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.     

Role of the thymus and kidney graft in the maintenance of tolerance to heart grafts in miniature swine

BACKGROUND: The authors have examined the mechanism whereby co-transplantation of a kidney and heart from the same donor induces and maintains tolerance to both organs in miniature swine. METHODS: Transplants were performed across a major histocompatibility complex class I mismatch, and recipients received cyclosporine for 12 days. Group 1 animals received heart transplants alone (n=5), and all other groups received both heart and kidney allografts. Group 2 animals received no further intervention (n=2). Group 3 animals underwent transplant nephrectomy 8 days after heart and kidney co-transplantation (n=2). Group 4 animals underwent transplant nephrectomy 100 days after co-transplantation (n=2). Skin grafts were placed on group 4 animals, on one group 3 animal, and on two animals from group 2. Group 5 animals underwent thymectomy 100 days after co-transplantation (n=4). RESULTS: Group 1 animals developed cardiac allograft vasculopathy (CAV) and rejection. Group 2 animals never developed CAV and demonstrated in vitro donor-specific unresponsiveness. Group 3 animals suffered CAV and rejection. Group 4 animals developed CAV without concomitant donor-specific cell-mediated lympholysis reactivity, interstitial rejection, or cessation of graft function. Skin grafts on group 3 and group 4 animals led to fulminant rejection of heart and skin grafts, in contrast to grafts on group 2 animals that had no in vivo effect. Group 5 animals developed CAV but no significant increase in interstitial infiltrates. CONCLUSIONS: Both the kidney and thymus were necessary for maintenance of tolerance to heart allografts.     

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.     

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.     

Effect of organ culture on the survival of thyroid allografts in mice.

Mouse thyroid can be maintained in organ culture for 4 weeks. Uncultured BALB/c thyroid is rejected 10-15 days after transplantation under the kidney capsule of H-2 disparate recipients (C57BL, CBA). Organ culture of thyroid tissue prior to transplantation prolongs allograft survival. This prolongation of graft survival increases with increasing time in culture and 80-90% of BALB/c thyroids maintained in culture for 26 days survive in allogeneic CBA recipients for a 60- to 70-day test period. These allografts show normal function as measured by 125I uptake, and show no histological evidence of chronic rejection. Cultured allografts can be rejected if the host's immune system is stimulated with viable leukocytes of donor origin. Host animals carrying a functioning allograft are not tolerant of donor tissues and will reject a second uncultured allograft from the same donor strain.     

Effects of tolerance induction on the actions of interferon-gamma on porcine cardiac allografts

It is well known that interferon-gamma (IFN-gamma) not only plays a critical role in antigen-dependent but also in antigen-independent tissue injury; however, it is not clear how tolerance induction affects the actions of IFN-gamma in the transplant setting. To address this question, we compared the effects of IFN-gamma on porcine recipients of near-syngeneic, rejecting, and tolerant heart transplants. IFN-gamma was infused continuously into the left anterior descending artery of hearts transplanted into 3 groups of major histocompatibility complex (MHC) inbred miniature swine, each treated with a 12-day course of cyclosporine A (CyA). Group 1 recipients received a MHC class I disparate heart, group 2 recipients received a near-syngeneic heart, and group 3 recipients were cotransplanted with a MHC class I disparate heart and kidney, which uniformly induces tolerance to both grafts. An additional group of animals was not transplanted but received intracoronary IFN-gamma infusion into their native hearts. IFN-gamma perfusion not only accelerated the acute rejection of MHC class I disparate hearts (mean survival time = 19 +/- 7.21 vs 38 +/- 8.19 days, P = .025), but caused near-syngeneic heart transplants, which otherwise survive indefinitely, to reject within 35 days (n = 3). In contrast, IFN-gamma perfusion had no demonstrable effects on interstitial rejection, the development of vascular lesions, or graft survival in tolerant heart plus kidney allograft recipients (n = 4) or in autologous hearts (n = 2). These results suggest that tolerance induction mitigates the damaging effects of IFN-gamma itself and that the beneficial effects of tolerance induction on acute and chronic rejection may extend to antigen-independent factors like ischemia/reperfusion injury.     

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

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

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.     

The experimental study of cardiac allograft vasculopathy and myocardial fibrosis in rats

We sought to analyze the development of myocardial fibrosis and cardiac allograft vasculopathy (CAV) as a theoretical basis for the prevention and treatment of rejection. Heterotopic cardiac transplantation was performed from Wistar rats to Sprague-Dawley rats. The recipients pretreated with donor splenocyte (SPC) infusion followed by cyclophosphamide (CP) were divided into 3 groups: Control animals without immunosuppression (Group 1; n = 10); Group 2, CsA treatment (n = 10) with euthanasia 2-3 months posttransplantation; and Group 3 (n = 20), CP plus SPC treatment with 10 recipients euthanized at 2 weeks posttransplantation and 10 animals monitored for at least 1 year posttransplantation. Histological studies were performed to evaluate myocardial fibrosis and CAV; 2-3 days after transplantation, there was abundant infiltration of collagenous fibers in the adventitia and intima of the coronary arteries in Group 1 allografts. Group 2 allografts demonstrated abundant infiltration of collagenous fibers in the adventitia and intima of arteries and arterioles resulting in significant luminal stenosis. In contrast, pretreatment of animals with SPC and CP induced long-term allograft survival; myocardial fibrosis and CAV were dramatically reduced in Group 3 compared with Groups 1 and 2. The infiltration of collagenous fibers in coronary arteries was one of the major causes of CAV. Preconditioning of recipients with SPC followed by CP not only induced immune tolerance but also alleviated myocardial fibrosis and CAV in allografts.     

Monitoring antidonor alloantibodies as a predictive assay for renal allograft tolerance/long-term observations in nonhuman primates

BACKGROUND: In an effort to define reliable assays that might predict postimmunosuppressant-withdrawal development of chronic rejection (CR), despite conditioning for tolerance induction, we evaluated various immunological responses in nonhuman primate renal allograft recipients. METHODS: Fourteen Cynomolgus monkeys received low dose total body irradiation, thymic irradiation, antithymocyte globulin, and peritransplant CD154 blockade, followed by a one-month course of cyclosporine. Recipients underwent major histocompatibility complex mismatched kidney transplantation with donor bone marrow infusion (Group A, n=8), without donor cell infusion (Group B, n=2), or with donor splenocyte infusion (Group C, n=4). RESULTS: All Group A recipients developed mixed chimerism and four of them survived long-term without rejection. The remaining four rejected their kidney allografts either chronically or acutely. All recipients in Groups B and C failed to develop chimerism and rejected their allografts. Among various in vitro assays, detection of anti-donor alloantibody (ADA) by flow cytometry (FCM) was the most relevant to long-term outcome. All five recipients that developed both anti-T cell and B cell IgG ADA in Groups A, B and C, developed histological evidence of CR within 200 days of the appearance of ADA. One of two recipients that developed only anti-B cell IgG ADA eventually developed CR over two years following discontinuation of immunosuppression and 1.5 years after ADA development. Another recipient with very low anti-B cell ADA has never developed CR. CONCLUSION: ADA monitoring with FCM assay appears to be useful in predicting the failure of tolerance prior to the development of functional or histologic abnormalities of the renal allograft.     

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.     

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.     

Rejection of established mouse pancreatic islet allografts by active immunization requires class I (H-2 K, D) antigen disparities

In certain donor-recipient mouse strain combinations with class I (H-2 K, D, and K + D) or with classes I and II (H-2 D + I) disparities the incidence of islet allograft rejection is low. Furthermore pancreatic islet allografts transplanted between strains with class II (H-2 Ia) differences alone are rarely acutely rejected. In this experiment the ability of donor strain or third-party allogeneic splenocytes (active immunization) to induce rejection of established (greater than 100 days) islet allografts when the donor and recipient differed only for class I or class II antigens was tested. Class I disparate islet allografts are rejected if challenged with donor or third-party allogeneic splenocytes. The frequency of rejection is similar (80-89%) if the third-party splenocytes share the class I allele with the islet donor strain. In contrast, class II disparate islet allografts are not rejected after challenge with donor splenocytes or third-party splenocytes even when the third-party strain shares the class II disparity with the islet donor strain as well as class I antigens common to the donor and recipient. Furthermore, rejection of class II disparate islets did not occur following passive transfer of recipient strain splenocytes sensitized in vitro to donor strain lymphocytes. These results show that rejection of established islet allografts can only be induced if (1) the islet graft expresses H-2 K or H-2 D gene products that are different than the recipient strain, i.e., only class I antigens can serve as targets; and (2) challenging splenocytes also have class I disparities with the recipient.     

Enforcement of specific unresponsiveness by the long-term presence of allogeneic heart grafts

Mechanisms underlying the maintenance of long-term heart allografts were analyzed in rats treated with Cyclosporine. It was shown that acceptance of allografts after cyclosporine did not involve the attenuation of immunogenicity of the grafts. This conclusion was drawn from two observations: (1) Pretreatment of the donors with cyclosporine did not cause prolongation of graft survival time; and (2) cyclosporine stabilized allografts were normally rejected by secondary recipients when retransplanted on day 30. Studies of the acceptance of skin grafts from the heart donor strain indicated the existence of a mechanism to maintain donor-specific unresponsiveness in the presence of a stable allograft in a time-dependent manner. Thus, the mean rejection time of F344 skin grafts on WKA rats bearing F344 hearts was more than 80 days when transplanted on day 210, but it was 32 days when they were transplanted on day 30. Active participation of specific suppressor cells in the maintenance of unresponsiveness was suggested because data obtained in the cell transfer experiments was statistically significant. Transfer of lymphocytes from rats bearing long-term grafts showed a tendency to delay rejection of skin grafts by sublethally irradiated hosts, but it failed to delay the rapid rejection by normal lymphocytes cotransferred to the same recipients.     

Donor-specific cellular immunity in rejecting and long-term-surviving class I-disparate rat renal allograft recipients

The effects of pre- and posttransplant immunization on graft survival, infiltrate intensity, and host in situ/systemic cellular immune responsiveness were examined for class I MHC-disparate rat renal allograft recipients. Naive, unsensitized PVG (RT1c) recipients of class I MHC disparate PVG.R1 (RT1.Aa on PVG background) orthotopic kidney transplants displayed long-term (greater than 50 days) survival (LTS) in a majority (41/52) of cases. Pretransplant immunization of recipients with a PVG.R1 skin graft most often resulted in rejection (mean survival greater than 21.3 days) with 8/15 rats surviving less than or equal to 2 weeks and only 3/15 with LTS. Pretransplant immunization with a skin graft from a fully MHC-disparate PVG.1A (RT1a on PVG background) donor resulted in acute rejection (mean = 6.1 days) with 0/8 rats surviving greater than or equal to 2 weeks. Donor-specific class I and II disparate (PVG.1A), and third-party (LEW) skin transplants applied on LTS (greater than 50 days) PVG.R1 kidney graft recipients showed typical 1st- and accelerated 2nd-set skin graft rejection, but had no effect on kidney graft survival. In contrast, 6/7 LTS PVG.R1 kidney graft recipients accepted PVG.R1 skin grafts indefinitely following their transient partial rejection. Histologic analysis of kidney allografts revealed the highest degree of mononuclear cell infiltrates in animals specifically sensitized by PVG.1A skin grafts prior to transplant. Donor class I-specific cytotoxic T lymphocyte precursor (pCTL) frequencies, as determined by limiting dilution assays, were increased and equivalent at 1 week posttransplant in kidney allograft cell eluates from nonrejecting naive recipients (1/127-1/2209) and rejecting presensitized animals (1/470-1/7848). LTS animals had decreased intragraft pCTL at greater than 50 days (1/2969-1/61875), as did LTS at greater than 50 days that received PVG.R1, PVG.1A, or LEW skin grafts posttransplant. In all groups, splenocyte pCTL frequencies were significantly lower than the corresponding values within the allograft. By comparison, no significant differences in intragraft or splenic proliferative T lymphocyte (pPTL) precursor frequencies were observed between any groups. These results indicate that unsensitized recipients of class I-disparate renal cells grafts are capable of maintaining graft survival in the early posttransplant period, despite the presence of significant in situ antidonor class I MHC-specific cellular immune responsiveness. These findings also indicate that long-surviving PVG recipients of class I-disparate renal allografts develop specific functional tolerance to donor class I alloantigens, that may be associated with a diminished frequency of anti-class I cytotoxic (but not proliferative) T cell precursors.     

Combination treatment with donor-specific transfusions and cyclosporine a induces long-term survival of cardiac allografts in miniature Swine

BACKGROUND: To evaluate whether pretransplant donor-specific transfusions (DST) can induce tolerance to cardiac allografts in large animals, heterotopic cardiac transplants were performed across a class I MHC barrier in inbred miniature swine. METHODS: Experimental animals received two DSTs, each containing 1.4x10 viable peripheral blood mononuclear cells, 14 and 7 days prior to transplantation together with a 12-day course of cyclosporine (CyA) (13 mg/kg IV) starting on postoperative day (POD) 0. RESULTS: Untreated (n=2) and DST-only (n=2) treated control animals rejected between POD 6 and 8. Animals treated with CyA alone (n=3) exhibited graft survival to 53, 52 and 59 days. In contrast, the combination of DST and CyA (n=3) led to stable graft function for >200 days. Long-term survivors maintained peripheral CML response against donor antigen. Following DSTs, the donor-specific proliferative response of CD8+ recipient T cells was significantly increased (P=0.011), and a significant number of CD8+ T cells underwent apoptosis (10.1% on POD 0; 5.2% on POD -14; P=0.04). None of the DST-treated animals developed donor-specific antibodies. CONCLUSIONS: These results are the first to demonstrate the ability of DST to induce operational tolerance to cardiac allografts in large animals, and they suggest that peripheral mechanisms of tolerance mediate this effect.     

Humoral Immunity to Vimentin Is Associated with Cardiac Allograft Injury in Nonhuman Primates

Immunity to autologous protein has not previously been described following nonhuman primate cardiac transplant. Native hearts and cardiac allografts from cynomolgus monkeys were assessed by immunohistology for vimentin, a highly conserved intermediate filament protein. IgM and IgG to vimentin were measured in serial sera from untreated (n = 4) or cyclosporine (CsA)-treated (n = 8, 2 with ATG) cardiac allograft recipients, and in groups treated with anti-CD154 antibody with (n = 6) or without ATG (n = 28). IgM or IgG reactive with vimentin was elaborated within 30 days with unmodified acute rejection (3/4) or in CsA-treated animals (5/6). CD154 blockade did not prevent anti-vimentin IgM (14/28) but tended to delay the IgG response during therapy (anti-CD154: 8/28, p = 0.10 vs. CsA; anti-CD154+ATG: 2/6). CAV and alloantibody were seen in 25 of 26 animals with grafts surviving over 30 days, including seven animals without increasing anti-vimentin antibody. Anti-vimentin antibodies and vascular complement deposition were found in rejected hearts. Acute and chronic alloimmunity disrupt modulation of autoreactivity to vimentin through pathways, which are resistant to CsA, but may be partially regulated by CD154.     

The Indirect Alloresponse Impairs the Induction but Not Maintenance of Tolerance to MHC Class I-Disparate Allografts

We studied the effects of indirect allorecognition on the induction and maintenance phases of tolerance in miniature swine cotransplanted with heart and kidney allografts. MHC class I-mismatched heart and kidney grafts were cotransplanted in recipients receiving CyA for 12 days. Recipients were unimmunized or immunized with a set of donor-derived or control third-party MHC class I peptides either 21 days prior to transplantation or over 100 days after transplantation. T-cell proliferation, delayed type hypersensitivity reaction (DTH) and antibody production were assessed. All animals injected with donor MHC class I peptides developed potent indirect alloresponses specific to the immunizing peptides. While untreated recipients developed stable tolerance, all animals preimmunized with donor allopeptides rejected kidney–heart transplants acutely. In contrast, when peptide immunization was delayed until over 100 days after kidney–heart transplantation, no effects were observed on graft function or in vitro measures of alloimmunity. Donor peptide immunization prevented tolerance when administered to recipients pre transplantation but did not abrogate tolerance when administered to long-term survivors post transplantation. This suggests that the presence of T cells activated via indirect allorecognition represent a barrier to the induction but not the maintenance of tolerance.     

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.