Project description:T helper 17 (TH17) cells are found in the periphery and synovium of patients with rheumatoid arthritis (RA); however, IL-17–targeted interventions have limited efficacy in established RA. Inflammation can induce TH17 cell transdifferentiation into IL-17–negative exTH17 cells, but the role of exTH17 cells in arthritis is unknown. We performed TH17 cell lineage tracing in the SKG mouse model of RA. In arthritic mice, synovial TH17 cells transdifferentiate into CD44+ exTH17 cells, which are more arthritogenic and sustain inflammation that is IL-17 independent. The exTH17 cell gene signature includes up-regulation of CD44 and sphingosine-1-phosphate receptor 4 (S1PR4) and correlates with the profile of human RA synovial CD4+ T cells. We demonstrate that cross-talk between TH17 cells and fibroblast-like synoviocytes (FLSs) via S1P promotes TH17-exTH17 cell conversion. CD44 is necessary for exTH17 cell–mediated arthritis. Our study suggests that FLS expansion during RA progression promotes TH17-exTH17 cell conversion. These results could potentially enable RA precision therapy.

Project description:T helper 17 (TH17) cells are found in the periphery and synovium of patients with rheumatoid arthritis (RA); however, IL-17–targeted interventions have limited efficacy in established RA. Inflammation can induce TH17 cell transdifferentiation into IL-17–negative exTH17 cells, but the role of exTH17 cells in arthritis is unknown. We performed TH17 cell lineage tracing in the SKG mouse model of RA. In arthritic mice, synovial TH17 cells transdifferentiate into CD44+ exTH17 cells, which are more arthritogenic and sustain inflammation that is IL-17 independent. The exTH17 cell gene signature includes up-regulation of CD44 and sphingosine-1-phosphate receptor 4 (S1PR4) and correlates with the profile of human RA synovial CD4+ T cells. We demonstrate that cross-talk between TH17 cells and fibroblast-like synoviocytes (FLSs) via S1P promotes TH17-exTH17 cell conversion. CD44 is necessary for exTH17 cell–mediated arthritis. Our study suggests that FLS expansion during RA progression promotes TH17-exTH17 cell conversion. These results could potentially enable RA precision therapy.

Project description:T helper 17 (TH17) cells are found in the periphery and synovium of patients with rheumatoid arthritis (RA); however, IL-17–targeted interventions have limited efficacy in established RA. Inflammation can induce TH17 cell transdifferentiation into IL-17–negative exTH17 cells, but the role of exTH17 cells in arthritis is unknown. We performed TH17 cell lineage tracing in the SKG mouse model of RA. In arthritic mice, synovial TH17 cells transdifferentiate into CD44+ exTH17 cells, which are more arthritogenic and sustain inflammation that is IL-17 independent. The exTH17 cell gene signature includes up-regulation of CD44 and sphingosine-1-phosphate receptor 4 (S1PR4) and correlates with the profile of human RA synovial CD4+ T cells. We demonstrate that cross-talk between TH17 cells and fibroblast-like synoviocytes (FLSs) via S1P promotes TH17-exTH17 cell conversion. CD44 is necessary for exTH17 cell–mediated arthritis. Our study suggests that FLS expansion during RA progression promotes TH17-exTH17 cell conversion. These results could potentially enable RA precision therapy.

Project description:Objectives: TNF-induced activation of fibroblast-like synoviocytes (FLS) is a critical determinant for synovial inflammation and joint destruction in rheumatoid arthritis (RA). The detrimental role of TNF-receptor 1 (TNFR1) has thoroughly been characterized. The contributions of TNFR2, however, are largely unknown. This study was performed to delineate the role of TNFR2 in human FLS activation. Methods: TNFR2 expression in synovial tissue samples was determined by immunohistochemistry. Expression of TNFR2 was silenced using RNAi or CRISPR/Cas9 technologies. Global transcriptional changes were determined by RNA-seq. QPCR, ELISA and immunoblotting were used to validate RNA-seq results and to uncover pathways operating downstream of TNFR2 in FLS.  Results. TNFR2 expression was increased in RA when compared to OA synovial tissues. In particular, RA-FLS demonstrated higher levels of TNFR2 when compared to OA-FLS. TNFR2 expression in RA-FLS correlated with RA disease activity, synovial T- and B-cell infiltration. TNF and IL1 were identified as inflammatory mediators that upregulate TNFR2 in RA-FLS. Silencing of TNFR2 in RA-FLS markedly diminished the TNF-induced expression of inflammatory cytokines and chemokines, including CXCR3-binding chemokines and the B-cell activating factor TNFSF13B. Immunobiochemical analyses revealed that TNFR2-mediated expression of inflammatory mediators critically depends on STAT1. Conclusion: Our results define a critical role for TNFR2 in FLS-driven inflammation and unfold its participation in the unresolved course of synovial inflammation in RA.

Project description:Invasive pannus, mainly composed of fibroblast-like synoviocytes (FLSs), is a hallmark of rheumatoid arthritis (RA) pathology. Secreted proteins from RA-FLS play key roles in RA invasive pannus. However, RA-FLS-derived secretome associated with invasive pannus has not been systematically investigated. Here, we first identified 843 secreted proteins from RA-FLSs treated with TNFα and IL-1β using liquid chromatography-tandem mass spectrometry (LC-MS/MS) analysis. Functional enrichment analysis revealed that 58.5% (493 proteins) of the secretome were associated with pannus-driven RA pathologies. Among them, parallel reaction monitoring (PRM) analysis then identified 16 secreted proteins that were increased in RA SFs (117 samples) than in OA SFs (45 samples). Of them, MYH9 further showed significant positive correlations with RA pathological parameters, such as synovial hyperplasia, increased articular vascularity, and inflammation severity. Molecular and cellular experiments confirmed that MYH9 was expressed in RA-FLSs and more highly under disease-aggravating conditions, and MYH9 depletion significantly defected migration and invasion of RA-FLS in RA pannus. Our study provides a comprehensive resource of RA-FLS-derived secretome, and our results suggest MYH9 that was increased in RA SF and strongly correlated with disease severity as a potential therapeutic target for invasive pannus.

Project description:Rheumatoid synoviocytes, which consist of fibroblast-like synoviocytes (FLS) and synovial macrophages (SM), are crucial for the progression of rheumatoid arthritis (RA). Particularly, FLS of RA patients (RA-FLS) exhibit invasive characteristics reminiscent of cancer cells, destroying cartilage and bone, although it remains unresolved how RA-FLS exhibit invasive phenotype. RA-FLS and SM originate differently from mesenchymal and myeloid cells, respectively, but share many pathologic functions. However, the molecular signatures and biological networks representing the distinct and shared features of the two cell types are unknown. Presently, we performed global transcriptome profiling of FLS and SM obtained from RA and osteoarthritis patients. By comparing the transcriptomes, we identified distinct molecular signatures and cellular processes defining invasiveness of RA-FLS and pro-inflammatory properties of RA synovial macrophages (RA-SM), respectively. Interestingly, under interleukin1β-stimulated condition, RA-FLS newly acquired pro-inflammatory signature mimicking RA-SM without losing invasive properties. We next reconstructed a network model that delineates the shared, RA-FLS-dominant (invasive), and RA-SM-dominant (inflammatory) processes. From the network model, we selected 13 genes, including POSTN and TWIST1, as novel regulator candidates responsible for FLS invasiveness. Of note, POSTN and TWIST1 expressions were elevated in independent RA-FLS and were further instigated by interleukin1β. In vitro functional assays demonstrated the requirement of POSTN and TWIST1 for migration and invasion of RA-FLS stimulated with interleukin1β. Taken together, our systems approach to rheumatoid synovitis provides a basis for identifying novel regulators responsible for pathological features of RA-FLS and RA-SM, demonstrating how a certain type of cells acquires functional redundancy under chronic inflammatory conditions. To identify molecular signatures of FLS and MLS in RA joints, we isolated FLS from synovial tissues of RA and osteoarthritis (OA) patients, obtained synovial macrophages from synovial fluid of RA patients, and differentiated control macrophages from peripheral blood of healthy subjects. Also, we stimulated FLS with IL1β, and then analyzed gene expression profiles of both IL1β-stimulated RA-FLS and OA-FLS

Project description:T helper 17 (Th17) cells are found in peripheral blood and synovial fluid of rheumatoid arthritis (RA) patients, however IL-17-targeted interventions have shown limited efficacy in established RA. While it is known that inflammation can induce Th17 transdifferentiation into Th1- or Tr1-like IL-17-negative exTh17 cells, the role of exTh17 in arthritis is not known. Here, we explore the premise that exTh17 cells promote joint inflammation in autoimmune arthritis. To assess the potential immunophenotypic dynamics and role of exTh17 in inflammatory arthritis, we performed Th17 lineage tracing studies in the SKG mouse model of RA. We show that in arthritic mice, synovial Th17 transdifferentiate into IFNγ- and IL-10- exTh17 which become the most prominent CD4+ population in chronic arthritis. SKG exTh17 cells are more arthritogenic than Th17, and able to sustain synovial inflammation that is IL-17-independent but enriched with IL-6 and TNF, two RA-promoting cytokines. Synovial exTh17 present a unique gene signature, including upregulation of CD44 and S1PR4. This gene signature has correlates in the profile of CD4+ T cells found in human RA synovium. We further demonstrate that crosstalk between Th17 and fibroblast-like synoviocytes via S1P signaling promote Th17-exTh17 conversion. Additionally, CD44 is necessary for the arthritogenic effect of exTh17. Our study suggests that the fibroblast-like synoviocyte expansion, which occurs during RA progression, can drive progressive conversion of Th17 into exTh17 which sustains inflammation with features of human established RA. The results offer new insights that could be potentially useful for future precision therapy approaches to RA.

Project description:TNF-like ligand 1A (TL1A) is a member of TNF receptor superfamily and involved in the pathogenesis of autoimmune diseases by inducing apoptosis via intracellular death domain or promoting inflammation through the activation of NFM-NM-:B by binding to its specific receptor death receptor 3 (DR3). Meanwhile, decoy receptor 3 (DcR3) competitively binds soluble TL1A in addition to Fas-ligand (FasL) and LIGHT and inhibits the signaling of TL1A via DR3. DcR3 overexpressed in rheumatoid synovial fibroblasts (RA-FLS) stimulated with inflammatory cytokines such as TNFM-NM-1 or IL-1M-NM-2 inhibits Fas-induced apoptosis. In contrast, DcR3 inhibited cell proliferation induced by inflammatory cytokines via membrane-bound TL1A expressed on RA-FLS. Therefore, TL1A-DcR3/DR3 signaling may be involved in the pathogenesis of RA by modulating apoptosis and proliferation of RA-FLS. We hypothesized that TL1A regulates the gene expression in RA-FLS. We used to search for genes in which expression in RA-FLS is regulated by the ligation of TL1A. RA-FLS were obtained from 4 RA patients (sample1-4). Each sample was incubated with either 1.0 M-NM-<g/ml recombinant human TL1A protein or phosphate buffered saline (PBS) diluted with serum-free Opti-MEM medium as non-stimulated control for 12 hours at 37M-BM-0C with 5% CO2. Gene expression in RA-FLS stimulated by TL1A was compared with that of their respective non-stimulated controls.

Project description:TNF-like ligand 1A (TL1A) is a member of TNF receptor superfamily and involved in the pathogenesis of autoimmune diseases by inducing apoptosis via intracellular death domain or promoting inflammation through the activation of NFκB by binding to its specific receptor death receptor 3 (DR3). Meanwhile, decoy receptor 3 (DcR3) competitively binds soluble TL1A in addition to Fas-ligand (FasL) and LIGHT and inhibits the signaling of TL1A via DR3. DcR3 overexpressed in rheumatoid synovial fibroblasts (RA-FLS) stimulated with inflammatory cytokines such as TNFα or IL-1β inhibits Fas-induced apoptosis. In contrast, DcR3 inhibited cell proliferation induced by inflammatory cytokines via membrane-bound TL1A expressed on RA-FLS. Therefore, TL1A-DcR3/DR3 signaling may be involved in the pathogenesis of RA by modulating apoptosis and proliferation of RA-FLS. We hypothesized that TL1A regulates the gene expression in RA-FLS. We used to search for genes in which expression in RA-FLS is regulated by the ligation of TL1A.

Project description:The pathogenesis of rheumatoid arthritis (RA) is complicated and involves both innate and adaptive immunity [5]. The innate immunity such as macrophages or fibroblast-like synoviocytes (FLS) in the synovium can generate inflammatory mediators, including TNF-α, IL-1, IL-6, IL-17, IFN-γ, and chemo kines that lead to synovial inflammation, bone erosion, and cartilage damage [6-8]. The IL-17 signaling mediates the autoantibody production in collagen-induced arthritis (CIA) model [9]. However, the treatment response with an anti-IL17 monoclonal antibody in RA patients shows a high degree of heterogeneity [10]. The inhibitors of the Janus kinase (JAK) pathway are approved for RA patients [11]. These data suggest that the targeted multiple cytokines through the JAK pathway are useful for RA treatment. Disturbance of type I IFNs (IFNs-I) signaling and production drive autoimmune development [12]. The presymptomatic RA patients display an increase of IFNs-I before the onset of symptoms [13]. The RA patients also show the elevation of IFN- α in the synovial fluid and high expression of IFNs-I regulated gene in peripheral blood mononuclear cells (PBMC) [14]. However, the role of IFNs-I in arthritis and bone homeostasis has suggested the accelerating effect of arthritis and bone damage. The interferon-alpha receptor knockout mice develop arthritis severity higher than wild-type mice in the model of antigen-induced arthritis [15]. IFNs-I also affects the bone homeostasis by inhibiting osteoclastogenesis via receptor activator of nuclear factor-kappa B (RANK) pathway, and reduction of c-FOS expression [16-18]. Therefore, the goal of RA treatment with antagonizing the IFNs-I pathway has to be optimized between efficacy and potentially adverse effect. STING is a cytosolic DNA sensor that initiates the production of IFNs-I. STING functions have been reported as both pro-inflammatory signaling and negative regulator against inflammation [19-21]. The mutation in exon 5 of the STING gene results in gain function leading to initiate inflammation and cause the Sting associated vasculopathy with onset in infancy (SAVI) [22]. Loss of STING function rescues DNaseII-deficient mice from lethality and polyarthritis [23]. However, Sting-deficient lupus mice (MRL/Lpr mice) show higher and earlier mortality than Sting-sufficient MRL/Lpr mice [24]. The pathology also shows lymphoid hypertrophy with a higher amount of macrophages and granulocytes infiltration, autoantibodies, and cytokine [24]. The objective of this study was to identify the role of STING in the pathogenesis of rheumatoid arthritis using collagen-induced arthritis (CIA) model as a representative model of the human RA.