Transplanted Pig Organs Research Articles

The Role of Adhesion Molecules in Human Leukocyte Attachment to Porcine Vascular Endothelium: Implications for Xenotransplantation

Many obstacles still prevent successful xenotransplantation of porcine donor organs. When hyperacute rejection is averted, transplanted pig organs are subject to acute vascular and cellular rejection. In autologous systems, leukocyte recruitment into inflamed tissues involves selectins, integrins, and Ig family members. To determine whether these mechanisms allow human leukocytes to effectively enter porcine grafts, the pathways by which human leukocytes adhere to TNF-alpha-stimulated porcine aortic endothelium were examined under static and physiologic flow conditions. L-selectin and E-selectin had overlapping functions in neutrophil capture and rolling, whereas Ab blockade of E-selectin and the beta2 integrins inhibited firm arrest of rolling neutrophils. Combined blockade of selectins and beta2 integrins resulted in negligible human neutrophil attachment to pig endothelium. Lymphocyte attachment to porcine endothelium was primarily L-selectin mediated, whereas beta2 integrin and VCAM-1/very late Ag-4 (VLA-4) interactions promoted static adhesion. Concurrent beta2 integrin, VLA-4, VCAM-1, and L-selectin blockade completely inhibited lymphocyte attachment. Thus, interactions between leukocyte-endothelial cell adhesion receptor pairs remained remarkably intact across the human-porcine species barrier. Moreover, disrupting the adhesion cascade may impair the ability of human leukocytes to infiltrate a transplanted porcine organ during rejection.

Xenotransplanters Turn Xenovirologists

Donor organs for transplantation are scarce, and this shortage has stimulated academic and commercial interest in techniques that employ animals as potential organ sources. One approach rapidly gaining ground is the use of pig organs for human transplantation. Though promising, pig

In vivo immunoadsorption of antipig antibodies in baboons using a specific Gal(alpha)1-3Gal column.

The major role of anti-alphaGal antibodies in the hyperacute rejection of pig organs by humans and baboons has been clearly demonstrated. Spacered alpha-galactose disaccharide (Gal(alpha1)-3Gal) hapten was produced by chemical synthesis and covalently attached to a flexible, hydrophilic polymer (PAA), which in turn was covalently coupled to macroporous glass beads, forming an immunoadsorbent that is mechanically and chemically stable and can be sterilized. The extracorporeal immunoadsorption (EIA) of anti-alphaGal antibodies using this column has been investigated in vivo in 3 baboons. In Baboon 1 (which had hyperacutely rejected a pig heart transplant 4 months previously, was not splenectomized, and did not receive any pharmacologic immunosuppression) the levels of anti-alphaGal antibody and antipig IgM and IgG, as well as serum cytotoxicity, fell significantly after each of 3 EIAs but were not eliminated. Serum cytotoxicity, antipig immunoglobulin and anti-alphaGal antibody rose steeply within 24 hr of the final EIA, suggesting that the return of cytotoxicity was associated with anti-alphaGa1 antibody. In Baboons 2 and 3 (which were immunologically naive and splenectomized, and received triple drug immunosuppressive therapy) serum cytotoxicity was totally eliminated and anti-alphaGal antibody and antipig IgM and IgG levels were greatly reduced by courses of EIA. In Baboon 2, cytotoxicity and all antibody levels remained negligible for approximately one week after the final (fourth) daily EIA. In Baboon 3, cytotoxicity and antibody levels were maintained low by intermittent EIA (over a period of 13 days) for almost 3 weeks, although antipig IgM began to rebound 4 days after the final EIA. We conclude that, in an immunosuppressed, splenectomized baboon, repeated EIA using a specific alphaGal disaccharide column will reduce antipig and anti-alphaGal antibody levels and serum cytotoxicity significantly for several days. This reduction in cytotoxicity will almost certainly be sufficient to delay the hyperacute rejection of a transplanted pig organ, but further studies are required to investigate whether it will be sufficient to allow accommodation to develop.

Cobra venom factor stimulates anti-alpha-galactose antibody production in baboons. Implications for pig-to-human xenotransplantation.

Cobra venom factor (CVF) depletes complement and may therefore be of use in preventing the hyperacute rejection that follows discordant organ xenotransplantation. In two baboons studied, the intramuscular injection of CVF (0.25 mg/kg) was followed by a marked reduction in serum C3 and CH50, and serum cytotoxicity to pig kidney (PK15) cells. There was, however, a very rapid rise in the level of anti-alpha-galactose (alpha Gal) antibody, and a slower rise in anti-CVF antibody. A second intramuscular injection of CVF on day 14 was ineffective in reducing C3, CH50, and serum cytotoxicity. The major oligosaccharide of CVF is known to contain alpha Gal residues, which we suggest stimulate the major increase in anti-alpha Gal antibody level seen in the present study. In the clinical situation, this might lead to an increased immune response to a concomitantly transplanted pig organ.

Monomorphic and polymorphic carbohydrate antigens on pig tissues: implications for organ xenotransplantation in the pig-to-human model

Abstract The existence of the αCial epitope in 137 pigs belonging to 23 different breeds suggests that this antigen is either monomorphic or occurs at a high incidence in the porcine species. Its histological location at the surface of pig vascular endothelial cells makes it a target for human natural anti-alGal antibodies and complement, which may be responsible for the hyperacute vascular rejection of transplanted pig organs. The precursor carbohydrate chain (N-acetyllactosamine) and NeuAc-substituted epitopes are also exposed at the surface of pig vascular endothelium and were found in all pigs in this study. However, humans also have these two epitopes on vascular endothelium and, consequently, have not made natural antibodies against these carbohydrate antigens. Therefore, these two pig epitopes cannot be the main target of the hyperacute vascular rejection process. Three pig phenotpyes-A + (51%), A:H + (38%), and A - H - I + (11%) were identified among 37 Large-white pigs by the presence of polymorphic A, H, and I carbohydrate antigens on the brush border of the surface epithelium of small intestine. These antigens were also present in other exocrine secretions but were not detected on vascular endothelium of the same pigs, suggesting that they are not involved in the hyperacute vascular rejection, although the pig A tissue antigen can induce an immune response in ***O or B blood group recipients. Once the problem of the initial hyperacute vascular rejection directed against the αGal epitope is overcome, typing donor pigs for A, H, and I, as well as for the protein swine leukocyte antigens (SLA) and other pig antigens, may help in elucidating antigens involved in acute or chronic xenograft rejection.

Monomorphic and polymorphic carbohydrate antigens on pig tissues: implications for organ xenotransplantation in the pig-to-human model.

The existence of the alpha Gal epitope in 137 pigs belonging to 23 different breeds suggests that this antigen is either monomorphic or occurs at a high incidence in the porcine species. Its histological location at the surface of pig vascular endothelial cells makes it a target for human natural anti-alpha Gal antibodies and complement, which may be responsible for the hyperacute vascular rejection of transplanted pig organs. The precursor carbohydrate chain (N-acetyllactosamine) and NeuAc-substituted epitopes are also exposed at the surface of pig vascular endothelium and were found in all pigs in this study. However, humans also have these two epitopes on vascular endothelium and, consequently, have not made natural antibodies against these carbohydrate antigens. Therefore, these two pig epitopes cannot be the main target of the hyperacute vascular rejection process. Three pig phenotypes-A+ (51%), A:H+ (38%), and A-H- I+ (11%) were identified among 37 Large-white pigs by the presence of polymorphic A, H, and I carbohydrate antigens on the brush border of the surface epithelium of small intestine. These antigens were also present in other exocrine secretions but were not detected on vascular endothelium of the same pigs, suggesting that they are not involved in the hyperacute vascular rejection, although the pig A tissue antigen can induce an immune response in 0 or B blood group recipients. Once the problem of the initial hyperacute vascular rejection directed against the alpha Gal epitope is overcome, typing donor pigs for A, H, and I, as well as for the protein swine leukocyte antigens (SLA) and other pig antigens, may help in elucidating antigens involved in acute or chronic xenograft rejection.