Upon CD95L and anti-CD95 treatment we observed significantly more viable thymocytes from vavFLIPR mice compared with the number of WT thymocytes (Fig. 3A and B). In contrast, dexamethasone (Dex)-induced cell death, which proceeds via the glucocorticoid receptor in a death receptor-independent pathway, was not affected by the c-FLIPR transgene (Fig. 3A and B). To have a closer look into the time-course of apoptosis, thymocytes from WT and vavFLIPR animals were stimulated with CD95L for
up to 8 h. After 4 h of CD95L-stimulation, more early apoptotic (AnnexinV+ 7AAD−) WT cells than vavFLIPR cells were identified (Fig. 3C and D). After 8 h of stimulation, higher frequencies of both late apoptotic (AnnexinV+ 7AAD+) and early apoptotic WT cells were observed in comparison to vavFLIPR Roscovitine thymocytes (Fig. 3C and D). Taken together, WT thymocytes were rapidly
undergoing apoptosis, whereas vavFLIPR thymocytes were more resistant to CD95-induced apoptosis. Next, we examined the apoptosis sensitivity of peripheral T and B check details cells. Sorted CD4+ and CD8+ T cells as well as CD19+ B cells were stimulated with CD95L and Dex. Significantly, more viable (AnnexinV− 7AAD−) vavFLIPR CD4+ and CD8+ cells were identified upon CD95L stimulation compared to WT cells, while the Dex-treated controls were comparable between WT and vavFLIPR cells (Fig. 4A and B). Furthermore, sorted CD19+ B cells were activated with lipopolysaccharide (LPS) for 2 days to induce expression of the CD95 receptor before CD95L- and Dex-stimulation. Although activated B cells were fairly insensitive toward both
CD95L- and Dex-induced apoptosis, we detected significantly lower specific apoptosis of vavFLIPR B cells than of WT B cells (Fig. 4C). Again, the specific apoptosis of Dex-treated B cells was comparable between WT and vavFLIPR samples (Fig. 4D). Reactivation www.selleck.co.jp/products/AP24534.html of the T-cell receptor leads to subsequent apoptosis via the death receptor pathway and the CD95 receptor has been shown to be involved in activation-induced cell death (AICD) [20-23]. To assay AICD, peripheral lymph node cells from WT and vavFLIPR mice were isolated and T cells were activated for 2 days with plate-bound anti-CD3 and anti-CD28 in presence of IL-2. Activated T cells were further expanded for 3 days in medium containing IL-2. Subsequently, AICD was assessed by restimulating T cells with plate-bound anti-CD3 to induce cell death on day 5. Also in this assay, cells from vavFLIPR mice showed significantly less specific apoptosis compared to WT cells (Fig. 4E). Thus, the c-FLIPR transgene is functional and protects primary immune cells against CD95-induced apoptosis and AICD. Next, we analyzed lymphocyte populations in vavFLIPR mice, since inhibition of CD95-induced apoptosis is often associated with alterations in lymphocyte numbers. However, total cellularity in spleen, peripheral lymph nodes, and thymus, was overall comparable between WT and vavFLIPR mice (Table 1).