Antibody-induced rejection of pig proislet xenografts in CD4+ T cell-depleted diabetic mice

Reversal of diabetes in mice was achieved following in vivo depletion of host CD4+ T cells and transplantation of xenogeneic fetal pig proislets (pancreatic islet precursors). These procedures resulted in xenograft tolerance since established pig proislet xenografts were not rejected by antipig antibodies produced in the host, and rejection was not induced following the administration of donor major histocompatibility complex--specific pig lymphocytes. Proislet xenografts were rejected following the administration of donor MHC-specific hyper-immune antipig PBL serum raised in normal mice. Although established proislet xenografts in anti-CD4-treated mice are sensitive to antibody-mediated destruction, such hosts are unable to produce an antibody response that leads to graft rejection. The study indicates that the mechanism of preventing xenograft rejection by anti-CD4 treatment in vivo involves not only initial CD4+ T cell depletion but also quantitative and/or qualitative modulation of a CD4+ T cell-dependent antibody response. As a consequence, an apparent state of xenograft tolerance is produced.     

Expression of Complement Regulatory Proteins in Accommodated Xenografts Induced by Anti-α-Gal IgG1 in a Rat-to-Mouse Model

Anti-graft antibodies are often associated with graft rejection. Under special conditions, grafts continue to function normally even in the presence of anti-graft antibodies and complement. This condition is termed accommodation. We developed a xenograft accommodation model in which baby Lewis rat hearts are transplanted into Rag/GT-deficient mice, and accommodation is induced by repeated i.v. injections of low-dose anti-α-Gal IgG₁. The accommodated grafts survived a bolus dose of anti-α-Gal IgG₁, while freshly transplanted second grafts were rejected. To study the mechanism of anti-α-Gal IgG₁-mediated accommodation, both real-time PCR and immunohistochemical staining revealed elevated expression of DAF, Crry and CD59 in the accommodated grafts. In vitro exposure of rat endothelial cells to anti-α-Gal IgG₁ also induced the up-regulation of DAF, Crry and CD59, as revealed by Western blot analyses, and was associated with an acquired resistance to antibody and complement-mediated lysis in vitro . Collectively, these studies suggest that the up-regulation of complement regulatory proteins may abrogate complement-mediated rejection and permit the development of xenograft accommodation.     

Effect of GK1.5 monoclonal antibody dosage on survival of pig proislet xenografts in CD4+ T cell-depleted mice

Treatment of CBA/H mice with 5 injections of anti-CD4 (GK1.5 mAb) terminating on day 10 posttransplant resulted in long-term survival (greater than or equal to 6 weeks) of fetal pig proislet (pancreatic islet precursor) xenografts. The GK1.5 mAb dose determined the duration of CD4+ T cell depletion and the extent to which the survival of pig proislet xenografts was prolonged. Sustained depletion of CD4+ T cells (0%, 1%, and 9% of total T cells in peripheral lymph nodes at 2, 4, and 6 weeks, respectively) and survival of proislet xenografts at 6 weeks posttransplant was observed when transplant recipients were treated with 5.4 mg GK1.5 mAb/injection. Treatment of transplanted mice with a suboptimal dose of GK1.5 mAb (0.2 mg/injection) resulted in the same level of depletion at 2 weeks posttransplant but a more rapid recovery of CD4+ T cells in the periphery (24% of total T cells at 4 weeks) and only temporary prolongation in xenograft survival (less than or equal to 4 weeks). Control xenografts showed evidence of graft destruction by as early as 6-7 days posttransplant and were completely rejected by 2 weeks. The rejection reaction consisted predominantly of CD4+ T cells, eosinophils and F4/80-positive macrophages. Only small numbers of CD8+ T cells were identified. CD4+ T cells therefore represented the major T cell component of the cellular infiltrate. In contrast, surviving xenografts in GK1.5 mAb-treated recipient mice showed essentially an absence of CD4+ T cells but presence of CD8+ T cells. This finding may be attributable to the increase (1.7-3.1-fold) in the absolute size of the population of CD8+ T cells in the periphery following GK1.5 mAb treatment in vivo. Compared with isolated fetal pig proislets, which contained only a small population of insulin-producing cells in addition to glucagon- and somatostatin-positive cells, surviving pig proislet xenografts contained mainly insulin-positive beta cells with smaller populations of glucagon- and somatostatin-positive cells. Fetal pig proislets therefore differentiate into insulin-producing islet tissue posttransplant and thus show evidence of normal development of endocrine function.     

Specific depletion of preformed IgM natural antibodies by administration of anti-mu monoclonal antibody suppresses hyperacute rejection of pig to baboon renal xenografts

BACKGROUND: The elimination of circulating anti-porcine preformed antibodies is crucial for avoiding hyperacute vascular rejection (HAVR) of primarily vascularized xenograft in discordant pig to baboon model. Previously described methods used for eliminating natural antibodies, however, constantly removed both anti-porcine IgM and IgG antibodies, as well as often complement proteins. To study specifically the role of preformed anti-porcine IgM antibodies, a specific anti-IgM monoclonal antibody (mAb) has been designed and evaluated in vivo. METHODS: Iterative injections of anti-IgM mAb (LO-BM2) at high dose (20 mg/kg) depleted to undetectable level the circulating IgM and therefore anti-porcine IgM antibodies but did not change the concentration of anti-pig IgG antibodies. The serum concentration of IgM and IgG antibodies was assessed by ELISA and the level of anti-pig natural IgM and IgG antibodies by flow cytometry (FC). Anti-rat sensitization was assessed by specific ELISA as well as the serum concentration of LO-BM2. RESULTS: Iterative injections of LO-BM2 allowed to specifically eliminate the anti-porcine IgM antibodies to undetectable levels at ELISA. Despite a normal serum level of anti-porcine IgG and complement proteins, HAVR was avoided. Without immunosuppression, the specific elimination of preformed anti-porcine IgM prolonged the survival of a renal xenograft in baboon up to 6 days, whereas without IgM antibody elimination, the renal xenografts were hyperacutely rejected within hours. The lost of activity of LO-BM2 after 10 days was concomitant to an IgM and IgG antibody rebound, which caused an acute vascular rejection of the xenograft. CONCLUSION: Specific elimination of natural anti-porcine IgM antibodies allows to avoid HAVR of a pig to baboon renal xenograft, whereas anti-porcine IgG antibodies and complement proteins were present in the serum. This result confirms previous in vitro reports and demonstrates for the first time in vivo that preformed IgM antibodies alone are responsible for HAVR, while preformed anti-porcine IgG antibodies are unable alone to cause HAVR. Anti-IgM therapy appears as an important tool to transiently but completely eliminates xeno-IgM antibodies in vivo.     

Co-stimulatory molecules in islet xenotransplantation: CTLA4Ig treatment in CD40 ligand-deficient mice

Previous work has demonstrated that short-term systemic administration of cytotoxic T lymphocyte antigen-4 (CTLA-4) Ig blocks human pancreatic islet xenograft rejection in mice and induces long-term, donor-specific tolerance, whereas studies on pig pancreatic islet rejection in mice have failed to demonstrate a role for CTLA4Ig in preventing rejection. Treatment with anti-CD40 ligand (L) monoclonal antibodies alone is somewhat effective in prolonging the survival of islet xenografts, but ineffective when applied to skin xenografts. However, simultaneous blockade of the CD28 and CD40 co-stimulatory pathways prolongs the survival of pig skin on recipient mice. To evaluate the role of CD28 and CD40 co-stimulatory pathways in pig islet-like cell cluster (ICC) xenograft rejection in mice, CD40L-deficient mice transplanted with fetal porcine ICCs were given posttransplant treatment with human (h) CTLA4Ig or a human IgG1 chimeric mAb (hL6). Xenografts were evaluated 6 or 12 days after transplantation. Fetal porcine ICC xenografts were protected from rejection in hCTLA4Ig-treated CD40L-deficient mice, whereas xenograft rejection persisted in untreated CD40L-deficient mice. Simultaneous blockade of the CD28 and CD40 co-stimulatory pathways is mandatory to inhibit ICC xenograft rejection in the pig-to-mouse model, because the CD28 and CD40 co-stimulatory pathways seem capable of efficiently substituting for one another.     

Serum anti-pig antibodies as potential indicators of acute humoral xenograft rejection in pig-to-cynomolgus monkey kidney transplantation

BACKGROUND: Hyperacute rejection of solid organ pig xenografts in nonhuman primates has been overcome by using donors transgenic for human complement regulatory proteins, but grafts are still susceptible to humoral (antibody-mediated) rejection. We investigated whether circulating xenoreactive antibodies are a useful indicator of this xenograft rejection. METHODS: Five assays were employed in a retrospective analysis on 20 selected cynomolgus monkey recipients of renal xenografts transgenic for human decay-accelerating factor, with survival between 4 and 60 days. The assays included hemolytic and hemagglutination assays and the measurement of immunoglobulin (Ig)G and IgM binding to porcine endothelial cells and leukocytes, and to the Gal alpha 1-3Gal trisaccharide (Gal) antigen. To assess non-Gal-directed antibodies, sera were absorbed with a Gal-coated resin. A predictive value was defined as an increase in antibody levels before a decline in graft failure (>20% increase in creatinine levels) and humoral rejection in graft pathology. RESULTS: Data on hemolytic anti-pig antibody correlated with those on IgM antibody to endothelial cells, leukocytes, and Gal. In absorbed sera IgM and IgG antibody to endothelial cells and leukocytes correlated with each other, indicative for an elicited antibody response to non-Gal antigens. Sixteen animals showed humoral rejection, and in all but two animals one or more assays was considered of predictive value. On the other hand, increased antibody levels were noted in two animals without signs of rejection in graft pathology and in two cases with cellular xenograft rejection. CONCLUSIONS: It is recommended to use multiple assays (preferably hemolytic, anti-Gal, and anti-endothelial cell) to be able to fully monitor the peripheral antibody responses in pig-to-primate xenograft recipients.     

Lewis rat pancreas, but not cardiac xenografts, are resistant to anti-gal antibody mediated hyperacute rejection

BACKGROUND: The objective of this study was to evaluate the role of anti-Gal Abs and non-anti-Gal Abs in hyperacute rejection (HAR) of concordant pancreas xenografts compared with heart xenografts. In addition, we tested whether rejection of Lewis rat pancreas grafts was T-cell dependent and could be prevented by anti-T-cell treatment. METHODS: To determine the role of anti-Gal Abs in the induction of HAR, Lewis rat pancreas and heart xenografts were transplanted into alpha1,3Galactosyltransferase knockout (GT-Ko) mice treated with normal human serum (NHS) or hyperimmune serum, or into presensitized GT-Ko mice. To investigate whether rejection of pancreas xenograft was mediated by a T-cell dependent response, Lewis rat pancreas grafts were transplanted into streptozotocin (STZ)-induced diabetic GT-Ko mice treated with FK506, anti-CD4 mAbs (GK1.5), and thymectomy. Antidonor-specific IgM and IgG and anti-Gal Abs were analyzed by flow cytometry. Rejected and long-term surviving pancreas xenografts were assessed by functional (blood glucose) and histopathological examination. RESULTS: HAR of Lewis rat pancreas xenografts could not be induced by NHS (0.4 ml), whereas NHS (0.2 ml) resulted in HAR of Lewis heart xenografts. Infusion of Lewis rat-specific hyperimmune serum (0.2 ml) resulted in HAR of Lewis rat pancreas xenografts. In addition, second Lewis rat pancreas grafts were hyperacutely rejected by presensitized GT-Ko mice. Immunohistochemical staining showed a low expression of Galalpha1,3Gal antigen in the endocrine tissue compared with that in the cardiac grafts. The levels of anti-Gal Abs in pancreas xenograft transplantation did not increase in GT-Ko mice after pancreas xenograft transplantation that was significantly increased after heart transplantation. FK506 treatment induced long-term survival of Lewis pancreas xenografts (mean survival time (MST) >90 days). Anti-CD4 treatment delayed rejection of Lewis rat pancreas xenografts with MST of 34.3 days, whereas anti-CD4, in combination with thymectomy, synergistically prolonged survival of pancreas xenograft (MST=70.4 days). CONCLUSION: Pancreas xenograft is resistant to anti-Gal Abs-induced HAR but is susceptible to anti-donor specific Abs. Rejection of Lewis pancreas xenograft in STZ-induced, diabetic, GT-Ko mice is T-cell dependent.     

Acute cell-mediated rejection in orthotopic pig-to-mouse corneal xenotransplantation

Abstract: Background:  To investigate the role of T cells and natural killer (NK) cells in mediating corneal xenograft rejection in a pig-to-mouse model.
Methods:  Pig corneas were orthotopically transplanted into BALB/c, C57BL/6, nude, severe combined immunodeficiency (SCID), and NOD/SCID/γc^null (NOG) mice. Graft survival was clinically assessed by slit-lamp biomicroscopy and median survival times (MST) were calculated. The rejected grafts were histologically evaluated using antibodies against CD4, CD8, NK1.1, and F4/80.
Results:  The pig corneal xenografts were acutely rejected by BALB/c and C57BL/6 mice (MST 9.0 days), while nude, SCID and NOG mice rejected pig corneas in a more delayed fashion (MST 16.0, 16.4, and 16.9 days, respectively). The majority of infiltrating cells found in rejected grafts in C57BL/6 mice were macrophages and CD4⁺ T cells, while CD8⁺ T cells and NK cells were rarely found. The grafts in nude mice had markedly decreased inflammatory infiltration with small numbers of macrophages and CD4⁺ T cells. Infiltration was even more modest in grafts in SCID and NOG mice.
Conclusions:  T cells play an important role in acute rejection of pig corneal xenografts in mice, although acute rejection is not solely the result of T-cell-mediated immunity. NK cells are less likely to be involved in the rejection process.     

Failure to deplete anti-Galalpha1-3Gal antibodies after pig-to-baboon organ xenotransplantation by immunoaffinity columns containing multiple Galalpha1-3Gal oligosaccharides

BACKGROUND: The impact of anti-Galalpha1-3Gal (alphaGal) antibodies on the acute humoral xenograft rejection (AHXR) of pig organs transplanted in baboons is unclear. METHODS: Twenty-three baboons underwent heterotopic pig heart transplantation (Tx). Groups A (n = 5) and B (n = 6) received non-transgenic and human decay accelerating factor (hDAF) pig hearts, respectively, without any treatment. Groups C (n = 5) and D (n = 7) were transplanted with non-transgenic and hDAF organs, respectively, and the exclusive treatment was repeated extracorporeal immunoadsorptions (EIA) before and after Tx with an alphaGal column containing disaccharide (DI), trisaccharide (TRI) 2 and pentasaccharide (PENTA) oligosaccharides. RESULTS: In group A, 3 of 5 xenografts underwent hyperacute rejection (HAR). No xenograft from groups B, C and D experienced HAR, most of them failing from AHXR. Immediately after Tx and up to day 2, the level of immunoglobulin (Ig)M and IgG anti-alphaGal DI, TRI2 and TRI6, and anti-pig hemolytic antibody (APHA) antibodies decreased in all the groups by 80 to 96% compared with the concentration present before Tx. From day 3 to AHXR, a sustained increase of anti-alphaGal IgM DI, TRI2 and TRI6, and APHA occurred in all groups. EIA depleted anti-alphaGal IgM and APHA before Tx, but it did not modify the increase of these antibodies after Tx. Baboon serum samples before Tx, pre-incubated in vitro with 1 mg/ml of DI, TRI2 and TRI6, had an average of 93% reduction of anti-alphaGal IgM antibodies specific against each one of these alphaGal oligosaccharides. In contrast, at AHXR, the average reduction after in vitro pre-incubation with either 1 or 5 mg/ml of DI, TRI2 and TRI6 was 40%. CONCLUSIONS: The EIA reduces anti-alphaGal and APHA antibodies, preventing the HAR of non-transgenic pig hearts transplanted in baboons, as does hDAF expression. However, EIA does not modify the level of anti-alphaGal IgM and APHA antibodies after Tx nor the AHXR of either non-transgenic or hDAF pig organs. The increase in anti-alphaGal IgM after Tx was similar for the different antibodies of the anti-alphaGal polymorphism, and was only partially neutralized in vitro with the specific alphaGal oligosaccharide.     

Administration of GAS914 in an orthotopic pig-to-baboon heart transplantation model

BACKGROUND: Long-term survival of transgenic cardiac xenografts is currently limited by a form of humoral rejection named acute vascular rejection. Preformed and elicited cytotoxic antibodies against Galalpha(1,3)Gal terminating carbohydrate chains, known as the primary cause of hyperacute rejection, are crucial for this process. We investigated whether GAS914, a soluble, polymeric form of a Galalpha(1,3)Gal trisaccharide would sufficiently minimize xenograft rejection of hDAF-transgenic pig hearts orthotopically transplanted into baboons. METHODS: Orthotopic heart transplantations were performed using hDAF transgenic piglets as donors and four non-splenectomized baboons as recipients. Baseline immunosuppression consisted of tacrolimus, sirolimus, ATG, steroids. In addition two animals received low-dose GAS914, and two animals high-dose GAS914. One of these baboons received high dose GAS914 and cyclophosphamide induction therapy. Serum levels of anti-Galalpha(1,3)Gal IgM and IgG antibodies, and anti-pig antibodies were controlled daily by anti-Galalpha(1,3)Gal enzyme-linked immunosorbant assay and anti-pig hemolytic assays. Histomorphological (hematoxylin and eosin, elastic van Gieson) and immunohistochemical (IgM, IgG) evaluations were performed on tissue specimens. RESULTS: Following low-dose GAS914 therapy survival time was 1 and 9 days, respectively. In baboons treated with high dosages of GAS914 a survival of 30 h and 25 days could be obtained. GAS914 caused an immediate and significant reduction of both anti-Galalpha(1,3)Gal IgM and IgG antibodies. However, sufficient antibody reduction was independent of dosage and form of application of GAS914. A pre-transplant GAS914 treatment was not necessary to effectively reduce antibody levels and prevent hyperacute rejection. In the early postoperative period preformed anti-pig antibodies corresponded predominantly to anti-Galalpha(1,3)Gal antibodies making them susceptible to GAS914. Subsequently, while anti-Galalpha(1,3)Gal antibodies remained low, anti-pig antibodies increased despite of GAS914 application. Corresponding to increased anti-pig antibody titers depositions of IgM and IgG immunoglobulins were detected, which were possibly non-Galalpha(1,3)Gal-specific. CONCLUSIONS: Following orthotopic transplantation of hDAF-transgenic pig hearts into baboons, GAS914 is able to maintain a sufficient reduction of Galalpha(1,3)Gal-specific cytotoxicity to the graft. GAS914 therefore is able to prevent not only hyperacute rejection, but also acute vascular rejection at its beginning, when serum cytotoxicity to the pig heart appears to be predominantly Galalpha(1,3)Gal-specific. A sustained prevention of acute vascular rejection, however, still requires the identification of antibody specificities other than to Galalpha(1,3)Gal.     

Natural antibodies do not inhibit xenogeneic transplantation of human PBL in lethally irradiated mice

Abstract: Attempts to transfer human peripheral blood lymphocytes (hu-PBL) into lethally irradiated mice resulted in limited engraftment in recipients lacking natural antibodies (nAb) and could not be achieved in immunologically normal mice. It has been proposed that nAb with antihuman specificity play a major role in the rejection of the hu-PBL graft. In the present study we demonstrate that, following intensification of the conditioning protocol (thymectomy, supralethal dose of TBI, and radioprotection with bone marrow for donors with severe combined immune deficiency (SCID), transplants of 50 to 70 × 10⁶ hu-PBL were successfully engrafted in BALB/c, CBA/J and C3H/HeJ mice—regardless of the initial high levels of nAb. The percentage of human CD45⁺ cells in peritoneal lavage was not statistically different from that obtained in congenitally immune-deficient corresponding strains (SCID and CBA/N) lacking natural antibodies. Significant differences in engraftment of hu-PBL, between different human donors, were related neither to the nAb content (r = 0.29) nor to the ABO(H) blood group. The transfer of serum with high level of nAb into SCID and CBA/N mice or incubation of hu-PBL in such a serum prior to implantation, did not impede the engraftment and did not decrease the production of human immunoglobulins. These data demonstrate that the presence of nAb in supralethally irradiated normal mice does not inhibit the engraftment of hu-PBL, emphasizing the role of cellular mediated mechanisms in xenograft rejection.     

Characterization of a pig-to-goat orthotopic lung xenotransplantation model to study beyond hyperacute rejection.

BACKGROUND: A pig-to-goat orthotopic lung xenograft model was developed to test whether depletion of goat xenoreactive antibodies against pig red blood cells would prolong pig lung xenograft survival. METHODS: Adult goats with anti-pig xenoreactive antibodies underwent left pneumonectomy followed by orthotopic transplantation of pig left lung (group 1) or immunodepletion of their xenoreactive antibodies by extracorporeal right pig lung perfusion before transplantation without (group 2) or with (group 3) complete clampage of the right pulmonary artery. In group 4, goat left lungs were orthotopically transplanted into pigs and served as negative controls (pig serum does not have anti-goat xenoreactive antibodies). Each study group included 5 animals. Immunosuppression in surviving recipients included cyclosporine and azathioprine. RESULTS: Group 1 recipients died 7 +/- 3 hours after xenograft reimplantation of severe pulmonary hypertension and dysfunction and vasogenic shock, with little evidence of histologic xenograft injury. Group 2 xenografts had a stable circulatory and respiratory function on reperfusion and survived 9 +/- 4 days. Group 3 animals also tolerated complete occlusion of the right pulmonary artery, and xenografts assured the total respiratory support for 4 +/- 1 days. After immunodepletion, goat serum showed no detectable titers of xenoreactive antibodies, which began to reappear by postoperative day 2, where xenografts showed histologic stigmata of acute (humoral and cellular-mediated) rejection that evolved to a complete xenograft necrose at death. Group 4 xenografts showed scattered features of acute rejection 5 +/- 1 days after the operation. CONCLUSIONS: Pig left lung xenografts can provide prolonged and complete respiratory support after depletion of goat xenoreactive antibodies, but they ultimately necrose once recipient xenoreactive antibodies return to pretransplantation values.     

Acute Xenograft Rejection Mediated by Antibodies Produced Independently of TH1/TH2 Cytokine Profiles

There is substantial support for the hypothesis that T(H)1 cytokine responses are critical for the normal elaboration of allograft rejection. Recent studies by Wang et al. (1) underscore the importance of T(H)2 responses in xenograft rejection and revealed that T(H)1 cytokines, IL-12 and interferon-gamma (IFN-gamma), can negatively regulate the development of humoral responses necessary for xenograft rejection. Their exceptional studies prompted us to test whether the ability of allografts to elicit cellular rejection and xenografts to induce humoral rejection also result from the differential ability to induce T(H)1 and T(H)2 responses. We compared the kinetics of antibody and cytokine (IFN-gamma and IL-4) production in C57BL/6 mice following allograft transplantation with BALB/c hearts and in C57BL/6 and BALB/c mice following transplantation with Lewis rat hearts. We also compared the ability of BALB/c mice, deficient in the ability to produce IL-4 or IFN-gamma, to reject xenografts and produce xenoantibodies. We observed that T(H)1/T(H)2 cytokine production minimally affected the kinetics of graft rejection but regulated the magnitude of IgG subclass production. Anti-graft IgM played a critical role in initiating acute antibody-mediated xenograft rejection, and the production antigraft IgM was unaffected by IL-4 or IFN-gamma deficiency. In contrast to the report by Wang et al. (1), we conclude that antibody-mediated xenograft rejection in the concordant Lewis rat heart-to-C57BL/6 mouse xenotransplantation model is dependent on anti-IgM production but independent of T(H) cytokine profiles.     

Mechanism of delayed rejection in transgenic pig-to-primate cardiac xenotransplantation

BACKGROUND: Pig-to-primate cardiac xenografts undergo hyperacute rejection (HAR), in which primate IgM bind to porcine endothelial alpha-Gal molecules and activate membrane attack complex (MAC) deposition. Prolonged graft survival can be achieved by using transgenic pig donors, which express human complement regulatory proteins (hCRP) to inhibit MAC. However, these xenografts invariably fail from delayed xenograft rejection (DXR). We sought to investigate the poorly understood DXR process. MATERIALS AND METHODS: Wild-type (n = 3) and transgenic (n = 3) porcine hearts were heterotopically transplanted into baboons. Biopsies were analyzed by histology and by immunohistochemistry for porcine endothelial markers (vWF, alpha-Gal, and beta-Gal) and primate IgM and MAC deposition. RESULTS: Wild-type xenografts survived 60-80 min but succumbed to rapid IgM/MAC deposition and microvascular thrombosis. Transgenic xenografts avoided HAR but showed increasing IgM/MAC deposition before rejection on days 5, 7, and 11. Serum from baboons after transgenic xenograft rejection showed increased activity against porcine endothelial cells, and in vitro incubation of untransplanted porcine cardiac sections with sensitized baboon serum showed elevated microvascular IgM binding. Increased IgM deposition appeared specific to alpha-Gal, since it competes specifically with alpha-Gal-specific GS-4 lectin, but not with beta-Gal-specific RCA-1 lectin. Competition with GS-4 was not seen if na?ve baboon serum was used. CONCLUSION: DXR may be mediated by increasing baboon IgM binding on porcine microvascular endothelial alpha-Gal molecules.     

Anti-galactose-alpha(1,3) galactose antibody production in alpha1,3-galactosyltransferase gene knockout mice after xeno and allo transplantation

Antibodies (Abs) that mediate the hyperacute rejection and acute vascular rejection/delayed xenograft rejection of pig organs in humans and Old World primates are predominantly directed at a single carbohydrate epitope, galactose-alpha1,3-galactose (alpha1,3Gal). The T-cell dependence of elicited anti-alpha1,3Gal Ab responses in humans and Old World primates is controversial. In this study we have characterized anti-alpha1,3Gal Ab production in mice with disrupted alpha1,3-galactosyltransferase genes (GT-Ko mice) and determined the T-cell dependence of anti-alpha1,3Gal Ab responses, following xenograft and allograft transplantation. GT-Ko mice produce natural anti-alpha1,3Gal IgM and IgG in an age-dependent manner, however, these Abs could not elicit hyperacute rejection nor affect the rate of cardiac xenograft (3-5 days) or allograft rejection (7-9 days). Transplantation of xenogeneic Lewis rats hearts elicited modest anti-alpha1,3Gal Ab, but vigorous xenoAb responses. The anti-alpha1,3Gal Ab response was restricted to the IgM and IgG3 subclass while the xenoAb response comprised IgM and all four IgG subclasses. Transplantation of allogeneic C3H hearts elicited weak anti-alpha1,3Gal Ab responses that were primarily IgM, but vigorous alloAb responses. Despite the restriction of elicited anti-alpha 1,3Gal Ab responses to the IgM and IgG3 isotypes, these responses are T-cell dependent. The ability of allografts to elicit weak anti-alpha1,3Gal but strong allo-Ab responses, can be explained by the dependence of alpha1,3Gal-specific B cells on cognate help from T cells.     

In Vitro and in Vivo Prevention of Human CD8+ CTL-Mediated Xenocytotoxicity by Pig c-FLIP Expression in Porcine Endothelial Cells

Overcoming cell-mediated immunity, especially of human CD8⁺ CTLs, is important for the success of xenotransplantation. Our group has previously reported that the cytotoxicity of human CD8⁺ CTLs against pig endothelial cells (PEC) is highly detrimental and mediated in major part by the Fas/FasL apoptotic pathway. Cellular FLICE inhibitory protein (c-FLIP) was originally identified as an inhibitor of death-receptor signaling through binding competition with caspase-8 for recruitment to Fas-associated via death domain (FADD). Two major c-FLIP variants result from alternative mRNA splicing: a short, 26-KDa protein (c-FLIP_S) and a long, 55-KDa form (c-FLIP_L). The cytoprotective effects of c-FLIP_S/L in xenograft cells remain controversial. This study demonstrates that the overexpression of c-FLIP_S/L genes markedly suppress human CD8⁺ CTL-mediated xenocytotoxicity and, in addition, the cytoprotective effects of c-FLIP_L appear to be significantly stronger than those of c-FLIP_S. Furthermore, to prove the prolonged effects of xenograft survival, PEC transfectants with c-FLIP_S/L genes were transplanted under rat kidney capsules. Prolonged survival was elicited from FLIP_S/L transfectants, whereas parental PEC was completely rejected through day 5, posttransplant. Thus, intracellular remodeling with the overexpression of c-FLIP_S/L in xenograft cells may avoid innate cellular attacks against xenografts and facilitate long-term xenograft survival.     

Elicited non-anti-alphaGAL antibodies may cause acute humoral rejection of hDAF pig organs transplanted in baboons

The combination of immunosuppression and GAS 914, a polylysine containing alphaGal trisaccharide type 2 (TRI 2), has been associated with the prevention of acute humoral xenograft rejection (AHXR) in human decay accelerating factor (hDAF) pig-to-baboon xenotransplants. The aim of this study was to investigate the role of immunosuppression and GAS 914 to neutralize xenoantibodies before and after xenotransplantation. Eight baboons underwent heteropic heart xenotransplantation with hDAF transgenic pig organs, receiving GAS 914 before and after transplantation. Six baboons (Group A) were treated with an immunosuppression protocol that included cyclophosphamide (CyP), Neoral, ERL, and steroids. The other 2 baboons (Group B) were treated with the same immunosuppression but with a 50% reduction in the doses of CyP. No xenograft from Group A underwent acute humoral xenograft (median survival, 27 days), whereas the 2 in Group B experienced rejection (median survival, 6 days). GAS 914 depleted both immunoglobulin (Ig)M and IgG anti-alphaGAL disaccharide (DI), trisaccharide type 2 (TRI 2), and trisaccharide type 6 (TRI 6), before and after transplantation in Groups A and B. However, cytotoxic antibodies with other anti-pig specificities were elicited by the xenografts in Group B leading to AHXR.