Project description:Although higher-order genome organization is tissue-specific, its functional relevance and mechanistic basis are poorly understood. Here we analyzed the dynamics of chromatin interactions for lineage-specific cytokine loci during T helper (Th) differentiation. The naive-to-effector transition is accompanied by a profound shift from promiscuous to highly selective and functionally enriched genome-wide contacts. Despite the establishment of divergent interactomes and global reprogramming of transcription in Th1 versus Th2 commitment, the overall expression status of the contact genes is surprisingly similar between the two lineages. Importantly, the genomic contacts are retained and strengthened precisely at DNA binding sites of the specific lineage-determining STAT transcription factor. The global aggregation of STAT binding loci from genic and non-genic regions highlights a new role for differentiation-promoting transcription factors in direct specification of higher-order nuclear architecture through interacting with regulatory regions. Such subnuclear environments have implications for efficient functioning of the mature effector lymphocytes. Nineteen arrays total: Eighteen microarrays from individual biological replicates, one microarray from a pool of two biological replicates.

Project description:Emerging evidence indicates that various cancers, including prostate, breast, melanoma and lung cancers, could gain resistance to targeted therapies by acquiring lineage plasticity. Although various genomic and transcriptomic aberrations correlate with lineage plasticity-driven resistance, the molecular mechanisms and kinetics of acquiring lineage plasticity are not fully elucidated. Through integrated transcriptomic and single cell RNA-seq (scRNA-seq) analysis of more than 80,000 cells, we show that the ectopic activation of Janus kinase (JAK)-signal transducer and activator of transcription (STAT) pathway drives lineage plasticity and Androgen Receptor (AR) targeted therapy resistance in PCa with TP53/RB1-deficiency. Ectopic activation of JAK-STAT signaling enables Heterogeneous and AR-independent subclones to emerge upon the selective pressure of AR targeted therapy, including subclones expressing multi-lineage, progenitor-like and epithelial to mesenchymal transition (EMT)-like lineage survival transcriptional programs. Both genetic and pharmaceutical inactivation of key components of the JAK-STAT signaling pathway significantly re-sensitizes resistant PCa tumors to AR targeted therapy. In summary, these results show for the first time that JAK-STAT signaling pathway is a key effector in driving lineage plasticity and represents a potential therapeutic target for overcoming AR targeted therapy resistance.

Project description:T cells trigger non-specific signaling pathways to elicit specialized effector functions to eliminate pathogens and cancers. Chromatin accessibility at T effector loci prior to antigen encounter poises cells to couple antigen recognition to the activation of lineage-specific responses. Here, by tracing the chromatin accessibility profiles unique to T effector functions during development, we find that the majority of T effector loci become accessible prior to antigen receptor expression. Epigenomic feature analysis, biochemical studies, and inducible perturbations identified two mechanistic linchpins: the physical association of the mSWI/SNF remodeling complex to the pleiotropic transcription factor (TF) RUNX1, and the cooperativity between RUNX1 and lineage-defining TFs PU.1 and BCL11B that respectively facilitate the establishment and maintenance of chromatin accessibility at T effector loci in early thymocyte progenitors. These findings reflect a design principle that allows distinct cell types to use the same signaling pathways to execute disparate roles which collectively orchestrate the immune response.

Project description:T cells trigger non-specific signaling pathways to elicit specialized effector functions to eliminate pathogens and cancers. Chromatin accessibility at T effector loci prior to antigen encounter poises cells to couple antigen recognition to the activation of lineage-specific responses. Here, by tracing the chromatin accessibility profiles unique to T effector functions during development, we find that the majority of T effector loci become accessible prior to antigen receptor expression. Epigenomic feature analysis, biochemical studies, and inducible perturbations identified two mechanistic linchpins: the physical association of the mSWI/SNF remodeling complex to the pleiotropic transcription factor (TF) RUNX1, and the cooperativity between RUNX1 and lineage-defining TFs PU.1 and BCL11B that respectively facilitate the establishment and maintenance of chromatin accessibility at T effector loci in early thymocyte progenitors. These findings reflect a design principle that allows distinct cell types to use the same signaling pathways to execute disparate roles which collectively orchestrate the immune response.

Project description:T cells trigger non-specific signaling pathways to elicit specialized effector functions to eliminate pathogens and cancers. Chromatin accessibility at T effector loci prior to antigen encounter poises cells to couple antigen recognition to the activation of lineage-specific responses. Here, by tracing the chromatin accessibility profiles unique to T effector functions during development, we find that the majority of T effector loci become accessible prior to antigen receptor expression. Epigenomic feature analysis, biochemical studies, and inducible perturbations identified two mechanistic linchpins: the physical association of the mSWI/SNF remodeling complex to the pleiotropic transcription factor (TF) RUNX1, and the cooperativity between RUNX1 and lineage-defining TFs PU.1 and BCL11B that respectively facilitate the establishment and maintenance of chromatin accessibility at T effector loci in early thymocyte progenitors. These findings reflect a design principle that allows distinct cell types to use the same signaling pathways to execute disparate roles which collectively orchestrate the immune response.

Project description:Interleukin-23 (IL-23) is a pro-inflammatory cytokine required for the pathogenicity of T helper 17 (Th17) cells but the molecular mechanisms governing this process remain unclear. We identified the transcription factor Blimp-1 (Prdm1) as a key IL-23-induced factor that drove the inflammatory function of Th17 cells. In contrast to thymic deletion of Blimp-1, which causes T cell development defects and spontaneous autoimmunity, peripheral deletion of this transcription factor resulted in reduced Th17 activation and reduced severity of autoimmune encephalomyelitis. Furthermore, genome wide occupancy and overexpression studies in Th17 cells revealed that Blimp-1 co-localized with transcription factors RORγt, STAT-3 and p300 at the Il23r, Il17a/f and Csf2 cytokine loci to enhance their expression. Blimp-1 also directly bound to and repressed cytokine loci Il2 and Bcl6. Taken together, our results demonstrate that Blimp-1 is an essential transcription factor downstream of IL-23 that acts in concert with RORγt to activate the Th17 inflammatory program. Genome-wide binding analysis of Blimp1 from in vitro generated T effector and regulatory cells

Project description:Congenital heart disease (CHD) is a leading cause of infant mortality in the US and is commonly thought to arise from perturbations of transcription factors (TFs) during cardiac development. ISLET1 (ISL1) is one such TF, although it also directs differentiation of other cell types, including motor neuron progenitors (MNPs) and pancreatic islet cells. Although cellular specificity of ISL1 function is likely achieved through combinatorial interactions, its essential cardiac interacting partners are unknown. By assaying ISL1 genomic occupancy in human iPSC-derived cardiac progenitors (CPs) or MNPs and leveraging the deep learning approach BPNet, we identified cell-type-specific motifs of other TFs that predicted ISL1 occupancy in each lineage, with the NKX2.5 motif being most closely associated to ISL1 in CPs. We demonstrated ISL1 forms a protein complex with NKX2.5 in CPs, and the two regulated similar gene networks. NKX2.5 co-occupied more than half of ISL1-bound loci, and ISL1 was dependent on NKX2.5 for CP-specific localization. Furthermore, overexpression of NKX2.5 in MNPs led to ISL1 redistribution to CP-specific loci. These results reveal how ISL1 can guide differential lineage choices through a combinatorial code that dictates genomic occupancy and transcription.

Project description:Mammalian interphase chromosomes interact with the nuclear lamina (NL) through hundreds of large Lamina Associated Domains (LADs). We report a method to map NL contacts genome-wide in single human cells. Analysis of ~400 maps reveals a core architecture of gene-poor LADs that contact the NL with high cell-to-cell consistency, interspersed by LADs with more variable NL interactions. The variable contacts are more sensitive to a change in genome ploidy than the consistent contacts. Single-cell maps indicate that NL contacts involve multivalent interactions over hundreds of kilobases. Moreover, we observe extensive intra-chromosomal coordination of NL contacts, even over tens of megabases. Such coordinated loci exhibit preferential interactions as detected by Hi-C. Finally, single-cell gene expression and chromatin accessibility analysis shows that loci with consistent NL contacts are expressed at lower levels and are more consistently inaccessible than loci with lower contact frequencies. These results highlight fundamental principles of single cell chromatin organization. Hi-C Data

Project description:Long-range chromosomal interaction is an important mechanism by which differentiating cells organise three dimensional promoter-enhancer networks to regulate lineage-specifying, developmental, regulatory genes1,2. Distal promoter contacts in pluripotent stem and specialised cell types, such as foetal liver cells, form co-regulated gene networks correlated with their biological functions1. Promoter interactomes of 17 primary blood cell types also reflect high cell-type specificity3. The lineage-specifying promoter interactions can be constrained by polycomb repressive complexes and genes with specialised functions will be selectively released from this poised network during cell fate specification or differentiation2. The cis-regulatory contact upon lineage commitment is also a dynamic process that includes acquisition and loss of specific promoter interactions4. We characterise 5126 promoter-enhancer interactions specific to cardiomyocytes differentiated from human embryonic stem cells (hESC-CM) by performing a differential promoter capture Hi-C (PCHi-C)5 approach that allows physical promoter-enhancer contacts in hESC-CM to be identified against the background level of embryonic stem cells’ interactions. This approach enables us to extract key genomic regulators and their target genes highly specific to the cardiovascular development and functions.

Project description:Mapping proteomic composition at distinct genomic loci and subnuclear landmarks in living cells has been a long-standing challenge. Here we report that dCas9-APEX2 Biotinylation at genomic Elements by Restricted Spatial Tagging (C-BERST) allows the unbiased mapping of proteomes near defined genomic loci, as demonstrated for telomeres and centromeres. C-BERST enables the high-throughput identification of proteins associated with specific sequences, facilitating annotation of these factors and their roles in nuclear and chromosome biology.