Dale Christiansen

The Molecular Basis for Galα(1,3)Gal Expression in Animals with a Deletion of the α1,3Galactosyltransferase Gene

The production of homozygous pigs with a disruption in the GGTA1 gene, which encodes α1,3galactosyltransferase (α1,3GT), represented a critical step toward the clinical reality of xenotransplantation. Unexpectedly, the predicted complete elimination of the immunogenic Galα(1,3)Gal carbohydrate epitope was not observed as Galα(1,3)Gal staining was still present in tissues from GGTA1−/− animals. This shows that, contrary to previous dogma, α1,3GT is not the only enzyme able to synthesize Galα(1,3)Gal. As iGb3 synthase (iGb3S) is a candidate glycosyltransferase, we cloned iGb3S cDNA from GGTA1−/− mouse thymus and confirmed mRNA expression in both mouse and pig tissues. The mouse iGb3S gene exhibits alternative splicing of exons that results in a markedly different cytoplasmic tail compared with the rat gene. Transfection of iGb3S cDNA resulted in high levels of cell surface Galα(1,3)Gal synthesized via the isoglobo series pathway, thus demonstrating that mouse iGb3S is an additional enzyme capable of synthesizing the xenoreactive Galα(1,3)Gal epitope. Galα(1,3)Gal synthesized by iGb3S, in contrast to α1,3GT, was resistant to down-regulation by competition with α1,2fucosyltransferase. Moreover, Galα(1,3)Gal synthesized by iGb3S was immunogenic and elicited Abs in GGTA1 −/− mice. Galα(1,3)Gal synthesized by iGb3S may affect survival of pig transplants in humans, and deletion of this gene, or modification of its product, warrants consideration.

Humans lack iGb3 due to the absence of functional iGb3-synthase: implications for NKT cell development and transplantation.

The glycosphingolipid isoglobotrihexosylceramide, or isogloboside 3 (iGb3), is believed to be critical for natural killer T (NKT) cell development and self-recognition in mice and humans. Furthermore, iGb3 may represent an important obstacle in xenotransplantation, in which this lipid represents the only other form of the major xenoepitope Galα(1,3)Gal. The role of iGb3 in NKT cell development is controversial, particularly with one study that suggested that NKT cell development is normal in mice that were rendered deficient for the enzyme iGb3 synthase (iGb3S). We demonstrate that spliced iGb3S mRNA was not detected after extensive analysis of human tissues, and furthermore, the iGb3S gene contains several mutations that render this product nonfunctional. We directly tested the potential functional activity of human iGb3S by expressing chimeric molecules containing the catalytic domain of human iGb3S. These hybrid molecules were unable to synthesize iGb3, due to at least one amino acid substitution. We also demonstrate that purified normal human anti-Gal immunoglobulin G can bind iGb3 lipid and mediate complement lysis of transfected human cells expressing iGb3. Collectively, our data suggest that iGb3S is not expressed in humans, and even if it were expressed, this enzyme would be inactive. Consequently, iGb3 is unlikely to represent a primary natural ligand for NKT cells in humans. Furthermore, the absence of iGb3 in humans implies that it is another source of foreign Galα(1,3)Gal xenoantigen, with obvious significance in the field of xenotransplantation.

Characterization of a CD46 transgenic pig and protection of transgenic kidneys against hyperacute rejection in non-immunosuppressed baboons

Abstract:  Human membrane cofactor protein (CD46) controls complement activation and when expressed sufficiently as a transgene protects xenografts against complement‐mediated rejection, as shown here using non‐immunosuppressed baboons and heterotopic CD46 transgenic pig kidney xenografts. This report is of a carefully engineered transgene that enables high‐level CD46 expression. A novel CD46 minigene was validated by transfection and production of a transgenic pig line. Pig lymphocytes were tested for resistance to antibody and complement‐mediated lysis, transgenic tissues were characterized for CD46 expression, and kidneys were transplanted to baboons without immunosuppression. Absorption of anti‐Galα(1,3)Gal epitope (anti‐GAL) serum antibodies was measured. Transgenic pigs expressed high levels of CD46 in all tissues, especially vascular endothelium, with stable expression through three generations that was readily monitored by flow cytometry of transgenic peripheral blood mononuclear cells (PBMC). Transgenic PBMC pre‐sensitized with antibody were highly resistant to human complement‐mediated lysis which readily lysed normal pig PBMC. Normal pig kidneys transplanted without cold ischemia into non‐immunosuppressed adult baboons survived a median of 3.5 h (n = 7) whereas transgenic grafts (n = 9), harvested at ∼24‐h intervals, were either macroscopically normal (at 29, 48 and 68 h) or showed limited macroscopic damage (median > 50 h). Microscopic assessment of transplanted transgenic kidneys showed only focal tubular infarcts with viable renal tissue elsewhere, no endothelial swelling or polymorph adherence and infiltration by lymphocytes beginning at 3 days. Coagulopathy was not a feature of the histology in four kidneys not rejected and assessed at 48 h or later after transplantation. Baboon anti‐GAL serum antibody titers were high before transplantation and, in one extensively analyzed recipient, reduced ∼8‐fold within 5.5 h. The data demonstrate that a single CD46 transgene controls hyperacute kidney graft rejection in untreated baboons despite the presence of antibody and complement deposition. The expression levels, tissue distribution and in vitro functional tests indicate highly efficient CD46 function, controlling both classical and alternative pathway complement activation, which suggests it might be the complement regulator of choice to protect xenografts.

CD46 (membrane cofactor protein) associates with multiple β1 integrins and tetraspans

The tetraspans associate with a large number of surface molecules, including a subset of β1 integrins and, indirectly through CD19, with the complement receptor CD21. To further characterize the tetraspan complexes we have raised and selected monoclonal antibodies (mAb) for their ability to immunoprecipitate a molecule associated with CD9. A unique mAb was identified which recognizes the complement regulator CD46 (membrane cofactor protein). CD46 associated in part with several tetranspans and with all β1 integrins that were tested (CD29 / CD49a, CD29 / CD49b, CD29 / CD49c, CD29 / CD49e, CD29 / CD49f) but not with β4 integrins. These data, together with cross‐linking experiments showing the existence in living cells of CD46 / integrin complexes, suggest that CD46 associates directly with β1 integrins and indirectly with tetraspans. CD46 also acts as a receptor for measles virus; however, mAb to various integrins and tetraspans did not modify the virus fusion entry step.

Identification of the streptococcal M protein binding site on membrane cofactor protein (CD46).

Adherence of group A streptococcus (GAS) to keratinocytes is mediated by an interaction between human CD46 (membrane cofactor protein) with streptococcal cell surface M protein. CD46 belongs to a family of proteins that contain structurally related short consensus repeat (SCR) domains and regulate the activation of the complement components C3b and/or C4b. CD46 possesses four SCR domains and the aim of this study was to characterize their interaction with M protein. Following confirmation of the M6 protein-dependent interaction between GAS and human keratinocytes, we demonstrated that M6 protein binds soluble recombinant CD46 protein and to a CD46 construct containing only SCRs 3 and 4. M6 protein did not bind to soluble recombinant CD46 chimeric proteins that had the third and/or fourth SCR domains replaced with the corresponding domains from another complement regulator, CD55 (decay-accelerating factor). Homology-based molecular modeling of CD46 SCRs 3 and 4 revealed a cluster of positively charged residues between the interface of these SCR domains similar to the verified M protein binding sites on the plasma complement regulators factor H and C4b-binding protein. The presence of excess M6 protein did not inhibit the cofactor activity of CD46 and the presence of excess C3b did not inhibit the ability of CD46 to bind M6 protein by ELISA. In conclusion, 1) adherence of M6 GAS to keratinocytes is M protein dependent and 2) a major M protein binding site is located within SCRs 3 and 4, probably at the interface of these two domains, at a site distinct from the C3b-binding and cofactor site of CD46.

α1,3-Galactosyltransferase knockout pigs are available for xenotransplantation: Are glycosyltransferases still relevant?

In the early 1990s, the Galα(1,3)Gal carbohydrate linkage was found to be the major xenoepitope causing hyperacute rejection. This carbohydrate, the antibodies that bind to it, and the enzyme that produces it (α1,3‐galactosyltransferase) were the foci of research by many groups. Nearly a decade later, α1,3‐galactosyltransferase knockout pigs were finally produced; hyperacute rejection could be avoided in these pigs. Having achieved this goal, enthusiasm declined for the study of glycosyltransferases and their carbohydrate products. To examine whether this decline was premature, we evaluate whether gene deletion has indeed solved the initial rejection problem or, in fact, created new problems. This review addresses this by examining the impact of the gene deletion on cell surface carbohydrate. Surprisingly, Galα(1,3)Gal is still present in α1,3‐galactosyltransferase knockout animals: it is possibly synthesized on lipid by iGb3 synthase. Furthermore, removal of αGal resulted in the exposure of the N‐acetyllactosamine epitope. This exposed epitope can bind natural antibodies and perhaps should be capped by transgenic expression of another transferase. We believe the continued study of glycosyltransferases is essential to examine the new issues raised by the deletion of α1,3‐galactosyltransferase.

Octamerization Enables Soluble CD46 Receptor To Neutralize Measles Virus In Vitro and In Vivo

ABSTRACT A chimeric fusion protein encompassing the CD46 ectodomain linked to the C-terminal part of the C4b binding protein (C4bp) α chain (sCD46-C4bpα) was produced in eukaryotic cells. This protein, secreted as a disulfide-linked homo-octamer, was recognized by a panel of anti-CD46 antibodies with varying avidities. Unlike monomeric sCD46, the octameric sCD46-C4bpα protein was devoid of complement regulatory activity. However, sCD46-C4bpα was able to bind to the measles virus hemagglutinin protein expressed on murine cells with a higher avidity than soluble monomeric sCD46. Moreover, the octameric sCD46-C4bpα protein was significantly more efficient than monomeric sCD46 in inhibiting virus binding to CD46, in blocking virus induced cell-cell fusion, and in neutralizing measles virus in vitro. In addition, the octameric sCD46-C4bpα protein, but not the monomeric sCD46, fully protected CD46 transgenic mice against a lethal intracranial measles virus challenge.

Control of C3b and C5b deposition by CD46 (membrane cofactor protein) after alternative but not classical complement activation.

C3b and C5b deposition following complement activation, and its regulation by CD46 were studied using xenogenic Chinese hamster ovary (CHO) cells as targets and cytofluorometry. Following activation of the alternative pathway, an initial low level of C3b deposition was observed on CHO cell surfaces after a lag time of approximately 4 min. This was followed by a secondary high level of C3b deposition with a slower rate. C3b deposition was maximal within 15 min. When CD46 was expressed (B2 isoform), the kinetics of C3b deposition were essentially unchanged, but the onset of the secondary high C3b deposition was fully prevented. C5b deposition was also observed on CHO but not an CHO.CD46 cells following activation of the alternative pathway. Activation of the classical pathway on CHO and CHO.CD46 cells, using factor B‐depleted human serum and anti‐CHO antibodies, resulted in almost identical single‐peak C3b deposition profiles. Accordingly, no regulation of C5b deposition by CD46 was evident following activation of the classical pathway. These data indicate that CD46 prevents the C3b deposition amplification loop mediated by the alternative C3 convertase and, consequently, inhibits the formation of the alternative C5 convertase. But CD46 prevents neither the spontaneous tick‐over C3b deposition leading to the formation of the alternative C3 convertase nor the formation of the functional classical C3 and C5 convertases.

Interactions between the ectodomains of haemagglutinin and CD46 as a primary step in measles virus entry

Recombinant soluble forms of the ectodomains of measles virus haemagglutinin (sH) and of its receptor CD46 (sCD46) were obtained as a purified disulphide-bonded sH homodimer with an apparent molecular mass of 160 kDa and a purified sCD46 monomer with an apparent molecular mass of 60 kDa, without detectable contamination with moesin. Purified sH bound to purified and immobilized sCD46 and this binding was specifically inhibited by sCD46 in solution. sCD46 bound to wild-type H expressed on the cell surface and inhibited measles virus binding to CD46-expressing cells. Binding of sCD46 to cell surface H was increased about twofold when measles virus fusion protein was coexpressed with H. sH bound to wild-type cell surface CD46 and inhibited measles virus binding onto CD46-expressing cells. sCD46 also inhibited virus infection. Thus, the direct interaction between the ectodomains of H and CD46 is likely to be the primary event in measles virus infection.

A therapeutic human anti‐idiotypic antibody mimics CD55 in three distinct regions

The human anti‐idiotypic antibody 105AD7 was isolated from a colorectal cancer patient receiving the anti‐tumor antibody 791T/36 for radioimmuno‐scintigraphy of liver metastases. We have mapped the binding site of 791T/36 to the first two small consensus repeat (SCR) domains of the complement regulatory protein (CD55) that is overexpressed by a wide range of solid tumors. Cloning of both antigen and anti‐idiotype has identified the molecular basis of their mimicry. Amino acid homology has been identified between three complementarity‐determining regions of 105AD7 and three regions of CD55 within the first two SCR domains. 791T/36 and anti‐anti‐idiotypic (Ab3) polyclonal antibodies raised against 105AD7 showed specific binding to these peptides. The antibodies were also found to bind synergistically to combinations of these peptides, indicating cooperativity between the peptides in stabilizing antibody binding. This also implies that the contact face on both CD55 antigen and 105AD7 is generated by the cooperation of several peptides positioned on two domains in each protein. Thus a human monoclonal anti‐idiotypic antibody generated by a cancer patient is able to show both amino acid and structural homology with the complement regulatory protein CD55. These findings help identify the mechanism by which a human anti‐idiotypic antibody is able to mimic a tumor‐associated antigen and stimulate anti‐tumor B and T cell responses.