We conclude that (i) CVF prevents HAR, (ii) the addition of Spx + IS delays rejection, but (iii) the early deposition of antibody leads to progressive graft injury, resulting in (iv) delayed vascular rejection. Our findings indicate that the features of delayed xenograft rejection described in small animal models also occur in the pig-to-baboon model, and that rejection may occur in a complement-independent manner from the effects of antibody and/or host macrophages.
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.
Therapeutic mAbs that target tumor-associated Ags on the surface of malignant cells have proven to be an effective and specific option for the treatment of certain cancers. However, many of these protein markers of carcinogenesis are not expressed on the cells’ surface. Instead these tumor-associated Ags are processed into peptides that are presented at the cell surface, in the context of MHC class I molecules, where they become targets for T cells. To tap this vast source of tumor Ags, we generated a murine IgG2a mAb, 3.2G1, endowed with TCR-like binding specificity for peptide-HLA-A*0201 (HLA-A2) complex and designated this class of Ab as TCR mimics (TCRm). The 3.2G1 TCRm recognizes the GVL peptide (GVLPALPQV) from human chorionic gonadotropin β presented by the peptide-HLA-A*0201 complex. When used in immunofluorescent staining reactions using GVL peptide-loaded T2 cells, the 3.2G1 TCRm specifically stained the cells in a peptide and Ab concentration-dependent manner. Staining intensity correlated with the extent of cell lysis by complement-dependent cytotoxicity (CDC), and a peptide concentration-dependent threshold level existed for the CDC reaction. Staining of human tumor lines demonstrated that 3.2G1 TCRm was able to recognize endogenously processed peptide and that the breast cancer cell line MDA-MB-231 highly expressed the target epitope. The 3.2G1 TCRm-mediated CDC and Ab-dependent cellular cytotoxicity of a human breast carcinoma line in vitro and inhibited in vivo tumor implantation and growth in nude mice. These results provide validation for the development of novel TCRm therapeutic reagents that specifically target and kill tumors via recognition and binding to MHC-peptide epitopes.
We have previously demonstrated that hyperacute rejection does not occur in a pig-to-newborn baboon heart transplant model, presumably because of low levels of cytotoxic antipig antibodies present in the serum of newborn baboons. Cytotoxic antipig antibodies are primarily directed to alpha-1,3-galactosyl (alpha Gal) residues on endothelial cell surface structures Twenty-one full-term humans and 5 full-term baboons were tested for complement mediated lysis (CML) of pig kidney (PK-15) cells and anti-alpha Gal activity with an ELISA using BSA-conjugated alpha Gal residues as target. To evaluate the significance of the anti-alpha Gal titers in vivo 5 newborn baboons underwent heterotopic pig cardiac xenotransplantation. Six of 21 human samples and 1 of 5 baboon samples demonstrated significant cytotoxicity to PK-15 cells. Twelve of 21 newborn humans had anti-alpha Gal IgG antibodies at titers of 1:80 or greater. None of the samples had anti-alpha Gal IgM. In newborn baboons, 1 of 5 sera had anti-alpha Gal IgG antibodies at titers greater than 1:80 and none of these samples had anti-alpha Gal IgM. Xenografts survived for an average of 3.6 days, even in the baboon with high anti-alpha Gal IgG titers. Analysis of the explanted grafts showed minimal evidence of complement-mediated hyperacute rejection (HAR), but prominent mononuclear cell infiltrates. In serum tested posttransplant there was an induced anti-alpha Gal response with cytotoxicity against PK-15 cells. These results show that anti-alpha Gal IgM is absent in newborn human and baboon sera, allowing pig grafts to avoid HAR. However, the presence of anti-alpha Gal IgG may be associated with mononuclear cell infiltration of the xenograft and its subsequent rejection.
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