Role of the thymus in transplantation tolerance in miniature swine: V. Deficiency of the graft-to-thymus pathway of tolerance induction in recipients of cardiac transplants

BACKGROUND: We have previously shown that both thymic immigrants (graft to thymus pathway) and thymic emigrants (thymus to graft pathway) are involved in tolerance to renal allografts in miniature swine treated with a short course of calcineurin inhibitors. This study investigates the role of these pathways in cardiac transplant survival in recipients treated with a short course of tacrolimus. METHODS: Eleven animals received two-haplotype fully MHC-mismatched cardiac grafts with a 12-day course of tacrolimus. Recipients were thymectomized on day -21 (n=5) or day 0 (n=3), or were left euthymic (n=3). Two of the day -21 thymectomized animals received a day 0 host-MHC matched thymocyte infusion. RESULTS: Euthymic recipients of cardiac grafts treated with an immunosuppressive regimen identical to that previously shown to induce tolerance in euthymic recipients of renal allografts all rejected their grafts. Although no animal became tolerant, animals that were euthymic or thymectomized on day 0, as well as recipients of day 0 host-type thymocyte infusions following thymectomy on day -21, developed donor-specific hyporesponsiveness and maintained their cardiac grafts for markedly prolonged periods. In contrast, all animals thymectomized on day -21 that did not receive thymocyte infusions developed strong antidonor CTL responses and rejected their grafts by day 35. CONCLUSIONS: The graft-to-thymus pathway that plays an important role in tolerance induction to renal allografts appears to be relatively deficient in recipients of cardiac grafts. Strategies to increase donor antigen migration to the host thymus might therefore assist in tolerance induction to cardiac 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.     

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.     

Vascularized thymic lobe transplantation in a pig-to-baboon model: a novel strategy for xenogeneic tolerance induction and T-cell reconstitution

BACKGROUND: This laboratory has previously demonstrated the induction of allogeneic tolerance by vascularized thymic lobe (VTL) transplantation in miniature swine. We report here our initial attempt to induce tolerance by VTL transplantation in the clinically relevant, discordant, pig-to-baboon model of xenotransplantation. METHODS: Six baboons received xenografts of hDAF VTLs. Four of these baboons also received omental thymic tissue implants. All recipients were treated with an immunosuppressive conditioning regimen that included thymectomy, splenectomy, extracorporeal immunoadsorption of anti-alpha Gal antibodies, and T-cell depletion. Two control baboons received sham operations, of which one also received 5x10 hDAF porcine thymocytes/kg intravenously. RESULTS: Transplanted VTL grafts supported early thymopoiesis of recipient-type immature thymocytes, and facilitated engraftment of nonvascularized thymic omental implants. Recipients of the VTL grafts demonstrated donor-specific unresponsiveness in MLR assays, development of peripheral CD45RAhigh/CD4 double positive (DP) cells, and positive cytokeratin staining of thymic stroma in the grafts for 2 months following xenotransplantation. The control baboons did not show these markers of thymic reconstitution. The eventual return of Gal natural antibodies led to the destruction of graft epithelial cells and the rejection of all VTL grafts by 3 months posttransplantation. CONCLUSIONS: VTL transplantation from hDAF swine to baboons induced early thymopoiesis in the recipients and donor-specific cellular unresponsiveness in vitro. When coupled with additional strategies aimed at silencing humoral rejection, VTL transplantation may significantly prolong xenograft survival and result in long-term tolerance.     

Effect of mixed hematopoietic chimerism on cardiac allograft survival in cynomolgus monkeys

BACKGROUND: We have previously reported the successful induction of mixed chimerism and long-term acceptance of renal allografts in MHC-mismatched nonhuman primates after nonmyeloablative conditioning and donor bone marrow transplantation. In this study, we extended our regimen to cardiac allotransplantation and compared the immunological responses of heart and kidney allograft recipients. METHODS: Five cynomolgus monkeys were conditioned with low-dose total body irradiation (1.5 Gy on days -6 and -5), supplemental thymic irradiation (7 Gy on day -1), antithymocyte globulin (50 mg/kg on days -2, -1, and 0), splenectomy (day 0), donor bone marrow transplantation (day 0), and a 4-week posttransplant course of cyclosporine. Heart allografts from MHC-mismatched donors were transplanted heterotopically on day 0. RESULTS: Two monkeys failed to develop multilineage chimerism and rejected their allografts soon after cyclosporine was stopped (postoperative days [PODs] 43 and 56). Three monkeys developed multilineage chimerism, which persisted 20 to 43 days posttransplant by flow cytometric analysis and to POD 124 by polymerase chain reaction analysis. Allograft survival in these recipients was prolonged to 138, 428, and 509 days, and in vitro mixed leukocyte reaction and cell-mediated lympholysis (CML) assays demonstrated donor-specific hyporesponsiveness. However, in contrast to kidney allograft recipients, long-term heart allograft recipients eventually developed humoral and cellular immunity against the donor and rejected the grafts. At the time of rejection, 1.3% to 9.5% of donor coronary arteries exhibited intimal proliferation. CONCLUSIONS: The induction of transient mixed hematopoietic chimerism leads to long-term heart allograft survival in MHC disparate monkeys without chronic immunosuppression. However, unlike kidney allografts, full tolerance to cardiac allografts was not achieved. Organ-specific modifications of the preparative regimen may be necessary to prevent the chronic cellular and humoral immune responses elicited by cardiac allografts.     

Kidney‐Induced Cardiac Allograft Tolerance in Miniature Swine is Dependent on MHC‐Matching of Donor Cardiac and Renal Parenchyma

Kidney allografts possess the ability to enable a short course of immunosuppression to induce tolerance of themselves and of cardiac allografts across a full‐MHC barrier in miniature swine. However, the renal element(s) responsible for kidney‐induced cardiac allograft tolerance (KICAT) are unknown. Here we investigated whether MHC disparities between parenchyma versus hematopoietic‐derived “passenger” cells of the heart and kidney allografts affected KICAT. Heart and kidney allografts were co‐transplanted into MHC‐mismatched recipients treated with high‐dose tacrolimus for 12 days. Group 1 animals (n = 3) received kidney and heart allografts fully MHC‐mismatched to each other and to the recipient. Group 2 animals (n = 3) received kidney and heart allografts MHC‐matched to each other but MHC‐mismatched to the recipient. Group 3 animals (n = 3) received chimeric kidney allografts whose parenchyma was MHC‐mismatched to the donor heart. Group 4 animals (n = 3) received chimeric kidney allografts whose passenger leukocytes were MHC‐mismatched to the donor heart. Five of six heart allografts in Groups 1 and 3 rejected <40 days. In contrast, heart allografts in Groups 2 and 4 survived >150 days without rejection (p < 0.05). These data demonstrate that KICAT requires MHC‐matching between kidney allograft parenchyma and heart allografts, suggesting that cells intrinsic to the kidney enable cardiac allograft tolerance.     

Heart and en-bloc thymus transplantation in miniature swine

BACKGROUND: Donor-specific tolerance to organ allografts might be induced by cotransplantation of a sufficient amount of vascularized donor thymus. To facilitate donor thymus-induced cardiac allograft tolerance, we have developed a novel technique for heart and en-bloc thymus transplantation in swine. METHODS: Donor heart and en-bloc thymus grafts were prepared by a technique that preserves the entire arterial supply and venous drainage of the right thymic lobe. En-bloc grafts (n = 4) were transplanted heterotopically into the abdomens of major histocompatibility complex-matched miniature swine. Recipients received 12 days of cyclosporine intravenously. Grafts were monitored by palpation, electrocardiographic monitoring, and periodic open biopsy. Engraftment of the donor thymus was demonstrated by measuring the proportion of recipient-type thymocytes in the donor thymus with flow cytometry. RESULTS: All of the heart and en-bloc thymus grafts had normal cardiac contractility and immediate perfusion of the thymus. All en-bloc grafts were accepted for more than 200 days without significant acute cellular rejection or cardiac allograft vasculopathy. Thymic tissue of en-bloc grafts displayed normal architecture and supported thymopoiesis of recipient-type cells. CONCLUSION: We have validated a new technique of donor thymus transplantation that could have utility in human heart transplantation.     

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.     

Recipient bone marrow engraftment in donor tissue after long-term tolerance to a composite tissue allograft

BACKGROUND: An important component of a composite tissue limb allograft (CTA) is the vascularized bone marrow and bone marrow stroma, which when transplanted could create immediate marrow space and engraftment. We have previously demonstrated that tolerance to musculoskeletal allografts can be achieved with a 12-day course of cyclosporine without the presence of long-term peripheral donor cell chimerism. The objective of this study was to determine the fate of the donor bone marrow after transplantation of a limb allograft in a miniature swine model. METHODS: CTAs from donor swine were heterotopically transplanted into six MHC-matched, minor-antigen-mismatched recipients, and a 12-day course of cyclosporine was given. Previous animals transplanted without cyclosporine rejected their grafts in less than 42 days. A non-MHC-linked marker, pig allelic antigen (PAA), was used to distinguish host and donor cells. Three PAA- animals received PAA+ CTAs, and three PAA+ animals received PAA- CTAs. Bone marrow was harvested from the donor limb grafts and the recipient and analyzed by flow cytometry and histology. Thymus, spleen, and mesenteric lymph nodes were also harvested from the recipient swine and evaluated for the presence of donor cells by flow cytometry. RESULTS: All animals receiving cyclosporine demonstrated permanent tolerance to their allografts. Donor bone marrow cells were present in all grafts at the time of transplantation and during the immediate postoperative period. By 48 weeks, donor cells were no longer detectable within the marrow space of the allograft. In long-term animals host bone marrow cells replaced donor cells in the graft marrow space. No evidence of donor cell engraftment was found in recipient animals. CONCLUSION: This study demonstrates that in long-term tolerant recipients of musculoskeletal allografts there is no evidence of persistent donor bone marrow cells in the hematopoietic tissues of the graft or the host. Rather, the recipient's bone marrow cells and lymphocytes repopulate the donor marrow space of the graft.     

An MHC class II disparity raises the threshold for tolerance induction in pulmonary allografts in miniature swine

OBJECTIVES: The mechanisms and treatment of chronic rejection in pulmonary allotransplantation remain elusive. We have induced robust tolerance to class I-disparate lung allografts in miniature swine using an intensive 12-day course of tacrolimus. Here, we tested whether a tolerant state can be induced in swine receiving fully mismatched lung allografts. METHODS: Orthotopic left lung allografts were performed using MHC class I-disparate (group 1: n = 3) or fully disparate (group 2: n = 6) donors. The recipients received a 12-day postoperative course of tacrolimus (continuous intravenous infusion; target level = 35-50 ng/mL) as their only immunosuppression. RESULTS: All swine in group 1 maintained their grafts long term without developing any lesions of chronic rejection (>497, >432, >451 days). These recipients exhibited donor-specific hyporesponsiveness in cell-mediated lymphocytotoxity (CML) and mixed lymphocyte reaction (MLR) assays. In group 2, five of the six recipients maintained their grafts long term (sacrificed on postoperative days 515, 389, 429, 481, and 438 with viable grafts). Isolated lesions of obliterative bronchiolitis were occasionally seen on biopsy, and donor-specific hyporesponsiveness on assays was consistently observed. The remaining recipient rejected its graft on day 103 with histologic findings of obliterative bronchiolitis. CONCLUSIONS: We report long-term graft acceptance without chronic immunosuppression in five of six recipients across a full MHC disparity, albeit with some evidence of obliterative bronchiolitis. These data suggest that the class II disparity inherent in a fully mismatched transplant increases the requirement for tolerance induction.     

Tolerance to musculoskeletal allografts with transient lymphocyte chimerism in miniature swine

BACKGROUND: Although transplantation of musculoskeletal allografts in humans is technically feasible, the adverse effects of long-term immunosuppression subject the patient to high risks for correcting a non-life-threatening condition. Achieving immunologic tolerance to musculoskeletal allografts, without the need for chronic immunosuppression, could expand the clinical application of limb tissue allografting. Tolerance to musculoskeletal allografts has been accomplished previously in miniature swine in our laboratory. Although stable, mixed chimerism has been suggested as the mechanism underlying long-term tolerance in a rat limb model, the mechanism of this tolerance induction has not been established. This report explores the possible relationship between hematopoietic chimerism and tolerance to musculoskeletal allografts in swine. METHODS: Twelve miniature swine underwent vascularized musculoskeletal allograft transplantation from histocompatibility complex (MHC) matched, minor antigen-mismatched donors. Eight animals received a 12-day coprse of cyclosporine, one of which was excluded due to subtherapeutic levels. Four recipients were not immunosuppressed. Serial biopsies to assess graft viability and flow cytometry to assess chimerism were performed. Donor and third-party skin grafts were placed on recipients with surviving allografts greater than 100 days to validate tolerance. RESULTS: Both groups developed early peripheral chimerism, but this chimerism became undetectable by postoperative day 19 in the cyclosporine group and by day 13 in the control group. Animals receiving cyclosporine developed permanent tolerance to their allografts, whereas those not receiving cyclosporine rejected their allografts in 6-9 weeks. Animals demonstrating tolerance to their bone allografts also demonstrated prolonged donor skin graft survival. CONCLUSIONS: Induction of tolerance to musculoskeletal allografts can be achieved in the MHC matched swine. Although hematopoietic chimerism is present in the immediate postoperative period, persistent, long-term chimerism does not seem to be necessary for maintenance of such tolerance.     

Composite ''Thymoheart'' Transplantation Improves Cardiac Allograft Survival

We have generated a novel composite organ, the thymoheart, which facilitates the contemporaneous transfer of fully vascularized and functional donor thymic tissue to the host at the time of cardiac transplantation. Composite thymoheart allografts were prepared in MHC-inbred miniature swine by implanting autologous thymic tissue into donor hearts 60-90 days before organ procurement. Thymoheart allografts and unmanipulated control hearts were then transplanted into three groups, each treated with the same 12 days of cyclosporine. MHC-matched thymohearts transplanted into euthymic recipients had a minimum survival ranging between 72 and 194 days vs. 42-64 days for unmanipulated control hearts (p = 0.02). MHC class I-disparate thymohearts transplanted into euthymic recipients had a minimum survival ranging between 64 and 191 days vs. 30-55 days for unmanipulated control hearts (p = 0.01). MHC class I-disparate thymohearts transplanted into thymectomized recipients survived between 41 and 70 days vs. 8-27 days for unmanipulated control hearts (p = 0.01). Cellular and humoral functional assays, and skin grafting, confirmed the presence of donor-specific hyporesponsiveness in long-term thymoheart allografts recipients. The transfer of vascularized, functional donor thymic tissue to the host at the time of cardiac transplantation may provide a novel approach to the induction of tolerance in human heart transplant recipients.     

Long-term acceptance of porcine pulmonary allografts without chronic rejection

OBJECTIVES: The mechanisms and treatment of chronic rejection in pulmonary allotransplantation remain elusive. Using a strategy to induce tolerance across strong allogeneic barriers, we have employed a brief, intensive course of immunosuppression to determine whether the induction of donor-specific hyporesponsiveness would prevent allograft rejection in a preclinical model of lung transplantation using MHC-inbred miniature swine. METHODS: Orthotopic left lung allografts were performed using MHC class I-disparate donors. The recipients received a 12-day postoperative course of cyclosporine (n = 6) or a 12-day postoperative course of high-dose tacrolimus (n = 3) as their only immunosuppression. Control animals received no immunosuppression (n = 3). RESULTS: Cyclosporine-treated recipients exhibited graft survival ranging from 67 to >605 days. All six animals developed acute cellular rejection between postoperative days (PODs) 27 and 108. Two animals lost their grafts on PODs 67 and 69, before developing obliterative bronchiolitis (OB). The other four recipients developed OB between PODs 119 and 238. In contrast, all tacrolimus-treated recipients maintained their grafts long term, without developing chronic rejection (>339, >308, and >231). These recipients also exhibited donor-specific hyporesponsiveness in assays of cell-mediated lymphocytotoxity. All untreated control animals lost their grafts to acute rejection by POD 11. CONCLUSIONS: This study demonstrates the ability of a brief course of high-dose tacrolimus to induce long-term graft acceptance with donor-specific hyporesponsiveness in a class I-disparate preclinical lung transplant 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.     

Thymectomy does not abrogate long-term acceptance of MHC class I-disparate lung allografts in miniature Swine

We have previously reported that tolerance to class I disparate lung allografts in miniature swine could be induced using an intensive 12-day course of tacrolimus and that pretransplant sensitization with immunogenic MHC class I allopeptides failed to block the induction of tolerance. We also have previously reported the importance of the presence of the thymus in the induction of tolerance to isolated heart, kidney, and combined heart-kidney transplants. In this study, we examined the impact of thymectomy on tolerance induction in lung transplantation. METHODS: Orthotopic left lung transplantation was performed using MHC class I-disparate donors. The recipients received a 12-day course of high-dose tacrolimus (n = 6). Total thymectomies were performed in three of the swine 21 days prior to transplantation. Lung grafts were monitored by chest radiography and serial open lung biopsy. RESULTS: All euthymic recipients maintained their grafts for over 1 year. None of the thymectomized recipients has experienced graft loss in the 6 to 10 months following transplantation. Although isolated lesions of obliterative bronchiolitis were occasionally seen in one thymectomized animal on biopsy, donor-specific unresponsiveness has been observed on assays of cell-mediated lymphocytotoxicity in all recipients. Moreover, co-culture assays have shown that recipient lymphocytes can strongly inhibit the normally robust response of na?ve recipient-matched lymphocytes to donor antigen. This inhibition was not seen when using stimulators primed with third-party antigens against appropriate targets. CONCLUSIONS: These data suggest that thymus-independent peripheral regulatory mechanisms may be sufficient to induce and maintain long-term acceptance of the lung allografts.     

Induction of Transplant Tolerance with Immunodominant Allopeptide-pulsed Host Lymphoid and Myeloid Dendritic Cells

We have studied the effects of adoptive transfer of host thymic dendritic cells pulsed with immunodominant WF Class I peptide 5 (residues 93-109) on cardiac allograft survival in the WF-to-ACI rat combination. Our results showed that, whereas intrathymic inoculation of WF peptide 5-pulsed ACI thymic dendritic cells alone on day -7 did not prolong graft survival, similar treatment combined with 0.5 mL antilymphocyte serum (ALS) led to 100% permanent acceptance (> 200d) of donor-specific cardiac allografts. Extension of our study to systemic administration of peptide 5-pulsed host thymic dendritic cells confirmed that intravenous injection of peptide 5-pulsed self thymic dendritic cells combined with ALS transient immunosuppression resulted in 100% permanent donor-specific graft survival (> 200d). These results were reproducible in a clinically relevant model using intravenous injection of peptide-pulsed host myeloid dendritic cells. In contrast, thymectomy prior to adoptive transfer of peptide-pulsed host dendritic cells resulted in acute graft rejection at times equivalent to rejection in thymectomized controls. The long-term unresponsive recipients challenged with second-set grafts accepted permanently (> 100d) donor-type (WF) but not third party (Lewis) cardiac allografts. This study suggests that intravenous administration of genetically engineered dendritic cells expressing donor MHC molecules has the potential of inducing transplant tolerance.     

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.     

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.     

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.     

Thymic transplantation in miniature swine. I. Development and function of the "thymokidney"

BACKGROUND: Previous studies in our laboratory have demonstrated the importance of the thymus for rapid and stable tolerance induction in an allotransplant model. The focus of the present study was to explore the feasibility of autologous thymic transplantation to produce a new transplantable organ (thymokidney) and to examine the function of subsequent vascularized thymokidney transplants in T cell development. MATERIALS AND METHODS: Eight juvenile swine received autologous thymic grafts under the renal capsule. Thymic tissue was obtained through a partial (n=6) or complete (n=2) thymectomy, and growth of the autologous thymic graft was compared between partially and completely thymectomized animals. Two of the partially thymectomized animals received irradiated (1000 cGy) as well as non-irradiated autologous thymic grafts. Graft survival, growth and evidence of thymocyte development was determined by (a) macroscopic examination of the implanted tissue, (b) histological examination, and (c) flow cytometry. Naive CD4 SP T cells were identified by CD45RA-expression. RESULTS: Growth of transplanted thymic tissue was demonstrated in all thymic graft recipients. No difference was seen between partially and completely thymectomized animals. By POD 60, the thymic grafts exhibited normal macroscopic and microscopic structure, and normal thymocyte composition. Irradiated thymic tissue displayed a similar pattern of development, but growth was markedly delayed. To evaluate thymic function of the graft, a composite thymokidney was transplanted into a recipient which had previously been thymectomized, had few circulating CD4-single positive cells and had lost MLR reactivity. The number of CD4+/CD45RA+ cells in this animal increased steadily from POD 30 to POD 150, indicating that the thymus of the composite thymokidney allograft was functional; in addition, MLR assays demonstrated that the recipient recovered immunocompetence. CONCLUSIONS: The establishment of a thymokidney by thymic autografting to the renal subcapsular space results in normal thymic growth and function, and may provide a valuable tool for studying the role of the thymus in tolerance induction. As far as we are aware, we provide the first evidence of functional vascularized thymic graft reconstituting T cells and leading to a return of a immunocompetence in a large animal model.