Lisa E. Diamond

The role of antibodies in acute vascular rejection of pig-to-baboon cardiac transplants.

Long-term success in xenotransplantation is currently hampered by acute vascular rejection. The inciting cause of acute vascular rejection is not yet known; however, a variety of observations suggest that the humoral immune response of the recipient against the donor may be involved in the pathogenesis of this process. Using a pig-to-baboon heterotopic cardiac transplant model, we examined the role of antibodies in the development of acute vascular rejection. After transplantation into baboons, hearts from transgenic pigs expressing human decay-accelerating factor and CD59 underwent acute vascular rejection leading to graft failure within 5 d; the histology was characterized by endothelial injury and fibrin thrombi. Hearts from the transgenic pigs transplanted into baboons whose circulating antibodies were depleted using antiimmunoglobulin columns (Therasorb, Unterschleisshein, Germany) did not undergo acute vascular rejection in five of six cases. Biopsies from the xenotransplants in Ig-depleted baboons revealed little or no IgM or IgG, and no histologic evidence of acute vascular rejection in the five cases. Complement activity in the baboons was within the normal range during the period of xenograft survival. In one case, acute vascular rejection of a xenotransplant occurred in a baboon in which the level of antidonor antibody rose after Ig depletion was discontinued. This study provides evidence that antibodies play a significant role in the pathogenesis of acute vascular rejection, and suggests that acute vascular rejection might be prevented or treated by therapies aimed at the humoral immune response to porcine antigens.

A human CD46 transgenic pig model system for the study of discordant xenotransplantation.

Background. Thechronic shortage in the supply of human organs available for allotransplantation has turned attention toward the use of animals as potential donors, with pigs as the most likely species under consideration. Hyperacute rejection, the initial and immediate barrier to a pig-to-primate xenograft, has been addressed by generation of transgenic pigs that express the human membrane-bound complement-regulatory proteins CD59 and/or CD55. Difficulty has been encountered in generation of transgenic animals that express a third membrane-bound complement-regulatory protein, CD46. Methods. We have generated transgenic animals by using a large genomic construct that encompasses the entire human CD46 gene. Results. We report the first description of transgenic mice and pigs that express high levels of human CD46 in a cell and tissue type-specific manner, resembling patterns of endogenous CD46 expression observed in human tissues. Furthermore, when human CD46 transgenic porcine hearts were transplanted into baboons, the grafts did not succumb to hyperacute rejection, and survival extended for up to 23 days. Under the same conditions, nontransgenic grafts underwent hyperacute rejection within 90 min. Conclusions. This is the first report to describe generation of transgenic pigs that express human CD46, and the first in vivo demonstration of the ability of human CD46 expressed on pig organs to regulate complement activation and overcome hyperacute rejection upon transplantation of a vascularized organ into nonhuman primates.

Characterization of transgenic pigs expressing functionally active human CD59 on cardiac endothelium

The critical shortage of human donor organs has generated interest in the potential for porcine to human xenotransplantation. The initial immunological barrier to xenotransplantation is hyperacute rejection, which is mediated by xenoreactive antibodies and complement, and results in rapid and irreversible tissue destruction. While endogenous complement regulatory proteins (CRPs) protect cells from injury caused by autologous complement, they are relatively species specific and most likely ineffectual in this setting. This has led to the hypothesis that expression of human CRPs in transgenic pigs may affect susceptibility to complement-mediated tissue injury in a porcine-to-human xenograft. Using specific lines of transgenic pigs that express low levels of human CD59, a CRP that acts at the terminal stage of the complement cascade, we present evidence that shows that the human CD59 protein inhibits membrane attack complex assembly and reduces tissue damage when the heart is transplanted to a baboon. Examination by immunohistochemistry of transgenic porcine hearts after transplantation revealed markedly reduced deposition of C5b and MAC, but a similar level of C3 deposition as compared with transplanted control hearts. This finding supports the concept that the species specific function of CRPs contributes to the humoral barrier to xenotransplantation and, given the low level of human CD59 protein expression in the porcine heart, argues that the human protein contributes a unique rather than an additive function in regulation of complement in a xenogeneic setting.

The role of anti-Galalpha1-3Gal antibodies in acute vascular rejection and accommodation of xenografts.

BACKGROUND A major impediment to the transplanting of porcine organs into humans is the susceptibility of porcine organs to acute vascular rejection, which can destroy a vascularized xenograft over a period of hours to days. Acute vascular rejection of porcine-to-primate xenografts is thought to be triggered by binding of xenoreactive antibodies to the graft. We tested whether antibodies, binding to Galalpha1-3Gal epitopes in porcine tissue, initiate this phenomenon. METHODS AND RESULTS Specific depletion of anti-Galalpha1-3Gal antibodies from the blood of baboons, using extracorporeal perfusion of separated plasma through columns of Sepharose beads covalently linked to the antigenic trisaccharide, Galalpha1-3Galbeta1-4GlcAc, averted the development of acute vascular rejection in porcine organs transgenic for human decay-accelerating factor and CD59. More importantly, after immunodepletion was stopped and Gala1-3Gal antibodies were allowed to return, these same organs continued to function and remained pathologically normal and thus seemed to achieve a state of accommodation. CONCLUSION These results demonstrate that anti-Galalpha1-3Gal antibodies cause acute vascular rejection and suggest that depletion of these antibodies leads to accommodation of the donor cardiac xenograft and could supply an important model for additional study.

The role of natural anti-galα1–3gal antibodies in hyperacute rejection of pig-to-baboon cardiac xenotransplants

Xenoreactive natural antibodies in humans and higher primates are directed predominantly at Gal alpha 1-3Gal. These antibodies are thought to initiate hyperacute rejection of porcine organ xenografts. The contribution of anti-Gal alpha 1-3Gal antibodies to the xenoractive natural antibody repertoire and to the initiation of hyperacute rejection was tested in a pig-to-baboon cardiac xenograft model. Anti-Gal alpha 1-3Gal antibodies were depleted from baboons by extracorporeal absorption of anti-Gal alpha 1-3Gal antibodies from plasma using columns with a matrix bearing Gal alpha 1-3Galb1-4GlcNAc. Specific removal of anti-Gal alpha 1-3Gal antibodies was achieved prior to transplantation as demonstrated by immunoassay. Porcine hearts were then transplanted into these baboons and the outcome of the transplants was analysed. Immunofluorescence revealed little deposition of baboon antibodies in the grafts. The porcine hearts did not undergo hyperacute rejection even though complement activity was approximately 90% of baseline at the time of transplantation. These findings demonstrate that anti-Gal alpha 1-3Gal antibodies constitute a major fraction of xenoreactive natural antibodies in primate blood and that these antibodies contribute significantly to the pathogenesis of hyperacute xenograft rejection.

Hearts from transgenic pigs constructed with CD59/DAF genomic clones demonstrate improved survival in primates.

We have previously created transgenic pigs bearing the human complement regulatory proteins CD59 and decay‐accelerating factor (DAF) by either the intercellular transfer or the cDNA transgenic method. To achieve more physiologic protein expression, we constructed a new line of transgenic pigs with CD59 and DAF human genomic clones. We transplanted these CD59/DAF transgenic pig hearts into baboons immunosuppressed with cyclosporine, methylprednisone or leflunomide/mofetil mycophenolate. The four wild‐type hearts survived for 20–80 min, whereas the four CD59/DAF hearts functioned for 85–130 h. Immunohistochemical staining showed levels of CD59 and DAF protein expression similar to that in human hearts. Wild‐type and transgenic hearts demonstrate a similar level of IgM deposition, although transgenic hearts suffered less hyperacute rejection and thus less membrane attack complex deposition. The histology of the transgenic grafts after explant was consistent with acute vascular rejection, with a high level of IgG deposit compared with wild‐type control. We conclude that this new line of CD59/DAF transgenic pigs express high levels of the transgene products, which conferred longer survival because of better protection from hyperacute rejection. Similar to previous transgenic pigs, however, these animals suffered from delayed xenograft rejection.

Transgenic expression of human complement regulatory proteins in mice results in diminished complement deposition during organ xenoperfusion

Complement activation is an essential step in the hyperacute rejection of a vascularized xenograft. Endothelial cell-associated complement regulatory proteins limit complement activation in most settings, but are not able to limit the extensive complement activation that occurs in xenografts, at least in part due to their species specificity. To overcome this problem we and others have sought to express human complement regulatory proteins in the organs of potential donor animals. As an initial step toward evaluating this concept we tested organs from transgenic mice expressing human CD59 and/or decay-accelerating factor (DAF) in two in vitro perfusion systems for the ability to control activation of heterologous complement. In the first system, mouse hearts were perfused on a Langendorff circuit with 50% human plasma. Immuno-pathologic analysis of heart biopsies revealed deposition of human IgG, IgM, and C4 in both control and transgenic organs. The hearts from mice transgenic for human CD59 had substantially less and in some cases no membrane attack complex (MAC) and hearts from CD59/DAF transgenic mice had substantially less or no C5b and MAC. In the second system, mouse hearts were perfused with baboon blood through arterial lines inserted into baboons. Immunopathologic analysis of serial biopsies revealed the deposition of IgG, IgM, and C4 in control and transgenic hearts. Compared with controls, less MAC was deposited in many CD59-expressing hearts and less C5b and MAC in DAF-expressing hearts. These results demonstrate that human complement regulatory proteins expressed in a xenogeneic organ are able to contribute to the control of complement activation in that organ and support the concept that expression of these human molecules would help protect a xenogeneic organ transplanted into a human.

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

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

Analysis of the control of the anti-gal immune response in a non-human primate by galactose α1-3 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 gal&agr;1–3gal 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 gal&agr;1–3gal conjugated polyethylene glycol polymers that can bind to anti-gal&agr;1–3gal 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-gal&agr;1–3gal antibodies. The level of circulating antibody-secreting cells that make anti-gal&agr;1–3gal antibodies is also reduced. Conclusion. These &agr;-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.

Human CD59 expressed in transgenic mouse hearts inhibits the activation of complement

Porcine-to-human xenotransplantation offers a potential solution to the critical shortage of human organs. The major immunological barrier to xenotransplantation between these species is a rapid rejection process mediated by preformed natural antibodies and complement. Xenogeneic organ grafts are especially susceptible to complement mediated injury because complement regulatory proteins, which ordinarily protect cells from inadvertent injury during the activation of complement, function poorly in regulating activation of heterologous complement. Removal of xenoreactive antibodies or systemic inhibition of complement activity has been shown to prolong graft survival. As an alternative to the systemic inhibition of complement activity, we have established a model system using transgenic animals to test whether the expression of human membrane bound complement regulatory proteins on mouse endothelial cells can inhibit the activation of human complement. CD59, which acts at the terminal stage of complement activation by inhibiting the formation of the membrane attack complex, was used as a paradigm for this model. A CD59 construct containing the putative CD59 gene promoter linked to the CD59 coding region was used to demonstrate expression of the human CD59 protein in various tissues of transgenic mice, including endothelial cells in the heart. In addition, we show that the transgenic CD59 protein is biologically active as determined by the ability to inhibit the formation of membrane attack complex in transgenic mouse hearts perfused ex vivo with human plasma. These results demonstrate that expression of membrane bound complement regulatory proteins can achieve complement inhibition in a xenogeneic organ and suggest that this approach may be useful for successful xenotransplantation between discordant species.