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.     

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.     

Hyperacute rejection of mouse lung by human blood: characterization of the model and the role of complement

BACKGROUND: The pathophysiology of hyperacute lung rejection (HALR) is not fully understood. A mouse model of HALR by human blood would be valuable to efficiently dissect the molecular mechanisms underlying this complex process, but it has not been described. METHODS: We developed a xenogenic mouse lung-perfusion model. Perfusion with heparinized autologous blood (n=3) was compared with human blood unmodified (n=7) or pretreated with C1 inhibitor (n=5) or soluble complement receptor type 1 (n=6) at unchanged flow conditions. RESULTS: Perfusion with autologous blood was associated with stable physiologic parameters and no overt evidence of lung injury for up to 2 hr. Pulmonary artery perfusion pressure increased rapidly after introduction of unmodified human blood, plasma anti-Gal(alpha)1,3Gal antibodies declined (90% immunoglobulin [Ig]M, 80% IgG), and lungs reliably met survival endpoints within 11 min (median 10 min, confidence interval [CI]: 9-11). Human Ig and neutrophils were rapidly sequestered in the lung. Survival was significantly prolonged in the soluble complement receptor type 1 group (36 min, CI: 26-46) (P<0.01) and in the C1 inhibitor group (23 min, CI: 21-25) (P<0.05), and pulmonary vascular resistance elevation and complement activation were significantly attenuated but not prevented. CONCLUSIONS: Hyperacute rejection of mouse lung by human blood occurs with kinetics, physiology, and histology closely analogous to the pig-to-human model. In addition, as in that model, neither of two potent soluble-phase complement inhibitors prevented complement activation or HALR. We conclude that the mouse lung model is relevant to dissect the cellular and molecular mechanisms governing HALR.     

Prevention of hyperacute rejection in a model of orthotopic liver xenotransplantation from pig to baboon using polytransgenic pig livers (CD55, CD59, and H-transferase)

INTRODUCTION: The search for alternative sources for transplant organs leads us to the search for animals as an inexhaustible source of organs. The objective of this study was to analyze whether livers from polytransgenic pigs expressing the human complement regulatory proteins CD55 (hDAF), CD59, and alfa alpha1,2-fucosyltransferase (H-transferase), protected against hyperacute rejection after orthotopic liver xenotransplantation to a baboon and also to study pig liver function in a nonhuman primate. MATERIALS AND METHODS: Nine liver transplants from pig to baboon were divided into two groups: a control group (n = 4) of genetically unmodified pigs and an experimental group (n = 5) of pigs transgenic for CD55, CD59, and H-transferase as donors. All the donating piglets obtained through hysterectomy were maintained in specific pathogen-free conditions. The selection of transgenic pig donors followed demonstration of transgene expression using monoclonal antibodies (antiCD55, antiCD59) and immunohistological studies on liver biopsies. RESULTS: All animals in the control group developed hyperacute rejection with survival rates less than 16 hours without function of transplanted livers. In the experimental group none of the animals suffered hyperacute rejection. Survival in this group was between 13 and 24 hours. The livers were functional, producing bile and maintaining above 35% prothrombin activity. Only in one case was there primary dysfunction of the xenograft. CONCLUSION: Polytransgenic livers for complement regulatory proteins prevent hyperacute rejection when xenotransplanted into a baboon.     

Hyperacute lung rejection in the pig-to-human model. III. Platelet receptor inhibitors synergistically modulate complement activation and lung injury

BACKGROUND: The influence of platelet von Willebrand factor (vWF)-glycoprotein (GP)Ib-V-IX and GPIIb-IIIa receptor interactions in the context of hyperacute rejection (HAR) of pulmonary xenografts has not previously been explored. METHODS: Aurintricarboxylic acid (ATA, an inhibitor of platelet-GPIb interactions with vWF), SC52012A (SC, a synthetic GPIIb/IIIa inhibiting peptide), or both were added to heparinized whole human blood before perfusion of isolated piglet lungs. Results were compared with unmodified blood ("unmodified"). RESULTS: Perfusion of porcine lungs with unmodified human blood resulted in an immediate rise in pulmonary vascular resistance (PVR), fluid and platelet sequestration in the lung, and, without exception, cessation of function within 15 minutes with a mean survival of 8 minutes. Addition of ATA or SC before lung perfusion significantly decreased the rise in PVR, diminished histamine release, and prolonged survival to 31+/-11 and 31+/-22 minutes, respectively. When the therapies were combined, mean survival was 156+/-77 minutes (P<0.05 vs. either monotherapy). Complement activation was synergistically attenuated only when the drugs were used together. CONCLUSIONS: Platelet protein receptor adhesive interactions play an important role in amplification of complement activation during hyperacute lung rejection. Inhibiting recruitment of platelets at the site of initial immunologic injury to endothelial cells may protect porcine organs against thrombosis and inflammation during the initial exposure to human blood.     

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.     

Aspects of our liver support systems using extracorporeal xenoperfusion of pig or baboon liver: review

Artificial liver support systems using xenoperfusion of pig or baboon liver have metabolic activity and there is the possibility that they could substitute for total liver functions; however, several problems have yet to be solved. In our early clinical experience, a method of cross-hemodialysis with interposed cuprophane membrane was employed in order to avoid immunological reactions in patients. Sixteen patients with hepatic failure were treated by this method. Although the coma grade was ameliorated in 65% of the patients, the ultimate survival rate was 18.9%. In this clinical trial, the indication for liver support was clarified based on hepatic mitochondrial functions. This unsatisfactory result could also be attributed to insufficient effects of the device, due to the interposed membrane, and also to damage of the supporting livers due to hyperacute xenoperfusion injury. Recent investigations in the field of xenotransplantations have shown us possibilities for controlling xenogeneic hyperacute rejection. Suppression of complement activation enabled long-term xenoperfusion of supporting livers with high metabolic activity. The administration of prostaglandin E1 or soluble complement receptor type 1, and the use of transgenic pig livers expressing human decay-accelerating factor, may be promising methods to estab-lish highly active artificial liver support systems using xenoperfusion. Received: July 7, 2000 / Accepted: October 12, 2000     

Transgenic pigs expressing human CD59, in combination with human membrane cofactor protein and human decay-accelerating factor

BACKGROUND: The expression of human complement regulators has been proved as an effective strategy to overcome hyperacute rejection in discordant xenogeneic organ transplantation. In this study, we tested the hypotheses that expression of triple transgenes for human complement regulators and provide more effective protection to the transplanted pig tissues. METHODS: Pigs transgenic for human complement regulatory proteins, human CD59 (hCD59) and human membrane cofactor protein (hMCP), have been generated using large genomic constructs. Heterozygous human decay-accelerating factor (hDAF) transgenic pigs, from a previously established line, were bred with hCD59 or hCD59 plus hMCP pigs to produce animals that expressed both hCD59 and hDAF, or expressed triple transgenes hCD59, hDAF and hMCP. RESULTS: All three transgenes were widely expressed in most of the tissues analyzed, but the expression of hMCP was at low levels. In cytotoxicity assays on porcine peripheral blood mononuclear cells, the expression of a single transgenic protein, hCD59, or hCD59 in combination with hMCP provided similar protection against human complement-mediated damage as the single expression of hDAF. However, the expression of triple transgenic proteins or double hCD59 and hDAF transgenic proteins provided greater protection than either hCD59 or hDAF alone. CONCLUSIONS: Thus, pigs transgenic for multiple transgenes provide a greater degree of human complement regulation and hence might be more suitable for xenotransplantation.     

Effect of complement fragment 1 esterase inhibition on survival of human Decay-Accelerating factor pig lungs perfused with human blood

BACKGROUND: The role of complement in hyperacute lung xenograft rejection has not been fully elucidated. The present study evaluates the effect of complement (C) 1 esterase inhibition on hyperacute rejection of human decay-accelerating factor (hDAF)-positive pig lung by human blood. METHODS: Using a modification of an established ex vivo model, right and left lungs from individual animals were surgically isolated and separately perfused. Pigs homozygous for hDAF were perfused with fresh human blood that was either untreated or treated with complement 1 esterase inhibitor (C1-Inh) at doses of 1 U/ml (n = 5), 5 U/ml (n = 3) or 10 U/ml plasma (n = 5). RESULTS: Only C1-Inh at 10 U/ml prolonged survival time (230 +/- 48.3 minutes) as compared with controls (65.6 +/- 26.5 minutes, p < 0.05) and diminished complement activation (C3a and C5a, p < 0.05). Interestingly, a low concentration of C1-Inh increased the pulmonary vascular resistance (PVR; 1 U/ml: 0.54 +/- 0.3; 10 U/ml: 0.19 +/- 0.08). Sequestration of neutrophils (92 +/- 3%) and platelets (64 +/- 13%) was not prevented by any concentration of C1-Inh. Tissue deposition of C3b and C5b-9 were diminished by hDAF expression, and further blunted by treatment, with 10 U/ml C1-Inh. CONCLUSIONS: Complement plays a critical role in early events of lung hyperacute rejection (HAR). However, even potent inhibition of C1 esterase and C3/C5 convertase, using serum C1-Inh in pig lungs homozygous for hDAF expression, does not prevent rapid lung injury. Our findings implicate innate immune pathways resistant to efficient complement regulation, and suggest a role for neutrophils and platelets in the lung's particular vulnerability.     

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.     

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.     

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.     

Classical pathway complement destruction is not responsible for the loss of human erythrocytes during porcine liver perfusion

BACKGROUND: Porcine livers perfused with human blood destroy 85% of human erythrocytes (red blood cells [RBC]) during prolonged extracorporeal perfusion, raising the possibility of a complement-mediated graft-versus-host effect. METHODS: Isolated porcine livers were perfused with fresh human blood. Plasma samples were analyzed for complement production by reverse CH50 analysis and porcine immunoglobulin class and specificity by enzyme-linked immunosorbent assay (ELISA) and flow cytometry. Anti-CD59 and anti-decay accelerating factor (DAF) monoclonal antibody were used to investigate whether human complement regulatory proteins inhibit porcine complement. RESULTS: After 64 hr of perfusion of porcine livers with human blood, mean complement activity in the perfusate was 95% of the starting value and increasing, whereas perfusion in the absence of a liver showed a falling complement activity of 28.7%. ELISA demonstrated porcine immunoglobulin (Ig) G and IgM in the xenoperfused human plasma. Whereas in a previous study flow cytometry demonstrated porcine antibodies specific for antigens on human T lymphocytes, in this study, anti-human RBC antibodies were not found. Xenoperfused human plasma did not lyse fresh human RBC. Human complement was consistently more efficient at lysing porcine RBC than was porcine complement at lysing human RBC, and human plasma inhibited the ability of porcine plasma to lyse human RBC, raising the possibility of cross-species complement regulation. Complement regulatory proteins on human RBC were blocked using mouse monoclonal anti-human CD59 and DAF. Blocking CD59, but not DAF, augmented lysis of human RBC by porcine complement. CONCLUSIONS: Human CD59 inhibits porcine complement. The production of porcine complement from xenoperfused porcine livers is unlikely to result in clinically significant injury mediated through the classical pathway of complement activation.     

Complement inhibition by FUT-175 and K76-COOH in a pig-to-human lung xenotransplant model

Abstract: Two complement inhibitors, FUT-175 (FUT) and K76-COOH (K76), were studied as single agents in an ex vivo, in situ model of pig lung rejection by human blood. Pulmonary toxicity (primarily increased pulmonary vascular resistance [PVR]) was seen with FUT at a dose which inhibited complement in vitro (0.4 mg/ml); a lower dose (0.1 mg/ml) was therefore used. K76 had little apparent toxicity at a dose which inhibited complement in vitro (6 mg/ml), but activated complement, leading to C3a elaboration. Efficacy was then assessed by 1) deposition of complement pathway components in the lung and 2) lung survival during perfusion with human blood. Neither agent consistently prolonged median lung survival (FUT: 50 min.±8 SEM; K76: 37±6), blocked thromboxane production, or prevented PVR elevation compared to experiments using unmodified human blood (survival 9 min.±2). At the doses used, both agents prevented deposition of terminal complement complex (TCC) in the lung. This finding demonstrates that the various phenomena associated with hyperacute lung rejection (thromboxane release, PVR elevation, capillary leak, and intraalveolar hemorrhage) can all occur despite abrogation of membrane attack complex formation. We can not exclude a contribution by drug toxicity or complement damage (mediated by C3a or other complement pathway components proximal to TCC) to the observed lung injury. We conclude that, although both FUT and K76 inhibit deposition of TCC in the lung, at the dose tested neither drug is useful as a single agent to prolong survival in a pig-to-human lung xenograft model.     

Hyperacute lung rejection in the pig-to-human model. 2. Synergy between soluble and membrane complement inhibition

Azimzadeh A, Zorn GL III, Blair KSA, Zhang JP, Pfeiffer S, Harrison RA, Cozzi E, White DJG, Pierson RN III. Hyperacute lung rejection in the pig‐to‐human model. 2. Synergy between soluble and membrane complement inhibition. Xenotransplantation 2003; 10: 120–131. © Blackwell Munksgaard, 2003 Background. The role of complement in hyperacute lung xenograft rejection has not been elucidated. The present study evaluates the effect of complement (C) C3/C5 convertase inhibition on hyperacute rejection of pig lung by human blood. Methods. In an established ex‐vivo model, lungs from pigs heterozygous for human decay accelerating factor (hDAF), non‐transgenic littermate control pigs, or farm‐bred pigs were perfused with fresh human blood that was either unmodified or treated with soluble complement receptor type 1 (sCR1: TP10, 100 μg/ml). Results. Non‐transgenic lungs from littermate controls had a median survival time of 35 min (range 5 to 210; P=0.25 vs. farm‐bred piglets: median 5 min, range 5 to 10). Lungs expressing hDAF survived for a median of 90 min (range 10 to 161; P=0.5 and 0.01 vs. littermate and farm‐bred controls, respectively), with sCR1, whereas hDAF (–) lungs failed by 35 min (range 6 to 307), hDAF (+) lungs survived for 330 min (range 39 to 577) [P=0.002 vs. farm‐bred; P=0.08 vs. hDAF (–); P=0.17 vs. sCR1/hDAF (–)]. The rise in pulmonary vascular resistance (PVR) at 5 min was blunted only by hDAF (+) with sCR1 (0.26 ± 0.2 vs. 0.5 to 0.7 mmHg/ml/min for other groups). Plasma C3a and sC5b‐9 and tissue deposition of C5b‐9 were dramatically diminished using sCR1, and further decreased in association with hDAF. Histamine and thromboxane were produced rapidly in all groups. Conclusion. Complement plays an important role in lung HAR. However, even potent inhibition of C3/C5 convertase, both membrane bound in lung and by a soluble‐phase inhibitor in the blood, does not prevent activation of inflammatory responses known to be particularly injurious to the lung. Our findings implicate a role for innate immune pathways resistant to efficient complement regulation. The role of anti‐species antibody, coagulation pathway dysregulation, and additional environmental or genetic influences remain to be defined.     

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.     

猪供人异种移植超急性排斥反应体外实验模型的初步研究

目的 研究通过转基因方法在猪主动脉内皮细胞上表达人ＣＤ５９蛋白,抑制猪供人移植超急性排斥反应。方法 体我２的猪主动脉和人脐静脉内皮细胞,用免疫荧光和免疫组化的方法得到鉴定。构建含入ＣＤ５９ＣＤＮＡ的真核细胞表达载体ＬＸＳＮ－ＣＤ５９,限制性内切酶酶切,琼脂糖凝胶电泳和多聚酶链反应（ＰＣＲ）法鉴定。脂质体转染法将ＬＸＳＮ－ＣＤ５９转化进猪血管内皮细胞,Ｇ４１８筛选得到稳定转化子流式细胞仪筛选得到表达     

Liver allotransplantation after extracorporeal hepatic support with transgenic (hCD55/hCD59) porcine livers: clinical results and lack of pig-to-human transmission of the porcine endogenous retrovirus

BACKGROUND: Whole organ extracorporeal perfusion of a genetically modified humanized (transgenic) pig liver has been proposed as a technology that may sustain patients with severe liver failure while awaiting human liver transplantation. METHODS: We report on two cases of successful extracorporeal perfusion of a transgenic pig liver in patients awaiting transplantation for fulminant hepatic failure. The pig livers used were transgenic for human CD55 (decay-accelerating factor) and human CD59. These transgenic modifications are designed to reduce or eliminate the hyperacute rejection inherent in pig-to-primate xenotransplants. We also report on the results of serial surveillance testing for presence of the porcine endogenous retrovirus (PoERV) in these two patients. RESULTS: Extracorporeal perfusion in two patients was performed for 6.5 and 10 hr, respectively, followed by the successful transplantation of a human liver and resultant healthy patients (18 and 5 months later as of this writing). The porcine livers showed evidence of synthetic and secretory function (decreasing protime and bilirubin, bile production). Serial polymerase chain reaction analysis of these patients' peripheral blood mononuclear cells has failed to show presence of PoERV DNA sequences. CONCLUSIONS: The CD55/CD59 transgenic porcine liver appears capable of safely "bridging" a patient to liver transplantation. Human PoERV infection from these livers has yet to be demonstrated.     

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.     

Effect of an anti-C5a monoclonal antibody indicates a prominent role for anaphylatoxin in pulmonary xenograft dysfunction

BACKGROUND: In contrast to renal or cardiac xenografts, the inhibition of complement using cobra venom factor (CVF) accelerates pulmonary xenograft failure. By activating C3/C5 convertase, CVF depletes complement while additionally generating C5a and other anaphylatoxins, to which pulmonary xenografts may be uniquely susceptible. The current study investigates the role of C5a in pulmonary xenograft failure in baboons. METHODS: Left orthotopic pulmonary xenografts using swine lungs expressing human CD46 were performed in baboons receiving: I) no other treatment (n=4), II) immunodepletion (n=5), and III) immunodepletion plus a single dose of mouse anti-human C5a monoclonal antibody (anti-C5a, 0.6 mg/kg administered intravenously) (n=3). The extent to which anti-C5a inhibits baboon C5a was assessed in vitro using a hemolytic reaction involving baboon serum and porcine red blood cells and by ELISA. RESULTS: Baboons in Group III exhibited significantly prolonged xenograft survival (mean=722+/-121 min, P=0.02) compared to baboons in Group I (mean=202+/-24 min) and Group II (mean=276+/-79 min). Furthermore, baboons in Groups I and II experienced pronounced hemodynamic compromise requiring inotropic support whereas those in Group III remained hemodynamically stable throughout experimentation without the need for additional pharmacologic intervention. CONCLUSIONS: These findings indicate that C5a exacerbates pulmonary xenograft injury and compromises recipient hemodynamic status. Moreover, blockade of anaphylatoxins, such as C5a, offers a promising approach for future investigations aimed at preventing pulmonary xenograft injury in baboons.