Mixed hematopoietic chimerism induces long-term tolerance to cardiac allografts in miniature swine.

BACKGROUND: Tolerance to cardiac allografts has not been achieved in large animals using methods that are readily applicable to human recipients. We investigated the effects of mixed hematopoietic chimerism on cardiac allograft survival and chronic rejection in miniature swine METHODS: Recipients were T-cell depleted using a porcine CD3 immunotoxin, and each received either of two nonmyeloablative preparative regimens previously demonstrated to permit the establishment of stable mixed hematopoietic chimerism across MHC-matched, minor antigen-mismatched histocompatibility barriers. Five to 12 months after the chimerism was induced, hearts from the original cell donors were heterotopically transplanted into the stable mixed chimeras. RESULTS: Cardiac allografts transplanted into untreated recipients across similar minor antigen barriers were rejected within 44 days (within 21, 28, 35, 39, 44 days among individual study subjects). In contrast, hearts transplanted into the mixed chimeras were all accepted long term ( > 153, > 225, > 286, > 362 days) without immunosuppressive drugs and developed minimal vasculopathy. CONCLUSIONS: Mixed hematopoietic chimerism, established in miniature swine using clinically relevant, non-myeloablative conditioning regimens, permits long-term cardiac allograft survival without chronic immunosuppressive therapy, significant vasculopathy, or graft-versus-host disease.

Mechanisms of tolerance induction and prevention of cardiac allograft vasculopathy in miniature swine: the effect of augmentation of donor antigen load.

OBJECTIVE: Cotransplantation of a donor kidney along with a heart allograft can induce tolerance to both organs and prevent cardiac allograft vasculopathy in miniature swine. To determine whether the tolerogenic effect of donor kidney cotransplantation was due to an effect specific to the kidney graft or to an increase in donor antigen load, we compared heart-kidney recipients with recipients receiving two class I disparate hearts or with recipients receiving donor peripheral mononuclear cells at the time of isolated heart transplantation. METHODS: Recipients of major histocompatibility complex class I disparate allografts received 12 days of cyclosporine (INN: cyclosporin; 10-13 mg/kg administered intravenously on days 0-11). Group 1 animals received a heart alone (n = 5). Group 2 animals received heart and kidney allografts (n = 4). Group 3 animals received two major histocompatibility complex-matched heart allografts (n = 4). Two double-heart recipients were thymectomized 21 days before transplantation. Group 4 animals received a heart allograft and an infusion of high-dose donor peripheral blood leukocytes (2.5 x 10(9) cells/kg, n = 2). RESULTS: Vasculopathy developed in group 1 recipients and the allografts were rejected within 55 days. Group 2 recipients accepted their heart and kidney allografts indefinitely without vasculopathy. Euthymic recipients from group 3 accepted their hearts long-term (>190 and >197 days), but vascular lesions developed. In thymectomized recipients from group 3, the hearts were rejected in 63 and 96 days with severe vasculopathy. Group 4 recipients demonstrated transient macrochimerism but their hearts were rejected within 47 and 63 days. CONCLUSIONS: The beneficial effects of donor kidney cotransplantation on cardiac allograft survival and prevention of cardiac allograft vasculopathy are likely to involve both an increase in donor antigen load and an effect specific to the kidney allograft.

Blockade of CD28-B7, but not CD40-CD154, prevents costimulation of allogeneic porcine and xenogeneic human anti-porcine T cell responses.

Despite increasing use of swine in transplantation research, the ability to block costimulation of allogeneic T cell responses has not been demonstrated in swine, and the effects of costimulatory blockade on xenogeneic human anti-porcine T cell responses are also not clear. We have compared the in vitro effects of anti-human CD154 mAb and human CTLA4IgG4 on allogeneic pig T cell responses and xenogeneic human anti-pig T cell responses. Both anti-CD154 mAb and CTLA4IgG4 cross-reacted on pig cells. While anti-CD154 mAb and CTLA4IgG4 both inhibited the primary allogeneic pig MLRs, CTLA4IgG4 (7.88 microg/ml) was considerably more inhibitory than anti-CD154 mAb (100 microg/ml) at optimal doses. Anti-CD154 mAb inhibited the production of IFN-gamma by 75%, but did not inhibit IL-10 production, while CTLA4IgG4 completely inhibited the production of both IFN-gamma and IL-10. In secondary allogeneic pig MLRs, CTLA4IgG4, but not anti-CD154 mAb, induced Ag-specific T cell anergy. CTLAIgG4 completely blocked the indirect pathway of allorecognition, while anti-CD154 mAb blocked the indirect response by approximately 50%. The generation of porcine CTLs was inhibited by CTLA4IgG4, but not by anti-CD154 mAb. Human anti-porcine xenogeneic MLRs were blocked by CTLA4IgG4, but only minimally by anti-CD154 mAb. Finally, CTLA4IgG4 prevented secondary xenogeneic human anti-porcine T cell responses. These data indicate that blockade of the B7-CD28 pathway was more effective than blockade of the CD40-CD154 pathway in inhibiting allogeneic pig T cell responses and xenogeneic human anti-pig T cell responses in vitro. These findings have implications for inhibiting cell-mediated immune responses in pig-to-human xenotransplantation.

Thymic transplantation across an MHC class I barrier in swine.

Thymic tissue transplantation has been performed previously in adult mice to induce donor-specific tolerance across allogeneic and xenogeneic barriers. We have now attempted to extend this technique to a large animal preclinical model and describe here our initial studies of allogeneic thymic transplantation in miniature swine. Two miniature swine were thymectomized before thymic tissue transplantation, and two remained euthymic. Donor thymic tissue was harvested from SLA class I-mismatched juvenile pigs and placed into recipient sternocephalicus muscle, kidney capsule, and omentum. A 12-day course of cyclosporin A was started on the day of transplantation. Allogeneic thymic engraftment could only be achieved in euthymic and not in thymectomized miniature swine using this treatment regimen. Both nonthymectomized animals showed good graft development, with evidence of thymopoiesis, as indicated by positive CD1 and host-type SLA class I immunoperoxidase staining of immature graft-infiltrating cells. Both animals also demonstrated donor-specific T cell hyporesponsiveness, as measured by MLR and cell-mediated lympholysis. The thymic grafts continued to develop despite the appearance of high levels of anti-donor specific cytotoxic IgG Abs. Thus, thymic tissue transplanted across an SLA class I barrier can engraft and support host thymopoiesis in euthymic miniature swine. The presence of the host thymus was required for engraftment. These data support the potential of thymic transplantation as part of a regimen to induce donor-specific tolerance to xenogeneic organ grafts.