Interferon signature in giant cell arteritis aortitis.

OBJECTIVES: Molecular mechanisms underlying large-vessel involvement in giant cell arteritis (LV-GCA) are largely unknown. Herein, we explore the critical involvement of pro-inflammatory signaling pathways in both aorta and T cells from patients with LV-GCA. METHODS: We analyzed transcriptome and interferon gene signature in inflamed aortas from LV-GCA patients and compared them to non-inflammatory control aorta. Differential transcriptomic analyses of circulating CD4+ and CD8+ T cells were also performed between patients with active GCA (not under any immunosuppressants or corticosteroid doses higher than 10 mg/day by the time of blood collection) and healthy donors. Interferon-alpha serum levels were measured using ultra-sensitive technique (HD-X Simoa Planar Technology) in GCA patients according to disease activity status. RESULTS: Transcriptomic analyses revealed 1042, 1479 and 2075 significantly dysregulated genes for aortas, CD4+ and CD8+ cells from LV-GCA patients, respectively, as compared to controls. A great enrichment for pathways linked to interferons (type I, II and III), JAK/STAT signaling, cytokines and chemokines was seen across aortas and circulating T cells. A type I interferon signature was identified as significantly upregulated in the aorta of patients with LV-GCA, notably regarding EPSTI1 and IFI44L genes. STAT3 was significantly upregulated in both aorta and T cells and appeared as central in related gene networks from LV-GCA patients. Interferon-alpha serum levels were higher in patients with active GCA when compared to those in remission (0.024 vs. 0.011 pg/mL; p = 0.028). CONCLUSION: LV-GCA presents a clear type I interferon signature in aortas, which paves the way for tailored therapeutical targeting.

Inflammatory Flt3l is essential to mobilize dendritic cells and for T cell responses during Plasmodium infection.

Innate sensing mechanisms trigger a variety of humoral and cellular events that are essential to adaptive immune responses. Here we describe an innate sensing pathway triggered by Plasmodium infection that regulates dendritic cell homeostasis and adaptive immunity through Flt3 ligand (Flt3l) release. Plasmodium-induced Flt3l release in mice requires Toll-like receptor (TLR) activation and type I interferon (IFN) production. We found that type I IFN supports the upregulation of xanthine dehydrogenase, which metabolizes the xanthine accumulating in infected erythrocytes to uric acid. Uric acid crystals trigger mast cells to release soluble Flt3l from a pre-synthesized membrane-associated precursor. During infection, Flt3l preferentially stimulates expansion of the CD8-α(+) dendritic cell subset or its BDCA3(+) human dendritic cell equivalent and has a substantial impact on the magnitude of T cell activation, mostly in the CD8(+) compartment. Our findings highlight a new mechanism that regulates dendritic cell homeostasis and T cell responses to infection.

CD4+CD25+ regulatory/suppressor T cells prevent allogeneic fetus rejection in mice.

Recent evidences indicate that naturally occurring CD4+CD25+ regulatory/suppressor T cells (T(reg)) regulate not only autoimmunity, but also alloreactivity. In mice, they notably control tolerance to allogeneic transplants and graft-versus-host disease after allogeneic hematopoietic stem cell transplantation. Here, we studied the role of T(reg) in maternal tolerance to fetuses, i.e. natural semi-allogeneic grafts. We show that semi-allogeneic pregnancies in mice induce an expansion of T(reg), but not of activated CD4+ and CD8+ T cells, in para-aortic lymph nodes draining fetal antigens. The treatment of female mice with an anti-CD25 antibody before mating results in depletion of T(reg) and expansion of activated CD4+ and CD8+ T cells solely in the draining lymph nodes, ultimately leading to fetus rejection. These observations were not made in the context of syngeneic pregnancies. Thus, T(reg) play a major role in maternal-fetal tolerance.