Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Suppressor of cytokine signaling-1 (SOCS1) exerts control over inflammation by targeting p65 NFκB for degradation in addition to its canonical role regulating cytokine signaling. We report here that SOCS1 does not operate on all p65 targets equally, instead localizing to a select subset of pro-inflammatory genes. Promoter-specific interactions of SOCS1 and p65 determine the subset of genes activated by NFκB during systemic inflammation, with profound consequences for cytokine responses, immune cell mobilization, and tissue injury. Nitric oxide synthase-1 (NOS1)-derived NO is required and sufficient for displacement of SOCS1 from chromatin, permitting full transcriptional activation of these genes. Single cell transcriptomic analysis of NOS1-deficient animals led to the detection of a regulatory macrophage subset, which exerts potent suppression on inflammatory cytokine responses and tissue remodeling. These results provide the first example of a redox-sensitive, gene-specific mechanism for converting macrophages from cells that regulate inflammation to cells licensed to promote aggressive and potentially injurious inflammation.

Project description:Suppressor of cytokine signaling-1 (SOCS1) exerts control over inflammation by targeting p65 NFκB for degradation in addition to its canonical role regulating cytokine signaling. We report here that SOCS1 does not operate on all p65 targets equally, instead localizing to a select subset of pro-inflammatory genes. Promoter-specific interactions of SOCS1 and p65 determine the subset of genes activated by NFκB during systemic inflammation, with profound consequences for cytokine responses, immune cell mobilization, and tissue injury. Nitric oxide synthase-1 (NOS1)-derived NO is required and sufficient for displacement of SOCS1 from chromatin, permitting full transcriptional activation of these genes. Single cell transcriptomic analysis of NOS1-deficient animals led to the detection of a regulatory macrophage subset, which exerts potent suppression on inflammatory cytokine responses and tissue remodeling. These results provide the first example of a redox-sensitive, gene-specific mechanism for converting macrophages from cells that regulate inflammation to cells licensed to promote aggressive and potentially injurious inflammation.

Project description:Suppressor of cytokine signaling-1 (SOCS1) exerts control over inflammation by targeting p65 NFκB for degradation in addition to its canonical role regulating cytokine signaling. We report here that SOCS1 does not operate on all p65 targets equally, instead localizing to a select subset of pro-inflammatory genes. Promoter-specific interactions of SOCS1 and p65 determine the subset of genes activated by NFκB during systemic inflammation, with profound consequences for cytokine responses, immune cell mobilization, and tissue injury. Nitric oxide synthase-1 (NOS1)-derived NO is required and sufficient for displacement of SOCS1 from chromatin, permitting full transcriptional activation of these genes. Single cell transcriptomic analysis of NOS1-deficient animals led to the detection of a regulatory macrophage subset, which exerts potent suppression on inflammatory cytokine responses and tissue remodeling. These results provide the first example of a redox-sensitive, gene-specific mechanism for converting macrophages from cells that regulate inflammation to cells licensed to promote aggressive and potentially injurious inflammation.

Project description:SOCS1 regulates a subset of NFκB-target genes through direct chromatin binding and defines macrophage functional phenotypes

Project description:SOCS1 regulates a subset of NFκB-target genes through direct chromatin binding and defines macrophage functional phenotypes (scRNA-Seq).

Project description:SOCS1 regulates a subset of NFκB-target genes through direct chromatin binding and defines macrophage functional phenotypes (RNA-Seq).

Project description:SOCS1 regulates a subset of NFκB-target genes through direct chromatin binding and defines macrophage functional phenotypes (ChIP-Seq).

Project description:Erythroblastic islands are a specialized niche that contain a central macrophage surrounded by erythroid cells at various stages of maturation. However, identifying the precise genetic and transcriptional control mechanisms in the island macrophage remains difficult due to macrophage heterogeneity. Using unbiased global sequencing and directed genetic approaches focused on early mammalian development, we find that fetal liver macrophages exhibit a unique expression signature that differentiates them from erythroid and adult macrophage cells. The importance of erythroid Krüppel-like factor (EKLF)/KLF1 in this identity is shown by expression analyses in EKLF-/- and in EKLF-marked macrophage cells. Single-cell sequence analysis simplifies heterogeneity and identifies clusters of genes important for EKLF-dependent macrophage function and novel cell surface biomarkers. Remarkably, this singular set of macrophage island cells appears transiently during embryogenesis. Together, these studies provide a detailed perspective on the importance of EKLF in the establishment of the dynamic gene expression network within erythroblastic islands in the developing embryo and provide the means for their efficient isolation.

Project description:I?B proteins are the primary inhibitors of NF-?B. Here, we demonstrate that sumoylated and phosphorylated I?B? accumulates in the nucleus of keratinocytes and interacts with histones H2A and H4 at the regulatory region of HOX and IRX genes. Chromatin-bound I?B? modulates Polycomb recruitment and imparts their competence to be activated by TNF?. Mutations in the Drosophila I?B? gene cactus enhance the homeotic phenotype of Polycomb mutants, which is not counteracted by mutations in dorsal/NF-?B. Oncogenic transformation of keratinocytes results in cytoplasmic I?B? translocation associated with a massive activation of Hox. Accumulation of cytoplasmic I?B? was found in squamous cell carcinoma (SCC) associated with IKK activation and HOX upregulation.