Abstract: Methods to treat cancer in a subject comprising administering to the subject a therapeutically effective amount of T-cells of the subject having increased IRF4 polypeptide expression compared to a control are disclosed. Also disclosed are methods of increasing tumor reactivity of a T-cell by increasing IRF4 polypeptide expression, and methods to predict the likelihood that a subject having cancer will respond therapeutically to administered T-cells having increased IRF4 polypeptide expression. Also disclosed are compositions comprising a T-cell and a viral vector encoding an IRF4 polypeptide. The compositions are methods are useful for treating numerous cancers in which higher level expression of IRF4 in T-cells would be beneficial. In some embodiments, activated tumor-specific T-cells having increased IRF4 expression have greater infiltration in tumors and enhanced local immunological responses.

Abstract: Methods to treat cancer in a subject comprising administering to the subject a therapeutically effective amount of T-cells of the subject having increased IRF4 polypeptide expression compared to a control are disclosed. Also disclosed are methods of increasing tumor reactivity of a T-cell by increasing IRF4 polypeptide expression, and methods to predict the likelihood that a subject having cancer will respond therapeutically to administered T-cells having increased IRF4 polypeptide expression. Also disclosed are compositions comprising a T-cell and a viral vector encoding an IRF4 polypeptide. The compositions are methods are useful for treating numerous cancers in which higher level expression of IRF4 in T-cells would be beneficial. In some embodiments, activated tumor specific T-cells having increased IRF4 expression have greater infiltration in tumors and enhanced local immunological responses.

Abstract: Disclosed are methods and compositions for inhibiting IRF4 in T-cells, thereby improving transplant outcomes or treating an autoimmune disease such as a myelination disorder. Thus, disclosed are methods to improve a transplant outcome in a recipient of a transplant comprising inhibiting IRF4 in T-cells of the recipient, thereby improving the transplant outcome. In some embodiments, IRF4 can be inhibited by administering an IRF4 inhibitor (e.g., trametinib or anti-IRF4 siRNA), and/or by adoptive transfer of T-cells having IRF4 inhibition. In some embodiments, the T-cells are CD4+ Tcells, and the infiltration thereof into a transplant can be reduced. Also disclosed are methods of treating a subject with a myelination disorder (e.g., multiple sclerosis or encephalomyelitis) comprising inhibiting IRF4.

Abstract: Methods to treat cancer in a subject comprising administering to the subject a therapeutically effective amount of T-cells of the subject having increased IRF4 polypeptide expression compared to a control are disclosed. Also disclosed are methods of increasing tumor reactivity of a T-cell by increasing IRF4 polypeptide expression, and methods to predict the likelihood that a subject having cancer will respond therapeutically to administered T-cells having increased IRF4 polypeptide expression. Also disclosed are compositions comprising a T-cell and a viral vector encoding an IRF4 polypeptide. The compositions are methods are useful for treating numerous cancers in which higher level expression of IRF4 in T-cells would be beneficial. In some embodiments, activated tumor specific T-cells having increased IRF4 expression have greater infiltration in tumors and enhanced local immunological responses.

Abstract: Disclosed herein are methods for scoring a patient on a liver transplant list, methods of performing a liver transplant, methods of determining expected post-transplant mortality in a subject, and methods of determining expected sepsis. The disclosed methods can be used to avoid futile transplantation, avoid wasting organs, and promote efficient management of organ placement. These methods involve assaying a sample from the subject for T cell receptor (TCR) repertoire.

Abstract: The present invention is based, in part, on expression studies of IL-2 and IL-15 receptor subunits by cycling T cells in vivo. In one embodiment, the invention generally features novel combinations of IL-2 and IL-15 antagonists and methods of suppressing the immune response by administering these antagonists. In each case, suppression is achieved by administration of a first agent that targets an IL-15 molecule or an IL-15 receptor (IL-15R) and a second agent that targets an IL-2 molecule or an IL-2 receptor (IL-2R). More generally, the invention features novel combinations of agents that, when administered to a patient (or to a transplant ex vivo), reduce the number of antigen-reactive T cells. For example, the invention features compositions (e.g., pharamaceutically acceptable compositions) that include two or more agents, each of which promote T cell death. Alternatively, the composition can contain at least one agent that promotes T cell death and at least one agent that inhibits T cell proliferation.

Abstract: The present invention is based, in part, on expression studies of IL-2 and IL-15 receptor subunits by cycling T cells in vivo. In one embodiment, the invention generally features novel combinations of IL-2 and IL-15 antagonists and methods of suppressing the immune response by administering these antagonists. In each case, suppression is achieved by administration of a first agent that targets an IL-15 molecule or an IL-15 receptor (IL-15R) and a second agent that targets an IL-2 molecule or an IL-2 receptor (IL-2R). More generally, the invention features novel combinations of agents that, when administered to a patient (or to a transplant ex vivo), reduce the number of antigen-reactive T cells. For example, the invention features compositions (e.g., pharamaceutically acceptable compositions) that include two or more agents, each of which promote T cell death. Alternatively, the composition can contain at least one agent that promotes T cell death and at least one agent that inhibits T cell proliferation.

Abstract: The present invention is based, in part, on expression studies of IL-2 and IL-15 receptor subunits by cycling T cells in vivo. In one embodiment, the invention generally features novel combinations of IL-2 and IL-15 antagonists and methods of suppressing the immune response by administering these antagonists. In each case, suppression is achieved by administration of a first agent that targets an IL-15 molecule or an IL-15 receptor (IL-15R) and a second agent that targets an IL-2 molecule or an IL-2 receptor (IL-2R). More generally, the invention features novel combinations of agents that, when administered to a patient (or to a transplant ex vivo), reduce the number of antigen-reactive T cells. For example, the invention features compositions (e.g., pharamaceutically acceptable compositions) that include two or more agents, each of which promote T cell death. Alternatively, the composition can contain at least one agent that promotes T cell death and at least one agent that inhibits T cell proliferation.