Project description:The use of autologous tolerogenic dendritic cells (tolDC) has become a promising alternative for the treatment of autoimmune diseases. Among the different alternatives available, the use of vitamin D3 for the generation of tolDC (vitD3‑tolDC) constitutes one of the most robust approaches due to their immune regulatory properties, which are currently being tested in clinical trials. However, the mechanisms that vitD3‑tolDC are triggering for the induction of tolerance remain elusive. For this reason, we have performed a full transcriptomic characterization of T cells upon their interaction with autologous, antigen-specific vitD3-tolDC. Our results evidenced a strong down-modulation of genes involved in cell cycle and cell response to immune-related stimuli in T CD4+ cells after their interaction with vitD3-tolDC. Consequently, our results show the induction of a strong antigen-specific hyporresponsiveness, which manifests the regulatory properties of these cells and therefore their therapeutic potential in the clinic.

Project description:Complex autoimmune diseases have proven difficult to dissect down to their causative genetic mechanisms. As a result, epidemiological data from different human association studies are often merged to arrive at a working hypothesis. In one of such examples, lack of sun exposure and consequent lower serum vitamin D3 levels has been proposed to increase risk of autoimmunity, attributing vitamin D3 an immune regulatory role. However, conclusive evidence demonstrating its efficacy in treating autoimmune diseases is missing. In this study, we have used a forward genetics approach to positionally identify polymorphic nucleotides controlling T cell-dependent inflammatory diseases using congenic mouse strains. Here, we identify the vitamin D3 receptor (Vdr) as a driver of inflammation. Congenic mice carrying a polymorphic Vdr allele overexpressed the receptor selectively in activated T cells, thereby escaping systemic calcaemic side effects that often constitute a confounding factor in the study of immunomodulation by vitamin D3. Mice overexpressing Vdr in T cells developed more severe collagen-induced arthritis (CIA) and exhibited an enhanced antigen-specific CD4+ T cell response. Deficiency of vitamin D3 completely protected mice from CIA by limiting the activation of antigen-specific T cell responses, and arthritis susceptibility was restored by re-administration of vitamin D3. We demonstrate that vitamin D3 signalling specifically through Vdr predominantly acts to enhance T cell proliferation, thereby contributing to inflammation. In conclusion, our results demonstrate that genetically determined expression of VDR codetermines the pro-inflammatory behaviour of activated T cells. Furthermore, our data suggest that the anti-inflammatory properties of vitamin D3 might be limited by high expression of VDR at the site of inflammation.

Project description:The comparative analysis of the transcriptome of tolerogenic dendritic cells (tolDC) differentiated using different stimulus (either vitamin D3, dexamethasone or rapamycin) would allow to evidence potential common genes and pathways that could explain their potency as tolerance-inducing cells.

Project description:We screened the differential expressed microRNA from the rheumatoid arthritis patients and healthy person in their hydrops articuli CD4+ T cells. We screened the differential expressed microRNA from the rheumatoid arthritis patients and healthy person in their hydrops articuli CD4+ T cells. 1.Isolated the CD4+ T cells from the hydrops articuli cells of 2 rheumatoid arthritis patients. 2.Isolated the CD4+ T cells from healthy person's peripheral blood as control. 3.Isolation of total RNA from CD4+ T cells then sent the samples to KangChen Bio-tech Inc (Shanghai, China) where they were labeled, hybridized, scaned, normalied and transformed to the final data.

Project description:Rheumatoid arthritis (RA) is a systemic autoimmune disease characterized by chronic destructive arthritis. Although helper T cells are involved in the pathogenesis of RA, the characteristics of synovium-infiltrating CD4+ T cells are still largely unknown. In this study, we investigated synovium-infiltrating helper T cells of rheumatoid arthritis patients

Project description:Synovial biopsies of Rheumatoid Arthritis patients with active disease were obtained prior to anti-TNF therapy. Clinical response to anti-TNF treatment was measured 20 weeks later using the EULAR response criteria. Gene expression profiles of patients responding to anti-TNF therapy were compared to non-responders and several genes were found to be differentially expressed between both groups of Rheumatoid Arthritis patients.

Project description:It has been suggested that CD4+ T cell senescence is involved in the pathogenesis of elderly-onset rheumatoid arthritis (EORA). We performed scRNA-seq analysis using CD4+ T cells collected from inguinal lymph nodes of young and old DBA/1 mice to investigate the association between aging CD4+ T cells and elderly-onset arthritis.

Project description:Exosomes were isolated from CD4+T cell by ExoQuickTC kit in rheumatoid arthritis patients and controls. Proteomic analysis of CD4+ T-cell-derived exosomes was performed by TMT combined with LC‒MS/MS.

Project description:Rheumatoid arthritis (RA) is an autoimmune disease that causes chronic inflammation of the joints involved with genetic and epigenetic aberrant. Recent evidence found more and more importance of the epigenetic contribution, especially the DNA methylation, to the pathogenesis of rheumatoid arthritis. To understand the extent and nature of dysregulated DNA methylation in rheumatoid arthritis T cells, we performed a genome-wide DNA methylation study in CD4+ T cells in 12 rheumatoid arthritis patients compared to 12 matched normal healthy controls. [Methods and Result] Cytosine methylation status was quantified with Illumina methylation 450K microarray (HM450K, 485512 CpG sites). We identified 810 hypomethylated and 392 hypermethylated CG sites in RA CD4+ T cells compared to normal controls, representing 383 and 785 genes hypermethylated and hypomethylated in RA patients (P<3.4*10-7). Cluster analysis based on significantly differential methylated loci showed distinct separation between RA and normal controls. Gene ontology analysis showed alternative splicing (P=1.2*10-7, FDR) and phosphoprotein (1.7*10-2, FDR) were significantly aberrant in RA patients, indicating the abnormal of transcript alternative splicing and protein modification mediated by DNA methylation might play important role in the pathogenesis of rheumatoid arthritis. What’s more, the result showed human leukocyte antigen (HLA) region was frequently hypomethylated in RA patients, including HLA-DRB6, HLA-DQA1 and HLA-E, however, HLA-DQB1 showed different methylation profiles with significant hypermethylation in CpG island region and hypomethylation in CpG shelf region. Outsite of the MHC region, the most hypermethylated genes in RA included HDAC4, NXN, TBCD and TMEM61 while the most significant hypomethylated genes included ITIH3, TCN2, PRDM16, SLC1A5 and GALNT9. [Conclusion] Genome-wide DNA methylation patterns revealed significant DNA methylation change in CD4+ T cells from patients with rheumatoid arthritis. 12 rheumatoid arthritis and 12 matched health individuals

Project description:We screened the differential expressed microRNA from the rheumatoid arthritis patients and healthy person in their hydrops articuli CD4+ T cells.