Pig alpha1, 3galactosyltransferase: a major target for genetic manipulation in xenotransplantation.

Terminal carbohydrate residues of glycolipids and glycoproteins display polymorphism among as well as within various species. With the exception of Old World monkeys, great apes and man, the Gala1,3Gal structure is widely expressed in all mammals examined so far. The lack of expression of the glycosyltransferase responsible for the synthesis of Gala1,3Gal leads to the production of high titers of natural antibodies (NAb) against the Gala1,3Gal of other species. The inactivation of this gene occurred during early evolution of primates. Neutralization of viruses (e.g. retroviruses) carrying the epitope, by the pre-formed human NAb, indicates one possible evolutionary reason for the polymorphism of terminal carbohydrates among as well as within species. It has been shown that this epitope constitutes the major target, on pig endothelial cells (EC), for the pre-formed human NAb resulting in a hyperacute rejection (HAR) response. This currently makes transplantation of e.g. pig organs to humans impossible. Efforts are currently underway to prevent or to eradicate the expression of this epitope in transgenic pigs. Such pigs are likely to display a greatly increased resistance to the HAR.

Sensitization of cells and retroviruses to human serum by (alpha 1-3) galactosyltransferase.

Mammalian C-type retroviruses are inactivated by human serum, following triggering of the classical complement cascade. This may have inhibited transmission to humans of C-type oncoviruses from other mammals. Indeed, the retroviruses human immunodeficiency virus and human T-cell leukaemia virus are resistant to human complement. Antibody-independent activation of human C1q, the first component of the classical pathway, by retroviral envelope proteins has been described. However, retroviruses produced from human cells are resistant to inactivation by human complement and human serum is known to contain antibodies directed against carbohydrates on retroviral envelopes. Gal(alpha 1-3)Gal terminal carbohydrates are expressed by most mammals but are absent in humans, which lack a functional (alpha 1-3)galactosyltransferase gene. Here, we demonstrate that anti-Gal(alpha 1-3)Gal antibodies in human serum inactivate retroviruses produced from animal cells. Expression of porcine (alpha 1-3)galactosyltransferase in human cells renders the cells and the retroviruses they produce sensitive to human serum.

cDNA sequence and chromosome localization of pig alpha 1,3 galactosyltransferase.

Human serum contains natural antibodies (NAb), which can bind to endothelial cell surface antigens of other mammals. This is believed to be the major initiating event in the process of hyperacute rejection of pig to primate xenografts. Recent work has implicated galactosyl alpha 1,3 galactosyl beta 1,4 N-acetyl-glucosaminyl carbohydrate epitopes, on the surface of pig endothelial cells, as a major target of human natural antibodies. This epitope is made by a specific galactosyltransferase (alpha 1,3 GT) present in pigs but not in higher primates. We have now cloned and sequenced a full-length pig alpha 1,3 GT cDNA. The predicted 371 amino acid protein sequence shares 85% and 76% identity with previously characterized cattle and mouse alpha 1,3 GT protein sequences, respectively. By using fluorescence and isotopic in situ hybridization, the GGTA1 gene was mapped to the region q2.10-q2.11 of pig chromosome 1, providing further evidence of homology between the subterminal region of pig chromosome 1q and human chromosome 9q, which harbors the locus encoding the AB0 blood group system as well as a human pseudogene homologous to the pig GGTA1 gene.

Impaired resistance to infection does not increase the virulence of Salmonella htrA live vaccines for mice.

We have described a new class of live attenuated salmonella vaccines harbouring lesions in htrA, a stress protein gene previously. The virulence and invasiveness of Salmonella htrA mutants was investigated in three models of increased susceptibility to Salmonella infection. These included BALB/c mice, either given sublethal whole body irradiation (350 R) or administered rabbit anti-TNF alpha antiserum, and (CBA/NfemaleXBALB/cmale)F1 male mice which express the xid sex-linked B cell defect of CBA/N mice and are more susceptible to salmonellae than female littermates. Salmonella typhimurium htrA mutants derived from virulent strains, C5046 (C5 htrA::TnphoA) and BRD726 (SL1344 delta htrA) were not more invasive in immunosuppressed mice than in normal controls in the three mouse models of defective immunity. The results indicate that susceptibility to S. typhimurium htrA vaccines derived from virulent parents is not enhanced by conditions of impaired resistance to infection.

Evaluation of Salmonella typhimurium strains harbouring defined mutations in htrA and aroA in the murine salmonellosis model.

Derivatives of the mouse-virulent Salmonella typhimurium strain SL1344 were constructed harbouring defined mutations in htrA, aroA or htrA aroA combined. When administered orally or intravenously to BALB/c mice, all the mutants were found to be highly attenuated. All mutants were able to confer significant protection against lethal challenge with SL1344 after a single oral dose of live organisms. SL1344 htrA mutants persisted in livers and spleens at a lower level than SL1344 aroA mutants after intravenous administration. SL1344 htrA aroA mutants persisted at an even lower level and were cleared from the livers and spleens of mice within 21 days of intravenous administration. Thus htrA and htrA aroA mutants can be considered as potential oral vaccines against salmonellosis.

Development of cloned DNA probes for the identification of snail intermediate hosts within the genus Bulinus.

DNA fragments have been isolated from Bulinus cernicus and cloned in Escherichia coli strain JM109 using pUC18 as the vector. Four recombinant plasmids designated pBC123, pBC126, pBC127 and pBC134 were selected for further analysis and were shown by both dot and Southern blot hybridisations to have different specificities to species representing the four species groups of Bulinus. Non-specific hybridisation occurred with pBC126 whereas pBC123 and pBC134 hybridised only to B. cernicus. Partial restriction maps of the inserts revealed sequence differences between pBC123 and pBC134. Intermediate specificity was shown by pBC127 as this probe hybridised only to DNA from snails of the B. forskalii group and B. truncatus of the B. truncatus/tropicus complex. The results demonstrate the potential of DNA probes for the identification and characterisation of intermediate hosts of schistosomes.