Hyperacute rejection of hDAF-transgenic pig organ xenografts in cynomolgus monkeys: influence of pre-existing anti-pig antibodies and prevention by the alpha GAL glycoconjugate GAS914

BACKGROUND: Our introductory pig-to-cynomolgus monkey heart or kidney transplantation using organs from pigs transgenic for human decay-accelerating factor (hDAF), showed a high incidence of hyperacute rejection (HAR), which was ascribed to extraordinary high levels of anti-pig antibodies. We evaluated the efficacy of GAS914, a Gal alpha 1-3Gal trisaccharide linked to a poly-l-lysine backbone, in inhibition of HAR. METHODS: hDAF transgenic heterotopic heart (n = 15) or life-supporting kidney (n = 8) transplantation included induction with cyclophosphamide or anti-thymocyte globulin, and maintenance with cyclosporine or tacrolimus, steroids and mycophenolate sodium/mofetil. Four doses of GAS914 were given before transplantation. Rejection was confirmed by graft histology, and anti-pig antibody levels were determined in various assays. RESULTS: Four of six heart transplants without GAS914 treatment showed HAR. Nine subsequent transplants with GAS914 pre-treatment, did not show HAR (chi-square, P < 0.05). Two of four kidney transplants without GAS914 treatment ended with HAR. Four subsequent transplants with GAS914 did not show HAR. Animals with HAR showed extremely high antibody levels. Samples just before transplantation showed significantly higher antibody levels in recipients presenting with HAR. In all assays antibody levels were significantly lowered by GAS914 pre-treatment. CONCLUSIONS: HAR of hDAF solid organs could be ascribed to high levels of anti-pig antibodies. It is hypothesized that the hDAF transgene shows a threshold in efficacy, above which an overwhelming attack by antibodies and complement activation cannot be modulated to prevent HAR. HAR does not occur when animals with lower levels are used, or when antibodies are effectively depleted from the circulation by GAS914 treatment.     

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.     

Soluble Galalpha(1,3)Gal conjugate combined with hDAF preserves morphology and improves function of cardiac xenografts

BACKGROUND: Cytotoxic anti-Galalpha(1,3)Gal antibodies play a key role in the rejection of pig organs transplanted into primates. Regimens reducing anti-Galalpha(1,3)Gal antibodies were associated with severe side effects unable to prevent antibody rebound until soluble synthetic oligosaccharides with terminal Galalpha(1,3)Gal inhibiting antigen binding became available. We displayed kinetics of anti-pig and anti-Galalpha(1,3)Gal IgM and IgG antibody levels using GAS914, a Galalpha(1,3)Gal trisaccharide conjugated to poly-l-lysine, and investigated corresponding changes of parameters of heart function. METHODS: Using a working heart model, hDAF pig hearts were perfused with human blood containing GAS914 (group 1). As controls hDAF pig hearts (group 2) and landrace pig hearts (group 3) were perfused with human blood only. Levels of anti-Galalpha(1,3)Gal (IgM, IgG) and anti-pig antibodies were assessed to prove the effectiveness of GAS914. As parameters of heart function, cardiac output (CO), stroke work index (SWI), coronary blood flow (CBF) and coronary resistance were measured. Creatine phosphokinases, lactate dehydrogenase and aspartate aminotransferase were evaluated as markers of myocardial damage. Histological and immunohistochemical investigations were performed at the end of perfusion. RESULTS: In group 1 an immediate and extensive reduction in both IgM and IgG anti-Galalpha(1,3)Gal was found. Anti-pig antibodies were eliminated accordingly. Antibody binding to GAS914 was complete before the start of organ perfusion. Corresponding to rapid antibody elimination in group 1 GAS914 not only was able to significantly prolong the beating time of the heart in hDAF pigs, but also to clearly improve functional parameters. When switching to the working heart mode hDAF pig hearts perfused with human blood containing GAS914 (group 1) revealed a CO starting at a significantly higher level than hDAF (group 2) and non-transgenic pig hearts (group 3) perfused with human blood only. Similarly, in group 1 SWI was significantly increased at the beginning of perfusion compared to that of group 2 and group 3. The increase in CBF during perfusion and the corresponding fall of coronary resistance occurred without significant differences between the groups revealing the independence of hDAF and GAS914. CONCLUSIONS: Due to an immediate and profound reduction in Galalpha(1,3)Gal-specific antibodies, soluble Galalpha(1,3)Gal conjugates not only prolong survival, but also improve the hemodynamic performance of the heart in DAF pigs.     

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.     

Improvement in human decay accelerating factor transgenic porcine kidney xenograft rejection with intravenous administration of gas914, a polymeric form of alphaGAL

BACKGROUND: The present study was undertaken to determine whether intravenous administration of GAS914, a polymeric form of alphaGal, would minimize porcine kidney xenograft rejection in baboons. Human decay accelerating factor renal xenografts were transplanted into 16 baboon recipients. METHODS: Baseline immunosuppression for all groups included cyclosporine A, cyclophosphamide, SDZ-RAD, and methylprednisolone. Group 1 received only baseline immunosuppression; group 2 animals received low-dose GAS914 with baseline immunosuppression; group 3 animals received high dose GAS914 with high-dose baseline immunosuppression; and animals from group 4 received high-dose GAS914 and low-dose baseline immunosuppression. RESULTS: None of the animals in this study developed hyperacute rejection. Intravenous administration of GAS914 significantly reduced xenoreactive antibodies as measured by antiporcine hemolytic assays and anti-Gal (immunoglobulin [Ig] G and IgM) antibody assays. Rejection was less severe in the GAS914-treated group. Only 25% (3 of 12) of GAS914-treated animals were killed as a result of rejection, whereas 75% (three of four) of non-GAS914-treated animals were killed because of terminal rejection (P<0.01). Protocol biopsies demonstrated that the degree of acute humoral xenograft rejection (AHXR) was reduced in the GAS914-treated animals compared with non-GAS914-treated animals. CONCLUSION: The intravenous administration of GAS914 reduces xenoreactive antibody levels and reduces the degree of porcine kidney xenograft rejection, but does not improve survival. AHXR and drug toxicity remain major barriers to the long-term success of xenotransplantation.     

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.     

Hyperacute lung rejection in the pig-to-human model 4: evidence for complement and antibody independent mechanisms

BACKGROUND: We assessed whether the combination of complement regulation and depletion of xenoreactive antibodies improves the outcome of pulmonary xenografts compared with either strategy alone. METHODS: Lungs from pigs heterozygous (hDAF(+/-)) or homozygous (hDAF(+/+)) for the human decay accelerating factor transgene (hDAF) or their nontransgenic litter mates (hDAF(-/-)) were perfused with heparinized whole human blood. In additional groups, xenoreactive natural antibodies (XNA) were depleted by pig lung perfusion (hDAF(-/-)/AbAbs, hDAF(+/-)/AbAbs) before the experiment. This combined approach was augmented by adding soluble complement receptor 1 (sCR1) to the perfusate in one further group (hDAF(+/-)/AbAbs/sCR1). RESULTS: HDAF(-/-) lungs perfused with unmodified human blood were rejected after 32.5 min (interquartile range, IQR 5 to 210). HDAF(+/-) lungs survived for 90 min (IQR 10 to 161, P = 0.54). Both groups showed a rapid rise in pulmonary vascular resistance (PVR), which is a characteristic feature of hyperacute rejection (HAR). This phenomenon was blunted in the hDAF(+/+) group, although survival (48 min, IQR 14 to 111) was not further prolonged. Antibody depletion (AbAbs) led to a significant increase in survival time (hDAF(-/-)/AbAbs: 315 min, IQR 230 to 427; hDAF(+/-)/AbAbs: 375 min, IQR 154 to 575), reduced PVR and less complement production. Addition of sCR1 reduced complement elaboration but did not further improve survival (200 min, IQR 128 to 580) and surprisingly tended to increase PVR. CONCLUSIONS: Depletion of xenoreactive antibodies is more effective than membrane-bound complement regulation to blunt hyperacute rejection of pulmonary xenografts, but even the combined approach including soluble-phase complement inhibition is not sufficient to reliably prevent organ failure within hours. It therefore seems likely that other factors independent of antibody and complement contribute to HAR in this model.     

The effect of soluble complement receptor type 1 on acute humoral xenograft rejection in hDAF-transgenic pig-to-primate life-supporting kidney xenografts

BACKGROUND: In pig-to-nonhuman primate solid organ xenotransplantation using organs from donors transgenic for human decay-accelerating factor (hDAF), the main type of rejection is antibody-mediated (acute humoral xenograft rejection, AHXR). This occurs despite the complement-regulatory function of the transgene, neutralization of natural antibodies to Galalpha1-3Gal (Gal) using soluble glycoconjugates, and chronic immunosuppression. As complement components play a major role in graft destruction after antibody binding, we evaluated the efficacy of chronic complement inhibition by soluble complement receptor type 1 (TP10). METHODS: Life-supporting hDAF-transgenic kidney transplantation was performed in cynomolgus monkeys, using cyclophosphamide induction, and maintenance immunosuppression with cyclosporin A, mycophenolate sodium, and tapering steroids. Rejection was treated with bolus steroid injections: if not successful animals were terminated. Three groups were studied: in group 1 (n=4) GAS914 (a soluble glycoconjugate comprising Gal on a poly-L-lysine backbone) was added before and after transplantation; group 2 (n=2) received GAS914 as in group 1 and in addition TP10 before and after transplantation; in group 3 (n=4) GAS914 was only given before transplantation and TP10 as in group 2. Monitoring included the regular assessment of anti-porcine antibodies, complement activity (soluble C5b-9), therapeutic drug monitoring, and graft histology. Results: Survival in group 1 was 6, 12, 31 and 37 days, respectively, and in all four cases graft histology showed AHXR. The two animals in groups 2 survived 3 and 15 days, respectively, and similarly showed AHXR in graft histology. In group 3 two animals showed AHXR (10 and 37 days survival, respectively), and two others did not show AHXR (20 and 32 days survival, respectively). The diagnosis AHXR included the deposition of complement activation products in the graft, which were present at lower intensity in animals treated with TP10. In all animals GAS914 effectively neutralized circulating anti-Gal antibody. Antibodies were detectable in the circulation of all animals using porcine erythrocytes in a hemolytic assay, although at lower levels than before transplantation. Soluble C5b-9 was not detectable in the circulation of animals receiving TP10, and circulating TP10 concentrations in these animals were in a presumed pharmacologically active range. CONCLUSIONS: The inclusion of TP10 in the immunosuppressive protocol does not clearly lead to improved xenograft survival. Despite effective neutralization of anti-Gal antibodies and effective inhibition of systemic complement activity, AHXR was apparent in four of six animals under chronic TP10 treatment, including deposits of complement activation products in the graft. Apparently, effective systemic complement inhibition by TP10 in combination with local complement regulation by the hDAF transgene product does not necessarily result in effective inhibition of complement activation at locations in the xenograft upon binding of anti-porcine antibodies to the grafted endothelium.     

Protease inhibitor nafamostat mesilate attenuates complement activation and improves function of xenografts in a discordant lung perfusion model

Tagawa T. Protease inhibitor nafamostat mesilate attenuates complement activation and improves function of xenografts in a discordant lung perfusion model. Xenotransplantation 2011; 18: 315–319. © 2011 John Wiley & Sons A/S. Abstract: Background: Anti‐complement activity of nafamostat mesilate (FUT‐175) is strong including its variety of pharmacological effects. The effect of FUT‐175 for xenografts in an ex vivo guinea pig‐to‐rat lung perfusion model was evaluated. Methods: Heparinized Lewis rat blood was used to perfuse the lungs in three groups (n = 6 each). Group I used Lewis rat left lung for donor, Group X used guinea pig left lung for donor, and Group XF used guinea pig left lung for donor, which was perfused with Lewis rat blood with 0.2 mg/ml of FUT‐175. Complement activity causing 50% hemolysis (CH50) in the perfusion blood and pulmonary function either before or during perfusion were serially measured. Pathological assessments of the lungs were also carried out after perfusion. Results: The duration of satisfactory pulmonary function was significantly increased in Group XF. Complement activity causing 50% hemolysis in Group XF decreased more significantly compared to Group X. FUT‐175 suppressed both the increase in pulmonary arterial pressure and airway resistance, and the decrease in dynamic lung compliance. In Group X, pathology showed intra‐alveolar hemorrhage, perivascular edema, and medial thickening with endothelial swelling of the pulmonary arteries. In Group XF, less changes were observed compared to Group X. Group X showed deposition of IgM, IgG, and C3 at the endothelium of arteries, which was fewer in Group XF, and even fewer in Group I. Conclusions: This study suggests that FUT‐175 inhibited complement activation and improved lung xenograft function. FUT‐175 ameliorates hyperacute rejection in a guinea pig‐to‐rat ex vivo xenogeneic lung perfusion model.     

Transgenic animals in experimental xenotransplantation models: orthotopic heart transplantation in the pig-to-baboon model

Pig organs are at risk for hyperacute and acute vascular rejection mediated by anti-pig antibodies, mainly binding to the Galalpha(1,3)Gal epitope. Acute cellular rejection is characterized by progressive infiltration of mononuclear cells. There is an ongoing search for immunosuppressive regimens that provide adequate protection against all patterns of xenograft rejection, but have no severe impact on the condition of xenograft recipients. Herein orthotopic heart transplantations were performed from hDAF or hCD46 piglets to nonsplenectomized baboons. Basic immunosuppression consisted of tacrolimus, sirolimus, GAS914, steroids, and ATG. Group 1 received basic immunosuppression. Group 2 was additionally treated with rituximab and group 3 with half-dose cyclophosphamide. Group 4 received cyclophosphamide and an anti-HLA-DR antibody. Three baboons received GAS914 and TPC. Monitoring included the regular assessment of anti-porcine antibodies, blood counts, therapeutic drug monitoring, and graft histology. Two grafts failed due to technical mistakes. In group 1, baboons died after 1 and 9 days. In group 2, maximum survival was 30 hours. In group 3, baboons lived 20 hours, 25 days, and 14 days. Group 4 survival times were 9.5 hours, 5.5 hours, 4 days, 34 hours, and 3 days. An increase of non-Galalpha(1,3)Gal antibodies was observed. Depositions of immunoglobulins and complement revealed a humoral rejection process. No cellular infiltration could be observed. In conclusion, suppressing cellular rejection with half-dose cyclophosphamide together with tacrolimus and sirolimus produced longer graft survival with a good general condition. Prevention of acute xenograft rejection further needs inhibition of non-Galalpha(1,3)Gal cytotoxicity by sufficient depression of B-cell activation.     

The xenoantibody response and immunoglobulin gene expression profile of cynomolgus monkeys transplanted with hDAF-transgenic porcine hearts

BACKGROUND: Recent work has indicated a role for anti-Gal alpha 1-3Gal (Gal) and anti-non-Gal xenoantibodies in the primate humoral rejection response against human-decay accelerating factor (hDAF) transgenic pig organs. Our laboratory has shown that anti-porcine xenograft antibodies in humans and non-human primates are encoded by a small number of germline IgV(H) progenitors. In this study, we extended our analysis to identify the IgV(H) genes encoding xenoantibodies in immunosuppressed cynomolgus monkeys (Macaca fascicularis) transplanted with hDAF-transgenic pig organs. METHODS: Three immunosuppressed monkeys underwent heterotopic heart transplantation with hDAF porcine heart xenografts. Two of three animals were given GAS914, a poly-L-lysine derivative shown to bind to anti-Gal xenoantibodies and neutralize them. One animal rejected its heart at post-operative day (POD) 39; a second animal rejected the transplanted heart at POD 78. The third monkey was euthanized on POD 36 but the heart was not rejected. Peripheral blood leukocytes (PBL) and serum were obtained from each animal before and at multiple time points after transplantation. We analyzed the immune response by enzyme-linked immunosorbent assay (ELISA) to confirm whether anti-Gal or anti-non-Gal xenoantibodies were induced after graft placement. Immunoglobulin heavy-chain gene (V(H)) cDNA libraries were then produced and screened. We generated soluble single-chain antibodies (scFv) to establish the binding specificity of the cloned immunoglobulin genes. RESULTS: Despite immunosuppression, which included the use of the polymer GAS914, the two animals that rejected their hearts showed elevated levels of cytotoxic anti-pig red blood cell (RBC) antibodies and anti-pig aortic endothelial cell (PAEC) antibodies. The monkey that did not reject its graft showed a decline in serum anti-RBC, anti-PAEC, and anti-Gal xenoantibodies when compared with pre-transplant levels. A V(H)3 family gene with a high level of sequence similarity to an allele of V(H)3-11, designated V(H)3-11(cyno), was expressed at elevated levels in the monkey that was not given GAS914 and whose graft was not rejected until POD 78. IgM but not IgG xenoantibodies directed at N-acetyl lactosamine (a precursor of the Gal epitope) were also induced in this animal. We produced soluble scFv from this new gene to determine whether this antibody could bind to the Gal carbohydrate, and demonstrated that this protein was capable of blocking the binding of human serum xenoantibody to Gal oligosaccharide, as had previously been shown with human V(H)3-11 scFv. CONCLUSIONS: DAF-transgenic organs transplanted into cynomolgus monkeys induce anti-Gal and anti-non-Gal xenoantibody responses mediated by both IgM and IgG xenoantibodies. Anti-non-Gal xenoantibodies are induced at high levels in animals treated with GAS914. Antibodies that bind to the Gal carbohydrate and to N-acetyl lactosamine are induced in the absence of GAS914 treatment. The animal whose heart remained beating for 78 days demonstrated increased usage of an antibody encoded by a germline progenitor that is structurally related, but distinct from IGHV311. This antibody binds to the Gal carbohydrate but does not induce the rapid rejection of the xenograft when expressed at high levels as early as day 8 post-transplantation.     

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.     

Influence of cold ischemia time, pretransplant anti-porcine antibodies, and donor/recipient size matching on hyperacute graft rejection after discordant porcine to cynomolgus kidney transplantation

Organs transplanted between phylogenetically disparate species, such as from the pig into the primate, are subject to hyperacute rejection (HAR). This form of xenograft rejection is mediated by preformed natural antibodies and is believed to occur invariably in discordant xenografts thus leading to rapid destruction and complete thrombosis of the graft. Recent data, however, have shown that in the porcine to cynomolgus monkey setting, HAR is not inevitably seen after porcine kidney transplantation. The influence of preoperative antiporcine antibody levels in the recipient, cold ischemia time, and donor organ weight on the onset of HAR was investigated by using unmodified large white pigs (aged 3-12 weeks) as organ donors and adult cynomolgus monkeys (aged 1.5-3.5 years) as recipients. Porcine kidney xenotransplantation was performed in either a non-life-supporting model (n=7) or in a life-supporting model (n=8). In both models, no correlation was found between cold ischemia time and HAR. When preoperative anti-porcine antibody levels were investigated, a significant increase in incidence of HAR was observed in animals with elevated anti-porcine IgM (P<0.05) but not IgG levels (P=NS). Interestingly, although 5 of 12 grafts with an organ weight of less than 50 g underwent HAR, none of three grafts with a donor organ weight of more than 70 g showed signs of HAR. In addition, all three larger grafts showed intraoperative and postoperative urine production, although only in 1 (48 g) of the 12 grafts weighing less than 50 g primary graft function was observed. In one animal, a second porcine kidney (23 g) was successfully transplanted (without HAR) immediately after HAR and subsequent removal of a first porcine kidney (20 g). These results indicate that in the porcine to cynomolgus monkey setting anti-porcine IgM rather than IgG anti-porcine antibody levels seem to be of predominant importance for the induction of HAR. By increasing the donor organ size and weight the frequency of the onset of HAR can be at least reduced. This is most likely due to immunoabsorption of the recipients preformed antibodies in the porcine kidney without lethal damage for the graft.     

The role of antibodies in dysfunction of pig-to-baboon pulmonary transplants

OBJECTIVE: Pulmonary transplantation has become the preferred treatment for end-stage lung disease, but application of the procedure is limited because of a paucity of donors. One way to solve donor limitations is to use animal organs as a donor source or xenotransplantation. The current barrier to pulmonary xenotransplantation is the rapid failure of the pulmonary xenograft. Although antibodies are known to play a role in heart and kidney xenograft rejection, their involvement in lung dysfunction is less defined. This project was designed to define the role of antibodies in pulmonary graft rejection in a pig-to-baboon model. METHODS: Orthotopic transgenic swine left lung transplants were performed in baboons depleted of antibodies by one of three techniques before transplantation: (1) ex vivo swine kidney perfusion, (2) total immunoglobulin-depleting column perfusion, and (3) ex vivo swine lung perfusion. Results were compared with those of transgenic swine lung transplants in unmodified baboons. RESULTS: All three techniques of antibody removal resulted in depletion of xenoreactive antibodies. Only pretransplantation lung perfusion improved pulmonary xenograft function compared with lung transplantation in unmodified baboons. CONCLUSIONS: The pathogenesis of pulmonary injury in a swine-to-primate transplant model is different from that in renal and cardiac xenografts. Depletion of antibodies alone does not have a beneficial effect and may actually be detrimental.     

Pre-treatment of porcine pulmonary xenograft with desmopressin: a novel strategy to attenuate platelet activation and systemic intravascular coagulation in an ex-vivo model of swine-to-human pulmonary xenotransplantation

Abstract: Background: Von Willebrand factor (vWF) has been proposed as a major contributor to the development of coagulopathy in pulmonary xenotransplantation. Pretreatment of donor swine with 1‐deamino‐8‐d ‐arginine vasopressin (DDAVP), an analog of vasopressin, can reduce the content of vWF in pulmonary xenografts. Here, we investigate the effects of DDAVP pre‐treatment in an ex‐vivo perfusion model of pulmonary xenotransplantation. Methods: We set up and performed the ex‐vivo perfusion using porcine pulmonary accessory lobes and fresh human whole blood (n = 12). Half of the donor swine were given 3 μg/kg DDAVP intravenously for 3 days before ex‐vivo perfusion (DDAVP group) and half of them were left untreated (control group). The porcine lung was perfused with fresh blood for 1 h and changes in the following parameters were monitored: pulmonary arterial pressure, pulmonary vascular resistance, blood cell counts, fibrinogen, antithrombin, platelet factor 4, D‐dimer, C3a, C4d, and xenoreactive IgM. The release of Galα1‐3Gal xenoantigen (αGal) from porcine lung which had been perfused and retained for 30 min with human blood was assessed by enzyme‐linked immunosorbent assay using αGal‐binding lectin. Results: Both DDAVP and control groups showed typical findings of immediate pulmonary dysfunction: an increase of pulmonary vascular resistance and sequestration of leukocytes and platelets after ex‐vivo perfusion. However, in the DDAVP group, the increase of platelet factor 4, C3a, and C4d after perfusion was attenuated compared to that in the control group. The release of αGal after blood retention was significantly lower in the DDAVP group than that of the control group. Conclusion: Pre‐infusion of DDAVP to the donor swine was beneficial in attenuating platelet activation as well as complement/coagulation activation. These effects of DDAVP are likely to relate to the reduction of porcine vWF content in the xenograft. Therefore, the modulation of vWF secretion in donor lungs could be an additional therapeutic way to reduce systemic coagulopathy in pulmonary xenotransplantation.     

Hyperacute rejection in ex vivo-perfused porcine lungs transgenic for human complement regulatory proteins

Inhibition of complement activation via human membrane-associated complement regulators is known to prevent hyperacute rejection in heart and kidney pig-to-primate transplantation. The protective effect of such strategies in pulmonary xenografts, however, seems to be insufficient. In an ex vivo perfusion, model lungs from donor pigs transgenic for human CD55 (n = 6) or human CD59 (n = 5) were perfused with fresh human blood and compared with nontransgenic organs (n = 6). In addition, a soluble complement component 1 esterase inhibitor (C1-Inh) was applied in h-CD55 transgenic lungs (n = 3). In the h-CD55 transgenic group, survival was prolonged (P < 0.05), quality and maximal time of oxygenation significantly improved and pulmonary vascular resistance reduced compared with the control group. There was a decreased sequestration of platelets, less parenchymal injury and reduced deposition of C(5b-9) in the h-CD55 transgenic group. Additional soluble complement inhibition (C1-Inh) did not prolong survival of h-CD55 transgenic lungs. Survival and pulmonary function in lungs expressing h-CD59 was not significantly different from parameters observed in nontransgenic lungs. In this ex vivo model of pig-to-primate lung transplantation, membrane-based complement inhibition resulted in significantly improved pulmonary function. However, minor histopathological injuries observed in these transgenic xenografts suggested only partial protection from pulmonary dysfunction by complement inhibition alone.     

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.     

"Shock lung" resulting from perfusion of canine lungs with stored bank blood.

An in situ lung perfusion model was used to study the impact of stored bank blood, with or without dacron wool filtration, on morphologic and functional derangement in canine lungs. Autologous blood was stored 24 hours or 21 days in ACD solution and then passed through standard recipient set filters before perfusion through the left lower lung lobes of dogs equipped to have pressure and gas tensions monitored from pulmonary artery, vein and bronchus. In an additional group of dogs, 21-day stored blood was additionally filtered through dacron-wool prior to lung perfusion. Pulmonary vascular resistance increased markedly for lungs perfused with stored blood, whether or not dacron-wool filtered, as compared with lungs perfused with fresh blood. Effective compliance decreased in both groups of lungs perfused with stored blood, and arteriovenous oxygen gradients decreased significantly in these groups as compared with fresh blood-perfused lungs. As an index of congestion, wet/dry lung weight ratios increased for both groups perfused with stored blood which also showed gross and microscopic evidence of pulmonary edema. As a measure of microaggregated blood debris, screen filtration pressure determinations were not significantly different in fresh or stored canine blood in ACD. We conclude from observations of these canine lung perfusions that pulmonary anatomic and functional injury can result from the use of stored bank blood which may be modified, but not eliminated, by depth filtration. We infer that microaggregated blood debris is not the primary noxious factor in stored canine blood, and a toxic serum-borne factor may be implicated.     

The Role of Antibodies and Von Willebrand Factor in Discordant Pulmonary Xenotransplantation

Pulmonary xenotransplantation is one potential solution to the paucity of donors but is currently limited by rapid failure of the graft. Unlike cardiac and renal xenotransplants, pulmonary xenografts release large quantities of swine von Willebrand factor (vWF). Swine vWF binds xenoreactive antibodies and is capable of activating primate platelets. The contribution of swine vWF to lung xenograft dysfunction is not entirely clear. To probe the role vWF plays in xenograft dysfunction, we traced the fate of xenoantibodies in vWF+ and von Willebrand factor-deficient (vWFD) swine lungs. These studies showed that the vast majority of xenoantibodies bind the vWF released from the vWF+ swine lung, and thus do not remain bound on lung endothelium. The vWF complexed to xenoantibody remained capable of aggregating primate platelets. With this information, we performed swine-to-baboon lung transplants using vWF+ and vWFD donors. Without vWF present to complex xenoantibodies, a picture of hyperacute rejection more typical of heart and kidney xenografts, with antibody deposition along the graft endothelium, interstitial hemorrhage, and edema occurred. These findings suggest that porcine vWF plays a major role in the pathogenesis of pulmonary xenograft dysfunction, and suggests promising strategies to treat lung xenograft dysfunction.     

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.