Project description:The identification of druggable therapeutic targets that preferentially promote autoimmunity remains a key goal in the field. Recent work shows that populations of memory/stem-like T cells drive autoimmunity, but the factors that generate and sustain these populations are incompletely understood. The lymphocyte-restricted transcriptional cofactor OCA-B/Pou2af1 is a regulator of CD4+ T cell memory. Here we show that T cell-intrinsic loss of OCA-B protects mice from experimental autoimmune encephalomyelitis (EAE) in both chronic and relapsing-remitting mouse models while preserving acute responses to infection with a neurotropic coronavirus. In adoptive transfer EAE driven by antigen re-encounter, T cell-specific OCA-B loss largely eliminates Th1- and Th17-mediated CNS infiltration, proinflammatory cytokine production and disease. Using an OCA-B-mCherry reporter mouse, we show that OCA-B expressing CD4+ T cells within the CNS of mice with EAE preferentially display a memory-like phenotype. Transferring these OCA-Bhi memory-like CD4+ T cells preferentially confers disease, identifying OCA-B as a marker of encephalitogenic autoreactive CD4+ T cells. Notably, in a relapsing-remitting EAE model, OCA-B T cell-deficient mice show specific protection at relapse, highlighting the potential to target OCA-B in MS patients to limit disease progression. During remission, OCA-B promotes the expression of Tcf7, Slamf6, and Sell in proliferating T cell populations. At relapse, OCA-B loss results in the accumulation of an immunomodulatory CD4+ T cell population expressing Ccr9 and Bach2. These results highlight OCA-B as a driver of pathogenic stem-like T cells responsible for relapse and promising MS therapeutic target.

Project description:The identification of druggable therapeutic targets that preferentially promote autoimmunity remains a key goal in the field. Recent work shows that populations of memory/stem-like T cells drive autoimmunity, but the factors that generate and sustain these populations are incompletely understood. The lymphocyte-restricted transcriptional cofactor OCA-B/Pou2af1 is a regulator of CD4+ T cell memory. Here we show that T cell-intrinsic loss of OCA-B protects mice from experimental autoimmune encephalomyelitis (EAE) in both chronic and relapsing-remitting mouse models while preserving acute responses to infection with a neurotropic coronavirus. In adoptive transfer EAE driven by antigen re-encounter, T cell-specific OCA-B loss largely eliminates Th1- and Th17-mediated CNS infiltration, proinflammatory cytokine production and disease. Using an OCA-B-mCherry reporter mouse, we show that OCA-B expressing CD4+ T cells within the CNS of mice with EAE preferentially display a memory-like phenotype. Transferring these OCA-Bhi memory-like CD4+ T cells preferentially confers disease, identifying OCA-B as a marker of encephalitogenic autoreactive CD4+ T cells. Notably, in a relapsing-remitting EAE model, OCA-B T cell-deficient mice show specific protection at relapse, highlighting the potential to target OCA-B in MS patients to limit disease progression. During remission, OCA-B promotes the expression of Tcf7, Slamf6, and Sell in proliferating T cell populations. At relapse, OCA-B loss results in the accumulation of an immunomodulatory CD4+ T cell population expressing Ccr9 and Bach2. These results highlight OCA-B as a driver of pathogenic stem-like T cells responsible for relapse and promising MS therapeutic target.

Project description:Experimental autoimmune encephalomyelitis (EAE) is a murine model of multiple sclerosis, a chronic neurodegenerative and inflammatory autoimmune condition of the central nervous system (CNS). Pathology is driven by the infiltration of autoreactive CD4+ lymphocytes into the CNS where they attack neuronal sheaths causing ascending paralysis. We used an isotope-coded protein labelling approach to investigate the proteome of CD4+ cells isolated from the spinal cord and brain of mice at various stages of EAE progression in two EAE disease models; PLP139-151-induced relapsing-remitting EAE and MOG35-55-induced chronic EAE, which emulate the two forms of human multiple sclerosis. A total of 1120 proteins were quantified across disease onset, peak-disease and remission phases of disease and of these, 13 up-regulated proteins of interest were identified with functions relating to the regulation of inflammation, leukocyte adhesion and migration, tissue repair and the regulation of transcription/translation. Proteins implicated in processes such as inflammation (S100A4 and S100A9) and tissue repair (Annexin A1), which represent key events during EAE progression were validated by quantitative PCR. This is the first targeted analysis of autoreactive cells purified from the CNS during EAE, highlighting fundamental CD4+ cell-driven processes that occur during the initiation of relapse and remission stages of disease.

Project description:Full development of IL-17 producing CD4+ T helper cells (TH17 cells) requires the transcriptional activity of both orphan nuclear receptors RORa and RORgt. Despite this evidence, RORa is considered functionally redundant to RORgt; thus, the function and therapeutic value of RORa in TH17 cells remains underexplored. Using mouse models of autoimmune and chronic inflammation, we show that expression of RORa is required for TH17 cell pathogenicity. T-cell specific deletion of RORa reduced the development of experimental autoimmune encephalomyelitis (EAE) and colitis. Reduced inflammation was associated with decreased TH17 cell development, lower expression of tissue-homing chemokine receptors and integrins, and increased frequencies of Foxp3+ T regulatory (Treg) cells. Importantly, inhibition of RORa with a selective small molecule antagonist largely phenocopied our genetic data, potently suppressing the in vivo development of both chronic/progressive and relapsing/remitting EAE but had no effect on overall thymic cellularity. Furthermore, use of the RORa antagonist effectively inhibited human TH17 cell differentiation and memory cytokine secretion. Together, these data suggest that RORa acts independently of RORgt in programming TH17 pathogenicity and identifies RORa as a safer and more selective therapeutic target for the treatment of TH17-mediated autoimmunity.

Project description:Epigenetic changes are crucial for the generation of immunological memory. Failure to generate or maintain these changes will result in poor memory responses. Similarly, augmenting or stabilizing the correct epigenetic states offers a potential method of enhancing immune memory. Yet the transcription factors that regulate these processes are poorly defined, as are the target genes they control and they chromatin-modifying complexes they recruit. Using model pathogens and three different mouse models, we find that the widely expressed transcription factor Oct1 and its cofactor OCA-B are selectively required for the in vivo generation of functional CD4 memory. In vitro, both proteins are required to maintain a poised state at the Il2 target locus in resting but previously stimulated CD4 T cells, and to generate robust Il2 expression upon restimulation. Gene expression profiling indicates that OCA-B is also required for the robust re-expression of multiple other targets including Ifng and Il17a. ChIPseq identify multiple differentially expressed direct targets. We identify an underlying mechanism involving OCA-B recruitment of the histone lysine demethylase Jmjd1a to targets such as Il2 and Ifng. The findings pinpoint Oct1 and OCA-B as unanticipated mediators of CD4 T cell memory. Examination of transcription factor occupancy in CD4 T cells upon rest and restimulation.

Project description:Using liquid chromatography combined with tandem mass spectrometry, we want to use quantitative proteomics of CD4+ T cells from relapsing-remitting MS (RRMS) patients and healthy controls. Cells were left unstimulated or stimulated through the T cell receptor (TCR) in vitro allowing us to disentangle potential CD4+ T cell specific differences induced by T cell activation This will provide novel insights into disease mechanisms of MS.

Project description:Epigenetic changes are crucial for the generation of immunological memory1-4. Failure to generate or maintain these changes will result in poor memory responses. Similarly, augmenting or stabilizing the correct epigenetic states offers a potential method of enhancing immune memory. Yet the transcription factors that regulate these processes are poorly defined, as are the chromatin modifying complexes they recruit and the chromatin modifications they control. Using pathogen infection models and three different mouse models, including a new conditional allele, we find that the widely expressed transcription factor Oct15, and its cofactor OCA-B6,7, are selectively required the in vivo generation of functional CD4 memory. In vitro, both proteins are also required to maintain a poised state at the Il2 target locus in resting but previously stimulated CD4 T cells, and to generate robust Il2 expression upon restimulation. OCA-B is also required for the robust re-expression of other known targets including Il17a, and Ifng. We identify an underlying mechanism involving OCA-B recruitment of the histone lysine demethylase Jmjd1a8 to targets such as Il2 and Ifng. The findings pinpoint Oct1 and OCA-B as unanticipated mediators of CD4 T cell memory. Examination of 4 different conditions in 2 genotypes

Project description:The transcriptional coregulator OCA-B is induced in stimulated naïve CD4+ T cells, where docks with transcription factor Oct1 to regulate genes such as Il2 and Ifng. OCA-B regulates its targets in cases of repeated antigen exposure, a necessary feature of autoimmunity. Polymorphisms in binding sites for Oct1, and by extension OCA-B, as associated with multiple forms of autoimmunity including autoimmune (type-1) diabetes. We hypothesized that T cell-specific OCA-B deletion would protect mice from type-1 diabetes, and that pharmacologic OCA-B inhibition would provide similar protection. We developed an Ocab (Pou2af1) conditional allele and backcrossed it onto a diabetes-prone NOD/ShiLtJ strain background. T cell-specific OCA-B loss protected mice from spontaneous T1D. To clarify the mechanism, we profiled leukocytes from prediabetic islets by single-cell RNA sequencing and T cell receptor clonotype analysis.

Project description:Objective: Multiple sclerosis (MS) is a chronic inflammatory demyelinating disease of the central nervous system (CNS), characterized by a global increasing incidence driven by relapsing-remitting disease in females. p38 MAP kinase (MAPK) has been described as a key regulator of inflammatory responses in autoimmunity, but its role in the sexual dimorphism in MS or MS models remains unexplored. Methods: Toward this end, we used experimental autoimmune encephalomyelitis (EAE), the principal animal model of MS, combined with pharmacologic and genetic inhibition of p38 MAPK activity and transcriptomic analyses. Results: Pharmacologic inhibition of p38 MAPK selectively ameliorated EAE in female mice. Conditional deletion studies demonstrated that p38M-NM-1 signaling in macrophages/myeloid cells, but not T cells or dendritic cells, recapitulated this sexual dimorphism. Analysis of CNS inflammatory infiltrates showed that female, but not male mice lacking p38M-NM-1 in myeloid cells exhibited reduced immune cell activation compared with controls, while peripheral T cell priming was unaffected in both sexes. Transcriptomic analyses of myeloid cells revealed differences in p38M-NM-1-controlled transcripts comprising female- and male-specific gene modules, with greater p38M-NM-1 dependence of pro-inflammatory gene expression in females. Interpretation: Our findings demonstrate a key role for p38M-NM-1 in myeloid cells in CNS autoimmunity and uncover important molecular mechanisms underlying sex differences in disease pathogenesis. Taken together, our results suggest that the p38 MAPK signaling pathway represents a novel target for much needed disease modifying therapies for MS WT vs. p38alphaCKO macrophages, male vs. female

Project description:We analyzed the gene expression patterns of different blood cell types before and during fingolimod treatment in a group of patients with relapsing-remitting multiple sclerosis (RRMS). Affymetrix Human Transcriptome Arrays (HTA) 2.0 were used to obtain gene expression profiles of immune cell populations from 10 RRMS patients within the first 3 months of fingolimod treatment. This GEO entry provides the Affymetrix HTA 2.0 microarray data of peripheral blood CD4+ cells, preprocessed according to the exon level workflow.