The influence of antigen-dependent and antigen-independent factors on the development of graft vasculopathy in a fully allogeneic cardiac allograft model in the rat.

Graft vasculopathy (GVP) is one of the major obstacles to long-term graft and patient survival after cardiac transplantation and a major reason for morbidity and mortality. Antigen-dependent and antigen-independent factors play causal roles in the development of GVP. The aim of this study was to evaluate antigen-dependent and -independent factors in the development of GVR in a clinically relevant fully allogeneic rat cardiac model under immunosuppression with cyclosporine (CyA). Lewis rats were challenged with Wistar-Furth cardiac allografts. Acute rejection occurred within 10 days after engraftment (n = 6). Daily SC administration of CyA (2.5 mg/kg body weight, n = 12) led to long-term graft survival (>100 days) but did not prevent GVP (Adams Score: 1.7 +/- 1.9, n = 4). Isografts did not develop GVP. In allografts, the dose modification of CyA to 5 mg or 1.25 mg/kg body weight as well as the prolongation of ischemia from 45 minutes to 4 hours did not increase the development of GVP. In isografts, the prolongation of ischemic time from 45 minutes to 4 hours significantly increased the development of GVP (Adams score, 0.3 +/- 0.8 [n = 7] vs 1.2 +/- 1.9 [n = 6]; P < .05). In this fully allogeneic cardiac allograft model with clinically relevant immunosuppressive therapy, GVP was induced independent of the applied CyA dose. In addition, the prolongation of ischemic time did not increase the development of GVP. Isografts only developed significant GVP with long ischemia times. Therefore, an initial injury, either prolonged ischemia time or an allogeneic immune response, predispressed to the development of GVP.

Sanglifehrin a blocks key dendritic cell functions in vivo and promotes long-term allograft survival together with low-dose CsA.

Sanglifehrin A (SFA) is a novel compound with unsurpassed cyclophilin-binding affinity, but relatively low direct antilymphocytic activity. Here, we report the capacity of SFA to selectively inhibit key dendritic cell (DC) functions in vivo and to suppress acute and chronic heart allograft rejection. We show that in vivo, SFA profoundly decreases DC receptor-mediated endocytosis and macropinocytosis and DC-T-cell allostimulatory activity. Furthermore, SFA abrogates >90% of IL-12p70 production in vivo while having no significant effect on IL-10 and TNF-alpha production. In a rat vascularized heart transplant model, SFA alone did not prevent graft rejection and rejection occurred within 23 days after low-dose CsA, whereas addition of SFA to low-dose CsA promoted long-term graft survival (median survival time >100 days; p = 0.0007). With respect to chronic rejection, SFA + CsA almost completely prevented graft arteriosclerosis compared to animals treated with CsA alone and controls. We propose that SFA represents a novel class of immunophilin-binding immunosuppressants with high activity against DCs and the development of graft vasculopathy in CsA-treated recipients.