The band 3 protein of the human red cell membrane: A review

Band 3 is the predominant polypetide and the purported mediator of anion transport in the human erythrocyte membrane. Against a background of minor and apparently unrelated polypeptides of similar electrophoretic mobility, and despite apparent heterogeneity in its glycosylation, the bulk of band 3 exhibits uniform and characteristic behavior. This integral glycoprotein appears to exist as a noncovalent dimer of two ～ 93,000-dalton chains which span the membrane asymmetrically. The protein is hydrophobic in its composition and in its behaviour in aqueous solution and is best solubilized and purified in detergent. It can be cleaved while membrane-bound into large, topographically defined segments. An integral, outer-surface, 38,000-dalton fragment bears most of the band 3 carbohydrate. A 17,000-dalton, hydrophobic glycopeptide fragment spans the membrane. A ～ 40,000-dalton hydrophilic segment represents the cytoplasmic domain. In vitro, glyceraldehyde 3-P dehydrogenase and aldolase bind reversibly, in a metabolite-sensitive fashion, to this cytoplasmic segment. The cytoplasmic domain also bears the amino terminus of this polypetide, in contrast to other integral membrane proteins. Recent electron microscopic analysis suggests that the poles of the band 3 molecule can be seen by freezeetching at the two original membrane surfaces, while freeze-fracture reveals the transmembrane disposition of band 3 dimer particles. There is strong evidence that band 3 mediates 1:1 anion exchange across the membrane through a conformational cycle while remaining fixed and asymmetrical. Its cytoplasmic pole can be variously perturbed and even excised without a significant alteration of transport function. However, digestion of the outer-surface region leads to inhibition of transport, so that both this segment and the membrane-spanning piece (which is slectively labeled by covalent inhibitors of transport) may be presumed to be involved in transport. Genetic polymorphism has been observed in the structure and immunogenicity of the band 3 polypeptide but this feature has not been related to variation in anion transport or other band 3 activities.     

Binding of chloride and a disulfonic stilbene transport inhibitor to red cell band 3

Summary The effect of chloride on 4,4-dibenzamido-2,2-disulfonic stilbene (DBDS) binding to band 3 in unsealed red cell ghost membranes was studied in buffer [NaCl (0 to 500mm) + Na citrate] at constant ionic strength (160 or 600mm). pH 7.4, 25°C. In the presence of chloride, DBDS binds to a single class of sites on band 3. At 160mm ionic strength, the dissociation constant of DBDS increases linearly with chloride concentration in the range [Cl]=450mm. The observed rate of DBDS binding to ghost membranes, as measured by fluorescence stopped-flow kinetic experiments, increases with chloride concentration at both 160 and 600mm ionic strength. The equilibrium and kinetic results have been incorporated into the following model of the DBDS-band 3 interaction: The equilibrium and rate constants of the model at 600mm ionic strength areK ₁=0.67±0.16 m,k ₂=1.6±0.7 sec^–1,k _–2=0.17±0.09 sec^–1,K ₁=6.3±1.7 m,k ₂=9±4 sec^–1 andk _–2=7±3 sec^–1. The apparent dissociation constants of chloride from band 3,K _Cl, are 40±4mm (160mm ionic strength) and 11±3mm (600mm ionic strength). Our results indicate that chloride and DBDS have distinct, interacting binding sites on band 3.     

A tyrosine kinase associated with the red cell membrane phosphorylates band 3

Phosphorylation of Band 3, the anion transport protein of human erythrocyte membranes, has been studied by incubating isolated ghosts with [gamma-32P]ATP. One of the phosphate-acceptor sites is tyrosine 8 in the NH2-terminal cytoplasmic domain of the Band 3 protein. Seven out of 11 residues in the sequence surrounding the phosphorylated tyrosine are Asp or Glu. It is concluded that the erythrocyte, like other cells, contains a membrane-associated tyrosine kinase which phosphorylates highly anionic peptide acceptor sites.     

Interaction of thiourea with band 3 in human red cell membranes

Summary Although urea transport across the human red cell membrane has been studied extensively, there is disagreement as to whether urea and water permeate the red cell by the same channel. We have suggested that the red cell anion transport protein, band 3, is responsible for both water and urea transport. Thiourea inhibits urea transport and also modulates the normal inhibition of water transport produced by the sulfhydryl reagent,pCMBS. In view of these interactions, we have looked for independent evidence of interaction between thiourea and band 3. Since the fluorescent stilbene anion transport inhibitor, DBDS, increases its fluorescence by two orders of magnitude when bound to band 3 we have used this fluorescence enhancement to study thiourea/band 3 interactions. Our experiments have shown that there is a thiourea binding site on band 3 and we have determined the kinetic and equilibrium constants describing this interaction. Furthermore,pCMBS has been found to modulate the thiourea/band 3 interaction and we have determined the kinetic and equilibrium constants of the interaction in the presence ofpCMBS. These experiments indicate that there is an operational complex which transmits conformational signals among the thiourea,pCMBS and DBDS sites. This finding is consistent with the view that a single protein or protein complex is responsible for all the red cell transport functions in which urea is involved.     

An immunological study of band 3, the anion transport protein of the human red blood cell membrane

Band 3, the predominant membrane-spanning polypeptide and purported anion transport protein of human red cells, was isolated by a new procedure which utilized selective solubilization and anion exchange chromatography on Affi-Gel 102 in 0.5% and Triton X-100/0.03% sodium dodecyl sulfate. Rabbit anti-serum prepared against the purified protein reacted with human and monkey band 3 but gave no immunoprecipitate with membrane proteins from several non-primate species. The antiserum was directed solely towards a portion of the cytoplasmic pole of the band 3 polypeptide contained within a 23,000 dalton amino-terminal fragment, as shown by agglutination, absorption, double diffusion and immunoprecipitation techniques. Saturation of both surfaces of resealed erythrocyte ghosts with the anti-band 3 antiserum had no significant effect on chloride transport. Our data define the topographically-limited immunogenicity of human band 3 in rabbits, demonstrate a lack of immunological cross-reactivity of band 3 between primates and non-primates, and support the hypothesis that the cytoplasmic domain of band 3 is not intimately involved in anion transport.     

The preparation of hydrophilic derivatives of band 3 protein by acylation of the human red blood cell membrane

In situ reaction of erythrocyte membranes with dicarboxylic anhydrides leads to solubilization of hydrophobic integral proteins. Removal of peripheral proteins and bulk lipid by appropriate sedimentation and dialysis steps yields hydrophilic band 3 protein derivatives. These acyl compounds display size heterogeneity upon gel filtration. A chromatographically homogeneous acyl band 3 protein is obtained if the acylation is conducted in the presence of detergent and the detergent subsequently removed. Hydrophilic acyl derivatives of band 3 protein can be subjected to conventional analytical techniques without the use of detergents.     

Cation dependence of the phosphorylation of specific residues in red cell membrane protein band 3

Phosphorylation of anion channel protein (ACP), the major component of erythrocyte protein band 3, was achieved in red cell ghosts in buffers containing vanadate (an inhibitor of phosphatases) and Mg2+ or Mn2+, known specific activators of the various kinases present in the red cell membrane. The anion channel protein was isolated to purity and the phosphorylated aminoacids were determined. The present results show that the phosphorylation of anion channel protein in its membraneous environment leads to an equal phosphorylation of tyrosine and serine plus threonine in the presence of Mg2+. In contrast, phosphotyrosine represents 80% of the total when Mn2+ is the activator.     

Anion transport across the red blood cell membrane and the protein in band 3.

The paper reviews existing evidence for the participation of the protein in band 3 (nomenclature of Steck, [1]) in anion transport across the red cell membrane and discusses the possible role of common binding sites on band 3 for 1-fluoro-2,4-dinitrobenzene, 2-(4'-aminophenyl)-6-methylbenzenethiazol-3',7-disulfonic acid and dihydro 4,4'-diisothiocyanato stilbene-2,2'-disulfonic acid in the transport process.     

Binding of rabbit muscle aldolase to band 3, the predominant polypeptide of the human erythrocyte membrane.

Aldolase is a trace protein in isolated human red cell membrane preparations. Following total elution of the endogenous enzyme by a saline wash, the interaction of this membrane with rabbit muscle aldolase was studied. At saturation, exogenous aldolase constituted over 40% of the repleted membrane protein. Scatchard analysis revealed two classes of sites, each numbering approximately 7 X 10(5) per ghost. Specificity was suggested by the exclusive binding of the enzyme to the membrane's inner (cytoplasmic) surface. Furthermore, milimolar levels of fructose 1,6-bisphosphate eluted the enzyme from ghosts, while fructose 6-phosphate and NADH (a metabolite which elutes human erythrocyte glyceraldehyde-3-phosphate dehydrogenase (G3PD) from its binding site) were ineffectuve. Removing peripheral membrane proteins with EDTA and lithium 3,5-diiodosalicylate did not diminish the binding capacity of the membranes. An aldolase-band 3 complex, dissociable by high ionic strength or fructose 1,6-bisphosphate treatment, was demonstrated in Triton X-100 extracts of repleted membranes by rate zonal sedimentation analysis on sucrose gradients. We conclude that the association of rabbit muscle aldolase with isolated human erythrocyte membranes reflects its specific binding to band 3 at the cytoplasmic surface, as is also true of G3PD.     

Proteolysis of band 3 is enhanced by anti-Rho(D) binding to the red cell membrane

Surface radioiodinated human red cells were incubated with IgG fractions and the radioelectrophoretic profile of the ghost membranes determined. The patterns of RhO(D)-negative membranes exposed to anti-RhO(D) IgG and RhO(D)-positive membranes exposed to non-immune IgG fractions remained intact. Membranes of RhO(D)-positive membranes following incubation with anti-RhO(D) IgG showed a sharp reduction in the quantity of intact band 3, the main glycoprotein of the red cell membrane. This process was significantly abrogated in the presence of protease inhibitors. The results suggest a possible role for IgG binding in promoting the generation of band 3-derived fragments described by others as normal constituents of isolated ghosts.     

Modulation of red cell glycolysis: interactions between vertebrate hemoglobins and cytoplasmic domains of band 3 red cell membrane proteins

Several vital functions/physical characteristics of erythrocytes (including glycolysis, the pentose phosphate pathway, ion fluxes, and cellular deformability) display dependence on the state of hemoglobin oxygenation. The molecular mechanism proposed involves an interaction between deoxyhemoglobin and the cytoplasmic domain of the anion-exchange protein, band 3 (cdB3). Given that band 3 also binds to membrane proteins 4.1 and 4.2, several kinases, hemichromes, and integral membrane proteins, and at least three glycolytic enzymes, it has been suggested that the cdB3-deoxyhemoglobin interaction might modulate the pathways mediated by these associated proteins in an O(2)-dependent manner. We have investigated this mechanism by synthesizing 10-mer peptides corresponding to the NH(2)-terminal fragments of various vertebrate cdB3s, determining their effects on the oxygenation reactions of hemoglobins from the same and different species and examining binding of the glycolytic enzyme glyceraldehyde-3-phosphate dehydrogenase to the erythrocytic membrane of mouse erythrocytes. The cdB3 interaction is strongly dependent on pH and the number of negative and positive charges of the peptide and at the effector binding site, respectively. It lowers the O(2) association equilibrium constant of the deoxygenated (Tense) state of the hemoglobin and is inhibited by magnesium ions, which neutralize cdB3's charge and by 2,3-diphosphoglycerate, which competes for the cdB3-binding site. The interaction is stronger in humans (whose erythrocytes derive energy predominantly from glycolysis and exhibit higher buffering capacity) than in birds and ectothermic vertebrates (whose erythrocytes metabolize aerobically and are poorly buffered) and is insignificant in fish, suggesting that its role in the regulation of red cell glycolysis increased with phylogenetic development in vertebrates.     

Fine structure of the band 3 protein in human red cell membranes: Freeze-fracture studies

The major red cell membrane protein, band 3, is a glycoprotein which extends across the membrane from the extracellular space into the cytoplasmic compartment. It is widely held that band 3 is a component of the intramembrane particles (IMP) which can be demonstrated by freeze-fracture electron microscopy. In this study, we find that the outer surface poles of the IMP can be seen by freeze-etching after they are unmasked by proteolysis under conditions which excise the surrounding sialopeptides from the membrane. The poles appear as distinctive projections, 30–50 Å in diameter, the “ES particles.” The ES particles remain associated with the outer surface of the membrane following cleavage of the band 3 polypeptide by chymotrypsin or pronase. This is consistent with previous biochemical studies which have shown that the 38,000-dalton outer surface segment of band 3 is intercalated in the lipid bilayer. A granulofibrillar component at the inner surface of the membrane is provisonally identified as the 40,000-dalton inner-surface domain of band 3.     

Chronic myelogenous leukemia: alterations in red cell membrane band 3 and increased IgG binding

Chronic myelogenous leukemia (CML) is a hematologic malignancy arising from an abnormal hemopoietic stem cell. Our earlier studies have identified defects in spectrin tetramer formation and organization of cytoskeletal proteins (Basu et al., Biochim. Biophys. Acta 1988, 121-126); and decreased ankyrin binding to ankyrin-depleted vesicles in CML patients. These may lead to clustering of band 3 and increased binding of autologous IgG. This has now been explored by studying the binding of 125I-protein A to normal and CML erythrocytes. There is increased binding of 125I-protein A in CML erythrocytes compared to normal erythrocytes. Since binding of autologous IgG is responsible for removal of erythrocytes from the circulation, the above findings suggest that CML erythrocytes are likely to be prematurely removed from the circulation, accounting for anemia.     

Water-soluble proteins of the human red cell membrane

Summary Procedures were developed for preparation of red cell membranes almost free of hemoglobin but with minimal loss of membrane proteins. Two water-soluble protein fractions are described, each constituting about 25% of the ghost protein. The first is ionically bonded and can be solubilized in water rapidly at pH 7.0 and more slowly at higher ionic strength solutions, with a minimal rate at 20mm. This fraction contains four major components with molecular weights ranging from 30,000 to 48,000. The second fraction can only be solubilized at an appreciable rate if Ca⁺⁺ is absent and at higher pH (9.0). It is predominantly a single molecular weight component (150,000). It tends to aggregate at higher ionic strength and in the presence of Ca⁺⁺. Evidence is presented suggesting that the water-soluble proteins are present at the inner face of the membrane. The lipids remain in a water-insoluble residue that contains four major protein components ranging in molecular weight from 30,000 to 100,000. The latter is the predominant component. Only the residue contains the Na⁺–K⁺-activated ATPase, the cholinesterase, antigenic activity and most of the sialic acid and carbohydrate. The first water-soluble fraction contains a Mg⁺⁺-activated ATPase. The extraction of the water-soluble proteins is accompanied by anatomical changes resulting finally in the formation of small membranous vesicles.     

Relation between red cell membrane (Na + K)-ATPase and band 3 protein

This study is designed to examine the participation of the major red cell membrane protein, band 3 protein, in the chain which transmits information from the cardiac glycoside site on the external face of the cell (Na⁺ + K⁺)-ATPase to the megadalton glycolytic enzyme complex within the cell. The experiments show that the anion transport inhibitor, 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, affects the resonance of 2,3-diphosphoglycerate, as does the cardiac glycoside cation transport inhibitor, ouabain. Resonance shifts induced by the cardiac glycoside alone are modulated by addition of the anion transport inhibitor which indicates that there is coupling in the red cell between the (Na⁺ + K⁺)-ATPase and band 3 protein. Band 3 protein was separated from the membrane and partially purified following the technique of Yu and Steck ((1975) J. Biol. Chem. 250, 9170–9175). When glyceraldehyde-3-phosphate dehydrogenase was added to the separated band 3 protein preparation, addition of cardiac glycosides caused shifts in the ³¹P resonance of glyceraldehyde 3-phosphate. These experiments indicate that there is coupling between the (Na⁺ + K⁺)-ATPase and band 3 protein in the separated preparation and suggest that the anion and cation transport systems may be closely related spatially and functionally in the intact red cell.     

Properties of a membrane-bound tyrosine kinase phosphorylating the cytosolic fragment of the red cell membrane band 3 protein

Band 3 protein of human erythrocyte membrane is phosphorylated on a tyrosine residue located near the NH2 terminal by an endogenous tyrosine kinase activity (Dekowski, S., Rybicki, A. and Drickamer, K. (1983) J. Biol. Chem. 258, 2750-2753). A tyrosine kinase phosphorylating the band 3 protein in situ has been extracted from ghosts by non-ionic detergent and partially characterized (Phan-Dinh-Tuy, F., Henry, J. and Kahn, A. (1985) Biochem. Biophys. Res. Commun. 126, 304-312). We have studied the properties of the tyrosine kinase activity which remains bound to the ghosts after detergent extraction using the 43 kDa fragment of protein 3 as substrate. This activity, solubilized from the detergent-resistant material at 0.25 M NaCl and concentrated by phosphocellulose and tyrosine-agarose chromatographies, remains linked to high molecular weight complexes. It is specific for tyrosine. Assayed with the purified 43 kDa fragment it requires the presence of Mn2+ which cannot be replaced by Mg2+. Its affinity for 43 kDa fragment is very high with a Km of 3.3 microM. ATP acts as a phosphoryl donor with a Km of 0.55 microM. The tyrosine kinase activity was not modified by insulin, DMSO, phorbol ester and epidermal growth factor, vanadate and xanthine derivatives. Polyamines spermidine and the polylysine are inhibitors in the presence of Mn2+ but not in the presence of Mg2+. Heparin is a competitive inhibitor of ATP. 2,3-Diphosphoglycerate is an inhibitor at physiological concentrations (Ki = 2 mM). Purified red cell actin is not phosphorylated by the tyrosine kinase. These properties distinguish the red cell membrane-bound tyrosine kinase from other tyrosine kinases extracted from normal cells.     

Plasmodium falciparum histidine-rich protein 1 associates with the band 3 binding domain of ankyrin in the infected red cell membrane

Infection of erythrocytes by the malaria parasite Plasmodium falciparum results in the export of several parasite proteins into the erythrocyte cytoplasm. Changes occur in the infected erythrocyte due to altered phosphorylation of proteins and to novel interactions between host and parasite proteins, particularly at the membrane skeleton. In erythrocytes, the spectrin based red cell membrane skeleton is linked to the erythrocyte plasma membrane through interactions of ankyrin with spectrin and band 3. Here we report an association between the P. falciparum histidine-rich protein (PfHRP1) and phosphorylated proteolytic fragments of red cell ankyrin. Immunochemical, biochemical and biophysical studies indicate that the 89 kDa band 3 binding domain and the 62 kDa spectrin-binding domain of ankyrin are co-precipitated by mAb 89 against PfHRP1, and that native and recombinant ankyrin fragments bind to the 5' repeat region of PfHRP1. PfHRP1 is responsible for anchoring the parasite cytoadherence ligand to the erythrocyte membrane skeleton, and this additional interaction with ankyrin would strengthen the ability of PfEMP1 to resist shear stress.     

Kinetics and regulation of the ankyrin-band 3 interaction of the human red blood cell membrane

In an attempt to identify potential regulatory mechanisms for erythrocyte membrane-cytoskeletal interactions, the kinetics and pH dependence of the band 3-ankyrin interaction were investigated. Association of 125I-ankyrin with KI-stripped inside-out erythrocyte membrane vesicles was found to proceed in two kinetic phases. The initial, fast phase (t1/2 approximately 15-30 min) involved predominantly the binding of ankyrin to low affinity sites (KD approximately 130 nM) in a pH-dependent manner. The apparent pKa values describing this reversible pH dependence (7.2 +/- 0.1 and 9.2 +/- 0.1) defined states of band 3 with high, moderate, and no capacity to bind ankyrin (in order of increasing pH). Since the cytoplasmic domain of band 3 also exists in 3 distinct conformational states characterized by apparent pKa values of 7.2 and 9.2, it was hypothesized that the reversible structural equilibrium in band 3 could influence ankyrin binding. The second or slow phase of ankyrin binding to band 3 involved the conversion of low to high affinity sites (KD approximately 13 nM). This phase, which was largely temperature and pH independent, required roughly an order of magnitude longer to reach completion than the fast phase. Unfortunately, even though the slow phase could be cleanly separated from the fast phase at low pH, insufficient data were available to formulate a physical interpretation of its origin. Significantly, however, even after completion of the slow phase under the most quantitative binding conditions identified, a maximum of only 26% of the band 3 was found to bind ankyrin in situ. Although higher ankyrin-band 3 stoichiometries may be achievable with the isolated cytoplasmic fragment of band 3, we interpret the above 1:4 stoichiometry to suggest that the tetramer of band 3 constitutes the predominant ankyrin binding oligomer of band 3 on the membrane.     

Study of actin filament ends in the human red cell membrane

There is conflicting evidence concerning the state of the actin protofilaments in the membrane cytoskeleton of the human red cell. To resolve this uncertainty, we have analysed their characteristics with respect to nucleation of G-actin polymerization. The effects of cytochalasin E on the rate of elongation of the protofilaments have been measured in a medium containing 0.1 M-sodium chloride and 5 mM-magnesium chloride, using pyrene-labelled G-actin. At an initial monomer concentration far above the critical concentration for the negative (pointed) end of F-actin, high concentrations of cytochalasin reduce the elongation rate of free F-actin by about 70%. The residual rate is presumed to correspond to the elongation rate at the negative ends. By contrast, the elongation rate on red cell ghosts or cytoskeletons falls to zero, allowing for the background of self-nucleated polymerization of the G-actin. The critical concentration of the actin in the red cell membrane has been measured after elongation of the filaments by added pyrenyl-G-actin in the same solvent. It was found to be 0.07 microM, compared with 0.11 microM under the same conditions for actin alone. This is consistent with prediction for the case of blocked negative ends on the red cell actin. The rate of elongation of actin filaments, free and in the red cell membrane cytoskeleton, has been measured as a function of the concentration of an added actin-capping protein, plasma gelsolin, with a high affinity for the positive ends. The elongation rate falls linearly with increasing gelsolin concentration until it approaches a minimum when the gelsolin has bound to all positive filament ends. The elongation rate at this point corresponds to the activity of the negative ends, and its ratio to the unperturbed polymerization rate (in the absence of capping proteins) is indistinguishable from zero in the case of ghosts, but about 1 : 4 in the case of F-actin. When ATP is replaced in the system by ADP, so that the critical concentrations at the two filament ends are equalized, the difference is equally well-marked: for F-actin, the rate at the equivalence point is about 40% of that in the absence of capping protein, whereas for ghosts the nucleated polymerization rate at the equivalence point is again zero, indicating that under these conditions the negative ends contribute little or not at all to the rate of elongation.(ABSTRACT TRUNCATED AT 400 WORDS)