Abstract The adaptive immune system has the capacity to recognize and kill malignant cells. However, immune tolerant mechanisms that normally protect healthy tissues from autoimmune attack prevent the development of effective anti-tumor immunity. Tumor uses numerous immunosuppressive mechanisms to evade otherwise effective T-cell responses. A growing number of immune evasion mechanisms have been characterized including molecular and cellular mechanisms. Despite promising results achieved by targeting one or more of these immune evasion mechanisms, there is clearly room for improvement since only a subset of cancer patients usually respond to such a treatment. The PIM kinases have been studied extensively in tumorigenesis and as potential therapeutic targets for various cancers. PIM kinases are also expressed on activated T cells, but their roles in T-cell activity and function are inconclusive and the functions of each isoform in these cells remain unclear. Using genetically mutant mice, we found that individual PIM kinases play unique as well as overlapping roles in T-cell response to alloantigens. Strikingly, we consistently observed that PIM-2-deficient T cells had significantly increased ability to induce graft-versus-host disease (GVHD) after allogeneic bone marrow transplantation (BMT). More importantly, we found that CD8 T cells mount substantially strong anti- tumor responses when PIM-2 was deficient or blocked. Our preliminary studies have been extended from genetic to pharmacologic approaches and from mouse to human T cells. Thus, our preliminary studies provide compelling evidence that PIM-2 serves as a powerful negative regulator of T-cell immunity against cancer. Our Central Hypothesis is that targeting PIM-2 substantially promotes cancer immunotherapy while potentially inhibiting tumor progression directly. This hypothesis will be tested in the following two Specific Aims: 1) To delineate mechanistic action by which PIM-2 negatively regulates T-cell response; 2) To validate PIM-2 as an immunotherapy target against cancer. Based on our compelling preliminary data demonstrating for the first time that PIM-2 negatively regulates T-cell immunity, we expect to firmly validate this observation and to define the cellular and molecular mechanisms by which this regulation occurs. We also expect to demonstrate that blockade or inhibition of PIM-2 will enhance anti-tumor immunity against different types of cancer mediated by both mouse and human T cells.