Radioactive labeling techniques for the identification of G antigen in the human Rh blood group system

The G antigen is one of the erythrocyte membrane Rh antigens. The amount of Rh antigen present on the red blood cell is about 10(-15) g and radioactive labeling of membrane proteins is a useful method for its identification and characterization. In this paper, we compare 4 labeling techniques. Using a human monoclonal anti-Rh(G) antibody and an immunofixation technique, we located the G antigen on a polypeptide of an average molecular weight of 28,000 Da.     

Isolation of a new cDNA clone encoding an Rh polypeptide associated with the Rh blood group system

We searched for a human chromosome that would restore the cholesterol metabolism in 3T3 cell lines (SPM-3T3) derived from homozygous sphingomyelinosis mice (spm/spm). Mouse A9 cells containing a single copy of pSV2neo-tagged chromosomes 9, 11, or 18 derived from normal human fibroblasts served as donor cells for transfer of human chromosomes. Purified A9 microcells were fused with SPM-3T3 cells, and the microcell hybrids were selected in medium containing G418 antibiotics. The microcell hybrids that contained human chromosomes 9, 11, or 18 in a majority of cells were examined. The accumulation of intracellular cholesterol in the microcell hybrids containing a chromosome 18 decreased markedly, whereas in the microcell hybrids containing either chromosomes 9 or 11 it was similar to that in SPM3T3 cells. The SPM-3T3 cells with an intact chromosome 18 were further passaged and subcloned. Clones which again accumulated intracellular cholesterol had concurrently lost the introduced chromosome 18. The abnormal accumulation was associated with a decrement in the esterification of exogenous cholesterol. These findings suggest that the gene responsible for the abnormal cholesterol metabolism in the spm/spm mice can be restored by a hu man chromosome 18. The gene was tentatively mapped on 18pter18p11.3 or 18q21.3qter that was lost during subcloning, thereby resulting in reaccumulation of the intracellular cholesterol.     

Diabetic pregnancy: evidence of selection on the Rh blood group system.

The blood glucose levels of pregnant women with insulin-dependent diabetes mellitus and the blood glucose levels of newborns during the first few hours of life show an association with maternal Rh genotype. Distortions of joint maternal-fetal Rh phenotype distribution have also been observed. Because a cluster of genes involved in glycide metabolism is located on the short arm of chromosome 1, the present observations may reflect the action of these genes.     

Evolutionary history of the Rh blood group-related genes in vertebrates

Rh and its homologous Rh50 gene products are considered to form heterotetramers on erythrocyte membranes. Rh protein has Rh blood group antigen sites, while Rh50 protein does not, and is more conserved than Rh protein. We previously determined both Rh and Rh50 gene cDNA coding regions from mouse and rat, and carried out phylogenetic analyses. In this study, we determined Rh50 gene cDNA coding regions from African clawed frog and Japanese medaka fish, and examined the long-term evolution of the Rh blood group and related genes. We constructed the phylogenetic tree from amino acid sequences. Rh50 genes of African clawed frog and Japanese medaka fish formed a cluster with mammalian Rh50 genes. The gene duplication time between Rh and Rh50 genes was estimated to be about 510 million years ago based on this tree. This period roughly corresponds to the Cambrian, before the divergence between jawless fish and jawed vertebrates. We also BLAST-searched an amino acid sequence database, and the Rh blood group and related genes were found to have homology with ammonium transporter genes of many organisms. Ammonium transporter genes can be classified into two major groups (amt alpha and amt beta). Both groups contain genes from three domains (bacteria, archaea, and eukaryota). The Rh blood group and related genes are separated from both amt alpha and beta groups.     

Assignment of the red cell antigen, Targett (Rh40), to the Rh blood group system.

Statistical and serological evidence from a large kindred and two unrelated adults indicates that Targett (Tar) is an antigen in the Rh blood group system and that its presence is assocciated with a weak expression of the Rh antigen D. In the numerical notation the Tar antigen is designated Rh40.     

The R-C-E-F blood group system of chimpanzees: Serology and genetics

Six chimpanzee alloimmune antibodies define 20 phenotypes of the R-C-E-F blood group system, the counterpart of the human Rh system. Of the several specificities of this system, the R^c constitutes the crucial link with human Rh since the reactions of some chimpanzee alloimmune anti-R^c sera with human red cells parallel those obtained with human anti-Rh_o reagents. Reciprocally, properly absorbed human anti-Rh_o sera detect R^c specificity on chimpanzee red cells. Tests with large panels of human monoclonal anti-D antibodies confirm the notion of shared epitopes between human alloantigen Rh_o(D) and chimpanzee alloantigen R^c.     

Evolutionary genetics of the Drosophila alcohol dehydrogenase gene-enzyme system

Evolutionary genetics embodies a broad research area that ranges from the DNA level to studies of genetic aspects in populations. In all cases the purpose is to determine the impact of genetic variation on evolutionary change. The broad range of evolutionary genetics requires the involvement of a diverse group of researchers: molecular biologists, (population) geneticists, biochemists, physiologists, ecologists, ethologists and theorists, each of which has its own insights and interests. For example, biochemists are often not concerned with the physiological function of a protein (with respect to pH, substrates, temperature, etc.), while ecologists, in turn, are often not interested in the biochemical-physiological aspects underlying the traits they study. This review deals with several evolutionary aspects of the Drosophila alcohol dehydrogenase gene-enzyme system, and includes my own personal viewpoints. I have tried to condense and integrate the current knowledge in this field as it has developed since the comprehensive review by van Delden (1982). Details on specific issues may be gained from Sofer and Martin (1987), Sullivan, Atkinson and Starmer (1990); Chambers (1988, 1991); Geer, Miller and Heinstra (1991); and Winberg and McKinley-McKee (1992).Dedicated to Professor Billy W. Geer, because of his contributions to knowledge of the biochemical genetics of Drosophila.     

Investigation of the human Rh blood group system in nonhuman primates and other species with serologic and Southern blot analysis

To investigate the evolution of the Rh blood-group system in anthropoid apes, New and Old World monkeys, and nonprimate animals, serologic typing of erythrocytes from these species with antibodies specific for the human Rh blood-group antigens was performed. In addition, genomic DNA from these animals was analyzed on Southern blots with a human Rh-specific cDNA.Consistent with earlier reports, serologic results showed that gorilla and chimpanzee erythrocytes had epitopes recognized by human Rh D and c antisera, and gibbon erythrocytes were recognized by the c antisera. Surprisingly, some Old and New World monkeys also expressed a Rh c epitope on their erythrocytes. No erythrocytes from the nonprimate animals reacted specifically with any of the human Rh antisera.Southern blot analysis with a human Rh-specific cDNA probe detected Rh-related sequences in anthropoid apes, all New and Old World monkeys, and in most nonprimate animals tested. Although some Rh-related restriction fragments were conserved across species lines in primates, the Rh locus was more polymorphic in chimpanzees and gorillas than in humans. In addition, restriction fragments segregating with the presence of the D antigen in humans were present in the primate species that expressed the D antigen.     

The molecular genetics of blood group polymorphism

Over 300 blood group specificities on red cells have been identified, many of which are polymorphic. The molecular mechanisms responsible for these polymorphisms are diverse, though many simply represent single nucleotide polymorphisms (SNPs). Other mechanisms include the following: gene deletion; single nucleotide deletion and sequence duplication, which introduce reading-frame shifts; nonsense mutation; intergenic recombination between closely linked genes, giving rise to hybrid genes and hybrid proteins; and a SNP in the promoter region of a blood group gene. Examples of these various genetic mechanisms are taken from the ABO, Rh, Kell, and Duffy blood group systems. Null phenotypes, in which no antigens of a blood group system are expressed, are not generally polymorphic, but provide good examples of the effect of inactivating mutations on blood group expression. As natural human ‘knock-outs’, null phenotypes provide useful clues to the functions of blood group antigens. Knowledge of the molecular backgrounds of blood group polymorphisms provides a means to predict blood group phenotypes from genomic DNA. This has two main applications in transfusion medicine: determination of foetal blood groups to assess whether the foetus is at risk from haemolytic disease and ascertainment of blood group phenotypes in multiply transfused, transfusion-dependent patients, where serological tests are precluded by the presence of donor red cells. Other applications are being developed for the future.     

Molecular genetics of chimpanzee Rh-related genes: Their relationship with the R-C-E-F blood group system,the chimpanzee counterpart of the human rhesus system

As the chimpanzee R-C-E-F blood group system appears to be the chimpanzee counterpart of the human Rhesus (RH) system, we have tried to determine whether chimpanzee Rh-like genes encode R-C-E-F-related proteins. Chimpanzee genomic DNA, digested by any of eight endonucleases and hybridized with three Rh exon-specific probes, exhibits a high degree of polymorphism. Analysis of DNA from unrelated individuals of different R-C-E-F types revealed that the presence of some restriction fragments is correlated with particular R-C-E-F types. The cosegregation of these fragments with R-C-E-F haplotypes was confirmed by family studies. Oligonucleotides complementary to regions flanking human exons were used as PCR primers on chimpanzee DNA; the resulting amplified fragments were identical in size to their human counterparts. Moreover, the nucleotide sequences of the fragments present a high degree of similarity to the corresponding human regions.     

The M-N-V-A-B-D blood group system of chimpanzee and other apes: Serology and genetics

Poly- and monoclonal anti-M and anti-N reagents detect on the red cells of anthropoid apes the M and/or N antigens which are similar to, but not identical with human M and N. A series of V-A-B-D specificities, closely related to the M-N system, are recognized on ape red blood cells by chimpanzee immune sera. To account for the distributions of the M-N-V-A-B-D types in man and in various apes, a genetic model is proposed that assumes the existence of two independent pairs of alleles: M/m, and N/n. In the processes of speciation, some of the alleles were lost or replaced by multiple mutations, resulting in chimpanzee in a series of codominant alleles responsible for as many as 16 M-N-V-A-B-D phenotypes.     

Chimpanzee R-C-E-F blood group system: a counterpart of the human Rh-Hr blood groups

A chimpanzee blood group system is defined by a set of isoimmune antisera, anti-Rc, anti-Cc, anti-Ec, anti-Fc, anti-Cc and anti-Cc1, that distinguish 19 blood types. Population analysis of 285 unrelated animals and the study of 21 chimpanzee families support the postulated model of inheritance by 9 allelic genes. There is a close relationship between the R-C-E-F blood group system and human Rh-Hr blood groups as indicated by overall structural resemblance of both systems and by serological similarity of their principal antigens, Rc and Rho. There are indications that R-like structures are also present on the red cells of other anthropoid apes, and possibly on those of the Old World monkeys.     

Involvement of Rh blood group polypeptides in the maintenance of aminophospholipid asymmetry

The human erythrocyte (RBC) Rh blood group system consists of a complex of distinct integral membrane polypeptides with physical properties common to the aminophospholipid transporter responsible for the transbilayer movement of phosphatidylserine (PS) in RBC. To assess the involvement of Rh polypeptides in PS translocation, the aminophospholipid translocase was labeled with a photoactivatable PS analogue, 125I-azido-PS, and with an inhibitor of PS transport, 125I-labeled 2-(2-pyridyldithio)ethylamine. The ability of monoclonal Rh antibodies to immunoprecipitate the labeled transporter was determined. Immunoprecipitated Rh polypeptides were found to be labeled with the aminophospholipid translocase markers, suggesting that Rh proteins are involved in the transbilayer movement of PS.