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Non-human orthologs of the Rh blood group system
Recent studies of RHAG and RHCED genes in a number of different mammalian and non-mammalian organisms indicate that both loci arose from a common origin and evolved into an ever-expanding gene family. Whereas products of RHAG and RHCED are expressed in erythrocytes of all mammals examined so far, homologs of RHAG only have been identified both in erythroid and non-erythroid tissues, and all RH-like genes recently identified in lower species such as C. elegans or the slime mold, are more homologous to RHAG than to RHCED, and may represent the prototype of the ancestor gene.
Thus it appears that, early in evolution, RHCED arose from RHAG via a chromosomal translocation event and the divergence of both loci then proceeded at distinct rates; RHCED (ultimately gave rise to RHCE and RHD) evolved at a rate about twice faster than RHAG and remains polymorphic at the level of populations, whereas RHAG remains monomorphic. It appears that both loci experienced different selective forces, that possibly relate to their functional conservation during evolution. The discovery of RH orthologs and paralogs in slime mold and non-erythroid tissues supports the idea that RH proteins fulfill an important function in the physiology of the organism that is not confined to erythocytes only. This function still needs to be clarified. (Learn about primates here.)
Figure above shows a dendrogram of 30 Rh protein homologues obtained from representative organisms. For details, see C.-H. Huang and P.Z. Liu, Blood Cells Mol. Dis. 2001. 27(1); 90-101(with permission from the journal).
In most primates and mammals such as mouse, rat or cow (only mammals examined so far) a single gene, a homologue of RHCED, is present. This gene encodes counterparts of human Rh30 polypeptides that are expressed at the erythocyte surface and, like in man, seem to be integral membrane proteins with multiple transmembrane spanning segments. As deduced from the hydrophobicity profiles they most probably display twelve transmembrane segments delineating six external loops (see the human Rh site).
In the course of primate evolution, in the common ancestor of man, chimpanzee and gorilla, the RHCED ancestor gene duplicated and the two resulting genes further diversified; one resulted in the RHCE ancestor and the other gave rise to the RHD ancestor gene. Thereafter, due to multiple unequal crossings-overs favored by the homology of the RH genes, a polymorphism of RH gene number appeared at the locus. In man, two types of haplotypes are known. The first type is characterized by the presence of two closely linked genes: one called RHD, responsible for the expression of the antigen D, the second, called RHCE, possesses four different alleles, responsible for the expression of the two antithetical series of antigens C/c and E/e. The second haplotype (occurs with a frequency of 39% in Caucasians), is characterized by the complete deletion of the RHD gene but the presence of RHCE, in form of the four alleles. Chimpanzees and gorillas possess,respectively, three and two RH-like genes per haplotype.
Only chimpanzee and gorilla possess antigen D counterparts. Other apes, orangutan and gibbon possess more distantly related antigens. In the case of the Chimpanzee, the D counterpart is carried by proteins which define the chimpanzee blood group antigens of the R-C-E-F system. This blood group system is as complex at that of man and it depends on the polymorphism of the chimpanzee Rh-like genes. In gorilla, Rh-like gene polymorphism is related to the expression of the Dgor antigen which is the gorilla couterpart of the human D antigen. Counterparts of the human antigen c are expressed by chimpanzee, gorilla and gibbon. However in these species, in contrast to man, the expression of the c-like antigen is monomorphic The other human Rh antigens (C, e, E) have no counterparts among apes or other primates.
In the case of the mouse RHCED gene, the only species in addition to human whose gene organization was studied, the exon-intron structure and arrangement appear identical to the human gene. The deduced protein sequence is consistent with an integral membrane protein showing a high level of sequence homology among family members and across the species. Mouse and all lower mammalian and non-mammalian species do not express Rh antigen counterparts, eventhough their red cell membranes contain the Rh30 proteins.
Above is a model for the vertebrate Rh glycoprotein homologues constructed with the consensus amino acid sequences: The consensus sequence was derived by aligning 16 proteins. Hydropathy analysis was done using Kyte-Doolittle method. Red denotes identical residues present in 14-16 protein sequences; black, conserved; and crosses, non-conserved residues. Conserved charge distribution is in yellow and E/Q (Glu/Gln) alternation is in green. [(x)]n denotes length variation in the N- or C- terminal sequence.
Rh30 are erythrocyte integral membrane nonglycosylated, palmitoylated proteins, with an apparent molecular weights, by SDS-PAGE, between 32 and 35 kDa (actual MW ~ 45 kDa). Rh30 polypeptides are components of a membrane complex of erythrocyte membrane proteins including Rh50 glycoprotein and LW, Fy, CD47 and GPB proteins. Interaction with Rh50 is essential for the expression of RhCED antigens.
Blancher & Socha. The Rhesus System. In Blancher, Klein, Socha Eds. Molecular Biology and Evolution of Blood Group and MHC antigens in Primates, p93-164. Heildelberg, Springer Verlag. 1997; Kitano et al. BBRC. 249, 78, 1998; Matassi et al. J. Mol. Evol. 48, 151, 1999; Westhoff et al. Genomics. 57:451, 1999; Liu & Huang. Biochem. Genet. 37:119, 1999; Huang et al. J. Mol. Evol. 51: 76. 2000; Huang et al. Seminars in Hematol. 37:150. 2000.Rh30 orthologs
About Rh50 orthologs
In most primates and mammals such as mouse or rat a single gene, a homologue of RHAG, is present. In contrast to RHCED, RHAG remains invariant at the population level. The gene encodes counterparts of human Rh50 glycoprotein that is expressed at the erythocyte surface and also in some non-erythroid tissues and, like in man, seems to be an integral membrane protein with multiple transmembrane-spanning segments.It shares ~ 36% identity with Rh30 polypeptides but, its disposition across the membrane is similar to Rh30; thus, as deduced from the hydrophobicity profiles, it most probably displays twelve transmembrane segments delineating six external loops (see the human RHAG site).
Rh50 is a glycosylated membrane protein with an apparent molecular weight, by SDS-PAGE, between x and x kD; heterogeneity of the glycosylation is responsible for this range of sizes but the molecular weight of the protein moiety is ~ 45 kDa. The human Rh50 locus is located on chromosome 6p11-21.1 and, in mouse, its counterpart resides on chromosome 17 in a syntenic region. Its chromosomal location has not been determined in primates.
The Rh50 protein is a component of a membrane complex of erythrocyte membrane proteins which includes, in man, RhCED, LW, Fy, CD47 and GPB proteins. In man, Rh50 is essential for the surface expression of the Rh30 polypeptides which carry the Rh blood group antigens. The absence of the Rh50 (or some specific point mutations) is responsible for the absence (or very low expresion) of the Rh antigens. This syndrome in man,is referred to as Rhnull of regulator type.
In the case of mouse, the only species in addition to human in which gene organization was studied, the exon-intron structure and arrangement appear identical to the human gene. The deduced protein sequence is consistent with an integral membrane protein and shows a high level of sequence homology to the primate counterparts. It shows about 40% identity to other family members (Rh30) across the species.
Rh50 proteins display homology with proteins deduced from cDNA sequences of Caenorrhabditis elegans, of the marine sponge and green algae. Also,the Rh50 proteins share some homology with ammonium transporters of bacteria, yeast and C. elegans. Yet, the Rh50 and ammonium transporter genes of C. elegans are different (accession numbers of the latter: U53338; M195.3; Z66498). At this time, the function of the Rh50 and Rh30 proteins remains elusive.
Orthologs of RHAG (Rh50) genes
Antoine Blancher, MD, PhD, Laboratoire d'Immunologie, Hopital Rangueil Av.Jean Poulhes 31403 Toulouse CEDEX 4, France. Email -
Cheng-Han Huan, MD, PhD, Laboratory of Biochemistry and Molecular Genetics. Lindsley F.Kimball Research Institute. New York Blood Center. New York, N.Y. 10021. Tel.: 212 570-3388. Fax: 212 570 3251. Email -
Updated June, 2005