Project description:This project identified NFI family members as CARM1 substrates. NFIB was previously reported to play a critical role in the development of small cell lung cancer. We provided evidence that the arginine methylation of NFIB is required for its oncogenic function in small cell lung cancer.

Project description:The mechanisms by which the fetal type b-globin-like genes HBG1 and HBG2 are silenced in adult erythroid precursor cells is a basic biology question in human development. Reversal of such mechanisms is beneficial for b hemoglobinopathies, such as sickle cell disease (SCD). A CRISPR-Cas9 genetic screen uncovered two members of the NFI transcription factor family – NFIA and NFIX – as novel HBG1/2 repressors. Both factors are expressed at elevated levels in adult erythroid cells, and their single or combined depletion revealed cooperativity in HBG1/2 regulation in cultured cells and human-to-mouse xenotransplant experiments, as well as in preventing sickling of SCD-derived erythroblasts. Genomic profiling, gene editing and in vitro binding assays demonstrated that the potent concerted activity of NFIA and NFIX factors is explained in part by their ability to activate expression of BCL11A, a known silencer of the HBG1/2 genes, and in part by repressing the HBG1/2 genes via two direct binding sites. NFI factors emerge as versatile regulators of the fetal-to-adult switch in b-globin production.

Project description:The mechanisms by which the fetal type b-globin-like genes HBG1 and HBG2 are silenced in adult erythroid precursor cells is a basic biology question in human development. Reversal of such mechanisms is beneficial for b hemoglobinopathies, such as sickle cell disease (SCD). A CRISPR-Cas9 genetic screen uncovered two members of the NFI transcription factor family – NFIA and NFIX – as novel HBG1/2 repressors. Both factors are expressed at elevated levels in adult erythroid cells, and their single or combined depletion revealed cooperativity in HBG1/2 regulation in cultured cells and human-to-mouse xenotransplant experiments, as well as in preventing sickling of SCD-derived erythroblasts. Genomic profiling, gene editing and in vitro binding assays demonstrated that the potent concerted activity of NFIA and NFIX factors is explained in part by their ability to activate expression of BCL11A, a known silencer of the HBG1/2 genes, and in part by repressing the HBG1/2 genes via two direct binding sites. NFI factors emerge as versatile regulators of the fetal-to-adult switch in b-globin production.

Project description:The mechanisms by which the fetal type b-globin-like genes HBG1 and HBG2 are silenced in adult erythroid precursor cells is a basic biology question in human development. Reversal of such mechanisms is beneficial for b hemoglobinopathies, such as sickle cell disease (SCD). A CRISPR-Cas9 genetic screen uncovered two members of the NFI transcription factor family – NFIA and NFIX – as novel HBG1/2 repressors. Both factors are expressed at elevated levels in adult erythroid cells, and their single or combined depletion revealed cooperativity in HBG1/2 regulation in cultured cells and human-to-mouse xenotransplant experiments, as well as in preventing sickling of SCD-derived erythroblasts. Genomic profiling, gene editing and in vitro binding assays demonstrated that the potent concerted activity of NFIA and NFIX factors is explained in part by their ability to activate expression of BCL11A, a known silencer of the HBG1/2 genes, and in part by repressing the HBG1/2 genes via two direct binding sites. NFI factors emerge as versatile regulators of the fetal-to-adult switch in b-globin production.

Project description:Tissue homeostasis and regeneration rely upon resident stem cells (SCs), whose behavior is regulated through niche-dependent crosstalk. The mechanisms underlying SC maintenance are still unfolding. Here, using hair follicles (HFs) as model and spatiotemporal gene ablation in mice, we uncover transcription factors (TFs) NFIB and NFIX as guardians of the process. Complete NFI ablation causes SC depletion and hair loss which resembles irreversible alopecia in humans, who intriguingly also display reduced NFI. Through single cell transcriptomics, ATAC- and ChIP-seq profiling, we uncover a key role for NFIB/NFIX in governing chromatin accessibility of HFSC master TFs . When NFIB/NFIX are genetically removed, the stemness epigenetic landscape is lost, as enhancers driving HFSC identity are decommissioned and those of epidermal differentiation and wound-repair are de-repressed. Together, our findings expose NFIB/NFIX as crucial rheostats of tissue homeostasis, functioning to safeguard the SC epigenome from a breach in lineage confinement that otherwise triggers irreversible tissue degeneration.

Project description:Tissue homeostasis and regeneration rely upon resident stem cells (SCs), whose behavior is regulated through niche-dependent crosstalk. The mechanisms underlying SC maintenance are still unfolding. Here, using hair follicles (HFs) as model and spatiotemporal gene ablation in mice, we uncover transcription factors (TFs) NFIB and NFIX as guardians of the process. Complete NFI ablation causes SC depletion and hair loss which resembles irreversible alopecia in humans, who intriguingly also display reduced NFI. Through single cell transcriptomics, ATAC- and ChIP-seq profiling, we uncover a key role for NFIB/NFIX in governing chromatin accessibility of HFSC master TFs . When NFIB/NFIX are genetically removed, the stemness epigenetic landscape is lost, as enhancers driving HFSC identity are decommissioned and those of epidermal differentiation and wound-repair are de-repressed. Together, our findings expose NFIB/NFIX as crucial rheostats of tissue homeostasis, functioning to safeguard the SC epigenome from a breach in lineage confinement that otherwise triggers irreversible tissue degeneration.

Project description:Tissue homeostasis and regeneration rely upon resident stem cells (SCs), whose behavior is regulated through niche-dependent crosstalk. The mechanisms underlying SC maintenance are still unfolding. Here, using hair follicles (HFs) as model and spatiotemporal gene ablation in mice, we uncover transcription factors (TFs) NFIB and NFIX as guardians of the process. Complete NFI ablation causes SC depletion and hair loss which resembles irreversible alopecia in humans, who intriguingly also display reduced NFI. Through single cell transcriptomics, ATAC- and ChIP-seq profiling, we uncover a key role for NFIB/NFIX in governing chromatin accessibility of HFSC master TFs . When NFIB/NFIX are genetically removed, the stemness epigenetic landscape is lost, as enhancers driving HFSC identity are decommissioned and those of epidermal differentiation and wound-repair are de-repressed. Together, our findings expose NFIB/NFIX as crucial rheostats of tissue homeostasis, functioning to safeguard the SC epigenome from a breach in lineage confinement that otherwise triggers irreversible tissue degeneration.

Project description:Tissue homeostasis and regeneration rely upon resident stem cells (SCs), whose behavior is regulated through niche-dependent crosstalk. The mechanisms underlying SC maintenance are still unfolding. Here, using hair follicles (HFs) as model and spatiotemporal gene ablation in mice, we uncover transcription factors (TFs) NFIB and NFIX as guardians of the process. Complete NFI ablation causes SC depletion and hair loss which resembles irreversible alopecia in humans, who intriguingly also display reduced NFI. Through single cell transcriptomics, ATAC- and ChIP-seq profiling, we uncover a key role for NFIB/NFIX in governing chromatin accessibility of HFSC master TFs . When NFIB/NFIX are genetically removed, the stemness epigenetic landscape is lost, as enhancers driving HFSC identity are decommissioned and those of epidermal differentiation and wound-repair are de-repressed. Together, our findings expose NFIB/NFIX as crucial rheostats of tissue homeostasis, functioning to safeguard the SC epigenome from a breach in lineage confinement that otherwise triggers irreversible tissue degeneration.

Project description:This project identified NFI family members as CARM1 substrates. NFIB was previously reported to play a critical role in the development of small cell lung cancer. We provided evidence that the arginine methylation of NFIB is required for its oncogenic function in small cell lung cancer.

Project description:Hematopoietic stem cells are both necessary and sufficient to sustain the complete blood system of vertebrates. Here we show that Nfix, a member of the nuclear factor I (Nfi) family of transcription factors, is highly expressed by hematopoietic stem and progenitor cells (HSPC) of murine adult bone marrow. Although shRNA mediated knockdown of Nfix expression in Lineage-Sca-1+c-Kit+ HSPC had no effect on in vitro cell growth or viability, Nfix-depleted HSPC displayed a significant loss of colony forming potential, as well as short- and long-term in vivo hematopoietic repopulating activity. Analysis of recipient mice 4-20 days post-transplant revealed that Nfix-depleted HSPC establish in the bone marrow but fail to persist due to increased apoptotic cell death. Gene expression profiling of Nfix-depleted HSPC reveals that loss of Nfix expression in HSPC is concomitant with a decrease in the expression of multiple genes known to be important for HSPC survival, such as Erg, Mecom, Mpl and Prdm16. These data reveal that Nfix is a novel regulator of HSPC survival post-transplantation and establish, for the first time, a role for Nfi genes in the regulation of this cellular compartment. 3 NFIX depleted samples are compared to 3 wt samples