Project description:Some transcription factors (TFs) can form liquid-liquid phase separated (LLPS) condensates. However, the function of these TF condensates in 3D genome organization and gene regulation remains elusive. In response to methionine (met) starvation in budding yeast, Met4 and a few sequence-specific co-activators, including Met32, induce a set of genes involved in met biosynthesis. Here, we show that the endogenous Met4 and Met32 form puncta-like structures that significantly overlap in yeast nuclei upon met depletion. Recombinant Met4 and Met32 form mixed droplets with LLPS properties in vitro. In relation to chromatin, Met4 puncta co-localize with target genes, and at least a subset of these target genes are clustered in 3D in a Met4-dependent manner. A MET3pr-GFP reporter inserted near several native Met4 binding sites becomes co-localized with Met4 puncta and displays enhanced transcriptional activity. A Met4 variant with a partial truncation of an intrinsically disordered region (IDR) shows less puncta formation, and this mutant selectively reduces the reporter activity near Met4 binding sites to the basal level. Overall, these results support a model where Met4 and co-activators form condensates to bring multiple target genes into a vicinity with higher local TF concentrations, which facilitates a strong response to met depletion (-met).

Project description:In this study, C. albicans regulates its methionine biosynthetic pathways using the transcription factors Met4 and Cbf1. This circuitry appears more complex than that of filamentous fungi, which use orthologs of the Met4 transcription factor, but lack versions of Cbf1, but is considerably less complex than that of S. cerevisiae, which 2 requires two transcription complexes, involving Cbf1 and Met31/32 as DNA binding modules, and Met4 and the Met4 ortholog Met28 as co-activators, to regulate Met biosynthesis. Although C. albicans contains Met31/32 and Met28 orthologs, they do not appear to be linked to regulation of the methionine circuit. Thus, the phylogenetic progression from filamentous fungi to S. cerevisiae is characterized by increasing complexity of the regulators, although the structural elements of the pathways are fundamentally the same.

Project description:HIPPO-YAP/TAZ signaling has been implicated in supratentorial ependymoma formation from neural progenitor cells (NPC) in the brain, however, the underlying mechanisms to trigger the neural progenitor cell transformation remains elusive. Here, we uncover that patient-derived tumorigenic YAP-fusion proteins (YAP-MAMLD1 and C11ORF95-YAP) promote ependymoma tumorigenesis through forming liquid-liquid phase-separated condensates. Intrinsically disordered regions (IDR) in the fusion proteins promote oligomerization of YAP-transcriptional co-activators and self-assembly of nuclear puncta-like membrane-less organelles. Phase separation of YAP-fusion proteins further facilitates the compartmentalization of transcriptional coactivators, BRD4 and MED1, resulting in pervasive enhancer landscape changes and exclusion of transcriptional repressors such as PRC2 complexes. YAP-fusion proteins-induced nuclear puncta recruit RNA polymerase II to promote transcriptional bursting of multiple oncogenic pathways. Moreover, we show that IDR-mediated phase separation is necessary for YAP-fusion protein-induced tumor formation. Distinct YAP fusion-proteins identified in other human tumors also encompass IDR features. Together, our data suggest that IDR-mediated phase separation is an integral component of YAP-fusion protein-induced tumorigenesis and might serve as a therapeutic target in supratentorial ependymoma.

Project description:HIPPO-YAP/TAZ signaling has been implicated in supratentorial ependymoma formation from neural progenitor cells (NPC) in the brain, however, the underlying mechanisms to trigger the neural progenitor cell transformation remains elusive. Here, we uncover that patient-derived tumorigenic YAP-fusion proteins (YAP-MAMLD1 and C11ORF95-YAP) promote ependymoma tumorigenesis through forming liquid-liquid phase-separated condensates. Intrinsically disordered regions (IDR) in the fusion proteins promote oligomerization of YAP-transcriptional co-activators and self-assembly of nuclear puncta-like membrane-less organelles. Phase separation of YAP-fusion proteins further facilitates the compartmentalization of transcriptional coactivators, BRD4 and MED1, resulting in pervasive enhancer landscape changes and exclusion of transcriptional repressors such as PRC2 complexes. YAP-fusion proteins-induced nuclear puncta recruit RNA polymerase II to promote transcriptional bursting of multiple oncogenic pathways. Moreover, we show that IDR-mediated phase separation is necessary for YAP-fusion protein-induced tumor formation. Distinct YAP fusion-proteins identified in other human tumors also encompass IDR features. Together, our data suggest that IDR-mediated phase separation is an integral component of YAP-fusion protein-induced tumorigenesis and might serve as a therapeutic target in supratentorial ependymoma.

Project description:Development of cancer is intimately associated with genetic abnormalities that target proteins with intrinsically disordered regions (IDRs). In human hematological malignancies, recurrent chromosomal translocation of nucleoporin (NUP98 or NUP214) generates an aberrant chimera that invariably retains nucleoporin?s IDR, tandemly dispersed phenylalanine-and-glycine (FG) repeats. However, it remains elusive how unstructured IDRs contribute to oncogenesis. We show that IDR harbored within NUP98-HOXA9, a homeodomain-containing transcription factor (TF) chimera recurrently detected in leukemias, is essential for establishing liquid-liquid phase separation (LLPS) puncta of chimera and for inducing leukemic transformation. Strikingly, LLPS of NUP98-HOXA9 not only promotes chromatin occupancy of chimera TFs but is also required for formation of a broad, ?super-enhancer?-like binding pattern, typically seen at a battery of leukemogenic genes, potentiating their transcriptional activation. Artificial HOX chimera (FUS-HOXA9), created by replacing NUP98?s FG repeats with an unrelated LLPS-forming IDR of FUS, had similar enhancement effects on chimera?s genome-wide binding and target gene activation. Hi-C mapping further demonstrated that phase-separated NUP98-HOXA9 induces CTCF-independent chromatin looping enriched at proto-oncogenes. Together, this report describes a proof-of-principle example wherein cancer acquires mutation to establish oncogenic TF condensates via phase separation, which simultaneously enhances their genomic targeting and induces organization of aberrant three-dimensional chromatin structure during tumorous transformation. As LLPS-competent molecules are frequently implicated in diseases, this mechanism can potentially be generalized to many malignant and pathological settings.

Project description:Development of cancer is intimately associated with genetic abnormalities that target proteins with intrinsically disordered regions (IDRs). In human hematological malignancies, recurrent chromosomal translocation of nucleoporin (NUP98 or NUP214) generates an aberrant chimera that invariably retains nucleoporin?s IDR, tandemly dispersed phenylalanine-and-glycine (FG) repeats. However, it remains elusive how unstructured IDRs contribute to oncogenesis. We show that IDR harbored within NUP98-HOXA9, a homeodomain-containing transcription factor (TF) chimera recurrently detected in leukemias, is essential for establishing liquid-liquid phase separation (LLPS) puncta of chimera and for inducing leukemic transformation. Strikingly, LLPS of NUP98-HOXA9 not only promotes chromatin occupancy of chimera TFs but is also required for formation of a broad, ?super-enhancer?-like binding pattern, typically seen at a battery of leukemogenic genes, potentiating their transcriptional activation. Artificial HOX chimera (FUS-HOXA9), created by replacing NUP98?s FG repeats with an unrelated LLPS-forming IDR of FUS, had similar enhancement effects on chimera?s genome-wide binding and target gene activation. Hi-C mapping further demonstrated that phase-separated NUP98-HOXA9 induces CTCF-independent chromatin looping enriched at proto-oncogenes. Together, this report describes a proof-of-principle example wherein cancer acquires mutation to establish oncogenic TF condensates via phase separation, which simultaneously enhances their genomic targeting and induces organization of aberrant three-dimensional chromatin structure during tumorous transformation. As LLPS-competent molecules are frequently implicated in diseases, this mechanism can potentially be generalized to many malignant and pathological settings.

Project description:Polycomb-repressive complex 1 (PRC1) has a constraining influence on 3D genome organization, mediating localized and chromosome-wide clustering of target loci. Polycomb-bound regions form transcriptionally repressive chromatin domains independent of topologically associating domains (TADs). Several subunits of PRC1 have the capacity to form biomolecular condensates through liquid-liquid phase separation (LLPS) in vitro and when tagged and over-expressed in cells. Here, we use 1,6 hexandiol (1,6-HD), which disrupts liquid-like condensates, to examine the role of endogenous PRC1 biomolecular condensates on local and chromosome-wide clustering of PRC1-bound loci. Using imaging and chromatin immunoprecipitation combined with deep sequencing (ChIP-seq) analyses, we show that PRC1-mediated localized chromatin compaction and clustering of targeted genomic loci at megabase and tens of megabase scales can be reversibly disrupted by the addition and subsequent removal of 1,6-HD to mouse embryonic stem cells (mESCs). Decompaction and dispersal of polycomb domains and clusters cannot be solely attributable to the reduction of PRC1 binding following 1,6-HD treatment as the addition of 2,5-HD has similar effects despite this alcohol not perturbing PRC1-mediated clustering, at least at the sub-megabase and megabase scales. These results suggest that weak, hydrophobic interactions between PRC1 molecules characteristic of liquid condensates do have a role in polycomb-mediated genome organization.

Project description:Super-enhancers (SEs) are clusters of enhancers that cooperatively assemble a high density of transcriptional apparatus to drive robust expression of genes with prominent roles in cell identity. We recently proposed that a phase-separated multi-molecular assembly underlies the formation and function of SEs. Here, we demonstrate that the SE-enriched factors BRD4 and MED1 form nuclear puncta that occur at SEs and exhibit properties of liquid-like condensates. Disruption of BRD4 and MED1 puncta by 1,6-hexanediol is accompanied by a loss of BRD4 and MED1 at SEs and a loss of RNAPII from SE-driven genes. We find that the intrinsically disordered regions (IDRs) of BRD4 and MED1 are sufficient to form phase-separated droplets in vitro and the MED1 IDR promotes phase separation in living cells. The MED1 IDR droplets are capable of compartmentalizing BRD4 and other transcriptional machinery in nuclear extracts. These results support the idea that SEs form phase-separated condensates that compartmentalize the transcription apparatus at key genes, provide insights into the role of cofactor IDRs in this process, and offer new insights into mechanisms involved in control of key cell identity genes.

Project description:Super-enhancers (SEs) are clusters of enhancers that cooperatively assemble a high density of transcriptional apparatus to drive robust expression of genes with prominent roles in cell identity. We recently proposed that a phase-separated multi-molecular assembly underlies the formation and function of SEs. Here, we demonstrate that the SE-enriched factors BRD4 and MED1 form nuclear puncta that occur at SEs and exhibit properties of liquid-like condensates. Disruption of BRD4 and MED1 puncta by 1,6-hexanediol is accompanied by a loss of BRD4 and MED1 at SEs and a loss of RNAPII from SE-driven genes. We find that the intrinsically disordered regions (IDRs) of BRD4 and MED1 are sufficient to form phase-separated droplets in vitro and the MED1 IDR promotes phase separation in living cells. The MED1 IDR droplets are capable of compartmentalizing BRD4 and other transcriptional machinery in nuclear extracts. These results support the idea that SEs form phase-separated condensates that compartmentalize the transcription apparatus at key genes, provide insights into the role of cofactor IDRs in this process, and offer new insights into mechanisms involved in control of key cell identity genes.

Project description:Nuclear speckles (NSs) are nuclear biomolecular condensates that are postulated to arise through liquid-liquid phase separation (LLPS), although the detailed underlying forces driving NS formation remain elusive. SRRM2 and SON are 2 non-redundant scaffold proteins for NSs. How each individual protein governs assembly of NS protein network and the functional relationship between SRRM2 and SON are largely unknown. Here, we uncover immiscible multiphase of SRRM2 and SON within NSs. SRRM2 and SON are functionally independent, specifically regulating alternative splicing of subsets of mRNA targets, respectively. We further uncover that SRRM2 forms multicomponent liquid phase in cells to drive NS subcompartmentalization, which is reliant on homotypic interaction and heterotypic non-selective protein-RNA complex coacervation-driven multicomponent LLPS. SRRM2 RS domains form high-order oligomers, and can be replaced by oligomerizable synthetic modules, the serine residues within the RS domains, however, play an irreplaceable role in fine-tuning the liquidity of NSs.