K27me3), resulting in gene repression. PRC2 consists of two sub-complexes, PRC2.1 and PRC2.2, in which the PRC2 core associates with distinct ancillary subunits such as MTF2 and JARID2, respectively. Both MTF2, present in PRC2.1, and JARID2, present in PRC2.2, play a role in core PRC2 recruitment to target genes in mouse embryonic stem cells (mESCs). However, it remains unclear how these distinct sub-complexes cooperate to establish H3K27me3 domains. Here, we combine a range of Polycomb mutant mESCs with chemical inhibition of PRC2 catalytic activity, to systematically dissect their relative contributions to PRC2 binding to target loci. We find that PRC2.1 and PRC2.2 mediate two distinct paths for recruitment, with mutually reinforced binding. Part of the cross-talk between PRC2.1 and PRC2.2 occurs via their catalytic product H3K27me3, which is bound by the PRC2 core-subunit EED, thereby mediating a positive feedback. Strikingly, removal of either JARID2 or H3K27me3 only has a minor effect on PRC2 recruitment, whereas their combined ablation largely attenuates PRC2 recruitment. This strongly suggests an unexpected redundancy between JARID2 and EED-H3K27me3-mediated recruitment of PRC2. Furthermore, we demonstrate that all core PRC2 recruitment occurs through the combined action of MTF2-mediated recruitment of PRC2.1 to DNA and PRC1-mediated recruitment of JARID2-containing PRC2.2. Both axes of binding are supported by EED-H3K27me3 positive feedback, but to a different degree. Finally, we provide evidence that PRC1 and PRC2 mutually reinforce reciprocal binding. Together, these data disentangle the interdependent and cooperative interactions between Polycomb complexes that are important to establish Polycomb repression at target sites.

Project description:Polycomb Repressive Complex 2 (PRC2) plays an essential role in development by catalysing trimethylation of histone H3 lysine 27 (H3K27me3), resulting in gene repression. PRC2 consists of two sub-complexes, PRC2.1 and PRC2.2, in which the PRC2 core associates with distinct ancillary subunits such as MTF2 and JARID2, respectively. Both MTF2, present in PRC2.1, and JARID2, present in PRC2.2, play a role in core PRC2 recruitment to target genes in mouse embryonic stem cells (mESCs). However, it remains unclear how these distinct sub-complexes cooperate to establish H3K27me3 domains. Here, we combine a range of Polycomb mutant mESCs with chemical inhibition of PRC2 catalytic activity, to systematically dissect their relative contributions to PRC2 binding to target loci. We find that PRC2.1 and PRC2.2 mediate two distinct paths for recruitment, with mutually reinforced binding. Part of the cross-talk between PRC2.1 and PRC2.2 occurs via their catalytic product H3K27me3, which is bound by the PRC2 core-subunit EED, thereby mediating a positive feedback. Strikingly, removal of either JARID2 or H3K27me3 only has a minor effect on PRC2 recruitment, whereas their combined ablation largely attenuates PRC2 recruitment. This strongly suggests an unexpected redundancy between JARID2 and EED-H3K27me3-mediated recruitment of PRC2. Furthermore, we demonstrate that all core PRC2 recruitment occurs through the combined action of MTF2-mediated recruitment of PRC2.1 to DNA and PRC1-mediated recruitment of JARID2-containing PRC2.2. Both axes of binding are supported by EED-H3K27me3 positive feedback, but to a different degree. Finally, we provide evidence that PRC1 and PRC2 mutually reinforce reciprocal binding. Together, these data disentangle the interdependent and cooperative interactions between Polycomb complexes that are important to establish Polycomb repression at target sites.