Matured Tolerogenic Dendritic Cells Effectively Inhibit Autoantigen Specific CD4+ T Cells in a Murine Arthritis Model.

Tolerogenic dendritic cells (tolDCs) are a promising treatment modality for diseases caused by a breach in immune tolerance, such as rheumatoid arthritis. Current medication for these diseases is directed toward symptom suppression but no real cure is available yet. TolDC-based therapy aims to restore immune tolerance in an antigen-specific manner. Here we used a mouse model to address two major questions: (i) is a maturation stimulus needed for tolDC function in vitro and in vivo and is maturation required for functioning in experimental arthritis and (ii) can tolDCs modulate CD4+ T cell responses? To answer these questions, we compared matured and immature dexamethasone/vitamin D3-generated tolDCs in vitro. Subsequently, we co-transferred these tolDCs with naïve or effector CD4+ T cells to study the characteristics of transferred T cells after 3 days with flow cytometry and Luminex multiplex assays. In addition, we tested the suppressive capabilities of tolDCs in an experimental arthritis model. We found that tolDCs cannot only modulate naïve CD4+ T cell responses as shown by fewer proliferated and activated CD4+ T cells in vivo, but also effector CD4+ T cells. In addition, Treg (CD4+CD25+FoxP3+) expansions were seen in the proliferating cell population in the presence of tolDCs. Furthermore, we show that administered tolDCs are capable to inhibit arthritis in the proteoglycan-induced arthritis model. However, a maturation stimulus is needed for tolDCs to manifest this tolerizing function in an inflammatory environment. Our data will be instrumental for optimization of future tolDC therapies for autoimmune diseases.

Oral exposure to drugs with immune-adjuvant potential induces hypersensitivity responses to the reporter antigen TNP-OVA.

Immune-mediated drug hypersensitivity reactions are important causes of black box warnings and drug withdrawals. Despite the high demand for preclinical screening tools, no validated in vitro or in vivo models are available. In the current study, we used a previously described oral administration model using trinitrophenyl-ovalbumin (TNP-OVA) as an antigen to report immuno-adjuvating effects of the analgesic drug acetaminophen (APAP) and its nonhepatotoxic regioisomer 3'-hydroxyacetanilide (AMAP), the antibiotic ofloxacin (OFLX), the antiepileptic drug carbamazepine (CMZ), and the antidiabetic drug metformin (MET). Furthermore, APAP and AMAP were tested in a popliteal lymph node assay (PLNA) combined with TNP-OVA as reporter antigen (RA). C3H/HeOuJ mice were dosed by oral gavage with diclofenac (DF), APAP, AMAP, OFLX, MET, or CMZ. On the first exposure day, the mice received an ip injection with TNP-OVA. Fifteen days later, they were ear challenged with TNP-OVA and delayed-type hypersensitivity (DTH) responses were assessed 24 h later. One week after challenge, the ear-draining lymph node was removed and TNP-specific antibody-secreting cells were determined. DF, APAP, CMZ, and OFLX showed a significant increase in DTH responses to ear injection with TNP-OVA, whereas AMAP and MET did not. C57BL/6 mice were slightly less responsive to APAP and DF after oral gavage, and importantly both AMAP and APAP were negative in the RA-PLNA. The present work shows that the oral exposure model using RA and the RA-PLNA may serve to screen the immune-adjuvant potential of new chemical entities during preclinical drug development.