The differential effects of donor versus host Langerhans cells in the rejection of MHC-matched corneal allografts

The fate of MHC-identical, multiple minor H-disparate corneal grafts was examined in the rat. Although skin grafts exchanged between LEW and F344 rats were invariably rejected, only 26% of the corresponding corneal grafts underwent rejection. The immunologic privilege of the minor H-disparate corneal grafts was due, at least in part, to the absence of donor-derived Langerhans cells. Corneal grafts were normally devoid of donor-derived Langerhans cells; however, grafts pretreated with latex beads became infiltrated with donor-derived Langerhans cells and were rejected by 59% of the naive minor H--compatible recipients. By contrast, untreated LEW corneal grafts underwent rejection in 26% of the naive F344 hosts even though the grafts became heavily infiltrated with host-derived Langerhans cells. The immunologic privilege of minor H-disparate corneal grafts was not the result of efferent blockade or suppression of the immune response. F344 hosts bearing long-term surviving LEW corneal allografts were challenged with LEW skin grafts. In all cases, orthotopic skin grafts were rejected acutely. Moreover, all previously clear corneal grafts underwent rejection following skin graft rejection. Thus, the unique absence of donor-derived Ia+ passenger cells and the avascular graft bed conspire to provide the primary minor H-disparate corneal graft with an immunologic privilege not shared by other organ grafts.     

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.     

Development of autoimmunity after skin graft rejection via an indirect alloresponse

BACKGROUND: T cell allorecognition occurs through direct contact with donor peptide: MHC complexes on graft cells and through indirect recognition of donor-derived determinants expressed by recipient MHC molecules. As both indirect allorecognition and autoantigen recognition are self-restricted, we hypothesized that chronic activation of indirectly primed T cells might result in determinant spreading to involve autoantigens, analogous to that which occurs during chronic autoimmune diseases. METHODS: We placed C57BL/6 MHC II knockout (B6 II-/-) skin grafts onto BALB/c SCID mice reconstituted with wild-type (WT) CD4+ T cells. Under these conditions the CD4+ cells could not recognize any antigen on the graft, but could respond through the indirect pathway. CD4+ cell-mediated rejection of WT B6 skin was studied to determine if autoreactivity was induced after direct allorecognition. Recall immune responses against donor- and self-stimulator cells were determined by ELISPOT and animals were tested for their ability to reject second isografts. RESULTS: WT allografts were rejected by day 14 although B6 II-/- grafts underwent delayed rejection over 4-5 weeks. CD4+ cells reisolated from the recipients of the MHC II-/- grafts, but not from the recipients of WT grafts, vigorously produced interferon-gamma and interleukin-2 in response to self, BALB/c stimulators. These autoreactive CD4+ T cells mediated rejection of a second isogenic BALB/c skin graft, demonstrating that the autoimmune response was pathogenic. CONCLUSION: Autoreactivity can develop after transplant rejection via the indirect pathway. Although the direct alloresponse is likely to be the driving force in acute graft rejection, posttransplantation induced autoimmune responses may be important elements of delayed or chronic rejection.     

Indefinite survival of rat islet allografts following infusion of donor bone marrow without cytoablation

We have tested the effect of donor bone marrow cell (DBMC) infusion on the survival of pancreatic islet allografts in the rat, without the use of cytoablative recipient conditioning. Lewis and diabetic Brown Norway rats were used as donors and recipients, respectively. Donor islets were placed beneath the left renal capsule. Infusion of DBMC and temporary immunosuppression followed by delayed islet transplantation resulted in indefinite survival of all islet grafts (MST >180 days). Control animals demonstrated recurrent hyperglycemia (islet allografts rejection). Donor bone marrow derived cells were detected in the spleen and cervical lymph nodes of BN recipients of LEW bone marrow but not in the recipients of islet transplants alone. Second set full thickness skin grafts were performed in normal BN and in recipients of a previously successful ITX. Donor specific skin grafts were accepted in the animals that had received DBMC 40 days before the islet allograft, while animals receiving DBMC at the time of the islet allograft rejected the donor specific skin graft similarly to the controls. However, these animals did not reject a second set donor-specific islet transplant. The results indicate that radiation conditioning of the recipients was not necessary to induce microchimerism and graft acceptance in this rodent model of islet allotransplantation.     

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.     

Co-transplantation of donor-derived hepatocytes induces long-term tolerance to cardiac allografts in a rat model

BACKGROUND: Liver allografts transplanted between MHC-disparate mice, rats, and swine are spontaneously accepted in most strain combinations without requirement for immunosuppression. The underlying mechanism has, however, remained elusive. Here, we demonstrate that co-transplantation of donor-derived hepatocytes protect Lewis (RT1.A1) cardiac allografts from acute and chronic rejection in DA (RT1.Aa) recipients indefinitely. METHODS: Livers of donor Lewis rats were harvested and the hepatocytes separated from hepatic leukocytes by collagenase digestion and gradient separation. DA recipient animals were transplanted Lewis cardiac allografts and simultaneously intraportally infused either Lewis-derived hepatocytes or hepatic leukocytes. Recipient animals were either not further treated or received a single dose of 15 mg/kg cyclosporine. RESULTS: Donor hepatocytes alone significantly protected syngeneic cardiac allografts from rejection, whereas hepatic leukocytes failed to influence graft survival. In combination with cyclosporine, recipient cardiac allografts were indefinitely protected from rejection. Graft-infiltrating cells in tolerant animals presented as clusters of CD4+ T cells and stained mostly positive for interleukin-4, whereas graft-infiltrating cells in rejected allografts were predominantly positive for interferon-gamma. Adoptive transfer of splenocytes derived from tolerant animals protected Lewis cardiac allografts from rejection in DA recipients without immunosuppression. In contrast, hepatic leukocytes protected only 50% of the allografts from rejection. CONCLUSION: We propose that donor hepatocytes induce permanent engraftment of syngeneic allografts by establishing a Th2 type alloresponse that is transferable to new graft recipients. The results of this study demonstrate that liver parenchymal cells significantly mediate spontaneously liver-induced tolerance.     

Donor marrow-derived cells as immunogens and targets for the immune response to bone and skin allografts

The relative importance of donor marrow-derived cells in the immunogenicity of bone and skin allografts was compared. Radiation chimeras were created to have marrow-derived cells (MDCs) of a different genotype from their nonmarrow-derived cells (NMDCs). Such animals were used as donors of bone or skin for recipients chosen so that either the MDCs or the NMDCs of the graft would be incompatible. Immunogenicity was determined by measuring the recipient antibody response. The effect of the immune response on the bone graft (rejection) was determined by impaired bone healing. When MDCs alone were H-2 disparate with the recipient, bone grafts were immunogenic, and the bone graft healing was impaired. In contrast, skin grafts in the same combinations were immunogenic but were not rejected if the differences were only expressed on the MDCs of the graft. The role of NMDCs in all of these experiments was more difficult to interpret, but the results suggested that NMDCs are relatively unimportant for healing of bone grafts, although critical for rejection of skin grafts. We conclude that, unlike the situation with skin grafts, the major inducers and targets of the immune response to bone allografts are marrow derived.     

Survival of microvascular physeal allograft transplants following withdrawal of short-term postoperative immunosuppression

BACKGROUND: Physeal necrosis following vascularized allograft transplantation occurs because of vascular rejection. The effect of immunosuppression withdrawal on physeal viability after bone-healing to the recipient site was investigated with use of a validated model for heterotopic microvascular transplantation of rabbit tibial physeal allografts. Our hypothesis was that an allograft survives after withdrawal of immunosuppression only if bone-healing, and therefore epiphyseal and metaphyseal vascular continuity, occurs between the transplanted physis and the recipient bone. METHODS: Physeal grafts with adjacent exposed epiphyseal and metaphyseal bone were transplanted to allogeneic recipients. Graft circulation was restored microsurgically. The immunosuppression regimen consisted of cyclosporine, administered for six weeks, followed by withdrawal of immunosuppression for four weeks. The animals were killed at ten weeks postoperatively. Group I consisted of twelve allografts that were transferred with bone contact between the transplanted graft and the iliac crest recipient site, whereas group II consisted of twelve allografts transplanted without bone contact. Control groups had identical surgical procedures without immunosuppression. Longitudinal growth was assessed by fine-detail radiography, and osseous union was evaluated histologically. Transplanted physes were evaluated histologically, and cellular viability was quantified by bromodeoxyuridine uptake. Two-way analysis of variance was used to compare physeal viability between groups. RESULTS: Following immunosuppression withdrawal, the physeal grafts with bone contact had significantly greater viability indices (16.0 +/- 2.9 compared with 0.0 +/- 0.0, p < 0.005) and decreased longitudinal growth (5.1 +/- 1.9 mm compared with 10.3 +/- 3.5 mm, p < 0.05), and they demonstrated histological features that were consistent with continued viability associated with mild rejection compared with grafts transplanted without bone contact. Abnormalities of physeal architecture, however, were seen routinely. All control physes transferred without immunosuppression were nonviable and did not grow. CONCLUSIONS: The viability of physeal allograft transplants is preserved following the withdrawal of immunosuppression, provided that the graft design and recipient site preparation allow for epiphyseal and metaphyseal neovascularization mediated by bone-healing between graft and recipient.     

Peritransplant streptavidin recipient treatment prolongs rat cardiac allograft survival

BACKGROUND: Because streptavidin shows high localization in inflamed tissues, it might also interfere with the proliferation of cells involved in allograft rejection. METHODS AND RESULTS: Treatment of na?ve ACI recipients with 20 mg/kg streptavidin i.p. alone significantly prolonged Lewis cardiac allografts from a mean survival time of 9.8+/-0.7 days in controls to 19.8+/-6.5 days, with one recipient accepting the graft permanently (>250 days). Peritransplant streptavidin treatment combined with 0.5 ml of antilymphocyte serum (ALS) transient immunosuppression led to permanent graft survival (>250 days) in 6 of 10 recipients. Second-set skin grafts performed 60 days after the primary cardiac allograft were prolonged to 45 days, whereas the third party Wistar-Furth (WF) skin grafts were rejected in 15 days without the rejection of the primary Lewis cardiac allografts. Pathology of transplanted cardiac allografts at 100 days showed no mononuclear cell infiltration or chronic allograft vasculopathy. Streptavidin given for 5 days at 20 mg/kg caused a moderate initial weight loss but had no effect on hematologic, biochemical, and histologic parameters in the treated recipients. CONCLUSION: This study demonstrates that peritransplant recipient treatment with streptavidin combined with peritransplant ALS induces prolonged cardiac and second-set skin allograft survival. We conclude that recipient peritransplant streptavidin treatment may provide a new strategy for the induction of transplant tolerance.     

The replacement of graft endothelium by recipient-type cells conditions allograft rejection mediated by indirect pathway CD4+ T cells

BACKGROUND: Whereas the participation of alloreactive T cells sensitized by indirect allorecognition in graft rejection is well documented, the nature of recipient antigen presenting cells recognized by indirect pathway CD4+ T cells within the graft has yet to be identified. The purpose of this study was to determine the role played by graft endothelium replacement in the immune recognition of cardiac allografts rejected by indirect pathway CD4+ T cells. METHODS: Transgenic RAG2-/- mice expressing I-Ab-restricted male antigen H-Y-specific TcR were studied for their capacity to reject H-2k male cardiac allografts. Chronic vascular rejection in this model was due to the indirect recognition of H-Y antigen shed from H-2k male allograft and presented by the recipient's own I-Ab APC to transgenic T cells. RESULTS: Immunohistochemical analysis of rejected grafts revealed the presence of numerous microvascular endothelial cells (EC) that expressed recipient's I-Ab MHC class II molecules. This observation suggested that graft endothelium replacement by I-Ab-positive cells of recipient origin could stimulate the rejection of male H-2k graft by I-Ab-restricted H-Y-specific T cells. To investigate further this possibility, hearts from H-2b-into-H-2k irradiation bone marrow (BM) chimera were transplanted in transgenic recipients. A direct correlation was observed between the presence of I-Ab-positive EC within myocardial microvessels and the induction of acute rejection of chimeric H-2k male cardiac allografts transplanted in transgenic recipients. CONCLUSIONS: We conclude that graft endothelium replacement by recipient-type cells is required for the rejection of cardiac allograft mediated by indirect pathway alloreactive CD4+ T cells.     

猕猴预致敏后肾移植加速性排斥反应的免疫学及病理学特点

目的 观察猕猴预致敏后肾移植加速性排斥反应的免疫学及病理学变化特点.方法 建立猕猴皮肤预致敏后肾移植加速性排斥反应模型(供、受者各3只).检测3只受者皮肤移植预致敏前、后及肾移植后血清内供者特异性抗体的变化.并在发生排斥反应时对移植肾进行免疫组织化学(测定补体、抗体的沉积及各类型淋巴细胞浸润情况)及病理学分析.结果 3只受者均发生了加速性排斥反应.其中2只受者在预致敏后血清中供者特异性抗体明显增加,对供者的淋巴毒反应明显升高;肾移植后受者血清中供者特异性抗体及针对供者的淋巴毒进一步升高.苏木精-伊红染色显示排斥反应的移植肾内有明显的动脉坏死、血栓形成、间质出血、中性粒细胞浸润;免疫组织化学及荧光染色显示移植肾内有大量的补体、抗体沉积(主要为IgG),而各种类型的淋巴细胞浸润少见.另1只受者体内的供者特异性抗体及对供者淋巴毒反应的升高程度不如前2只明显,病理学变化以肾小管损伤为主.结论 皮肤移植预致敏可以诱导受者产生程度不等的预存抗体,导致大多数移植肾在术后早期发牛主要南抗体和补体介导的严重的急性体液性排斥反应.     

灵长类动物预致敏后肾移植加速排斥反应模型的建立

目的 建立灵长类动物预致敏后肾移植加速排斥反应模型.方法 取血型相容的正常猕猴配对,预先将供者腹部全层皮肤移植到受者背部,使受者预致敏.2周后再将同一供者的左侧肾脏移植到受者腹腔内,间时切除受者自体双肾,术后予以环孢素A、霉酚酸酯和泼尼松治疗(致敏用药组),不用免疫抑制剂者为对照(致敏对照组),以未致敏的肾移植作为对照组.术后观察受者血肌酐变化、移植物存活时间及病理特点.结果 对照组的4只移植肾存活时间分别为9、18、8、7 d;致敏对照组的3只移植肾存活时间分别为3、3、4 d;致敏用药组的3只移植肾存活时间分别为2、3、4 d.移植皮肤于术后10 d出现排斥反应,至术后14 d被完全排斥.对照组于肾移植1周以后才发牛排斥反应,而致敏者均在肾移植后3 d左右发生较严重的排斥反应.结论 受者被供者皮肤预致敏后再行肾移植,可以加速移植物的排斥,且不能被环孢素A、霉酚酸酯及泼尼松所组成的三联免疫抑制方案逆转.     

In vitro correlates of rejection. II. Rat mixed lymphocyte reactivity in vitro and cardiac allograft acute rejection, hyperacute or accelerated rejection, and prolongation by active immunization.

The relationship of F1 hybrid to parental strain cardiac allograft rejection rates to mixed lymphocyte reactivity in vitro has been studied in 10 strain combinations crossing the major histocompatibility barrier in three different models of acute rejection, accelerated or hyperacute rejection after skin graft immunization, and attempted active enhancement using 10(7) donor strain bone marrow cells. Although high and low reactivity could be discerned between the F1 hybrid and reciprocal parental strain in three of five instances in the one-way lymphocyte culturr reaction, low reactivity was only associated with prolonged graft survival in one combination. Two strain combinations giving high in vitro lymphocyte responses were associated with easily enhanced grafts. The BN strains was a low responder in vitro in the three combinations tested and as a recipient strain, allografts could not be actively enhanced. After skin graft presensitization, BN recipients rejected grafts hyperacutely in two of three combinations and with a median survival time of 2 days in the third combination. The association of poor in vitro proliferative responses, the inability to induce enhancement, and rapid graft rejection after skin graft presensitization could be related to genetic mechanisms controlling the amount and class or subclass of antibody or to the generation of suppressor cells and remains to be determined.     

The replacement of graft endothelium by recipient-type cells conditions allograft rejection mediated by indirect pathway CD4(+) T cells

BACKGROUND: Whereas the participation of alloreactive T cells sensitized by indirect allorecognition in graft rejection is well documented, the nature of recipient antigen presenting cells recognized by indirect pathway CD4(+) T cells within the graft has yet to be identified. The purpose of this study was to determine the role played by graft endothelium replacement in the immune recognition of cardiac allografts rejected by indirect pathway CD4(+) T cells. METHODS: Transgenic RAG2(-/-) mice expressing I-A(b)-restricted male antigen H-Y-specific TcR were studied for their capacity to reject H-2(k) male cardiac allografts. Chronic vascular rejection in this model was due to the indirect recognition of H-Y antigen shed from H-2(k) male allograft and presented by the recipient's own I-A(b) APC to transgenic T cells. RESULTS: Immunohistochemical analysis of rejected grafts revealed the presence of numerous microvascular endothelial cells (EC) that expressed recipient's I-A MHC class II molecules. This observation suggested that graft endothelium replacement by I-A(b)-positive cells of recipient origin could stimulate the rejection of male H-2(k) graft by I-A(b)--restricted H-Y--specific T cells. To investigate further this possibility, hearts from H-2(b)--into--H-2(k) irradiation bone marrow (BM) chimera were transplanted in transgenic recipients. A direct correlation was observed between the presence of I-A(b)-positive EC within myocardial microvessels and the induction of acute rejection of chimeric H-2(k) male cardiac allografts transplanted in transgenic recipients. CONCLUSIONS: We conclude that graft endothelium replacement by recipient-type cells is required for the rejection of cardiac allograft mediated by indirect pathway alloreactive CD4(+) T cells.     

Assessment of peripheral tolerance in anti-CD4 treated C57BL/6 mouse heart transplants recipients.

The study was designed to compare second heart and skin grafts and in vitro assays as a means of assessing peripheral tolerance in C57BL/6 mice. Vascularized heterotopic BALB/c hearts were placed in C57BL/6 recipients treated with anti-CD4, GK1.5 (1 mg total per 20 g mouse i.p. on days 0, 1, 2, 3). Those mice in which hearts survived for >60 days were challenged with donor and third-party (CBA) skin grafts or with second heart grafts, of donor or third-party origin, attached to the carotid artery and jugular vein. In vitro alloreactivity was assessed by mixed lymphocyte reactions (MLR) and cell mediated lympholysis (CML) using recipient spleen cells. Parenchymal damage, cellular infiltration and vascular disease were assessed from the histology of long-term allografts and isografts. Allografts in untreated recipients were rapidly rejected while isografts survived > 100 days. Primary allografts in anti-CD4 treated recipients also survived > 100 days, as did donor strain secondary heart transplants given at >60 days after the first graft. Third-party hearts were rapidly rejected, as were donor and third-party skin grafts placed on recipients with long-term allografts. These recipients showed low MLR response to both donor and third-party stimulators and donor-specific suppression of CML at 60 days post graft. Long-surviving heart allografts all showed evidence of parenchymal damage and vascular intimal thickening. Thus in the BALB/c to C57BL/6 donor-recipient strain combination, hearts, but not skin grafts, could be used to demonstrate peripheral tolerance, which seemed to be both organ and major histocompatibility complex (MHC) specific. Despite long survival, BALB/c hearts all showed evidence of parenchymal damage and vascular intimal thickening, a sign of chronic rejection.     

IL-4 deficiency prevents eosinophilic rejection and uncovers a role for neutrophils in the rejection of MHC class II disparate skin grafts

BACKGROUND: Acute rejection of MHC class II-disparate bm12 skin grafts by C57BL/6 recipient mice is characterized by massive graft infiltration by eosinophils, together with increased intragraft amounts of IL-4 and IL-5 mRNA. IL-5 blockade prevents the intragraft eosinophil infiltration and prolongs the survival of skin allografts. As the differentiation of T cell precursors into Th2 cells is largely driven by IL-4, we investigated the role of IL-4 in MHC class II-disparate allograft rejection. METHODS: We performed skin grafts from MHC class II incompatible bm12 mice into wild-type C57BL/6 mice (IL-4) or C57BL/6 IL-4 deficient mice (IL-4). Graft survival, in vitro T cell reactivity, and histology were compared. RESULTS: We observed that 50% of IL-4 mice rapidly rejected their bm12 allograft, whereas the other 50% retained their graft 60 days after transplantation. Histological examination of bm12 allografts retained by IL-4 mice showed a normal appearance with no inflammatory infiltrate and no eosinophils. Among IL-4 mice that acutely rejected their bm12 skin graft, we observed a dense polymorphonuclear infiltrate. The depletion of neutrophils significantly prolonged bm12 graft survival. CONCLUSIONS: Eosinophil infiltrates, typical of MHC class II disparate acute skin graft rejection, are critically dependent on the availability of IL-4. IL-4 mice reject MHC class II disparate skin grafts by a pathway of rejection where neutrophils play a direct causal role.     

The role of indirect recognition of MHC class I and II allopeptides in a fully mismatched miniature swine model of lung transplantation

Considerable evidence suggests that indirect recognition of MHC allopeptides plays an important role in solid-organ rejection. Here, we examine whether immunization with class I or class II allopeptides accelerates rejection in a fully MHC-mismatched lung transplant model in miniature swine. METHODS: Recipients were immunized with either donor-derived class I or class II peptides. Sensitization to the peptides was confirmed by DTH testing and in vitro proliferation assays. Nonimmunized control (n = 6), class I peptide-immunized (n = 3), and class II peptide-immunized (n = 3) swine were transplanted with fully mismatched lungs using only a 12-day course of tacrolimus. RESULTS: One control animal rejected its graft on postoperative day 103, while the others maintained their grafts for over 1 year. In the class I peptide-immunized group, two recipients rejected their grafts (days 14 and 52). The third animal has not rejected the graft (day 120, experiment is ongoing). In contrast, in the class II-peptide immunized group, only one animal rejected its graft on day 52, while the others maintained their grafts over 1 year. Both anti-donor IgM and IgG antibodies were detectable in all acute rejectors, although no alloantibody was detectable in long-term acceptors. Regardless of the fate of the graft, all animals have maintained their proliferative responses to the peptides. However, only acceptors maintained donor-specific hyporesponsiveness in cell-mediated lymphocytotoxity and mixed lymphocyte reaction assays. CONCLUSIONS: Pretransplant sensitization of lung allograft recipients to donor allopeptides accelerates graft rejection. This appears particularly true for class I-derived allopeptides, suggesting that class II molecules may be less antigenic when presented indirectly.     

Skin-specific alloantigens in miniature swine

BACKGROUND: The acceptance of skin allografts has historically been among the most challenging problems in the field of transplantation, attributed, at least in part, to the existence of antigens expressed by skin but not by other tissues. Many studies have suggested the existence of skin-specific antigens in rodents, but data in large-animal models are more limited. METHODS: We have recently developed protocols for attaining stable mixed hematopoietic chimerism in miniature swine, using MHC-matched donors and recipients. We have now assessed tolerance to donor-derived skin and cardiac allografts in these chimeric animals. RESULTS: Skin-graft rejection was seen in four of six animals receiving skin grafts taken from the respective hematopoietic donors. In the other two animals, donor-derived skin grafts survived indefinitely. No cardiac-allograft rejection was observed in mixed-chimeric animals that received heart transplants from their hematopoietic donors, even in animals that had already rejected skin allografts from the same donors. In all animals assessed, in vitro hyporesponsiveness to donor hematopoietic cells persisted. CONCLUSION: These findings support the concept that skin expresses immunogenic alloantigens that either are not expressed or are not immunogenic in cardiac or hematopoietic tissue.     

Early biological and immune response to semi-identical liver or kidney allograft in miniature swine

In inbred miniature swine, semi-identical liver allograft recipients survive up to 3 months without immunosuppression, whereas similarly mismatched kidney allografts are uniformly rejected within 2 weeks. The early biological and immunological events were assessed in this unique model. SLA(d/d) pigs (MGH, Harvard Medical School, Boston, MA, USA) received liver or kidney allograft from heterozygous SLA(c/d) miniature swine. Survival, graft function, histology, intragraft cytokines, peripheral lymphocyte and platelet count, plasma cortisol level and cellular/humoral anti-donor immune response were assessed. Kidney allografts were uniformly rejected within 2 weeks, whereas liver allografts survived for up to 87 days. After both liver and kidney transplantation, the peripheral lymphocyte count decreased during the first week concomitantly to a significant elevation of plasma cortisol level. Early decrease of peripheral platelet count was observed after liver but not renal transplantation. Up-regulation of transforming growth factor beta1 (TGF-beta1) and interferon-gamma (IFN-gamma) was observed during the first postoperative week in semi-identical liver allografts and IFN-gamma as well as IL-10 in kidney allografts. In liver recipients, labelled autologous lymphocytes accumulated in the liver graft and native spleen, whereas after renal allograft, lymphocytes accumulated in the native spleen and liver but never in the kidney allograft. Specific cellular anti-donor unresponsiveness was observed from the first post-transplant day in both liver and kidney recipients, while the humoral anti-donor response remained intact. In semi-identical liver allograft, recipient rejection is milder and slower than in similarly matched kidney allograft. The intragraft up-regulation of TGF-beta1 in semi-identical liver allograft might be one mediator to explain the modulation of rejection after liver transplant. The rapid, nonspecific accumulation of recipient lymphocytes in the liver allograft but not in kidney allograft might also play a role in the different survival time in this model.     

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.