Strong expression of CD55 and CD59 completely protected porcine kidneys from hyperacute rejection and allowed a detailed analysis of xenograft rejection in the absence of immunosuppression. Coagulopathy appears to be a common feature of pig-to-baboon renal transplantation and represents yet another major barrier to its clinical application.
This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.The instant blood-mediated inflammatory reaction (IBMIR) is a major obstacle to the engraftment of intraportal pig islet xenografts in primates. Higher expression of the galactose-a1,3-galactose (aGal) xenoantigen on neonatal islet cell clusters (NICC) than on adult pig islets may provoke a stronger reaction, but this has not been tested in the baboon model. Here, we report that WT pig NICC xenografts triggered profound IBMIR in baboons, with intravascular clotting and graft destruction occurring within hours, which was not prevented by anti-thrombin treatment. In contrast, IBMIR was minimal when recipients were immunosuppressed with a clinically relevant protocol and transplanted with NICC from aGal-deficient pigs transgenic for the human complement regulators CD55 and CD59. These genetically modified (GM) NICC were less susceptible to humoral injury in vitro than WT NICC, inducing significantly less complement activation and thrombin generation when incubated with baboon platelet-poor plasma. Recipients of GM NICC developed a variable anti-pig antibody response, and examination of the grafts 1 month after transplant revealed significant cell-mediated rejection, although scattered insulin-positive cells were still present. Our results indicate that IBMIR can be attenuated in this model, but long-term graft survival may require more effective immunosuppression or further donor genetic modification.
Delayed rejection of pig kidney xenografts by primates is associated with vascular injury that may be accompanied by a form of consumptive coagulopathy in recipients. Using a life-supporting pig-to-baboon renal xenotransplantation model, we have tested the hypothesis that treatment with recombinant human antithrombin III would prevent or at least delay the onset of rejection and coagulopathy. Non-immunosuppressed baboons were transplanted with transgenic pig kidneys expressing the human complement regulators CD55 and CD59. Recipients were treated with an intravenous infusion of antithrombin III eight hourly (250 units per kg body weight), with or without low molecular weight heparin. Antithrombin-treated recipients had preservation of normal renal function for 4-5 days, which was twice as long as untreated animals, and developed neither thrombocytopenia nor significant coagulopathy during this period. Thus, recombinant antithrombin III may be a useful therapeutic agent to ameliorate both early graft damage and the development of systemic coagulation disorders in pig-to-human xenotransplantation.
Lectins were able to bind underlying carbohydrate structures (sialylated Tn and Forssman antigens) that are normally cryptic antigens on H-transferase transgenic mouse spleen and cardiac endothelial cells, probably as a consequence of the reduction in the electronegativity of the cell surface due to reduced sialylation. As humans have preformed anti-Tn and anti-Forssman antibodies, it is possible that these structures may become targets of the xenograft rejection process, including hyperacute rejection.
Genetic engineering of donor animals in xenotransplantation research has been directed largely toward obtaining expression of various immunoregulatory molecules on vascular endothelium, the initial target of recipient antibody and complement. However, specific high-level expression of transgenes throughout the vascular tree in adult animals has proved difficult to achieve, perhaps because of the inherent heterogeneity of endothelium. Using the promoter of the gene for intercellular adhesion molecule 2 (ICAM-2), which is constitutively expressed on all vascular endothelium, we have developed a system for endothelial cell gene targeting in vivo. A 334-basepair fragment from the 5' flanking region of the human ICAM-2 gene was used to drive the expression of human CD59 in transgenic mice. Strong and uniform expression of CD59 was observed on the endothelial cells of all blood vessels in the heart, kidney, lung, liver, and pancreas in the three lines of mice examined. Little or no expression was seen in other cell types, with the exception of neutrophils and monocytes. These results suggest that this small promoter region contains most of the signals necessary to endow it with endothelial cell specificity, making it a potentially valuable tool in areas ranging from xenotransplantation to gene therapy.
Xenotransplantation using porcine donors is rapidly approaching clinical applicability as an alternative therapy for treatment of many end-stage diseases including type 1 diabetes. Porcine neonatal islet cell clusters (NICC) have normalised blood sugar levels for relatively short periods in the preclinical diabetic rhesus model but have met with limited success in the stringent baboon model. Here we report that NICC from genetically modified (GM) pigs deleted for αGal and expressing the human complement regulators CD55 and CD59 can cure diabetes long-term in immunosuppressed baboons, with maximum graft survival exceeding 22 months. Five diabetic baboons were transplanted intraportally with 9,673 – 56,913 islet equivalents (IEQ) per kg recipient weight. Immunosuppression consisted of T cell depletion with an anti-CD2 mAb, tacrolimus for the first 4 months, and maintenance with belatacept and anti-CD154; no anti-inflammatory treatment or cytomegalovirus (CMV) prophylaxis/treatment was given. This protocol was well tolerated, with all recipients maintaining or gaining weight. Recipients became insulin-independent at a mean of 87 ± 43 days post-transplant and remained insulin-independent for 397 ± 174 days. Maximum graft survival was 675 days. Liver biopsies showed functional islets staining for all islet endocrine components, with no evidence of the inflammatory blood-mediated inflammatory reaction (IBMIR) and minimal leukocytic infiltration. The costimulation blockade-based immunosuppressive protocol prevented an anti-pig antibody response in all recipients. In conclusion, we demonstrate that genetic modification of the donor pig enables attenuation of early islet xenograft injury, and in conjunction with judicious immunosuppression provides excellent long-term function and graft survival in the diabetic baboon model.
Antibodies directed against galactose-alpha1,3-galactose (alphaGal) are believed to play an important role in the pathogenesis of delayed xenograft rejection (DXR). This study was designed to determine whether alpha1,3-galactosyltransferase-deficient (Gal KO) mice can naturally acquire a sufficient anti-alphaGal titre to cause the delayed type rejection of alphaGal-expressing hearts. Gal KO mice of various ages were assessed for anti-alphaGal antibody levels. alphaGal-expressing hearts were transplanted heterotopically into these mice and monitored daily. Rejecting and surviving hearts were evaluated histologically. In Gal KO mice greater than 6-month-old, 64% had an anti-alphaGal antibody titre above the background level. When wild-type alphaGal-expressing hearts were transplanted into this group, 45% of grafts rejected within 5 to 13 days. Histological examination of the rejected hearts displayed marked tissue damage and an inflammatory infiltrate of predominantly macrophage/monocytes. Surviving grafts showed preserved morphology. Like humans, Gal KO mice naturally develop anti-alphaGal antibodies with age. The titre in these mice was sufficient to cause a "delayed-type" rejection of a significant proportion of alphaGal-expressing cardiac grafts. This model thus provides an opportunity to investigate the role of naturally acquired anti-alphaGal antibodies in the pathogenesis of DXR.
High-level expression of CD46-GPI was achieved in transgenic mice by using a modified cDNA-based construct. The CD46-GPI was functional, providing some protection from complement-mediated damage in the ex vivo model, and may be useful in xenotransplantation if expressed in combination with CD55 and CD59.
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