Molecular basis of spectrin deficiency in hereditary pyropoikilocytosis

Hereditary pyropoikilocytosis (HPP) is a recessively inherited hemolytic anemia characterized by severe poikilocytosis and red blood cell fragmentation. HPP red blood cells are partially deficient in spectrin and contain a mutant alpha or beta-spectrin that is defective in terms of spectrin self-association. Although the nature of the latter defect has been studied in considerable detail and many mutations of alpha-spectrin and beta spectrin have been identified, the molecular basis of spectrin deficiency is unknown. Here we report two mechanisms underlying spectrin deficiency in HPP. The first mechanism involves a thalassemia-like defect characterized by a reduced synthesis of alpha-spectrin as shown by studies involving synthesis of spectrin in two unrelated HPP probands and their parents: One parent carries the elliptocytogenic spectrin mutation, whereas the other parent is fully asymptomatic. Peripheral blood mononuclear cells as a source of erythroid burst-forming unit (BFUe) were cultured in a two-phase liquid culture system that gives rise to terminally differentiated erythroblasts. Pulse-labeling studies of an equal number of erythroblasts or morphologically identical maturity showed that the synthesis of alpha-spectrin as well as the mRNA levels as measured by the competitive polymerase chain reaction (PCR) method are markedly reduced in the presumed asymptomatic carriers and the HPP probands. In contrast, the synthesis and mRNA levels of beta-spectrin were normal. These results constitute a direct demonstration of an alpha-spectrin synthetic defect in a subset of asymptomatic carriers of HPP and HPP probands. The second mechanism underlying spectrin deficiency involves increased degradation of mutant spectrin before its assembly on the membrane. This is evidenced by pulse labeling studies of erythroblasts from a patient with HPP associated with a homozygous state for spectrin alpha I/46 mutation (leu-pro mutation at AA 207 of alpha-spectrin). These studies showed that although spectrin is synthesized in the cytosol in normal amounts, the rate of turnover of alpha-spectrin is faster resulting in about 40% to 50% reduced assembly of alpha-spectrin and beta-spectrin on the membrane. Thus, spectrin deficiency in this case is at least in part caused by increased susceptibility of the mutant spectrin to degradation before its assembly on the membrane. We conclude that at least two separate mechanisms underlie the molecular basis of spectrin deficiency in HPP.     

Hereditary poikilocytic anemia associated with the co-inheritance of two alpha spectrin abnormalities

This report describes a black family in which two distinct structural defects of alpha spectrin were inherited singly and in combination. The propositus, who has a poikilocytic hemolytic anemia that shares many of the features of hereditary pyropoikilocytosis (HPP) or homozygous elliptocytosis, is a compound heterozygote for both the spectrin alpha 1/65 and spectrin alpha 1/50a defects as demonstrated by electrophoretic analysis of spectrin tryptic fragments. The spectrin alpha 1/65 defect alone was found in his mother and sibling, while the spectrin alpha 1/50a defect was present in the father and another sibling. The red cell spectrin content was normal in all family members. The functional consequences of inheritance of these two spectrin defects were compared with those found in an unrelated patient with classic HPP who had the alpha 1/50a spectrin defect and was spectrin deficient as well. Prolonged incubation at 37 degrees C resulted in striking budding, fragmentation, and sphering of classic HPP red cells but only minimal changes in propositus cells. The percentage of spectrin dimers was increased tenfold in classic HPP, sevenfold in the propositus, and threefold in other family members. Mechanical stability of erythrocyte ghosts, measured by ektacytometry, was reduced severely in both classic HPP and in the propositus, but only moderately in other family members. Thus, co-inheritance of two alpha spectrin defects can result in a poikilocytic hemolytic anemia milder than that usually found in HPP. The greater clinical severity of HPP may be a consequence of the presence of spectrin deficiency, a finding absent in the propositus.     

Alteration of the erythrocyte membrane skeletal ultrastructure in hereditary spherocytosis, hereditary elliptocytosis, and pyropoikilocytosis

The membrane skeleton of normal erythrocytes is largely organized into a hexagonal lattice of junctional complexes (JC) crosslinked by spectrin tetramers, and occasional double tetramers and hexamers. To explore possible skeletal alterations in hereditary spherocytosis (HS), elliptocytosis (HE), and pyropoikilocytosis (HPP), we have studied the ultrastructure of the spread membrane skeletons from a subpopulation of HS patients with a partial spectrin deficiency ranging from 43% to 86% of normal levels, and in patients with HPP who, in addition to a mild spectrin deficiency, also carried a mutant spectrin that was dysfunctional, thus reducing the ability of spectrin dimers to assemble into tetramers. Membrane skeletons derived from Triton-treated erythrocyte ghosts were examined by negative staining electron microscopy. HS membrane skeletons contained structural elements, consisting of JC and spectrin filaments similar to the normal skeleton. However, less spectrin filaments interconnected the JC, and the decrease of spectrin filaments attached to JC appeared to correlate with the severity of spectrin deficiency. Only in severe HS associated with severe spectrin deficiency was the loss of spectrin sufficient enough to disrupt the overall skeletal architecture. In contrast, membrane skeletons prepared from red blood cells (RBCs) of subjects with HPP were strikingly different from HS RBCs with a comparable degree of spectrin deficiency. Although HPP RBCs were only mildly deficient in spectrin, their skeletal lattice was grossly disrupted, in contrast to only mild ultrastructural abnormalities of HS membrane skeletons with a nearly identical degree of spectrin deficiency. Skeletons from patients with common mild HE or asymptomatic carriers, carrying the mutant spectrin but having normal spectrin content, exhibited a moderate disruption of the skeletal lattice. We propose that the above differences in skeletal ultrastructure may underlie differences in the biomechanical properties and morphology of HS, HE, and HPP RBCs.     

Structural and functional heterogeneity of alpha spectrin mutations involving the spectrin heterodimer self-association site: relationships to hematologic expression of homozygous hereditary elliptocytosis and hereditary pyropoikilocytosis

Defects involving alpha spectrin (Sp) are found in patients with hereditary elliptocytosis and a related disorder, hereditary pyropoikilocytosis (HPP). We have previously found that the severity of hemolysis was related to the total spectrin content of the cells and the percentage of unassembled dimeric Sp (SpD) in the membranes, which, in turn, reflected the amount of mutant Sp in the cell. However, no data are available comparing differences in the function of various alpha Sp mutations to clinical severity. We now report studies of nine homozygotes or double heterozygotes for four alpha Sp mutations: alpha 1/74, alpha 1/46, alpha 1/65, and alpha 1/61, whose red blood cells (RBCs) contained only the mutant Sp and no normal Sp. Sp alpha 1/74, Sp alpha 1/46, and alpha 1/65 homozygotes differed strikingly in the severity of hemolysis that correlated with the severity of mutant Sp dysfunction, as reflected by the fraction of unassembled SpD in the membranes and the self-association of mutant Sp on inside-out vesicles. Homozygotes for Sp alpha 1/74 had a very severe hemolytic anemia and their SpD were virtually incapable of self-association, whereas SpD alpha 1/46 were not as severely affected. The Sp alpha 1/65 homozygotes had a relatively mild hemolytic anemia and their SpD showed the least impairment of function. Ultrastructural examination of membrane skeletons from subjects whose SpD self-association was severely impaired showed gross skeletal disruption and loss of hexagonal structure. In striking contrast, the homozygote for the mildly dysfunctional Sp alpha 1/65 had only a moderate disruption of the skeleton. Some of the homozygous or doubly heterozygous subjects also exhibited a partial deficiency of Sp that correlated with a RBC morphology characteristic of HPP, namely, marked microspherocytosis with virtual absence of elliptocytes. These data demonstrate striking differences in the function and structure of various alpha Sp mutants that underlie differences in clinical expression.     

Poikilocytic hereditary elliptocytosis associated with spectrin Alexandria: an alpha I/50b Kd variant that is caused by a single amino acid deletion

Hereditary elliptocytosis (HE) is a heterogeneous disorder of red blood cells frequently associated with abnormal limited tryptic digestion of the alpha I domain of spectrin and impaired spectrin dimer self- association. We studied two related individuals with poikilocytic hereditary elliptocytosis (HE) of different severity. Limited tryptic digestion of spectrin from these individuals showed the presence of a variant alpha I/50b Kd peptide at the expense of the normal alpha I/80 Kd peptide. Amino acid sequence analysis of the abnormal peptide showed that the proteolytic cleavage occurred after the arginine at position 470 of the alpha spectrin chain. Spectrin from these patients had an impaired ability to undergo self-association, as evidenced by increased amounts of spectrin dimers in 4 degrees C extracts of erythrocyte membrane from affected individuals. The polymerase chain reaction was used to study the DNA sequence of the alpha spectrin gene encoding the region of the alpha spectrin chain surrounding the abnormal proteolytic cleavage site. We detected the in-frame deletion of the trinucleotide CAT, encoding histidine 469, two amino acid residues to the N-terminal side of the abnormal proteolytic cleavage site between residues 470 and 471. Similar to many other defects of spectrin associated with HE, this deletion occurs in helix three of repeat 5 of the proposed triple helical model of spectrin repeats.     

Hereditary elliptocytosis, spherocytosis and related disorders: consequences of a deficiency or a mutation of membrane skeletal proteins

The membrane skeleton, a protein lattice that laminates the internal side of the red cell membrane, contains four major proteins: spectrin, actin, protein 4.1 and ankyrin. By mass, the most abundant of these proteins is spectrin, a fibre-like protein composed of two chains, alpha and beta, which are twisted along each other into a heterodimer. At their head region, spectrin heterodimers are assembled into tetramers. At their distal end, these tetramers are interconnected into a two dimensional network by their linkage to oligomers of actin. This interaction is greatly strengthened by protein 4.1. The skeleton is attached to the membrane by ankyrin, a protein that connects the spectrin beta chain to the major transmembrane protein band 3, the anion channel protein. Additional attachment sites are those of protein 4.1 with several glycoproteins, namely glycophorin A and C, as well as direct interactions between spectrin, protein 4.1 and the negatively charged lipids of the inner membrane lipid bilayer. Hereditary spherocytosis, elliptocytosis and pyropoikilocytosis represent a group of disorders that are due to deficiency or dysfunction of one of the membrane skeletal proteins (Fig. 1). Known deficiency states include that of spectrin, ankyrin and protein 4.1. Severe spectrin and ankyrin deficiencies (with decrease in spectrin and ankyrin contents to about 50% of the normal amount) are both rare disorders associated with severe autosomal recessive hereditary spherocytosis. On the other hand, mild spectrin deficiency is found in the majority of patients with autosomal dominant spherocytosis in which the degree of spectrin deficiency correlates with the clinical severity of the disease. Protein 4.1 deficiency, in contrast, is associated with hereditary elliptocytosis, which in certain populations constitutes about 20% of all such patients. Known skeletal protein dysfunctions include mutants of both alpha and beta spectrin that involve the spectrin heterodimer self-association site. These are clinically expressed as hereditary elliptocytosis (HE) and a closely related disorder, hereditary pyropoikilocytosis (HPP). At the level of protein function, this defect can be detected by analysis of the content of spectrin dimers and tetramers in 0 degrees C low ionic strength extracts of red cell membranes. Their structural identification is accomplished by limited proteolytic digestion of spectrin followed by two-dimensional tryptic peptide mapping.(ABSTRACT TRUNCATED AT 400 WORDS)     

Spectrin-alpha I/61: a new structural variant of alpha-spectrin in a double-heterozygous form of hereditary pyropoikilocytosis

Recent biochemical studies have led to the identification of abnormal spectrins in the erythrocytes of patients with hereditary pyropoikilocytosis (HPP) and hereditary elliptocytosis (HE). In this report we describe the biochemical characterization of the erythrocytes from a proband with severe HPP who is doubly heterozygous for two mutant spectrins (Sp): Sp alpha I/74 and a new, previously undetected, mutant of alpha-spectrin designated Sp alpha I/61. The proband's erythrocytes are unstable when exposed to 45 degrees C, and her membrane skeletons exhibit instability to shear stress. The content of spectrin in the proband's erythrocyte membranes is decreased to 75% of control values. The amount of spectrin dimers in crude 4 degrees C spectrin extracts is increased (58%) as compared with control values (6% +/- 4%). Limited tryptic digestion reveals a marked decrease in the normal 80,000-dalton alpha I domain, an increase in the 74,000-dalton fragment that is characteristic of Sp alpha I/74, and an increase in a series of new fragments of 61,000, 55,000, 21,000, and 16,000 daltons. Both parents are asymptomatic, but they have increased amounts of spectrin dimers (17% to 25%). Limited tryptic digestion of the father's spectrin demonstrates the presence of a previously identified abnormal spectrin (Sp alpha I/74) that is characterized by a decrease in content of the 80,000-dalton peptide and an increase in concentration of the 74,000-dalton peptide. The mother's spectrin digests show a decrease in the amount of 80,000-dalton peptide and the formation of new peptides of 61,000, 55,000, 21,000, and 16,000 daltons. The data indicate that this severe form of HPP is due to the inheritance of two distinct abnormal spectrins, Sp alpha I/74 and a new spectrin mutant, Sp alpha I/61.     

Abnormal spectrin in hereditary elliptocytosis

An abnormal alpha subunit of erythrocyte spectrin has been described in hereditary pyropoikilocytosis (HPP), a rare hemolytic anemia characterized by erythrocyte budding and fragmentation. In HPP spectrin, the N terminal domain of the alpha subunit (alpha I T80) shows increased susceptibility to tryptic digestion, resulting in cleavage to a 50,000-d peptide, presumably due to a change in primary structure of the alpha I domain which alters conformation and generates the new cleavage site. The functional result of this conformational alteration is marked impairment of spectrin oligomer formation in vitro, consistent with the established role of alpha I T80 in spectrin self-association. In the present study, we demonstrate an abnormal spectrin alpha subunit in two kindreds with hereditary elliptocytosis (HE) that is qualitatively identical to HPP spectrin. Clinical expression of HE in these families ranges from mild elliptocytosis without hemolysis to severe poikilocytic hemolytic anemia clinically resembling HPP. In all affected individuals, a fraction of alpha I T80 is abnormal, as shown by its cleavage during mild tryptic digestion to the 50 kd peptide described in HPP; the fraction of alpha I T80 affected is directly proportional to the severity of clinical expression of HE. Spectrin oligomer formation is likewise impaired to a degree which correlates with hematologic disease. One of the HE kindreds studied demonstrated polymorphism in the spectrin alpha II domain, previously described as a frequent occurrence in blacks. This family also demonstrates a variant alpha III domain in spectrin that has not previously been described. We conclude that the abnormality in the alpha I domain originally described in HPP spectrin is shared by a subset of patients with HE; the severity of clinical expression, ranging from mild nonhemolytic HE to poikilocytic hemolytic anemia, is related to the fractional quantity of the alpha subunit that is affected.     

Tissue-specific alternative splicing of protein 4.1 inserts an exon necessary for formation of the ternary complex with erythrocyte spectrin and F-actin

Erythrocyte protein 4.1 is an 78- to 80-Kd peripheral membrane protein that promotes the interaction of spectrin with actin protofilaments and links the resulting interlocking network to the integral membrane proteins. There are several isoforms of protein 4.1 that appear to be expressed in a restricted group of tissues. These arise from alternative mRNA splicing events that lead to the combinational insertion or deletion of at least 10 blocks of nucleotides (motifs) within the mature mRNA. One of these, motif I, consists of 63 nucleotides encoding 21 amino acids in the N-terminal region of the putative spectrin/actin-binding domain. The expression of the motif U- containing isoform occurs late in erythroid maturation. We generated recombinant isoforms of protein 4.1 and of the putative 10-Kd spectrin/actin-binding fragment that contain or lack this 21 amino acid sequence and examined their ability to form a ternary complex with erythrocyte spectrin and F-actin. The isoforms of the complete protein and of the 10-Kd fragment that contain the sequence encoded by motif I efficiently form the ternary complex. Isoforms that lack this sequence, but are otherwise identical, do not participate in the formation of the ternary complex. These results, in conjunction with the expression of motif I during late erythroid maturation, suggest that interaction with actin and the erythroid form of spectrin is a specialized property of the erythrocyte form of protein 4.1. Alternative mRNA splicing in developing red blood cells thus plays a key adaptive role in the formation of the highly specialized erythrocyte membrane.     

Red blood cell membrane disorders

The recent discovery of the specific molecular defects in many patients with hereditary spherocytosis and hereditary elliptocytosis/pyropoikilocytosis partially clarifies the molecular pathology of these diseases. HE and HPP are caused by defects in the horizontal interactions that hold the membrane skeleton together, particularly the critical spectrin self-association reaction. Single gene defects cause red cells to elongate as they circulate, by a unknown mechanism, and are clinically harmless. The combination of two defective genes or one severe alpha spectrin defect and a thalassaemia-like defect in the opposite allele (alphaLELY) results in fragile cells that fragment into bizarre shapes in the circulation, with haemolysis and sometimes life-threatening anaemia. A few of the alpha spectrin defects are common, suggesting they provide an advantage against malaria or some other threat. HS, in contrast, is nearly always caused by family-specific private mutations. These involve the five proteins that link the membrane skeleton to the overlying lipid bilayer: alpha and beta spectrin, ankyrin, band 3 and protein 4.2. Somehow, perhaps through loss of the anchorage band 3 provides its lipid neighbours (Peters et al, 1996), microvesiculation of the membrane surface ensues, leading to spherocytosis, splenic sequestration and haemolysis. Future research will need to focus on how each type of defect causes its associated disease, how the spleen aggravates membrane skeleton defects (a process termed 'conditioning'), how defective red, cells are recognized and removed in the spleen, and why patients with similar or even identical defects can have different clinical severity. Emphasis also needs to be given to improving diagnostic tests, particularly for HS, and exploring new options for therapy, like partial splenectomy, which can ameliorate symptoms while better protecting patients from bacterial sepsis and red cell parasites, and perhaps from atherosclerosis (Robinette & Franmeni, 1977) and venous thrombosis (Stewart et al, 1996).     

Hereditary pyropoikilocytosis and elliptocytosis in a white French family with the spectrin alpha I/74 variant related to a CGT to CAT codon change (Arg to His) at position 22 of the spectrin alpha I domain

We describe a white French family in which 12 subjects presented with hereditary elliptocytosis (HE) or hereditary pyropoikilocytosis (HPP). Eight of these subjects were shown to be heterozygous for a spectrin (Sp) alpha I/74 variant, as demonstrated by analysis of partial tryptic digestion fragments of spectrin. This abnormal peptide pattern was associated with a decreased ability of Sp dimers to self-associate. In this kindred, in which four generations were available for study, the clinical expression varied from mild HE to HPP with an intermediate status of hemolytic HE. The severity of the disease appeared to be correlated both with the estimated amount of variant Sp (42% to 65%) and the excess of Sp dimers found in the membrane (30% to 51%, with a normal value of 3.7% +/- 1.6%). Reassociation studies using isolated Sp alpha and beta chains from an affected patient and an unaffected control subject showed that the Sp alpha I/74 Kd abnormal tryptic peptide resulted from a defect in the Sp alpha chain. Partial amino acid sequencing showed that the Sp alpha I/74 Kd peptide resulted from cleavage at lysine residue 42 of the Sp alpha I/80 Kd domain. Knowledge of the exon/intron organization of the human alpha Sp gene allowed us to amplify by the polymerase chain reaction the second exon of the alpha Sp gene in total cellular DNA of the HPP proposita. The amplified fragment was subcloned and sequenced. We found a G to A base substitution in the 22nd codon (CAT for CGT), which changes the normal arginine to a histidine. Hybridization of amplified DNAs with allele-specific oligonucleotides corresponding to the normal and mutant sequences confirmed the presence of the mutation in six other HE and HPP members of the family. The identification of this mutation at the DNA level confirmed the transmission of the same molecular defect in Sp through four generations but with different patterns of clinical expression.     

Molecular determinants of clinical expression of hereditary elliptocytosis and pyropoikilocytosis

The clinical severity of common hereditary elliptocytosis (HE) is highly variable, ranging from an asymptomatic carrier state to a severe hemolytic anemia. To elucidate the molecular basis of this variable clinical expression, we evaluated 56 subjects from 24 HE kindred, who carry alpha spectrin mutants characterized by a spectrin dimer (SpD) self-association defect related to a structural abnormality of the alpha I domain of spectrin. Twenty-nine subjects had common HE, 13 subjects have a closely related disorder, hereditary pyropoikilocytosis (HPP), and 14 are asymptomatic carriers. We compared the severity of hemolysis with the following biochemical parameters: (a) spectrin heterodimer self-association, as manifested by the percentage of SpD in the 4 degrees C low ionic strength spectrin extract; (b) spectrin structure, as examined by limited tryptic digestion of spectrin; and (c) spectrin content of the RBC membrane. Our analysis indicates that the severity of hemolysis may be correlated with quantitative differences in the percentage of SpD in the 4 degrees C spectrin extract, as well as the total spectrin content of the membrane. Thus, HPP subjects, who have the most severe hemolytic anemia, have the highest percentage of SpD as well as a decreased spectrin content. HE subjects and asymptomatic carriers, respectively, have a lower percentage of SpD and a normal spectrin content. Factors influencing these two determinants include functional differences between the individual spectrin mutants, the relative amounts of mutant spectrin present in the cells, the stability of mutant spectrin, and the possibility of a superimposed genetic defect involving spectrin synthesis.     

Heterogeneity of the molecular basis of hereditary pyropoikilocytosis and hereditary elliptocytosis associated with increased levels of the spectrin alpha I/74-kilodalton tryptic peptide

Hereditary pyropoikilocytosis (HPP) and hereditary elliptocytosis are closely related, congenital disorders of the red blood cell usually associated with defective spectrin self-association and abnormal limited tryptic digestion of the N-terminal of domain of spectrin. Enhanced cleavage by trypsin of spectrin from affected individuals at arginyl residue 45* and lysyl residue 48* frequently yields increased amounts of an alpha 1/74-Kd fragment at the expense of the normal alpha 1/80-Kd parent fragment. Limited tryptic digestion of three unrelated individuals with HPP showed the alpha 1/74 defect. To ascertain the molecular defect responsible for the abnormality, the structure of exon 2 of the alpha-spectrin gene was examined. Genomic DNA from the subjects was amplified by the polymerase chain reaction using primers flanking exon 2. Restriction endonuclease digestion of amplified products showed the loss of the HindIII site at codons 47 and 48 in one allele of subject 1 and abolished the AhaII site at codons 27 and 28 in one allele of subjects 2 and 3. Nucleotide sequence analysis of subcloned amplified DNA from the HPP subjects showed three novel amino acid substitutions. In subject 1 (a black individual), a single base substitution (AAG----AGG) at codon position 48 changes amino acid residue lysine to arginine. In subject 2 (a white individual), a single base substitution (CGT----AGT) at codon 28 changes arginine to serine. In subject 3 (a black individual), a different base substitution at position 28 (CGT----CTT) changes arginine to leucine. These mutations occur at positions of the alpha l domain where other mutations have also been described, indicating that the normal residues at these positions play an important role in spectrin dimer self-association and thus, in membrane stability.     

Role of the interaction between Lu/BCAM and the spectrin‐based membrane skeleton in the increased adhesion of hereditary spherocytosis red cells to laminin

Lu/BCAM, the unique erythroid receptor for laminin 511/521, interacts with the erythrocyte membrane skeleton through spectrin binding. It has been reported that Hereditary Spherocytosis red blood cells (HS RBC) exhibit increased adhesion to laminin. We investigated the role of Lu/BCAM–spectrin interaction in the RBC adhesion properties of 2 splenectomised HS patients characterized by 40% spectrin deficiency. Under physiological flow conditions, HS RBC exhibited an exaggerated adhesion to laminin that was completely abolished by soluble Lu/BCAM. Triton extraction experiments revealed that a greater fraction of Lu/BCAM was unlinked to the membrane skeleton of HS RBC, as compared to normal RBC. Disruption of the spectrin interaction site in Lu/BCAM expressed in the transfected K562 cell line resulted in a weakened interaction to the skeleton and an enhanced interaction to laminin. These results demonstrated that the adhesion of HS RBC to laminin was mediated by Lu/BCAM and that its interaction with the spectrin‐based skeleton negatively regulated cell adhesion to laminin. Finally, the results of this study strongly suggest that the reinforced adhesiveness of spectrin‐deficient HS RBC to laminin is partly brought about by an impaired interaction between Lu/BCAM and the membrane skeleton.     

Hereditary spherocytosis (HS) due to loss of anion exchange transporter.

BACKGROUND. Hereditary spherocytosis encompasses a heterogenous group of inherited disorders due to alteration of r.b.c. surface/volume ratio. Spectrin deficiency is the most common observed defect. We analyzed a case of HS associated with band 3 deficiency without spectrin reduction. METHODS. In the study of a family originating from southern Italy, we show that a 20% deficiency of band 3 with normal spectrin content may be responsible for dominantly inherited hereditary spherocytosis (HS). The proband is a 12 years old girl consulting for jaundice, chronic anaemia and splenomegaly. Her mother had a similar haematologic phenotype. RESULTS. Electrophoretic analysis of erythrocyte membrane proteins showed a deficiency in band 3 protein. Band 3 protein chymotryptic fragments, deglycosylated band 3, and its isolated cytoplasmic domain, all displayed normal electrophoretic migrations. Furthermore, the tryptic peptides profile of the cytoplasmic domain of the protein did not demonstrate any abnormality, nor did the amino acid composition of the peptides. Analysis of the membrane proteins during erythrocyte ageing, evaluated in density-fractionated red cells, showed that band 3 content was normal in the lighter fraction, whereas in the denser fraction band 3 deficiency was more pronounced than in membranes from non fractionated red blood cells. CONCLUSIONS. This case describes HS due to anion exchange transporter deficiency. Our results on fractioned red cells support the hypothesis that the defect was probably due to a band 3 protein loss during cell ageing and not to a primitive quantitative defect.     

The instability of the membrane skeleton in thalassemic red blood cells

The thalassemias are a heterogeneous group of disorders characterized by accumulation either of unmatched alpha or beta globin chains. These in turn cause the intramedullary and peripheral hemolysis that leads to varying anemia. A partial explanation for the hemolysis came our of our studies on material properties that showed that beta-thalassemia (beta- thal) intermedia ghosts were very rigid but unstable. A clue to this instability came from the observation that the spectrin/band 3 ratio was low in red blood cells (RBCs) of splenectomized beta-thal intermedia patients. The possible explanations for the apparent decrease in spectrin content included deficient or defective spectrin synthesis in thalassemic erythroid precursors or globin chain-induced membrane changes that lead to spectrin dissociation from the membrane during ghost preparation. To explore the latter alternative, samples from different thalassemic variants were obtained, ie, beta-thal intermedia, HbE/beta-thal, HbH (alpha-thal-1/alpha-thal-2), HbH/Constant Spring (CS), and homozygous HbCS/CS. We searched for the presence of spectrin in the first lysate of the standard ghost preparation. Normal individuals and patients with autoimmune hemolytic anemia, sickle cell anemia, and anemia due to chemotherapy served as controls. Using gradient sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, no spectrin was detected in identical aliquots of the supernatants of normals and these control samples. Varying amounts of spectrin were detected in the first lysate supernatants of almost all thalassemic patients. The identification of spectrin was confirmed by Western blotting using an affinity-purified, monospecific, rabbit polyclonal antispectrin antibody. Relative amounts of spectrin detected were as follows in decreasing order: splenectomized beta-thal intermedia including HbE/beta-thal; HbCS/CS; nonsplenectomized beta-thal intermedia, HbH/CS; and, lastly, HbH. These findings were generally confirmed when we used an enzyme-linked immunosorbent assay technique to measure spectrin in the first lysate. Subsequent analyses showed that small amounts of actin and band 4.1 also appeared in lysates of thalassemic RBCs. Therefore, the three major membrane skeletal proteins are, to a varying degree, unstably attached in severe thalassemia. From these studies we could postulate that membrane association of abnormal or partially oxidized alpha- globin chains has a more deleterious effect on the membrane skeleton than do beta-globin chains.     

Changes in the composition of plasma membrane proteins during differentiation of embryonic chick erythroid cell.

Erythroid cells which are homogeneous with regard to stage of maturation are naturally available from the circulation of chick embryos at various times of development. This provides a convenient system for examining the changes in plasma membrane protein composition during red cell maturation. Plasma membranes are isolated from chick embryonic erythroid cells at various stages of maturation. Extensive characterization of the isolated membranes show that they are pure and their proteins undegraded. Analyses by sodium dodecyl sulfate/polyacrylamide gel electrophoresis show that both qualitative and quantitative changes occur in membrane protein composition during the early stage of erythroid differentiation. Specific proteins of red cell membrane such as "spectrin" and band three proteins are present in low levels in early erythroblasts but increase in their relative amounts with maturation. A steady-state membrane protein composition seems to be established by the late polychromatophilic erythroblast stage.     

Erythropoiesis in ha/ha and sph/sph mice, mutants which produce spectrin-deficient erythrocytes

In order to characterize chronically accelerated erythropoiesis, we studied the ultrastructure of bone marrow and spleen of ha/ha and sph/sph mice, two mutants with profound hemolytic anemia secondary to deficiency of the erythrocyte membrane protein spectrin. The marrows and spleens of both varieties were extremely erythropoietic and were without histological abnormalities directly related to spectrin deficiency. Erythropoiesis was consistently associated with distinctive, dark branched cells which constituted large proportions of the stroma of the mutant spleens and marrow. These dark cells were not present in untreated and acutely bled controls. Plasma clot assays for erythroid progenitors revealed that CFU-E concentrations in the mutant marrows were significantly increased over those in untreated controls while BFU-E concentrations were approximately half. In addition, mutant CFU-E often gave rise to abnormal appearing colonies. Spectrin, though crucial to erythrocyte function is probably not important to the process of erythroid differentiation and maturation. The status of erythroid precursors in the marrows of the spectrin deficient mice is similar to that of mice subjected to an acute bleed. The divergent changes in CFU-E and BFU-E may indicate that these two cells play different roles in accelerated erythropoiesis. The dark cells that we describe are similar to stromal cells observed in models of the early stages of erythropoiesis.     

Sp alpha I/65: a new variant of the alpha subunit of spectrin in hereditary elliptocytosis

Two molecular defects involving the spectrin heterodimer (SpD) contact site of the alpha chain (the alpha I domain) were previously identified using limited tryptic digestion followed by two-dimensional isoelectric focusing/sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Both are characterized by atypical peptide maps which reveal a marked decrease of the 80,000-dalton alpha I domain and a formation of new major peptides of either 74,000 (Sp alpha I/74) or 46,000 (Sp alpha I/46) daltons. We now report a third variant of the spectrin alpha chain, designated Sp alpha I/65, in three unrelated black families. In all three probands, the percentage of SpD in the low ionic strength (O degrees C) membrane extracts was increased to 19% to 32%. One- and two- dimensional electrophoretic separations of limited tryptic digests of spectrin from all three probands revealed a decrease of the alpha I domain of spectrin and the concomitant appearance of peptides at 65,000 daltons and isoelectric points ranging from 5.2 to 5.3. The abnormal 65,000-dalton peptides could be stained with an antiserum which had been raised against the alpha I domain, indicating that it was derived from the alpha I domain.