Progress in multiple genetically modified minipigs for xenotransplantation in China

Pig‐to‐human organ transplantation provides an alternative for critical shortage of human organs worldwide. Genetically modified pigs are promising donors for xenotransplantation as they show many anatomical and physiological similarities to humans. However, immunological rejection including hyperacute rejection (HAR), acute humoral xenograft rejection (AHXR), immune cell–mediated rejection, and other barriers associated with xenotransplantation must be overcome with various strategies for the genetic modification of pigs. In this review, we summarize the outcomes of genetically modified and cloned pigs achieved by Chinese scientists to resolve the above‐mentioned problems in xenotransplantation. It is now possible to knockout several porcine genes associated with the expression of sugar residues, antigens for (naturally) existing antibodies in humans, including GGTA1, CMAH, and β4GalNT2, and thereby preventing the antigen‐antibody response. Moreover, insertion of human complement‐ and coagulation‐regulatory transgenes, such as CD46, CD55, CD59, and hTBM, can further overcome effects of the humoral immune response and coagulation dysfunction, while expression of regulatory factors of immune responses can inhibit the adaptive immune rejection. Furthermore, transgenic strategies have been developed by Chinese scientists to reduce the potential risk of infections by endogenous porcine retroviruses (PERVs). Breeding of multi‐gene low‐immunogenicity pigs in China is also presented in this review. Lastly, we will briefly mention the preclinical studies on pig‐to‐non‐human primate xenotransplantation conducted in several centers in China.     

Systemic inflammation in xenograft recipients (SIXR)

Dysregulation of the coagulation system commonly develops in pig xenograft recipients, and remains an obstacle to successful pig organ xenotransplantation. Uncontrolled activation of coagulation leads to consumptive coagulopathy (CC) in the recipients, and thrombotic microangiopathy (TM) in the grafts. T cell‐directed immunosuppression successfully prevents the adaptive immune response to pig antigens after xenotransplantation and prolongs survival of organ xenografts. In some reports, T cell‐directed immunosuppression was able to delay (or prevent) the development of CC and/or TM. Recent reports have confirmed that inflammation can lead to activation of the coagulation system. Additionally, pro‐coagulant proteins, e.g. thrombin, are considered as pro‐inflammatory factors. In fact, an amplification loop is suggested to exist between inflammation and coagulation, leading to escalation of each other. Our in vitro data indicate that thrombin activation of pig endothelial cells is associated with upregulation of human T cell responses, suggesting that control of activation of coagulation and prevention of thrombin activation may facilitate the regulation of immune responses to xenografts in vivo. We hypothesize that a state of systemic inflammation develops after pig organ xenotransplantation, which is generated by both adaptive and innate immune responses. Even if T cell‐directed immunosuppression can control activation of coagulation induced by adaptive immune responses, pro‐inflammatory signals induced by the innate immune system can still promote activation of coagulation. We studied two models of xenotransplantation of different antigen loads; (i) pig aortic patch xenotransplantation, i.e. low antigen load, and (ii) pig organ (heart and kidney) xenotransplantation, i.e. high antigen load. We evaluated activation of coagulation, development of a T cell‐dependent immune response, and production of innate and adaptive pro‐inflammatory factors. In recipients of a low antigen load xenograft, effective prevention of the adaptive immune response by T cell‐directed immunosuppression (i.e. suppression of T cell proliferation in response to pig antigens and prevention of elicited antibody production) was associated with reduced thrombin activation. However, there was (i) upregulation of C‐reactive protein (CRP) and (ii) fibrinogen levels, (iii) increased IL‐6 production in the circulation, and (iv) an increase in the absolute number of innate immune cells (monocytes and neutrophils). Furthermore, (v) monocytes and dendritic cells showed significant upregulation of tissue factor expression, and aggregation with platelets after transplantation. In recipients with a high antigen load xenograft, short‐term organ survival was associated with high levels of CRP and IL‐6 early after transplantation. In long‐term organ survival, high levels of CRP and IL‐6 preceded the development of CC. There was intense CRP deposition in kidney xenografts (more than in heart xenografts) suggesting a stronger innate immune response. Additionally, CRP‐positive cells were detected in native lungs, suggesting an innate systemic inflammatory response. In conclusion, efficient blockade of the T cell‐dependent adaptive immune response in xenograft recipients is associated with systemic upregulation of inflammatory markers. Systemic inflammation in xenograft recipients (SIXR) is associated with upregulation of tissue factor expression on innate immune cells and their aggregation with platelets. As inflammation is known to break tolerance after transplantation, understanding the underlying mechanisms and regulation of SIXR may be necessary to achieve long‐term survival of organ xenografts (and T cell tolerance to pig antigens). Also, further genetic modifications of donor pigs to express anti‐inflammatory proteins may be essential.     

The pathobiology of pig‐to‐primate xenotransplantation: a historical review

The immunologic barriers to successful xenotransplantation are related to the presence of natural anti‐pig antibodies in humans and non‐human primates that bind to antigens expressed on the transplanted pig organ (the most important of which is galactose‐α1,3‐galactose [Gal]), and activate the complement cascade, which results in rapid destruction of the graft, a process known as hyperacute rejection. High levels of elicited anti‐pig IgG may develop if the adaptive immune response is not prevented by adequate immunosuppressive therapy, resulting in activation and injury of the vascular endothelium. The transplantation of organs and cells from pigs that do not express the important Gal antigen (α1,3‐galactosyltransferase gene‐knockout [GTKO] pigs) and express one or more human complement‐regulatory proteins (hCRP, e.g., CD46, CD55), when combined with an effective costimulation blockade‐based immunosuppressive regimen, prevents early antibody‐mediated and cellular rejection. However, low levels of anti‐non‐Gal antibody and innate immune cells and/or platelets may initiate the development of a thrombotic microangiopathy in the graft that may be associated with a consumptive coagulopathy in the recipient. This pathogenic process is accentuated by the dysregulation of the coagulation‐anticoagulation systems between pigs and primates. The expression in GTKO/hCRP pigs of a human coagulation‐regulatory protein, for example, thrombomodulin, is increasingly being associated with prolonged pig graft survival in non‐human primates. Initial clinical trials of islet and corneal xenotransplantation are already underway, and trials of pig kidney or heart transplantation are anticipated within the next few years.     

Lung xenotransplantation: recent progress and current status

Xenotransplantation has undergone important progress in controlling initial hyperacute rejection in many preclinical models, with some cell, tissue, and organ xenografts advancing toward clinical trials. However, acute injury, driven primarily by innate immune and inflammatory responses, continues to limit results in lung xenograft models. The purpose of this article is to review the current status of lung xenotransplantation—including the seemingly unique challenges posed by this organ—and summarize proven and emerging means of overcoming acute lung xenograft injury.     

Pathology of xenograft rejection: a commentary

Abstract: Trends in solid organ xenograft pathology are presented, with the focus on pig-to-nonhuman primate models. A simplified classification of rejection is followed, including hyperacute rejection (HAR), acute humoral xenograft rejection (AHXR), and acute cellular xenograft rejection (ACXR). The main components in HAR are natural xenoreactive antibodies in combination with complement activation. This is evident from the prevention of HAR in recipients in whom either antibodies or complement activation is depleted or inhibited. However, these strategies generally fail to prevent AHXR, which occurs later. AHXR is a multifactorial process in which natural and elicited antibodies may play roles, possibly in conjunction with complement, coagulation factors, and white blood cells. A main target appears to be the microvasculature which, in kidney grafts, is associated with a glomerular thrombotic microangiopathy. It is not clear to what extent species-specific physiologic disparities in complement and coagulation processes may play a role, separate from antibody-initiated processes. As rejection of solid organ xenografts is currently from AHXR, ACXR has not yet received close attention. In addition to intragraft rejection events, systemic complications following host–graft interactions have emerged, including (often fatal) consumptive coagulopathy and immune complex disease. It is anticipated that rejection processes will change when pigs with new genetic modifications become available. For instance, the precise role of natural antibodies to Galα1,3Gal will be able to be distinguished from other factors when pigs that lack the target antigen are available, and their organs can be evaluated in large animal xenotransplantation models.     

Current cellular immunological hurdles in pig-to-primate xenotransplantation

In this review, we summarize the work published over the last few years relative to cellular immunological hurdles encountered specifically in pig-to-primate xenotransplantation models. The works summarized here cover both the innate and adaptative cellular immune response as well as strategies to overcome them and consequently prevent xenograft rejection.     

Xenotransplantation--how far have we come?

The immunologic barriers to xenotransplantation are summarized and approaches to overcome them briefly reviewed. Intensive investigation is being directed to the problem of acute humoral xenograft rejection, which is the major current barrier. Although the induced antibody response appears to be prevented by combination therapy with an anti-CD154 monoclonal antibody and mycophenolate mofetil, deposition of natural anti-Gal antibody on the graft endothelial cells appears to be sufficient to lead to rejection or a state of consumptive coagulopathy. Approaches towards the induction of tolerance are described. The potential microbiologic risks and physiologic incompatibilities of pig-to-human organ transplantation are also briefly discussed.     

Xenotransplantation of solid organs in the pig-to-primate model

Xenotransplantation using pig organs could solve the significant increasing shortage of donor organs for allotransplantation. In the last two decades, major progress has been made in understanding the xenoimmunobiology of pig-to-nonhuman primate transplantation, and today we are close to clinical trials. The ability to genetically engineer pigs, such as human decay-accelerating factor (hDAF), CD46 (membrane cofactor protein), or alpha1,3-galactosyltransferase gene-knockout (GT-KO), has been a significant step toward the clinical application of xenotransplantation. Using GT-KO pigs and novel immunosuppressant agents, 2 to 6 months' survival of heterotopic heart xenotransplants has been achieved. In life-supporting kidney xenotransplantation, promising survival of close to 3 months has been achieved. However, liver and lung xenotransplantations do not have such encouraging survival as kidney and heart xenotransplantation. Although the introduction of hDAF and GT-KO pigs largely overcame hyperacute rejection, acute humoral xenograft rejection (AHXR) remains a challenge to be overcome if survival is to be increased. In several studies, when classical AHXR was prevented, thrombotic microangiopathy and coagulation dysregulation became more obvious, which make them another hurdle to be overcome. The initiating cause of failure of pig cardiac and renal xenografts may be antibody-mediated injury to the endothelium, leading to the development of microvascular thrombosis. Potential contributing factors toward the development of the thrombotic microangiopathy include: 1) the presence of preformed anti-non-Gal antibodies, 2) the development of very low levels of elicited antibodies to non-Gal antigens, 3) natural killer cell or macrophage activity, and 4) inherent coagulation dysregulation between pigs and primates. The breeding of pigs transgenic for an 'anticoagulant' or 'anti-thrombotic' gene, such as human tissue factor pathway inhibitor, hirudin, or CD39, or lacking the gene for the prothrombinase, fibrinogen-like protein-2, is anticipated to inhibit the change in the endothelium to a procoagulant state that takes place in the pig organ after transplantation. A further limitation for organ xenotransplantation is the potential for cross-species infection. As far as exogenous viruses are concerned, porcine cytomegalovirus has been detected in the tissues of recipient non-human primates, although no invasive disease was reported. Until today, no formal evidence has been presented from in vivo studies in non-human primates or from humans exposed to pig organs, tissues, or cells that porcine endogenous retroviruses infect primate cells. Xenotransplantation is a potential answer to the current organ shortage. Its future depends on; 1) further genetic modification of pigs, 2) the introduction of novel immunosuppressive agents that target the innate immune system and plasma cells, and 3) the development of clinically-applicable methods to induce donor-specific tolerance.     

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.     

Antibody-mediated activation of the classical complement pathway in xenograft rejection

Transplant rejection is a multifactorial process involving complex interactions between components of the innate and the acquired immune system. In view of the shortage of donor organs available for transplantation, xenotransplantation of pig organs into man has been considered as a potential solution. However, in comparison to allografts, xenografts are subject to extremely potent rejection processes that are currently incompletely defined. Consequently, an appropriate and safe treatment protocol ensuring long-term graft survival is not yet available. The first barrier that has to be taken for a xenograft is hyperacute rejection, a rapid process induced by the binding of pre-formed antibodies from the host to the graft endothelium, followed by activation of the classical complement pathway. The present review concentrates on the role of antibodies and complement in xenograft rejection as well as on the approaches for treatment that target these components. The first part focuses on porcine xenoantigens that are recognized by human xenoreactive antibodies and the different treatment strategies that aim on interference in antibody binding. The second part of the review deals with complement activation by xenoreactive antibodies, and summarizes the role of complement in the induction of endothelial cell damage and cell activation. Finally, various options that are currently under development for complement inhibition are discussed, with special reference to the specific inhibition of the classical complement pathway by soluble complement inhibitors.     

FTY720 in corneal concordant xenotransplantation

BACKGROUND.: Currently, there are no effective treatments for the control of corneal xenograft rejection. We evaluated the efficacy and mode of action of a novel immunosuppressant, FTY720, in a model of corneal xenograft transplantation. METHODS.: Rat-to-mouse corneal xenografts were performed and the effects of treatment with daily intraperitoneal injections of FTY720 (0.5 or 3.0 mg/kg/day) or saline from 2 days pretransplantation were assessed clinically. Immunohistochemical studies of the grafts and flow cytometry of the draining lymph node subpopulations were performed at the time of clinical rejection. RESULTS.: Treatment with FTY720 delayed the onset of corneal rejection, from 8 days postgraft in saline-treated mice to 12.0 +/- 0.89 days for low-dose FTY720 treatment and 15.6 +/- 3.1 days for high-dose FTY720 treatment (both P<0.001). Histologically, FTY-treated animals had a markedly reduced inflammatory response in the anterior chamber and cornea after replacement of the xenograft epithelium with normal healthy host epithelium. In contrast, saline-treated xenografts had persisting corneal epithelial defects and ulceration. In the draining lymph nodes, FTY720 not only inhibited the increase in the cell number observed in saline-treated recipients of xenografts, but also reduced the expression of activation markers on B cells (MHC class II and CD86). CONCLUSIONS.: FTY720 treatment significantly delayed rejection and decreased its severity in a dose-dependent manner in a rat-to-mouse model of corneal xenotransplantation. Since corneal xenograft rejection is mediated not by natural antibodies or CD8+ T cells directly, but by CD4+ T cells, the data from these experiments imply that FTY720 mediated its effect via CD4+ T cells.     

Pig kidney xenotransplantation: Progress toward clinical trials

Pig organ xenotransplantation offers a solution to the shortage of deceased human organs for transplantation. The pathobiological response to a pig xenograft is complex, involving antibody, complement, coagulation, inflammatory, and cellular responses. To overcome these barriers, genetic manipulation of the organ‐source pigs has largely been directed to two major aims—(a) deletion of expression of the known carbohydrate xenoantigens against which humans have natural (preformed) antibodies, and (b) transgenic expression of human protective proteins, for example, complement‐ and coagulation‐regulatory proteins. Conventional (FDA‐approved) immunosuppressive therapy is unsuccessful in preventing an adaptive immune response to pig cells, but blockade of the CD40:CD154 costimulation pathway is successful. Survival of genetically engineered pig kidneys in immunosuppressed nonhuman primates can now be measured in months. Non‐immunological aspects, for example, pig renal function, a hypovolemia syndrome, and rapid growth of the pig kidney after transplantation, are briefly discussed. We suggest that patients on the wait‐list for a deceased human kidney graft who are unlikely to receive one due to long waiting times are those for whom kidney xenotransplantation might first be considered. The potential risk of infection, public attitudes to xenotransplantation, and ethical, regulatory, and financial aspects are briefly addressed.     

异种移植免疫排斥的研究进展

异种移植是解决人体器官严重短缺的重要思路.随着对异种移植排斥和人畜共患感染性疾病的深入研究,以及α-1,3-半乳糖苷转移酶基因敲除猪的成功构建,以猪为供体的异种移植与临床应用之间的距离正在逐渐缩短.阻碍异种移植发展的主要障碍仍是免疫排斥反应.本文试就目前异种免疫排斥的研究进展进行综述,希望对未来的临床异种移植研究提供参...     

Xenotransplantation: where are we in 2008?

Xenotransplantation holds promise to solve the ever increasing shortage of donor organs for allotransplantation. In the last 2 decades, major progress has been made in understanding the immunobiology of pig-into-(non)human primate transplantation and today we are on the threshold of the first clinical trials. Hyperacute rejection, which is mediated by pre-existing anti-alpha Gal xenoreactive antibodies, can in non-human primates be overcome by complement- and/or antibody-modifying interventions. A major step forward was the development of genetically engineered pigs, either transgenic for human complement regulatory proteins or deficient in the alpha1,3-galactosyltranferase enzyme. However, several other immunologic and nonimmunologic hurdles remain. Acute vascular xenograft rejection is mediated by humoral and cellular mechanisms. Elicited xenoreactive antibodies play a key role. In addition to providing B cell help, xenoreactive T cells may directly contribute to xenograft rejection. Long-term survival of porcine kidney- and heart xenografts in non-human primates has been obtained but required severe T and B cell immunosuppression. Induction of xenotolerance, e.g. through mixed hematopoietic chimerism, may represent the preferred approach, but although proof of principle has been delivered in rodents, induction of pig-to-non-human primate chimerism remains problematic. Finally, it is now clear that innate immune cells, in particular macrophages and natural killer cells, can mediate xenograft destruction, the determinants of which are being elucidated. Chronic xenograft rejection is not well understood, but recent studies indicate that non-immunological problems, such as incompatibilities between human procoagulant and pig anticoagulant components may play an important role. Here, we give a comprehensive overview of the currently known obstacles to xenografting: immune and non-immune problems are discussed, as well as the possible strategies that are under development to overcome these hurdles.     

Analysis of the control of the anti-gal immune response in a non-human primate by galactose alpha1-3 galactose trisaccharide-polyethylene glycol conjugate

BACKGROUND: The current limitation to the clinical application of xenotransplantation using pig organs is a rejection process that has been termed delayed xenograft rejection or acute vascular rejection. It is thought that acute vascular rejection may be mediated at least in part by both the continued synthesis, of preexisting, and the induction, posttransplantation, of antibodies against the carbohydrate moiety galalpha1-3gal that is present on glycoproteins and glycolipids of the pig endothelium. The synthesis of these antibodies has proven difficult to control with currently available immunosuppressive agents. METHODS: We have synthesized galalpha1-3gal conjugated polyethylene glycol polymers that can bind to anti-galalpha1-3gal antibodies and tested their activity in non-human primates. RESULTS: These conjugates when administered to non-human primates can substantially reduce the levels of preexisting and control the induction of anti-galalpha1-3gal antibodies. The level of circulating antibody-secreting cells that make anti-galalpha1-3gal antibodies is also reduced. CONCLUSION: These alpha-gal polyethylene glycol conjugates may have the potential to control the anti-gal antibody response in a pig to primate organ transplant setting and may be a useful therapeutic agent in prolonging graft survival.     

Xenotransplantation: role of natural immunity

Hyperacute rejection, mediated by natural anti-Galalpha1,3Galbeta1,4GlcNAc (alphaGal) antibodies and the classically activated complement pathway, was identified as the first major barrier to the survival of porcine organs in humans. Subsequently, discordant pig-to-nonhuman primate and concordant rodent models revealed key roles for T and B lymphocytes in the second form of rejection, acute vascular rejection (AVR) or delayed xenograft rejection (DXR). As significant progress was made in strategies to circumvent or suppress xenoreactivity of the adaptive immune system, it became clear that, apart from natural antibodies, other innate immune system elements actively participate in AVR/DXR and represent a barrier to xenograft acceptance that may be particularly difficult to overcome. Observations in pig-to-primate and semi-discordant and concordant rodent models indicate that Natural Killer (NK) cells play a more prominent role in xenograft than in allograft rejection. Several mechanisms through which human NK cells recognize porcine endothelial cells have been elucidated and these appear to be more diverse than those involved in NK cell alloreactivity. Further, it has been demonstrated that human macrophages and neutrophils can directly recognize pig derived cells and can mediate direct xenograft damage. Here, we review the recent progress in the understanding of the xenoreactivity of the natural immune system, focussing on preclinical pig-to-(non)human primate systems, and discuss the proposed strategies to overcome these barriers.     

Innate immunity and organ transplantation: focus on lung transplantation

Ischemia reperfusion injury (IRI) that occurs with solid organ transplantation activates the innate immune system to induce inflammation. This leads to enhanced acute allograft rejection, impaired transplant tolerance and accelerated progression of chronic rejection. In this review, we discuss the innate immune signaling pathways that have been shown to play a role in organ transplantation. In particular, we focus on Toll‐like receptor signaling pathways and how they have influenced outcomes after organ transplantation both experimentally and from clinical studies. Furthermore, we describe the substances that trigger the innate immune system after transplantation and several of the key cellular mediators of inflammation. We specifically point out unique aspects of activation of the innate immune system after lung transplantation. Finally, we discuss the areas that should be investigated in the future to more clearly understand the influence of the innate immune system after organ transplantation.     

The complex functioning of the complement system in xenotransplantation

The role of complement in xenotransplantation is well‐known and is a topic that has been reviewed previously. However, our understanding of the immense complexity of its interaction with other constituents of the innate immune response and of the coagulation, adaptive immune, and inflammatory responses to a xenograft is steadily increasing. In addition, the complement system plays a function in metabolism and homeostasis. New reviews at intervals are therefore clearly warranted. The pathways of complement activation, the function of the complement system, and the interaction between complement and coagulation, inflammation, and the adaptive immune system in relation to xenotransplantation are reviewed. Through several different mechanisms, complement activation is a major factor in contributing to xenograft failure. In the organ‐source pig, the detrimental influence of the complement system is seen during organ harvest and preservation, for example, in ischemia‐reperfusion injury. In the recipient, the effect of complement can be seen through its interaction with the immune, coagulation, and inflammatory responses. Genetic‐engineering and other therapeutic methods by which the xenograft can be protected from the effects of complement activation are discussed. The review provides an updated source of reference to this increasingly complex subject.