Cytoplasmic Domain Of Band Research Articles

Characterization of the pH dependence of hemoglobin binding to band 3: Evidence for a pH-dependent conformational change within the hemoglobin-band 3 complex

The pH dependence of hemoglobin binding to inside-out red cell membrane vesicles was studied using 90° light scattering (Salhany, J.M. et al., Biochemistry 19 (1980) 1447–1454). Hyperbolic binding curves were observed for high-affinity hemoglobin binding to the cytoplasmic domain of band 3 (CDB3) within the intact transporter. Analysis of these saturation curves yielded the apparent K d and the maximum light scattering signal change (ΔLS max ). The apparent K d for hemoglobin binding did not change substantially between pH 5.5 and 7.0, while at pH 8, there is no binding. In contrast, ΔLS max decreased by about 20-fold between pH 5.5 and 7.0, with an apparent p K of 6.5. These results suggest that hemoglobin binds to CDB3 with high affinity at both neutral and acid pH, a suggestion that was confirmed using a centrifugation method. Thus, the p K for the light scattering signal change is significantly lower than the p K for the actual binding process. We show that the change in ΔLS max is not related to a change in band 3 binding capacity, which remains constant as a function of pH. We also show that hemoglobin binding to non-band 3 sites contributes less than 10% to ΔLS max under our specific experimental conditions. On the basis of these and previous fluorescence quenching results in the literature, we propose a new model for hemoglobin binding to band 3, where raising the pH from 6 and 7 causes the CDB3–hemoglobin complex to undergo a conformational change leading to the movement of the bound hemoglobin away from the surface of the bilayer. The possible implication of this new mechanistic interpretation is discussed briefly.

Effects of chemical modification of cysteines 201 and 317 of band 3 on hemolytic properties of human erythrocytes under hydrostatic pressure.

In the membrane stability of human erythrocytes, the role of two cysteine residues (Cys-201 and Cys-317) in the cytoplasmic domain of band 3 is not clear. So we tried to resolve this problem by examining hemolytic properties under high pressure. From SH contents and spin labeling, it was found that Cys-201 and Cys-317 of band 3 were modified with N-ethylmaleimide (NEM). The hemolysis of intact erythrocytes at 200 MPa was suppressed by the binding of 4, 4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS), anion transport inhibitor, to band 3. Similarly, the suppressive effect of DIDS was observed in the erythrocyte that Cys-201 and Cys-317 were modified with NEM. These results suggest that the cysteine residues in the cytoplasmic domain of band 3 are not essential for the DIDS-induced membrane stabilization.

Modulation of Clinical Expression and Band 3 Deficiency in Hereditary Spherocytosis

AbstractWe present two novel alleles of the anion-exchanger 1 (AE1) gene, allele Coimbra and allele Mondego. Allele Coimbra (V488M, GTG → ATG) affects a conserved position in the putative second ectoplasmic loop of erythrocyte band 3. In 15 simple heterozygotes, it yielded a mild form of hereditary spherocytosis (HS) with band 3 deficiency (−20% ± 2%) and a reduced number of 4,4′-diisothiocyano-1,2-diphenylethane-2,2′-disulfonate (H2DIDS) binding sites (−35%). However, two additional heterozygotes presented with an aggravated HS and a more pronounced reduction of band 3 (−40%) and of H2DIDS binding sites (−48%). They carried, in trans to allele Coimbra, allele Mondego, defined by two mutations: E40K, GAG → AAG, the known mutation Montefiore, and P147S, CCT → TCT, a novel mutation, both located in the cytoplasmic domain of band 3. Allele Mondego itself resulted in no clinical or hematologic HS signs in the simple heterozygous state. Yet it yielded a slight decrease in band 3 (−6% to −12%) and in the number of H2DIDS binding sites (−19%). Thus, the more pronounced decrease in band 3 in the two compound heterozygotes derived from the additive effects of two unequally expressed AE1 alleles, resulting in a more severe clinical picture.

Modulation of Clinical Expression and Band 3 Deficiency in Hereditary Spherocytosis

We present two novel alleles of the anion-exchanger 1 (AE1) gene, allele Coimbra and allele Mondego. Allele Coimbra (V488M, GTG → ATG) affects a conserved position in the putative second ectoplasmic loop of erythrocyte band 3. In 15 simple heterozygotes, it yielded a mild form of hereditary spherocytosis (HS) with band 3 deficiency (−20% ± 2%) and a reduced number of 4,4′-diisothiocyano-1,2-diphenylethane-2,2′-disulfonate (H2DIDS) binding sites (−35%). However, two additional heterozygotes presented with an aggravated HS and a more pronounced reduction of band 3 (−40%) and of H2DIDS binding sites (−48%). They carried, in trans to allele Coimbra, allele Mondego, defined by two mutations: E40K, GAG → AAG, the known mutation Montefiore, and P147S, CCT → TCT, a novel mutation, both located in the cytoplasmic domain of band 3. Allele Mondego itself resulted in no clinical or hematologic HS signs in the simple heterozygous state. Yet it yielded a slight decrease in band 3 (−6% to −12%) and in the number of H2DIDS binding sites (−19%). Thus, the more pronounced decrease in band 3 in the two compound heterozygotes derived from the additive effects of two unequally expressed AE1 alleles, resulting in a more severe clinical picture.

Identification of the Major Casein Kinase I Phosphorylation Sites on Erythrocyte Band 3

AbstractHuman erythrocyte band 3 is a major substrate of two red blood cell protein kinases, casein kinase I and p72syk protein tyrosine kinase. Although the phosphorylation sites and physiologic consequences of p72syk phosphorylation have been characterized, little is known regarding casein kinase I phosphorylation. In this report, we identify the major phosphorylation site of casein kinase I. Using isolated components, casein kinase I was found to phosphorylate the cytoplasmic domain of band 3 (CDB3), primarily on Thr residues. Classical peptide mapping narrowed the major phosphorylation site to a peptide encompassing residues 24-91. Computer-assisted evaluation of this sequence not only showed two consensus casein kinase I phosphorylation sites, but also provided information on how to proteolytically separate and isolate the candidate sites. Following the suggested protocols, a heptapeptide containing the major phosphorylation site was isolated, subjected to amino acid sequencing, and found to be phosphorylated on Thr 42. A minor phosphorylation site was similarly identified as Ser 303. Because Thr 42 is situated near the binding sites on CDB3 of ankyrin, protein 4.1, protein 4.2, and the glycolytic enzymes, phosphorylation of CDB3 by casein kinase I could conceivably impact erythrocyte structure and/or function.

Cytoskeleton-membrane connections in the human erythrocyte membrane: band 4.1 binds to tetrameric band 3 protein

Band 4.1 provides, besides ankyrin, the main linkage between the erythrocyte membrane and its cytoskeleton. Its predominant binding sites in the membrane are located on the glycophorins. However, the cytoplasmic domain of band 3 can also bind band 4.1. We have studied which of the different band 3 oligomers observed (monomers, dimers, tetramers) can act as band 4.1 binding sites, by equilibrium sedimentation experiments on mixtures of purified band 3 and dye-labelled band 4.1 in solutions of a nonionic detergent. At low molar ratios of band 4.1 and band 3, the sedimentation equilibrium distributions obtained could all be perfectly fitted assuming that only two dye-labelled particles were present: uncomplexed band 4.1 and a complex formed between one band 4.1 molecule and one band 3 tetramer. The presence of small amounts of complexes containing band 3 monomers or dimers could not be completely ruled out but is unlikely. On the other hand, stabilized band 3 dimers effectively bound band 4.1. At higher molar band 4.1/band 3 ratio, the band 3 tetramer apparently could bind up to at least four band 4.1 molecules. The band 4.1/band 3 tetramer complex was found to be unstable. The results described, together with those reported previously, point at a prominent role of tetrameric band 3 in ligand binding.

Se-mediated domain-domain communication in band 3 of human erythrocytes.

Na2SeO3 could affect the anion flux of Band 3 of inside-out erythrocyte membrane vesicles (IOVs). Such effect was believed to be based on the interaction of SH groups of Band 3 with Na2SeO3. This effect could be eliminated when the cytoplasmic domain of Band 3 was proteolytically removed by trypsin. This suggested that SH groups in the cytoplasmic domain were involved in such interaction. Measurement of the pH dependence of intrinsic fluorescence intensity provided evidence that conformational changes of Band 3 occurred as a consequence of interaction with selenite. KI quenching of intrinsic fluorescence of Band 3 could also show that there was a conformational change in the cytoplasmic domain of Band 3 after reaction with Na2SeO3. Such conformational change in turn could be transmitted to the membrane domain of Band 3 monitored by quenching of intrinsic fluorescence of Band 3 using hypocrellin B (HB) (a photosensitive pigment obtained from a parasitic fungus growing in Yunnan, China). It is suggested that the cytoplasmic domain of Band 3 is not necessary for its anion flux, but is essential for the regulation (e.g., by Se) of its active site located at the membrane domain, and hence, it may provide evidence of communication between the cytoplasmic domain and the membrane domain of Band 3.

Associations between erythrocyte band 3 protein and aldolase in detergent solution. Determining their stoichiometry by analytical ultracentrifugation.

The cytoplasmic domain of band 3, the predominant polypeptide of the erythrocyte membrane, represents a binding site for certain glycolytic enzymes. We have studied the association between human band 3 protein and aldolase, in order to clarify the role of the different band 3 oligomers as ligand binding sites. The experiments were performed on mixtures of solubilized band 3 and aldolase in solutions of a nonionic detergent, nonaethyleneglycol lauryl ether. The main technique applied was sedimentation equilibrium analysis in an analytical ultracentrifuge. In addition, nonequilibrium centrifugation techniques were used. To facilitate the evaluations, the aldolase was labelled with a dye. The following results were obtained. (1) With unmodified band 3, aldolase is bound exclusively or at least predominantly to the band 3 tetramer (but not to monomers or dimers). (2) The band 3 tetramer can bind up to four aldolase tetramers. (3) The band 3 tetramer/aldolase complex is unstable on the time scale of the techniques used. (4) Stable band 3 dimers (stabilized either covalently or noncovalently) can also associate with aldolase and can bind up to two aldolase tetramers. The results described, together with those reported previously, point at a prominent role of the band 3 tetramer in ligand binding.

Distance between Cys-201 in erythrocyte band 3 and the bilayer measured by single-photon radioluminescence

Single-photon radioluminescence (SPR), the excitation of fluorophores by short-range beta-decay electrons, was developed for the measurement of submicroscopic distances. The cytoplasmic domain of band 3 (cdb3) is the primary, multisite anchorage for the erythrocyte skeleton. To begin to define the membrane arrangement of the highly asymmetrical cdb3 structure, the distance from the bilayer of Cys-201 next to the "hinge" of cdb3 was measured by both SPR and resonance energy transfer (RET). cdb3 was labeled at Cys-201 with fluorescein maleimide. For SPR measurements, the bilayer was labeled with [3H]oleic acid. The corrected cdb3-specific SPR signal was 98 +/- 2 cps microCi-1 [mumol band 3]-1. From this and the signal from a parallel sample in which 3H2O was substituted for [3H]oleic acid to create uniform geometry between 3H and the fluorophores, a Cys-201-to-bilayer separation of 39 +/- 7 A was calculated. Confirmatory distances of 40 and 43 A were obtained by RET between fluorescein on Cys-201 and eosin and rhodamine B lipid probes, respectively. This distance indicates that Cys-201 lies near band 3's vertical axis of symmetry and that the subdomain of cdb3 between the hinge and the membrane is not significantly extended. In addition, these results validate SPR as a measure of molecular distances in biological systems.

Identification of a band-3 binding site near the N-terminus of erythrocyte membrane protein 4.2.

Protein 4.2 (P4.2) is a major component of the erythrocyte plasma membrane accounting for approx. 5% of total membrane protein. The major membrane binding site for P4.2 is contained within the cytoplasmic domain of band 3 (cdb3), although the precise location of the cdb3 binding site is not known. To identify the cdb3 binding site, we used synthetic P4.2 peptides (15-mers) that spanned the entire 721-amino-acid large isoform of P4.2, and determined the binding of these peptides to cdb3 in an in vitro binding assay. One peptide, P8 (L61FVRRGQPFTIILYF), bound strongly to cdb3 and four others bound less strongly (P22, L271LNKRRGSVPILRQW; P27, G346EGQRGRIWIFQTST; P41, L556WRKKLHLTLSANLE; P48, I661HRERSYRFRSVWPE). These peptides have in common a cluster of two or three basic amino acid residues (arginine or lysine), in a region without nearby acidic residues. Cdb3 bound saturably to P8 with a Kd of 0.16 microM and a capacity of 0.56 mol of cdb3 monomer/mol of P8. Use of overlapping synthetic peptides further defined the cdb3 site as being contained within V63RRGQPFTIILYF. Replacement of R64R with R64G, G64R or G64G almost completely abolished cdb3 binding, suggesting that R64R is essential for cdb3 binding. P8 competitively inhibited binding of purified human erythrocyte P4.2 to cdb3. In blot overlay assays, cdb3 bound to a 23 kDa N-terminal P4.2 tryptic peptide containing V63RRGQPFTIILYF but not to other P4.2 tryptic peptides lacking this site. The V63RRGQPFTIILYF site is highly conserved in mouse and human erythrocyte P4.2 as well as between P4.2 and transglutaminase proteins, which are evolutionarily related to P4.2.

Zn2+-Mediated Domain-Domain Communication in Human Erythrocyte Band 31

Zn2+ could inhibit the anion transport activity of spectrin-stripped inside-out human erythrocyte membrane vesicles (IOVs). Removal of the cytoplasmic domain from Band 3 by trypsin could eliminate Zn2+ inhibition. The location of a Zn(2+)-binding site was confirmed by atomic absorbance spectrometry. The results of time-resolved fluorescence and intrinsic fluorescence quenching by KI and hypocrellin B (a photosensitive pigment obtained from a parasitic fungus growing in Yunnan, China) showed that the cytoplasmic domain is necessary for the Zn(2+)-induced conformational changes of the whole molecule as well as the membrane domain of Band 3. It is suggested that Zn2+ induced a conformational change in the cytoplasmic domain of Band 3, which in turn was transmitted to the membrane domain, resulting in an inhibition of activity of Band 3. Such long-range conformational changes may imply that the cytoplasmic domain is poised to function as a cytosolic arm in order to modulate the structure of the membrane domain of Band 3.

Neutral polymers elicit and antibodies to spectrin band 4.1 protein and cytoplasmic domain of band 3 protein inhibit the concanavalin A-mediated agglutination of human erythrocytes

Concanavalin A (Con A) is known to agglutinate human erythrocytes if the cells are pre-treated with a proteinase or neuraminidase. We report that untreated cells can also be made to agglutinate with the lectin if the lectin-bound cells are treated with anti-Con A antibodies, or if a neutral polymer such as serum albumin, polyvinylpyrrolidone or Ficoll is added. Thus, Con A falls in the category of ‘incomplete’ lectins. The polymer induces Con A-agglutinability without altering the receptor number, or deformability of the cells. If the polymer is sequestered within erythrocyte ghosts, Con A is unable to agglutinate them; but the presence of the polymer only on the outer surface (as in intact cells) or on both the surfaces permits agglutinability. Thus, the site of the polymer effect resides on the outer surface of the membrane. The polymer, however, is unable to induce agglutinability in erythrocyte vesicles, whose membrane lacks skeletal proteins. The result suggests a positive role for the membrane skeleton in the process of agglutination brought about by the polymer, as is true also for the agglutination of proteinase-treated cells. In order to obtain detailed information on the proteins participating in agglutination, monospecific antibodies to spectrins, band 4.1 protein, ankyrin and the cytoplasmic domain of band 3 protein were internalized in erythrocytes. It is found that anti-spectrin and anti-band 3 cytoplasmic domain, but not their Fab's, inhibit the Con A-mediated agglutinability partially, and anti-4.1 antibodies, as well as the Fab's, inhibit the agglutinability substantially. Anti-ankyrin, however, was without any effect. The results confirm a positive role for the membrane skeleton in the Con A-mediated agglutination of normal erythrocytes in the presence of a neutral polymer, or in proteinase treated cells. We also provide evidence for requirement of Mg-ATP in the agglutination process.

Oxidative interactions between the erythrocyte membrane and phosphatidylcholine vesicles.

Sonicated unilamellar phosphatidylcholine vesicles induce hemoglobin oxidation in erythrocytes and resealed membrane fragments (buds) at pH 5.5. No such oxidation was observed in vesicle-bud mixtures at pH 7.4, in cells or buds suspended in pH 5.5 buffer, or in cells incubated with multilamellar lipid vesicles at pH 5.5. In buds, vesicle-induced hemoglobin oxidation was accompanied by lipid peroxidation and formation of covalent high molecular weight protein aggregates. The causative relationships among the oxidative events were examined using selective antioxidants and membrane fragments in which the cytoplasmic domain of band 3 was cleaved. Protein cross-linking and lipid peroxidation were found to be independent events, but both were found only in concert with heme oxidation. Further, vesicle-induced hemoglobin oxidation was found to be correlated with quasi-stable adsorption of intact vesicles to cells; intercalation of foreign lipid into the cell bilayer was not required. The inability of multilamellar vesicles to induce these low pH oxidative effects suggests a steric limitation on this cell-vesicle association. The results suggest that membrane component reorganization and patching induced by low pH may enhance vesicle adsorption, which in turn initiates oxidative damage.

Segmental dynamics of the cytoplasmic domain of erythrocyte band 3 determined by time-resolved fluorescence anisotropy: sensitivity to pH and ligand binding.

Interactions between the erythrocyte membrane and its skeleton are mediated primarily by binding of cytoskeletal components to a conformationally sensitive structure, the cytoplasmic domain of band 3 (cdb3). To examine the nanosecond segmental motions of cdb3, band 3 was labeled selectively by fluorescein maleimide at Cys-201 near the proposed hinge in cdb3 about which pH-dependent conformational changes occur. Time-resolved anisotropy of labeled cdb3 in isolated form and in stripped erythrocyte membranes was measured by parallel-acquisition frequency-domain microfluorimetry. Samples had a single-component fluorescein lifetime of approximately 4 ns. Multifrequency phase and modulation data (5-200 MHz) fitted well to a segmental motion model containing two correlation times (tau 1c and tau 2c) and two limiting anisotropies (r1infinity and r2infinity). Measurements in protease-cleaved and denatured samples indicated that tau 1c (100-150 ps) corresponded to rapid rotation of bound fluorescein and tau 2c (2-5 ns) corresponded to segmental motion of cdb3. Both motions were hindered as quantified by nonzero r1infinity and r2infinity. The strong pH dependence of segmental motion correlated with that of cdb3 conformation measured by intrinsic tryptophan fluorescence. Significant changes in cdb3 segmental motion occurred upon interactions with the small ligands 2,3-bisphosphoglycerate and calcium and several glycolytic enzymes known to bind to the N terminus of band 3. These time-resolved fluorescence measurements of the nanosecond segmental dynamics of a labeled membrane protein provide evidence for the sensitivity of cdb3 conformation to ligand binding and suggest long-range structural communication through cdb3.

Human Erythrocyte Protein 4.2 Deficiency Associated With Hemolytic Anemia and a Homozygous 40Glutamic Acid → Lysine Substitution in the Cytoplasmic Domain of Band 3 (Band 3Montefiore)

Abstract Red blood cell (RBC) protein 4.2 deficiency is often associated with a moderate nonimmune hemolytic anemia, splenomegaly, and osmotically fragile RBCs resembling, but not identical to, hereditary spherocytosis (HS). In the Japanese type of protein 4.2 deficiency (protein 4.2Nippon), the anemia is associated with a point mutation in the protein 4.2 cDNA. In this report, we describe a patient with moderate and apparently episodic nonimmune hemolytic anemia with splenomegaly, spherocytosis, osmotically fragile RBCs, reduced whole cell deformability, and abnormally dense cells. Sodium dodecyl sulfate- polyacrylamide gel electrophoresis analysis of the proposita's RBC membrane proteins showed an 88% deficiency of protein 4.2 and a 30% deficiency of glyceraldehyde-3-phosphate dehydrogenase (band 6). Structural and molecular analyses of the proposita's protein 4.2 were normal. In contrast, limited tryptic digestion of the proposita's band 3 showed a homozygous abnormality in the cytoplasmic domain. Analysis of the pedigree disclosed six members who were heterozygotes for the band 3 structural abnormality and one member who was a normal homozygote. Direct sequence analysis of the abnormal band 3 tryptic peptide suggested that the structural abnormality resided at or near residue 40. Sequence analysis of the proposita's band 3 cDNA showed a 232G-->A mutation resulting in a 40glutamic acid-->lysine substitution (band 3Montefiore). Allele-specific oligonucleotide hybridization was used to probe for the mutation in the pedigree, showing that the proposita was homozygous, and the pedigree members who were heterozygous for the band 3 structural abnormality were also heterozygous for the band 3Montefiore mutation. The band 3Montefiore mutation was absent in 26 chromosomes from race-matched controls and in one pedigree member who did not express the band 3 structural abnormality. In coincidence with splenectomy, the proposita's anemia was largely corrected along with the disappearance of most spherocytes and considerable improvements of RBC osmotic fragility, whole cell deformability, and cell density. We conclude that this hereditary hemolytic anemia is associated with the homozygous state for band 3Montefiore (40glutamic acid-->lysine) and a decreased RBC membrane content of protein 4.2. We speculate that band 3 structural abnormalities can result in defective interactions with protein 4.2 and band 6, and in particular, that the region of band 3 containing 40glutamic acid is involved directly or indirectly in interactions with these proteins.

Human erythrocyte protein 4.2 deficiency associated with hemolytic anemia and a homozygous 40glutamic acid-->lysine substitution in the cytoplasmic domain of band 3 (band 3Montefiore)

Red blood cell (RBC) protein 4.2 deficiency is often associated with a moderate nonimmune hemolytic anemia, splenomegaly, and osmotically fragile RBCs resembling, but not identical to, hereditary spherocytosis (HS). In the Japanese type of protein 4.2 deficiency (protein 4.2Nippon), the anemia is associated with a point mutation in the protein 4.2 cDNA. In this report, we describe a patient with moderate and apparently episodic nonimmune hemolytic anemia with splenomegaly, spherocytosis, osmotically fragile RBCs, reduced whole cell deformability, and abnormally dense cells. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the proposita's RBC membrane proteins showed an 88% deficiency of protein 4.2 and a 30% deficiency of glyceraldehyde-3-phosphate dehydrogenase (band 6). Structural and molecular analyses of the proposita's protein 4.2 were normal. In contrast, limited tryptic digestion of the proposita's band 3 showed a homozygous abnormality in the cytoplasmic domain. Analysis of the pedigree disclosed six members who were heterozygotes for the band 3 structural abnormality and one member who was a normal homozygote. Direct sequence analysis of the abnormal band 3 tryptic peptide suggested that the structural abnormality resided at or near residue 40. Sequence analysis of the proposita's band 3 cDNA showed a 232G-->A mutation resulting in a 40glutamic acid-->lysine substitution (band 3Montefiore). Allele-specific oligonucleotide hybridization was used to probe for the mutation in the pedigree, showing that the proposita was homozygous, and the pedigree members who were heterozygous for the band 3 structural abnormality were also heterozygous for the band 3Montefiore mutation. The band 3Montefiore mutation was absent in 26 chromosomes from race-matched controls and in one pedigree member who did not express the band 3 structural abnormality. In coincidence with splenectomy, the proposita's anemia was largely corrected along with the disappearance of most spherocytes and considerable improvements of RBC osmotic fragility, whole cell deformability, and cell density. We conclude that this hereditary hemolytic anemia is associated with the homozygous state for band 3Montefiore (40glutamic acid-->lysine) and a decreased RBC membrane content of protein 4.2. We speculate that band 3 structural abnormalities can result in defective interactions with protein 4.2 and band 6, and in particular, that the region of band 3 containing 40glutamic acid is involved directly or indirectly in interactions with these proteins.

Interaction of eosin-5-maleimide with band 3 of human erythrocytes.

The interaction between EMI (eosin-5-maleimide) and band 3 of human erythrocytes was studied under various conditions. It was found that the effects of the ionic strength on the EMI-band 3 interaction strongly depended on pH. At pH 6.0, the ionic strength had remarkable effects on the EMI-bound band 3, whereas at pH 7.4, the EMI-band 3 interaction was independent of ionic strength. From the change in the circular dichroism spectra of the EMI-bound band 3, it was revealed that the conformation or the structure of the EMI-binding sites in the cytoplasmic domain of band 3 was strongly dependent on ionic strength. The thermodynamic parameters for the covalent-binding between EMI and band 3 were calculated on the basis of the difference spectra of the EMI and ghost system. The values of activation energy and activation entropy change at pH 6.0 were extraordinarily small compared with those values at pH 7.4. These findings represent the characteristics of the EMI-binding sites in the cytoplasmic domain of band 3. The interaction of EMI with an isolated fragment of the cytoplasmic domain, 43k fragment, was also examined. The circular dichroism spectra of the EMI-bound 43k fragments was significantly different from those of the EMI-bound band 3. This may indicate that the quaternary structure of the EMI-binding site in the cytoplasmic domain of band 3 is altered by an allosteric connection with the membrane-spanning domain of band 3. Further, from the pH titration of the 43k fragment, it was suggested that lysine residues are responsible for the ionic interaction between EMI and the 43k fragment.

Mechanism of hypotonic hemolysis of human erythrocytes.

A mechanism of hemolytic hole formation during rapid hemolysis in a hypotonic medium has been investigated using eosin-5-maleimide (EMI) as a probe. The EMI-labeled erythrocytes revealed a distinct cluster and/or ring of intense fluorescence staining in a hypotonic 5 mM Hepes buffer (pH 7.4), but not in an isotonic buffer containing 150 mM KCl. This EMI cluster indicates an association of band 3 proteins, which correspond to a hemolytic hole. The hole was confirmed by an atomic force microscopy image. The erythrocytes showed a single large hole in the membrane. By the use of EMI-labeled ghosts, it was observed that the lateral clustering of band 3 was accompanied by a biphasic change of fluorescence intensity of EMI. This biphasic change is interpreted as the hemolytic hole formation by band 3, followed by a disappearance of the hole accompanied by band 3 diffusion or distribution within membrane. The latter event corresponds to a spontaneous membrane seal. When a cytoplasmic domain of band 3 was digested with trypsin, or when SH groups in the cytoplasm-facing components of the membrane were also labeled by EMI, no fluorescence change was observed. These results suggest that the association and/or dissociation of band 3 proteins in a hypotonic medium are strongly influenced by cytoplasmic domains. The apparent biphasic change of the fluorescence intensity in the hypotonic medium was well explained by assuming three events: swelling, clustering of band 3, and sealing accompanied by band 3 redistribution.

Structural and functional characterization of band 3 from Southeast Asian ovalocytes.

To determine why deletion of the nine amino acids joining the membrane and cytoplasmic domains of band 3 from Southeast Asian ovalocytes (SAO) renders the erythrocytes rigid, we compared the structural and functional properties of SAO and normal band 3. Calorimetric data, inhibitor binding studies, and anion transport assays all reveal that the membrane-spanning domain of SAO band 3 is denatured, while proteolysis studies and circular dichroism spectroscopy suggest the mutant domain retains much secondary structure. It is concluded that the transmembrane helices of SAO band 3 are dissociated and randomized but not unfolded. The cytoplasmic domain of SAO band 3 was shown to be structurally and functionally normal based on (i) calorimetric properties, (ii) native conformational change, (iii) ability to form an intersubunit disulfide bond, (iv) affinity and capacity for binding ankyrin and protein 4.1, and (v) kinetics of association with ankyrin. However, both normal and mutant isoforms of band 3 in SAO cells were found to adhere nonspecifically to the spectrin skeleton. Further, when SAO cells were osmotically swollen, the detergent extractability of band 3 became normal. We propose that much of band 3 is nonspecifically entrapped in the spectrin network in SAO cells and that this nonspecific adhesion may be responsible for the rigidity of the SAO erythrocyte.

Band 3‐Memphis is associated with a lower transport rate of phosphoenolpyruvate

Band 3-Memphis is the most common variant of erythrocyte band 3 protein, in which a single amino acid substitution (Lys56-->Glu) in a cytoplasmic domain of band 3 has been found. We showed here that the prevalence of the variant was particularly higher in the Japanese population than that in other populations. The calculated gene frequency of the variant in Japanese was 0.156, which was about 4 times higher than that in Caucasian. Although it has been generally accepted that the cytoplasmic domain of band 3 bears no relation to anion transport activity, we found that the transport rate of phosphoenolpyruvate in erythrocytes of homozygotes was decreased to about 80% of that in control cells, and that of heterozygotes was at an intermediate level. The evidence indicates that some structural changes in the cytoplasmic domain of band 3 may have influence on the conformation of anion transport system.