Project description:Macrophages are critical immune cells in inflammatory diseases and their differentiation and function are tightly regulated by epigenetic alterations. H3K79 methylation is an epigenetic modification associated with active gene expression and DOT1L is the only histone methyltransferase for H3K79. Here we determine the role of DOT1L in macrophages by applying a selective DOT1L inhibitor in mouse and human macrophages and using myeloid-specific Dot1l deficient mice. We found that DOT1L directly regulates macrophage function by controlling lipid biosynthesis gene programs including central lipid regulators like sterol regulatory element-binding proteins SREBP1 and SREBP2. DOT1L inhibition also leads to macrophage hyperactivation which is associated with disrupted SREBP pathways. In vivo, myeloid Dot1l deficiency reduces atherosclerotic plaque stability and increases the activation of inflammatory plaque macrophages. Our data show that DOT1L is a crucial regulator of macrophage inflammatory responses and lipid regulatory pathways and suggests a high relevance of H3K79 methylation in inflammatory disease.

Project description:Macrophages are critical immune cells in inflammatory diseases and their differentiation and function are tightly regulated by epigenetic alterations. H3K79 methylation is an epigenetic modification associated with active gene expression and DOT1L is the only histone methyltransferase for H3K79. Here we determine the role of DOT1L in macrophages by applying a selective DOT1L inhibitor in mouse and human macrophages and using myeloid-specific Dot1l deficient mice. We found that DOT1L directly regulates macrophage function by controlling lipid biosynthesis gene programs including central lipid regulators like sterol regulatory element-binding proteins SREBP1 and SREBP2. DOT1L inhibition also leads to macrophage hyperactivation which is associated with disrupted SREBP pathways. In vivo, myeloid Dot1l deficiency reduces atherosclerotic plaque stability and increases the activation of inflammatory plaque macrophages. Our data show that DOT1L is a crucial regulator of macrophage inflammatory responses and lipid regulatory pathways and suggests a high relevance of H3K79 methylation in inflammatory disease.

Project description:Macrophages are critical immune cells in inflammatory diseases and their differentiation and function are tightly regulated by epigenetic alterations. H3K79 methylation is an epigenetic modification associated with active gene expression and DOT1L is the only histone methyltransferase for H3K79. Here we determine the role of DOT1L in macrophages by applying a selective DOT1L inhibitor in mouse and human macrophages and using myeloid-specific Dot1l deficient mice. We found that DOT1L directly regulates macrophage function by controlling lipid biosynthesis gene programs including central lipid regulators like sterol regulatory element-binding proteins SREBP1 and SREBP2. DOT1L inhibition also leads to macrophage hyperactivation which is associated with disrupted SREBP pathways. In vivo, myeloid Dot1l deficiency reduces atherosclerotic plaque stability and increases the activation of inflammatory plaque macrophages. Our data show that DOT1L is a crucial regulator of macrophage inflammatory responses and lipid regulatory pathways and suggests a high relevance of H3K79 methylation in inflammatory disease.

Project description:We wanted to investigate the effects of Dot1l deletion on gene expression in LSKs and GMPs of C57/BL6 mice Aberrant Hox gene activation is a recurrent feature in several different types of human leukemia, including leukemias with rearrangements of the mixed lineage leukemia (MLL) gene. In this study, we demonstrate that Hox gene expression is controlled by higher degree H3K79 methylation in acute myeloid leukemia (AML). We show that the deposition of progressive H3K79 methylation states at the genomic loci of critical Hox genes is dependent on the interaction of the H3K79 methyltransferase Dot1l with Af10, a protein that is found in the Dot1l complex isolated from diverse cell types. Furthermore, abrogation of the Dot1l-Af10 interaction reverses aberrant epigenetic profiles found in the leukemia epigenome and impairs the transforming ability of mechanistically distinct AML oncogenes. Lineage negative Sca-1 positive Kit positive (LSK) cells and granulocyte macrophage progenitors (GMPs) were sorted from Dot1 wt/wt x Mx-Cre mice or Dot1l fl/fl x Mx-Cre mice were injected with PIPC. PIPC injection induced biallelic deletion of the Dot1l allele in the Dot1l fl/fl mice but not the Dot1l wt/wt mice. The Dot1l wt/wt LSKs and GMPs were compared to the Dot1l -/- counterparts by RNA extraction and Microarrays.

Project description:Macrophages represent a major immune cell population in atherosclerotic plaques and play central role in the progression of this lipid-driven chronic inflammatory disease. Targeting immunometabolism is proposed as a strategy to revert aberrant macrophage activation to improve disease outcome. Here, we show ATP citrate lyase (Acly) to be activated in inflammatory macrophages and human atherosclerotic plaques. We demonstrate that myeloid Acly deficiency induces a stable plaque phenotype characterized by increased collagen deposition and fibrous cap thickness, along with a smaller necrotic core. In-depth functional, lipidomic, and transcriptional characterization indicate deregulated fatty acid and cholesterol biosynthesis and reduced liver X receptor activation within the macrophages in vitro. This results in macrophages that are more prone to undergo apoptosis, whilst maintaining their capacity to phagocytose apoptotic cells. Together, our results indicate that targeting macrophage metabolism improves atherosclerosis outcome and we reveal Acly as a promising therapeutic target to stabilize atherosclerotic plaques.

Project description:Metabolic reprogramming is well-appreciated to be able to control macrophage activation. However, it remains unknown whether the SREBPs-lipogenesis pathway is involved in macrophage alternative (or M2) activation. Here, we showed that IL4-induced M2 activation was coupled with increased SREBP2 maturation and activated cholesterol biosynthetic pathway, while the SREBP1-fatty acid biosynthesis pathway remained unaffected after IL4 stimulation. Genetic or pharmacologic blockade of SREBP2 maturation significantly inhibited IL4-induced M2 activation independent of cholesterol. Instead, cholesterol inhibited M2 activation most likely through its feedback regulation of SREBP2 maturation. Mechanically, the upregulation of SREBP2 maturation was dependent on the activation of upstream MTOR, and mature SREBP2 increased the expression of KAZALD1 and subsequently activated the IGF1 signaling to promote IL4-induced M2 activation. Consistently, myeloid-specific Scap deficiency markedly decreased the number of M2 macrophages in the lung and attenuated the HDM-induced allergic airway inflammation. Taken together, these findings highlight a critical role for cholesterol homeostatic regulator SREBP2 in M2 activation, which advances our understanding of the regulation of immunometabolism for M2 activation and points to new opportunities for therapeutic control of M2 activation and allergic airway inflammation.

Project description:Systematic analyses of the temporal dynamics of transcriptomes and chromatin landscapes of macrophages during timecourse of TLR4-mediated inflammatory response. As a multifunctional effector cell, macrophages play pivotal roles in both the induction and resolution components of varied inflammatory processes. During the course of an inflammation response, macrophages engage in a homeostatic program characterized by tightly coordinated modulation of temporal outputs of both lipid metabolism and inflammation. We demonstrate inversely biphasic temporal dynamics of specific fatty acid metabolic and inflammatory gene expression profiles, associated with concordant temporal reprogramming of macrophage fatty acid profiles. In part, the late phase of the macrophage inflammatory response is characterized by tailoring of fatty acid related gene expressions, facilitating both significant induction of anti-inflammatory unsaturated fatty acid production and associated resolution of inflammation. We demonstrate the biphasic temporal dynamics of macrophage inflammation, specifically anti-inflammatory omega-3 and omega-9 unsaturated fatty acid levels, are transcriptionally driven genome-wide by an unexpected shift from an LXR to SREBP1-dominant regulatory program in the late phase inflammatory response. Collectively, our findings reveal a novel Srebp1-driven mechanism allowing the intimate inverse temporal relationship between the transcriptional regulation of inflammatory and fatty acid metabolic outputs; whereby modulation key transcriptional regulators (LXR, SREBP1 and NF-kB) of these pathways coordinate appropriate temporal tailoring of local enhancer associated reprogramming and eventual pathway regulatory interactions, during the course of TLR4-dependent inflammatory response in macrophages. This specific Srebp-driven, temporal reprogramming of macrophage fatty acid metabolism, characterized by late phase induction of anti-inflammatory unsaturated fatty acid production, is necessary for appropriate resolution of inflammation. Thus, this study suggests that selective reprogramming of macrophage lipid metabolism can serve as a viable therapeutic intervention aimed at ameliorating chronic inflammation and varied metabolic syndrome associated states.

Project description:We used single cell RNA-sequencing of aortic CD45+ cells, combined with immunohistologic, morphometric and flow cytometric analyses to define the changes in plaque immune cell composition, gene expression and function following miR-33 inhibition. We report that anti-miR-33 treatment of Ldlr–/– mice with advanced atherosclerosis reduced plaque burden and altered the plaque immune cell landscape by shifting the balance of pro- and anti-atherosclerotic macrophage and T cell subsets. By quantifying the kinetic processes that determine plaque macrophage burden, we found that anti-miR-33 reduced levels of circulating monocytes and splenic myeloid progenitors, decreased macrophage proliferation and retention, and promoted macrophage attrition by apoptosis and efferocytotic clearance. scRNA-sequencing of aortic arch plaques showed that anti-miR-33 reduced the frequency of MHCIIhi “inflammatory” and Trem2hi “metabolic” macrophages, but not tissue resident macrophages. Furthermore, anti-miR-33 led to derepression of distinct miR-33 target genes in the different macrophage subsets: in resident and Trem2hi macrophages, anti-miR-33 relieved repression of miR-33 target genes involved in lipid metabolism (e.g., Abca1, Ncoa1, Ncoa2, Crot), whereas in MHCIIhi macrophages, anti-miR-33 upregulated target genes involved in chromatin remodeling and transcriptional regulation. Anti-miR-33 also reduced the accumulation of aortic CD8+ and CD4+ Th1 cells, and increased levels of FoxP3+ regulatory T cells in plaques, consistent with an immune-dampening effect on plaque inflammation.

Project description:TNF-mediated macrophage polarization is important for inflammatory disease pathogenesis, but mechanisms that regulate polarization are not well understood. Transcriptomic and epigenomic analysis of the TNF response in primary human macrophages revealed late phase activation of SREBP2, the master regulator of cholesterol biosynthesis genes. TNF stimulation extended the genomic profile of SREBP2 occupancy to include binding to and activation of inflammatory and interferon response genes independently of its functions in sterol metabolism. Genetic ablation of SREBP function shifted the balance of macrophage polarization from M1 to an M2-like reparative phenotype in peritonitis and skin wound healing models. Genetic ablation of SREBP activity in myeloid cells or topical pharmacological inhibition of SREBP improved skin wound healing under homeostatic and chronic inflammatory conditions. Our results identify a new function and mechanism of action for SREBP2 in augmenting TNF-induced M1 macrophage polarization and inflammation, and open therapeutic avenues for promoting wound repair.

Project description:TNF-mediated macrophage polarization is important for inflammatory disease pathogenesis, but mechanisms that regulate polarization are not well understood. Transcriptomic and epigenomic analysis of the TNF response in primary human macrophages revealed late phase activation of SREBP2, the master regulator of cholesterol biosynthesis genes. TNF stimulation extended the genomic profile of SREBP2 occupancy to include binding to and activation of inflammatory and interferon response genes independently of its functions in sterol metabolism. Genetic ablation of SREBP function shifted the balance of macrophage polarization from M1 to an M2-like reparative phenotype in peritonitis and skin wound healing models. Genetic ablation of SREBP activity in myeloid cells or topical pharmacological inhibition of SREBP improved skin wound healing under homeostatic and chronic inflammatory conditions. Our results identify a new function and mechanism of action for SREBP2 in augmenting TNF-induced M1 macrophage polarization and inflammation, and open therapeutic avenues for promoting wound repair.