Project description:Glucocorticoid Receptor (GR) suppresses inflammation by activating anti-inflammatory and repressing pro-inflammatory genes. GR-interacting protein (GRIP)1 of the p160 family has emerged as a unique GR corepressor in macrophages (MΦ), however, whether GRIP1 contributes to GR-activated transcription, and what dictates its context-specific coactivator vs. corepressor properties is unknown. We report that loss of GRIP1 in human and mouse MΦ attenuated GR-mediated induction of several anti-inflammatory targets, revealing a non-redundant function of GRIP1 in coactivation. Moreover, glucocorticoid treatment of quiescent MΦ globally directed GRIP1 toward GR-bound genomic sites dominated by classic palindromic GREs, suggesting its dedicated role as a GR coactivator. Further, GRIP1 N-terminal region was phosphorylated at a serine cluster by Cyclin-Dependent Kinase (CDK)9, which was recruited into GC-induced GR:GRIP1:CDK9 ternary complexes, producing distinct GRIP1 phospho-isoforms at different GREs even associated with the same gene. Functionally, phosphorylation potentiated GRIP1 coactivator properties by facilitating its recruitment and/or creating novel protein:protein interaction surfaces in a GRE-specific manner. Strikingly, GRIP1 function as a GR corepressor was phosphorylation-independent; consistently, no phospho-GRIP1 or CDK9 was detected at GR transrepression sites near pro-inflammatory genes. Thus, liganded GR in MΦ restricts actions of its own coregulator via CDK9-mediated phosphorylation to a subset of complexes driving anti-inflammatory gene transcription.

Project description:Macrophage polarization is implicated in acute and chronic inflammatory settings, and central to diseases such as obesity, atherosclerosis and cancer. However, the transcription programs driving macrophage polarization are only partially known. Macrophage phenotypes exist on a spectrum, with anti-inflammatory (M2-like) and pro-inflammatory (M1-like) states viewed as polar opposite and relatively stable phenotype. The main driver of the M2-like program in response to IL4 is the Krüppel-like factor 4(KLF4), which uses transcriptional coregulator GRIP1 as a co-activator. Coincidentally, glucocorticoid hormone (GC)-activated GC receptor (GR) also induces the M2-like state, and GRIP1 is a well-known co-factor of GR. We are investigating if GRIP1 facilitates transcriptional and phenotypic convergence of the M2-like state via the GR and KLF4-regulated pathways. Using RNA-seq on bone marrow-derived macrophages (BMDMs) from WT and GRIP1-cKO mice, we have shown that GR and KLF4-regulated pathways share common and distinct transcriptomes. A lot of the key M2 genes are GRIP1-dependent, and some key pro-inflammatory targets need GRIP1 for suppression in the M2–like state. Similarly, H3K27ac ChIP and ATAC-seq, which profile active and open chromatin regions respectively, revealed both specific and shared enhancers for these two pathways in the M2-like state. GR recruitment to the genomic binding sites was shown to be strictly GC-specific, whereas GRIP1 is recruited in both signal-specific and combinatorial manner. It is plausible that GRIP1 facilitates the binding of GR and KLF4 to the shared enhancers, thus leading to overlapping changes in gene expression. At the cellular level, GC- and particularly IL4-polarized GRIP1-cKO BMDMs exhibit reduced phagocytosis, an M2-characteristic activity, compared to the WT. Furthermore, in vivo, in the acute inflammatory setting of DSS-induced colitis, GRIP1-cKO mice exhibit greater colonic inflammation and tissue destruction, and fail to up-regulate M2 genes to the same degree as the WT. GRIP1 is therefore a crucial regulator of macrophage polarization to the anti-inflammatory state. The specific contribution of GRIP1 to the shared transcriptional phenotype is currently being assessed.

Project description:Macrophage polarization is implicated in acute and chronic inflammatory settings, and central to diseases such as obesity, atherosclerosis and cancer. However, the transcription programs driving macrophage polarization are only partially known. Macrophage phenotypes exist on a spectrum, with anti-inflammatory (M2-like) and pro-inflammatory (M1-like) states viewed as polar opposite and relatively stable phenotype. The main driver of the M2-like program in response to IL4 is the Krüppel-like factor 4(KLF4), which uses transcriptional coregulator GRIP1 as a co-activator. Coincidentally, glucocorticoid hormone (GC)-activated GC receptor (GR) also induces the M2-like state, and GRIP1 is a well-known co-factor of GR. We are investigating if GRIP1 facilitates transcriptional and phenotypic convergence of the M2-like state via the GR and KLF4-regulated pathways. Using RNA-seq on bone marrow-derived macrophages (BMDMs) from WT and GRIP1-cKO mice, we have shown that GR and KLF4-regulated pathways share common and distinct transcriptomes. A lot of the key M2 genes are GRIP1-dependent, and some key pro-inflammatory targets need GRIP1 for suppression in the M2–like state. Similarly, H3K27ac ChIP and ATAC-seq, which profile active and open chromatin regions respectively, revealed both specific and shared enhancers for these two pathways in the M2-like state. GR recruitment to the genomic binding sites was shown to be strictly GC-specific, whereas GRIP1 is recruited in both signal-specific and combinatorial manner. It is plausible that GRIP1 facilitates the binding of GR and KLF4 to the shared enhancers, thus leading to overlapping changes in gene expression. At the cellular level, GC- and particularly IL4-polarized GRIP1-cKO BMDMs exhibit reduced phagocytosis, an M2-characteristic activity, compared to the WT. Furthermore, in vivo, in the acute inflammatory setting of DSS-induced colitis, GRIP1-cKO mice exhibit greater colonic inflammation and tissue destruction, and fail to up-regulate M2 genes to the same degree as the WT. GRIP1 is therefore a crucial regulator of macrophage polarization to the anti-inflammatory state. The specific contribution of GRIP1 to the shared transcriptional phenotype is currently being assessed.

Project description:Macrophages adopt distinct phenotypes in response to environmental cues, with type-2 cytokine interleukin-4 (IL4) promoting a tissue-repair homeostatic state (M2IL4). Glucocorticoids - widely used anti-inflammatory therapeutics - reportedly impart a similar phenotype (M2GC), however how or to what extent these populations functionally converge is unknown. We show that M2IL4 and M2GC transcriptomes share a striking overlap mirrored by a shift in chromatin landscape in both common and signal-specific gene subsets. This core homeostatic program is enacted by transcriptional effectors KLF4 and the GC receptor (GR), whose genome-wide occupancy and actions are integrated in a stimulus-specific manner by the nuclear receptor cofactor GRIP1. Indeed, 35% of the shared IL4- vs. GC-elicited transcriptomic changes were GRIP1-dependent. Consistently, GRIP1 loss attenuated M2IL4 and M2GC phagocytic activity in vitro and macrophage tissue-repair properties in the murine colitis model in vivo. These findings provide a mechanistic framework for homeostatic macrophage programming by distinct signals, to better inform GR-targeting drug design.

Project description:Obesity is associated with chronic low-grade white adipose tissue (WAT) inflammation that can contribute to the development of insulin resistance in mammals. Previous studies have identified interleukin (IL)-12 as a critical upstream regulator of WAT inflammation and metabolic dysfunction during obesity, however, the cell types and mechanisms that initiate WAT IL-12 production remain unclear. Analysis of mouse and human WAT single cell transcriptomic datasets, IL-12 reporter mice, and IL-12p70 protein levels by ELISA identified activated conventional type 1 dendritic cells (cDC1s) as the cellular source of WAT IL-12 during diet-induced obesity. cDC1s were required for the development of obesity-associated inflammation by increasing group 1 innate lymphocyte interferon (IFN)-γ production and inflammatory macrophage accumulation. Inducible depletion of cDC1s increased WAT insulin sensitivity and systemic glucose tolerance during diet-induced obesity. Endocytosis of apoptotic bodies containing self-DNA by WAT cDC1 drove STING-dependent IL-12 production. Together, these results suggest that WAT cDC1s act as critical regulators of adipose tissue inflammation and metabolic homeostasis during obesity.

Project description:Growing evidence are showing a pivotal role of macrophages (MФ) and microglia (MG) in the pathogenesis of Multiple sclerosis (MS). Interferon β (IFN β) and glucocorticoids are front line treatments in MS, and disrupting either type I IFN or GC receptor (GR) pathway in mice aggravates EAE, the mouse model of MS. Here, we evaluated GR Interacting Protein 1 actions in neuroinflammation by subjecting mice conditionally lacking GRIP1 in myeloid cells (cKO) to EAE. We showed that myeloid GRIP1 plays a dual role by promoting the ‘effector’ neuroinflammatory phase of EAE as well as mediating IFN β therapeutic effect. Our sorted MФ/MG transcriptome analysis reveals dramatic changes in inflammatory and IFN-pathway gene expression including potential differences of GRIP1 function in these distinct myeloid cell populations.

Project description:GRBATKO_BAT_COLDEXPOSURE Aberrant activity of the glucocorticoid (GC)/glucocorticoid receptor (GR) endocrine system has been linked to obesity-related metabolic dysfunction. Traditionally, the GC/GR axis has been believed to play a crucial role in adipose tissue formation and function in both, white (WAT) and brown adipose tissue (BAT). While recent studies have challenged this notion for WAT, the contribution of GC/GR signaling to BAT-dependent energy homeostasis remained unknown. Here, we have generated and characterized a BAT-specific GR knockout mouse (GRBATKO), for the first time allowing to genetically interrogate the metabolic impact of BAT GR. The HPA axis in GRBATKO mice was intact, as was the ability of mice to adapt to cold. BAT GR was dispensable for the adaptation to fasting-feeding cycles and the development of diet-induced obesity. In obesity, glucose and lipid metabolism, insulin sensitivity, and food intake remained unchanged, aligning with the absence of changes in thermogenic gene expression. Together, we demonstrate that the GR in UCP1-positive BAT adipocytes plays a negligible role in systemic metabolism and BAT function, thereby opposing a long-standing paradigm in the field.

Project description:Chronic low-grade visceral white adipose tissue (WAT) inflammation is a hallmark of metabolic syndrome in obesity. Here, we demonstrate that a subpopulation of adipose tissue perivascular (PDGFRb+) cells, termed “fibro-inflammatory progenitors” (FIPs), activate pro-inflammatory signaling cascades shortly after the onset of high-fat diet feeding of mice and regulate pro-inflammatory macrophage accumulation in WAT in a TLR4-dependent manner. FIPs activation in obesity is mediated by the downregulation of ZFP423, identified here as a transcriptional co-regulator of NFkB. Biochemical analysis of ZFP423-protein complexes and ChIP-seq analysis reveal that ZFP423 suppresses the DNA-binding capacity of the p65 subunit of NFkB by inducing a p300 to NuRD co-regulator switch. Doxycycline-inducible expression of Zfp423 in PDGFRb+ cells suppresses inflammatory signaling in FIPs and attenuates metabolic inflammation of visceral WAT in obesity. Inducible inactivation of Zfp423 in PDGFRb+ cells increases FIP activity, exacerbates adipose macrophage accrual, and promotes WAT dysfunction. These studies implicate perivascular mesenchymal cells as important regulators of chronic adipose tissue inflammation in obesity and identify ZFP423 as a transcriptional break on NFkB signaling.

Project description:The circadian clock component REVERBα is considered a dominant regulator of lipid metabolism, with global Reverbα deletion driving dysregulation of white adipose tissue (WAT) lipogenesis and obesity. However, a similar phenotype is not observed under adipocyte-selective deletion (ReverbαFlox2-6AdipoCre), and transcriptional profiling demonstrates that, under basal conditions, direct targets of REVERBα regulation are limited, and include the circadian clock and collagen dynamics. Under high-fat diet (HFD) feeding, ReverbαFlox2-6AdipoCre mice do manifest profound obesity, yet without the accompanying WAT inflammation and fibrosis exhibited by controls. Integration of the WAT REVERBα cistrome with differential gene expression reveals broad control of metabolic processes by REVERBα which is unmasked in the obese state.

Project description:Background: Excessive white adipose tissue (WAT) expansion as in obesity is generally associated with chronic inflammation of WAT, which contributes to obesity associated complications. Low oxygen availability in WAT is hypothesized to be the initiator of this inflammatory response. Hypothesis: We examined the hypothesis that local tissue hypoxia is responsible for the initiation of inflammation in WAT. Research design and methods: Diet-induced obese male C57BL/6JOlaHsd mice, housed at thermoneutrality, were exposed to mild environmental oxygen restriction (OxR, to 13% oxygen) for five days and compared with mice kept at normoxia, after which WAT and serum were collected. Body composition, systemic metabolic parameters, WAT macrophage infiltration (as marker for tissue inflammation) and whole genome microarray analysis, and circulating adipokines were measured. Results: Five days OxR decreased body weight and fat mass, and increased blood levels of haemoglobin and haematocrit, as well as lactate to glucose ratio, which indicated systemic hypoxia. No difference in adipose tissue inflammation was found, which was supported by down regulation of inflammation-associated transcript levels of S100a8, Saa1, and Saa3. Serum metabolomics revealed an increase of branched chain amino acid Valine and propionylcarnitine. Adipokines CCDC3, CCK, and Adiponectin are reduced by OxR on transcript (Cck) or serum protein level (Adiponectin), or both (CCDC3). Conclusions: Mild oxygen restriction does not increase white adipose tissue inflammation in obese mice. However, a systemic adaptation together with a metabolic response in WAT was observed.