RH Blood Groups and Rh-Deficiency Syndrome

Molecular biology and genetics of the Rh blood group system

The Rh (Rhesus) blood group system is the most complex of the known human blood group polymorphisms. The expression of its antigens is controlled by a two-component genetic system consisting of RH and RHAG loci, which encode Rh30 polypeptides and Rh50 glycoprotein, respectively. Over the past decade, there has been a rapid advance in knowledge of the biochemistry, molecular biology, and genetics of the Rh genes and proteins. The primary structures of D and CcEe antigens have become well understood and the molecular genetic basis of a vast array of phenotype polymorphisms has been delineated. The identification of various molecular defects associated with Rh deficiency syndrome clarifies the nature of the amorph, suppressor, and modifier genes. The observed mutation spectrum defines a basic set of components essential for Rh complex assembly in the erythrocyte membrane. The resulting molecular information, combined with new experimental tools, is helping to dissect the fine structure of Rh antigens in terms of epitope mapping. The discovery of novel Rh homologs in primitive organisms and in nonerythroid tissues opens new avenues of research beyond the scope of erythrocytes and Rh antigens. This review provides an update on the Rh family in antigen expression, phenotype diversity, and disease association.

Rhmod syndrome: a family study of the translation-initiator mutation in the Rh50 glycoprotein gene

Rhmod syndrome is a rare genetic disorder thought to result from mutations at a "modifier" but not at the suppressor underlying the regulator type of Rhnull disease. We studied this disorder in a Jewish family with a consanguineous background and analyzed RH and RHAG, the two loci that control Rh-antigen expression and Rh-complex assembly. Despite the presence of a d (D-negative) haplotype, no other gross alteration was found at RH, and cDNA sequencing showed a normal structure for D, Ce, and ce Rh transcripts in family members. However, analysis of RHAG transcript, which encodes Rh50 glycoprotein, identified a single G-->T transversion in the initiation codon, causing a missense amino acid change (ATG[Met]-->ATT[Ile]). This point mutation also occurred in the genomic region spanning exon 1 of RHAG, and its genotypic status in the mother and two children was confirmed by analysis of single-strand conformation polymorphism. Although blood typing showed a very weak expression of Rh antigens, immunoblotting barely detected the Rh proteins in the Rhmod membrane. In vitro transcription-coupled translation assays showed that the initiator mutants of Rhmod-but not those of the wild type-could be translated from ATG codons downstream. Our findings point to incomplete penetrance of the Rhmod mutation, in the form of "leaky" translation, leading to some posttranslational defects affecting the structure, interaction, and processing of Rh50 glycoprotein.

The VS and V blood group polymorphisms in Africans: a serologic and molecular analysis

BACKGROUND

VS and V are common red cell antigens in persons of African origin. The molecular background of these Rh system antigens is poorly understood.

STUDY DESIGN AND METHODS

Red cells from 100 black South Africans and 43 black persons from Amsterdam, the Netherlands, were typed serologically for various Rh system antigens. Allele-specific polymerase chain reaction and sequencing of polymerase chain reaction products were used to analyze C733G (Leu245Val) and G1006T (Gly336Cys) polymorphisms in exons 5 and 7 of RHCE and the presence of a D-CE hybrid exon 3.

RESULTS

The respective frequencies of all VS+ and of VS+ V-(r's) phenotypes were 43 percent and 9 percent in the South Africans and 49 percent and 12 percent in the Dutch donors. All VS+ donors had G733 (Val245), but six with G733 were VS- (4 V+w, 2 V-). The four VS- V+w donors with G733 appeared to have a CE-D hybrid exon 5. T1006 (Cys336) was present in 12 percent and 16 percent of donors from the two populations. With only a few exceptions, T1006, a D-CE hybrid exon 3, and a C410T (Ala137Val) substitution were associated with a VS+ V-phenotype ((C)ces or r's haplotype). Two VS+ V-individuals, with the probable genotype, (C)ces/(C)ces), were homozygous for G733 and for T1006.

CONCLUSIONS

It is likely that anti-VS and anti-V recognize the conformational changes created by Val245, but that anti-V is sensitive to additional conformational changes created by Cys336.

Rh50 Glycoprotein Gene and Rhnull Disease: A Silent Splice Donor Is trans to a Gly279→Glu Missense Mutation in the Conserved Transmembrane Segment

Rhnull disease includes the amorph and regulator types that are thought to result from homozygous mutations at theRH30 and RH50 loci, respectively. Here we report an unusual regulator Rhnull where two G→A nucleotide (nt) transitions occurred in trans, targeting different regions of the two copies of Rh50 gene. The nt 836 G→A mutation was a missense change located in exon 6; it converted Gly into Glu at position 279, a central amino acid of the transmembrane segment 9 (TM9). While cDNA analysis showed expression of the 836A(Glu279) allele only, genomic studies showed the presence of both 836A(Glu279) and 836G(Gly279) alleles. A detailed analysis of gene organization led to the identification in the Rh50(836G) allele of a defective donor splice site, caused by a G→A mutation in the invariant GT element of intron 1. This is the first known example of such mutations that has apparently abolished the functional splicing of a pre-mRNA encoding a multipass integral membrane protein. With a silent phenotypic copy intrans, the negatively charged Glu279 residue may disrupt TM9 and impair the interaction of the missense protein with Rh30 polypeptides. To evaluate the significance of the mutation, we took a comparative genomic approach and identified Rh50 homologues in different species. We found that Gly279 is a conserved residue and its adjacent amino acid sequence is identical fromCaenorhabditis elegans to human. These findings provide new insight into the diversity of Rhnull disease and suggest that the C-terminal region of Rh50 may also participate in protein-protein interactions involving Rh complex formation.

© 1998 by The American Society of Hematology.

Rh50 Glycoprotein Gene and Rhnull Disease: A Silent Splice Donor Is trans to a Gly279→Glu Missense Mutation in the Conserved Transmembrane Segment

Rhnull disease includes the amorph and regulator types that are thought to result from homozygous mutations at theRH30 and RH50 loci, respectively. Here we report an unusual regulator Rhnull where two G→A nucleotide (nt) transitions occurred in trans, targeting different regions of the two copies of Rh50 gene. The nt 836 G→A mutation was a missense change located in exon 6; it converted Gly into Glu at position 279, a central amino acid of the transmembrane segment 9 (TM9). While cDNA analysis showed expression of the 836A(Glu279) allele only, genomic studies showed the presence of both 836A(Glu279) and 836G(Gly279) alleles. A detailed analysis of gene organization led to the identification in the Rh50(836G) allele of a defective donor splice site, caused by a G→A mutation in the invariant GT element of intron 1. This is the first known example of such mutations that has apparently abolished the functional splicing of a pre-mRNA encoding a multipass integral membrane protein. With a silent phenotypic copy intrans, the negatively charged Glu279 residue may disrupt TM9 and impair the interaction of the missense protein with Rh30 polypeptides. To evaluate the significance of the mutation, we took a comparative genomic approach and identified Rh50 homologues in different species. We found that Gly279 is a conserved residue and its adjacent amino acid sequence is identical fromCaenorhabditis elegans to human. These findings provide new insight into the diversity of Rhnull disease and suggest that the C-terminal region of Rh50 may also participate in protein-protein interactions involving Rh complex formation.

© 1998 by The American Society of Hematology.

Rhnull Disease: The Amorph Type Results From a Novel Double Mutation in RhCe Gene on D-Negative Background

Rhnull disease, which includes the amorph and regulator types, is a rare genetic disorder characterized by stomatocytosis and chronic hemolytic anemia. We studied here a German family transmitting a putative amorph Rhnull disease gene and identified a rare mutation causing the loss-of-function phenotype. We analyzed the genomic and transcript structure of RH30, RH50, andCD47, the three loci thought to be most critical for expression of the Rh complex in the red blood cell membrane. We showed that in this family the Rh50 and CD47 transcripts were normal in primary sequence. However, the RH30 locus contained an unusual double mutation in exon 7 of the RhCe gene, in addition to a deletion of the RhD gene. The mutation targeted two adjacent codons in multiple arrangements probably via the mechanism of microgene conversion. One scheme entails a noncontiguous deletion of two nucleotides, [ATT(Ile322)→AT] and [CAC(His323)→CC], whereas the other involves a T→C transition [ATT(Ile322)→ATC] and a dinucleotide deletion [CAC(His323)→C]. They caused the same shift in open reading frame predicted to encode a shortened protein with 398 amino acids. The loss of two transmembrane domains and gain of a new C-terminal sequence are likely to alter the protein conformation and impair the Rh complex assembly. Our findings establish the molecular identity of an amorph Rhnull disease gene, showing that Rh30 and Rh50 are both essential for the functioning of the Rh structures as a multisubunit complex in the plasma membrane.

Rhnull Disease: The Amorph Type Results From a Novel Double Mutation in RhCe Gene on D-Negative Background

Rhnull disease, which includes the amorph and regulator types, is a rare genetic disorder characterized by stomatocytosis and chronic hemolytic anemia. We studied here a German family transmitting a putative amorph Rhnull disease gene and identified a rare mutation causing the loss-of-function phenotype. We analyzed the genomic and transcript structure of RH30, RH50, andCD47, the three loci thought to be most critical for expression of the Rh complex in the red blood cell membrane. We showed that in this family the Rh50 and CD47 transcripts were normal in primary sequence. However, the RH30 locus contained an unusual double mutation in exon 7 of the RhCe gene, in addition to a deletion of the RhD gene. The mutation targeted two adjacent codons in multiple arrangements probably via the mechanism of microgene conversion. One scheme entails a noncontiguous deletion of two nucleotides, [ATT(Ile322)→AT] and [CAC(His323)→CC], whereas the other involves a T→C transition [ATT(Ile322)→ATC] and a dinucleotide deletion [CAC(His323)→C]. They caused the same shift in open reading frame predicted to encode a shortened protein with 398 amino acids. The loss of two transmembrane domains and gain of a new C-terminal sequence are likely to alter the protein conformation and impair the Rh complex assembly. Our findings establish the molecular identity of an amorph Rhnull disease gene, showing that Rh30 and Rh50 are both essential for the functioning of the Rh structures as a multisubunit complex in the plasma membrane.

The human Rh50 glycoprotein gene. Structural organization and associated splicing defect resulting in Rh(null) disease

The Rh (Rhesus) protein family comprises Rh50 glycoprotein and Rh30 polypeptides, which form a complex essential for Rh antigen expression and erythrocyte membrane integrity. This article describes the structural organization of Rh50 gene and identification of its associated splicing defect causing Rhnull disease. The Rh50 gene, which maps at chromosome 6p11-21.1, has an exon/intron structure nearly identical to Rh30 genes, which map at 1p34-36. Of the 10 exons assigned, conservation of size and sequence is confined mainly to the region from exons 2 to 9, suggesting that RH50 and RH30 were formed as two separate genetic loci from a common ancestor via a transchromosomal insertion event. The available information on the structure of RH50 facilitated search for candidate mutations underlying the Rh deficiency syndrome, an autosomal recessive disorder characterized by mild to moderate chronic hemolytic anemia and spherostomatocytosis. In one patient with the Rhnull disease of regulator type, a shortened Rh50 transcript lacking the sequence of exon 7 was detected, while no abnormality was found in transcripts encoding Rh30 polypeptides and Rh-related CD47 glycoprotein. Amplification and sequencing of the genomic region spanning exon 7 revealed a G-->A transition in the invariant GT motif of the donor splice site in both Rh50 alleles. This splicing mutation caused not only a total skipping of exon 7 but also a frameshift and premature chain termination. Thus, the deduced translation product contained 351 instead of 409 amino acids, with an entirely different C-terminal sequence following Thr315. These results identify the donor splicing defect, for the first time, as a loss-of-function mutation at the RH50 locus and pinpoint the importance of the C-terminal region of Rh50 in Rh complex formation via protein-protein interactions.