Project description:The ability of individual cells to maintain a distinct identity and respond to transient environmental signals requires tightly controlled regulation of gene networks. However, how discrete sets of gene regulators coordinate circuits that respond to extracellular cues remains poorly defined. The need for context-dependent regulation is prominent in human CD4+ T cells, where distinct cell lineages must respond to diverse signals to orchestrate effective adaptive immune responses and maintain homeostasis. Here, we performed CRISPR screens in multiple primary human CD4+ T cell contexts to identify regulators that control expression of IL2RA, which is a canonical marker of T cell activation in pro-inflammatory effector T cells (Teffs) and constitutively expressed in anti-inflammatory regulatory T cells (Tregs) where it is required for fitness. Strikingly, the majority of identified regulators are required in discrete cell type and stimulation timepoints, and a subset even had opposite functional effects in different conditions. Using single-cell transcriptomics after pooled perturbation of context-specific screen hits, we characterized specific factors as regulators of overall rest or activation and constructed state-specific regulatory networks. Upstream of these networks, MED12 – a component of the Mediator complex – serves as a dynamic orchestrator of regulators across conditions, governing both cell type- and stimulation-specific gene expression. MED12 interacts with the histone modifying complex COMPASS, affecting chromatin state and expression of genes encoding key context- and lineage-specific regulators; including rest maintenance factor KLF2 and activation promoting genes. We demonstrated that CRISPR ablation of MED12 blunted this cell state transition and protected T cells from activation-induced cell death. Overall, this work leverages CRISPR screens performed across primary cell conditions to identify context-specific regulators and dynamic gene circuits required to establish resting and activated T cell states.

Project description:The ability of individual cells to maintain a distinct identity and respond to transient environmental signals requires tightly controlled regulation of gene networks. However, how discrete sets of gene regulators coordinate circuits that respond to extracellular cues remains poorly defined. The need for context-dependent regulation is prominent in human CD4+ T cells, where distinct cell lineages must respond to diverse signals to orchestrate effective adaptive immune responses and maintain homeostasis. Here, we performed CRISPR screens in multiple primary human CD4+ T cell contexts to identify regulators that control expression of IL2RA, which is a canonical marker of T cell activation in pro-inflammatory effector T cells (Teffs) and constitutively expressed in anti-inflammatory regulatory T cells (Tregs) where it is required for fitness. Strikingly, the majority of identified regulators are required in discrete cell type and stimulation timepoints, and a subset even had opposite functional effects in different conditions. Using single-cell transcriptomics after pooled perturbation of context-specific screen hits, we characterized specific factors as regulators of overall rest or activation and constructed state-specific regulatory networks. Upstream of these networks, MED12 – a component of the Mediator complex – serves as a dynamic orchestrator of regulators across conditions, governing both cell type- and stimulation-specific gene expression. MED12 interacts with the histone modifying complex COMPASS, affecting chromatin state and expression of genes encoding key context- and lineage-specific regulators; including rest maintenance factor KLF2 and activation promoting genes. We demonstrated that CRISPR ablation of MED12 blunted this cell state transition and protected T cells from activation-induced cell death. Overall, this work leverages CRISPR screens performed across primary cell conditions to identify context-specific regulators and dynamic gene circuits required to establish resting and activated T cell states.

Project description:The ability of individual cells to maintain a distinct identity and respond to transient environmental signals requires tightly controlled regulation of gene networks. However, how discrete sets of gene regulators coordinate circuits that respond to extracellular cues remains poorly defined. The need for context-dependent regulation is prominent in human CD4+ T cells, where distinct cell lineages must respond to diverse signals to orchestrate effective adaptive immune responses and maintain homeostasis. Here, we performed CRISPR screens in multiple primary human CD4+ T cell contexts to identify regulators that control expression of IL2RA, which is a canonical marker of T cell activation in pro-inflammatory effector T cells (Teffs) and constitutively expressed in anti-inflammatory regulatory T cells (Tregs) where it is required for fitness. Strikingly, the majority of identified regulators are required in discrete cell type and stimulation timepoints, and a subset even had opposite functional effects in different conditions. Using single-cell transcriptomics after pooled perturbation of context-specific screen hits, we characterized specific factors as regulators of overall rest or activation and constructed state-specific regulatory networks. Upstream of these networks, MED12 – a component of the Mediator complex – serves as a dynamic orchestrator of regulators across conditions, governing both cell type- and stimulation-specific gene expression. MED12 interacts with the histone modifying complex COMPASS, affecting chromatin state and expression of genes encoding key context- and lineage-specific regulators; including rest maintenance factor KLF2 and activation promoting genes. We demonstrated that CRISPR ablation of MED12 blunted this cell state transition and protected T cells from activation-induced cell death. Overall, this work leverages CRISPR screens performed across primary cell conditions to identify context-specific regulators and dynamic gene circuits required to establish resting and activated T cell states.

Project description:The ability of individual cells to maintain a distinct identity and respond to transient environmental signals requires tightly controlled regulation of gene networks. However, how discrete sets of gene regulators coordinate circuits that respond to extracellular cues remains poorly defined. The need for context-dependent regulation is prominent in human CD4+ T cells, where distinct cell lineages must respond to diverse signals to orchestrate effective adaptive immune responses and maintain homeostasis. Here, we performed CRISPR screens in multiple primary human CD4+ T cell contexts to identify regulators that control expression of IL2RA, which is a canonical marker of T cell activation in pro-inflammatory effector T cells (Teffs) and constitutively expressed in anti-inflammatory regulatory T cells (Tregs) where it is required for fitness. Strikingly, the majority of identified regulators are required in discrete cell type and stimulation timepoints, and a subset even had opposite functional effects in different conditions. Using single-cell transcriptomics after pooled perturbation of context-specific screen hits, we characterized specific factors as regulators of overall rest or activation and constructed state-specific regulatory networks. Upstream of these networks, MED12 – a component of the Mediator complex – serves as a dynamic orchestrator of regulators across conditions, governing both cell type- and stimulation-specific gene expression. MED12 interacts with the histone modifying complex COMPASS, affecting chromatin state and expression of genes encoding key context- and lineage-specific regulators; including rest maintenance factor KLF2 and activation promoting genes. We demonstrated that CRISPR ablation of MED12 blunted this cell state transition and protected T cells from activation-induced cell death. Overall, this work leverages CRISPR screens performed across primary cell conditions to identify context-specific regulators and dynamic gene circuits required to establish resting and activated T cell states.

Project description:The ability of individual cells to maintain a distinct identity and respond to transient environmental signals requires tightly controlled regulation of gene networks. However, how discrete sets of nuclear regulators coordinate dynamic circuits that respond to extracellular cues remains poorly defined. This is prominent in CD4+ T cells, where cells must respond to diverse immunogenic signals to orchestrate effective adaptive immune responses and maintain immune homeostasis. Here, we performed CRISPR screens in multiple primary human CD4+ T cell contexts to identify nuclear regulators that control expression of IL2RA, a canonical marker of T cell activation that is differentially regulated between pro-inflammatory effector T cells and anti-inflammatory regulatory T cells. Strikingly, we discovered that the majority of identified regulators function within discrete cell type and stimulation timepoints, and a subset even had opposite effects across conditions. Using single-cell transcriptomics and surface proteomics after pooled perturbation of context specific screen hits, we characterized many factors as regulators of overall rest or activation and constructed state-specific regulatory networks. KLF2, MYB, and SOCS3 were distinguished as interconnected repressors of activation in resting T cells while GATA3 and MYC are required for proper stimulation response. Upstream of these circuits, MED12 – a component of the Mediator complex – serves as a dynamic orchestrator of trans regulators across conditions, governing both cell type and stimulation specific gene expression. Chromatin analysis revealed how MED12 coordinates key regulators as T cells transition to and from rest and activation. We demonstrated that CRISPR ablation of MED12 blunted this transition and protected T cells from activation-induced cell death.

Project description:The RNA polymerase II transcriptional Mediator subunit MED12 is broadly implicated in vertebrate brain development, and genetic variation in human MED12 is associated with X-linked intellectual disability and neuropsychiatric disorders. Although prior studies have begun to elaborate the functional contribution of MED12 within key neurodevelopmental pathways, a more complete description of MED12 function in the developing nervous system, including the specific biological networks and cellular processes under its regulatory influence, remains to be established. Herein, we sought to clarify the global contribution of MED12 to neural stem cell (NSC) biology through unbiased transcriptome profiling of mouse embryonic stem (ES) cell-derived NSCs following RNAi-mediated MED12 depletion. A total of 240 genes (177 up, 73 down) were differentially expressed in MED12-knockdown versus control mouse NS-5 (mNS-5) NSCs. Gene set enrichment analysis revealed MED12 to be prominently linked with “cell-to-cell interaction” and “cell cycle” networks, and subsequent functional studies confirmed these associations. Targeted depletion of MED12 led to enhanced NSC adhesion and upregulation of cell adhesion genes, including Syndecan 2 (SDC2). Concomitant depletion of both SDC2 and MED12 reversed enhanced cell adhesion triggered by MED12 knockdown alone, confirming that MED12 negatively regulates NSC cell adhesion by suppressing the expression of cell adhesion molecules. MED12-mediated suppression of NSC adhesion is a dynamically regulated process in vitro, enforced in self-renewing NSCs and alleviated during the course of neuronal differentiation. Accordingly, MED12 depletion enhanced adhesion and prolonged survival of mNS-5 NSCs induced to differentiate on gelatin, effects that were bypassed completely by growth on laminin. On the other hand, MED12 depletion in mNS-5 NSCs led to reduced expression of G1/S phase cell cycle regulators and a concordant G1/S phase cell cycle block without evidence of apoptosis, resulting in a severe proliferation defect. These findings suggest that MED12 contributes to the maintenance of NSC identity through a functionally bipartite role in suppression and activation of gene expression programs dedicated to cell adhesion and G1/S phase cell cycle progression, respectively. MED12 may thus contribute to the regulatory apparatus that controls the balance between NSC self-renewal and differentiation, with important implications for MED12-linked neurodevelopmental disorders.

Project description:Mediator is a multi-protein complex which facilitates the initial steps of gene transcription. Mediator 12 (MED12) and MED13 are components of a module that reversibly associates with the core Mediator complex, and both positively and negatively regulates gene expression. Here, in an Arabidopsis mutant screen for factors that can bypass repressive epigenetic marks, we identified MED12 and MED13 as anti-silencing factors. Both are preferentially required for the expression of genes in the absence of H3K4me3, an activating chromatin mark. Thus, MED12 and MED13 respond to specific epigenetic states and can act as conditional positive gene regulators in Arabidopsis.

Project description:Mediator is a multi-protein complex which facilitates the initial steps of gene transcription. Mediator 12 (MED12) and MED13 are components of a module that reversibly associates with the core Mediator complex, and both positively and negatively regulates gene expression. Here, in an Arabidopsis mutant screen for factors that can bypass repressive epigenetic marks, we identified MED12 and MED13 as anti-silencing factors. Both are preferentially required for the expression of genes in the absence of H3K4me3, an activating chromatin mark. Thus, MED12 and MED13 respond to specific epigenetic states and can act as conditional positive gene regulators in Arabidopsis.

Project description:Chemical cross-linking coupled to mass spectrometry was used to study binary and ternary complexes involving cyclin-dependent kinase 19 (CDK19), cyclin-C, and an N-terminal fragment of subunit 12 of the Mediator complex (MED12 1-100). Cross-linking was performed using disuccinimidyl suberate (DSS). These results were generated in the context of the study published as Klatt et al., A precisely positioned MED12 activation helix stimulates CDK8 kinase activity, Proc. Natl. Acad. Sci. USA 2020 (DOI: 10.1073/pnas.1917635117) with the associated data set PXD015394, but were not included in the article.

Project description:Cell differentiation results from coordinated changes in gene transcription in response to combinations of signals. FGF, Wnt, and mTOR signals regulate the differentiation of pluripotent mammalian cells towards embryonic and extraembryonic lineages, but how these signals cooperate with general transcriptional regulators is not fully resolved. Here, we report a genome-wide CRISPR screen that reveals both signaling components and general transcriptional regulators for differentiation-associated gene expression in mESCs. Focusing on the Mediator subunit Med12 as one of the strongest hits in the screen, we show that it regulates gene expression in parallel to FGF and mTOR signals. Loss of Med12 is compatible with differentiation along both the embryonic epiblast and the extraembryonic primitive endoderm lineage, but pluripotency transitions are slowed down, and the transcriptional separation between epiblast and primitive endoderm identities is enhanced in Med12-mutant cells. These cellular phenotypes correlate with reduced biological noise upon loss of Med12. These findings suggest that Med12 regulates cellular plasticity through the priming of transcriptional changes during differentiation, thereby modulating the effects of a broad range of signals.