Pre-treatment of donor with 1-deamino-8-d-arginine vasopressin could alleviate early failure of porcine xenograft in a cobra venom factor treated canine recipient.

OBJECTIVE: Unlike cardiac or renal xenotransplants, the depletion of complement using cobra venom factor (CVF) does not improve pulmonary xenograft survival. Several cases suggest that the swine von Willebrand factor (vWF) may play a major role in presenting a different pathogenesis of pulmonary xenograft dysfunction from other organs. To evaluate the role of vWF and the complement system in mediating hyperacute vascular injury of pulmonary xenografts and elucidate pathogenesis of the injury, we performed swine-to-canine orthotropic single lung xenotransplantation after pre-treatment of 1-deamino-8-d-arginine vasopressin (DDAVP) and CVF. METHODS: We set up three groups for lung xenotransplantation: group I served as the control group; group II, recipients pre-treated with CVF; group III, donors pre-treated with DDAVP (9 mg/kg, 3 days)/recipients pre-treated with CVF (60 u/kg). Hemodynamic data, coagulation and complement system parameters, and grafted lung pathologies were examined serially for 3h after transplantation. RESULTS: DDAVP infusion reduced the vWF content in swine lung tissue in vivo (7.7+/-2.4 AU/mg vs 16.0+/-5.6 AU/mg, P < 0.0001). Infusion of CVF 24 h prior to transplantation effectively depleted the recipient's serum C3 and complement hemolytic activity below the detectable range. Regardless of the use of CVF, both groups I and II transplanted with unmodified grafts showed an immediate drop in leukocytes and platelet counts after transplantation. However, in group III, in recipients transplanted with DDAVP pre-treated swine lung, the platelet count did not decrease after transplantation (P = 0.0295). The decrease of plasma antithrombin and fibrinogen tended to be attenuated in group III. Light microscopic examination revealed extensive vascular thromboses in both capillary and larger vessels, as well as early pulmonary parenchymal damage in groups I and II, but were rarely observed in group III. CONCLUSIONS: Complement inhibition alone was not enough to alleviate intravascular thrombosis, the main pathology in pulmonary xenotransplantation. Pre-infusion of DDAVP to the donor animal was effective in preventing platelet sequestration and attenuated intravascular thrombosis. It is suggested that the strategies targeting vWF would be promising for successful pulmonary xenotransplantation.     

Aurintricarboxylic acid inhibits endothelial activation, complement activation, and von Willebrand factor secretion in vitro and attenuates hyperacute rejection in an ex vivo model of pig-to-human pulmonary xenotransplantation

Abstract: Background: In the xenotransplantation of vascularized organs, such as the lung, a large area of endothelial cell layer is a big hurdle to be overcome. We investigated the potential protective effect of aurintricarboxylic acid (ATA), a known inhibitor of platelet adhesion, on endothelial damage induced by xenogeneic serum. We also assessed its role in hyperacute xenograft rejection using a porcine ex vivo lung perfusion model. Methods: Porcine endothelial cells were incubated with human serum and other inflammatory stimuli. For the evaluation of von Willebrand factor (vWF) secretion and tissue factor (TF) expression, we used human endothelial cells. E‐selectin expression, complement activation, TF expression and platelet activation were investigated by flow cytometry. In an ex vivo porcine lung perfusion model, the porcine lungs were perfused with fresh human whole blood: unmodified blood (n = 5), ATA‐treated blood (n = 5), and ATA and lepirudin‐treated blood (n = 5). Results: Aurintricarboxylic acid significantly inhibited TNF‐α‐ or lipopolysaccharide‐induced endothelial E‐selectin expression in a dose‐dependent manner. ATA also prevented human serum induced‐E‐selectin expression and human monocytic cell adhesion to porcine endothelial cells. Moreover, ATA abolished thrombin‐induced vWF secretion as well as complement activation. However, ATA induced endothelial TF expression and platelet activation in vitro. In ex‐vivo experiments, ATA treatment improved pulmonary function and attenuated sequestration of leukocytes. Although ATA did not influence thrombin generation, we were able to minimize its activity by adding lepirudin to the blood with ATA. Conclusions: Our study demonstrated in vitro protective effect of ATA on the inhibition of endothelial activation and vWF secretion and confirmed detrimental effect of ATA on induction of endothelial TF and platelet activation. The combination of ATA and lepirudin may act beneficially by preventing coagulation perturbation while maintaining improved xenograft survival.     

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.     

Hyperacute rejection is attenuated in GalT knockout swine lungs perfused ex vivo with human blood

BACKGROUND: Hyperacute rejection (HAR) is one of the principal obstacles to successful xenotransplantation. Homozygous alpha-1,3-galactosyltransferase knockout (GalT-KO) miniature swine now offer the prospect of overcoming this barrier to xenotransplantation. In this study, the short-term function of GalT-KO swine lungs was evaluated in a well-established ex vivo model of swine-to-human lung xenotransplantation. METHODS: Lungs from homozygous GalT-KO swine (n = 3) and control lungs from pigs of the background strain used to create the GalT-KO pig line (n = 2) were perfused ex vivo with freshly collected heparinized human blood. Graft function was assessed by various physiologic measurements, serial histologic and immunohistochemical evaluation, and assays of complement and platelet activation. RESULTS: Xenoperfused control swine lungs exhibited HAR with graft survival times <5 minutes. In contrast, GalT-KO swine lungs retained their function for approximately 2 hours, on average. GalT-KO swine lungs showed decreased complement and platelet activation compared with controls. Nonetheless, activation of complement and coagulation cascades was not completely eliminated in the GalT-KO swine lungs. CONCLUSIONS: The survival of xenoperfused GalT-KO swine lungs was significantly prolonged, as compared with control lungs expressing Gal. This appears to have been due largely to substantially reduced complement activation. Nonetheless, the xenoperfused GalT-KO lungs still showed some evidence of complement fixation and intravascular coagulopathy by the time of graft demise.     

Absence of Gal epitope prolongs survival of swine lungs in an ex vivo model of hyperacute rejection

Nguyen B‐NH, Azimzadeh AM, Schroeder C, Buddensick T, Zhang T, Laaris A, Cochrane M, Schuurman H‐J, Sachs DH, Allan JS, Pierson RN. Absence of Gal epitope prolongs survival of swine lungs in an ex vivo model of hyperacute rejection. Xenotransplantation 2011; 18: 94–107. © 2011 John Wiley & Sons A/S. Abstract: Background: Galactosyl transferase gene knock‐out (GalTKO) swine offer a unique tool to evaluate the role of the Gal antigen in xenogenic lung hyperacute rejection. Methods: We perfused GalTKO miniature swine lungs with human blood. Results were compared with those from previous studies using wild‐type and human decay‐accelerating factor‐transgenic (hDAF^+/+) pig lungs. Results: GalTKO lungs survived 132 ± 52 min compared to 10 ± 9 min for wild‐type lungs (P = 0.001) and 45 ± 60 min for hDAF^+/+ lungs (P = 0.18). GalTKO lungs displayed stable physiologic flow and pulmonary vascular resistance (PVR) until shortly before graft demise, similar to autologous perfusion, and unlike wild‐type or hDAF^+/+ lungs. Early (15 and 60 min) complement (C3a) and platelet activation and intrapulmonary platelet deposition were significantly diminished in GalTKO lungs relative to wild‐type or hDAF^+/+ lungs. However, GalTKO lungs adsorbed cytotoxic anti‐non‐Gal antibody and elaborated high levels of thrombin; their demise was associated with increased PVR, capillary congestion, intravascular thrombi and strong CD41 deposition not seen at earlier time points. Conclusions: In summary, GalTKO lungs are substantially protected from injury but, in addition to anti‐non‐Gal antibody and complement, platelet adhesion and non‐physiologic intravascular coagulation contribute to Gal‐independent lung injury mechanisms.     

Bio artificial pancreas – the immune barrier and oxygen deficiency

The heterotopic thoracic pig‐to‐baboon heart transplantation has been established by our group as a safe preclinical model. Since the recipient's own heart remains in place, it is possible to evaluate immunological reactions of various types and the symptoms of the thrombotic microangiopathy under working heart conditions. However, these experiments are complex and costly. In order to limit the number of transplants, we tested our multi‐transgenic porcine donor hearts in an ex‐vivo perfusion model first. Ex‐vivo model: Both beating ventricles were perfused with heparinized freshly drawn human whole blood using a centrifugal pump and a membrane oxygenator. During 3 h of observation, cardiac function parameters were obtained continuously; specimens from the perfusate, coronary sinus blood, and myocardial biopsies were assessed. Various genetically modified porcine donor hearts were tested; we are currently evaluating the impact of human thrombomodulin on the porcine microcirculation; the efficacy of complement regulation is another work package. Pig‐to‐baboon heterotopic cardiac xenotransplantation: In our latest group, seven baboons received five double (Gal‐KO/hCD46), and two triple (Gal‐KO/hCD46/hTM resp./HLA‐E) transgenic pig hearts. Our immunosuppressive regimen included preoperative anti‐CD20‐antibody, bortezomib, dexamethasone and cyclophosphamide; postoperatively, ATG, tacrolimus, MMF, anti‐CD20‐antibody, bortezomib and dexamethasone were administered. Total lymph node irradiation (6 Gy) was applied on postoperative day five. The triple transgenic hearts survived 35 and 37 days respectively. Both hearts maintained function throughout the experiment. Both recipients succumbed to fungal infections. Humoral rejection was seen only once. The next barrier appears to be the complex event of thrombotic microangiopathy that needs to be addressed with the additional expression of human thrombomodulin strategies.     

Lung xenogenic injury: does anticoagulation help?

The shortage of human organ donors remains a major limitation to the field of transplantation [1], and can potentially be solved using xenografts. During the past decade, many advances have been made to address the major initial immunological obstacle to “discordant” pig‐to‐human solid organ transplantation: hyperacute rejection (HAR). As organs from unmodified pigs were evaluated in animal models, HAR was found to be primarily a consequence of the recipient's preformed anti‐pig antibodies binding on porcine vascular endothelial cells leading to subsequent complement activation, thrombosis and graft failure [2]. This process occurs within minutes to hours of human blood perfusion in porcine organs. Since the carbohydrate structure Galactose‐α(1,3‐Galactose (Gal) is recognized by over 80% of anti‐pig antibodies found in man, genetically modified galactosyl transferase knock‐out (GalTKO) pig organs have been developed [3,4]. Endothelium and parenchymal cells from GalTKO animals lack the Galα1,3Gal epitope. As predicted, heart and kidney transplant studies in baboons showed that the GalTKO phenotype is associated with decreased antibody binding, reduced activation of the complement cascade and prolonged graft survival [5–8]. However, delayed xenograft rejection, consumptive coagulopathy and microangiopathy limit long‐term outcomes. Xenogenic lungs are even more sensitive to xenogenic injury [9, 10], even with additional expression of complement regulatory protein human CD46 [Burdorf et al]. Immunohistology and biochemical evidence and work by others implicated inflammation and coagulation cascade activation as residual xenogenic injury pathways. To determine the role of these pathways in lung xenogenic injury, our group is evaluating new transgenic pigs [11] and various pharmacologic approaches. New transgenes include human thrombomodulin (hTM), endothelial protein C receptor (EPCR) and ectonucleoside triphosphate diphosphohydrolase‐1 (CD39). Pharmacologic interventions consist in targeting platelet receptors (GPIb, GPIIbIIIa), thrombin (hirulog) and adding exogenous activated protein C to perfused human blood and administering desmopressin to lung donor pigs. The differential effects of these interventions on lung physiological parameters, platelet and coagulation activation will be summarized. Future work will place emphasis on combined targeting of these pathways. Acknowledgments: Funded in part by NIH (IU19A1090959, 1U01AI066335) and by gifts from Revivicor and United Therapeutics. References 1. Cooper DKC. Xenografting: how great is the clinical need? Xeno 1993; 1: 25–26. 2. Pierson RNIII. Antibody‐mediated xenograft injury: mechanisms and protective strategies. Transpl Immunol 2009; 21: 65–69. 3. Phelps CJ, Koike C, Vaught TD et al.Production of alpha 1,3‐galactosyltransferase‐deficient pigs. Science 2003; 299: 411–414. 4. Kolber‐ Simonds D, Lail L, Watt SR et al. Production of alpha‐1,3‐galactosyltransferase null pigs by means of nuclear transfer with fibroblasts bearing loss of heterozygosity mutations. Proc Natl Acad Sci U S A 2004; 101: 7335–7340. 5. Tseng YL, Kuwaki K, Dor FJ et al. alpha1,3‐Galactosyltransferase gene‐knockout pig heart transplantation in baboons with survival approaching 6 months. Transplantation 2005; 80: 1493–1500. 6. Kuwaki K, Tseng YL, Dor FJet al. Heart transplantation in baboons using alpha1,3‐galactosyltransferase gene‐knockout pigs as donors: initial experience. Nat Med 2005; 11: 29–31. 7. Yamada K, Yazawa K, Shimizu Aet al. Marked prolongation of porcine renal xenograft survival in baboons through the use of alpha1,3‐galactosyltransferase gene‐knockout donors and the cotransplantation of vascularized thymic tissue. Nat Med 2005; 11: 32–34. 8. Mohiuddin MM, Corcoran PC, Singh AK, et al. B‐cell depletion extends the survival of GTKO.hCD46Tg pig heart xenografts in baboons for up to 8 months. Am J Transplant. 2012; 12:763–71. 9. Nguyen BN, Azimzadeh AM, Zhang T, et al. Life‐supporting function of genetically modified swine lungs in baboons. J Thorac Cardiovasc Surg 2007; 133: 1354–1363. 10. Nguyen BN, Azimzadeh AM, Schroeder C et al. Absence of Gal epitope prolongs survival of swine lungs in an ex vivo model of hyperacute rejection. Xenotransplantation. 2011; 18:94–107. 11. Cooper DK, Ekser B, Burlak C et al. Clinical lung xenotransplantation – what donor genetic modifications may be necessary? Xenotransplantation. 2012; 19:144–58.     

The fate of human platelets perfused through the pig liver: implications for xenotransplantation

Burlak C, Paris LL, Chihara RK, Sidner RA, Reyes LM, Downey SM, Tector AJ. The fate of human platelets perfused through the pig liver: implications for xenotransplantation.
Xenotransplantation 2010; 17: 350–361. © 2010 John Wiley & Sons A/S. Abstract: Background: Pig liver xenotransplantation could offset the shortage of livers available for orthotopic liver transplantation. Studies in pig and baboon liver xenografts revealed the main obstacle to be a lethal thrombocytopenia that occurred within minutes to hours of transplantation. Methods: We have created a model of xenotransplantation‐induced thrombocytopenia using ex vivo pig liver perfusion with human platelets. Thrombocytopenia was examined using fluorescently labeled platelets during the ex vivo perfusion and coculture with primary liver sinusoidal endothelial cells (LSEC). Results: Ex vivo liver perfusion revealed that 93% of human platelets were removed from circulation after 15 min. Endothelial cells and platelets were not activated based on tissue factor release into the perfusate. Biopsies from the ex vivo perfusion at 15 and 30 min and in vitro analysis indicated that human platelets are phagocytosed by pig LSEC and degraded in phagosomes. Sixty to 120 min after the addition of platelets to the ex vivo perfusion system, we observed platelet fragments and degraded platelets in hepatocytes. Platelet phagocytosis was not mediated by opsonization as Fc blocking had no effect on platelet phagocytosis. In vitro uptake of human platelets by primary LSEC cultures peaked at 15 min followed by a greater than 55% decrease in platelet fluorescence after 3 h. Primary pig LSEC phagosomes containing human platelets were colocalized with lysosomes positive for lysosome‐associated membrane protein‐1 (LAMP1), indicating the formation of mature phagosomes within pig LSEC. Conclusions: Our observation of pig LSEC phagocytosis of human platelets describes a novel mechanism of large‐particle uptake in the liver. The creation of a model system to study xenotransplantation‐induced thrombocytopenia makes possible the investigation into mechanisms that mediate platelet loss.     

Differences in human and porcine platelet oligosaccharides may influence phagocytosis by liver sinusoidal cells in vitro

Paris LL, Chihara RK, Sidner RA, Tector AJ, Burlak C. Differences in human and porcine platelet oligosaccharides may influence phagocytosis by liver sinusoidal cells in vitro. Xenotransplantation 2012; 19: 31–39. © 2012 John Wiley & Sons A/S. Abstract: Background: Acute thrombocytopenia was revealed as a limiting factor to porcine liver xenotransplantation from in vitro and in vivo studies using porcine liver in human and baboon transplant models. The asialoglycoprotein receptor 1 (ASGR1) on liver sinusoidal endothelial cells (LSEC) and macrophage antigen complex‐1 (Mac‐1) on Kupffer cells (KC) mediate platelet phagocytosis and have carbohydrate‐binding sites that recognize galactose and N‐acetyl glucosamine in the beta conformation. Analysis of these receptor carbohydrate‐binding domains and surface carbohydrates on human and porcine platelets may shed light on the mechanism of xenotransplantation‐induced thrombocytopenia. Methods: An amino acid sequence comparison of human and porcine ASGR1 lectin‐binding domains was performed. Using fluorescent labeled‐lectins, human platelets, domestic and α1,3 galactosyltransferase knockout/human decay accelerating factor, porcine platelets were characterized by flow cytometry and lectin blot analyses. After desialylation, human and porcine platelets were examined by flow cytometry to determine whether sialic acid capping of galactose and N‐acetyl glucosamine oligosaccharides in the beta conformation was a factor. Further, desialylated human platelets were studied on primary porcine liver sinusoidal cells with regard to binding and phagocytosis. Results: Human platelets have four times more exposed galactose β1‐4 N‐acetyl glucosamine (Galβ) and N‐acetyl glucosamine β1‐4 N‐acetyl glucosamine (βGlcNAc) than fresh porcine platelets. Galβ and βGlcNAc moieties on porcine platelets were not masked by sialic acid. Removal of sialic acid from human platelets increased binding and phagocytosis by LSEC and KC. Conclusions: Differences between human and porcine ASGR1 and Mac‐1, in combination with a significantly higher number of galactose and N‐acetyl glucosamine‐containing oligosaccharides on human platelets contribute, in part, to platelet loss seen in porcine liver xenotransplantation.     

Depletion of pulmonary intravascular macrophages prevents hyperacute pulmonary xenograft dysfunction

BACKGROUND: Recent years have brought dramatic progress in the field of xenotransplantation, with the development of transgenic swine and various other means of overcoming the rejection mediated by xenoreactive antibodies. Although progress has been rapid with kidney and heart xenografts, progress with pulmonary xenografts has lagged behind. Recent findings have suggested that donor pulmonary intravascular macrophages may play a critical role in the hyperacute dysfunction of pulmonary xenografts. METHODS: The function of pulmonary xenografts from pigs depleted of pulmonary intravascular macrophages was compared with the function of xenografts from normal pigs. RESULTS: Pulmonary xenografts from pigs from which pulmonary intravascular macrophages were depleted survived (23.5+/-0.9 hours) about five times longer than normal (macrophage sufficient) xenografts (4.4+/-1.41 hours) (P< 0.0001). At 21 hours post-reperfusion, the left pulmonary arterial flow was 225.0+/-34 ml/min in lungs depleted of pulmonary intravascular macrophages, whereas all normal xenografts had failed. CONCLUSIONS: These findings indicate that donor macrophages play a critical role in pulmonary xenograft dysfunction. This finding has broad implications for xenotransplantation, suggesting that porcine macrophages might pose a barrier to the engraftment and function of a variety of porcine organ xenografts.     

Disseminated intravascular coagulation in association with pig-to-primate pulmonary xenotransplantation

BACKGROUND: Profound coagulopathy has been proposed as a barrier to xenotransplantation. Disseminated intravascular coagulation (DIC) has been observed with the rejection of renal and bone marrow xenografts but has not yet been described in pulmonary xenografts. METHODS: This study examined the coagulation parameters in five baboons that received pulmonary xenografts and one baboon that was exposed to porcine lung during an extracorporeal perfusion. Platelet counts, prothrombin times (PT), and levels of fibrinogen, D-dimers, and thrombin-antithrombin III complex (TAT) were analyzed. In addition, serum levels of plasminogen activator inhibitor-1 (PAI-1), thrombomodulin (TM), tissue plasminogen activator (tPA), and tissue factor (TF) were determined. RESULTS: Hyperacute pulmonary xenograft dysfunction, which occurred within 0-9 hr of graft reperfusion, was associated with clinically evident DIC. This coagulopathy was characterized by thrombocytopenia, decreased fibrinogen levels, elevations in PT, and increases in D-dimers and TAT. Furthermore, transient increases in PAI-1, increases in TM, and increases in tPA were observed in the serum of some but not all recipients. None of the baboons demonstrated measurable increases in soluble TF. CONCLUSIONS: Although DIC in renal or bone marrow xenotransplantation develops over a period of days, DIC associated with hyperacute pulmonary xenograft dysfunction develops within hours of graft reperfusion. Thus, the DIC in pulmonary xenotransplantation may represent a unique and/or accelerated version of the coagulopathy observed with renal and bone marrow xenotransplantation.     

Up to 9-day survival and control of thrombocytopenia following alpha1,3-galactosyl transferase knockout swine liver xenotransplantation in baboons

Kim K, Schuetz C, Elias N, Veillette GR, Wamala I, Varma M, Smith RN, Robson SC, Cosimi AB, Sachs DH, Hertl M. Up to 9‐day survival and control of thrombocytopenia following GalT‐KO swine liver xenotransplantation in baboons. Xenotransplantation 2012; 19: 256–264.. © 2012 John Wiley & Sons A/S. Abstract: Background:  With standard miniature swine donors, survivals of only 3 days have been achieved in primate liver‐transplant recipients. The recent production of alpha1,3‐galactosyl transferase knockout (GalT‐KO) miniature swine has made it possible to evaluate xenotransplantation of pig organs in clinically relevant pig‐to‐non‐human primate models in the absence of the effects of natural anti‐Gal antibodies. We are reporting our results using GalT‐KO liver grafts. Methods:  We performed GalT‐KO liver transplants in baboons using an immunosuppressive regimen previously used by our group in xeno heart and kidney transplantation. Post‐operative liver function was assessed by laboratory function tests, coagulation parameters and histology. Results:  In two hepatectomized recipients of GalT‐KO grafts, post‐transplant liver function returned rapidly to normal. Over the first few days, the synthetic products of the donor swine graft appeared to replace those of the baboon. The first recipient survived for 6 days and showed no histopathological evidence of rejection at the time of death from uncontrolled bleeding, probably caused by transfusion‐refractory thrombocytopenia. Amicar treatment of the second and third recipients led to maintenance of platelet counts of over 40 000 per μl throughout their 9‐ and 8‐day survivals, which represents the longest reported survival of pig‐to‐primate liver transplants to date. Both of the last two animals nevertheless succumbed to bleeding and enterococcal infection, without evidence of rejection. Conclusions:  These observations suggest that thrombocytopenia after liver xenotransplantation may be overcome by Amicar therapy. The coagulopathy and sepsis that nevertheless occurred suggest that additional causes of coagulation disturbance must be addressed, along with better prevention of infection, to achieve long‐term survival.     

Reduction of consumptive coagulopathy using porcine cytomegalovirus-free cardiac porcine grafts in pig-to-primate xenotransplantation

BACKGROUND: Xenotransplantation using pigs as the source species for organs carries a potential risk for transmission and activation of porcine herpesviruses. Activation of porcine cytomegalovirus (PCMV) in pig-to-baboon xenotransplantation is associated with xenograft injury and possibly an increased incidence of consumptive coagulopathy (CC). METHODS: To further investigate the role of PCMV activation in the occurrence of CC, a strategy to exclude PCMV from the donor was developed. To exclude PCMV, piglets were early-weaned and raised separated from other swine. These piglets were used as donors in an experimental protocol of pig-to-baboon heart xenotransplantation. RESULTS: Early weaning of piglets was successful in excluding PCMV. Use of PCMV-free cardiac porcine xenografts in baboons resulted in prolonged graft survival and prevented consumptive coagulopathy in all recipients. CONCLUSIONS: The use of PCMV-free cardiac grafts is beneficial in reducing the direct effects of PCMV activation in the graft (tissue damage) and the indirect effects of PCMV activation in the recipient (consumptive coagulopathy).     

Effect of αGal on corneal xenotransplantation in a mouse model

Choi HJ, Kim MK, Lee HJ, Jeong SH, Kang HJ, Park C‐S, Park C‐G, Kim SJ, Wee WR. Effect of αGal on corneal xenotransplantation in a mouse model. Xenotransplantation 2011; 18: 176–182. © 2011 John Wiley & Sons A/S. Abstract: Background: It has been reported that hyperacute rejection (HAR) does not occur after pig‐to‐nonhuman corneal xenotransplantation. However, considering that immune privilege is already disrupted in most human corneal recipients, and the expression of αGal can be gradually reduced after pig‐to‐rat corneal transplantation, the long‐term survival of corneal grafts from wild‐type pigs cannot be guaranteed. Accordingly, we aimed to investigate the effect of αGal on the change in anti‐Gal antibodies, using sensitized α1,3‐galactosyltransferase gene‐knockout (GTKO) mice recipients. Methods: C57BL/6 (B6) and GTKO mice were divided into 5 groups and underwent orthotopically full thickness cormeal transplantation as follows (n=4 for each group): (1) group 1: B6 to B6; (2) group 2: fresh porcine posterior corneal lamella to B6; (3) fresh porcine posterior corneal lamella to GTKO; (4) group 4: decellularized porcine posterior corneal lamella to GTKO, and (5) group 5: B6 to GTKO. Before transplantation, all GTKO recipients were sensitized using intraperitoneal injections of rabbit blood cells. Median survival times (MST) for the corneal grafts of the different groups were compared and plasma concentrations of IgG/IgM anti‐Gal antibodies were evaluated at 1 week, 2 weeks and 3 weeks post‐transplantation. Results: There were no differences in MSTs between groups. Although there was no HAR of fresh porcine posterior corneal grafts even in sensitized GTKO recipients, αGal expression was induced in the transplanted fresh porcine corneal grafts and plasma concentration of IgG anti‐Gal antibody was gradually increased in fresh porcine cornea‐grafted GTKO recipients. On the contrary, αGal expression did not increase in the grafts and plasma concentration of anti‐Gal antibodies did not change after transplantation using decellularized porcine corneas. Conclusions: Our findings suggest that αGal may affect the long‐term survival of porcine corneal xenografts via antibody‐mediated rejection, although αGal does not have an effect on acute rejection and decellularized porcine corneas may enable the long‐term survival of porcine corneal xenografts.     

Coagulopathy in α-galactosyl transferase knockout pulmonary xenotransplants

Bush EL, Barbas AS, Holzknecht ZE, Byrne GW, McGregor CG, Parker W, Duane Davis R, Lin SS. Coagulopathy in α‐galactosyl transferase knockout pulmonary xenotransplants. Xenotransplantation 2011; 18: 6–13. © 2011 John Wiley & Sons A/S. Abstract: Background: After substantial progress on many fronts, one of the remaining barriers still opposing the clinical application of xenotransplantation is a disseminated intravascular coagulopathy (DIC) that is observed in the pre‐clinical model of porcine‐to‐primate transplantation. The onset of DIC is particularly rapid in recipients of pulmonary xenografts, usually occurring within the first days or even hours of reperfusion. Methods: In this study, we describe the results of two porcine‐to‐baboon transplants utilizing porcine lungs depleted of macrophages, deficient in the α‐1,3‐galactosyltransferase gene, and with the expression of human decay‐accelerating factor, a complement regulatory protein. Results: In both cases, evidence of DIC was observed within 48 h of reperfusion, with thrombocytopenia and increases in levels of thrombin–antithrombin complex evident in both cases. Depletion of fibrinogen was observed in one graft, whereas elevation of D‐dimer levels was observed in the other. One graft, which showed focal lymphocytic infiltrates pre‐operatively, failed within 3 h. Conclusions: The results indicate that further efforts to address the coagulopathy associated with pulmonary xenotransplantation are needed. Further, evidence suggests that resident porcine immune cells can play an important role in the coagulopathy associated with xenotransplantation.     

O-linked glycosylation and functional incompatibility of porcine von Willebrand factor for human platelet GPIb receptors

BACKGROUND: Xenograft rejection is associated with vascular inflammation, thrombocytopenia and the accelerated consumption of coagulation factors. Primary biological incompatibilities of the xenograft in the regulation of clotting appear to amplify pathological processes associated with rejection. The functional incompatibility of porcine von Willebrand factor (vWF) expressed within the xenograft vasculature may heighten interactions with the primate platelet receptor GPIb, hence augmenting formation of platelet microthrombi and vascular injury. Here, we address the functional impact of O-linked glycosylation of the vWF A1 domain on primate platelet activation. METHODS: Recombinant human or porcine vWF A1-domains were transiently over-expressed in COS-7 cells as FLAG-tagged fusion protein, linked to plasma membranes via GPI anchors. O-linked glycosylation was blocked by the addition of phenyl-alpha-GalNAc2 to cultures. Expressed vWF-A1 domains were characterized utilizing cytofluometric- and Western blot analyses. RESULTS: Cytofluometric analysis confirmed equivalent levels of human and porcine vWF A1-domain expression irrespective of the levels of O-linked glycosylation. Differential glycosylation patterns of vWF-A1 under these conditions were confirmed by Western blot analyses. Native porcine vWF A1-domains had enhanced human platelet activation potential when compared with human recombinant vWF A1. However, the loss of O-linked glycosylation abolished differences in aggregatory responses between human and porcine vWF A1 domains. CONCLUSIONS: Various degrees of O-linked glycosylation of vWF-A1-domains modulate levels of functional interaction with platelet receptor GPIb and consequent platelet aggregation responses in vitro. These data may have implications for outcomes of xenotransplantation. We speculate that alterations in glycosylation of vWF and other adhesion proteins associated with the targeting of the alpha1,3-Gal-epitope in mutant swine may have salutatory effects on the primate platelet activation observed in these xenografts.     

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.     

IgM‐dependent activation of the lectin pathway of complement in xenotransplantation

Background: The classical pathway is the dominant initiator of complement activation in xenotransplantation. By amplification of C3b generation, the alternative pathway is also critical. However, little attention has been paid up to date to the involvement of the lectin pathway in xenograft rejection. Natural IgM, containing anti‐Gal, is a major initiator of classical pathway complement activation, but recently it has been shown that during ischemia/reperfusion injury, IgM also induces lectin pathway activation. Thus, the present study was focused on lectin pathway as well as interaction of IgM and MBL in a pig‐to‐human in vitro xenotransplantation model. Methods: Cell ELISA using porcine aortic endothelial cells (PAEC) and normal human serum (NHS) was used to assess activation of the different complement pathways. To confirm activation of the lectin pathway and to analyze the role of natural IgM in it's activation, co‐localized deposition of MBL/MASP2 with C3b/c, C4b/c & C6 and IgM with MBL & MASP2 was investigated by immunofluorescence (IF)/confocal microscopy on PAEC. Influence of IgM presence on MBL binding to PAEC was tested using IgM depleted/repleted and anti‐Gal immunoabsorbed NHS. Finally, tissue samples from ex vivo xenoperfusion of pig limbs with whole human blood were tested for IgM mediated lectin pathway activation by IF staining. Results: Activation of all the three pathways of complement system was observed in vitro as indicated by IgM, C1q, MBL and Factor Bb binding on PAEC. MBL deposition was co‐localized with MASP2, C3b/c, C4b/c and C6, suggesting a predominant role of the lectin pathway in xenograft rejection. IgM co‐localization with MBL and MASP2 as well as dose‐dependently increased deposition of MBL on PAEC in the presence of human polyclonal IgM, further supports the idea that upon deposition of IgM a binding site for MBL is exposed. In addition, co‐localized deposition of MBL with IgM, C4b/c and C6 was also observed on ex vivo xenoperfusion samples. Conclusion: The lectin pathway of complement activation was shown to be involved in xenotransplantation. Co‐localization of MBL / MASP2 with IgM and complement proteins indicate that lectin pathway activation in xenotransplantation is dependent on antigen recognition by naturalIgM. These findings suggest that, similar to ischemia/reperfusion injury, the lectin pathway has a functional role in endothelial damage in xenotransplantation.     

Effects of carbon monoxide on early dysfunction and microangiopathy following GalT‐KO porcine pulmonary xenotransplantation in cynomolgus monkeys

Background

Despite progress in the current genetic manipulation of donor pigs, most non‐human primates were lost within a day of receiving porcine lung transplants. We previously reported that carbon monoxide (CO) treatment improved pulmonary function in an allogeneic lung transplant (LTx) model using miniature swine. In this study, we evaluated whether the perioperative treatment with low‐dose inhalation of CO has beneficial effects on porcine lung xenografts in cynomolgus monkeys (cynos).

Methods

Eight cynos received orthotopic left LTx using either α‐1,3‐galactosyltransferase knockout (GalT‐KO; n = 2) or GalT‐KO with human decay accelerating factor (hDAF) (GalT‐KO/hDAF; n = 6) swine donors. These eight animals were divided into three groups. In Group 1 (n = 2), neither donor nor recipients received CO therapy. In Group 2 (n = 4), donors were treated with inhaled CO for 180‐minute. In Group 3 (n = 2), both donors and recipients were treated with CO (donor: 180‐minute; recipient: 360‐minute). Concentration of inhaled CO was adjusted based on measured levels of carboxyhemoglobin in the blood (15%‐20%).

Results

Two recipients survived for 3 days; 75 hours (no‐CO) and 80 hours (CO in both the donor and the recipient), respectively. Histology showed less inflammatory cell infiltrates, intravascular thrombi, and hemorrhage in the 80‐hour survivor with the CO treatment than the 75‐hours non‐CO treatment. Anti–non‐Gal cytotoxicity levels did not affect the early loss of the grafts. Although CO treatment did not prolong overall xeno lung graft survival, the recipient/donor CO treatment helped to maintain platelet counts and inhibit TNF‐α and IL‐6 secretion at 2 hours after revascularization of grafts. In addition, lung xenografts that were received recipient/donor CO therapy demonstrated fewer macrophage and neutrophil infiltrates. Infiltrating macrophages as well as alveolar epithelial cells in the CO‐treated graft expressed heme oxygenase‐1.

Conclusion

Although further investigation is required, CO treatment may provide a beneficial strategy for pulmonary xenografts.     

Prolonged Function of Macrophage, von Willebrand Factor-Deficient Porcine Pulmonary Xenografts

Porcine von Willebrand factor (vWF) activates human and primate platelets. Having determined the importance of pulmonary intravascular macrophages (PIMs) in pulmonary xenotransplantation, we evaluated whether, in the absence of PIMs, vWF might play a role in pulmonary xenograft dysfunction. Utilizing a left single-lung transplant model, baboons depleted of anti-alphaGal antibodies received lungs from either vWF-deficient (n = 2); MCP-expressing (n = 5); MCP PIM-depleted (n = 5); or vWF-deficient PIM-depleted swine (n = 3). Two out of three of the PIM-depleted, pvWF deficient grafts survived longer than any previously reported pulmonary xenografts, including PIM-depleted xenografts expressing human complement regulatory proteins. Depletion of PIM's from vWF-deficient lungs, like depletion of PIM's from hMCP lungs, resulted in abrogation of the coagulopathy associated with pulmonary xenotransplantation. Thus, in terms of pulmonary graft survival, control of adverse reactions involving pvWF appears to be equally or even more important than is complement regulation using hMCP expression. However, based on the rapid failure of PIM-sufficient, pvWF-deficient pulmonary xenografts, pVWF-deficient pulmonary xenografts appear to be particularly sensitive to macrophage-mediated damage. These data provide initial evidence that vWF plays a role in the 'delayed' (24 h) dysfunction observed in pulmonary xenotransplantation using PIM depleted hMCP organs.