Inhibition of the membrane attack complex of complement for induction of accommodation in the hamster-to-rat heart transplant model.

BACKGROUND: To induce accommodation in the hamster-to-rat cardiac transplantation model, in addition to cyclosporin A (CSA) to inhibit T-cell-mediated graft rejection, cobra venom factor (CVF) is often used to prevent complement-mediated graft rejection. Although it is generally assumed that CVF makes accommodation possible because it inactivates the complement membrane attack complex (MAC), it is not known which complement components must be inactivated and whether complement activation products generated by CVF are also involved in the induction of accommodation. Therefore, to investigate mechanisms by which CVF contributes to accommodation, we studied induction of accommodation of hamster hearts grafted into rats with complement deficiencies of C6; these rats cannot assemble the MAC but, in contrast to CVF, retain in their native state all complement proteins that precede the MAC. METHODS: Golden Syrian hamster hearts were transplanted heterotopically into the abdomen of normocomplementemic and C6-deficient (C6D) PVG rats. Graft rejection was determined by cessation of palpable cardiac contractions. CSA, 10 mg/kg, was administered daily to all rats. Graft survival was compared in rats given CVF (60 U/kg 1-day pre-transplant and 20 U/kg/day for the next 9 days), C6D rats given no CVF, normocomplementemic rats given anti-C6 IgG or non-immune IgG but no CVF, and C6D rats reconstituted with normocomplementemic rat serum. Total complement and C6 serum levels were measured using hemolytic assays in rat peripheral blood. RESULTS: We found that hamster hearts transplanted into C6D rats receiving CSA but no CVF survived long-term, with histology typical of an accommodated heart. The accommodated hamster heart did not reconstitute C6 levels of the C6D recipient rats. Moreover, in normocomplementemic rats given anti-C6 antibodies (abs) to induce partial C6 deficiency, accommodation also developed without administration of CVF. Accommodation of the hamster heart failed to develop in C6D rats whose complement was reconstituted by administration of normocomplementemic rat serum given before and following transplantation. CONCLUSIONS: These studies demonstrate that, in this model, inhibition of MAC-mediated graft rejection is sufficient to allow the development of accommodation. Inactivation of C3 or other complement proteins of the alternate pathway, or the presence of complement-derived biologically active fragments, is not needed for development of accommodation.

A soluble chimeric inhibitor of C3 and C5 convertases, complement activation blocker-2, prolongs graft survival in pig-to-rhesus monkey heart transplantation.

Complement plays a critical role in many pathologic processes and in xenograft rejection. Therefore, effective complement inhibitors are of great interest. In pig-to-primate organ transplantation, hyperacute rejection results from antibody deposition and complement activation. Complement activation blocker-2 (CAB-2), a recombinant soluble chimeric protein derived from human decay accelerating factor (DAF) and membrane cofactor protein, inhibits C3 and C5 convertases of both classical and alternative pathways. CAB-2 reduces complement-mediated tissue injury of a pig heart perfused ex vivo with human blood. Therefore, we studied the efficacy of CAB-2 when a pig heart is transplanted heterotopically into rhesus monkeys receiving no immunosuppression. Graft survival in three control monkeys was 1.26 +/- 0.2 h; it was markedly prolonged in eight monkeys that received CAB-2. Of the six monkeys that received a single dose of CAB-2 (15 mg/kg i.v.), four had graft survivals of 21, 95, 96, and 108 h, and two died at 7 to 11 h post-transplant with a beating graft, as a result of technical complications. The two monkeys given multiple doses of CAB-2 had graft survivals of 95 and 96 h. CAB-2 markedly inhibited complement activation, as shown by a strong reduction in generation of C3a and SC5b-9. At graft rejection, tissue deposition of iC3b, C4 and C9 was similar or slightly reduced from controls, and deposition of IgG, IgM, C1q and fibrin did not change. Thus, complement inhibition with CAB-2 abrogates hyperacute rejection of pig hearts transplanted into rhesus monkeys, but does not prevent delayed/acute vascular rejection. These studies demonstrate that the beneficial effects of complement inhibition on survival of a pig heart xenograft in rhesus monkeys are similar to those in other primate species and that CAB-2 may be useful in xenotransplantation and other complement-mediated conditions.