Tolerance to composite tissue allografts across a major histocompatibility barrier in miniature swine

BACKGROUND: Tolerance to composite tissue allografts might allow the widespread clinical use of reconstructive allotransplantation if protocols to achieve this could be rendered sufficiently nontoxic. The authors investigated whether tolerance could be generated in miniature swine to composite tissue allografts across a major histocompatibility (MHC) barrier. A clinically relevant tolerance protocol involving hematopoietic cell transplantation without the need for irradiation or myelosuppressive drugs was tested. METHODS: Seven recipient animals were transiently T-cell depleted and a short course of cyclosporine was initiated. Twenty-four hours later, a donor hematopoietic cell transplant consisting of cytokine-mobilized peripheral blood mononuclear cells or bone marrow cells and a heterotopic limb transplant were performed. In vitro anti-donor responsiveness was assessed by mixed-lymphocyte reaction and cell-mediated lympholysis assays. Acceptance of the limb allografts was determined by gross and histologic appearance. Chimerism in the peripheral blood and lymphohematopoietic organs was assessed by flow cytometry. RESULTS: All seven experimental animals accepted the musculoskeletal elements but rejected the skin of the allografts. All but one of the animals displayed donor-specific unresponsiveness in vitro. The animals that received cytokine mobilized-peripheral blood mononuclear cells showed chimerism but had clinical evidence of graft-versus-host disease (GVHD). None of the animals that received bone marrow cells showed stable chimerism and none developed GVHD. CONCLUSIONS: This protocol can achieve tolerance to the musculoskeletal elements of composite tissue allografts across an MHC barrier in miniature swine. Stable chimerism does not appear to be necessary for tolerance and may not be desirable because of the risk of GVHD.     

Factors affecting patency of venous allografts in miniature swine

In immunologically defined National Institutes of Health miniswine, a segment of internal jugular vein was anastomosed to the carotid artery as an interposition graft. Patency of swine major histocompatibility complex matched, one haplotype mismatched, and complete mismatched veins was 9.8, 6.3, and 3.0 weeks respectively (p = 0.009). More than 90% of mismatched and 20% of matched allografts developed a positive crossmatch before occlusion (p = 0.006). The mixed lymphocyte response did not predict graft occlusion. Treatment of 10 swine with cyclosporine (10 mg/kg/day) did not significantly improve patency for one haplotype mismatched grafts. In haplotype mismatched veins, cryopreserved grafts occluded more rapidly than noncryopreserved grafts: mean 2.4 versus 6.3 weeks, respectively (p = 0.002). In all cryopreserved vein grafts, alloantibody appeared at or after graft occlusion rather than before occlusion as seen with fresh allografts (p = 0.046). The mean patency of cryopreserved versus fresh autografts was 3.3 and greater than 32 weeks, respectively (p = 0.004). In summary, these results indicate that (1) allograft patency is related to the degree of swine major histocompatibility complex match and development of cytotoxic alloantibodies; (2) moderate-dose cyclosporine does not prolong allograft patency nor suppress development of antibody; (3) cryopreservation may accelerate graft occlusion through nonimmunologic mechanisms.     

Acceptance reaction: intragraft events associated with tolerance to renal allografts in miniature swine

Inbred miniature swine that are treated for 12 d with a high dose of cyclosporin A develop tolerance to MHC class II matched, class I-mismatched renal allografts. The aim of this study was to clarify the intrarenal allograft events associated with the development of tolerance in this protocol. Morphologic and immunologic studies were performed in serial biopsies from accepting grafts after 12 d of cyclosporin A treatment (n = 4) and were compared with those from untreated control rejecting grafts (n = 4). In accepting grafts with stable function, a transient interstitial infiltrate developed. The cellular infiltrate had many similarities to that in rejecting grafts; both had T cells and macrophages, similar proportions of T-cell subsets, and a similar frequency of in situ nick end labeling (TUNEL)+ apoptotic infiltrating cells. However, the cellular infiltrate in the acceptance reaction was distinguished by less T-cell activation (interleukin-2 receptor+), less proliferation (proliferating cell nuclear antigen+) of infiltrating cells, and less graft cell apoptosis in arteries, tubules, glomeruli, and peritubular capillaries. Thereafter, the infiltrate in the accepting grafts progressively resolved with decreased cell proliferation, activation, and apoptotic graft parenchymal cell injury, but the high frequency of apoptosis persisted in graft-infiltrating cells. In parallel to the intragraft events, donor-specific unresponsiveness developed as assessed by cell-mediated cytotoxicity by blood mononuclear cells in vitro. In conclusion, the acceptance reaction in transplanted grafts is characterized by progressive resolution of T-cell proliferation and activation and of cell-mediated graft injury, as well as prolonged T-cell apoptosis. These intragraft events suggest that both T-cell anergy and T-cell deletion occur in the graft during the development of tolerance. Some of the described immunopathologic findings (activation, proliferation, apoptosis) may be useful in distinguishing acceptance from rejection, as well as in predicting later graft acceptance in tolerance induction protocols.     

Induction of specific tolerance to class I-disparate renal allografts in miniature swine with cyclosporine.

Previous studies in miniature swine have suggested that the mechanism underlying the spontaneous development of tolerance in one third of one-haplotype class I disparate renal allografts (i.e., ag----ad) involves a relative T cell help deficit at the time of first exposure to antigen. If this hypothesis were correct, then one might expect the administration of an immunosuppressive agent capable of inhibiting lymphokine production during this period to lead to the induction of tolerance to class I MHC antigens in two-haplotype class I mismatched renal allografts (i.e., gg----dd), which are otherwise uniformly and acutely rejected. This hypothesis was tested in eight two-haplotype class I disparate, class II matched donor-recipient pairs, in which recipients were treated with cyclosporine 10 mg/kg, i.v. q.d. for 12 days. This protocol led to the induction of long-term (greater than 100 days) specific tolerance in 100% of recipients, as compared with control animals that rejected grafts in 13.7 +/- 0.9 days (P less than 0.0001). The specificity of tolerance was assessed both in vivo with subsequent skin grafts and in vitro by mixed lymphocyte response (MLR) and cell-mediated lymphocytotoxicity (CML). Survival of donor-specific skin grafts was prolonged compared with skin grafts bearing third-party class I antigens (19.5 +/- 2.0 versus 11.5 +/- 2.0 days, n = 4, P less than 0.05). Tolerant recipients had markedly diminished or absent anti-donor MLR and CML responses, but maintained normal reactivity to third party. Four of eight CsA-treated recipients showed detectable levels of anti-donor IgM, while none demonstrated the presence of anti-donor IgG, which was found in all rejecting controls.     

Successful induction of long-term specific tolerance to fully allogeneic renal allografts in miniature swine.

Major histocompatibility complex class II matching is of overwhelming importance for achieving tolerance to kidney transplants (KTX) in miniature swine. When class II antigens are matched, long-term specific tolerance across complete MHC class I antigen barriers can uniformly be induced by a 12-day perioperative course of cyclosporine. This same regimen is ineffective in fully MHC-mismatched combinations. We hypothesized that initial induction of tolerance to kidney donor class II antigens by bone marrow transplantation might allow tolerance to be induced to a subsequent fully allogeneic KTX in combination with CsA therapy. We report here the results of such fully allogeneic KTX performed in 4 recipients of prior single-haplotype class II-mismatched BMT. All animals received KTX from donors class II matched to the BMT donor and received a 12-day course of intravenous CsA (10 mg/kg/day). All four animals have maintained normal serum creatinine values (less than 2.0 mg/dl) for greater than 200 days posttransplant. Specific hyporesponsiveness to both BMT and KTX donor-type MHC antigens was found in mixed lymphocyte culture and cell-mediated lympholysis assays. Compared with third-party grafts, significantly prolonged survival of BMT donor-specific (P = 0.031) and KTX donor-specific (P = 0.031) skin grafts was observed. These results demonstrate that induction of tolerance to class II antigens by BMT allows a short course of CsA to induce specific tolerance to fully allogeneic renal allografts.     

Persistent chimerism despite antidonor MHC in vitro responses in miniature swine following allogeneic hematopoietic cell transplantation

BACKGROUND: T-cell chimerism predominates in miniature swine receiving hematopoietic-cell transplantation without myelosuppressive conditioning. Several chimeric recipients have become hyporesponsive to donor-major histocompatibility complex (MHC) in vitro and accepted donor-matched renal transplants without immunosuppression. However, some retained antidonor in vitro responses and subsequently rejected donor renal allografts despite the persistence of peripheral blood chimerism. In this study, we characterize the donor cells in both "tolerant" and "nontolerant" chimeric miniature swine. METHODS: Peripheral blood chimerism was determined by flow cytometry. In vitro antidonor responsiveness was determined by mixed lymphocyte reaction (MLR) and cell-mediated lymphocytotoxicity (CML). Donor cells were separated from chimeras by immunomagnetic bead separation and used as stimulators or targets in CML assays. Phenotypic analysis of donor cells in chimeras was performed using flow cytometry. RESULTS: Peripheral blood chimerism stabilized beyond 100 days and was made up almost entirely of T cells. PBMC from nontolerant chimeras could be stimulated in vitro to kill donor cells isolated from the mixed chimera itself. In contrast, PBMC from tolerant chimeras hyporesponsive to donor-type cells could not be stimulated in vitro to kill their own sorted donor cells. CONCLUSIONS: The in vivo persistence of donor T cells in mixed chimeric animals with in vitro antidonor responsiveness is not caused by an inability of these cells to be killed but rather by the poor stimulating capacity of these donor T cells. The nature of donor T cells that persist in the face of in vitro antidonor responses, has important implications for the induction of transplant tolerance by way of the generation of mixed chimerism.     

Transplantation in miniature swine. VI. Factors influencing survival of renal allografts.

Renal allografts were performed between and among animals from three herds of miniature swine that were selectively inbred to homozygosity at the major histocompatibility complex, MSLA. The results suggest several genetic factors which influence the survival of renal allografts in these animals. As expected, the major histocompatibility complex (MHC) was of dominant importance, and all MSLA-mismatched grafts were rejected promptly (12 +/- 3.7 days). Some MSLA-matched grafts were also rejected (30 +/- 15.0 days), indicating that non-MSLA loci also determine antigens which can lead to kidney rejection. Other MSLA-matched grafts were accepted indefinitely. At least one immune response gene that determined ability to reject kidneys across non-MSLA differences seemed to be segregating in our swine population. Animals that had accepted MSLA-matched renal grafts for extended periods demonstrated markedly prolonged survival of subsequent donor skin grafts compared to skin graft survival across the same non-MSLA difference in normal animals. This finding suggests that failure to reject kidneys across non-MSLA differences indicates systemic tolerance, and that there may be a relationship between the induction of such tolerance and the proposed immune response gene controlling rejection.     

Mixed allogeneic chimerism and tolerance to composite tissue allografts

The development of effective immunosuppressive drugs has made solid organ allotransplantation the preferred approach for treatment of end-organ failure. The benefits of these immunosuppressants outweigh their risks in preventing rejection of lifesaving solid-organ allografts. On the contrary, composite tissue allotransplants are non-lifesaving and whether the risks of immunosuppressants justify their benefits is a subject of debate. Hence, composite tissue allografts (CTA) have not enjoyed widespread clinical application for reconstruction of large tissue defects. Therefore, a method of preventing rejection that would eliminate the need for toxic immunosuppressants is of particular importance in CTA. Bone marrow transplantation (BMT) to establish mixed chimerism induces tolerance to a variety of allografts in animal models. This article reviews mixed chimerism-based tolerance protocols. Their limitations and their relevance to CTA are discussed, highlighting some unique characteristics (high antigenicity and the presence of active bone marrow) that make CTAs different from solid organ allografts.     

Vascularized thymic lobe transplantation in miniature swine: I. Vascularized thymic lobe allografts support thymopoiesis

BACKGROUND: Vascularized thymokidney transplants have previously been shown to induce tolerance across major histocompatibility complex barriers. The ability to perform vascularized thymic lobe transplantation could permit such tolerance to be induced with any cotransplanted solid organ or tissue. For this reason, we have developed a technique for vascularized thymic lobe transplantation in miniature swine. METHODS: Thymic vessels (n=2) were anastomosed to the carotid artery and the external jugular vein of na?ve minor-mismatched recipients treated with a 12-day course of cyclosporine A (10 mg/kg/day). Graft survival and thymopoiesis were assessed by histology, immunohistochemistry, and fluorescence-activated cell sorting. Allele-specific antibodies 74-12-4 and pig allelic antigen (PAA) were used to distinguish donor and recipient cells. RESULTS: Allografts showed intact cortical and medullary structure posttransplantation, without evidence of rejection or ischemia. Recipient thymocytes repopulated the donor cortical thymus by POD30 and increased in the cortex and medulla by POD60. CONCLUSIONS: Our study demonstrates the technical feasibility of vascularized thymic lobe transplantation and the support of thymopoiesis by such transplants in a large animal model. This technique may offer a novel strategy to induce transplant tolerance across allogeneic and xenogeneic barriers, and to support long-term thymopoiesis in immunodeficient hosts.     

Strategies to develop chimerism in vascularized skin allografts across MHC barrier

In this study, we investigated the effects of 7-day-protocols of alphabeta-T-cell receptor monoclonal antibody (alphabeta-TCRmAb), cyclosporine A (CsA), and tacrolimus (FK-506) immunosuppressive monotherapies, and their combinations on the survival of vascularized skin allografts (VSA). Forty-two transplantations of VSA across a strong MHC barrier were performed between ACI (RT1a) donors and Lewis (RT1(l)) recipients in seven groups. Isograft and allograft rejection controls received no treatment. Treatment groups received a 7-day protocol of alphabeta-TCRmAb, CsA, or FK-506 monotherapy, or a combination of alphabeta-TCRmAb/CsA and alphabeta-TCRmAb/FK-506. VSA transplants were evaluated on a daily basis. Donor-specific chimerism was determined by flow cytometry (FC). The combined protocols of alphabeta-TCRmAb/FK-506 and alphabeta-TCRmAb/CsA significantly prolonged VSA survivals compared to monotherapy groups ( P < 0.005). FC analysis revealed 15.82% of donor-specific chimerism on day 7 under the alphabeta-TCRmAb/CsA protocol and a gradual chimerism decline on day 63 posttransplant. The significant extension of VSA survival achieved under 7-day protocols of combined therapies was directly associated with the presence of donor-specific chimerism.