Characterization of blood-group-active erythrocyte membrane glycoproteins with human antiseras*

Scianna antigens including Rd are expressed by ERMAP

The Scianna blood group encompasses the high-frequency antigens Sc1 and Sc3 and the low-frequency antigen Sc2. Another low-frequency antigen Rd (Radin) was suggested to belong to the Scianna blood group. The molecular basis of the Scianna blood group was unknown. The erythrocyte membrane-associated protein (ERMAP) shared the genomic location, protein product size, and localization to the red blood cell (RBC) membrane surface with Scianna. The ERMAP gene was sequenced in probands with known Scianna and Radin phenotypes. In a Sc:-1,-2 proband, only an ERMAP allele with a 2-bp deletion in exon 3 causing a frameshift could be detected. A Sc:-1,2 proband was homozygous for the ERMAP(Gly57Arg) allele. An Rd(+) proband was heterozygous for the ERMAP(Pro60Ala) allele. Polymerase chain reaction with sequence-specific priming (PCR-SSP) systems was developed to detect the Sc2 and Rd alleles of the ERMAP gene. The 2 alleles occurred with about 1% and less than 1% frequency in the population, which was compatible with the frequency of the Sc2 and Rd antigens known in whites. Two Sc2(+) and one Rd(+) samples that were found by genotyping were confirmed by serology. The antigens of the Scianna blood group include Rd and are expressed by the human ERMAP protein. Sc2 is caused by an ERMAP(Gly57Arg) allele and Rd by an ERMAP(Pro60Ala) allele. Scianna is the last of the previously characterized protein-based blood group systems whose molecular basis was discerned. Hence, the phenotype prediction by genotyping became possible for all human blood group systems encoded by proteins.

Blood groups and their function

The function(s) assigned to red blood cell membrane components is based on an observed effect in the red cells that lack the component, comparison of the protein sequence (predicted from the nucleotide sequence of the gene) to proteins of known function, and extrapolation of function of the component in other cells. The functions are varied and include membrane structure, transport, receptor, adhesion, enzyme activity, complement components, complement regulation and glycocalyx formation. Several components have more than one function.

Chromosome location of genes encoding human blood groups

The chromosomal locations of genes controlling the expression of some 200 antigens constituting the 23 established human blood group systems have been reviewed. Twenty-one of the these genes are located on 12 autosomes, and two are located on the X chromosome. Refined chromosomal positions, to a single cytogenetically distinguishable band, have been established for 13 of the 23 genes. For the remainder, continued investigation will achieve the same result. The genes (RD, MER2, and OK) controlling the expression of one low-incidence and two high-incidence erythrocyte antigens have also been presented. Of these, OK is the most likely candidate for blood group system status, because its chromosomal location distinguishes it from all established system genes except LE and LW, and, the product of the OK gene is different from those of LE and LW (Table 3). This issue will be considered at the next meeting (scheduled for July 1998) of the ISBT Working Party. Alternatively, RD and MER2 are not good candidates for blood group system status because RD and MER2 reside in chromosomal regions containing genes for other blood group systems. In addition, the products of RD and SC have similar biochemical characteristics, and the product of MER2 has not yet been defined (Table 3). The challenge remaining for blood group scientists is characterization of genes that control expression of the approximately 50 other known erythrocyte antigens. Most of these are members of the ISBT's 700 (low-incidence) or 901 (high-incidence) series. Because the current genetic information for each of these antigens (attained by serologic investigation) varies considerably, future studies will have to rely on "tools" from related disciplines to provide the additional information. Use of resources such as molecular biological protocols and GBD should facilitate the effort.

[A molecular approach to the structure, polymorphism and function of blood groups]

Biochemical and molecular genetic studies have contributed to our molecular knowledge of blood group-associated molecules in the past few years. Among the 23 blood group systems presently identified, almost all have a molecular basis and present investigations are oriented towards the analysis of genetic polymorphisms, tissue-specific expression and structure-function relationships. Antigens defined by carbohydrate structures, among which ABO, Hh, Lewis and Secretor are the main representative species, are indirect gene products. They are synthesized by Golgi-resident glycosyltransferases, which are the direct products of the blood group genes. Many of these enzymes have been cloned and the molecular basis of the silent phenotypes, for instance 0, Bombay/paraBombay, Le(a-b-) and non-secretor, has been elucidated. However, the glycosyltransferases involved in the biosynthesis of Pk, P and P1 antigens are not yet characterized. A large number of blood group antigens carried by red cell polypeptides expressed at the cell surface are not related to a carbohydrate structure, and these proteins are direct blood group gene products. Most have been cloned and characterized recently, for instance MN antigens (glycophorin A), Ss antigens (glycophorin B), Gerbich antigens (glycophorins C and D) and antigens encoded by the RH, LW, KEL, FY, JK, XG, LU and XK loci. Other antigens have been located on proteins already identified, for instance the Cromer antigens on DAF, Knops antigens on CR1, Indian and AnWj antigens on CD44, Yt antigens on AChE, Diego, Wr, Rga and Warr on Band 3, Colton antigens on AQP-1 (water channel). The SC (Scianna) et DO (Dombrock) systems, however, still resist to molecular cloning. On the basis of this information, a tentative classification of blood group antigens into five functional categories is emerging: - Transporters and channels, - Receptors and ligands, - Adhesion molecules, - Enzymes, - Structural proteins. This review will focus on these recent findings and will illustrate how these studies may bring new information for analysis of normal and abnormal phenotypes and for understanding both the mechanisms of tissue specific expression and the potential function of these antigens, particularly those expressed in non-erythroid lineage. In addition, since our knowledge of the molecular basis of blood group polymorphisms has significantly increased, new genotyping techniques potentially useful in clinical applications will become available.