[Investigation of the surface heteroorganic antigens of rat hepatoma cells involved in process of cell proliferation]

The investigation of antigenic diversion of hepatoma cells resulting from the expression of heteroorganic kidney antigens has been continued. Tumor-associated heteroorganic antigens 110-115 and 125-130 kDa were detected by immunoserum of narrow specificity in fractions of plasmatic membranes of cells of rat ascitic hepatoma Zajdela and cultured hepatoma HTC; the antigen 75-80 kDa was revealed only for hepatoma Zajdela cells. It has been shown by methods of radioisotope analysis and flow DNA-cytometry that heteroorganic antigens 110-130 kDa can be involved in process of cell proliferation.

Xenogeneic beta 2-microglobulin substitution affects functional binding of MHC class I molecules by CD8+ T cells

NK cells and CD8+ T cells bind MHC-I molecules using distinct topological interactions. Specifically, murine NK inhibitory receptors bind MHC-I molecules at both the MHC-I H chain regions and beta2-microglobulin (beta2m) while TCR engages MHC-I molecules at a region defined solely by the class I H chain and bound peptide. As such, alterations in beta2m are not predicted to influence functional recognition of MHC-I by TCR. We have tested this hypothesis by assessing the capability of xenogeneic beta2m to modify the interaction between TCR and MHC-I. Using a human beta2m-transgenic C57BL/6 mouse model, we show that human beta2m supports formation and expression of H-2K(b) and peptide:H-2K(b) complexes at levels nearly equivalent to those in wild-type mice. Despite this finding, the frequencies of CD8+ single-positive thymocytes in the thymus and mature CD8+ T cells in the periphery were significantly reduced and the TCR Vbeta repertoire of peripheral CD8+ T cells was skewed in the human beta2m-transgenic mice. Furthermore, the ability of mouse beta2m-restricted CTL to functionally recognize human beta2m+ target cells was diminished compared with their ability to recognize mouse beta2m+ target cells. Finally, we provide evidence that this effect is achieved through subtle conformational changes occurring in the distal, peptide-binding region of the MHC-I molecule. Our results indicate that alterations in beta2m influence the ability of TCR to engage MHC-I during normal T cell physiology.

Glycoengineering of alphaGal xenoantigen on recombinant peptide bearing the J28 pancreatic oncofetal glycotope

In human pancreatic adenocarcinoma, alterations of glycosylation processes leads to the expression of tumor-associated carbohydrate antigens, representing potential targets for cancer immunotherapy. Among these pancreatic tumor-associated carbohydrate antigens, the J28 glycotope located within the O-glycosylated mucin-like C-terminal domain of the fetoacinar pancreatic protein (FAPP) and expressed at the surface of human tumoral tissues, can be a good target for anticancer therapeutic vaccines. However, the oncodevelopmental self character of the J28 glycotope associated with the low immunogenicity of tumor-associated carbohydrate antigens may be a major obstacle to effective anti-tumor vaccine therapy. In this study, we have investigated a method to increase the immunogenicity of the recombinant pancreatic oncofetal J28 glycotope by glycoengineering Galalpha1,3Galss1,4GlcNAc-R (alphaGal epitope) which may be recognized by natural anti-alphaGal antibody present in humans. For this purpose, we have developed a stable Chinese hamster ovary cell clone expressing the alphaGal epitope by transfecting the cDNA encoding the alpha1,3galactosyltransferase. These cells have been previously equipped to produce the recombinant O-glycosylated C-terminal domain of FAPP carrying the J28 glycotope. As a consequence, the C-terminal domain of FAPP produced by these cells carries the alphaGal epitope on oligosaccharide structures associated with the J28 glycotope. Furthermore, we show that this recombinant "alpha1,3galactosyl and J28 glycotope" may not only be targeted by human natural anti-alphaGal antibodies but also by the mAbJ28, suggesting that the J28 glycotope remains accessible to the immune system as vaccinating agent. This approach may be used for many identified tumor-associated carbohydrate antigens which can be glycoengineered to carry a alphaGal epitope to increase their immunogenicity and to develop therapeutic vaccines.

Use of molecular modeling and site-directed mutagenesis to define the structural basis for the immune response to carbohydrate xenoantigens

BACKGROUND

Natural antibodies directed at carbohydrates reject porcine xenografts. They are initially expressed in germline configuration and are encoded by a small number of structurally-related germline progenitors. The transplantation of genetically-modified pig organs prevents hyperacute rejection, but delayed graft rejection still occurs, partly due to humoral responses. IgVH genes encoding induced xenoantibodies are predominantly, not exclusively, derived from germline progenitors in the VH3 family. We have previously identified the immunoglobulin heavy chain genes encoding VH3 xenoantibodies in patients and primates. In this manuscript, we complete the structural analysis of induced xenoantibodies by identifying the IgVH genes encoding the small proportion of VH4 xenoantibodies and the germline progenitors encoding xenoantibody light chains. This information has been used to define the xenoantibody/carbohydrate binding site using computer-simulated modeling.

RESULTS

The VH4-59 gene encodes antibodies in the VH4 family that are induced in human patients mounting active xenoantibody responses. The light chain of xenoantibodies is encoded by DPK5 and HSIGKV134. The structural information obtained by sequencing analysis was used to create computer-simulated models. Key contact sites for xenoantibody/carbohydrate interaction for VH3 family xenoantibodies include amino acids in sites 31, 33, 50, 57, 58 and the CDR3 region of the IgVH gene. Site-directed mutagenesis indicates that mutations in predicted contact sites alter binding to carbohydrate xenoantigens. Computer-simulated modeling suggests that the CDR3 region directly influences binding.

CONCLUSION

Xenoantibodies induced during early and delayed xenograft responses are predominantly encoded by genes in the VH3 family, with a small proportion encoded by VH4 germline progenitors. This restricted group can be identified by the unique canonical structure of the light chain, heavy chain and CDR3. Computer-simulated models depict this structure with accuracy, as confirmed by site-directed mutagenesis. Computer-simulated drug design using computer-simulated models may now be applied to develop new drugs that may enhance the survival of xenografted organs.

Molecular cloning of pigGnT-I and I.2: An application to xenotransplantation

Xenotransplantation is one of the most attractive solutions for the current worldwide shortage of organs. The knocking out of alpha1,3-galactosyltransferase in pigs resulted in a drastic reduction in xenoantigenicity. However, more recent studies indicate that other xeno-antigens, so-called non-Gal antigens, will also need to be downregulated. In this study, pig N-acetylglucosaminyltransferase I (GnT-I), a key enzyme that initiates the biosynthesis of hybrid- and complex-type N-linked sugar chains, was isolated and the pigGnT-I.2 specific for the O-linked sugar chain was also isolated. Point mutants, pigGnT-I(123) and pigGnT-I(320), were subsequently constructed. While pigGnT-I(123) shows an indistinct dominant negative effect for endogenous GnT-I in pig cells, pigGnT-I(320) had a drastic effect. In addition, in the case of pig cell transfectants with pigGnT-I(320), cell surface carbohydrate structures were significantly altered and its antigenicity to human serum was reduced. Consequently, pigGnT-I(320) appears to be potentially useful in xenotransplantation by remodeling the carbohydrate structures on pig cells.

Active immunotherapy of tumors with a recombinant xenogeneic endoglin as a model antigen

Angiogenesis play a critical role in tumor growth and metastasis. Increasing evidence suggests that endoglin is a powerful marker of angiogenesis in solid malignancies. Thus, breaking of immune tolerance of self-endoglin-associated angiogenesis is an attractive approach to cancer therapy. To test this concept, we recombined the extracellular domains of porcine endoglin, and used it as a xenogeneic vaccine. We found that immunotherapy with porcine endoglin was effective at both protective and therapeutic anti-tumor immunity in several mouse tumor models. Autoantibodies against mouse endoglin were identified by Western blot and ELISA. IgG1 and IgG2b were substantially increased. Anti-endoglin antibody-producing B cells were detectable by ELISPOT assay. There was endothelial deposition of immunoglobulins within tumors. The anti-tumor activity was also induced by the adoptive transfer of the purified immunoglobulins. Angiogenesis was apparently inhibited within the tumor tissues and on the alginate beads. The increased apoptotic cells were found within the tumor tissues from the mice treated with porcine endoglin. The anti-tumor activity and production of autoantibodies against mouse endoglin could be abrogated by depletion of CD4(+) T lymphocytes. Remarkably, no marked toxicity was found in the immunized mice. These observations may provide an alternative rational strategy for active cancer immunotherapy.

Evaluating porcine RBC and platelet alpha-galactosyl expression

BACKGROUND

Naturally occurring human xenoreactive antibodies bind and agglutinate porcine RBCs.

STUDY DESIGN AND METHODS

To determine if xenoantigen expression on RBCs of individual pigs of different breeds and blood groups is variable, and if it correlates with platelet (PLT) expression, we measured adsorption of affinity-purified antibodies to alpha-galactosyl (alphaGal) by RBCs or PLTs from 22 pigs representing four breeds. Hemagglutination of RBCs from these pigs was also performed with pools of human group OAB, A, B, and AB sera, as well as with anti-alphaGal-depleted pooled OAB human serum.

RESULTS

There was significant variation in alphaGal expression on RBCs and PLTs among pigs. PLT alphaGal expression did not correlate with RBC alphaGal. RBCs from all pigs were agglutinated by pooled group O, AB, A, or B sera, whereas titers were reduced by 87 percent with anti-alphaGal-depleted serum and by 82 percent with AB sera from two volunteers. Agglutination titers were higher against RBCs from the five highest RBC alphaGal expressers compared with those from the five lowest RBC alphaGal expressers (92 +/- 12 vs. >160, p < 0.05, where 160 was the maximum dilution tested).

CONCLUSION

Hemagglutination is a feasible alternative for rapid identification of pigs with RBCs carrying less alphaGal.

Evaluation of potential antigenicity of active-site-inhibited recombinant human FVIIa (FFR-rFVIIa) in an immune-tolerant rat model

Recombinant human FVIIa (rFVIIa) was inactivated by coupling Phe-Phe-Arg-CK- (FFR) covalently to the active site of the enzyme. To test the chemically-modified human protein for potential antigenicity prior to clinical trial an immune-tolerant rat model was established. Intraperitoneal injection of the parent compound, human rFVIIa, within 30 h after birth, followed by repeated subcutaneous challenge with rFVIIa in Freunds incomplete adjuvant resulted in 79% non-responding rats at day 32. Monthly subcutaneous challenge showed that the induced tolerance was stable over the 3 months study period in 80% of the rats. The clinically relevant route, intravenous administration, was used for evaluating the potential antigenicity of FFR-rFVIIa. Repeated intravenous administration of different dosages of FFR-rFVIIa did not break tolerance, indicating that FFR-rFVIIa might not be antigenic, for a limited number of intravenous administrations in a clinical setting.

Solution structure of two xenoantigens: alpha Gal-LacNAc and alpha Gal-Lewis X

Organ hyperacute rejection, a phenomenon occurring during discordant xenotransplantation, is due to the recognition of an oligosaccharide epitope by human xenoreactive natural antibodies. In addition to the alpha Gal(1-3)beta Gal(1-4)GlcNAc trisaccharide, a fucosylated structure, alpha Gal-Lewis X, has been shown to be recognized by the antibodies. Both the trisaccharide and the tetrasaccharide have been synthesized by chemical methods. A complete nuclear magnetic resonance characterization of the two compounds has been performed, including the measurements of two-dimensional nuclear Overhauser effect spectroscopy data. Molecular dynamics simulations were run for several ns in the presence of explicit water molecules. The combination of experimental and theoretical approaches revealed the effect of an additional fucose residue on the conformational behavior of the xenoantigen. This branched fucose strongly rigidifies the N-acetyllactosamine. The effect on the alpha Gal(1-3)Gal fragment is less marked. In the presence of fucose, the terminal alpha Gal residue can still adopt two different conformations, but the equilibrium populations are modified.

The xenograft antigen bound to Griffonia simplicifolia lectin 1-B(4). X-ray crystal structure of the complex and molecular dynamics characterization of the binding site

The shortage of organs for transplantation into human patients continues to be a driving force behind research into the use of tissues from non-human donors, particularly pig. The primary barrier to such xenotransplantation is the reaction between natural antibodies present in humans and Old World monkeys and the Gal alpha(1-3)Gal epitope (xenograft antigen, xenoantigen) found on the cell surfaces of the donor organ. This hyperacute immune response leads ultimately to graft rejection. Because of its high specificity for the xenograft antigen, isolectin 1-B(4) from Griffonia simplicifolia (GS-1-B(4)) has been used as an immunodiagnostic reagent. Furthermore, haptens that inhibit natural antibodies also inhibit GS-1-B(4) from binding to the xenoantigen. Here we report the first x-ray crystal structure of the xenograft antigen bound to a protein (GS-1-B(4)). The three-dimensional structure was determined from orthorhombic crystals at a resolution of 2.3 A. To probe the influence of binding on ligand properties, we report also the results of molecular dynamics (MD) simulations on this complex as well as on the free ligand. The MD simulations were performed with the AMBER force-field for proteins augmented with the GLYCAM parameters for glycosides and glycoproteins. The simulations were performed for up to 10 ns in the presence of explicit solvent. Through comparison with MD simulations performed for the free ligand, it has been determined that GS-1-B(4) recognizes the lowest energy conformation of the disaccharide. In addition, the x-ray and modeling data provide clear explanations for the reported specificities of the GS-1-B(4) lectin. It is anticipated that a further understanding of the interactions involving the xenograft antigen will help in the development of therapeutic agents for application in the prevention of hyperacute xenograft rejection.

The xenograft antigen in complex with GS-1-B4 lectin: crystallization and preliminary X-ray analysis

The implantation of animal organs is one approach to overcoming the shortage of human donor organs for medical transplantation. Although readily available, non-primate tissues are subject to hyperacute rejection wherein human anti-Galalpha(1-3)Gal antibodies react with haptens present on the transplanted cells' surfaces. The understanding of this interaction on a molecular level will further the development of a strategy for the prevention of hyperacute rejection in xenotransplantation. The Galalpha(1-3)Gal hapten ('xenograft antigen') has been cocrystallized with the Gal-specific B(4) isolectin of Griffonia simplicifolia lectin-1. Crystals were analyzed by cryocrystallography and were found to diffract to moderately high resolution on a rotating-anode X-ray source. They belong to the P2(1)2(1)2 space group, with unit-cell parameters a = 111.0, b = 51.3, c = 76.9 A, and contain two molecules per asymmetric unit.

Remodeling of the major pig xenoantigen by N-acetylglucosaminyltransferase III in transgenic pig

We have been successful in generating several lines of transgenic mice and pigs that contain the human beta-d-mannoside beta-1,4-N-acetylglucosaminyltransferase III (GnT-III) gene. The overexpression of the GnT-III gene in mice and pigs reduced their antigenicity to human natural antibodies, especially the Galalpha1-3Galbeta1-4GlcNAc-R, as evidenced by immunohistochemical analysis. Endothelial cell studies from the GnT-III transgenic pigs also revealed a significant down-regulation in antigenicity, including Hanganutziu-Deicher antigen, and dramatic reductions in both the complement- and natural killer cell-mediated pig cell lyses. Changes in the enzymatic activities of other glycosyltransferases, such as alpha1,3-galactosyltransferase, GnT-IV, and GnT-V, did not support cross-talk between GnT-III and these enzymes in the transgenic animals. In addition, we demonstrated the effect of GnT-III in down-regulating the xenoantigen of pig heart grafts, using a pig to cynomolgus monkey transplantation model, suggesting that this approach may be useful in clinical xenotransplantation in the future.

Total synthesis of the natural antigen involved in the hyperacute rejection response to xenotransplants

The major glycosphingolipid in pig vascular endothelium is the ceramide pentasaccharide Gal alpha(1 --> 3)Gal beta(1 --> 4)GlcNAc beta(1 --> 3)Gal beta(1 --> 4)Glc beta(1 --> 0)Cer (1), which binds specifically to human anti-Gal antibody and is involved in the hyperacute rejection response in xenotransplantation from pig to man. The synthesis of 1 and its methyl glycoside 2 is described.

Binding of human natural antibodies to nonalphaGal xenoantigens on porcine erythrocytes

BACKGROUND

Xenotransplantation is considered one of possible solutions for the serious shortage of organs and cells in transplantation. Although the alphaGal epitope (Gal alpha1,3Gal beta1,4GlcNAc-R) has been identified as being a major xenoantigen responsible for hyperacute rejection, the removal of anti-alphaGal antibody alone from human serum is insufficient to circumvent antibody-mediated immune responses.

METHODS AND RESULTS

We report here the characterization of xenoreactive human natural antibodies against antigens without the alphaGal epitope (nonalphaGal xenoantigens) on porcine erythrocytes using flow cytometry and the evidence for their involvement in complement-mediated hemolysis. Furthermore, a novel protein of 45-kDa has been isolated from the porcine erythrocyte membrane as a major protein antigen recognized by human anti-nonalphaGal.

CONCLUSION

The data presented here will add to our knowledge of xenoantigens on porcine red cells and be important for developing strategies to produce modified red cells immunologically compatible to humans.

Alpha-Gal oligosaccharides: chemistry and potential biomedical application

This article focuses on the most recent research efforts by the Wang group in the field of alpha-Gal oligosaccharides. alpha-Gal oligosaccharides are carbohydrate structures bearing a Gal( alpha)1-3Gal(beta) terminus. This class of compounds are believed to act as xenoactive antigens that instigate the hyperacute rejection in xenotransplantation. Enzymatic methods using recombinant (alpha)1-3 galactosyltransferase were employed to synthesize several alpha-Gal oligosaccharides. In addition, a chemical synthetic scheme was devised in order to produce readily accessible amounts of alpha-Gal. Conformational analysis was done using both NMR techniques and molecular modeling protocols. These studies provide important information in the structure-function relationship of alpha-Gal and anti- alpha-Gal antibodies.

Characterisation of human natural anti-sheep xenoantibodies

Currently, the pig species is regarded as the most likely organ donor for human xenotransplantation in the future. However, it cannot be granted that the pig will be the optimal species of choice. We have studied human anti-sheep antibodies in comparison with anti-pig antibodies. The anti-sheep lymphocytotoxic and hemagglutination titers were in the range 8 to 128 and 2 to 32, respectively, in single individuals, which were considerably lower than the anti-pig titers of these individuals. Perfusion of sheep kidneys with human blood reduced the anti-sheep xenoantibody titers to zero as measured by lymphocytotoxic, hemagglutination, and sheep aortic endothelial cell antibody binding assays. The perfused kidneys showed generalised depositions of human IgM and C3c in the vascular tree and focal depositions of C1q and fibrin. Obliteration of capillaries by human platelets and polymorphonuclear cells were observed. Total neutral glycolipid fractions were isolated from sheep intestinal, pancreatic, and kidney tissues. By using a chromatogram binding assay, a monoclonal anti-Forssman antibody identified a single compound with five sugar residues in all organs. Several glycolipid bands were stained in all organs by the Gal(alpha)1-specific lectin I-B4 from Griffonia (Bandeiraea) Simplicifolia. A human AB serum pool showed staining by both IgG and IgM antibodies of the Forssman and Gal(alpha)1-terminating components as well as some other, not structurally identified, components. The Forssman and Gal(alpha)1-reactivity in human sera could be eliminated by immunoadsorption using Forssman and Gal(alpha)1-3Gal-immunoadsorbent columns, respectively. Immunostaining of sheep kidney tissue sections showed the presence of Gal(alpha)1-terminating epitopes by immunoperoxidase and immunogold silver staining techniques. Proximal convoluted tubules showed a strong staining, while thin loops of Henle, collecting ducts, urothelium, and vessels showed a weaker staining. Distal convoluted tubules and thick loops of Henle were completely negative. In summary, human serum contains anti-sheep xenoantibodies reacting mainly with the Forssman and Gal(alpha)1-determinants in sheep tissues and the anti-sheep antibody titers are lower than the corresponding anti-pig titers.

Tyrosine phosphorylation following lectin mediated endothelial cell stimulation

Terminal alpha (1,3) galactosyl galactoside epitopes (alpha-gal) on membrane glycoproteins expressed by vascular endothelial cells represent the major xenoreactive antigens in pig to primate xenotransplantation. In other discordant xenotransplantation combinations, such as from guinea pig to rat, carbohydrate epitopes other than alpha-gal may be targeted by xenoreactive antibodies (XNA). We have shown that agonist binding to alpha-gal epitopes induces proinflammatory activation of porcine aortic endothelial cells (PAEC). Binding of alpha-gal epitopes by Bandeiraea simplicifolia isolectin B4 results in both type I and type II PAEC activation. This includes the phosphorylation of tyrosine residue(s) of a protein with an apparent molecular weight of 130 kDa (p130). In order to investigate whether binding of other carbohydrate epitopes could induce a similar phosphorylation event, several lectins with different carbohydrate specificities were used to stimulate PAEC and human umbilical endothelial cells (HUVEC). In addition to BS-IB4 binding to alpha-gal, lectins binding to sialic acid isolated from Sambucus nigra (SNA), Maackia amurensis (MAA), Wheat germ agglutinin (WGA), and lectin from jack bean (Concanavalin A, ConA), that binds to mannose residues within the core structure of N-glycosylated proteins all induced the phosphorylation of the p130 protein(s). Lectins with affinity to alpha bound N-acetylgalactosamine, Dolichos biflorus (DOB), and Sophora japonoca (SOJ) did not induce this phosphorylation event. A similar negative result was obtained with Ulex europaeus lectin I, which binds to fucose residues. Conclusively, endothelial cell activation can be observed upon binding of various lectins to the glycosylated moiety of surface glycoproteins. These carbohydrate epitopes against which XNA may exist in certain models might represent minor xenoantigens from porcine to primates or may comprise the major xenoepitopes in other discordant xenograft models. Binding of XNA and subsequently the elicited xenoreactive antibodies to carbohydrate epitopes may therefore contribute to xenograft rejection even in the absence of complement inactivation.

Characterization of porcine platelet glycoproteins recognized by human natural "anti-gal" antibodies

Human natural "anti-Gal" antibodies are specifically directed to Gal alpha 1-3Gal beta 1-4GlcNAc residues expressed on non-primate mammal and new world monkey cells. We investigated the relative involvement of purified IgG and IgM anti-Gal as xenoreactive natural antibodies (XNA). IgG and IgM were isolated from human plasma, and anti-Gal antibodies were purified by affinity chromatography on a Synsorb-14 column (Chembiomed, Edmonton, Alberta, Canada). Anti-Gal of both IgM and IgG classes represent the bulk of human XNA that bind to porcine platelets in enzyme-linked immunosorbent assay (ELISA). On immunoblots, normal human sera, as well as purified IgM and IgG fractions, reacted with 115-, 125-, 135-, 150-, 180-, 210-, and 240-kd) pig platelet proteins, whereas purified anti-Gal antibodies of both IgM and IgG classes mainly bound to 135-, 150-, 180-, and 210-kD glycoproteins. A low reactivity was observed in ELISA with anti-Gal free IgM and IgG, indicating that xenoantibodies are not solely directed to galactosyl epitopes. These antibodies revealed bands of 115, 125, and 240 kD, alpha-Galactosidase treatment of porcine platelet glycoproteins (gps) enriched by affinity chromatography abrogated the reactivity of 135- and 210-kD proteins. N- and O-glycosidase treatments demonstrated that alpha-galactosyl residues are located on the O-glycans of the 135-kD component. Finally, glycoproteins of 90 and 135 kD were identified by amino acid sequencing as the pig analogs of the human glycoproteins IIIa and IIb, respectively, whereas the 240-kD) component was identified as the porcine fibrinogen, using a new murine monoclonal antibody (naM147-7B6; IgG1) specific for its beta-chain.

Characterization of human IgG-binding xenoantigens expressed by porcine aortic endothelial cells

Xenoreactive antibodies (XAb) play a major role in the rejection of xenografts. In this study, human IgG XAb that bind to xenoantigens expressed by porcine aortic endothelial cells (PAEC) were characterized, together with their corresponding xenoantigens. Using an ELISA with both fixed and unfixed confluent monolayers of PAEC, XAb of both IgG and IgM classes in pooled and individual normal human serum were identified. The binding of these IgG XAb to the endothelium is mediated by F(ab')2 and the only detectable subclasses that bind to the endothelium are IgG1 and IgG2. On the basis of direct binding experiments, inhibition and antibody adsorption studies, and enzymatic digestions, it is shown that only a minor component of the XAb binding is directed against galactose in an alpha 1,3 linkage with galactose on PAEC surfaces. There is some cross-reactivity with antigens expressed on porcine lymphocytes, but not porcine red blood cells. Histological examination of sections of porcine aortae, snap-frozen and stained using immunoperoxidase techniques, confirmed interaction with the vascular endothelium. Labeling of the PAEC with 125I, followed by cell lysis and immunoprecipitation under reducing conditions, showed binding of IgG XAb to several components on the endothelial cell surface, the most prominent of which have apparent molecular masses of 75 kDa, 110 kDa, 180 kDa, and 210 kDa. The 110-kDa component and the 180-kDa component were sensitive to digestion with endoglycosidase F, which suggests the participation of N-linked carbohydrate structures. These studies demonstrate that human IgG XAb recognize multiple determinants expressed by PAEC, a minor population of which contain alpha 1,3-linked galactose residues. Cross-reactive determinants are expressed on porcine lymphocytes but not porcine red blood cells.

Carbohydrate antigens of pig tissues reacting with human natural antibodies as potential targets for hyperacute vascular rejection in pig-to-man organ xenotransplantation

Pig tissues were screened by immunofluorescence with lectins, mAb, and human natural antibodies for the presence of carbohydrate antigens, which may be potential targets for hyperacute vascular rejection in pig to man xenotransplantation. The unfucosylated monomorph linear B-antigen was found at the surface of all porcine vascular endothelial cells. This pig linear-B antigen reacts strongly with the anti-alpha Gal isolectin B4 from Griffonia simplicifolia 1 and with human natural anti-alpha Gal antibodies specifically purified by affinity chromatography on synthetic oligosaccharides containing the terminal nonreducing alpha Gal1-->3 beta Gal-R disaccharide. This antigenic activity is destroyed by treatment of pig tissues with alpha-galactosidase. The localization of this linear-B epitope on vascular endothelium and its reactivity with natural human anti-alpha Gal antibodies suggest that it may play a major role in the hyperacute vascular rejection of pig to man organ xenografts. The lectin from Maackia amurensis reacting with alpha NeuAc2-->3 beta Gal1-->4GlcNAc/Glc was also positive on pig vascular endothelium, but we do not know yet whether there are human natural antibodies reacting with the carbohydrate recognized by this lectin. Epithelial cells of pig renal proximal convoluted tubules, respiratory epithelium, pancreatic ducts, and epidermis express the linear-B antigen, but they are less likely to trigger a hyperacute vascular rejection because they are not directly exposed to the blood. The genetically defined pig A+/A- system controls the expression of A and H antigens in pig epithelial cells from renal distal and collecting tubules, biliary ducts, pancreatic ducts, large bronchi, and digestive mucosa. The pig A antigen may trigger an immune response in human O or B recipients if they are transplanted with organs from A+ pigs, but the pig A antigen is probably not involved in the hyperacute vascular rejection of a xenograft because it is not expressed on vascular endothelium.