IL-17-secreting CD8 T cells (Tc17) have been described in several settings, but little is known regarding their functional characteristics. While Tc1 cells produced IFN-γ and efficiently killed targets, Tc17 cells lacked lytic function in vitro. Interestingly, the small numbers of IFN-γ-positive or IL-17/IFN-γ-double-positive cells generated under Tc17 conditions also lacked lytic activity and expressed a similar pattern of cell surface proteins to IL-17-producing cells. As is the case for Th17 (CD4) cells, STAT3 is important for Tc17 polarization, both in vitro and in vivo. Adoptive transfer of highly purified, Ag-specific IL-17-secreting Tc17 cells into Ag-bearing hosts resulted in near complete conversion to an IFN-γ-secreting phenotype and substantial pulmonary pathology, demonstrating functional plasticity. Tc17 also accumulated to a greater extent than did Tc1 cells, suggesting that adoptive transfer of CD8 T cells cultured in Tc17 conditions may have therapeutic potential for diseases in which IFN-γ-producing cells are desired.
Calcium-modulating cyclophilin ligand (CAML) is an endoplasmic reticulum resident protein that is widely expressed. Although it has been demonstrated to participate in the tail-anchored protein insertion pathway, its physiological role in the mature immune system is unknown. In this work, we show that mature, peripheral T cells require CAML for survival specifically following TCR-induced activation. In this study, we examined mature T cells from spleen and lymph nodes of tamoxifen-inducible CAML knockout mice (tCAML−/−). Whereas CAML-deficient T cells were able to express the early activation markers CD25 and CD69, and produce IL-2 normally upon stimulation, deficient cells proliferated less and died. Cells did not require CAML for entry into the S phase of the cell cycle, thus implicating its survival function at a relatively late step in the T cell activation sequence. In addition, CAML was required for homeostatic proliferation and for Ag-dependent cell killing in vivo. These results demonstrate that CAML critically supports T cell survival and cell division downstream of T cell activation.
Effective T cell function protects us from pathogens as well as cancer. However when T cell activation is dysfunctional, it has detrimental effects. If T cell activation cannot be shut down, it may cause autoimmunity. Therefore, it is crucial for us to study how T cell activation is regulated. Calcium modulating cyclophilin ligand (CAML) is a ubiquitously expressed endoplasmic reticulum protein. Using a transgenic conditional knock-out mouse model to delete CAML, we previously demonstrated that CAML is required for early embryonic development and thymopoiesis. Additionally, cells lacking CAML do not respond to EGFR stimulation due to a receptor recycling defect. However, the role of CAML in mature, peripheral T cells is not well understood. Here we provide preliminary data showing that loss of CAML in peripheral T cells leads to defective T cell activation and proliferation upon TCR stimulation, and inducing cell death through Fas ligand engagement. We hypothesize that CAML regulates components that are required to sustain optimum TCR signaling and function. T cell responsiveness to TCR stimulation is critical for T cells to deliver effector functions during antigen recognition and activation. Therefore understanding the regulation of TCR signaling by CAML will provide insight into novel mechanisms of immune regulation. These studies may provide potential treatments of immunodeficiency, autoimmunity or other inflammation associated diseases.
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