ALBERT

Description: Rabbit polyclonal antibodies were raised against synthetic peptides corresponding to hydrophilic regions of the human Rhesus (Rh) IX cDNA- encoded polypeptide predicted to be extracellularly or intracellularly exposed in the topologic model of the Rh blood group protein. Four antibodies encompassing residues 33–45 (MPC1), 224–233 (MPC4), 390–404 (MPC6), and 408–416 (MPC8) were characterized and compared with a polyclonal anti-Rh protein obtained by immunization with purified Rh proteins. All antibodies had specificity for authentic Rh polypeptides and reacted on Western blot with Rh proteins immunoprecipitated with human monoclonal anti-RhD, -c, and -E. MPC1, but not the other antibodies, agglutinated all human erythrocytes except Rhnull and Rhmod cells, which either lack totally or are severely deficient in Rh proteins, respectively. Immunoblotting analysis with membrane proteins from common and rare variants showed that MPC1 and MPC8 reacted in Western blot with 32-Kd Rh polypeptides from all common red blood cells except those from Rhnull and Rhmod, indicating that peptide regions 33– 45 and 408–416 may be common to several if not all Rh proteins, whatever the Rh blood group specificity. MPC4 reacted only with membrane preparations from cells carrying the E antigen, whereas MPC6 recognized preferentially the Rh proteins from E and Ee preparations, suggesting that the protein encoded by the RhIXb cDNA carries the E and/or e antigen(s). Immunoadsorption experiments using inside-out or right-side-out sealed vesicules from DccEE red blood cells as competing antigen showed that the MPC6 and MPC8 antibodies bound only to the cytoplasmic side of the erythrocyte membrane, thus providing evidence for the intracellular orientation of the C-terminal 27 residues of the Rh polypeptides. Attempts to transiently or stably express the Rh polypeptides. Attempts to transiently or stably express the Rh cDNA in eukaryotic cells were largely unsuccessful, suggesting that Rh antigen expression at the cell surface requires correct transport and/or folding of the Rh proteins, possibly as a complex with one-membrane proteins of the Rh cluster that are lacking in Rhnull cells.

Description: Three Rh-related cDNAs have been isolated from a human bone marrow cDNA library and by polymerase chain reaction (PCR) amplification of human bone marrow and erythroblast mRNAs. They potentially encode a family of Rh protein isoforms that exhibit several unexpected structural properties as compared with the Rh polypeptide encoded by the cDNA clone identified previously. These modifications include several peptide deletions, the predicted alteration of Rh protein topology within the cell membrane, variations in the number and surface exposition of cysteine residues, and the generation of new C-terminal polypeptide segments caused by frameshift mutations. The four Rh mRNAs now described correspond to different splicing isoforms transcribed from the same Rh gene, and all exist in the same cell lineage (erythroid). Moreover, PCR experiments indicated that at least three of these RNA species exist in reticulocytes from donors with different commonly expressed Rh phenotypes. Although the translated proteins have not yet been characterized, these results suggest that the two genes at the RH locus may direct the synthesis of several protein species possibly corresponding to different Rh antigenic variants.

Description: The Rh (Rhesus) blood group antigens, D, Cc, and Ee, are carried by three unglycosylated membrane proteins of the human erythrocytes encoded by two highly related genes, D and CcEe. The major antigen, D, is a mosaic composed of at least nine determinants (epD1 through epD9). The lack of expression of some of these D epitopes at the surface of variant red blood cells defines the so-called D category phenotypes. In this report, we have determined the molecular basis of the DVI category phenotype characterized by the lack of epitopes D1, D2, D5, D6/7, and D8. Southern blot analysis and mRNA sequencing showed that the DVI phenotype is associated with two types of rearrangement of the D gene. Of 10 DVI genomes investigated, 8 exhibited a segmental DNA replacement (gene conversion) between the D fragment encompassing exons 4, 5, and 6 and the equivalent region of the CcEe gene. In the two other variants, these three exons are deleted. In both cases, the genomic rearrangement did not alter the reading frame of the variant RhD transcripts that are translated in 417 and 266 amino acid polypeptides, respectively. A heterogeneity of category DVI samples based on variable reactivity of the red blood cells with anti-D antibodies was previously found to be associated with the CDVIe or cDVIE haplotypes. Interestingly, our present results indicated that this serologic subdivision of the DVI category is correlated to two types of genomic rearrangements of the D gene.

Description: The Rh (Rhesus) blood group antigens, D, Cc, and Ee, are carried by three unglycosylated membrane proteins of the human erythrocytes encoded by two highly related genes, D and CcEe. The major antigen, D, is a mosaic composed of at least nine determinants (epD1 through epD9). The lack of expression of some of these D epitopes at the surface of variant red blood cells defines the so-called D category phenotypes. In this report, we have determined the molecular basis of the DVI category phenotype characterized by the lack of epitopes D1, D2, D5, D6/7, and D8. Southern blot analysis and mRNA sequencing showed that the DVI phenotype is associated with two types of rearrangement of the D gene. Of 10 DVI genomes investigated, 8 exhibited a segmental DNA replacement (gene conversion) between the D fragment encompassing exons 4, 5, and 6 and the equivalent region of the CcEe gene. In the two other variants, these three exons are deleted. In both cases, the genomic rearrangement did not alter the reading frame of the variant RhD transcripts that are translated in 417 and 266 amino acid polypeptides, respectively. A heterogeneity of category DVI samples based on variable reactivity of the red blood cells with anti-D antibodies was previously found to be associated with the CDVIe or cDVIE haplotypes. Interestingly, our present results indicated that this serologic subdivision of the DVI category is correlated to two types of genomic rearrangements of the D gene.

Description: The Rh blood group antigens are encoded by two highly related genes, RHD and RHCE, and the sequence of the common alleles (D, Ce, CE, ce, and cE) of these genes has been previously elucidated. In this report, Rh transcripts and gene fragments have been amplified using polymerase chain reaction from the blood of donors with the CW+ andCX+ phenotypes. Sequence analysis indicated that the expression of the CW (Rh8) and CX (Rh9) antigens are associated with point mutations in the RHCE gene, which provides the definitive evidence that the CW and CX specificities are encoded by the same gene as the Cc and Ee antigens. As compared with the common (CW- and CX-) transcripts of the RHCE gene, the CW+ and CX+ cDNAs exhibited A122G and G106A transitions that resulted in Gln41Arg and Ala36Thr amino acid substitutions in the CW+ and CX+ polypeptides, respectively. Therefore, although the CW and CX specificities behave serologically as if they were allelic, they cannot not be considered, stricto sensu, as the products of antithetical allelic forms of the RHCE gene. Based on the CW-/CW+ nucleotide polymorphism, a polymerase chain reaction assay useful for diagnosis purposes has been developed that detects the presence of the CW+ allele by the use of an allele-specific primer.

Description: Three Rh-related cDNAs have been isolated from a human bone marrow cDNA library and by polymerase chain reaction (PCR) amplification of human bone marrow and erythroblast mRNAs. They potentially encode a family of Rh protein isoforms that exhibit several unexpected structural properties as compared with the Rh polypeptide encoded by the cDNA clone identified previously. These modifications include several peptide deletions, the predicted alteration of Rh protein topology within the cell membrane, variations in the number and surface exposition of cysteine residues, and the generation of new C-terminal polypeptide segments caused by frameshift mutations. The four Rh mRNAs now described correspond to different splicing isoforms transcribed from the same Rh gene, and all exist in the same cell lineage (erythroid). Moreover, PCR experiments indicated that at least three of these RNA species exist in reticulocytes from donors with different commonly expressed Rh phenotypes. Although the translated proteins have not yet been characterized, these results suggest that the two genes at the RH locus may direct the synthesis of several protein species possibly corresponding to different Rh antigenic variants.

Description: Rabbit polyclonal antibodies were raised against synthetic peptides corresponding to hydrophilic regions of the human Rhesus (Rh) IX cDNA- encoded polypeptide predicted to be extracellularly or intracellularly exposed in the topologic model of the Rh blood group protein. Four antibodies encompassing residues 33–45 (MPC1), 224–233 (MPC4), 390–404 (MPC6), and 408–416 (MPC8) were characterized and compared with a polyclonal anti-Rh protein obtained by immunization with purified Rh proteins. All antibodies had specificity for authentic Rh polypeptides and reacted on Western blot with Rh proteins immunoprecipitated with human monoclonal anti-RhD, -c, and -E. MPC1, but not the other antibodies, agglutinated all human erythrocytes except Rhnull and Rhmod cells, which either lack totally or are severely deficient in Rh proteins, respectively. Immunoblotting analysis with membrane proteins from common and rare variants showed that MPC1 and MPC8 reacted in Western blot with 32-Kd Rh polypeptides from all common red blood cells except those from Rhnull and Rhmod, indicating that peptide regions 33– 45 and 408–416 may be common to several if not all Rh proteins, whatever the Rh blood group specificity. MPC4 reacted only with membrane preparations from cells carrying the E antigen, whereas MPC6 recognized preferentially the Rh proteins from E and Ee preparations, suggesting that the protein encoded by the RhIXb cDNA carries the E and/or e antigen(s). Immunoadsorption experiments using inside-out or right-side-out sealed vesicules from DccEE red blood cells as competing antigen showed that the MPC6 and MPC8 antibodies bound only to the cytoplasmic side of the erythrocyte membrane, thus providing evidence for the intracellular orientation of the C-terminal 27 residues of the Rh polypeptides. Attempts to transiently or stably express the Rh polypeptides. Attempts to transiently or stably express the Rh cDNA in eukaryotic cells were largely unsuccessful, suggesting that Rh antigen expression at the cell surface requires correct transport and/or folding of the Rh proteins, possibly as a complex with one-membrane proteins of the Rh cluster that are lacking in Rhnull cells.

Description: The Rh blood group antigens are encoded by two highly related genes, RHD and RHCE, and the sequence of the common alleles (D, Ce, CE, ce, and cE) of these genes has been previously elucidated. In this report, Rh transcripts and gene fragments have been amplified using polymerase chain reaction from the blood of donors with the CW+ andCX+ phenotypes. Sequence analysis indicated that the expression of the CW (Rh8) and CX (Rh9) antigens are associated with point mutations in the RHCE gene, which provides the definitive evidence that the CW and CX specificities are encoded by the same gene as the Cc and Ee antigens. As compared with the common (CW- and CX-) transcripts of the RHCE gene, the CW+ and CX+ cDNAs exhibited A122G and G106A transitions that resulted in Gln41Arg and Ala36Thr amino acid substitutions in the CW+ and CX+ polypeptides, respectively. Therefore, although the CW and CX specificities behave serologically as if they were allelic, they cannot not be considered, stricto sensu, as the products of antithetical allelic forms of the RHCE gene. Based on the CW-/CW+ nucleotide polymorphism, a polymerase chain reaction assay useful for diagnosis purposes has been developed that detects the presence of the CW+ allele by the use of an allele-specific primer.