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Modulating the T cell response: using anti-interleukin-7 receptor-alpha monoclonal antibodies with autoantigen-specific immunotherapy to prevent type-1-diabetesLawson, Maxx 09 August 2019 (has links)
Autoimmunity develops over an extended period of time as the result of an amalgamation of genetic, environmental, and immunologic events. Though the precise etiological factors leading to most autoimmune disease are awaiting consensus, a common thread of the autoimmune paradigm is the inappropriate activation of tissue-specific immune cells by one or more autoantigen, which begins the destruction of the tissue. To prohibit immunopathology and fine-tune the immune responses in healthy individuals, the stimulatory activities of effector/memory T (Teffs) cells must be counteracted by the suppressive mechanisms of regulatory T cells (Tregs). Thus, the potential to modulate the ratio between Teff and Tregs in autoimmune patients has been widely investigated with high hopes to permanently cure certain autoimmune diseases such as type 1 diabetes militus (T1D). Autoantigen therapies, which attempt to induce Tregs to suppress pathogenic effector cells in an autoantigen-specific manner, have shown efficacy in preventing T1D in mice, but have largely failed in clinical trials. One approach to improve the effectiveness of islet autoantigen vaccinations is to combine them with an additional modulator of the T cell response which favors a regulatory phenotype. In the work presented here, we asked whether the addition of anti-interleukin-7 receptor-alpha (anti-IL-7Rα) monoclonal antibodies (mAbs) to islet autoantigen immunizations would modulate the T cell response and prevent T1D in non-obese diabetic (NOD) mice. It was found that anti-IL-7Rα mAbs reduced the absolute numbers of islet antigen-specific T cells when immunized with islet peptide in conjunction with the commonly used vaccine adjuvant alum. Such treatments were also observed to increase nonspecific IL-2, IFN-𝛾, and IL-10 cytokine production, resulting in no improvement of T1D onset prevention. In another approach, we generated a conjugate vaccine by conjugating islet autoantigens to the immunogenic carrier protein, Keyhole Limpet Hemocyanin (KLH). We found that islet antigen-KLH (Ag-KLH) vaccination resulted in significant expansion of the desirable antigen-specific Tregs. Further, Ag-KLH immunization successfully delayed, and in some cases entirely prevented, T1D onset in NOD mice. Indicating that KLH-conjugated vaccine may represent a promising approach for future autoantigen therapies against autoimmunity. Interestingly, administration of anti-IL-7Rα mAbs did not improve these outcomes. To the contrary, we again observed excessive nonspecific cytokine production induced by IL-7Rα blockade that inhibited the beneficial effects of Ag-KLH vaccination. Taken together, we concluded that the addition of anti-IL-7Rα mAbs did not improve the efficacy of autoantigen vaccinations to prevent T1D. Significant work still remains to better characterize and isolate the beneficial effects of anti-IL-7Rα mAbs to treat autoimmunity.
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