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

Project description:Currently, it is unclear if all monocyte subsets exhibit osteoclastogenic potential. Furthermore, the role of lineage determining TFs in regulating OC differentiation on a genome-wide scale remains poorly understood. In this study, we utilized a novel Irf8 conditional knockout (Irf8 cKO) mouse model to characterize the importance of IRF8 in OC progenitor development and epigenetic regulation of OC differentiation. We performed RNA-seq on Irf8 gWT, gKO, cWT and cKO BMMs, preosteoclasts (PreOCs), and OCs. Cells were analyzed prior to (BMMs) and 3 days (PreOCs) and 6 days (OCs) after RANKL stimulation. Here we show that greater a number of genes are significantly upregulated in Irf8 cKO OCs when compared to WT and Irf8 gKO OCs. Altogether, our data shows that Irf8 cKO mice provide more precise/reliable OC-specific transcriptomic results when compared to Irf8 gKO mice.

Project description:Currently, the epigenetic mechanisms governing the osteoclast differentiation process remains poorly understood. To investigate the combinatorial activity of TFs, cis-regulatory elements, and the enhancer landscape that establish and maintain osteoclast transcriptional identity, we profiled histone modifications (H3K4me1, H3K4me3, H3K27ac, H3K27me3) and PU.1 and IRF8 binding by ChIP-seq. RNA-seq data from sorted Ly6Chi, Ly6Cint, and Ly6C– cells were overlaid with ChIP-seq data to identify epigenetic changes specific to each subset and genotype. Our data suggest that the Ly6Chi inflammatory monocytes and Ly6Cint cells are transcriptionally and epigenetically programmed to differentiate in mature osteoclasts when compared to Ly6C– anti-inflammatory monocytes. A combinatorial activity of TFs and cis-regulatory elements in the vicinity of several osteoclast-specific genes are responsible for establishing and maintaining osteoclast identity in these subsets. In Irf8 cKO mice, several promoters and enhancers established during the progenitor stage may be critical for initiating early lineage commitment and priming monocyte subsets to differentiate into robust osteoclasts.

Project description:Currently, it is unclear if all monocyte subsets exhibit osteoclastogenic potential. Furthermore, the role of lineage determining TFs in regulating OC differentiation on a genome-wide scale remains poorly understood. In this study, we utilized a novel Irf8 conditional knockout (Irf8 cKO) mouse model to characterize the importance of IRF8 in OC progenitor development and epigenetic regulation of OC differentiation. To identify global transcriptional program governing the osteoclastogenic potential of Ly6Chi, Ly6Cint, and Ly6C– monocytes, and how it may be further influenced by IRF8 deficiency, we performed RNA-seq on sorted Ly6Chi, Ly6Cint, and Ly6C– cells from WT and Irf8 cKO mice. Cells were analyzed prior to (BMMs) and 4 days after RANKL stimulation (OCs). Here we show that WT Ly6Chi and Ly6Cint monocytes developmentally contain OC-specific transcripts, which are augmented upon RANKL stimulation. Additionally, in the absence of IRF8, OC-specific transcripts in all three monocyte subsets are primed to robustly respond to RANKL stimulation.

Project description:Monocyte Subsets with High Osteoclastogenic Potential and Their Epigenetic Regulation Orchestrated by IRF8

Project description:Monocyte Subsets with High Osteoclastogenic Potential and Their Epigenetic Regulation Orchestrated by IRF8 [RNA-Seq]

Project description:Monocyte Subsets with High Osteoclastogenic Potential and Their Epigenetic Regulation Orchestrated by IRF8 [ChIP-Seq]

Project description:Monocyte Subsets with High Osteoclastogenic Potential and Their Epigenetic Regulation Orchestrated by IRF8 [RNA-Seq sorted cells]

Project description:Human monocytes have been grouped into classical (CD14++CD16-), non-classical (CD14dimCD16++), and intermediate (CD14++CD16+) subsets. Documentation of normal function and variation in this complement of subtypes, particularly their differentiation potential to dendritic cells (DC) or macrophages, remains incomplete. We therefore phenotyped monocytes from peripheral blood of healthy subjects and performed functional studies on high-speed sorted subsets. Subset frequencies were found to be tightly controlled over time and across individuals. Subsets were distinct in their secretion of TNF?, IL-6, and IL-1? in response to TLR agonists, with classical monocytes being the most producers and non-classical monocytes the least. Monocytes, particularly those of the non-classical subtype, secreted interferon-? (IFN-?) in response to intracellular TLR3 stimulation. After incubation with IL-4 and GM-CSF, classical monocytes acquired monocyte-derived DC (mo-DC) markers and morphology and stimulated allogeneic T cell proliferation in MLR; intermediate and non-classical monocytes did not. After incubation with IL-3 and Flt3 ligand, no subset differentiated to plasmacytoid DC. After incubation with GM-CSF (M1 induction) or macrophage colony-stimulating factor (M-CSF) (M2 induction), all subsets acquired macrophage morphology, secreted macrophage-associated cytokines, and displayed enhanced phagocytosis. From these studies we conclude that classical monocytes are the principal source of mo-DCs, but all subsets can differentiate to macrophages. We also found that monocytes, in particular the non-classical subset, represent an alternate source of type I IFN secretion in response to virus-associated TLR agonists.

Project description:Monocytes and macrophages are key players in tissue homeostasis and immune responses. Epigenetic processes tightly regulate cellular functioning in health and disease. Recent Advances: Recent technical developments have allowed detailed characterizations of the transcriptional circuitry underlying monocyte and macrophage regulation. Upon differentiation and activation, enhancers are selected by lineage-determining and signal-dependent transcription factors. Enhancers are shown to be very dynamic and activation of these enhancers underlies the differences in gene transcription between monocytes and macrophages and their subtypes.It has been shown that epigenetic enzymes regulate the functioning of these cells and targeting of epigenetic enzymes has been proven to be a valuable tool to dampen inflammatory responses. We give a comprehensive overview of recent developments and understanding of the epigenetic pathways that control monocyte and macrophage function and of the epigenetic enzymes involved in monocyte and macrophage differentiation and activation.The key challenges in the upcoming years will be to study epigenetic changes in human disease and to better understand how epigenetic pathways control the inflammatory repertoire in disease. Antioxid. Redox Signal. 25, 758-774.