Recommendations for locus-specific databases and their curation.

Expert curation and complete collection of mutations in genes that affect human health is essential for proper genetic healthcare and research. Expert curation is given by the curators of gene-specific mutation databases or locus-specific databases (LSDBs). While there are over 700 such databases, they vary in their content, completeness, time available for curation, and the expertise of the curator. Curation and LSDBs have been discussed, written about, and protocols have been provided for over 10 years, but there have been no formal recommendations for the ideal form of these entities. This work initiates a discussion on this topic to assist future efforts in human genetics. Further discussion is welcome.

A novel St(a) glycophorin produced via gene conversion of pseudoexon III from glycophorin E to glycophorin A gene.

Stone (St(a)) is a variant antigen carried on human erythrocyte MNSs glycophorins (GPSt(a)) that are genetically associated with splicing mutations in GPA genes or with hybrid formation between GPA and GPB genes. Here we identify the first and rare gene conversion event in which GPE, the third member of the family, recombined with GPA, giving rise to a GPA-E-A hybrid gene encoding the St(a) antigen. Western blot detected expression in the proband of both GPA and GPSt(a) on the plasma membrane. Southern blot showed a new restriction fragment from the GPSt(a) gene, indicating an altered exon III-intron 3 junction. Sequencing of RT-PCR products identified one full-length and two shortened glycophorin cDNAs. The shortened forms were derived from GPSt(a) lacking one (exon III) and two exons (exon III and IV), respectively. To define the molecular basis for exon skipping, the genomic region spanning exon III of the GPSt(a) gene was amplified and sequenced. This revealed transfer from GPE to GPA of a DNA segment containing the pseudoexon III and its silent donor splice site. Thus, the inactivation of GPA exon III by conversion of a silent GPE donor splice site portrays a new molecular mechanism for St(a) antigen expression in human erythrocytes.

Alternative splicing of a novel glycophorin allele GPHe(GL) generates two protein isoforms in the human erythrocyte membrane.

The Henshaw antigen (synonym: He or MNS6) is carried by an altered form of glycophorin B (GPB), but the molecular basis for its variable expression or quantitative polymorphism remains largely undefined. We report here the identification and analysis of a novel glycophorin He allele, GPHe(GL), which gives rise to the expression of two protein isoforms in the erythrocyte membrane. In addition to the nucleotide changes defining the epitopic sequence of He, a single C-to-G nucleotide transversion in exon V coding for the membrane domain was found to cause aberrant RNA splicings by creating a new acceptor splice site. In addition, a T-to-G transversion at -6 position of the acceptor splice site for exon IV was identified. Both full-length and truncated transcripts of GPHe(GL) were detected as the result of partial activation of the new acceptor splice site and partial inactivation of the normal splice sites. The full-length cDNA encoded He, S, and U antigens, whereas the three truncated ones lacked either the sequence for S and U antigens or a large portion of the membrane domain or both. The GPB gene on the other chromosome was apparently normal and its transcript encoded N, s, and U antigens. These results correlate alternative RNA splicing with the expression of two GPHe isoforms and thus delineate a new mechanism for the phenotypic diversity of membrane glycophorins.

Molecular genetics of glycophorin MNS variants.

The antigens for the MNS blood group system are Glycophorins A and B (GPA,GPB), products of the GPA gene family. The existence of close to 40 variant phenotypes of this blood group system has been documented by serological analyses. Here is summarized the molecular basis for a large number of variants, including all the variants of the Miltenberger complex and several isoforms of Sta; also, Dantu, Sat, He, Mg, and deletion variants Ena, S-s-U- and Mk. The diversity is based predominantly on gene recombinations, namely unequal homologous recombinations and/or gene conversions, often coupled to pre-mRNA splicing. Most rearrangements occurred between GPA and GPB alleles, and were confined to hot-spots within the 4 kb region coding for the extracellular domain. The homologous region in GPE, the third member of the gene family, was involved only rarely. Sites of the variant epitopes are mapped to new intra- and inter-exon junctions or to patches of previously silenced sequences that become expressed following recombination.

The glycophorin A gene family in gorillas: structure, expression, and comparison with the human and chimpanzee homologues.

Homologues of MN blood group antigens, encoded by members of the glycophorin A (GPA) gene family, are expressed in man, anthropoid apes, and some species of Old World monkeys. Previous studies had shown that a three-gene framework, most closely related to that in man, is present in the chimpanzee. Here we report the genomic structure, transcript map, and protein expression of the GYPA locus in gorillas. Compared to the corresponding human and chimpanzee homologues, gorilla GPA, GPB, and GPB/E genes each showed a high degree of sequence identity, with the same exon-intron organization. However, the expression of exons III, IV or V encoding the extracellular or membrane domains of homologous glycophorins varied among the three species. Gorilla GPA and GPB/E genes were unique in that the former occurred in two allelic forms with or without the expression of exon III, whereas the latter contained one (psi exon III) instead of two silenced exons (psi exons III and IV). Differences from human but not chimpanzee GPA also included the presence of a hybrid M/N epitope and the absence of the sequon for N-glycosylation. Owing to the retention of a functional exon III, gorilla GPB was more similar to chimpanzee GPB than human GPB. A transspecies allele was identified in the gorilla that gave rise to the Henshaw (He)-like antigen similar to that found in man. These results provide further insight into the model for evolution of the GPA gene family, indicating that the mechanisms underlying inter- and intraspecific polymorphism of glycophorins could predate the divergence of gorillas as the consequence of gene duplication and diversification.

Expression and quantitative variation of the low-incidence blood group antigen He on some S-s-red cells.

BACKGROUND: Red cells devoid of glycophorin B (GPB)-borne S, s, and U antigens are classified as an S-s-U- or S-s-U variant (U+var) and can arise from deletion and nondeletion genetic backgrounds. In nondeletion forms of S-s-U-, little information is available on whether the altered GPB gene (GYPB) is expressed in red cells. STUDY DESIGN AND METHODS: Red cells classified as S-s-U- or S-s-U+var were tested with anti-U, anti-U/GPB, anti-He, and anti-N by hemagglutination. Selected samples were tested by flow cytometry, immunoblotting, and polymerase chain reaction amplification using allele-specific primers. RESULTS: He (MNS6) was found on 23 percent (20/87) of samples. These and another 21 of the 87 samples were agglutinated by an anti-U/GPB reagent; this indicated that approximately 50 percent of S-s-samples possessed GPB variants. The strength of He varied among the samples. Genomic polymerase chain reaction with allele-specific primers showed the presence of expected DNA GPB-like products encoding He. Immunoblotting showed that He was carried on a membrane component with a relative molecular mass indistinguishable from that of GPB. CONCLUSION: The finding of He on S-s- red cells provides direct evidence for the presence of an altered form of GPB in red cells previously thought to be devoid of this glycophorin. Quantitative variation in He antigen expression was observed in a subset of S-s- red cells.

Human red blood cell Wright antigens: a genetic and evolutionary perspective on glycophorin A-band 3 interaction.

The Wright (Wra/Wrb) blood group polymorphism is defined by an allelic change (Lys658Glu) in the band 3 protein; nevertheless, the Wrb antigen apparently requires glycophorin A (GPA) for surface presentation. To gain insight into the structural basis for this protein-protein interaction and delineate its relationship with Wrb antigen expression, we investigated GPA and band 3 sequence polymorphisms occurring in rare humans and nonhuman primates. The lack of GPA or amino acid residues 59 through 71 of GPA results in the absence of Wrb from human red blood cells (RBCs) exhibiting the MkMk, En(a-), or MiV phenotype. However, the SAT homozygous cells carried a Glu658 form of band 3 and a hybrid glycophorin with the entire GPA extramembrane domain from residues 1 through 71, yet expressed no Wrb antigen. This finding suggests that formation of the Wrb antigenic structure is dependent on protein folding and that the transmembrane junction of GPA is important in maintaining the required conformation. Comparative analyses of GPA and band 3 homologues led to the identification in the interacting regions of conserved and dispensable amino acid residues that correlated with the Wrb positive or negative status on nonhuman primates. In particular, the chimpanzee RBCs cells expressed Wrb and the Glu658 form of band 3, which is identical to humans, but their GPA contained the Gly rather than Arg residue at position 61. Taken together, the results suggest that (1) Arg61 of GPA and the proposed Arg61-Glu658 charge pair are not crucial for Wrb antigen exhibition and (2) the role of GPA for interaction with band 3, including Glu658, probably involves a number of amino acid residues located in the alpha-helical region and transmembrane junction.

Sequence diversification and exon inactivation in the glycophorin A gene family from chimpanzee to human.

In humans, the allelic diversity of MNSs glycophorins (GP) occurs mainly through the recombinational modulation of silent exons (pseudoexons) in duplicated genes. To address the origin of such a mechanism, structures of GPA, GPB, and GPE were determined in chimpanzee, the only higher primate known to have achieved a three-gene framework as in humans. Pairwise comparison of the chimpanzee and human genes revealed a high degree of sequence identity and similar exon-intron organization. However, the chimpanzee GPA gene lacks a completely formed M- or N-defining sequence as well as a consensus sequence for the Asn-linked glycosylation. In the case of the GPB gene, exon III is expressed in the chimpanzee but silenced, as a pseudoexon, in the human. Therefore, the protein product in the chimpanzee bears a larger extracellular domain than in the human. For the GPE genes, exon III and exon IV have been inactivated by identical donor splice-site mutations in the two species. Nevertheless, the chimpanzee GPE-like mRNA appeared to be transcribed from a GPB/E composite gene containing no 24-bp insertion sequence in exon V for the transmembrane domain. These results suggest a divergent processing of exonic units from chimpanzee to human in which the inactivation of GPB exon III preserved a limited sequence repertoire for diversification of human glycophorins.

Glycophorin SAT of the human erythrocyte membrane is specified by a hybrid gene reciprocal to glycophorin Dantu gene.

Previous studies of two unrelated Japanese families showed that two isoforms of glycophorin were associated with the expression of SAT antigen on the erythrocyte membrane. Here we report the molecular basis for one form of this MNSs-related surface marker that displayed an altered immunoblotting pattern. Evidence is presented that glycophorin SAT (GPSAT) is encoded by a hybrid gene resulting from unequal homologous recombination between GPA and GPB genes. Analysis of SAT genomic DNAs by Southern blots showed gross alterations in the glycophorin gene cluster. Those restriction fragments characteristic of the GPA 3' and GPB 5' ends were absent from the SAT homozygote and showed reduced intensity in SAT heterozygotes. Reticulocyte RNA polymerase chain reaction showed the presence in the SAT homozygote of GPSAT and GPE transcripts but no GPA and GPB transcripts. Direct sequencing of the amplified SAT cDNA showed that its sequence from exon I to exon IV was identical with the N allele of GPA, whereas its 3' portion, including exon V and exon VI, was derived from the GPB gene. The GPSAT protein in its mature form should contain 104 amino acid residues and bear a novel sequence, Ser-Glu-Pro-Ala-Pro-Val, encoded by the junction of GPA exon IV and GPB exon V. This sequence interfaces the extracellular and transmembrane domains and could be the epitope site of the SAT antigen. The formation of such a hybrid junction not only explains why SAT homozygous erythrocytes lack S, s, and U antigens but also shows a reciprocal arrangement with respect to the B-A hybrid GPDantu gene.

Molecular genetics of the glycophorin gene family, the antigens for MNSs blood groups: multiple gene rearrangements and modulation of splice site usage result in extensive diversification.

The purpose of the review is to describe a system of human erythrocyte membrane glycoproteins exhibiting extensive diversity. Glycophorins A and B (GPA and GPB) are the antigens of the MNSs blood groups; thus individuals bearing variant glycophorins can be readily identified by serological typing. Examination of the wide array of variants of these antigens showed that they include many forms, possibly made evident by lack of constraints due to the apparent dispensability of the parent molecules. This article reviews the molecular genetics of 25 variants of the glycophorin gene family, whose common denominator is that they arise from unequal gene recombinations or gene conversions coupled to splice-site mutations. Most rearrangements occurred within a 2-kb region mainly within GPA and GPB of the gene family and only rarely within the third member, GPE. The key feature is the shuffling of sequences within two specific exons (one of which is silent), homologous in the two parent genes. This has resulted in expression of a mosaic of sequences within this region, leading to polymorphism. The common pattern of recombinations coupled to pre-mRNA splicing was the predominant mechanism of the origin of glycophorin diversity. Thus far this mechanism appears to be unique among human gene families. It could have occurred by chance rearrangements among closely linked genes and been driven by a biological advantage, not as yet identified. This remains to be established. Nevertheless, gene rearrangements observed here are akin to those reported for the major histocompatibility complex (MHC). In the glycophorin family the small size of the region within which gene interactions have occurred and the participation of essentially only two alleles makes this relatively simpler system more focused and easier to dissect and describe molecularly.

Glycophorin He(Sta) of the human red blood cell membrane is encoded by a complex hybrid gene resulting from two recombinational events.

A complex glycophorin (GP) variant of the human red blood cell membrane exhibiting both He and Sta antigens was characterized at the molecular level. Restriction mapping identified two novel Msp I fragments derived from the 5' and 3' portions of the GPHe(Sta) gene, respectively. Genomic DNA, including exons II-V and their splice junctions, was amplified by polymerase chain reaction, and the nucleotide sequences were determined. Comparison with the GPA and GPB sequences showed the presence in GPHe(Sta) of multiple recombinational breakpoints. In the 5' region of the variant gene, a sequence covering a portion of exon II to intron 2 had been transferred from GPA to GPB, resulting in a B-A-B hybrid structure. Such a gene conversion-like event introduced a number of templated and untemplated nucleotide replacements and was the direct cause for the expression of the He antigen. In the 3' region of the variant gene, an unequal crossover from GPB to GPA took place in the third intron at a recombination site apparently identical to that observed in the B-A hybrid GPSta type A gene. These results indicated that GPHe(Sta) occurs as a B-A-B-A hybrid gene, most likely originating from a two-step mechanism of homologous recombination. Transcript analysis showed the maturation from the GPHe(Sta) pre-mRNA of two shortened mRNAs of which the exon III-deleted species encodes both the He and Sta antigens.

Remodeling of the transmembrane segment in human glycophorin by aberrant RNA splicing.

This paper describes the identification in S-s-U-erythrocytes of a novel glycophorin (GP), He(P2), with structural variations in both its extracellular and transmembrane domains. In the exon II-intron 2 region, a sequence transfer from GPA to GPB, probably via the mechanism of gene conversion, was associated with the induction of multiple untemplated nucleotide replacements. These changes defined the sequence for the He epitope while concomitantly abolishing GPB-associated N antigenicity. Moreover, the GPHe(P2) gene carries two splice site mutations that coordinately affect the processing of exon V coding for the transmembrane segment. The C-->G transversion at the 3' end of exon V created a cryptic acceptor splice site, whereas the G-->T transversion at the +5 position of intron 5 altered the consensus of the donor splice site. Transcript sequencing revealed that neither site was utilized in the splicing of GPHe(P2) pre-mRNA. Rather, complete skipping of exon V and subsequent joining of exon IV to exon VI caused a shift in the open reading frame, which remodeled GPHe(P2) with an elongated new hydrophobic sequence for membrane anchoring. As a result, GPHe(P2) does not display the S and U epitopes although it still contains an intact linear sequence for the two antigens. These findings illustrate how exon and intron sequences concertedly determine the specificity of in vivo splice site selection. In addition, they pinpoint the conformational dependence of the S, s, and U antigens and the importance of the hinge region for their presentation.

Alteration of splice site selection by an exon mutation in the human glycophorin A gene.

We report the identification in human glycophorin A gene of a novel exon mutation that affects splice site selection. DNA mapping showed that the mutation has abolished a unique MspI site marking the exon III-intron 3 splice junction (ACCG/GT). Genomic sequencing confirmed the occurrence of a single G-->A transition at the terminal nucleotide position of exon III. Analysis of the mRNA composition demonstrated a partial inactivation of the altered 5' splice site as well as skipping of exons involving the alternative use of other constitutive splice sites. The full-length transcript with the cognate A change encodes a variant glycophorin with an arginine replacing a glycine at position 59 and defining the ERIK epitope, whereas the exon III-deleted transcript specifies a shorter glycophorin carrying the Sta antigen. Also identified were the misspliced mRNA species with exon I-IV and exon I-V connections generated by selection of 5' splice sites far distant from the mutated site. Although having a correct translation frame, the predicted polypeptides of such exon-skipping products were not assembled on the erythrocyte membrane probably due to the severe truncation of the signal sequence required for targeting and translocation. These observations reveal a new mechanism for antigenic diversity of human glycophorins.

An anti-EnaTS detected in the serum of an MiI homozygote.

The serum of EH reacted with all red cells (RBCs) except her own, ficin- or trypsin-treated red cells, and En(a-) red cells. This reactivity defined an anti-EnaTS specificity. The red cells of the proposita typed as M-N+S-S+, Vw+Mur-Hil-Hut-Anek-Lane-, Wr(a-b+), EnaKT+. Red cells of five relatives were Vw+ and positive with her serum. Titration studies suggest that EH is genetically an MiI homozygote and that her Vw+ relatives are MiI heterozygotes. There is no history of consanguinity. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and immunoblotting studies have agreed with the serologic observations. A variant sialoglycoprotein of faster mobility than normal glycoprotein A, but no normal glycoprotein A, was detected on her red cells. Treatment with N-glycanase did not alter the mobility, which indicated that there was no N-glycosylation of residue 26. These findings are in agreement with the reported properties of the Mi.I-specific glycoprotein A. The relatives' Vw+ red cells showed the variant sialoglycoprotein and normal glycoprotein A. EH appears to be the first reported MiI homozygote.

Involvement of membrane glycophorins in human erythrocytes invaded by Plasmodium falciparum.

The extent of participation and changes of glycophorins (GPs) and membrane proteins in the merozite-human erythrocyte interaction during the invasion of Plasmodium falciparum (Pf) were studied by immunoblotting techniques. Polyclonal antisera to alpha GP and to its C-terminal fragment (residues 82-131) as well as M and N specific monoclonal antibodies (MoAbs) were used. We examined the GPs in the parasite-free saponin lysates, saponin pellets and the culture supernatants of the infected erythrocytes in comparison with the mock cultured normal RBC. Excepting the usual GP patterns, a GP with molecular weight of 77.5 K (band 1') existed in the parasitized erythrocytes and their saponin pellets and several GP bands ranging from 28K to 54K were present in saponin pellets when probed with anti-GP and anti-peptide C sera. This reflected the disintegration of erythrocyte membrane alpha GP through the invasion of Pf. The alpha 2 GP in the saponin pellets of the parasitized MM erythrocytes surprisingly cross-reacted with the N MoAb, implying that it may have come from the intermingling of the host alpha GP in MM erythrocytes with the parasite alpha GP reacting to N MoAb. The saponin pellets of parasitized erythrocytes preserved a considerable amount of ankyrin, band 3, protein 4.1 and 4.2, while the GP bands were densely mixed with the parasite proteins and the disintegrated products of membrane proteins. Four erythrocyte-binding antigens (EBA) of 143 K, 135 K, 115 K and 107 K recognized by malaria hyperimmune serum were detected in the culture supernatants of Pf, some of them appeared in the infected erythrocytes, their saponin lysates and pellets.

Exon skipping caused by DNA recombination that introduces a defective donor splice site into the human glycophorin A gene.

We report here the pre-mRNA splicing of the human glycophorin Mz (HGpMz) gene altered by a defective donor splice site introduced into the third intron via the mechanism of gene conversion. We found that the directional transfer from HGpB(delta) to HGpA(alpha) of a 145-base pair silent homologous segment had resulted in HGpMz as an alpha-beta-alpha hybrid gene with a G-T transversion in the consensus GT motif of the 5'-donor splice site. Transcript analysis showed the presence in the Mz reticulocytes of three major glycophorin cDNA species of which two occurred as the shortened and aberrantly spliced products of HGpMz pre-mRNA lacking the sequences encoded by one and two exons, respectively. The skipping of exon III results in one HGpMz protein with 99 amino acids that bears the M and Sta blood group antigens, whereas the coincident skipping of both exon III and exon IV leads to the expression of a minor HGpMz protein with 86 amino acids. These results indicate that the translocated defective donor splice site not only causes uniform skipping of the upstream exon but also affects the processing of the downstream exon. Complementing our previous studies, the finding that the active and inactive splice sites can be transposed by DNA recombination and alternatively used to construct new glycophorin alleles reveals a novel mechanism for sequence diversification in human genes.

Molecular analysis of human glycophorin MiIX gene shows a silent segment transfer and untemplated mutation resulting from gene conversion via sequence repeats.

The human glycophorin (HGp) loci that define the red blood cell surface antigens of the MNSs blood group system exhibit considerable allelic variation. Previous studies have identified gene conversion events involving HGpA(alpha) and HGpB(delta) that produced delta-alpha-delta hybrid genes which differ in the location of breakpoints. This report presents the molecular analysis of HGpMilX, the first example of a reverse alpha-delta-alpha hybrid gene that specifies a newly described phenotype of the Miltenberger complex. A novel restriction fragment unique to the HGpMilX gene was detected by Southern blot hybridization. The structure of the genomic region encoding the entire extracellular domain of the MilX protein was determined. Nucleotide sequencing of amplified genomic DNA showed that a silent segment of the HGpB(delta) gene had been transposed to replace the internal part of exon III in the HGpA(alpha) gene, thereby resulting in the formation of the MilX allele with an alpha-delta-alpha configuration. The proximal alpha-delta breakpoint was found to be flanked by a direct repeat of the acceptor splice site, whereas the distal delta-alpha breakpoint was localized to a palindromic region. This DNA rearrangement, with a minimal transfer of 16 templated nucleotides and a single mutation of untemplated adenyl nucleotide, not only created two intraexon hybrid junctions but transactivated the expression of a new stretch of amino acid residues in the MilX protein. Such a segment replacement may have occurred through the directional transfer from one duplex to the other via the mechanism of gene conversion. The occurrence of HGpMilX as another hybrid derived from parts of parent genes underlines the role of the recombinational "hotspot" in the generation of allelic diversity in the glycophorin family.

O-linked oligosaccharides of glycophorins A and B in erythrocytes of two individuals with the Tn polyagglutinability syndrome.

Tn polyagglutinability syndrome is an acquired condition where erythrocytes express Tn neo-antigen and become susceptible to hemagglutination by the naturally occurring anti-Tn present in normal sera. Early studies had indicated that O-linked N-acetyl galactosamine was the sole serologic Tn determinant, but more recently O-linked NeuNAc alpha 2, 6GalNAc also has been implicated as a Tn antigen (sialosyl-Tn). However, none of these studies were performed on purified glycoproteins. In this report we examine oligosaccharides of glycophorins A and B purified from Tn erythrocytes of two affected individuals to establish how N- and O-linked saccharides differ from normal. Analysis of carbohydrate composition and treatment with N-glycanase showed that the Asn-linked unit of glycophorin A was not affected. O-linked oligosaccharides were obtained by beta-elimination in the presence of tritiated sodium borohydride. The reduced radiolabeled products were fractionated by Bio-Gel P-2 chromatography, and their structures were investigated by comparison with standards, by monosaccharide quantification, and by neuraminidases of known specificities. The results show that Tn glycophorins from both donors contain intact and truncated forms of trisaccharide and tetrasaccharide NeuNAc alpha 2,3Gal beta 1,3GalNAc and NeuNAc alpha 2,3Gal beta 1,3- (NeuNAc alpha 2,6)GalNAc usually present in glycophorins A and B. The truncated forms include the protein O-linked monosaccharide, GalNAc and disaccharide, NeuNAc alpha 2,6GalNAc (major isomer). The presence of intact glycans in the total population of Tn erythrocytes was confirmed by their susceptibility to T activation after treatment with neuraminidase. The proportion of the four species was not identical in glycophorins of these two donors but, in both, the truncated units predominated and the amount of the disaccharide was approximately one half of that of the monosaccharide. The data are consistent with alterations in UDPGal:GalNAc beta 1,3galactosyl transferase that may have multiple molecular origins and with induction of a specific GalNAc protein alpha 2,6 sialosyl transferase in Tn hematopoietic precursor cells. The molecular basis for these alterations awaits further study.

Elliptocytosis associated with an abnormal alpha glycophorin.

A case of elliptocytosis associated with an undescribed abnormal alpha glycophorin (alpha GP) is reported. Using immunoblotting techniques, a clear-cut minor band 6' was detected emerging just behind the monomer of delta GP (band 6) when probed with anti-alpha GP antiserum. It also reacted with anti-peptide C antiserum, suggesting that this new band with a molecular weight of 24 K is related to the structural alteration of alpha GP and not delta GP. The erythrocyte membrane proteins of the patient exhibited a quite normal pattern, with a normal alpha spectrin/beta spectrin ratio, but the reaction with anti-protein 4.1 serum confirmed the increase in proteolytic susceptibility of her protein 4.1. The results of DNA mapping implied that the abnormality may be due to a short deletion of the heterozygote. The significance of deviation involving the alpha GP and protein 4.1 to the elliptocytic change of erythrocyte shape is briefly discussed.