Transplantation in miniature swine. VII. Evidence for cellular immune mechanisms in hyperacute rejection of renal alografts.

Renal allografts were performed in miniature swine that were identical at their major histocompatibility locus and were presensitized by skin grafts from their prospective renal donors. All of these renal grafts were rejected in a hyperacute or markedly accelerated manner compared to the survival of comparable grafts in nonsensitized animals. Studies directed at the mechanism of this rejection revealed no circulating recipient antidonor antibodies by several serological assays. In contrast, mixed lymphocyte cultures (MLCs) and cell-mediated lympholysis (CML) assays demonstrated marked recipient antidonor lymphocyte reactivity that appeared after skin grafts, diminished during the tenure of the renal graft in the host circulation, and reappeared after removal of the rejected kidney. These results suggest that cellular immune mechanisms may plan a role in the accelerated rejection of major histocompatibility complex (MHC)-identical renal allografts.     

Split tolerance to a composite tissue allograft in a swine model

BACKGROUND: The antigenicity of skin is a major obstacle to expanding human composite tissue transplantation. For example, multiple rejection episodes of the skin have been noted in clinical hand transplant patients. We have previously demonstrated tolerance to vascularized musculoskeletal allografts in major histocompatibility complex (MHC)-matched miniature swine treated with 12 days of cyclosporine. This regimen did not reproducibly lead to tolerance to subsequent frozen donor skin grafts. However, such skin grafts did not have a primary vascular supply. The aim of this study was to determine if tolerance to limb allografts with a vascularized skin component could be achieved with MHC matching and a 12-day course of immunosuppression. METHODS: Hind limb grafts harvested with a 100 cm(2) cutaneous paddle were transplanted heterotopically into six MHC-matched, minor antigen-mismatched miniature swine. All animals received a 12-day course of cyclosporine. One control animal was not immunosuppressed. Grafts were evaluated with biweekly biopsies and tissue viability determined by histologic analysis. To test for sensitization, frozen donor skin grafts were applied to all animals that survived to postoperative day 100. RESULTS: All treated animals (n=6) were tolerant to their musculoskeletal allografts at the time of necropsy (>100 days) regardless of the status of the epidermis. One animal demonstrated tolerance to the skin for more than 180 days. The other five animals demonstrated prolonged survival of the epidermal portion of the graft. The control animal rejected the graft epidermis at 10 days postoperatively. Frozen donor skin grafts demonstrated accelerated rejection (<10 days) in three of the animals and led to simultaneous rejection of both the epidermis of the allograft and the skin graft in the long-term tolerant animal. The rejection of the skin grafts did not break tolerance to the musculoskeletal portion in any of the animals. CONCLUSIONS: All animals exhibited indefinite survival of the musculoskeletal portion of their allografts but only prolonged survival of the epidermis. The loss of the graft skin appears to be the result of an isolated immune reaction to the skin, and, in particular, the epidermis. This observation is further substantiated by the accelerated rejection of secondarily placed frozen donor skin grafts.     

The failure of skin grafting to break tolerance to class I-disparate renal allografts in miniature swine despite inducing marked antidonor cellular immunity.

Long-term specific tolerance to one haplotype class I plus minor antigen disparate renal allografts develops without exogenous immunosuppression in approximately 35% of miniature swine (n = 128). Previous studies have suggested that this phenomenon is related to limited class I-specific helper T cell activity as evidenced by the failure of antibody class switching in vivo and the ability of exogenous interleukin 2 to elicit antidonor responses in vitro. To determine whether tolerance could be broken by inducing antidonor reactivity with donor antigen and a source of T cell help, multiple skin grafts bearing donor class I plus third-party class II antigens were placed on tolerant animals. Skin grafts were placed at least 3 months after the kidney transplant, at which time all recipients had normal renal function as measured by blood urea nitrogen and serum creatinine. First-set rejection of skin grafts by SLAad and SLAdd hosts occurred in 11.8 +/- 1.1 days (mean +/- SEM, n = 6) and in 9.3 +/- 0.9 days (n = 4), respectively. Coincident with skin rejection, most animals developed a transient rise in BUN to 62 +/- 11 mg/dl (n = 10) and a similar rise in Cr to 4.9 +/- 1.2 mg/dl (n = 10), with normal levels returning in all animals within two weeks. Subsequent skin grafts with the same disparity did not undergo second-set rejection and did not induce BUN or Cr elevations. Prior to skin grafting, animals showed no antidonor activity in mixed lymphocyte reaction or cell-mediated lymphocytotoxicity assays. After two skin grafts, all animals developed donor-specific CML and secondary MLR responses, and additional skin grafts amplified this cellular immunity. Development of marked antidonor immunity without a break in tolerance suggested that either graft adaptation or local suppression might be involved in maintaining tolerance to class I MHC antigens. In preliminary studies, an immunized SLAad animal and an immunized SLAdd animal were retransplanted with kidneys MHC matched to their first allografts. In both cases, the second graft was accepted permanently without immunosuppression, suggesting that graft adaptation is not necessary for the maintenance of tolerance to renal allografts in miniature swine.     

Induction of Cardiac Allograft Tolerance Across a Full MHC Barrier in Miniature Swine by Donor Kidney Cotransplantation

We have previously shown that tolerance of kidney allografts across a full major histocompatibility complex (MHC) barrier can be induced in miniature swine by a 12‐day course of high‐dose tacrolimus. However, that treatment did not prolong survival of heart allografts across the same barrier. We have now tested the effect of cotransplanting an allogeneic heart and kidney from the same MHC‐mismatched donor using the same treatment regimen. Heart allografts (n = 3) or heart plus kidney allografts (n = 5) were transplanted into MHC‐mismatched recipients treated with high‐dose tacrolimus for 12 days. As expected, all isolated heart allografts rejected by postoperative day 40. In contrast, heart and kidney allografts survived for >200 days with no evidence of rejection on serial cardiac biopsies. Heart/kidney recipients lost donor‐specific responsiveness in cell‐mediated lympholysis and mixed‐lymphocyte reaction assays, were free of alloantibody and exhibited prolonged survival of donor, but not third‐party skin grafts. Late (>100 days) removal of the kidney allografts did not cause acute rejection of the heart allografts (n = 2) and did not abrogate donor‐specific unresponsiveness in vitro. While kidney‐induced cardiac allograft tolerance (KICAT) has previously been demonstrated across a Class I disparity, these data demonstrate that this phenomenon can also be observed across the more clinically relevant full MHC mismatch. Elucidating the renal element(s) responsible for KICAT could provide mechanistic information relevant to the induction of tolerance in recipients of isolated heart allografts as well as other tolerance‐resistant organs.     

Induction of tolerance to heart transplants by simultaneous cotransplantation of donor kidneys may depend on a radiation-sensitive renal-cell population

BACKGROUND: To determine the mechanism by which cotransplantation of a donor kidney and heart allograft induces tolerance to both organs in miniature swine, we examined the renal elements responsible for tolerance induction. METHODS: Recipients received 12 days of cyclosporine, and transplants were performed across a major histocompatibility complex (MHC) class I mismatch. Group 1 animals received heart transplants (n=5); group 2 animals received heart and kidney allografts with no other manipulation (n=4); group 3 animals received heart transplants and donor-specific renal parenchymal cells (n=4); group 4 animals received heart and kidney allografts from lethally irradiated donors (n=7); group 5 animals received irradiated hearts and nonirradiated kidneys (n=2); group 6 animals received nonirradiated hearts and peripheral blood leukocytes from swine MHC matched to recipients and becoming tolerant to donor antigen (n=2); group 7 animals received nonirradiated hearts and donor-specific peripheral blood monocyte cells (PBMC) (n=2). RESULTS: Animals in group 1 developed vasculopathy and fulminant rejection by day 55. Animals in group 2 never developed vascular lesions. Parenchymal kidney cell infusion (group 3) did not prolong cardiac survival. Animals in group 4 developed arteriopathy by postoperative day (POD) 28. Group 5 recipients accepted allografts without vascular lesions. Adoptive transfer of leukocytes from tolerant swine (group 6) prolonged cardiac graft survival as much as 123 days, whereas donor PBMC infusion (group 7) did not affect cardiac survival or development of arteriopathy. CONCLUSIONS: Radiosensitive elements in kidney allograft may be responsible for tolerance induction and prevention of chronic vascular lesions in recipients of simultaneous heart and kidney allografts.     

Thymic transplantation in miniature swine: III. Induction of tolerance by transplantation of composite thymokidneys across fully major histocompatibility complex-mismatched barriers

BACKGROUND: This study determines whether composite thymokidney (TK) grafts, created by implantation of autologous thymic tissue beneath the donor's renal capsule before transplantation, could induce allogeneic transplantation tolerance across two-haplotype fully major histocompatibility complex (MHC)- mismatched barriers in juvenile MGH-miniature swine. METHODS: TK grafts were prepared by implanting autologous thymic tissue under the renal capsule of donor animals 2 to 3 months before transplantation. Four recipients were treated with a T-cell-depleting immunotoxin and received fully MHC-mismatched TK grafts plus a 12-day course of cyclosporine A (CsA). Control animals were treated with CsA alone or both CsA and immunotoxin, but with a normal kidney or a kidney implanted with autologous lymph node rather than thymus. Renal graft function was assessed by plasma creatinine levels and histologic analyses. Immunologic status was monitored by cell-mediated lympholysis assays. RESULTS: All four recipients of fully MHC-mismatched TK transplants treated with immunotoxin and a 12-day course of CsA accepted their composite renal allografts long-term. All control recipients receiving a TK and CsA alone, a normal kidney or a composite kidney containing lymph node tissue acutely rejected their grafts. CONCLUSIONS: To our knowledge, this is the first demonstration that functional vascularized thymic grafts can induce transplantation tolerance across fully MHC-mismatched barriers in a large animal model.     

Induction of transplantation tolerance with a short course of tacrolimus (FK506): I. Rapid and stable tolerance to two-haplotype fully mhc-mismatched kidney allografts in miniature swine

BACKGROUND: Inbred miniature swine provide a large animal model in which the effects of selective major histocompatibility complex (MHC) matching can be reproducibly studied. We have previously demonstrated that although a 12-day course of cyclosporine uniformly induces tolerance to class I-mismatched renal allografts, it does not induce tolerance across full MHC barriers. In this study, we assessed whether and at what dose tacrolimus might permit allografts to induce tolerance across different MHC barriers. METHODS: Recipients of MHC disparate renal allografts were treated with a 12-day course of tacrolimus by continuous intravenous infusion. Groups were divided as follows: (1) class I-mismatched kidneys with 0.3 mg/kg/day tacrolimus (n=3); (2) fully MHC-mismatched kidneys with 0.3 mg/kg/day tacrolimus (n=2); and (3) fully MHC-mismatched kidneys with 0.12-0.16 mg/kg/day tacrolimus (n=4). RESULTS: In groups 1 and 2, recipients with tacrolimus levels of 45-80 ng/ml accepted renal allografts long-term with stable renal function. Donor-specific hyporesponsiveness was demonstrated by cell-mediated lymphocytotoxicity and mixed lymphocyte response, and subsequent donor-matched grafts were also accepted, without further immunosuppression (n=4), confirming systemic tolerance. In group 3, recipients that achieved tacrolimus levels of 35 ng/ml (n=2) accepted their grafts without chronic changes, whereas recipients with levels of 20-26 ng/ml (n=2) developed chronic allograft glomerulopathy, suggesting 35 ng/ml as the threshold blood level for tolerance induction. In vitro assays demonstrated that peripheral blood lymphocytes from tolerant animals produced inhibitory cytokines, suggesting the involvement of regulatory mechanisms. CONCLUSIONS: To our knowledge, this study represents the first demonstration of the induction of transplant tolerance across a two-haplotype full MHC barrier with a short course of immunosuppression in a large animal model. These studies may also have clinical applicability, because the time course required to induce tolerance was sufficiently short that the high drug levels required might be expected to be tolerated clinically with only transient toxicity.     

Permanent acceptance of both cardiac and skin allografts using a mild conditioning regimen for the induction of stable mixed chimerism in mice

Patients who are receiving an organ transplant nowadays are sentenced to the life-long administration of immunosuppressive drugs, which have serious side effects. The reliable induction of donor-specific tolerance therefore remains a major goal in organ transplantation. Previously, we have developed a sublethal, non-myeloablative murine model in which permanent mixed, multilineage chimerism and donor-specific tolerance are established. Our model involves engraftment of fully allogeneic T cell depleted donor bone marrow cells in low dose irradiated and anti-CD3 treated major histocompatibility complex (MHC)-disparate recipient mice. To investigate whether vascularized organ grafts are accepted in our model, we performed heterotopic heart transplantations in our mixed chimeric mice. Chimeric mice permanently accepted hearts from the bone marrow donor (>130 days) and rapidly rejected third party-type allografts (median survival time 9 days). Untreated control recipient mice rejected both donor- and third party-type allografts. In addition, mice that accepted their cardiac grafts, donor-specific acceptance of skin grafts was observed. In conclusion, the establishment of stable mixed chimerism with this low-toxicity regimen resulted in permanent donor-specific acceptance of vascularized organ as well as skin grafts across a full MHC barrier.     

Down-regulation of the immune response to histocompatibility antigens and prevention of sensitization by skin allografts by orally administered alloantigen.

The effects of oral administration of major histocompatibility antigens on the alloimmune response have not been investigated. Lymphocytes from inbred LEW (RT1u) rats that were pre-fed allogeneic WF (RT1l) splenocytes exhibited significant antigen specific reduction of the mixed lymphocyte response in vitro and delayed-type hypersensitivity response in vivo, when compared with unfed controls. In an accelerated allograft rejection model, LEW rats were presensitized with BN (RT1n) skin allografts 7 days before challenging them with (LEW x BN)F1 or BN vascularized cardiac allografts. While sensitized control animals hyperacutely reject their cardiac allografts within 2 days, animals prefed with BN splenocytes maintained cardiac allograft survival to 7 days, a time similar to that observed in unsensitized control recipients. This phenomenon was antigen-specific, as third-party WF grafts were rejected within 2 days. Immunohistologic examination of cardiac allografts harvested on day 2 from the fed animals had markedly reduced deposition of IgG, IgM, C3, and fibrin. In addition, there were significantly fewer cellular infiltrates of total white blood cells, neutrophils, macrophages, T cells, IL-2 receptor-positive T cells, and mononuclear cells with positive staining for the activation cytokines IL-2 and IFN-g. On day 6 posttransplant, the grafts from fed animals showed immunohistologic changes typical of acute cellular rejection usually seen in unsensitized rejecting controls. Feeding allogeneic splenocytes prevents sensitization by skin grafts and transforms accelerated rejection of vascularized cardiac allografts to an acute form typical of unsensitized recipients. Oral administration of alloantigen provides a novel approach to down-regulate the specific systemic alloimmune response against histocompatibility antigens.     

Intrathymic immunomodulation in sensitized rat recipients of cardiac allografts: requirements for allorecognition pathways.

BACKGROUND: Intrathymic injection of alloantigen in the form of donor cells, soluble major histocompatibility complex (MHC) molecules, or MHC allopeptides induces donor-specific tolerance in a variety of acute allograft rejection models. We have previously shown that a single intrathymic injection of donor spleen cells into pre-sensitized rats abrogates accelerated (circa 24-hour) rejection and prolongs the survival of cardiac allografts to about 7 days. The present study was designed to investigate the mechanisms by which intrathymic administration of donor cells modifies the course of accelerated rejection. METHODS: Lewis RT1(1) (LEW) rats sensitized by transplantation with Wistar-Furth RT1(u) (WF) skin grafts received WF cardiac allografts 7 days later-a classic model of accelerated rejection. At the time of skin challenge, however, certain animals received intrathymic cell suspensions (either allogeneic or syngeneic) or donor-derived class I and/or class II MHC peptides. RESULTS: Control animals (sensitized by skin grafts but receiving no other treatment) rejected cardiac allografts within 24 hours. Intrathymic injection of WF splenocytes at the time of skin transplantation abrogated rejection at 24 hours and prolonged cardiac allograft survival to 6.6+/-0.6 days (p<0.001), whereas intrathymic administration of syngeneic (LEW) or allogeneic third party Brown Norway RT1(n) cells was ineffective in this regard. Intrathymic injection of gamma-irradiated donor cells marginally extended cardiac allograft survival to 3.0+/-0.9 days (p< 0.001), but the grafts were still rejected in an accelerated fashion. Intrathymic injection of donor-derived class I and/or class II MHC allopeptides at the same time period also failed to prolong cardiac allograft survival beyond 3 days. In the group receiving unmodified donor cells, elevated immunoglobulin M (IgM) and immunoglobulin G (IgG) allo-antibodies were found at the time of cardiac transplantation; this pattern was not observed with any other treatment. CONCLUSION: The superiority of non-modified donor spleen cells over gamma-irradiated donor cells or donor specific allopeptides in modifying the course of accelerated cardiac rejection suggests that direct allorecognition is the dominant pathway initiating rejection in sensitized transplant recipients. Marked alterations in the antidonor IgM and IgG responses are associated with successful abrogation of accelerated rejection by thymic immunomodulatory mechanisms.     

Long-term acceptance of renal allografts following prenatal inoculation with adult bone marrow

BACKGROUND: The aim was to investigate if intravascular in utero injection of adult bone marrow into swine fetuses could lead to macrochimerism and tolerance to the donor. METHODS: Outbred Yorkshire sows and boars screening negative for MHC allele SLA of MGH miniature swine were bred. A laparotomy was performed on the sows at 50 days gestation to expose the uterus. Bone marrow harvested from SLA miniature swine was T-cell depleted and injected intravascularly into seventeen fetuses. Flow cytometry was performed to detect donor cells (chimerism) in the peripheral blood after birth. Mixed lymphocyte reactions (MLR) and cell-mediated lympholysis (CML) assays were used to assess the response to donor MHC. Previously frozen skin grafts from the bone marrow donor were placed on the offspring from the first litter. Donor-matched renal transplant from SLA donors were performed on chimeric swine, with and without a short 12-day course of cyclosporine, and one nonchimeric littermate. RESULTS: Nine inoculated offspring demonstrated donor cell chimerism in the peripheral blood and lymphohematopoietic tissues. All animals with detectable chimerism within the first three weeks were consistently nonreactive to donor MHC in vitro. Animals challenged with donor skin grafts displayed prolonged graft survival without producing antidonor antibodies. All chimeric animals accepted donor-matched kidney allografts, even one without cyclosporine. The kidney in the nonchimeric littermate rejected by day 21. CONCLUSIONS: Transplantation of allogeneic adult bone marrow into immunocompetent fetal recipients resulted in chimerism. In utero inoculation led to operational tolerance to the donor's major histocompatibility antigens and long-term acceptance to organ allografts.     

An immunodominant minor histocompatibility alloantigen that initiates corneal allograft rejection

BACKGROUND: Murine orthotopic corneal allografts experience immune privilege and have good survival as compared with skin allografts. However, privilege is not complete, and some grafts are still rejected. Unexpectedly, corneas expressing minor histocompatibility (H) alloantigens are rejected at a higher rate than major histocompatibility complex (MHC) disparate grafts. We hypothesize that certain immunodominant minor H alloantigens are extremely immunogenic when expressed in corneal tissue, terminate ocular immune privilege, and initiate corneal allograft rejection. METHODS AND RESULTS: Corneal allograft survival and the role of CD4+ T cells and CD8+ T cells were examined in corneal transplants that expressed genetically defined minor H3 alloantigens. The H3 locus contains at least two minor H genes. H3a is presented by MHC class I and recognized exclusively by CD8+ T cells. H3b is presented by class II and recognized exclusively by CD4+ T cells. Congenic strains that differ from C57BL/10 at (1) H3a, (2) H3b, or (3) H3a+H3b were used for orthotopic corneal and skin transplants. Donor corneas expressing either H3a or H3a+H3b experienced immune privilege and survived longer than skin allografts. By contrast, donor corneas expressing H3b (recognized by CD4+ T cells) experienced vigorous rejection and were eliminated faster than skin allografts. CONCLUSION: There are minor H alloantigens that terminate ocular immune privilege and initiate corneal allograft rejection. These minor H alloantigens are more immunogenic when expressed in corneal tissue than when they are expressed in skin allografts.     

Spontaneous acceptance or rejection of orthotopic liver transplants in outbred and partially inbred miniature swine.

BACKGROUND: Results of clinical liver transplantation have shown that rejection and loss of human liver allografts occurs despite immunosuppression. Because genetic disparity and liver immunogenicity remain a matter of controversy, we reexamined the fate of outbred liver allografts without immunosuppression and used partially inbred miniature swine, in which the genetics of major histocompatibility complex (MHC) antigens have been characterized and can be controlled. METHODS: Orthotopic liver transplantation was performed between pairs of outbred domestic farm pigs and between pairs of inbred miniature swine with genetically defined major histocompatibility (SLA) loci. A passive splenic and vena caval to jugular vein shunt with systemic heparinization prevented hypotension during the anhepatic phase. Immunological responses were monitored by mixed lymphocyte culture (MLC), CML, skin graft rejection, liver biopsies, and serial serum chemistries. RESULTS: Median survival of technically successful liver allografts between pairs of outbred pigs (n=20) was 38 days and between partially inbred swine matched at the SLA locus (n=17) was 79 days. MLC responsiveness did not correlate with the development of rejection. Five of 20 (25%) outbred pigs and 6 of 17 (35%) MHC matched inbred miniature swine survived more than 100 days. In the long-term survivors, donor, but not third party, MHC matched skin graft survival times were prolonged. In contrast, all SLA-mismatched inbred recipients (n=26) died rapidly from massive liver rejection, with a median survival time of 9 days. In these rejecting animals, the marked MLC responsiveness to donor lymphocytes evident pretransplant diminished rapidly after transplantation, but an undiminished PHA responsiveness and a blunted third party MLC response persisted. CONCLUSION: The length of survival and the degree and incidence of rejection were similar in outbred pigs and in SLA-matched inbred miniature pigs, indicating that the outbred animals were, therefore, probably closely related and shared relevant genes. However, survival was significantly shortened and liver allograft rejection was accelerated in SLA-mismatched inbred swine. These results indicate that major histocompatibility differences play an important role in the rejection of liver allografts, as is true for other vascularized grafts in the unimmunosuppressed recipient. The development of liver allograft rejection across non-MHC differences is variable and, when present, appears to be a chronic process.     

Long-term acceptance of fully allogeneic cardiac grafts by cotransplantation of vascularized thymus in miniature swine

BACKGROUND: We have previously reported the ability of both thymokidney and vascularized thymic lobe (VTL) allografts to induce transplantation tolerance to renal allografts across a full major histocompatibility complex (MHC) mismatch in thymectomized miniature swine. However, whether vascularized thymus is capable of inducing tolerance to less tolerogeneic organs when it is transplanted simultaneously is not yet known. The present study investigates cardiac allograft survival and the mechanism of long-term acceptance in recipient swine following cotransplantation of VTL and cardiac grafts from fully MHC-mismatched donors. METHODS: Animals received a heart graft, a heart graft and a VTL, or a heart graft and a donor thymocyte infusion. Immunosuppressive regimens consisted of 12 or 28 days of tacrolimus. RESULTS: All animals that received a VTL maintained their grafts significantly longer than their counterparts that received only a heart graft, and those receiving 28 days of tacrolimus maintained their heart grafts long-term. Recipients of a donor thymocyte infusion demonstrated slightly prolonged cardiac graft survival but all rejected their grafts, highlighting the importance of thymic stroma. Cytotoxic T-lymphocyte responses against third-party antigens by cells from tolerant animals showed restriction by both self and donor MHC, whereas responses of controls were restricted to self MHC only. The presence of donor dendritic cells in the VTL grafts and results of co-culture assays suggest that both central and regulatory mechanisms were involved in achieving long-term acceptance. CONCLUSION: This is the first demonstration of the long-term acceptance of fully MHC-mismatched cardiac allografts in large animals.     

The immediately vascularized skin allograft.

A model for immediate vascularization of skin was devised to examine one of the possible explanations for the differential survival rates of transplants of freely grafted skin and organs, i.e., the increased vulnerability of skin to early ischemic necrosis prior to revascularization. Female Fischer (F) rat skin was transplanted beneath the kidney capsule of tolerant female Lewis (LEW) recipients. This skin healed in and initially appeared to be normal grossly and microscopically. In 27 rats, after 30 days, the composite grafts were excised, and immediately transplanted by means of vascular anastomosis into normal LEW recipients (syngeneic to the kidney portion of the graft and allogeneic to the skin). For 5 days after transplantation of the composite graft, the skin appeared to be normal with minimal or no inflammation in a panel of 11 recipients. From the 6th to 11th day, an active rejection reaction developed at the skin-kidney interface in a panel of six rats. In 10 rats, in which the composite grafts remained in their secondary hosts for 12 to 21 days, rejection of the skin was complete. The renal portion of all composite grafts appeared to be normal histologically. All recipients of composite grafts rejected subsequent orthotopic F skin grafts in an accelerated manner, with median survival times of 8.2 +/- 0.3 days compared to 11.5 +/- 0.7 days in untreated F leads to LEW controls, demonstrating that the skin on the composite graft was fully immunogenic. These results demonstrate that immediately vascularized skin allografts between rats compatible at the major Ag-B1 locus will still be rejected within 2 weeks compared to survivals of up to 48 weeks in renal allografts in the same histocompatibility combinations, suggesting that anatomical factors are not sufficient to account for the differences in survival times between skin and solid organs.     

Effects of Lung Cotransplantation on Cardiac Allograft Tolerance Across a Full Major Histocompatibility Complex Barrier in Miniature Swine

A 12‐day course of high‐dose tacrolimus induces tolerance of major histocompatibility complex–mismatched lung allografts in miniature swine but does not induce tolerance of heart allografts unless a kidney is cotransplanted. To determine whether lungs share with kidneys the ability to induce cardiac allograft tolerance, we investigated heart–lung cotransplantation using the same induction protocol. Hearts (n = 3), heart–kidneys (n = 3), lungs (n = 6), and hearts–lungs (n = 3) were transplanted into fully major histocompatibility complex–mismatched recipients treated with high‐dose tacrolimus for 12 days. Serial biopsy samples were used to evaluate rejection, and in vitro assays were used to detect donor responsiveness. All heart–kidney recipients and five of six lung recipients demonstrated long‐term graft survival for longer than 272 days, while all heart recipients rejected their allografts within 35 days. Tolerant recipients remained free of alloantibody and showed persistent donor‐specific unresponsiveness by cell‐mediated lympholysis/mixed‐lymphocyte reaction. In contrast, heart–lung recipients demonstrated rejection of both allografts (days 47, 55, and 202) and antidonor responsiveness in vitro. In contrast to kidneys, lung cotransplantation leads to rejection of both heart and lung allografts, indicating that lungs do not have the same tolerogenic capacity as kidneys. We conclude that cells or cell products present in kidney, but not heart or lung allografts, have a unique capacity to confer unresponsiveness on cotransplanted organs, most likely by amplifying host regulatory mechanisms.     

Experimental vascularized bone allografting

Presented here is a compendium of studies investigating the fate of vascularized bone allografts. The first set of experiments employ the posterior rib graft in two canine models. The rib-to-mandible model was used to evaluate the rejection phenomena of vascularized bone allografts in an outbred dog model. This ascertained the time course of rejection and histological characteristics of the grafts. Immunosuppression of the graft recipients was attempted with azathioprine and cyclosporine. The results demonstrated that azathioprine was not an effective immunosuppressant, whereas cyclosporine resulted in survival of cortical osteons. The use of the vascularized rib allograft, with and without azathioprine, to bridge the defect in the dog femur was met with failure. Further studies employed a genetically defined rat model to determine the effect of different histocompatibilities on the survival of vascularized knee allografts. Grafts were transplanted from Lewis rats to syngeneic Lewis rats as isografts and to Fischer-344 rats (F-344) and Brown-Norway rats (BN) as allografts. Grafts across a major histocompatibility barrier to BN were rejected by 7 days, whereas grafts across a weak histocompatibility barrier to F-344 were rejected more slowly. The use of cyclosporine in this model abrogated the rejection response when administered to both groups continuously. However, a short course of cyclosporine was effective in preventing rejection in the F-344 animals. Efforts to induce tolerance by blood transfusions, from the donor strain or from a third-party donor, were not effective in preventing rejection.     

Histocompatible miniature swine: an inbred large-animal model

Three herds of miniature swine, each homozygous for a different set of alleles at the major histocompatibility complex (MHC), and five intra-MHC recombinant strains, have been reported by the authors' laboratory. One herd (SLAdd) was selected for further inbreeding to achieve a histocompatible line. It has undergone seven additional generations of sequential brother-sister or father-daughter matings (termed G7). To determine the level of histocompatibility of these animals, the authors performed skin and heart transplantation without immunosuppression. In contrast to MHC-matched, minor antigen-mismatched animals that rejected skin in 11 days (median survival time [MST], n=6) and hearts in 35 days (MST, n=4), G7 animals accepted skin for greater than 340 days (>340, >448, and >677 days) and hearts for greater than 265 days (>265 and >269 days). Nevertheless, rejection of second grafts could be induced by sensitization, indicating that weak minor antigens remain, requiring further inbreeding to achieve full histocompatibility. We conclude that G7 animals are sufficiently inbred to accept first set skin and heart grafts indefinitely.     

Compromised kidney graft rejection response in Vervet monkeys after withdrawal of immunosuppressants tacrolimus and sirolimus

BACKGROUND: In nonprimates, organ allografts are often not rejected after withdrawal of immunosuppression. In this study, we examined whether such a phenomenon also occurs in primates. METHODS: Vervet monkeys were transplanted with renal allografts and treated for 60 days with tacrolimus, or tacrolimus plus sirolimus. The drugs were totally withdrawn on day 61. The survival of the monkeys was monitored, and their response to donor- or third party-derived alloantigens was examined in vivo and in vitro. RESULTS: The majority (80-100%) of the grafts survived for at least additional 30 days with no signs of acute rejection. The compromised rejection is donor-specific, because recipient monkeys failed to reject a donor-derived skin graft, but a third-party skin graft was rejected. In vitro mixed lymphocyte reaction and interleukin-2 production in the mixed lymphocyte reaction between the recipients and their donors or between the recipients and a third party had no discernable patterns, and thus did not reflect the in vivo status of the immune system. Although the recipients could not reject the graft acutely after drug withdrawal, the kidney grafts and the donor-derived skin grafts had pathological findings of chronic rejection. CONCLUSIONS: The rejection response of the monkeys to an established graft after withdrawal of immunosuppression is compromised. The compromised rejection is specific and is not due to a permanent alteration of the immune system by the initial drug treatment. The allografts are not inert but have low levels of interaction with the recipient immune system.     

Long-term tolerance to kidney allografts in a preclinical canine model

Durable immune tolerance supporting vascularized allotransplantation offers the possibility of extending graft survival and avoiding harmful complications of chronic immunosuppression. Immune tolerance to renal allografts was induced in a preclinical canine model through engraftment of donor hematopoietic cells using a combination of low-dose total body irradiation and a short course of immunosuppression. Subsequently, donor renal allografts were transplanted accompanied by bilateral native nephrectomies. With 5-year follow up, we found normal renal function in all recipients and no histological evidence of acute or chronic rejection. This tolerance does not extend universally to donor skin grafts, however, with two of four animals rejecting delayed donor skin grafts. Hematopoietic chimerism produces durable and robust immune tolerance to kidney allografts, although incomplete tolerance to donor skin grafting.