Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:Cell fate specification occurs via coordinated transcriptional changes in pluripotent cells, resulting in progressive commitment towards distinct lineages. Lineage-specific transcription factors (TFs), through their intrinsic DNA-binding ability, operate as master orchestrators of early and late developmental processes by turning on select cis-regulatory enhancers and proximal promoter elements. TF binding ultimately drives recruitment of the basal transcriptional machinery that comprises RNA Polymerase II (RNAPII) and a host of polymerase-associated multiprotein complexes, including the metazoan-specific Integrator complex. Integrator is primarily known to modulate RNAPII processivity and to surveil RNA integrity. Here we show that a set of Integrator subunits (enhancer module) plays a direct role in cell fate specification by promoting epigenetic changes and TF binding at enhancer elements that drive neurogenesis and maintain neuronal cell identity. Depletion of a single Integrator subunit (INTS10) results in loss of molecular and morphological neuronal features, while diverting progenitor cells towards mesenchymal identity. Commissioning of developmental enhancers rely on Integrator’s enhancer module, which stabilizes SOX2 binding at chromatin upon exit from pluripotency. Integrator therefore operates as a functional bridge between enhancers and target promoters and is a driver of early developmental processes, providing new insight into a growing family of neurodevelopmental syndromes.

Project description:The transcription factor MYC is overexpressed in most cancers, where it drives multiple hallmarks of cancer progression. MYC is known to promote oncogenic transcription by binding to active promoters. In addition, MYC has also been shown to invade distal enhancers when expressed at oncogenic levels, but this enhancer binding has been proposed to have low gene-regulatory potential. Here, we demonstrate that MYC enhancer binding directly promotes cancer type-specific gene programs predictive of poor patient prognosis. MYC induces transcription of enhancer RNA through recruitment of RNAPII, rather than regulating RNAPII pause-release as is the case at promoters. This is mediated by MYC-induced H3K9 demethylation by KDM3A and acetylation by GCN5, leading to enhancer-specific BRD4 recruitment through its bromodomains, which facilitates RNAPII recruitment. Thus, we propose that MYC drives prognostic cancer type-specific gene programs by promoting RNAPII recruitment to enhancers through induction of an epigenetic switch.

Project description:RNA Polymerase II (RNAPII) controls expression of all protein coding genes and most noncoding loci in higher eukaryotes. Calibrating RNAPII activity requires an assortment of polymerase-associated factors that are recruited at sites of active transcription. The Integrator complex is one of the most elusive transcriptional regulators in metazoans, deemed to be recruited after initiation to help establish and modulate paused RNAPII. Integrator is known to be composed of 14 subunits that assemble and operate in a modular fashion. We employed proteomics and machine-learning structure prediction (AlphaFold2) to identify an additional Integrator subunit, INTS15. We report that INTS15 assembles primarily with the INTS13/INTS14/INTS10 module and interfaces with the Int-PP2A module. Functional genomics analysis further reveals a role for INTS15 in modulating RNAPII pausing at a subset of genes. Our study shows that omics approaches combined with AlphaFold2-based predictions provide additional insights into the molecular architecture of large and dynamic multiprotein complexes.

Project description:Transcription by RNA polymerase II (RNAPII) is pervasive in the human genome. However, the mechanisms controlling transcription at promoters and enhancers remain enigmatic. Here, we demonstrate that Integrator subunit 11 (INTS11), the catalytic subunit of the Integrator complex, regulates transcription at these loci through its endonuclease activity. Promoters of genes require INTS11 to cleave nascent transcripts associated with paused RNAPII and induce their premature termination in the proximity of the +1 nucleosome. The turnover of RNAPII permits the subsequent recruitment of an elongation-competent RNAPII complex, leading to productive elongation. In contrast, enhancers require INTS11 catalysis not to evict paused RNAPII but rather to terminate enhancer RNA transcription beyond the +1 nucleosome. These findings are supported by the differential occupancy of negative elongation factor (NELF), SPT5, and tyrosine-1-phosphorylated RNAPII. This study elucidates the role of Integrator in mediating transcriptional elongation at human promoters through the endonucleolytic cleavage of nascent transcripts and the dynamic turnover of RNAPII.

Project description:Transcription by RNA polymerase II (RNAPII) is pervasive in the human genome. However, the mechanisms controlling transcription at promoters and enhancers remain enigmatic. Here, we demonstrate that Integrator subunit 11 (INTS11), the catalytic subunit of the Integrator complex, regulates transcription at these loci through its endonuclease activity. Promoters of genes require INTS11 to cleave nascent transcripts associated with paused RNAPII and induce their premature termination in the proximity of the +1 nucleosome. The turnover of RNAPII permits the subsequent recruitment of an elongation-competent RNAPII complex, leading to productive elongation. In contrast, enhancers require INTS11 catalysis not to evict paused RNAPII but rather to terminate enhancer RNA transcription beyond the +1 nucleosome. These findings are supported by the differential occupancy of negative elongation factor (NELF), SPT5, and tyrosine-1-phosphorylated RNAPII. This study elucidates the role of Integrator in mediating transcriptional elongation at human promoters through the endonucleolytic cleavage of nascent transcripts and the dynamic turnover of RNAPII.