R e v i e w S e R i e S : A u t o i m m u n i t y2 2 2 9 jci.org Volume 125 Number 6 June 2015theories have been proposed to explain this association, including epitope spreading, antigenic complementarity, and excessive innate/pattern recognition receptor activation. For example, evidence of EBV infection in postmortem brain tissue has been associated with MS but not other inflammatory disorders (17). Additionally, systemic infections have been reported to trigger relapses in patients with relapsing-remitting MS through enhancement of myelin-specific T cell responses (15). Another example of the association of infections with autoimmunity is that of periodontal infections and rheumatoid arthritis (18). In contrast, infections are also postulated to protect against some autoimmune diseases. For example, infection of germ-free mice with Bacteroides fragilis has been reported to protect against experimental autoimmune encephalomyelitis, the mouse model of MS, through induction of Treg cells (19). Additionally, a higher incidence of MS and type 1 diabetes is correlated with a decreased number of infections in developed countries (20). Recent interest has focused on the possible role of the microbiome in influencing local and systemic immune responses. Much of the emphasis has been on the gut microbiome. It is now believed that inflammatory bowel disease (IBD) is initiated by dysregulated and exaggerated immune responses to intestinal commensal microbes. In fact, the major manifestations of IBD may be caused by antimicrobial immune reactions and not by true autoimmunity (i.e., directed at tissue self-antigens). There are also several studies in mice that implicate commensal microbes in autoimmune disease, including type 1 diabetes (reviewed in ref. 21).A well-recognized nonmicrobial environmental trigger is UV irradiation for cutaneous lupus. A possible explanation for this connection is that UV radiation induces apoptotic death of many cell types and increases the burden of nuclear antigens, especially if the dead cells cannot be efficiently cleared (22). It has been suggested that low-level natural cell death in tissues is a mechanism for maintaining peripheral tolerance to tissue antigens through tolerance-promoting dendritic cell populations (23). It is plausible that lupus patients have a genetic predisposition for this system to become easily overwhelmed and are thus unable to maintain tolerance in the presence of continual UV exposure.Defective regulation as the cause of autoimmunity. If failure of self-tolerance is the fundamental abnormality in autoimmune diseases, the central question becomes -which mechanisms of tolerance fail in specific diseases, and why? In patients with SLE, defects in deletion of immature B cells in the bone marrow, in receptor editing, and in control of mature B cells in peripheral tissues have all been proposed (24). In humans with SLE, mature naive B cells can produce autoantibodies even before encounter with antigen, suggesting that defects in early B cell tolerance checkpoints m...
MicroRNAs (miRNAs) exert powerful effects on immune function by tuning networks of target genes that orchestrate cell behavior. We sought to uncover miRNAs and miRNA-regulated pathways that control the TH2 responses that drive pathogenic inflammation in asthma. Profiling miRNA expression in human airway-infiltrating T cells revealed miR-19a elevation in asthma. Modulating miR-19 activity altered TH2 cytokine production in both human and mouse T cells, and TH2 cell responses were markedly impaired in cells lacking the entire miR-17∼92 cluster. miR-19 promotes TH2 cytokine production and amplifies PI(3)K, JAK-STAT, and NF-κB signaling by direct targeting of PTEN, SOCS1, and A20. Thus, miR-19a up regulation in asthma may be an indicator and a cause of increased TH2 cytokine production in the airways.
Objective Adoptive Treg cell therapy has great potential to treat autoimmune disease. Currently, very little is known about how these cells impact inflamed tissues. This study was undertaken to elucidate how autologous Treg cell therapy influences tissue inflammation in human autoimmune disease. Methods We describe a systemic lupus erythematosus (SLE) patient with active skin disease who received adoptive Treg therapy. We comprehensively quantified Treg cells and immune activation in peripheral blood and skin, with data obtained at multiple time points posttreatment. Results Deuterium tracking of infused Treg cells revealed the transient presence of cells in peripheral blood, accompanied by increased percentages of highly activated Treg cells in diseased skin. Flow cytometric analysis and whole transcriptome RNA sequencing revealed that Treg cell accumulation in skin was associated with a marked attenuation of the interferon‐γ pathway and a reciprocal augmentation of the interleukin‐17 (IL‐17) pathway. This phenomenon was more pronounced in skin relative to peripheral blood. To validate these findings, we investigated Treg cell adoptive transfer of skin inflammation in a murine model and found that it also resulted in a pronounced skewing away from Th1 immunity and toward IL‐17 production. Conclusion We report the first case of a patient with SLE treated with autologous adoptive Treg cell therapy. Taken together, our results suggest that this treatment leads to increased activated Treg cells in inflamed skin, with a dynamic shift from Th1 to Th17 responses.
During an immune response against a microbial pathogen, activated naïve T lymphocytes give rise to effector cells that provide acute host defense and memory cells that provide long-lived immunity. It has been shown that T lymphocytes can undergo asymmetric division, enabling the daughter cells to inherit unequal amounts of fate-determining proteins and thereby acquire distinct fates from their inception. Here, we show that the absence of the atypical protein kinase C (aPKC) isoforms, PKCζ and PKCλ/ι, disrupts asymmetric CD8+ T lymphocyte division. These alterations were associated with aberrant acquisition of a ‘pre-effector’ transcriptional program, detected by single-cell gene expression analyses, in lymphocytes that had undergone their first division in vivo and enhanced differentiation toward effector fates at the expense of memory fates. Together, these results demonstrate a role for aPKC in regulating asymmetric division and the specification of divergent CD8+ T lymphocyte fates early during an immune response.
Talin, a cytoskeletal protein essential in mediating integrin activation, has been previously shown to be involved in the regulation of T cell proliferation and function. Here we describe a role for talin in maintaining the homeostasis and survival of the regulatory T (Treg) cell pool. T cell-specific deletion of talin in Tln1fl/flCd4Cre mice resulted in spontaneous lymphocyte activation, primarily due to numerical and functional deficiencies of Treg cells in the periphery. Peripheral talin-deficient Treg cells were unable to maintain high expression of IL-2Rα, resulting in impaired IL-2 signaling and ultimately leading to increased apoptosis through downregulation of pro-survival proteins Bcl-2 and Mcl-1. The requirement for talin in maintaining high IL-2Rα expression by Treg cells was due, in part, to integrin LFA-1-mediated interactions between Treg cells and dendritic cells. Collectively, our data suggest a critical role for talin in Treg cell-mediated maintenance of immune homeostasis.
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