Type 1 diabetes (T1D) results from insulin insufficiency due to the loss or dysfunction of pancreatic beta cells following T cell-mediated autoimmune attack. Currently the only long-term therapy is daily exogenous insulin replacement. The ideal curative approach is the durable restoration of functional islets via transplantation. To date the limiting factors impeding realization of this goal is the lack of a cost effective and limitless source of high-quality islets suitable for transplantation and the ability to provide long-term islet graft acceptance without prolonged need for deleterious immunosuppression. Ongoing clinical trials are testing islets derived from human induced pluripotent stem cells (iPSC); however, long-term acceptance of islet graft will require a effective therapeutic strategy to prevent engrafted islet destruction by pre-existing islet-antigen specific T cells. Here we demonstrate in the NOD mouse model for T1D that autologous islet graft acceptance can be achieved by the targeted elimination of (re)-activated islet-reactive CD4 + and CD8 + T effector (Teff) cells in the initial post-transplantation period by using a short-acting, combination therapy that results in the elimination of islet-reactive Teff cells by exacerbation of their natural DNA damage response (DDR) to drive apoptosis while at the same time maintaining endogenous Treg cells.
Article highlights: Activated beta-cell reactive CD4 + and CD8 + T effector cells undergo a profound DNA-damage response which is targetable by small molecule inhibitors of the p53 and cell cycle pathways that lead to apoptosis. The use of a combination of MDM2 and WEE1 inhibitors, which termed "p53 potentiation with checkpoint abrogation" (PPCA), conferred significant therapeutic efficacy in treating mouse models of new onset T1D. Specific targeting of these T effector cells by PPCA results in a loss of inflammatory T cell subsets, notably proliferation CD4 + Th0 and Th1 subsets and CD8 + T effector memory cells, as determined by single cell RNA-seq studies with the preservation of T regulatory cells. When autologous islet grafts are given to established diabetic NOD mice, a single course of PPCA results in long-term islet graft acceptance, restoration of normoglycemia and loss of beta cell specific CD4 + and CD8 + T cells. PPCA shows promise as a potential means of estimating islet graft tolerance in T1D recipients of islet graft transplantation.