Transplantation is a cure for end stage organ failure, yet achieving “one transplant for life” remains elusive for many transplant recipients due to immunologic rejection. Studies in mouse and NHP models and patient populations have consistently implicated memory CD8+ T cells as playing a causal role in mediating immunosuppression-resistant allograft rejection. Thus, the identification of the molecular mechanisms that regulate memory CD8+ T cells responses remains an important goal for immunotherapy in clinical transplantation. Fc receptors, previously known only to be expressed on B cells and innate immune cells, can fine-tune immune cell activation based on the balance of activating and inhibitory Fc receptor signaling, much like T cell costimulatory and coinhibitory molecules. During the last funding cycle we identified that the inhibitory receptor FcγRIIB is also expressed on a subset of multi-functional effector/ memory CD8+ T cells in mice and in humans, and showed that FcγRIIB functionally regulates CD8+ T cell immunity in a cell- autonomous manner in both mice and in a human clinical trial. However, the mechanisms by which this occurs are still not clear. First, the signals via which FcγRIIB ligation leads to T cell death are not known. We discovered that FcγRIIB signaling on CD8+ T cells is not controlled by antibody ligation, but instead by a novel immunosuppressive cytokine fibrinogen-like 2 (Fgl2). Moreover, our additional preliminary data suggest a FcγRIIB SHIP1-dependent mechanism that leads to the induction of apoptosis. Thus, in Aim 1, we will determine the cellular source of Fgl2 that is critical for FcγRIIB-mediated CD8+ T cell apoptosis, and will use a proteomics approach to elucidate the proximal intracellular signaling molecules that associate with FcγRIIB to promote caspase 3/7 activity. Second, we made the novel observation that FcγRIIB+ CD8+ T cells exhibit increased expression of the ganglioside metabolic enzyme Gm2a, and that increased expression of Gm2a mRNA in CD8+ T cells is associated with stability on minimal immunosuppression in a cohort of human renal transplant recipients. These preliminary data form the premise for the hypothesis to be tested in Aim 2: that Gm2a is a novel regulatory pathway that regulates transplant acceptance, potentially in an FcγRIIB- dependent fashion. Finally, in Aim 3 we propose to directly measure FcγRIIB, Fgl2, and Gm2a expression in CD8+ T cells isolated from a validation cohort of human renal transplant recipients, and to determine the association between CD8+ T cell FcγRIIB and Gm2a expression and reduced alloimmunity and/or acute rejection. These data will allow us to determine the ability of FcγRIIB/Gm2a-expressing T cells to be used as a predictive biomarker to stratify the risk of rejection following transplantation. In sum, through these mechanistic and translational studies, we will elucidate the fundamental molecular and cellular pathways of FcγRIIB- mediated inhibition of CD...