Permanent and specific transplantation tolerance induced by a nonmyeloablative treatment to a wide variety of allogeneic tissues: I. Induction of tolerance by a short course of total lymphoid irradiation and selective elimination of the donor-specific host lymphocytes

The long-term success of organ transplantation is limited by complications resulting from consistent nonspecific immunosuppression. Induction of stable, donor-specific tolerance remains the main goal of transplantation immunology. In this article, a new, nonmyeloablative method is described for induction of transplantation tolerance to fully mismatched bone marrow cells (BMC), bone marrow stromal precursors, heart muscle, and skin allografts. The method is based on pretransplant conditioning with no postgraft immunosuppression, and consists of a short course (six daily fractions of 200 cGy) of total lymphoid irradiation (sTLI), followed by selective elimination of donor-specific alloreactive cells of the host escaping low-dose sTLI. Donor-specific alloreactive cells were activated by intravenous inoculation with a high dose of donor BMC (3 x 10(7) cells) 1 day after sTLI, and eliminated by a single intraperitoneal dose (200 mg/kg) of cyclophosphamide given 1 day after cell transfer. Infusion of a low number of T cell-depleted BMC (3 x 10(6) cells) after tolerogenic preconditioning converted recipients to stable mixed chimeras free of graft-versus-host disease. The same treatment provided long-lasting acceptance of heterotopically transplanted allografts of the heart muscle and of the stromal precursors to the hematopoietic microenvironment. This treatment also led to acceptance and life-long survival of full-thickness donor skin allografts. However, skin allografts survived only in mice that received donor T cell-depleted BMC after cyclophosphamide and had 20-50% donor cells in the blood. Our results suggest that after sTLI, additional selective clonal deletion of residual host cells induces a state of long-lasting specific tolerance to a wide variety of donor-derived tissues.     

Tolerance induction ameliorates allograft vasculopathy in rat aortic transplants. Influence of Fas-mediated apoptosis

Based on successful induction of donor-specific unresponsiveness by alloantigenic stimulation in several animal models of acute rejection, we hypothesized that similar immune manipulations would also inhibit the evolution of chronic rejection and transplant vasculopathy. To induce immune tolerance, DA rats received a PVG heart allograft and were immunosuppressed with cyclosporine for 30 d. At day 100 the animals were challenged with a PVG aortic allograft after either 1 or 18 h of cold ischemia. 8 wk after the aortic transplantation, the grafts were investigated for morphological changes, infiltrating cells, apoptosis, and Fas-Fas ligand expression. Control allografts showed advanced transplant arteriosclerosis, whereas tolerance-induced aortic allografts displayed reduced neointimal formation, less medial atrophy, fewer apoptotic cells, and fewer Fas- and FasL-expressing cells. Prolonged ischemic storage time did not profoundly alter the morphological changes of the allografts. Fas expression was found in T cells, macrophages, vascular smooth muscle cells, and endothelial cells, whereas FasL was expressed mainly by T cells and macrophages. FasL mRNA expression was evident throughout the entire allograft wall. In conclusion, induction of allospecific tolerance can effectively prevent transplant arteriosclerosis. Cold ischemia damage does not abrogate the beneficial effect of tolerance, but creates a separate identity of mainly endothelial lesions. Furthermore, Fas-mediated apoptosis appears to be involved in the pathological lesions seen in chronic rejection.     

Long-term survival of hamster islet xenografts in mice under short-course treatment with nondepleting versus depleting anti-CD4 monoclonal antibodies

Xenogeneic grafts provide a potential alternative to the current shortage of human organs for transplantation. However, the prevention of rejection and tolerance induction of xenografts still remain to be further explored. Islet xenografts appear more promising than vascularized whole organ xenografts and additionally also more resistant to the recurrence of autoimmune disease than allografts. Recently, the nondepleting monoclonal antibody (mAb), which blocks the CD4 molecule on lymphocytes, was reported to be able to induce tolerance in allotransplantation and CD4 positive cells were further confirmed to be a major factor responsible for cellular xenograft rejection. Therefore, we hypothesize that anti-CD4 nondepleting mAb could also be effective in protecting cellular xenografts and inducing unresponsiveness of recipients. We studied the effect of the nondepleting anti-CD4 mAb YTS177.9 on islet xenograft survival by using the hamster-to-mouse islet transplantation model. Results were compared with that of the depleting anti-CD4 mAb GK1.5 that was shown to have similar binding sites on the CD4 molecule to mAb YTS177.9. Our data show that mAb YTS177.9 did effectively prolong the survival of islet xenografts and, in addition, also successfully did induce long-term acceptance of 40% grafts after only three perioperative injections of 0.5 mg mAb per mouse. The average survival of the graft was markedly prolonged to >66.8+/-37.1 days compared with controls (8.3+/-1.4 days) or with the depleting anti-CD4 mAb GK1.5 (25.7+/-5.5 days). However, the latter displayed a more profound inhibition in in vitro and ex vivo mixed lymphocyte xenoreaction than mAb YTS177.9. Moreover, the activity of this nondepleting mAb was found to be dose-dependent and 80% of grafts survived permanently when the dose was increased to six injections of 0.5 mg mAb. Like mAb GK1.5, mAb YTS177.9 also prevented rejection when given after a delay of two days posttransplant. In addition, we found that neither depleting nor nondepleting anti-CD8 mAb was effective in this model. Our results strongly suggest that an anti-CD4 nondepleting or blocking mAb alone is able to induce long-term acceptance of islet xenografts and that blocking the CD4 molecule is significantly superior to depleting CD4 positive cells for the protection of islet xenografts. This may indicate that CD4 cells play a major role in xenograft tolerance induction.     

Apoptosis as a mechanism of tissue injury in liver allograft rejection

Recent studies suggest that apoptosis is an important mechanism of cell death in the rejection of liver allografts and that infiltrating host lymphocytes mediate this process. The first section of this chapter addresses the cells and molecules that initiate the immune response following transplantation of a liver allograft. The recognition of donor alloantigens by infiltrating host lymphocytes stimulates a cascade of immune events which culminate in development of the effector cells that mediate tissue damage. Studies which demonstrate that apoptosis of hepatocytes and bile duct cells accompany allograft rejection are detailed in the second section of this chapter. The final section discusses the potential pathways which lead to apoptosis in liver allograft rejection. The contributions of the granule-exocytosis pathway, the Fas-mediated pathway, and cytokines to the induction of apoptosis in liver allografts are discussed. In addition, the concept that alloreactive graft infiltrating cells are deleted by apoptosis is presented. A further understanding of the mechanisms involved in apoptosis will lead to unique approaches toward the goal of achieving allograft tolerance.     

Accelerated rejection of Fas ligand-expressing heart grafts

The Fas/Fas ligand (FasL) system plays an important role in the induction of lymphoid apoptosis and has been implicated in the suppression of immune responses. Recently, there has been renewed interest in immune privilege, as it was shown that two privileged sites (the eye and testes) constitutively express FasL, which kills lymphoid cells that invade these areas. We have established murine FasL-transgenic mice (B6) under the control of the cardiac alpha-myosin heavy chain promotor, and transplanted FasL-expressing F1(B6 x C3H/HeJ) heart grafts into syngeneic (F1) and allogeneic (C3H/HeJ) recipients. FasL-expressing F1 heart allografts placed in C3H/HeJ recipients as well as FasL-expressing F1 isografts placed in nontransgenic and FasL-transgenic F1 were more rapidly rejected, and their survival was much shorter than that of nontransgenic control F1 allografts placed in C3H/HeJ. Native control and FasL-expressing hearts looked normal in mice up to 8 wk of age on hematoxylin-eosin staining. Control heart allografts undergoing ordinally acute rejection showed moderate focal lymphocyte infiltrates, while FasL-expressing F1 allografts and isografts showed massive hemorrhage, edema, and massive neutrophil infiltration as early as 1 day after transplantation. In conclusion, FasL expression and surgical procedure (ischemia/reperfusion) were synergistic in the induction of accelerated heart graft rejection, while allogenicity was not necessary. It may be necessary to find ways of controlling neutrophilic reaction/apoptosis in infiltrating lymphocytes to use FasL in clinical organ transplantation.     

Localization of Six4/AREC3 in the developing mouse retina; implications in mammalian retinal development

BACKGROUND: We designed an antisense phosphorothioate oligodeoxynucleotide (oligo) to specifically inhibit the expression of rat intercellular adhesion molecule-1 (ICAM-1) mRNA (IP-9125). METHODS: IP-9125 oligo was delivered intravenously by osmotic pump alone or in combination with cyclosporine (CsA) to recipients in order to prevent the rejection of kidney or heart allografts. In additional experiments, kidney allografts were perfused with IP-9125 before grafting. RESULTS: IP-9125 inhibited ICAM-1 mRNA and ICAM-1 protein expression in rat aortic endothelial cells; scrambled controls IP-12140 and IP-13944 were ineffective. Untreated ACI (RT1a) recipients rejected Lewis (RT1l) kidney allografts at a mean survival time of 8.5+/-1.1 days. A 14-day intravenous administration of 2.5 mg/kg/day IP-9125 prolonged the survival of kidney allografts to 39.2+/-16.4 days; 5.0 mg/kg/day, to 43.0+/-17.5 days; and 10.0 mg/kg/day, to 50.4+/-21.6 days. In contrast, a scrambled control IP-12140 was not effective. A combination of 10 mg/kg/day IP-9125 and 1.0 mg/kg/day CsA delivered for 14 days synergistically extended kidney allograft survival times 88.5+/-7.5 days. In contrast, the combination of 10.0 mg/kg/day control IP-12140 with CsA was ineffective (20.7+/-3.2 days) when compared with CsA alone (20.2+/-4.0 days). Similar results were obtained for heart transplants in recipients treated with IP-9125 alone or in combination with CsA. Furthermore, in situ immunostaining showed that IP-9125 significantly reduced the expression of ICAM-1 protein in kidney allografts. Finally, perfusion of kidney grafts alone with 20.0 mg per 2 ml of IP-9125 protected kidney allografts from rejection (37.5+/-7.5 days; P < 0.001), whereas perfusion with 20 mg per 2 ml of control IP-12140 was ineffective (12.6+/-5.0 days). CONCLUSIONS: Rat ICAM-1 IP-9125 oligo inhibits ICAM-1 protein expression in vitro and in vivo as well as blocks allograft rejection when used for pretreatment of donors, graft perfusion, or postoperative treatment of recipients.     

Immunosuppression by inhibition of cellular adhesion mediated by leukocyte function-associated antigen-1/intercellular adhesion molecule-1 in murine cardiac transplantation

BACKGROUND: Donor alloantigen-specific tolerance to vascularized allografts can be induced by several treatments, but the immunological mechanism(s) of these effects remain unclear. One hypothesis is that allograft unresponsiveness is correlated with a shift in the pattern of expression of the T helper 1 versus T helper 2 T-cell cytokines. We report here an extensive analysis of murine cardiac allografts, during normal first set rejection and in mice treated with anti-adhesion molecule monoclonal antibodies (mAbs), a regimen that results in prolonged unresponsiveness. METHODS: A combination of immunohistochemical staining with a panel of mAbs, and in situ hybridization with a panel of digoxigenin-labeled riboprobes, was performed on frozen-tissue sections of cardiac allografts. RESULTS: In several strain combinations, injection of anti-leukocyte function-associated antigen-1 and anti-intercellular adhesion molecule-1, from day 0 to day 6 after transplantation, results in significant long-term survival. Examination of tolerated cardiac allografts by in situ hybridization and immunohistochemical staining shows an altered cytokine expression pattern, although the frequency of CD3 and CD4 cells is not dramatically reduced. These allografts show a decreased frequency of interferon-gamma and interleukin (IL)-2-expressing cells and a slightly increased frequency of cells expressing IL-4 and IL-10, compared with unmodified acute rejection. A direct role of these changes in T-cell cytokine expression is demonstrated by reversal of tolerance induction and rejection of the allograft by in vivo injection of either anti-IL-10 or anti-IL-4 mAb. CONCLUSIONS: Although there are significant differences in the frequency of different cellular subsets and patterns of cytokine gene expression, these differences are quantitatively subtle, suggesting a delicately balanced immune response that can develop a pattern of specific unresponsiveness, with relatively minor alterations in the specific T-cell response.     

Pretransplant injection of allograft recipients with donor blood or lymphocytes permits allograft tolerance without the presence of persistent donor microchimerism

Donor-recipient microchimerism has recently been suggested to play a critical role in the induction and maintenance of allograft tolerance. In this study we sought evidence for this hypothesis using the LEW-to-ACI cardiac allograft as a model system. Donor-specific tolerance to cardiac allografts was induced by intravenous or intraportal injection of graft recipients with donor peripheral blood, T cells, or B cells 7 days before transplantation. All the graft recipients injected with donor antigens accepted donor heart grafts indefinitely when compared with control recipients that rejected donor allografts in 12 days. Long-term graft survivors rejected third-party BN heart allografts in 14 days without an adverse effect on the survival of the first LEW heart allografts, demonstrating the specificity of the tolerance. Tissue lysates prepared from heart, kidney, liver, bone marrow, thymus, lymph nodes, and spleen of tolerant (>120 days) graft recipients were analyzed for the presence of donor DNA using LEW T cell receptor C beta gene-specific primers for polymerase chain reaction that detects donor DNA at > or = 1:10,000 dilution. Donor DNA was detected in 77% of tolerant graft recipients. Chimeric recipients showed variations in the levels and presence of donor DNA in different tissues. The status of donor microchimerism, with respect to its presence and tissue distribution, was dependent upon the donor cell type and route of injection used for the induction of tolerance. Intraportal injection of the graft recipients with donor peripheral blood resulted in the highest degree of chimerism, whereas intravenous injection with donor B cells did not induce detectable microchimerism in this group of recipients. These data clearly demonstrate that the presence of microchimerism is common following administration of donor cells, but that its presence is not an absolute requirement for the long-term survival of allografts.     

A new rat infection-heart transplant model: effect of infection on graft survival studies

Considerable progress has been made in survival rates of heart transplant recipients; however, infections continue to be a major cause of death after transplantation. Although infection itself appears to cause immunologic suppression in some nontransplantation studies, the lack of an infection-transplant animal model has limited further investigation of this observation. We evaluated the utility of a heterotopic rat infection heart-transplant model by studying the effect of infection and limited administration of two immunosuppressive agents, cyclosporine and FK506, on allograft rejection and survival. Lewis rats received ACI heart allografts, and intraperitoneal infection was induced by cecal ligation. Infection was confirmed by blood and ascitic fluid cultures. Results showed that graft survival was slightly, but significantly, higher (p < 0.05) in group II (transplantation with infection) when compared to the control group I (transplantation only). Histologic rejection scores were less (p < 0.05) in group II 6 days after transplantation. The second phase of the study compared the effect of infection after transplantation in rats given a 1-week course of cyclosporine or FK506, which were discontinued after the induction of infection. Although the cyclosporine group had prolonged survival when compared to the FK506 group (p < 0.05), the respective infection groups receiving immunosuppression revealed no significant difference in allograft survival or histologic rejection scores when compared to the control groups. In this preliminary study, infection without immunosuppression resulted in a slight, but statistically significant, increase in allograft survival and reduced acute cellular rejection. In those groups receiving immunosuppressive agents, no additive immunosuppressive effect was attributable to bacterial infection.(ABSTRACT TRUNCATED AT 250 WORDS)     

Tolerance to rat liver allografts: IV. Acceptance depends on the quantity of donor tissue and on donor leukocytes

Liver allografts in some rat strains are often spontaneously accepted across a complete major histocompatibility barrier without the requirement for immunosuppression while other nonliver allografts are rejected. In previous studies, we have shown that spontaneous acceptance is dependent on liver passenger leukocytes. Depletion of passenger leukocytes by donor irradiation allows rejection, with DA recipients of irradiated PVG livers having a median survival time (MST) of 16 days. Here we show that, in this model, spontaneous acceptance is reconstituted by intravenous injection of donor leukocytes. Intravenous injection of 3-5x10(7) PVG liver leukocytes significantly prolonged DA survival time (MST=96 days, P=0.026), as did 5x10(7) spleen leukocytes (MST>100 days, P=0.002). Deletion of T cells from the reconstituting inoculum reduced survival time (MST=78 days, P=0.039), whereas deletion of B cells or monocytes/macrophages had no effect on survival time. In contrast, PVG hearts are regularly rejected by DA recipients, and PVG liver or spleen leukocytes, even at doses of greater than 3x10(8) cells/recipient, were unable to induce heart acceptance. To investigate the possibility that acceptance of the irradiated liver but not the heart might be due to the large mass of the liver, two kidneys and two hearts of PVG origin were transplanted to each DA recipient together with 1.5x10(8) PVG leukocytes. These organs survived for greater than 200 days, thereby showing that a large mass of donor tissue, in association with donor leukocytes, leads to acceptance of organs that are rejected if transplanted singly. It appears likely that spontaneous liver transplant tolerance is a high-dose or activation-associated immune phenomenon.     

The thymic way to transplantation tolerance

Within the past three decades, extensive research has been carried out with the aim to prevent graft rejection by minimizing the side effects related to the use of immunosuppressants. The major goal in transplantation research remains the development of strategies that would allow one to achieve a state of donor-specific unresponsiveness in order to promote a condition of true tolerance without the need of immunosuppressants. Recent evidence has been provided that this is a pursuing goal, at least in experimental animals. The thymus plays the major role in the development of self-tolerance, and initial work in the late 1960s indicated that the thymus also plays a critical role in the induction of acquired tolerance to exogenous antigens. Recently, the interest in acquired thymic tolerance has been renewed by the observation that, in the rat, the thymus is an immunologically privileged site in which isolated pancreatic islets can be engrafted and survive indefinitely. Moreover, intrathymic injection of the islets induced donor-specific unresponsiveness, which allowed survival of a second donor-strain islet cell allograft transplanted into an extrathymic site. These findings on cellular allografts have been extended to vascularized organ allografts.(ABSTRACT TRUNCATED AT 250 WORDS)     

Diastolic dysfunction coincides with early mild transplant rejection: in situ measurements in a heterotopic rat heart transplant model

BACKGROUND: Diastolic dysfunction seen in early clinical transplant rejection has been difficult to demonstrate in experimental rodent models because of the inability to make sensitive in situ measurements of systolic and diastolic functions. We have developed a heterotopic heart transplant model with Fisher 344 and ACI rats (without immunosuppression), where in situ measurements of diastolic and systolic functions were made sequentially (daily) by use of an implanted left ventricular balloon. METHODS: Syngeneic and allogeneic heterotopic heart transplants were performed. In situ function was determined by varying balloon volume to measure the developed pressure, the rates of pressure rise (+dp/dt) and pressure fall (-dp/dt), diastolic pressure-volume relationship, and the time constant of diastolic relaxation (tau). These results were compared with function measurements in transplanted hearts that were excised and perfused in a Langendorff mode (ex vivo) during the same posttransplantation period. RESULTS: Histologic examination revealed that at day 3 after transplantation, allografts showed mild lymphocytic infiltration indicative of mild or early rejection, and by day 5, there was severe rejection with myocyte necrosis. By day 3, the slope of the diastolic pressure-volume relationship (ie, left ventricular stiffness) was significantly higher in allografts as compared with isografts (436 +/- 96 vs 177 +/- 26 mm Hg/mL, p < .05). Similarly, tau was significantly longer in allografts by day 3 after transplantation. Developed pressure and +dp/dt became significantly lower in allografts beginning on day 6. Function measurements made in the isolated perfused ex vivo hearts yielded the same results at day 3 after transplantation as the in situ group of hearts. CONCLUSION: Using a chronically implanted left ventricular balloon, we have developed a heterotopic heart transplant model where sensitive measurements of systolic and diastolic functions can be made. With this preparation, the early changes in the diastolic dysfunction seen clinically can be reproducibly detected. Thus this model may be useful to study mechanisms and interventions during early transplant rejection.     

Rejection of cardiac allografts by T cells expressing a restricted repertoire of T-cell receptor V beta genes

We have recently shown that T cells infiltrating cardiac allografts early in graft rejection use a limited T-cell receptor (TCR) V beta repertoire. In this study we tested whether this limited repertoire of V beta genes is important for graft rejection. A cell line, AL2-L3, was established from LEW lymphocytes infiltrating ACI heart allografts 2 days after transplantation. This cell line is composed of CD4+ T cells that primarily recognize the class II RTI.B major histocompatibility complex (MHC) molecule expressed by the donor graft. This cell line precipitated acute rejection of donor hearts with a median survival time (MST) of 10.5 days following adoptive transfer to sublethally irradiated LEW recipients. This rate of graft rejection was significantly (P < 0.0007) accelerated when compared with a MST of 60 days for allografts in irradiated control recipients. The AL2-L3-mediated acceleration of graft rejection was donor specific as WF third-party heart allografts were rejected with a delayed tempo (MST = 28.5 days). The V beta repertoire of this cell line was primarily restricted to the expression of V beta 4, 15 and 19 genes. The nucleotide sequence analysis of the beta-chain cDNAs from this cell line demonstrated that the restricted use of the V gene repertoire was not shared with the N, D and J regions. A wide variety of CDR3 loops and J beta genes were used in association with selected V beta genes. These data provide evidence for the role a restricted repertoire of V beta genes plays in cardiac allograft rejection in this model. The restricted usage of the V beta repertoire in an early T-cell response to allografts may provide the opportunity to therapeutically disrupt the rejection reaction by targeting selected T-cell populations for elimination at the time of organ transplantation.     

A nonlethal conditioning approach to achieve engraftment of xenogeneic rat bone marrow in mice and to induce donor-specific tolerance

BACKGROUND: The supply of solid organs for transplantation will never meet the growing demand. Xenotransplantation is considered to be a potential solution for the critical shortage of allografts. However, xenograft rejection is currently not controlled by conventional immunosuppressive agents. Bone marrow chimerism induces donor-specific tolerance without the requirement for chronic immunosuppressive therapy. The aim of this study was to develop a nonlethal recipient-conditioning approach to achieve mixed bone marrow chimerism and donor-specific tolerance. METHODS: C57BL/10SnJ mice were conditioned with total body irradiation followed by a single injection of cyclophosphamide on day +2. On day 0, mice were reconstituted with untreated bone marrow cells from Fischer 344 rats. Recipients were analyzed by flow cytometry for donor bone marrow engraftment and multilineage chimerism. Donor-specific tolerance was tested by skin grafting. RESULTS: One hundred percent of recipients engrafted after irradiation with 600 cGy total body irradiation, transplantation with 80 x 10(6) Fischer 344 bone marrow cells, and injection with 50 mg/kg cyclophosphamide intraperitoneally. Donor chimerism was detectable in all engrafted animals for up to 11 months. This conditioning was nonlethal, because conditioned untransplanted animals survived indefinitely. Mixed xenogeneic chimeras were tolerant to donor-specific skin grafts but rejected third-party (Wistar Furth) grafts as rapidly as naive C57BL/10SnJ mice. In contrast, animals that received less efficacious conditioning regimens and did not exhibit detectable chimerism showed prolonged graft survival, but delayed graft rejection occurred in all animals within 10 weeks. CONCLUSION: The induction of bone marrow chimerism and donor-specific tolerance after nonlethal conditioning might be useful to prevent the vigorous cellular and humoral rejection response to xenografts.     

Volume recruitment and oxygenation in pulmonary edema: a comparison between HFOV and CMV

Although the transplanted human liver is susceptible to rejection with a similar incidence of rejection as seen with renal allografts, the liver enjoys many immunological benefits relative to other transplanted organs. These include relative resistance to antibody-mediated injury, low frequency of chronic rejection, relatively easy reversibility of acute rejection, and even reversibility of chronic rejection. The reasons for the liver's favored status from an immunological perspective are unclear but are perhaps multifactorial. Currently used clinical protocols of immunosuppression for liver transplantation rely principally on the calcineurin inhibitors, cyclosporine and FK-506. Steroid withdrawal at variable periods after liver transplantation is becoming increasingly common. Compared with other organ transplants, relatively few human liver transplants are lost because of rejection. The transplanted liver may be an appropriate target for tolerance studies.     

Specific tolerance induction and transplantation: a single-day protocol

Bone marrow transfusion is a well-established method for induction of mixed hematopoietic chimerism and donor-specific tolerance in animal models. This procedure, however, is inapplicable in clinical transplantation using cadaveric donors due to the interval (1 week to 7 months) between tolerance induction and organ transplantation. For clinical use, it is essential that allografts be placed at the time of bone marrow transfusion. In the present study, we performed skin transplantation within 1 hour after a nonlethal conditioning regimen. Recipient mice were treated with anti-CD3, anti-CD4, low-dose total body irradiation (3 to 6 Gy TBI) and fully mismatched or haploidentical donor bone marrow cells. Stable multilineage chimerism and specific T-cell nonresponsiveness developed. Donor skin grafts were permanently accepted. These results suggest that this single day protocol has clear potential for application in both cadaveric and living-related organ transplantation.