Sharing of Ia antigens between species. IV. Interspecies cross-reactivity of monoclonal antibodies directed against polymorphic mouse Ia determinants

The specificity of interspecies Ia cross-reactions has been analyzed by testing a panel of monoclonal antibodies (mAb) to mouse I-E and I-A antigens for reactivity with pig Ia antigens. Our earlier studies showed that mouse anti-I-E alloantisera recognized common determinants on Ia antigens of other species, whereas anti-I-A alloantisera showed much more limited cross-reactivity. These results were confirmed using a panel of 17 anti-I-E mAb, 10 of which were cytotoxic to pig cells. 2D gel electrophoretic analyses of precipitates with these mAb of 35S-labeled, NP40 solubilized pig cells revealed a limited set of protein spots that appeared to be identical to the subset of pig Ia antigens precipitated by A.TH anti-A.TL alloantiserum. Because the cross-reactive mouse sera were produced in mouse strains that do not express an I-E molecule (H-2b and H-2s), it was anticipated that the cross-reacting antibodies would be reactive with the monomorphic determinant of the I-E molecule, Ia.7. However, comparison of the reactivity of these mAb with pig cells and mouse cells revealed that the cross-reactivity on pig cells correlated not with Ia.7 but rather with detection of epitope(s) of the I-E molecule associated with inter-strain polymorphism. Anti-I-A cross-reactions were also detected, but were weaker and more limited. These findings may have implications for the evolution of Ia antigens in mammalian species.     

Overview of the diversity of erythrocyte blood group antigens

During the differentiation and maturation of erythrocytes, the surface molecules of erythrocytes are gradually expressed and stabilized. These molecules are to be antigenic in addition to their functions of maintaining cell membrane structural stability, material transport and exchange of cells and signal transmission between cells. The antigenic molecules on the erythrocyte surface are called erythrocyte blood group antigens. The blood group antigens and their corresponding blood group antibodies in vivo are important indicators for clinical blood transfusion and organ transplantation, and also form the basis for research on blood group related diseases. Three hundred and sixty-eight erythrocyte blood group antigens have been confirmed so far, which are classified into 39 blood group systems, 5 blood group collections and 2 blood group series. Based on the diversity of blood group antigens and their composition of glycolipids, glycoproteins and other molecules, this study mainly reviews the classification, molecular structure, antibody response and gene regulation of blood group antigens, and explains the main reasons for the diversity of blood group antigens.     

Human blood group glycosphingolipids of porcine erythrocytes.

Two glycosphingolipids with human blood group A and H antigenicity were isolated from porcine erythrocyte membranes which were obtained from the pooled blood. The yield of the A- and H-antigenic glycolipids was approximately 0.2 and 0.1% of total neutral glycolipids, respectively. No B antigen was detected. Through several methods the porcine erythrocyte antigens were all found to belong to lactoseries (type 1 chain), IV2Fuc alpha, IV3GalNAc alpha Lc4Cer for type A and IV2-Fuc alpha Lc4Cer for type H, in contrast to the antigenic glycolipids in human erythrocytes, which mostly belong to neolactoseries (type 2 chain). The constituent fatty acids of the A antigen were 75% normal acids and 25% 2-hydroxy acids, and the long chain base was 95% sphingenine. This is the first demonstration of the A- and H-antigenic glycolipids on erythrocytes of pig in whose gastric mucin the human blood group A and H substances have been demonstrated.     

Altered cell surface antigen expression in bladder carcinoma detected by a new hemagglutinating monoclonal antibody

A hemagglutinating monoclonal IgM antibody (MoAb145) was produced against a high incidence red blood cell membrane antigen. By the specific red cell adherence test, the antibody also reacted with human bladder epithelium; in addition, expression of the MoAb145 antigen was lost in some cases of transitional cell carcinoma of the bladder, in a manner similar to the ABH blood group. Hemagglutination studies with a panel of erythrocytes lacking specific high incidence red blood cell membrane antigens indicated that MoAb145 did not recognize ABH specificity but rather a determinant absent from rare MN variant erythrocytes, including En(a-) erythrocytes, which lack glycophorin-alpha. Failure of MoAb145 to stain, by indirect immunofluorescence, the erythroleukemia cell line K562, which expresses glycophorin-alpha and the MN blood group, and failure to inhibit MoAb145 hemagglutination with an erythrocyte sialoglycoprotein fraction that contained MN blood group activity suggests that MoAb145 does not recognize either glycophorin-alpha or the MN blood group, but rather another membrane determinant, which is altered in En(a-) erythrocytes. This study demonstrates a new epitope detected by MoAb145 that is shared between human erythrocyte membranes and bladder epithelia, and is affected by neoplastic transformation in transitional cell carcinoma of the bladder.     

Blood group A glycolipid antigen expression in kidney, ureter, kidney artery, and kidney vein from a blood group A1Le(a-b+) human individual. Evidence for a novel blood group A heptaglycosylceramide based on a type 3 carbohydrate chain

Kidney, ureter, kidney artery, and kidney vein tissue were obtained from a single human transplant specimen. The donors erythrocyte blood group phenotype was A1Le(a-b+). Total non-acid glycolipid fractions were isolated and individual glycolipid components were identified by immunostaining thin layer plates with a panel of monoclonal antibodies and by mass spectrometry of the permethylated and permethylated-reduced total glycolipid fractions. The dominating glycolipids in all tissues were mono- to tetraglycosylceramides. In the kidney, ureter, and artery tissue less than 1% of the glycolipids were of blood group type, having more than 4 sugar residues. In contrast, 14% of the vein glycolipids were of blood group type, and the dominating components were type 1 chain blood group H pentaglycosylceramides and A hexaglycosylceramides. Trace amounts of structurally different blood group A glycolipids (type 1 to 4 core saccharide chains) with up to 10 sugar residues were found in the kidney, ureter, and vein tissues, including evidence for a novel blood group A heptaglycosylceramide based on the type 3 chain in the vein. The only detected A glycolipid antigen in the artery tissue was the blood group A difucosyl type 1 chain heptaglycosylceramide (ALeb) structure. Blood group Lewis and related antigens (Lea, Leb, and ALeb) were expressed in the kidney, ureter, and artery, but were completely lacking in the vein, indicating that the Le gene-coded alpha 1-4-fucosyltransferase was not expressed in this tissue. The X and Y antigens (type 2 chain isomers of the Lea and Leb antigens) were detected only in the kidney tissue.     

Dynamics of heterozygosity and its correlation with fitness in a population of domestic pigs

Variation of heterozygosity at 11 loci for blood group systems (erythrocyte antigens), occurred during 14 years in the domestic pig population of Kemerovskaya breed is described. The two estimates computed for the population examined were represented by expected population heterozygosity, as a measure resistant to stochastic fluctuations, and individual heterozygosity, as a measure with the features of a quantitative trait. Our results showed that relative fitness of genotypic classes, formed by the alleles of erythrocyte antigen loci, was different. It was demonstrated that the population examined carried the alleles responsible for fitness decrease, as well as the alleles with stable and unstable equilibrium points (with increased and decreased relative fitness of heterozygotes). Suggestions based on these results, could be applied not only to the population examined, but also to the domesticated form of Sus scrofa as a whole.     

Blood group antigens on human erythrocytes-distribution,structure and possible functions

Human erythrocyte blood group antigens can be broadly divided into carbohydrates and proteins. The carbohydrate-dependent antigens (e.g.,ABH, Lewies, Ii, P₁, P-related, T and Tn) are covalently attached to proteins and/or sphingolipids, which are also widely distributed in body fluids, normal tissues and tumors. Blood group gene-specific glycosyltransferases regulate the syntheses of these antigens. Protein-dependent blood group antigens (e.g., MNSs, Gerbich, Rh, Kell, Duffy and Cromer-related) are carried on proteins, glycoproteins and proteins with glycosylphosphatidylinositol anchor. The functions of these molecules on human erythrocytes remain unknown; some of them may be involved in maintaining the erythrocyte shape. This review describes the distribution, structures and probable biological functions of some of these antigens in normal and pathological conditions.     

Biochemistry of the erythrocyte Rh polypeptides: a review

The clinically important Rh blood group system is complex, consisting of multiple distinct antigens. Despite clinical recognition for over 50 years, the Rh blood group antigens have remained poorly understood on a molecular level until the recent identification and characterization of the "Rh polypeptides," the core structural proteins of the Rh antigens. This group of erythrocyte membrane proteins of molecular weight 30,000-35,000 daltons was first recognized by employing Rh-specific antibodies to immunoprecipitate radiolabeled components of erythrocyte membranes. By using antibodies specific for the Rh D, c, and E antigens, a series of highly related non-identical proteins were immunoprecipitated, indicating that the Rh antigens are composed of multiple related proteins. The Rh polypeptides have been purified and characterized, and they were found to have several unusual biochemical characteristics. The Rh polypeptides penetrate the membrane bilayer; they are linked to the underlying membrane skeleton; they are covalently fatty acid acylated with palmitate. While the Rh antigenic reactivity is unique to human erythrocytes, the Rh polypeptides have been isolated from erythrocytes of diverse species and are thought to be fundamental components of all mammalian erythrocyte membranes. The functional role of the Rh polypeptides remains undefined, but a role in the organization of membrane phospholipid is suspected.     

Structural characterization of non-acid glycosphingolipids in kidneys of single blood group O and A pigs

Total non-acid glycosphingolipids were isolated from the kidneys of single pigs serologically typed on their red blood cells as blood groups O and A. Glycolipid species were purified by HPLC and structurally characterized by thin-layer chromatography, mass spectrometry, proton NMR spectroscopy, degradation analysis, and reactivity with various monoclonal antibodies, Gal alpha 1-4Gal-specific E. coli bacteria, and lectins. Glucosyl-, globotriaosyl-, and globotetraosylceramides were the predominant molecular species with lactosyl- and globopentaosylceramides (IV3GalGb4Cer) as abundant constituents too. Small amounts of galactosyl- and digalactosylceramides were also present. In the blood group O pig kidneys, blood group H antigens based on four different core saccharides (types 1, 2, 4, and lactosyl core) were identified and the major blood group structure was V2FucIV3Gal-Gb4Cer. In the kidneys from the blood group A pig the corresponding blood group A antigens were found and in addition, a type 3 chain blood group A antigen was indicated by mass spectrometry and by its reactivity with a monoclonal antibody. Trace amounts of the type 2 chain-based X and Y antigens were found while blood group B antigens and the type 1 chain based Lewis antigens could not be detected. The ceramide part of the glycolipids was mainly composed of dihydroxy 18:0 long chain bases and non-hydroxy 16:0-24:0 fatty cids.     

Cytotoxic immune cells with specificity for defined soluble antigens. I. Assay with antigen-coated target cells

An in vitro cytotoxic system is described, in which immune cells specific for a given soluble antigen exert a specific cytotoxic effect on target cells to which this antigen has been covalently linked. The nature of the target cell is important in this system. When antigen-coated P 815-X2 mastocytoma cells and antigen-coated chicken red blood cells were incubated for several hours in culture medium at 37 °C, the presence of membrane-bound antigen could still be demonstrated on the latter, but not on the former target cells. This might be the reason why antigen-specific target cell destruction by specific immune cells was observed only with antigen-coated chicken red blood cells as target cells. The specificity of the cytotoxic effect was controlled in each experiment in a criss-cross way by using two non cross-reacting antigens both as immunogens and for coating the target cells. Specific cytotoxicity was demonstrable with both guinea pig and mouse immune cells and with different kinds of antigens: foreign proteins, hapten-heterologous protein conjugates and hapten-autologous protein conjugates.     

Bovine leukocyte antigens

Using bovine erythrocyte typing reagents in a leukocyte microcytotoxicity system, bovine peripheral blood leukocytes were found to have specific surface antigens. In this study, no obvious association between leukocyte.antigens and erythrocyte antigens of any individual animal was found. The leukocyte and erythrocyte antigens appeared to be distinct from each other.     

The red blood cells in growing guinea pigs (Cavia cobaya). I. Communication: pre- and perinatal changes in bone marrow and blood

118 blood samples, 98 bone-marrow smears of guinea pig fetuses, 156 blood samples of spontaneously born guinea pigs 1 to 5 days of age, and 119 bone-marrow smears of the same age group were analysed quantitatively. The normoblasts show significant differences in pre- and early postnatal animals: a peak of the cell count is found in the late fetus which decreases immediately after birth. The prenatal development of the red blood picture is characterised by an increase of erythrocyte count and hematocrit and a decrease of cell size, and reticulocyte count. This development continues postnatally. The perinatal bone-marrow and blood picture findings suggest a true postnatal increase of the erythrocyte count in the guinea pig during the first 3 to 5 days of life which likely is due to the grown demand for oxygen transport capacity.     

Molecular characterization of the human ABO blood group orthologus system in pigs

The selection and use of animals with blood group 0 in the process of transplanting pig organs or tissues into humans can positively contribute to the control of acute immune rejection due to differences in blood groups. Exon-specific PCRs for the porcine blood group A transferase gene against genomic DNA from either blood group A or 0 animals resulted in the amplification failure of the A0 blood group gene exon 8 from blood group 0 animals. To characterize the genetic abnormality in the genome of blood group 0 animals, we screened bacterial artificial chromosome (BAC) clones from a Korean native pig BAC library which had the blood group 0 allele, and carried out shotgun sequencing. The analysis showed that the 0 allele has a large deletion between exon 7 of the A0 blood group gene and the neighbouring SURF6. We also showed that the ABO blood group antigens in humans and the A0 blood group antigens in pigs are coded by mutations within the orthologous glycosyltransferase gene. In addition, we developed a multiplex genotyping method for the porcine A0 blood group gene.     

Serological relationships among antigens of the BoLA and the bovine M blood group systems

Alloimmunizations with either lymphocytes or red cells from donor cows positive for BoLA w16 and blood group M' antigens into recipients negative for these antigens produced antisera reactive in the cytotoxic test with w16-positive lymphocytes and in the haemolytic test with M'-positive erythrocytes. Similarly, alloimmunizations of blood group M1-negative recipients with either lymphocytes or red cells from donor cows possessing the M1 blood group factor produced antisera specifically reactive with lymphocytes and erythrocytes from M1-positive cattle. Absorptions with either lymphocytes or erythrocytes from individual animals of the same M antigenic type as the donor removed all haemolytic and cytotoxic reactivity. The results indicate that blood group M' and BoLA w16 share a similar antigenic structure. Likewise, blood group M1 has an antigenically similar counterpart which is also part of the BoLA system.     

Mapping of the bovine blood group systems J,N', R', and Z show evidence for oligo-genetic inheritance

Genes determining the bovine erythrocyte antigens were mapped by linkage analysis. In total 9591 genotypes of 20 grandsire families with 1074 sires from a grand-daughter design were elucidated for the genes determining the erythrocyte antigens EAA, EAB, EAC, EAF, EAJ, EAL, EAM, EAN', EAR', EAS, EAT', and EAZ according to standard paternity testing procedures in the blood typing laboratories. Linkage analyses were performed with 248 microsatellite markers, eight SSCP markers and four polymorphic proteins and enzymes covering the 29 autosomes and the pseudoautosomal region of the sex chromosomes. The number of informative meioses for the blood group systems ranged from 76 to 947. Blood group systems EAM and EAT' were non-informative. Most of the erythrocyte antigen loci showed significant linkage to a single chromosome and were mapped unequivocally. The genes determining erythrocyte antigen EAA, EAB, EAC, EAL, and EAS were mapped to chromosomes 15, 12, 18, 3, and 21, respectively. Lod-score values ranged from 11.43 to 107.83. Moreover, the EAF system could be mapped to chromosome 17. However, the EAN' system previously known as part of the EAF system could be mapped to chromosome 5. In addition, the blood group systems EAJ, the new EAN', EAR', and EAZ, showed significant linkage to microsatellite markers on various chromosomes and also to other blood groups. The appearance of a single blood group system might be therefore either dependent on the existence of other blood group systems or because of an interaction between different loci on various chromosomes as is known in humans and in pigs.     

Isolation of a porcine UDP-GalNAc transferase cDNA mapping to the region of the blood group EAA locus on pig chromosome 1

In our studies of the genes constituting the porcine A0 blood group system, we have characterized a cDNA, encoding an alpha(1,3)N-acetylgalactosaminyltransferase, that putatively represents the blood group A transferase gene. The cDNA has a 1095-bp open reading frame and shares 76.9% nucleotide and 66.7% amino acid identity with the human ABO gene. Using a somatic cell hybrid panel, the cDNA was assigned to the q arm of pig chromosome 1, in the region of the erythrocyte antigen A locus (EAA), which represents the porcine blood group A transferase gene. The RNA corresponding to our cDNA was expressed in the small intestinal mucosae of pigs possessing EAA activity, whereas expression was absent in animals lacking this blood group antigen. The UDP-N-acetylgalactosamine (UDP-GalNAc) transferase activity of the gene product, expressed in Chinese hamster ovary (CHO) cells, was specific for the acceptor fucosyl-alpha(1,2)galactopyranoside; the enzyme did not use phenyl-beta-D-galactopyranoside (phenyl-beta-D-Gal) as an acceptor. Because the alpha(1,3)GalNAc transferase gene product requires an alpha(1,2)fucosylated acceptor for UDP-GalNAc transferase activity, the alpha(1,2)fucosyltransferase gene product is necessary for the functioning of the alpha(1,3)GalNAc transferase gene product. This mechanism underlies the epistatic effect of the porcine S locus on expression of the blood group A antigen. ABBREVIATIONS: CDS: coding sequence; CHO: Chinese Hamster Ovary; EAA: erythrocyte antigen A; FCS: foetal calf serum; Fucalpha(1,2)Gal: fucosyl-alpha(1,2)galactopyranoside; Gal: galactopyranoside; GGTA1: Galalpha(1,3)Gal transferase; PCR: polymerase chain reaction; phenyl-beta-D-Gal: phenyl-beta-D-galactopyranoside; R: Galbeta1-4Glcbeta1-1Cer; UDP-GalNAc: uridine diphosphate N-acetylgalactosamine     

Blood group antigens: synthesis of Ss antigenic peptides related to human glycophorin B

The human Ss blood group antigens are located on glycophorin B, a minor human erythrocyte membrane glycoprotein. The structural difference in Ss antigens is determined by a Met/Thr polymorphism at position 29. This report describes the first synthesis of the two peptides carrying the Ss specificities, SS: Asn-Gly-Glu-Met-Gly-Gln-Leu-Val and ss: Asn-Gly-Glu-Thr-Gly-Gln-Leu-Val.     

Contribution of glycolipids to species-specific antigens on erythrocytes of several animal species as to recognition of antigens with rabbit anti-glycolipids and anti-erythrocyte antisera

Because anti-glycolipid antibodies are involved in the onset of several neurological diseases, the reactivity of glycolipids on erythrocytes and the probability of generating the antibodies were determined to clarify the contribution of glycolipids as antigens. Anti-erythrocyte antisera reacted with the following glycolipids in a species-specific manner, i.e. blood group A-active glycolipid for man, Forssman glycolipid for sheep, Gg₃Cer for guinea pig, and Gg₄Cer and fucosyl GM1 for rat, and the hemolytic activities of the anti-erythrocyte antisera were attenuated by absorption of the antisera with liposomes prepared from the lipids of erythrocytes to the following levels, 94.5% for man, 24.5% for sheep, 17.5% for guinea pig, and 54.5% for rat. These species-specific glycolipids on erythrocytes reacted well with the respective anti-glycolipid antisera, but Gb₄Cer in man and GM1 in rat were shown to be cryptic on immunization with erythrocytes, indicating that the contribution of glycolipids as erythrocyte antigens differs among animal species. The glycolipid nomenclature is based on the recommendations of the IUPAC-IUB Commission on Biochemical Nomenclature [1]. The ganglioside nomenclature of Svennerholm is employed throughout [2].     

Ontogeny and expression of chicken A blood group antigens

Expression of chicken red blood cell (RBC) surface antigens was studied by using a monoclonal antibody (ISU-cA) specific for chicken A blood group antigens. Erythrocytes were examined from embryos of 3-18 days of incubation and from chicks at hatch up to 21 weeks of age. Specific antigens were detected on embryonic RBC surfaces by immunofluorescence as early as 3 days of incubation. Antigenic expression was examined by both haemagglutination and immunofluorescence and found to increase with age from embryos to mature birds. The antigen concentration on the cell surface was found to be affected by genotype; heterozygotes had an intermediate level of antigen between that of the two parental genotypes. These data confirm the co-dominance that is observed with most blood group antigens. Flow cytometric analysis allowed confirmation that the entire erythrocyte population gradually increased in antigenic expression over time, rather than having an antigen-negative subpopulation being replaced by a positive subpopulation.     

Relationship between the secretor status and the expression of ABH blood group antigenic determinants in human intestinal brush-border membrane hydrolases

At least six hydrolases of the human intestinal brush-border membrane bear ABH blood group antigenic determinants related to the erythrocyte phenotype: the intestinal glycoproteins of blood group A and B subjects express A or B determinants, respectively, while blood group O subjects express the H determinant identified with Ulex europaeus lectin I. These expressions are under the control of the secretor gene: ABH antigens were not detected in the hydrolases of non-secretor subjects.