B6, B6 PFPKO, and B6 gld CD4 T cells were utilized to reconstitute B6 rag^−/− recipients of C3H or Fas-deficient C3Hlpr cardiac allografts. Removal of Fas alone (◆, p=NS vs. control Wt C3H + B6 CD4 T cells) from the donor hearts or removal of perforin alone from the CD4 T cells (■, p=NS vs. control Wt C3H + B6 CD4 T cells) did not abrogate rejection. Interestingly, the removal of FasL from effector CD4 T cells did delay rejection significantly (●, p < 0.02 vs. Wt C3H + B6 CD4 T cells, p < 0.01 vs. Wt C3H + B6 PFPKO CD4 T cells, and p < 0.01 vs. C3Hlpr + B6 CD4 T cells). However, most allografts were still rejected (4 of 5). Significantly, the simultaneous removal of both donor Fas and CD4 T cell perforin completely abrogated rejection (○, p < 0.002 vs. control Wt C3H + B6 CD4T cells, Wt C3H + B6 PFPKO CD4 T cells, and C3Hlpr + B6 CD4 T cells). This abrogration was significantly more robust than the individual removal of CD4 T cell FasL (○, p < 0.003 vs. Wt C3H + B6 gld CD4 T cells).

A. (Panel 1): Wild type C3H allograft un-reconstituted at >60 days demonstrates no significant cellular infiltration and intact cardiomyocytes. (Panel 2): Wild type C3H allograft reconstituted with B6 CD4 T cells rejected at 10 days post reconstitution, demonstrates significant cellular lymphocytic infiltration and cardiomyocyte damage/necrosis. (Panel 3): Fas-deficient C3H lpr allograft reconstituted with B6 CD4 T cells rejected at 9 days post reconstitution, demonstrates significant cellular lymphocytic infiltration and cardiomyocyte damage/necrosis. (Panel 4): Wild type C3H allograft reconstituted with B6 PFPKO CD4 T cells rejected at 9 days post reconstitution, demonstrates significant cellular lymphocytic infiltration and cardiomyocyte damage/necrosis.
B. (Panel 1): Fas-deficient C3H lpr allograft reconstituted with B6 PFPKO CD4 T cells at >60 days post reconstitution, demonstrates moderate cellular lymphocytic infiltration and no significant cardiomyocyte damage. (Panel 2): Immunoperoxidase staining for CD4 shows CD4+ infiltrating cells in a Fas-deficient C3H lpr allograft reconstituted with B6 PFPKO CD4 T cells surviving >60 days. (Panel 3): Fas-deficient C3H lpr allograft reconstituted with B6 PFPKO CD4 T cells at >60 days post reconstitution demonstrates a vasculopathic lesion. (Panel 4): Immunoperoxidase staining for CD4 of the same vasculopathic lesion demonstrates CD4+ cells surrounding the lesion without infiltration of the lesion itself.
C. (Panel 1): Wt C3H allograft reconstituted with B6 gld CD4 T cells rejected at 42 days post reconstitution, demonstrates significant severe cellular lymphocytic infiltration and cardiomyocyte damage/necrosis. (Panel 2): Wt C3H allograft reconstituted with B6 gld CD4 T cells at >60 days post reconstitution, demonstrates moderate to severe cellular lymphocytic infiltration and cardiomyocyte damage/necrosis. (Panel 3): Immunoperoxidase staining for CD4 shows CD4+ infiltrating cells in a Wt C3H allograft reconstituted with B6 gld CD4 T cells surviving >60 days.

Cytotoxic T-lymphocyte Assays (CTL) demonstrate that activated B6 CD4 T cells, B6 PFPKO CD4 T cells, and B6 CD8 T cells are capable of directly killing MHC Class I and II bearing BALB/c-derived A20 target cells. However, activated Fas Ligand-deficient gld CD4 T cells demonstrate very little lysis of A20 target cells. Data are representative of three experiments testing CD4 and CD8 T cell direct cytoxicity against BALB/c-derived A20 B-cell lymphoma cells.

Mixed lymphocyte assays demonstrate that Fas-deficient C3H LPR stimulator cells elicit vigorous proliferative responses from both Wt B6 and Perforin-deficient B6 PFPKO CD4 T cells. Data are representative of three experiments testing CD4 T cell-dependent reactivity to donor splenocytes. Error bars represent the standard deviation from quadruplicate wells in the MLR assay.