Adoptive Transfer of Renal Allograft Tolerance in a Large Animal Model.

Our recent studies in an inbred swine model demonstrated that both peripheral and intra-graft regulatory cells were required for the adoptive transfer of tolerance to a second, naïve donor-matched kidney. Here, we have asked whether both peripheral and intra-graft regulatory elements are required for adoptive transfer of tolerance when only a long-term tolerant (LTT) kidney is transplanted. Nine highly-inbred swine underwent a tolerance-inducing regimen to prepare LTT kidney grafts which were then transplanted to histocompatible recipients, with or without the peripheral cell populations required for adoptive transfer of tolerance to a naïve kidney. In contrast to our previous studies, tolerance of the LTT kidney transplants alone was achieved without transfer of additional peripheral cells and without strategies to increase the number/potency of regulatory T cells in the donor. This tolerance was systemic, since most subsequent, donor-matched challenge kidney grafts were accepted. These results confirm the presence of a potent tolerance-inducing and/or tolerance-maintaining cell population within LTT renal allografts. They suggest further that additional peripheral tolerance mechanisms, required for adoptive transfer of tolerance to a naïve donor-matched kidney, depend on peripheral cells that, if not transferred with the LTT kidney, require time to develop in the adoptive host.

High incidence of xenogenic bone marrow engraftment in pig-to-baboon intra-bone bone marrow transplantation.

Previous attempts of α-1,3-galactocyltransferase knockout (GalTKO) pig bone marrow (BM) transplantation (Tx) into baboons have demonstrated a loss of macro-chimerism within 24 h in most cases. In order to achieve improved engraftment with persistence of peripheral chimerism, we have developed a new strategy of intra-bone BM (IBBM) Tx. Six baboons received GalTKO BM cells, with one-half of the cells transplanted into the bilateral tibiae directly and the remaining cells injected intravenously (IBBM/BM-Tx) with a conditioning immunosuppressive regimen. In order to assess immune responses induced by the combined IBBM/BM-Tx, three recipients received donor SLA-matched GalTKO kidneys in the peri-operative period of IBBM/BM-Tx (Group 1), and the others received kidneys 2 months after IBBM/BM-Tx (Group 2). Peripheral macro-chimerism was continuously detectable for up to 13 days (mean 7.7 days; range 3-13) post-IBBM/BM-Tx and in three animals, macro-chimerism reappeared at days 10, 14 and 21. Pig CFUs, indicating porcine progenitor cell engraftment, were detected in the host BM in four of six recipients on days 14, 15, 19 and 28. In addition, anti-pig unresponsiveness was observed by in vitro assays. GalTKO/pCMV-kidneys survived for extended periods (47 and 60 days). This strategy may provide a potent adjunct for inducing xenogeneic tolerance through BM-Tx.

Transgenic expression of human CD47 markedly increases engraftment in a murine model of pig-to-human hematopoietic cell transplantation.

Mixed chimerism approaches for induction of tolerance of solid organ transplants have been applied successfully in animal models and in the clinic. However, in xenogeneic models (pig-to-primate), host macrophages participate in the rapid clearance of porcine hematopoietic progenitor cells, hindering the ability to achieve mixed chimerism. CD47 is a cell-surface molecule that interacts in a species-specific manner with SIRPα receptors on macrophages to inhibit phagocytosis and expression of human CD47 (hCD47) on porcine cells has been shown to inhibit phagocytosis by primate macrophages. We report here the generation of hCD47 transgenic GalT-KO miniature swine that express hCD47 in all blood cell lineages. The effect of hCD47 expression on xenogeneic hematopoietic engraftment was tested in an in vivo mouse model of human hematopoietic cell engraftment. High-level porcine chimerism was observed in the bone marrow of hCD47 progenitor cell recipients and smaller but readily measurable chimerism levels were observed in the peripheral blood of these recipients. In contrast, transplantation of WT progenitor cells resulted in little or no bone marrow engraftment and no detectable peripheral chimerism. These results demonstrate a substantial protective effect of hCD47 expression on engraftment and persistence of porcine cells in this model, presumably by modulation of macrophage phagocytosis.

Results of gal-knockout porcine thymokidney xenografts.

Clinical transplantation for the treatment of end-stage organ disease is limited by a shortage of donor organs. Successful xenotransplantation could immediately overcome this limitation. The development of homozygous alpha1,3-galactosyltransferase knockout (GalT-KO) pigs removed hyperacute rejection as the major immunologic hurdle to xenotransplantation. Nevertheless, GalT-KO organs stimulate robust immunologic responses that are not prevented by immunosuppressive drugs. Murine studies show that recipient thymopoiesis in thymic xenografts induces xenotolerance. We transplanted life-supporting composite thymokidneys (composite thymus and kidneys) prepared in GalT-KO miniature swine to baboons in an attempt to induce tolerance in a preclinical xenotransplant model. Here, we report the results of seven xenogenic thymokidney transplants using a steroid-free immunosuppressive regimen that eliminated whole-body irradiation in all but one recipient. The regimen resulted in average recipient survival of over 50 days. This was associated with donor-specific unresponsiveness in vitro and early baboon thymopoiesis in the porcine thymus tissue of these grafts, suggesting the development of T-cell tolerance. The kidney grafts had no signs of cellular infiltration or deposition of IgG, and no grafts were lost due to rejection. These results show that xenogeneic thymus transplantation can support early primate thymopoiesis, which in turn may induce T-cell tolerance to solid organ xenografts.

Highly disparate xenogeneic skin graft tolerance induction by fetal pig thymus in thymectomized mice: Conditioning requirements and the role of coimplantation of fetal pig liver.

BACKGROUND: Highly disparate xenogeneic pig skin graft tolerance and efficient repopulation of mouse CD4+ T cells are achieved in thymectomized (ATX) B6 mice that receive T cell and natural killer (NK) cell depletion by injection of a mixture of monoclonal antibodies (mAbs) (GK1.5, 2.43, 30-H12, and PK136) on days -6, -1, +7, and +14 and 3 Gy total body irradiation (TBI) followed by implantation of fetal pig thymus/liver (FP THY/LIV) grafts on day 0. The requirements for each treatment in this model to achieve pig skin graft tolerance have not previously been defined. Therefore, we performed a series of experiments to address the role of each treatment in achieving maximal skin graft tolerance. METHODS: Peripheral mouse CD4+ T-cell repopulation and pig skin graft survival were followed in this pig-to-mouse model in which recipient B6 mice were treated with modified regimens that omitted thymectomy, 3 Gy TBI, anti-Thy1.2, and anti-NK1.1 mAbs, injection of a mixture of mAbs on day +14, or coimplantation of FP LIV, respectively. RESULTS: Prolongation but not permanent survival of donor MHC-matched pig skin grafts was observed in euthymic B6 mice that received T and NK cell depletion, 3 Gy TBI, and 7 Gy thymic irradiation and FP THY/LIV in the mediastinum, suggesting that full xenogeneic tolerance was not achieved in euthymic mice. However, after grafting FP THY alone to ATX B6 mice treated either with the "standard" regimen, or with a conditioning regimen that omitted all components of the conditioning regimen except treatment with anti-CD4 and anti-CD8 mAbs, efficient peripheral repopulation of mouse CD4+ T cells and long-term donor MHC-matched pig skin graft acceptance were observed. CONCLUSIONS: Highly disparate xenogeneic pig skin graft tolerance can be achieved by grafting FP THY alone in anti-CD4 and anti-CD8 mAb-treated ATX B6 mice, but not in euthymic B6 mice. Additional treatment of ATX recipient mice with anti-Thy1.2 and NK1.1 mAbs and 3 Gy TBI is not essential for donor pig skin graft tolerance induction.

Enhanced CD4 reconstitution by grafting neonatal porcine tissue in alternative locations is associated with donor-specific tolerance and suppression of preexisting xenoreactive T cells.

BACKGROUND: Donor-specific xenograft tolerance can be achieved by grafting fetal porcine thymus tissue to thymectomized (ATX) mice treated with natural killer (NK) and T-cell-depleting monoclonal antibodies plus 3 Gy of total body irradiation (TBI). Grafting of neonatal, instead of fetal, thymus, along with neonatal pig spleen, leads to a lower level of mouse CD4 cell reconstitution, with less reliable tolerance induction. For a number of reasons, it would be advantageous to use neonatal rather than fetal pigs as donors. We therefore investigated the possibility that grafting larger amounts of neonatal porcine thymus tissue to different sites could allow improved outcomes to be achieved. MATERIALS AND METHODS: Multiple or single fragments of neonatal porcine thymus tissue were grafted with a splenic fragment to different sites (mediastinum, mesentery, and kidney capsule) of ATX B6 mice treated with T- and NK-cell-depleting antibodies and 3Gy TBI. Mice also received an intraperitoneal injection containing 1 x 10(7) donor splenocytes. Donor-specific skin graft tolerance was evaluated, and CD4 reconstitution and mouse anti-donor xenoantibodies were followed by flow cytometry. RESULTS: Peripheral repopulation of CD4+ cells occurred by 7 weeks after transplantation in mice grafted with four fragments of neonatal porcine tissue in either the mediastinum or the mesentery, but not in mice grafted under both kidney capsules with the same amount of tissue. The level of CD4 reconstitution correlated with skin graft tolerance and an absence of induced anti-donor xenoantibodies. Seventy-five percent of mice with >20% of CD4+ cells among peripheral blood lymphocytes (PBL) by 13 weeks posttransplantation accepted donor porcine skin, while rejecting either non-donor neonatal porcine or mouse BALB/c skin allografts. In contrast, only 29% of grafted mice with <20% CD4+ cells in the peripheral blood at 13 weeks accepted donor porcine skin. Grafted mice with poor reconstitution showed either low or high levels of anti-pig xenoantibodies of the IgM, IgG1, and IgG2a isotypes. Grafted mice with >20% CD4+ cells all had low levels of anti-pig xenoantibodies of these isotypes and displayed mixed lymphocyte reaction (MLR) tolerance to donor pig major histocompatibility complex (MHC), with responsiveness to allogeneic mouse stimulators. CONCLUSION: Grafting neonatal porcine thymus into either the mediastinum or mesentery provides earlier and more efficient reconstitution of the CD4 compartment than does grafting under the kidney capsule. Good CD4 reconstitution was associated with optimal donor-specific skin graft tolerance and avoidance of the anti-donor xenoantibody responses observed in mice with poor CD4 reconstitution. These results also suggest that there is a suppressive component to the porcine xenograft tolerance induced with this approach.

Morphometric analysis of miniature swine hearts as potential human xenografts.

Miniature swine are considered to be potential donors for clinical cardiac transplantation. However, it is unclear how an appropriately sized porcine donor will be selected for a particular human recipient. To address this issue, we performed a morphometric study of the swine heart using transthoracic echocardiography (n = 26) to determine the diameters of the aortic annulus and root, pulmonary artery annulus, and mitral valve annulus. We also obtained direct ex vivo measurements of swine heart weight and linear dimensions (n = 71). Relationships between a swine's height, weight, length, chest circumference and these internal and external cardiac dimensions are described. The strongest correlations were found between a pig's body length and its aortic annulus and root diameters (r-values = 0.97). These relationships are accurately described by univariate linear regression models. By cross-relating our morphometric measurements of aortic annulus diameter in the miniature swine with normative human data, we were able to develop a nomogram, relating swine length and human height, which predicts which miniature swine would donate the best size-matched heart for a particular human recipient.

Maturation and function of mouse T-cells with a transgenic TCR positively selected by highly disparate xenogeneic porcine MHC.

Remarkably normal cellular immune function, along with specific T-cell tolerance to highly disparate xenogeneic donors, can be achieved by grafting fetal pig thymus (FP THY) tissue to T and NK cell-depleted, thymectomized (ATX) mice. Porcine MHC can mediate positive selection of mouse CD4+ T-cells with a mouse MHC-restricted TCR in FP THY-grafted, T- and NK cell-depleted, ATX TCR-transgenic "AND" mice. However, functional studies were not performed on transgenic mouse T-cells selected in a FP THY graft. We have now performed further studies to confirm the ability of porcine MHC to mediate the positive selection of mouse T-cells with a mouse MHC-restricted TCR, and to exclude the possibility that the maturation of mouse T-cells with a mouse MHC-restricted TCR in FP THY grafts in ATX "AND" mice is a special case. For this purpose, TCR-transgenic mice with an unrelated transgenic TCR ["3A9", specific for hen egg lysozyme (HEL) peptide 46-61 presented by I-Ak] were employed. Similar to FP THY-grafted ATX "AND" mice, large numbers of mouse CD4 single positive thymocytes expressing the transgenic TCR (Vbeta8.2) and expressing a mature phenotype (Qa-2high and heat stable antigen, HSAlow) were detected in FP THY grafts. Porcine thymus grafting led to a high level of peripheral repopulation with mouse naive-type (CD44low CD45RBhigh CD62Lhigh) CD4+ cells expressing the transgenic TCR in T and NK cell-depleted ATX "3A9" mice, regardless of whether the recipients had a positive selecting or a non-selecting, class II deficient MHC background. The mouse CD4+ T-cells expressing the "3A9" TCR showed efficient primary proliferative responses to the protein antigen (HEL) when it was presented by mouse class II+ antigen presenting cells (APC) in vitro. These results, collectively, support the general conclusion that discordant xenogeneic porcine MHC can mediate positive selection of mouse T-cells with mouse MHC-restricted TCR. This study has implications for the potential clinical use of xenogeneic thymus transplantation to reconstitute cellular immunity in the setting of thymic insufficiency or thymectomy, and hence for its applicability to the induction of xenograft tolerance and in the treatment of immunodeficiency diseases.

The critical role of mouse CD4+ cells in the rejection of highly disparate xenogeneic pig thymus grafts.

Long-term survival of fetal pig thymus (FP THY) grafts and efficient repopulation of mouse CD4+ T cells is achieved in thymectomized (ATX) B6 mice that receive T and NK cell depletion by injection of a cocktail of mAbs (GK1.5, 2.43, 30-H12, and PK136) and fetal pig thymus/liver (FP THY/LIV) grafts. The requirement for each mAb in this conditioning regimen in order to avoid the rejection of FP THY grafts has not yet been defined. In our present studies, CD4 cell-depleted ATX B6 mice and euthymic MHC class II-deficient (IIKO) mice were employed to investigate the role of mouse CD4+ cells in the rejection of FP THY grafts in vivo. After grafting FP THY/LIV to CD4+ cell-depleted ATX B6 mice, efficient repopulation of mouse CD4+ T cells was observed in the periphery. However, only two of four mice had remaining FP THY grafts by 17 weeks post-implantation, and these were of poor quality, whereas four of four T and NK cell-depleted ATX B6 mice had well-developed FP THY grafts. Furthermore, three of four FP THY/LIV-grafted, CD4+ cell-depleted ATX B6 mice rejected donor MHC-matched pig skin grafts. In contrast, three of three FP THY/LIV grafted, T and NK cell-depleted, ATX B6 mice accepted donor MHC-matched pig skin grafts, suggesting that optimal tolerance to xenogeneic pig antigens was not achieved in mice conditioned only with anti-CD4 mAb. ATX B6 mice treated with only anti-CD8 mAb rejected FP THY completely by 6 weeks post-grafting, a time when CD4+ cell-depleted ATX B6 mice had well-vascularized FP THY grafts. In addition, when euthymic IIKO mice were pre-treated with the standard conditioning regimen that includes four different mAbs, FP THY grafts survived and supported the repopulation of mouse CD4+ T cells in the periphery, while high levels of mouse CD8+ T cells developed in host thymi. These studies suggest that mouse CD4+ T cells play a critical role in the acute rejection of xenogeneic FP THY grafts. Without help from CD4+ cells, mouse CD8+ cells, NK, NK/T, and TCR(gamma/delta)+ T cells do not mediate acute rejection of FP THY grafts. Furthermore, our results suggest that other cell subsets besides CD4+ T cells play a role in the delayed rejection of highly disparate xenogeneic FP THY grafts.

The induction of specific pig skin graft tolerance by grafting with neonatal pig thymus in thymectomized mice.

BACKGROUND: Xenogeneic donor-specific tolerance can be induced by transplanting fetal pig thymus and liver tissue (FP THY/LIV) to thymectomized (ATX), T/NK cell-depleted mice. By using neonatal pig tissue, we hoped to overcome two obstacles that arise with the use of fetal pig tissue: (1) the inability to keep fetal pigs alive after harvesting their thymic tissue, resulting in unavailability of their skin or other organs for grafting; and (2) the limited fetal thymic tissue yield, making application to large animals and humans more difficult. METHODS: Neonatal pig thymus tissue (NP THY) was grafted into ATX, T/NK cell-depleted, 3Gy whole body-irradiated, originally immunocompetent B6 mice to evaluate the ability of NP THY to reconstitute mouse CD4+ T cells and to induce xenogeneic tolerance to donor pig skin grafts. RESULTS: Repopulation of mouse CD4+ T cells in the peripheral tissues was observed in T/NK cell-depleted, ATX B6 mice that received NP THY with or without neonatal pig spleen (NP SPL), but not in those receiving NP SPL alone, indicating that pig thymus grafting was necessary and sufficient for mouse T cell recovery. Seven of nine NP THY/SPL-grafted ATX mice and two of six NP THY-grafted ATX mice that reconstituted >5% CD4+ cells in PBL accepted donor pig skin long-term without lymphocyte infiltration, whereas they rejected allogeneic BALB/c skin and third party pig skin grafts as rapidly as euthymic mice. CONCLUSIONS: NP THY can support the development of mouse CD4+ T cells that are functional and specifically tolerant to donor pig antigens in ATX, T/NK cell-depleted, 3 Gy whole body-irradiated, originally immunocompetent B6 mice. Additional grafting of NP SPL with NP THY improves the efficiency of tolerance induction in this model.

Blockade of CD28-B7, but not CD40-CD154, prevents costimulation of allogeneic porcine and xenogeneic human anti-porcine T cell responses.

Despite increasing use of swine in transplantation research, the ability to block costimulation of allogeneic T cell responses has not been demonstrated in swine, and the effects of costimulatory blockade on xenogeneic human anti-porcine T cell responses are also not clear. We have compared the in vitro effects of anti-human CD154 mAb and human CTLA4IgG4 on allogeneic pig T cell responses and xenogeneic human anti-pig T cell responses. Both anti-CD154 mAb and CTLA4IgG4 cross-reacted on pig cells. While anti-CD154 mAb and CTLA4IgG4 both inhibited the primary allogeneic pig MLRs, CTLA4IgG4 (7.88 microg/ml) was considerably more inhibitory than anti-CD154 mAb (100 microg/ml) at optimal doses. Anti-CD154 mAb inhibited the production of IFN-gamma by 75%, but did not inhibit IL-10 production, while CTLA4IgG4 completely inhibited the production of both IFN-gamma and IL-10. In secondary allogeneic pig MLRs, CTLA4IgG4, but not anti-CD154 mAb, induced Ag-specific T cell anergy. CTLAIgG4 completely blocked the indirect pathway of allorecognition, while anti-CD154 mAb blocked the indirect response by approximately 50%. The generation of porcine CTLs was inhibited by CTLA4IgG4, but not by anti-CD154 mAb. Human anti-porcine xenogeneic MLRs were blocked by CTLA4IgG4, but only minimally by anti-CD154 mAb. Finally, CTLA4IgG4 prevented secondary xenogeneic human anti-porcine T cell responses. These data indicate that blockade of the B7-CD28 pathway was more effective than blockade of the CD40-CD154 pathway in inhibiting allogeneic pig T cell responses and xenogeneic human anti-pig T cell responses in vitro. These findings have implications for inhibiting cell-mediated immune responses in pig-to-human xenotransplantation.

Characterization of a monoclonal anti-porcine CD3 antibody.

Partially inbred miniature swine have been developed in this laboratory as a large animal model for studies related to transplantation tolerance and as a source of hematopoietic cells and organs for xenotransplantation. The identification of swine CD3 specific mAbs capable of activating or depleting T cells in vitro and inducing an immunosuppressive state in vivo greatly facilitates studies of the swine immune system, transplantation tolerance and xenotransplantation research. Flow cytometry was used to determine the phenotypic profile of the swine specific mAb 898H2-6-15 (2-6-15). The specificity of 2-6-15 was further defined biochemically by surface labeling and immunoprecipitation. The ability of this mAb to activate pig T cells in vitro was examined by several criteria including proliferation assays, calcium flux analysis and detection of surface CD25 upregulation by fluorescence activated cell sorter (FACS) analysis. Monoclonal antibody 898H2-6-15 is specific for swine CD3 and is capable of inducing proliferation and CD25 upregulation in cultured swine peripheral blood lymphocytes. In addition, it induces calcium flux in purified pig T cells. Surprisingly, in contrast to described antibodies to CD3 in swine and other species, the binding of this antibody to porcine CD3 is dependent on the presence of extracellular calcium. Thus calcium was required in order to immunoprecipitate labeled surface molecules for biochemical analysis and to stain cell surfaces for FACS analysis of swine lymphocytes. In this paper, we describe a new swine CD3 specific mAb, 898H2-6-15 (2-6-15) the characteristics of which make it an extremely useful tool for in vitro and in vivo studies of the swine immune system and xenotransplantation. The availability of swine T cell specific reagents should facilitate the monitoring of swine T cell engraftment and/or release amongst xenogeneic mixed chimeras and thymic transplant recipients as well as provide a means to treat potential GvHD across xenogeneic barriers. We are currently evaluating the in vivo effects of 2-6-15 in the pig.

Normal development in porcine thymus grafts and specific tolerance of human T cells to porcine donor MHC.

The induction of T cell tolerance is likely to play an essential role in successful xenotransplantation in humans. In this study, we show that porcine thymus grafts in immunodeficient mice support normal development of polyclonal, functional human T cells. These T cells were specifically tolerant to MHC Ags of the porcine thymus donor and responded to nondonor porcine xenoantigens and alloantigens. Exogenous IL-2 did not abolish tolerance, suggesting central clonal deletion rather than anergy as the likely tolerance mechanism. Our study suggests that the thymic transplantation approach to achieving tolerance with restoration of immunocompetence may be applicable to xenotransplantation of pig tissues to humans.

Mechanism of tolerance to class I-mismatched renal allografts in miniature swine: regulation of interleukin-2 receptor alpha-chain expression on CD8 peripheral blood lymphocytes of tolerant animals.

BACKGROUND: Donor-specific tolerance to renal allografts in miniature swine is uniformly induced across a two-haplotype class I plus minor histocompatibility antigen disparity by a 12-day course of cyclosporine. Recent studies have demonstrated that the thymus is essential for rapid and stable tolerance induction, because either prior thymectomy or a series of thymic biopsies induce a spontaneously reversible rejection crisis after the 12-day course of cyclosporine. The present study examined the peripheral cellular mechanisms of tolerance by analyzing cytotoxic effector pathways in peripheral blood lymphocytes (PBL) of tolerant animals. METHODS: The phenotype and cytotoxic T lymphocyte response of alloantigen-activated PBL cultures using cells from a series of tolerant animals with stable renal function (no thymic manipulation), or during a rejection crisis (induced by thymic biopsies), were studied. The in vitro findings were correlated with the in vivo clinical course of experimental animals. RESULTS: The data demonstrated that in vivo and in vitro tolerance was associated with a specific deficiency of interleukin-2 receptor (IL-2R) alpha-chain up-regulation on CD8 single-positive (SP) T cells expressing high levels of CD8 (CD8high) when PBL from tolerant animals are stimulated with donor class I alloantigen. Stimulation by third party class I alloantigen, or by donor antigen during a rejection crisis, produced efficient cytotoxic T lymphocyte responses and expression of IL-2Ralpha on CD8high SP cells. CONCLUSION: Antigen-specific regulation of the IL-2Ralpha expression on CD8high SP PBL is a principal event associated with and potentially involved in the mechanism of tolerance in this preclinical large animal model.

Cardiac allograft vasculopathy is abrogated by anti-CD8 monoclonal antibody therapy.

BACKGROUND: Cardiac allograft vasculopathy, a diffuse and accelerated form of arteriosclerosis, is a major cause of graft loss or heart transplant recipient death after the first transplant year. This study examined the effects of depleting host CD8 + T lymphocytes on the development of cardiac allograft vasculopathy in miniature swine. METHODS: Cardiac allografts were heterotopically transplanted across a major histocompatibility complex class I barrier in partially inbred miniature swine and monitored for rejection by serial biopsies, electrocardiograms, and echocardiograms. Four control animals received cyclosporine on postoperative days 0 to 11. Another four miniswine were given 14.5 mg/kg of 76-2-11 (a mouse anti-swine CD8 monoclonal antibody) on postoperative day 0, in addition to a 12-day course of cyclosporine. Host CD8+ T cells and circulating 76-2-11 monoclonal antibodies were monitored by flow cytometry. RESULTS: As compared with cyclosporine-treated control animals, swine receiving 76-2-11 demonstrated near-complete depletion of peripheral CD8+ T cells by postoperative day 2, which persisted for 14 to 18 days. Mean allograft survival of the antibody-treated group and the control group was not statistically different (33 days versus 39 days, respectively) and both groups demonstrated severe interstitial rejection at necropsy. Control animals demonstrated florid intimal thickening of large and small arteries at necropsy. However, swine treated with 76-2-11 showed no intimal proliferation. CONCLUSIONS: Depletion of host CD8+ T cells prevents or delays the development of intimal proliferation in miniature swine. CD8+ lymphocytes play an important role in the early development of cardiac allograft vasculopathy in large animals.

Positive and negative selection of functional mouse CD4 cells by porcine MHC in pig thymus grafts.

Specific tolerance to discordant xenogeneic donors can be achieved by grafting of fetal pig thymic and liver tissue (FP THY/LIV) to T cell and NK cell-depleted, thymectomized (ATX) mice. Mouse CD4+ T cells develop in FP THY/LIV grafts, and demonstrate remarkably normal immune function, including host-restricted responses to keyhole limpet hemocyanin. We have therefore studied the role of host MHC class II in the development of mouse T cells in FP THY/LIV grafts by comparing their development in ATX MHC class II-deficient (IIKO) and wild-type (H-2b) mice. Mouse CD4+ T cells repopulated T/NK cell-depleted, ATX IIKO mice after grafting with FP THY/LIV, indicating that pig MHC can positively select mouse CD4 cells. Expression of TCR, MHC class I, Qa-2, heat-stable Ag, and CD45RB among double-positive and CD4 single-positive (SP) graft thymocytes in wild-type recipients was similar to that in normal mouse thymi, whereas CD4 SP thymocytes in grafts of IIKO mice showed increased Qa-2 and decreased heat-stable Ag expression, suggesting an increased level of maturity. Double-positive cells in grafts of IIKO mice also expressed higher than normal levels of Qa-2. Deletion within the grafts of Vbeta3+, Vbeta5.1/5.2+, and Vbeta11+ but not Vbeta6+, Vbeta7+, or Vbeta8.1/8.2+ mouse CD4 SP thymocytes in ATX IIKO mice demonstrated that swine leukocyte Ag participates in negative selection of the T cell repertoire. Therefore, porcine MHC mediates positive and negative selection of mouse thymocytes, but host class II MHC molecules also regulate thymocyte maturation in xenogeneic thymic grafts.

Immune restoration by fetal pig thymus grafts in T cell-depleted, thymectomized mice.

Donor-specific tolerance can be induced across a discordant xenogeneic barrier in T/NK cell-depleted, thymectomized (ATX) B10 mice by grafting of fetal pig thymic and liver tissue (FP THY/LIV) under the kidney capsule. We have now examined the phenotype and function of murine T cells that develop in FP THY/LIV grafts in these mice. Mouse CD4+ T cells reached normal levels in PBL by 14 wk, and were maintained up to 30 wk. Similar proportions of splenic CD4+ cells expressed the naive phenotype (CD45RBhighMEL-14+CD44low) in FP THY/LIV graft recipients and euthymic control mice. These CD4 cells were functional, demonstrating normal proliferative responses and up-regulation of CD25 and CD69 after activation by mitogens or alloantigens. They proliferated in response to the protein Ag KLH presented by host MHC following in vivo immunization. ATX B10 mice grafted with FP THY/LIV also cleared Pneumocystis carinii infections, whereas simultaneously-treated ATX B10 mice not receiving FP THY were unable to do so. Discordant xenogeneic thymus grafting can therefore restore immune competence. Thus, in addition to tolerance induction, xenogeneic thymic replacement might have a potential role in the reconstitution of immunity in patients afflicted with immunodeficiencies affecting the thymus.