Human membrane cofactor protein (MCP, CD 46) protects transgenic pig hearts from hyperacute rejection in primates

Recently, we and others have shown the prolongation of xenograft survival with the use of transgenic pigs bearing human CD 59 and DAF complement regulatory proteins (CRP). We now report heart transplantation using a new line of transgenic pigs bearing a different human CRP, membrane cofactor protein (MCP, CD 46). We transplanted three MCP transgenic and three wild-type porcine hearts into baboons suppressed with cyclosporine, methylprednisone, and rapamycin or cyclophosphamide. In addition, recipients were treated with extracorporeal plasma perfusion to remove alpha-Gal reactivity. The wild-type grafts were rapidly rejected at 60 to 80 min. Two functioning MCP hearts were removed after 5 and 46 h for histological examination. One MCP heart showed vigorous function until postoperative day 16. Immunohistochemistry of both wild-type and MCP-transgenic hearts showed strong deposition of IgM. In contrast, there was less MAC deposition in the transgenic graft as compared to the wild-type control. MCP is another CRP capable of decreasing the features of hyperacute rejection of cardiac xenografts in baboon recipients.     

Differential galactose α(1,3) galactose expression by porcine cardiac vascular endothelium

Galactose α(1,3) galactose (Gal) is the terminal carbohydrate moiety recognized by xenoreactive natural antibodies during hyperacute rejection (HAR). Binding of these antibodies in HAR triggers rapid microvascular thrombosis. We examined the distribution of Gal on the endothelium of porcine hearts before and after heterotopic xenotransplantation into baboons. We found that Gal is strongly expressed on the endothelium of porcine capillaries with less expression on the endothelium of larger vessels. The distribution of Gal staining remains unchanged after xenotransplantation and correlates with the intensity of IgM and membrane attack complex (MAC) deposition. Thus, the Gal epitope is differentially expressed in the pig vasculature, which affects the pattern of xenoreactive antibody and MAC deposition and directs the distribution of vascular thrombosis.     

Potential of an injectable polymer to prevent hyperacute rejection of ex vivo perfused porcine lungs

BACKGROUND: Removal of xenoreactive antibodies in pig-to-human lung transplantation by columns or organ perfusions proofed to be unsatisfactory and associated with adverse effects. In an ex-vivo lung perfusion model, we evaluated the potential of a soluble trisaccharide polymer (GAS914) to bind alpha-Gal antibodies and to protect a pulmonary xenograft from hyperacute rejection (HAR) and pulmonary xenograft dysfunction. METHODS: Porcine lungs were perfused with fresh human blood for 240 min. In the GAS914 treated group (n=6) the polymer was applied in three different concentrations. The control group (n=6) received no GAS914. Survival and function of perfused xenografts were monitored, and alpha-Gal antibodies as well as cytolytic anti-porcine antibodies analyzed. RESULTS: In the GAS-treated group survival of lungs was significantly prolonged, pulmonary vascular resistance reduced, pulmonary edema prevented, and oxygenation improved. On histopathological evaluation application of GAS resulted in minimal graft injury and significantly less deposition of the terminal complement complex C5b-9. Following application of GAS914, up to 89.8% of IgG alpha-Gal, 79.5% of IgM and 73.6% of anti-porcine antibodies in the human blood were bound by the polymer. Subsequent perfusion of porcine lungs resulted in absorption of only 3% of the baseline IgG alpha-Gal antibodies in the GAS914 group, compared to 87% in the controls. CONCLUSIONS: In this ex-vivo lung perfusion model, a trisaccharide polymer prevented immediate HAR, due to effective removal of alpha-Gal antibodies. In combination with additional strategies GAS914 may be a valuable tool in overcoming HAR and dysfunction of pulmonary xenografts.     

Fresh porcine cardiac valves are not rejected in primates

OBJECTIVE: Transplanted porcine hearts are hyperacutely rejected by human immunoglobulin M antibodies against a porcine vascular endothelial molecule, galactose alpha-1,3-galactose, with ensuing human complement activation and membrane attack complex deposition. It is unclear, however, whether porcine valve endothelium triggers a similar immune response. We sought to investigate whether fresh porcine valves implanted into primates are rejected. METHODS: Wild-type porcine hearts before (n = 6) and after (n = 3) heterotopic transplantation into baboons underwent sectioning and were examined by hematoxylin and eosin staining and immunohistochemistry for galactose alpha-1,3-galactose, primate immunoglobulin M, and membrane attack complex. RESULTS: Examination of untransplanted porcine hearts showed that although cardiac microvascular endothelium strongly expressed the galactose alpha-1, 3-galactose antigen, galactose alpha-1,3-galactose was not detected on the endothelium of porcine aortic and pulmonary valves. Porcine hearts transplanted into baboon recipients were hyperacutely rejected 60 to 80 minutes after implantation. Despite dramatic tissue damage associated with extensive immunoglobulin M and membrane attack complex binding on the microvascular endothelium, the aortic and pulmonary valves were entirely spared. Valves remained morphologically intact at explant and showed no signs of immunoglobulin M- and membrane attack complex-mediated damage. CONCLUSIONS: The absence of galactose alpha-1,3-galactose expression may protect unfixed porcine valves from xenograft rejection in primates. Further investigation of viable porcine valves appears warranted.     

Life-supporting human complement regulator decay accelerating factor transgenic pig liver xenograft maintains the metabolic function and coagulation in the nonhuman primate for up to 8 days

BACKGROUND: It is not known whether the pig liver is capable of functioning efficiently when transplanted into a primate, neither is there experience in transplanting a liver from a transgenic pigs expressing the human complement regulator human complement regulator decay accelerating factor (h-DAF) into a baboon. The objective of this study was to determine whether the porcine liver would support the metabolic functions of non-human primates and to establish the effect of hDAF expression in the prevention of hyperacute rejection of porcine livers transplanted into primates. METHODS: Five orthotopic liver xenotransplants from pig to baboon were carried out: three from unmodified pigs and two using livers from h-DAF transgenic pigs. FINDINGS: The three control animals transplanted with livers from unmodified pigs survived for less than 12 hr. Baboons transplanted with livers from h-DAF transgenic pigs survived for 4 and 8 days. Hyperacute rejection was not detected in the baboons transplanted with hDAF transgenic pig livers; however, it was demonstrated in the three transplants from unmodified pigs. Baboons transplanted with livers from h-DAF transgenic pigs were extubated at postoperative day 1 and were awake and able to eat and drink. In the recipients of hDAF transgenic pig livers the clotting parameters reached nearly normal levels at day 2 after transplantation and remained normal up to the end of the experiments. In these hDAF liver recipients, porcine fibrinogen was first detected in the baboon plasma 2 hr postreperfusion, and was present up to the end of the experiments. One animal was euthanized at day 8 after development of sepsis and coagulopathy, the other animal arrested at day 4, after an episode of vomiting and aspiration. The postmortem examination of the hDAF transgenic liver xenografts did not demonstrate rejection. INTERPRETATION: The livers from h-DAF transgenic pigs did not undergo hyperacute rejection after orthotopic xenotransplantation in baboons. When HAR is abrogated, the porcine liver maintains sufficient coagulation and protein levels in the baboon up to 8 days after OLT.     

Increased immunosuppression, not anticoagulation, extends cardiac xenograft survival

BACKGROUND: Cardiac xenograft function is lost due to delayed xenograft rejection (DXR) characterized by microvascular thrombosis and myocardial necrosis. The cause of DXR is unknown but may result from thrombosis induced by antibody-mediated activation of endothelial cells and/or by incompatibilities in thromboregulatory interactions. METHODS: To examine these issues, a series (Groups 1-6) of previous transgenic CD46 pig-to-baboon heterotopic cardiac transplants were reanalyzed for baseline immunosuppressive levels, graft survival and infectious complications with and without systemic anticoagulation. Groups 1-4 received low dose tacrolimus and sirolimus maintenance therapy, with splenectomy, anti-CD20 and daily alpha-Gal polymer. Group 1 recipients received no anticoagulation. Groups 2-4 were anticoagulated with aspirin and Plavix, Lovenox, or Coumadin, respectively. Group 5 was treated with Lovenox and high dose tacrolimus and sirolimus maintenance therapy. Group 6 recipients received no postoperative anticoagulation but the same immunosuppression as group 5. RESULTS: Median survival (15-22 days) within groups 1-4 was not significantly different. At rejection all tissues exhibited microvascular thrombosis, coagulative necrosis and similar levels of platelet and fibrin deposition. Groups 5 and 6 median survival (76 days) was significantly increased compared to groups 1-4. There was no significant difference in median survival between Lovenox treated recipients (68 days) and anticoagulant free recipients (96 days). Rejected tissues showed vascular antibody deposition, microvascular thrombosis, and myocyte necrosis. CONCLUSION: Significant prolongation in xenograft survival is achieved by improved immunosuppression. These results suggest that ongoing immune responses remain the major stimulus for DXR.     

The pig analogue of CD59 protects transgenic mouse hearts from injury by human complement

BACKGROUND: It has been proposed that hyperacute rejection (HAR) of pig-to-primate vascularized xenografts is due in large part to ineffective regulation of recipient complement by pig complement regulatory proteins (CRPs), and indeed transgenic expression of human CRPs in pigs can prevent hyperacute rejection. However, at least one pig CRP (CD59) efficiently regulates human complement in vitro, suggesting that it is the level of expression of a particular CRP(s) rather than cross-species incompatibility that explains the HAR of porcine xenografts. We investigated the relative effectiveness of transgenically expressed pig and human CD59 in providing protection of mouse hearts from human complement in an ex vivo setting. METHODS: Transgenic mice expressing pig CD59 or human CD59 under the control of the human ICAM-2 promoter, which restricts expression in tissues to vascular endothelium, were used. Hearts from mice expressing similar levels of pig CD59 or human CD59 were perfused ex vivo with 10% human plasma and heart function was monitored for 60 min. Sections of perfused hearts were examined for deposition of the membrane attack complex (MAC). RESULTS: Control nontransgenic hearts (n=5) were rapidly affected by the addition of human plasma, with mean function falling to less than 10% of the initial level within 15 min. In contrast, hearts expressing either pig CD59 (n=6) or human CD59 (n=8) were protected from plasma-induced injury, maintaining 31 and 35% function, respectively, after 60 min of perfusion. MAC deposition was markedly reduced in both pig CD59 and human CD59 transgenic hearts compared to nontransgenic control hearts. CONCLUSIONS: When highly expressed on endothelium in transgenic mice, pig CD59 provided equivalent protection to human CD59 in a model of human complement-mediated xenograft rejection. Thus supranormal expression of endogenous porcine CRPs may be a feasible alternative to the expression of human CRPs in preventing HAR of pig-to-primate xenografts.     

The study of mitoxantrone as a potential immunosuppressor in transgenic pig renal xenotransplantation in baboons: comparison with cyclophosphamide

Mounting evidence suggests that delayed xenograft rejection (DXR) of discordant xenografts has a strong humoral component. To explore the possibility of targeting this humoral response more efficiently, we performed a preliminary study in baboons immunized against pig blood cells using the immunosuppressor mitoxantrone (Mx). The results from this study showed that, in comparison with cyclophosphamide (CyP), Mx induced a long-lasting depletion of circulating B cells within 6 days of its administration and delayed secondary anti-Gal antibody (Ab) responses to pig blood cell immunizations. Given these results, we next evaluated Mx in an in vivo model of pig to baboon renal xenotransplantation. We performed a series of renal xenotransplantations in baboons using human CD55-CD59 transgenic donor pigs. In the first group of baboons (Mx group; n = 4) Mx was administered 6 days prior to the day of transplantation, the objective being to perform the xenotransplantation in a context where the recipient would have few remaining circulating B cells and thus have an impaired capacity to mount an Ab response to the xenograft. We compared this group to a second group of baboons treated with CyP starting 1 day prior to transplantation (CyP group; n = 2). All baboons receiving Mx or CyP received an additional immunosuppression of cyclosporin A, mycophenolate mofetil and steroids. No hyperacute rejection was observed in either group but all xenografts underwent DXR. Mx did not show superiority to CyP in terms of graft survival with a mean survival time of 8 +/- 2 days compared with 9 days for both CyP-treated baboons. Neither CyP nor Mx decreased serum levels of pre-existing anti-Gal Abs but levels of these Abs decreased dramatically within 1 day of transplantation, likely reflecting their immediate trapping within the xenograft. Interestingly however, in contrast to CyP, Mx inhibited the return of anti-Gal immunoglobulin M (IgM) to the circulation, even at the time of rejection. Nevertheless, strong intragraft deposits of IgM, IgG and the activated complement complex C5b-9 were observed in biopsies at rejection. Furthermore, despite the expected profound depletion of circulating B cells by Mx within 6 days of its administration, biopsies from both groups at rejection displayed a mild B cell infiltrate accompanied by a strong macrophage and intermediate T-cell infiltration, the latter tending to be more abundant in Mx-treated animals. Our data show that in this particular model of pig to baboon xenotransplantation and at the dose used, Mx was not superior to CyP in conferring protection against rejection, despite its capacity to profoundly deplete circulating B cells and to inhibit anti-Gal Ab responses to xenografts. DXR was thus possible without the return of anti-Gal Abs and may have been mediated by the early fixation of pre-existing Abs with secondary complement activation. However, although Mx was not more efficient than CyP in controlling DXR, its capacity to deplete B cells and delay Ab recovery may be beneficial in the context of Gal knockout organ transplantation where the induced Ab response is likely to take precedence over the preformed response.     

The effect of immunoglobulin immunadsorptions on delayed xenograft rejection of human CD55 transgenic pig kidneys in baboons

Delayed xenograft rejection (DXR) remains a major obstacle in discordant xenotransplantation. As strategies of complement inhibition and xenogeneic natural antibody (Ab) removal have been shown to give prolonged xenograft survival, we endeavored to determine whether combining these two strategies would lead to an additive effect in terms of graft survival. The study was initiated with two groups, A and B, where group A received normal kidneys and group B received hCD55 transgenic kidneys. Both groups underwent pre-transplant (day-1) total immunoglobulin (Ig) immunoadsorption (IA) and received an immunosuppression of cyclophosphamide, cyclosporine A, mycophenolate mofetil and corticosteroids. Two subsequent groups (C and D) receiving hCD55 transgenic pig kidneys were then performed with an 'optimized' immunosuppression (Cyclophosphamide starting 1 day earlier) but only group D recipients were immunoadsorbed. Biopsies taken during the post-transplantation period were analyzed for Ab deposition, compliment activation and cellular infiltration. No hyperacute rejection was observed. In the initial immunoadsorbed groups A and B, all baboons underwent DXR, which started surprisingly early (day 5 in most cases. In the subsequent two groups, the immunoadsorbed group D baboons also underwent DXR, again as early as day 5. In contrast, group C baboons did not show any signs of DXR on their day 6 biopsy or at their time of death. Analysis of graft biopsies from the kidneys undergoing rejection or with stable function showed strong deposition of anti-Gal IgM in all cases whereas strong complement C5b-9 deposits were only observed in biopsies at rejection. Cellular infiltration consisted mostly of monocytes/macrophages, was more pronounced in biopsies taken at rejection and was associated with a pro-inflammatory environment involving interleukins 1alpha, 6 and 8. Our findings suggest non-specific Ig (anti-Gal and non-Gal Ig of all isotypes) IA or even incomplete IA in immunosuppressed baboon recipients of transgenic pig kidneys is detrimental to graft survival by being associated with an Ab and compliment driven rejection. We speculate that the IA were insufficient in terms of Ig depletion or frequency inducing an Ab rebound or that this total Ig depletion also removed components facilitating graft survival.     

Immunopathology of an hDAF transgenic pig model liver xenotransplant into a primate

BACKGROUND: hDAF transgenic pigs do not display the inherent hyperacute rejection reactions of pig-to-primate xenotransplants. The purpose of this study was to determine the immunopathologic phenomena following an hDAF transgenic pig hepatic orthotopic xenotransplant into a baboon. METHODS: Donor animals were unmodified pigs (n=4) and hDAF transgenic pigs (n=2). Recipient animals were baboons (Papio anubis). Liver biopsies were immunostained using monoclonal antibodies to C3, C5b-9, IgG, IgM, CD2, CD4, CD8, CD68, CD20, Bric 216, CD31, and fibrin, and polyclonal antibody to C4. RESULTS: hDAF transgenic grafts showed IgG, IgM, and C4 endothelial deposits. However, no fibrin, C3, or C5b9 deposits were observed after reperfusion. hDAF xenografts displayed CD31 staining in the portal spaces, perilobular areas, and at hepatic sinuisoidal levels. The baboon that lived for 4 days displayed either CD4 or CD8 T-cells periportal infiltrate. CONCLUSIONS: Future studies will seek to determine the physiologic role of CD31 hepatic sinusoidal expression in transgenic xenotransplants, and will also study the role of T-cell infiltrates in xenograft rejection.     

Thrombin Inhibition in discordant xenograft rejection

Abstract: Microvascular thrombosis and the associated platelet and endothelial cell activation are prominent observations in xenograft rejection. This pathological picture could be related to the excessive generation of thrombin in the context of either inflammation or putative inter-species molecular incompatibilities between activated coagulation factors and their natural anticoagulants. Relatively selective thrombin Inhibition with the serine protease inhibitor SDZ MTH 958 (MTH-958) are independent of heparinoids and anti-thrombin III. MTH-958 has been shown to significantly prolong porcine cardiac function during perfusion with human blood in an ex vivo model. The aim of this study was to validate the role of thrombin generation in a rodent model of discordant xenograft rejection in vivo. The effect of thrombin inhibition with MTH-958 was tested in both hyperacute rejection (HAR) and delayed xenograft rejection (DXR) after decomplementation with cobra venom factor (CVF) in normal Lewis (Lew) rats and Intrinsic C6 deficiency In PVG (C6-/PVG) recipient rats. Recipient rats received heterotopic guinea pig cardiac xenografts and were treated with titrated doses of MTH-958 until the time of graft rejection. Plasma samples at selected time points were examined to confirm effective thrombin inhibition, and rejected grafts were analyzed by immunohistology. MTH-958 significantly improved graft survival in HAR albeit the extent of prolongation was not marked, but the agent failed to prolong survival In CVF-treated Lew rats. In C6-/PVG rats receiving MTH-958, a significantly reduced graft survival time was observed when compared with C6-/PVG controls. The grafts from MTH-958-treated animals showed dense deposits of C3, IgM, and IgG with fibrin levels similar to controls. The thrombin antagonist tested could prolong xenograft survival during HAR but had no benefit in DXR. The relative non-specificity of the serine protease inhibitor MTH-958 with the potential activation of alternative pathway of complement via the inhibition of factor I could account for the failure to prolong xenograft survival in DXR. The pathogenetic significance of thrombin generation in this situation remains to be determined by the use of more selective and pharmacologically acceptable I anti-thrombin agents.     

Acute vascular rejection of xenografts: roles of natural and elicited xenoreactive antibodies in activation of vascular endothelial cells and induction of procoagulant activity

BACKGROUND: Hyperacute rejection of vascularized discordant xenografts can now be effectively managed. However, acute vascular rejection (AVR) then ensues, resulting in graft destruction, coagulopathy, or both within weeks. The aim of this study was to determine associations between humoral responses to the xenograft and the induction of AVR, coagulopathy, or both. METHODS: In vitro, heat-inactivated, naive or sensitized baboon sera containing xenoreactive natural or elicited antibodies were used to activate porcine aortic endothelial cells (PAEC) in vitro. Tissue factor expression on PAEC was determined as an index of heightened procoagulant activity. In vivo, porcine renal xenografts were transplanted into immunosuppressed baboons, and at the time of rejection or the development of a consumptive coagulopathy, biopsy specimens were obtained for studies of xenoreactive antibody binding and tissue factor expression. RESULTS: In vitro, incubation of PAEC with naive baboon sera containing natural anti-Galalpha1,3Gal (Gal) antibodies resulted in minimal tissue factor induction; the addition of complement boosted procoagulant responses. Elicited xenoreactive antibodies, and to non-Gal epitopes alone, induced high amounts of procoagulant activity on PAEC; the addition of complement resulted in overt cytotoxicity. In vivo, AVR was associated with xenoreactive antibody deposition in the graft. When vascular endothelial binding of xenoreactive antibody was combined with the expression of tissue factor, consumptive coagulopathy developed irrespective of histopathologic features of AVR. CONCLUSIONS: Our in vitro results indicate that elicited antibodies, potentially to non-Gal epitopes, induce endothelial cell activation and tissue factor expression; in vivo, a consumptive coagulopathy occurred when there was xenoreactive antibody deposition and increase of tissue factor.     

Thrombotic microangiopathy and graft arteriopathy in pig hearts following transplantation into baboons

BACKGROUND: Acute humoral xenograft rejection (AHXR) is an immunologic barrier in pig-to-baboon organ transplantation (Tx). We report microvascular thrombosis and myocardial necrosis in a series of cardiac xenografts. METHODS: Ten baboons underwent heterotopic heart Tx from pigs transgenic for human decay-accelerating factor. Recipients were treated with soluble Gal glycoconjugates and multiple immunosuppressive agents. Grafts were removed when palpable contractions stopped. Stained tissue sections from harvested grafts were analyzed by light and fluorescence microscopy. RESULTS: Xenograft survival ranged from 4 to 139 (mean 37, median 27) days. Some histology was typical for AHXR (n = 4; median survival 22 days). Hemorrhage and edema were only focal in the longer-surviving grafts (n = 4, median survival 54 days). All grafts had multiple platelet-rich fibrin thrombi occluding myocardial vessels. Ischemic damage was manifested by contraction band necrosis in four grafts, myocytolysis in eight, coagulative necrosis in nine, and patchy myocyte dropout in all grafts. A notable paucity of interstitial mononuclear cells was observed in all grafts. Marked intimal thickening resembling that of allograft vasculopathy was observed in one graft. Immunofluorescence showed immunoglobulin (Ig)G and/or IgM deposition in five grafts. Multivessel C4d deposition appeared in seven grafts. Significant C3 deposition was absent. CONCLUSIONS: Cardiac xenograft survival in the pig-to-baboon model can be significantly prolonged by vigorous immunosuppressive treatment of recipient animals. Additional efforts to block humoral activation of graft endothelial cells and/or to overcome species-specific molecular coagulation pathway incompatibilities may prevent the development of microvascular thrombosis and myocardial infarction. Cardiac xenograft vasculopathy (chronic rejection) can occur with prolonged graft survival.     

The role of the porcine von Willebrand factor: baboon platelet interactions in pulmonary xenotransplantation

BACKGROUND: Porcine von Willebrand factor (pvWF) has been shown to bind to human glycoprotein Ib (GPIb) and cause activation of human (or primate) platelets in the absence of shear stress. Pulmonary xenografts develop disseminated intravascular coagulation (DIC) and microvascular thrombosis within hours of reperfusion, and the aberrant interaction between pvWF and human platelets may be a possible cause of xenograft-associated DIC. METHODS: Experimental baboons (n=3) received mouse anti-human GPIb monoclonal antibody before undergoing orthotopic pulmonary xenotransplantation with porcine lungs expressing human membrane cofactor protein (CD46). RESULTS: Blocking the pvWF-GPIb interaction with a monoclonal antibody to GPIb prevented the agglutination of human and baboon platelets by pvWF in vitro. In vivo, the anti-GPIb antibody prevented platelet deposition and prevented the increases in D-Dimers (P=0.011) seen in control xenograft recipients (n=5). However, there was no difference in elevations of prothrombin times (PT) or improvement in the vasoconstriction associated with the loss of xenograft function. CONCLUSIONS: This study indicates that the DIC associated with the hyperacute dysfunction of pulmonary xenografts is a complex phenomenon that is affected by, but not solely dependent on, activation of platelets. Aberrant interactions between pvWF and GPIb play a significant role in DIC associated with pulmonary xenotransplantation.     

Porcine cytomegalovirus and coagulopathy in pig-to-primate xenotransplantation

BACKGROUND: A rapidly progressive disorder termed consumptive coagulopathy (CC) has been observed frequently in pig-to-baboon renal xenotransplantation. CC may be initiated by endothelial activation and induction of procoagulant factors after immunologic injury or infection, or by molecular incompatibilities between porcine coagulation proteins and primate clotting factors. The activation of porcine (P) cytomegalovirus (PCMV) and baboon (B) CMV infections has been documented in pig-to-primate xenotransplantation. The purpose of this study was to determine the contribution of PCMV and BCMV to CC. METHODS: Endothelial activation was assessed by means of measurement of porcine tissue factor (pTF) in a functional assay in primary porcine aortic endothelial cells (PAEC) in vitro. Renal xenografts and native kidneys were studied by immunohistochemistry in immunosuppressed swine and baboons. BCMV and PCMV DNA was measured by quantitative molecular assays using real-time polymerase chain reaction. RESULTS: In vitro, infection of PAEC with PCMV resulted in a significant increase of pTF expression. In vivo, pTF increase occurred without the activation of PCMV in two xenografts, and in four grafts no pTF was detected despite PCMV activation. All animals with graft pTF increase developed CC. BCMV activation in the baboon xenograft recipients did not correlate with CC or pTF increase. Control pigs and baboons had activation of PCMV and BCMV, respectively, but without coagulation abnormalities. CONCLUSIONS: PCMV induces endothelial cell activation in vitro with procoagulant expression. However, in vivo, CC and pTF induction has an uncertain relationship to increased replication of PCMV within a xenograft. Although the data do not exclude a contributory role of PCMV in CC, other mechanisms are also likely to contribute to coagulopathies observed in pig-to-primate xenotransplantation.     

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.     

Pathogenesis and pathology of delayed xenograft rejection in pig-to-rhesus monkey cardiac transplantation

It has been recognized that delayed xenograft rejection (DXR) is the major barrier to the acceptance of xenotransplantation after overcoming hyperacute rejection. OBJECTIVES: This study sought to investigate the pathogenesis and pathology of delayed xenograft rejection following pig-to-rhesus monkey heart xenotransplantation. METHODS: Heterotopic xenogeneic heart transplants in the abdominal cavity were performed using piglet donors to four monkey recipients. Complete complement depletion was achieved in the recipients with repetitive doses of high-activity cobra venom factor (Y-CVF). The recipients were immunosuppressed with a combination of cyclosporine, cyclophosphamide, and steroids. Sera were analyzed for C3 and C4 levels and complement activity and anti-pig endothelial xenoantibody. The grafts were examined histopathologically and immunohistochemically for C3, C4;C5b-9, IgM, IgG, tumor necrosis factor-alpha (TNF-alpha), intercellular adhesion molecule-1(ICAM-1), CD57(NK cells), CD68 (macrophages), CD4, and CD8. RESULTS: Xenografts survived 8, 10, 13, and 13 days respectively, all developing DXR. Venous thrombosis was the outstanding feature within DXR xenografts, complicated by interstitial edema, local hemorrhage, myocardial necrosis, and mild to moderate cellular infiltration. The serum C3 levels and complement activity decreased to almost 0 from the day of transplantation due to treatment with Y-CVF. The C4 level began to decrease 2 to 4 days before the cardiac xenografts lost their function. Anti-pig endothelial xenoantibody also decreased after transplantation, slightly increasing during DXR. All rejected xenografts showed C3, C4, C5b-9, IgG, and IgM deposits to various degrees. Large numbers of macrophages (50% of total leukocytes) infiltrated the entire xenograft with a few natural killer cells (8% to 10%), as well as some CD4+ T cells (15%) and CD8+ T cells (25%). Upregulation of ICAM-1 on graft endothelial cells and TNF-alpha in the interstitium were also demonstrated in the rejected heart. CONCLUSION: Both humoral and cell-mediated immunologic reactions may play important roles in the pathogenesis of DXR. Besides C3, C4, C5b-9, IgM, and IgG destroying the xenograft, NK cells, macrophages, and CD4+ and CD8+ T cells may further aggravate the development of DXR.     

单核细胞、NK细胞和T细胞在猪-猕猴延迟性异种移植排斥反应中的作用

目的观察单核细胞、NK细胞和T细胞在猪-猕猴延迟性异种移植排斥反应(DXR)中的作用。方法建立湖北白猪-云南猕猴的腹腔异位心脏移植模型，实验分为2组：对照组(n=5)，不使用中华眼睛蛇毒因(Y-CVF)；实验组(n=4)应用Y-CVF完全清除受者体内补体。2组受体猴均采用环孢素A(CsA)，环磷酰胺(CTX)和甲基强的松龙(MP)三联免疫抑制治疗。免疫组织化学方法检测移植心组织中细胞间黏附分子(ICAM)-1、肿瘤坏死因子(TNF)-α、单核细胞、NK细胞和T细胞的表达。结果对照组3个移植心在15～60min内发生超急性排斥反应(HAR)，另2个分别存活22h及6d，移植心均未见明显的炎性细胞浸润及ICAM-1和TNF-α的表达。实验组移植心存活时间分别为8、10、13和13d，移植物浸润细胞中可见大量的单核细胞(50％)，少量的NK细胞(8％～10％)，CD4^ T细胞(15％)和C08^ T细胞(25％)。移植物血管内皮细胞表面出现ICAM-1的表达上调，移植物间质中出现TNF-α的表达增加。结论单核细胞、NK细胞和T细胞介导的移植物损伤，在应用Y-CVF处理的猪-猕猴DXR发生中发挥重要作用。     

Acute vascular rejection is associated with systemic complement activation in a pig-to-primate kidney xenograft model

The introduction of h-DAF transgenic porcine organs into pre-clinical pig-to-primate discordant xenotransplantation has led to complete and reliable abrogation of hyperacute xenograft rejection (HAR). Despite additional heavy immunosuppression however, most xenografts are still lost due to acute vascular rejection (AVR), with current treatment protocols being of only limited value. In a life-supporting model of pig-to-primate kidney transplantation, unmodified (n=8) or h-DAF-transgenic (n=9) porcine kidneys were transplanted into cynomolgus monkeys under cyclophosphamide (CyP), cyclosporine and low-dose steroid immunosuppression. Longest recipient survival was 11 days in the control group and 68 days in the h-DAF transgenic group. Stable initial graft function with recipient survival >4 days was generated in eight animals (two controls and six transgenics). In these animals, plasma complement levels were analyzed during ongoing AVR. Compared with baseline levels, a two-fold increase in C3a levels and a four-fold increase in sC5b-9 levels were measured. In parallel to systemic complement activation, increased deposition of C3 and C5b-9 along with massive staining for recipient IgM immunoglobulins was detected in the xenografts on immunohistochemistry. We conclude that acute vascular xenograft rejection of porcine kidneys in cynomolgus monkeys is associated with classical pathway complement activation following binding of induced recipient anti-porcine antibodies. This complement activation can be observed despite membrane bound expression of human complement regulators in the porcine xenografts. Therefore, additional short-term fluid phase complement inhibition seems necessary for the future development of protocols designed for treatment of AVR in the pig-to-primate combination.