Chemical modification and labeling of glutamate residues at the stilbenedisulfonate site of human red blood cell band 3 protein

A new method has been developed for the chemical modification and labeling of carboxyl groups in proteins. Carboxyl groups are activated with Woodward's reagent K (N-ethyl-5-phenylisoxazolium 3'-sulfonate), and the adducts are reduced with [3H]BH4. The method has been applied to the anion transport protein of the human red blood cell (band 3). Woodward's reagent K is a reasonably potent inhibitor of band 3-mediated anion transport; a 5-min exposure of intact cells to 2 mM reagent at pH 6.5 produces 80% inhibition of transport. The inhibition is a consequence of modification of residues that can be protected by 4,4'-dinitrostilbene-2,2'-disulfonate. Treatment of intact cells with Woodward's reagent K followed by B3H4 causes extensive labeling of band 3, with minimal labeling of intracellular proteins such as spectrin. Proteolytic digestion of the labeled protein reveals that both the 60- and the 35-kDa chymotryptic fragments are labeled and that the labeling of each is inhibitable by stilbenedisulfonate. If the reduction is performed at neutral pH the major labeled product is the primary alcohol corresponding to the original carboxylic acid. Liquid chromatography of acid hydrolysates of labeled affinity-purified band 3 shows that glutamate but not aspartate residues have been converted into the hydroxyl derivative. This is the first demonstration of the conversion of a glutamate carboxyl group to an alcohol in a protein. The labeling experiments reveal that there are two glutamate residues that are sufficiently close to the stilbenedisulfonate site for their labeling to be blocked by 4,4'-diisothiocyanodihydrostilbene-2,2'-disulfonate and 4,4'-dinitrostilbene-2,2'-disulfonate.     

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.     

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 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.     

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.     

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.     

Inhibition of anion transport associated with chymotryptic cleavages of red blood cell band 3 protein

Right-side-out vesicles derived from red blood cells treated with chymotrypsin retain specific anion transport function (defined as transport sensitive to the specific inhibitor, 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS)), even though the transport protein, band 3, is cleaved into two segments of 60 and 35 kdaltons. In contrast, vesicles derived from alkali-stripped ghosts treated with relatively high concentrations of chymotrypsin retain almost no specific anion function. The loss of function appears to be related to additional cleavages of band 3 protein that occur in treated ghosts, the 60-kdalton segment being reduced first to a 17- and then to a 15-kdalton segment and the 35-kdalton segment being reduced to a 9-kdalton segment plus a carbohydrate containing fragment. The chymotryptic cleavages of band 3 protein of ghosts are preferentially inhibited by high ionic strength, the production of the 9-kdalton segment being somewhat slower than that of the 15-kdalton segment. Vesicles derived from ghosts treated with chymotrypsin at different ionic strengths show a graded reduction in specific anion transport activity, but it was not possible to determine, definitively, which of the additional cleavages was inhibitory. In the light of these data and other information, the functional role of the segments of band 3 is discussed.     

Binding of DTNB to band 3 in the human red cell membrane

Inhibition of red cell water transport by the sulfhydryl reagent 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) has been reported by Naccache and Sha'afi ((1974) J. Cell Physiol. 84, 449-456) but other investigators have not been able to confirm this observation. Brown et al. ((1975) Nature 254, 523-525) have shown that, under appropriate conditions, DTNB binds only to band 3 in the red cell membrane. We have made a detailed investigation of DTNB binding to red cell membranes that had been treated with the sulfhydryl reagent N-ethylmaleimide (NEM), and our results confirm the observation of Brown et al. Since this covalent binding site does not react with either N-ethylmaleimide or the sulfhydryl reagent pCMBS (p-chloromercuribenzenesulfonate), its presence has not previously been reported. This covalent site does not inhibit water transport nor does it affect any transport process we have studied. There is an additional low-affinity (non-covalent) DTNB site that Reithmeier ((1983) Biochim. Biophys. Acta 732, 122-125) has shown to inhibit anion transport. In N-ethylmaleimide-treated red cells, we have found that this binding site inhibits water transport and that the inhibition can be partially reversed by the specific stilbene anion exchange transport inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS), thus linking water transport to anion exchange. DTNB binding to this low-affinity site also inhibits ethylene glycol and methyl urea transport with the same KI as that for water inhibition, thus linking these transport systems to that for water and anions. These results support the view that band 3 is a principal constituent of the red cell aqueous channel, through which urea and ethylene glycol also enter the cell.     

Inhibition of cation cotransport by cholesterol enrichment of human red cell membranes.

1. Human red cells were enriched with cholesterol by incubation with lipid dispersions having a high cholesterol: phospholipid mol ratio and the kinetics of the furosemide-sensitive cotransport for Na+ and K+ were measured. 2. Influxes of both K+ and Na+ through this system were inhibited by 70 and 76% in cholesterol-rich cells (cholesterol: phospholipid mol ratio 1.80) and the Km of the furosemide-sensitive flux components for both K+ and Na+ decreased. 3. Effluxes of both K+ and Na+ are inhibited by furosemide and the magnitudes of these furosemide-sensitive components are markedly decreased in cholesterol-rich cells. 4. The inhibitory effect of cholesterol enrichment on this carrier-mediated transport of cations suggests that cholesterol may either alter the position of the carrier or retard its movement within a more viscous membrane micro-environment.     

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.     

Sodium-phosphate cotransport in human red blood cells. Kinetics and role in membrane metabolism

Orthophosphate (Pi) uptake was examined in human red blood cells at 37 degrees C in media containing physiological concentrations of Pi (1.0- 1.5 mM). Cells were shown to transport Pi by a 4,4'-dinitro stilbene- 2,2'-disulfonate (DNDS) -sensitive pathway (75%), a newly discovered sodium-phosphate (Na/Pi) cotransport pathway (20%), and a pathway linearly dependent on an extracellular phosphate concentration of up to 2.0 mM (5%). Kinetic evaluation of the Na/Pi cotransport pathway determined the K1/2 for activation by extracellular Pi ([Na]o = 140 mM) and extracellular Na [( Pi]o = 1.0 mM) to be 304 +/- 24 microM and 139 +/- 8 mM, respectively. The phosphate influx via the cotransport pathway exhibited a Vmax of 0.63 +/- 0.05 mmol Pi (kg Hb)-1(h)-1 at 140 mM Nao. Activation of Pi uptake by Nao gave Hill coefficients that came close to a value of 1.0. The Vmax of the Na/Pi cotransport varied threefold over the examined pH range (6.90-7.75); however, the Na/Pi stoichiometry of 1.73 +/- 0.15 was constant. The membrane transport inhibitors ouabain, bumetanide, and arsenate had no effect on the magnitude of the Na/Pi cotransport pathway. No difference was found between the rate of incorporation of extracellular Pi into cytosolic orthophosphate and the rate of incorporation into cytosolic nucleotide phosphates, but the rate of incorporation into other cytosolic organic phosphates was significantly slower. Depletion of intracellular total phosphorus inhibited the incorporation of extracellular Pi into the cytosolic nucleotide compartment; and this inhibition was not reversed by repletion of phosphorus to 75% of control levels. Extracellular 32Pi labeled the membrane-associated compounds that migrate on thin-layer chromatography (TLC) with the Rf values of ATP and ADP, but not those of 2,3-bisphosphoglycerate (2,3-DPG), AMP, or Pi. DNDS had no effect on the level of extracellular phosphate incorporation or on the TLC distribution of Pi in the membrane; however, substitution of extracellular sodium with N-methyl-D-glucamine inhibited phosphorylation of the membranes by 90% and markedly altered the chromatographic pattern of the membrane-associated phosphate.(ABSTRACT TRUNCATED AT 400 WORDS)     

A monoclonal antibody monitoring band 3 modifications in human red blood cells

Morphologic and methabolic erythrocyte modifications are thought to be the basis of cell removal from circulating blood. A significant role has been ascribed to the immunological network which may remove aged or misshapen erythrocytes through the binding of specific autoantibodies. Along this line recent observations indicate that a senescence antigen appears in consequence of postsynthetic modifications of band 3, one of the most important erythrocyte membrane proteins, which accounts for many functional activities of the red cells. On this basis, we raised a mouse hybridoma anti-band 3 monoclonal antibody (B6 MoAb) of the IgG2a class which monitors band 3 differences among normal red blood cells separated by Percoll density gradient. These differences are outlined by the decrease of B6 MoAb binding to band 3 monomer, the appearance of an 80–90 kDa new band, lighter than band 3, and the increase of low molecular weight fragments in the 4.5 region. The B6 MoAb appears to be very useful in detecting modifications of band 3 since it bind to a 19 kDa Chy-Try fragment estimated to be sensitive to aging.Abbreviations PBS Phosphate Buffer Saline - MoAb Monoclonal Antibody - RBCs Red Blood Cells - PMSF Phenylmethylsulphonyl Fluoride - PVC Polyvinyl Chloride - ACD Acid Citrate Dextrose - HMWP High Molecular Weight Polymers - Chy-Try Chymotrypsin-Trypsin Digested - i.p. intraperitoneum - ELISA Enzyme Linked Immuno Sorbent Assay - Hepes 4-(2-Hydroxyethyl)-piperazine-1-ethane-sulfonic acid. Enzymes: trypsin (EC 3.4.21.4), chymotrypsin (EC 3.4.21.1), neuraminidase (EC 3.2.1.18)     

The red cell band 3 protein: its role in anion transport

Studies of anion transport across the red blood cell membrane fall generally into two categories: (1) those concerned with the operational characterization of the transport system, largely by kinetic analysis and inhibitor studies; and (2) those concerned with the structure of band 3, a transmembrane peptide identified as the transport protein. The kinetics are consistent with a ping-pong model in which positively charged anion-binding sites can alternate between exposure to the inside and outside compartments but can only shift one position to the other when occupied by an anion. The structural studies on band 3 indicate that only 60% of the peptide is essential for transport. That particular portion is in the form of a dimer consisting of an assembly of membrane-crossing strands (each monomer appears to cross at least five times). The assembly presents its hydrophobic residues toward the interior of the bilayer, but its hydrophilic residues provide an aqueous core. The transport involves a small conformational change in which an anion-binding site (involving positively charged residues) can alternate between positions that are topologically in and topologically out.     

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.     

The location of a disulfonic stilbene binding site in band 3, the anion transport protein of the red blood cell membrane

The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, a specific, potent, irreversible inhibitor of anion transport in red blood cells is located in a 15 000 dalton transmembrane segment of band 3, produced by chymotrypsin treatment of ghosts stripped of extrinsic proteins. The segment was cleaved into three fragments of 7000, 4000 and 4000 daltons by CNBr. The C-terminus of the segment is located in the 7000 dalton fragment; the N-terminus in one of the 4000 dalton fragments; and the binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid in the middle 4000 dalton fragment. The latter was cleaved by $\text{N-}\text{bromosuccinimide}$ into two fragments of 2000 daltons. The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid was located on the fragment containing the newly formed N-terminus. It is concluded that the binding site is located about 9000 daltons from the C-terminus (at the outside face of the membrane) and 6000 daltons from the N-terminus (at the cytoplasmic face). In view of the existing evidence that the binding site may be located near the outside face of the membrane, it is suggested that the 15 000 dalton segment is folded, so that it crosses the bilayer three times.     

Inhibition of anion transport in the red blood cell by anionic amphiphilic compounds II. Chemical properties of the flufenamate-binding site on the band 3 protein

Flufenamate is a powerful inhibitor of anion exchange in red blood cells. It binds to the band 3 protein involved in the transport as discussed in the preceding paper (Cousin, J.-L. and Motais, R. (1982) Biochim. Biophys. Acta 687, 147–155). The present study is concerned with the chemical properties of the inhibitory binding site. Structure-activity studies were performed with two sets of compounds derivated from anthranilate (considered as the basic structure of flufenamate). The molar concentrations required to produce 50% inhibition ($\text{I}{}_{50}$) varied over more than a 10⁴ range. The inhibitory activity was quantitatively correlated with the hydrophobic character of the molecules and the electron-withdrawing capacity of the substituents. Comparison between the inhibitory potency of flufenamate analogs made a definition of the contribution of each part of the molecule in the binding to the receptor possible. The results suggest that anionic inhibitors bind to a site which presents a positively charged groups at the water-protein interface whereas the hydrophobic part of the molecule is inserted into an hydrophobic and electron-donor region of the protein. The specificity of amphiphilic compounds towards anion transport is discussed.     

Inhibition of inorganic anion transport across the human red blood cell membrane by chloride-dependent association of dipyridamole with a stilbene disulfonate binding site on the band 3 protein

The inhibition of inorganic anion transport by dipyridamole (2,6-bis(diethanolamino)-4,8-dipiperidinopyrimido[5,4-d] pyrimidine) takes place only in the presence of Cl-, other halides, nitrate or bicarbonate. At any given dipyridamole concentration, the anion flux relative to the flux in the absence of dipyridamole follows the equation: Jrel = (1 + alpha 2[Cl-])/(1 + alpha 4[Cl-]) where alpha 2 and alpha 4 are independent of [Cl-] but dependent on dipyridamole concentration. At high [Cl-] the flux approaches alpha 2/alpha 4, which decreases with increasing dipyridamole concentration. Even when both [Cl-] and dipyridamole concentration assume large values, a small residual flux remains. The equation can be deduced on the assumption that Cl- binding allosterically increases the affinity for dipyridamole binding to band 3 and that the bound dipyridamole produces a non-competitive inhibition of sulfate transport. The mass-law constants for the binding of Cl- and dipyridamole to their respective-binding sites are about 24 mM and 1.5 microM, respectively (pH 6.9, 26 degrees C). Dipyridamole binding leads to a displacement of 4,4'-dibenzoylstilbene-2,2'-disulfonate (DBDS) from the stilbenedisulfonate binding site of band 3. The effect can be predicted quantitatively on the assumption that the Cl- -promoted dipyridamole binding leads to a competitive replacement of the stilbenedisulfonates. For the calculations, the same mass-law constants for binding of Cl- and dipyridamole can be used that were derived from the kinetic studies on Cl- -promoted anion transport inhibition. The newly described Cl- binding site is highly selective with respect to Cl- and other monovalent anion species. There is little competition with SO4(2-), indicating that Cl- binding involves other than purely electrostative forces. The affinity of the binding site to Cl- does not change over the pH range 6.0-7.5. Dipyridamole binds only in its deprotonated state. Binding of the deprotonated dipyridamole is pH-independent over the same range as Cl- binding.     

Membrane rafts of the human red blood cell

The cell type of election for the study of cell membranes, the mammalian non-nucleated erythrocyte, has been scarcely considered in the research of membrane rafts of the plasma membrane. However, detergent-resistant-membranes (DRM) were actually first described in human erythrocytes, as a fraction resisting solubilization by the nonionic detergent Triton X-100. These DRMs were insoluble entities of high density, easily pelleted by centrifugation, as opposed to the now accepted concept of lipid raft-like membrane fractions as material floating in low-density regions of sucrose gradients. The present article reviews the available literature on membrane rafts/DRMs in human erythrocytes from an historical point of view, describing the experiments that provided the solution to the above described discrepancy and suggesting possible avenue of research in the field of membrane rafts that, moving from the most studied model of living cell membrane, the erythrocyte’s, could be relevant also for other cell types.