The mRNA for the Duffy blood group antigen, the erythrocyte receptor for the Plasmodium vivax malaria parasite, has recently been cloned and shown to encode a widely expressed chemokine receptor. Here, we show that the Duffy antigen/chemokine receptor gene (DARC) is composed of a single exon and that most Duffy-negative blacks carry a silent FY*B allele with a single T to C substitution at nucleotide -46. This mutation impairs the promoter activity in erythroid cells by disrupting a binding site for the GATA1 erythroid transcription factor. With the recent characterization of the FY*A and FY*B alleles, these findings provide the molecular basis of the Duffy blood group system and an explanation for the erythroid-specific repression of the DARC gene in Duffy-negative individuals.
Malaria therapy, experimental, and epidemiological studies have shown that erythrocyte Duffy blood group-negative people, largely of African ancestry, are resistant to erythrocyte Plasmodium vivax infection. These findings established a paradigm that the Duffy antigen is required for P. vivax erythrocyte invasion. P. vivax is endemic in Madagascar, where admixture of Duffy-negative and Duffy-positive populations of diverse ethnic backgrounds has occurred over 2 millennia. There, we investigated susceptibility to P. vivax blood-stage infection and disease in association with Duffy blood group polymorphism. Duffy blood group genotyping identified 72% Duffy-negative individuals (FY*B ES /*B ES ) in community surveys conducted at eight sentinel sites. Flow cytometry and adsorption-elution results confirmed the absence of Duffy antigen expression on Duffy-negative erythrocytes. P. vivax PCR positivity was observed in 8.8% (42/476) of asymptomatic Duffy-negative people. Clinical vivax malaria was identified in Duffy-negative subjects with nine P. vivax monoinfections and eight mixed Plasmodium species infections that included P. vivax (4.9 and 4.4% of 183 participants, respectively). Microscopy examination of blood smears confirmed blood-stage development of P. vivax, including gametocytes. Genotyping of polymorphic surface and microsatellite markers suggested that multiple P. vivax strains were infecting Duffy-negative people. In Madagascar, P. vivax has broken through its dependence on the Duffy antigen for establishing human blood-stage infection and disease. Further studies are necessary to identify the parasite and host molecules that enable this Duffyindependent P. vivax invasion of human erythrocytes.erythrocyte | evolution | DARC | Madagascar
BackgroundThe transition from enucleated reticulocytes to mature normocytes is marked by substantial remodeling of the erythrocytic cytoplasm and membrane. Despite conspicuous changes, most studies describe the maturing reticulocyte as a homogenous erythropoietic cell type. While reticulocyte staging based on fluorescent RNA stains such as thiazole orange have been useful in a clinical setting; these ‘sub-vital’ stains may confound delicate studies on reticulocyte biology and may preclude their use in heamoparasite invasion studies.Design and MethodsHere we use highly purified populations of reticulocytes isolated from cord blood, sorted by flow cytometry into four sequential subpopulations based on transferrin receptor (CD71) expression: CD71high, CD71medium, CD71low and CD71negative. Each of these subgroups was phenotyped in terms of their, morphology, membrane antigens, biomechanical properties and metabolomic profile.ResultsSuperficially CD71high and CD71medium reticulocytes share a similar gross morphology (large and multilobular) when compared to the smaller, smooth and increasingly concave reticulocytes as seen in the in the CD71low and CD71negativesamples. However, between each of the four sample sets we observe significant decreases in shear modulus, cytoadhesive capacity, erythroid receptor expression (CD44, CD55, CD147, CD235R, and CD242) and metabolite concentrations. Interestingly increasing amounts of boric acid was found in the mature reticulocytes.ConclusionsReticulocyte maturation is a dynamic and continuous process, confounding efforts to rigidly classify them. Certainly this study does not offer an alternative classification strategy; instead we used a nondestructive sampling method to examine key phenotypic changes of in reticulocytes. Our study emphasizes a need to focus greater attention on reticulocyte biology.
ammonium ͉ mouse mutants ͉ Rhesus deficiency
The RH (rhesus) blood group locus from RhD-positive donors is composed of two homologous structural genes, one of which encodes the Cc and Ee polypeptides, whereas the other, which is missing in the RhD-negative condition, encodes the D protein that carries the major antigen of the RH system. Recently, different splicing isoforms transcribed from the CcEe gene were isolated. We report now the characterization of two other Rh clones, RhII and RhXIII, generated by alternative choices for poly(A) addition sites that were identified as the RhD gene transcripts. That these cDNAs represented the RhD messenger and that the previously described Rh clones were derived from the CcEe gene was demonstrated by amplification of RhII/XIII sequences only from D-positive genomes and by cloning and sequencing of D- and CcEe-specific gene fragments. The predicted translation product of the RhD mRNA is a 417-amino acid protein (M(r) = 45,500) that exhibited a similar membrane organization with 13 bilayer-spanning domains compared with the polypeptide encoded by the CcEe gene. The D and Cc/Ee polypeptides differ by 36 amino acid substitutions (8.4% divergence), but the NH2- and COOH-terminal regions of the two proteins are well conserved. Similarly, five of the six cysteine residues of the Cc/Ee proteins were conserved in the D protein, including the unique exofacial cysteine, which is critical for antigenic reactivity. The sequence homology between the Cc/Ee and D proteins supports the concept that the genes encoding these polypeptides have evolved by duplication of a common ancestor gene.
cDNA clones encoding a human blood group Rh polypeptide were isolated from a human bone marrow cDNA library by using a polymerase chain reaction-amplified DNA fragment encoding the known common N-terminal region of the Rh proteins. The entire primary structure of the Rh polypeptide has been deduced from the nucleotide sequence of a 1384-base-pair-long cDNA clone. Translation of the open reading frame indicates that the Rh protein is composed of 417 amino acids, including the initiator methionine, which is removed in the mature protein, lacks a cleavable N-terminal sequence, and has no consensus site for potential Nglycosylation. The predicted molecular mass of the protein is 45,500, while that estimated for the Rh protein analyzed in NaDodSO4/polyacrylamide gels is in the range of 30,000-32,000. These findings suggest either that the hydrophobic Rh protein behaves abnormally on NaDodSO4 gels or that the Rh mRNA may encode a precursor protein, which is further matured by a proteolytic cleavage of the C-terminal region of the polypeptide. Hydropathy analysis and secondary structure predictions suggest the presence of 13 membrane-spanning domains, indicating that the Rh polypeptide is highly hydrophobic and deeply buried within the phospholipid bilayer. In RNA blot-hybridization (Northern) analysis, the Rh cDNA probe detects a major 1.7-kilobase and a minor 3.5-kilobase mRNA species in adult erythroblasts, fetal liver, and erythroid (K562, HEL) and megakaryocytic (MEG01) leukemic cell lines, but not in adult liver and kidney tissues or lymphoid (Jurkat) and promyelocytic (HL60) cell lines. These results suggest that the expression of the Rh gene(s) might be restricted to tissues or cell lines expressing erythroid characters.
The Rhesus (RH) blood group locus is composed of two related structural genes, D and CcEe, that encode red cell membrane proteins carrying the D, Cc and Ee antigens. As demonstrated previously, the RhD-positive/RhD-negative polymorphism is associated with the presence or the absence of the D gene. Sequence analysis of transcripts and genomic DNA from individuals that belong to different Rh phenotypes were performed to determine the molecular basis of the C/c and E/e polymorphisms. The E and e alleles differ by a single nucleotide resulting in a Pro226Ala substitution, whereas the C and c alleles differ by six nucleotides producing four amino acid substitutions Cys16Trp, Ile60Leu, Ser68Asn and Ser103Pro. With the recent cloning of the RhD gene, these findings provide the molecular genetic basis that determine D, C, c, E and e specificities.
Currently, there are no reliable red blood cells invasion assays to guide the discovery of vaccines against Plasmodium vivax, the most prevalent malaria parasite in Asia and South America. Here we describe a protocol for an ex vivo P. vivax invasion assay that can be easily deployed in laboratories located in endemic countries. The assay is based on mixing enriched cord blood reticulocytes with matured, trypsin treated P. vivax schizonts concentrated from clinical isolates. The reliability of this assay was demonstrated using a large panel of P. vivax isolates freshly collected from patients in Thailand.
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