Anion exchange in human erythrocytes has a large activation volume

Cell Physiology and Molecular Mechanism of Anion Transport by Erythrocyte Band 3/AE1

The major transmembrane protein of the red blood cell, known as band 3, AE1, and SLC4A1, has two main functions: 1) catalysis of Cl^-/HCO₃^- exchange, one of the steps in CO₂ excretion; 2) anchoring the membrane skeleton. This review summarizes the 150 year history of research on red cell anion transport and band 3 as an experimental system for studying membrane protein structure and ion transport mechanisms. Important early findings were that red cell Cl^- transport is a tightly coupled 1:1 exchange and band 3 is labeled by stilbenesulfonate derivatives that inhibit anion transport. Biochemical studies showed that the protein is dimeric or tetrameric (paired dimers) and that there is one stilbenedisulfonate binding site per subunit of the dimer. Transport kinetics and inhibitor characteristics supported the idea that the transporter acts by an alternating access mechanism with intrinsic asymmetry. The sequence of band 3 cDNA provided a framework for detailed study of protein topology and amino acid residues important for transport. The identification of genetic variants produced insights into the roles of band 3 in red cell abnormalities and distal renal tubular acidosis. The publication of the membrane domain crystal structure made it possible to propose concrete molecular models of transport. Future research directions include improving our understanding of the transport mechanism at the molecular level and of the integrative relationships among band 3, hemoglobin, carbonic anhydrase, and gradients (both transmembrane and subcellular) of HCO₃^-, Cl^-, O₂, CO₂, pH, and NO metabolites during pulmonary and systemic capillary gas exchange.

The substrate anion selectivity filter in the human erythrocyte Cl-/HCO3- exchange protein, AE1

AE1 facilitates Cl-/HCO3- exchange across the erythrocyte membrane. To identify residues involved in substrate selection and translocation, we prepared an array of single cysteine mutants in an otherwise cysteineless background. These mutants spanning the C-terminal portion of the AE1 membrane domain from Phe806-Cys885 were characterized for functional activity when expressed in human embryonic kidney 293 cells by measurement of changes of intracellular pH associated with bicarbonate transport. To identify residues involved in substrate translocation, transport activity was assessed for each mutant before and after treatment with the following sulfhydryl reagents: anionic para-chloromercuibenzenesulfonate; permeant (2-aminoethyl)methanethiosulfonate; and cationic [2-(trimethylammonium)ethyl]methanethiosulfonate (MTSET). Among the 80 mutants, only certain key residues in the Val849-Leu863 region were inhibited by the sulfhydryl reagent, consistent with direct involvement of these sites in anion transport. In the last two transmembrane segments, only mutants in the extracellular portion of the transmembrane segments could be inhibited by sulfhydryl reagent, suggesting that the outer portions line the translocation channel and the inner portions have some other role. Sensitivity to cationic MTSET and effects of Cl- identified the substrate charge filter as Ser852-Leu857.

Temperature dependence of the exchange of monovalent anions in human red blood cells

The temperature dependence of anion exchange across the red cell membrane was studied between 5 degrees C and 55 degrees C by measuring the rate of shrinkage of cells when transferred from a medium of pH 7.6 to one of pH 9.3 (as measured at 22 degrees C). The rates of shrinkage varied with the anion studied, the order being F-> Cl-> Br-> I-> SCN- but were faster in the presence of trace amounts of carbon dioxide than in its absence. NO3- was as fast as Cl- when carbon dioxide was present but comparable with I- when it was removed. Arrhenius plots of the rates were linear for all anions over the temperature range studied and gave the following apparent activation energies in kJ mol-1; F-, 67.7; NO3-, 68.4; Cl-, 70.2; Br-, 79.6; SCN-, 87.4 and I-, 95.1 in the presence of carbon dioxide. Inhibition of carbonic anhydrase with 5 microns ethoxzolamide and the removal of the carbon dioxide by degassing raised the activation energies to; F-, 124.8; NO3-, 129.0; Cl-, 141.5: Br-, 159.4; SCN-, 150.0 and I-, 185.6 kJ. mol-1. With the exception of F-, the apparent activation energies of the anions were linearly related to their thermochemical (dehydrated) radii in both cases. The relationship between the ionic radii and the energy of transfer suggests that anion exchange involves transfer through a hydrophobic pathway and that additional energy is required to overcome restrictions experienced in passing through the pathway. It is proposed that this, rather than a conformational change in the protein determines the activation energy of the process.

Inhibition of mouse erythroid band 3-mediated chloride transport by site-directed mutagenesis of histidine residues and its reversal by second site mutation of Lys 558, the locus of covalent H2DIDS binding

Substitution by site-directed mutagenesis of any one of the histidine residues H721, H837, and H852 by glutamine, or of H752 by serine, inhibits Cl- flux mediated by band 3 expressed in Xenopus oocytes. Mutation of Lys 558 (K558N), the site of covalent binding of H2DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonate) in the outer membrane surface, in combination with any one of the His/Gln mutations leads to partial (H721Q; H837Q) or complete (H852Q) restoration of Cl- flux. In contrast, inhibition of Cl- flux by mutation of proline or lysine residues in the vicinity of His 837 at the inner membrane surface cannot be reversed by the second-site mutation K558N, indicating specificity of interaction between Lys 558 and His 837. The histidine-specific reagent diethyl pyrocarbonate (DEPC) is known to inhibit band 3-mediated anion exchange in red blood cells [Izuhara, K., Okubo, K., & Hamasaki, N. (1989) Biochemistry 28, 4725-4728]. It was also found to inhibit transport after expression in the oocyte of wild-type band 3, of the double mutants of the histidines listed above, and of the single mutant H752S. The effects on the wild type and the double mutants were indistinguishable, while the mutant H752S exhibited a considerably reduced sensitivity to inhibition, suggesting that His 752 is the most prominent site of action of DEPC. According to a hydrophobicity plot of band 3 and further independent evidence, Lys 558, the mutated histidines, and Glu 699, the mutation of which was also found to inhibit Cl- flux [Müller-Berger, S., Karbach, D., Kang, D., Aranibar, N., Wood, P. G., Rüterjans, H., & Passow, H. (1995) Biochemistry 34, 9325-9332], are most likely located in five different transmembrane helices. The interactions between Lys 558 and the various histidines suggest that these helices reside in close proximity. Together with the helix carrying Glu 699, they could form an access channel lined with an array of alternating histidine and glutamate residues. Together with a chloride ion bridging the gap between His 852 and His 837, they could have the potential to form, at low pH, a transmembrane chain of hydrogen bonds. The possible functional significance of such channel is discussed.

Molecular mechanisms for passive and active transport of water

Water crosses cell membranes by passive transport and by secondary active cotransport along with ions. While the first concept is well established, the second is new. The two modes of transport allow cellular H2O homeostasis to be viewed as a balance between H2O leaks and H2O pumps. Consequently, cells can be hyperosmolar relative to their surroundings during steady states. Under physiological conditions, cells from leaky epithelia may be hyperosmolar by roughly 5 mosm liter-1, under dilute conditions, hyperosmolarities up to 40 mosm liter-1 have been recorded. Most intracellular H2O is free to serve as solvent for small inorganic ions. The mechanism of transport across the membrane depends on how H2O interacts with the proteinaceous or lipoid pathways. Osmotic transport of H2O through specific H2O channels such as CHIP 28 is hydraulic if the pore is impermeable to the solute and diffusive if the pore is permeable. Cotransport of ions and H2O can be a result of conformational changes in proteins, which in addition to ion transport also translocate H2O bound to or occlude in the protein. A cellular model of a leaky epithelium based on H2O leaks and H2O pumps quantitatively predicts a number of so-far unexplained observations of H2O transport.

Structural determinants of substrate specificity of the erythrocyte anion transporter

The human erythrocyte anion transport protein (AE1) mediates the rapid, tightly coupled, electroneutral transmembrane exchange of bicarbonate for chloride. AE1 transports a wide range of oxyanions, such as phosphate, sulfate and the physiological substrate bicarbonate. In this study, the transport characteristics of the selenium based oxyanions selenite (SeO3(2-)) and selenate (SeO4(2-)) were determined. The pH dependence of selenate influx was consistent with a titratable carrier having a extracellular pK value of 5.67 +2- 0.09. In contrast, the pH dependence of selenite influx had a maximum near pH 7.0, consistent with a hypothesis proposed by Labotka and Omachi (J. Biol. Chem. 263: 1166-1173, 1988) that the pH maximum of the transport of titratable anions is located at the midpoint between the pK of the carrier (5.7) and the pK of the titratable anion (8.3). Analysis of the transport rates and structures of these as well as a variety of other oxyanions reported in the literature suggested that oxyanions bind in a three-oxygen atom binding site, and that the formation of the transition state necessary for transport is sterically restrained by oxyanions that protrude in a direction perpendicular to the three-oxygen binding plane. This hypothesis can be used to predict the relationship between the transport rates of many oxyanions reported in the literature and should prove useful in helping to understand the molecular mechanism of AE1 mediated transport.

Effects of pressure on glucose transport in human erythrocytes

The operation of the human red cell glucose transporter has been studied at normal and high hydrostatic pressure to identify the step(s) which involve a volume change. Pressure inhibited zero-trans and equilibrium exchange influx to similar extents, by decreasing the Vmax but not significantly changing the Km. The Bmax and Kd of specific [3H]cytochalasin B binding were unaffected by pressure indicating no change to the number or affinity of functional transporters at pressure. Passive glucose transport was inhibited by pressure in a manner consistent with permeation across the lipid bilayer. These data indicate that there is a major change in volume during the translocation step of the glucose transporter which is rate-limiting for transport.

The volume changes associated with the operation of the 'simple' transporter

The effects of hydrostatic pressure (0.1-50 MPa) on uridine transport mediated by the 'simple' facilitated nucleoside transporter of guinea-pig and human erythrocytes have been studied in an attempt to identify the volume changes which occur during transport. Pressure inhibited the zero-trans (influx or efflux) mode of uridine transport in guinea-pig cells significantly more (about 2.2- x) than equilibrium exchange. The equilibrium binding of 3H-nitrobenzylthioinosine, a potent specific inhibitor of nucleoside transport, to human red cells and ghosts, was not significantly altered by pressure suggesting that the permeation site was unperturbed. Thus pressure inhibited the transporter primarily by preventing the volume increase associated with the translocation step. Furthermore, the return of the 'empty' transporter was found to be rate-limiting because it required a larger increase in volume than when the transporter was loaded with substrate.

Effects of low ionic strength media on passive human red cell monovalent cation transport

1. The effect of low ionic strength media on the residual, i.e. (ouabain + bumetanide + Ca2+)-insensitive, K+ influx was characterized in human red blood cells. 2. This K+ flux was enhanced significantly in isotonic solutions of low ionic strength using sucrose to maintain constant osmolarity. This effect was found for fresh red blood cells as well as for stored (bank) red blood cells. However, the absolute magnitude of K+ influx in solutions of low ionic strength was halved for stored red blood cells. 3. Anion replacement of Cl- by CH3SO4- did not affect residual K+ fluxes, showing that Cl- -dependent transport pathways (e.g. the KCl co-transporter) are not involved in the low ionic strength effect. 4. The enhanced K+ influx in low ionic strength media was reversible when the cells were resuspended in a solution of physiological ionic strength. 5. K+ influx measured in light and dense fractions of erythrocytes (separated by centrifugation and corresponding to samples enriched with either 'young' or 'mature' red cells) showed that the low ionic strength effect does not change markedly with cell age. 6. Low ionic strength media elevated residual, i.e. (ouabain + bumetanide + Ca2+)-insensitive, influx of both K+ and Na+ by about the same amount. In both cases the flux was linear with concentration in the range investigated (0.25-10 mM). No significant increase in the uptake of the cations Ca2+ and lysine in low ionic strength solutions could be found. 7. In CH3SO4- -containing solutions of physiological ionic strength the residual K+ influx was almost independent of cell volume, whereas this flux in CH3SO4- -containing solutions of low ionic strength declined as cell volume was increased. 8. K+ flux measurements in solutions of different external pH, where NaCl was replaced by sodium gluconate or sodium glucuronate, showed that the reduced ionic strength is of more importance for the enhanced residual K+ influx than the changed transmembrane potential or the changed intracellular pH. However, a small pH dependence could be found, the K+ flux passing through a minimum around pHi 7.3. 9. Hydrostatic pressure enhanced the residual K+ flux in media of low ionic strength synergistically, so that very large fluxes (greater than 10 mmol (1 cells)-1 h-1) were obtained at 40 MPa. The apparent activation volumes (delta V*) for the pressure-sensitive K+ flux were -108 and -69 ml mol-1 in low ionic strength or physiological ionic strength solutions respectively.(ABSTRACT TRUNCATED AT 400 WORDS)

The temperature dependence of human erythrocyte transport of phosphate, phosphite and hypophosphite

The temperature dependence of the erythrocyte anion transport protein (Band 3 or AE1) mediated influx of three nonspherical substrates, the divalent anions phosphate and phosphite, and the monovalent hypophoshite, were determined. Phase transitions were found in the temperature dependence of the influxes of all three anions. The 95% confidence limits for the transition temperatures were: 34.6-38.1 degrees C, 7.4-9.1 degrees C and 6.7-9.7 degrees C for phosphate, phosphite and hypophosphite, respectively, while the critical influx rates at the transitions were 29-50, 64-102 and 26-58 ions/s per carrier, respectively. That the critical rates rather than the transition temperatures are of similar magnitude indicates that the transitions are related to transport mechanisms rather than to thermal protein conformational changes. These critical rates are two orders of magnitude lower than those reported for the self-exchange of Cl- and Br- (Brahm, J. (1977) J. Gen. Physiol. 70, 283-306). The critical rate of monovalent hypophosphite is similar to that of divalent phosphate and phosphite, but not to that of Cl- indicating that this effect is mediated by the structure of the substrate rather than by its charge. The disparity in the rates rc at which phase transitions occur in AE1-mediated transport of spherical and nonspherical anions indicates a difference in the interaction between the two classes of anions and the protein.

Role of substrate binding forces in exchange-only transport systems: II. Implications for the mechanism of the anion exchanger of red cells

The transition-state theory of exchange-only membrane transport is applied to experimental results in the literature on the anion exchanger of red cells. Two central features of the system are in accord with the theory: (i) forming the transition state in translocation involves a carrier conformational change; (ii) substrate specificity is expressed in transport rates rather than affinities. The expression of specificity is consistent with other evidence for a conformational intermediate (not the transition state) formed in the translocation of all substrates. The theory, in conjunction with concepts derived from the chemistry of macrocyclic ion inclusion complexes, prescribes certain essential properties in the transport site. Separate subsites are required for the preferred substrates, Cl- and HCO3-, to account for tight binding in the transition state (Kdiss congruent to 1 microM). Further, the following mechanism is suggested. A substrate anion initially forms a loose surface complex at one subsite, but in the transition state the subsites converge to form an inclusion complex in which the binding forces are greatly increased through a chelation effect. The conformational change at the substrate site, which is driven by the mounting forces of binding, sets in train a wider conformational change that converts the carrier from an immobile to a mobile form. Though simple, this composite-site mechanism explains many unusual features of the system. It accounts for substrate inhibition, partially noncompetitive inhibition of one substrate by another, and "tunneling," which is net transport under conditions where exchange should prevail, according to other models. All three types of behavior result from the formation of a ternary complex in which substrate anions are bound at both subsites. The mechanism also accounts for the enormous range of substrate structures accepted by the system, for the complex inhibition by the organic sulfate NAP-taurine, and for the involvement of several cationic side chains and two different protein domains in the transport site.

Temperature dependence of anion transport in the human red blood cell

Arrhenius plots of chloride and bromide transport yield two regions with different activation energies (Ea). Below 15 or 25 degrees C (for Cl- and Br-, respectively), Ea is about 32.5 kcal/mol; above these temperatures, about 22.5 kcal/mol (Brahm, J. (1977) J. Gen. Physiol. 70, 283-306). For the temperature dependence of SO4(2-) transport up to 37 degrees C, no such break could be observed. We were able to show that the temperature coefficient for the rate of SO4(2-) transport is higher than that for the rate of denaturation of the band 3 protein (as measured by NMR) or the destruction of the permeability barrier in the red cell membrane. It was possible, therefore, to extend the range of flux measurements up to 60 degrees C and to show that, even for the slowly permeating SO4(2-) in the Arrhenius plot, there appears a break, which is located somewhere between 30 and 37 degrees C and where Ea changes from 32.5 to 24.1 kcal/mol. At the break, the turnover number is approx. 6.9 ions/band 3 per s. Using 35Cl- -NMR (Falke, Pace and Chan (1984) J. Biol. Chem. 259, 6472-6480), we also determined the temperature dependence of Cl- -binding. We found no significant change over the entire range from 0 to 57 degrees C, regardless of whether the measurements were performed in the absence or presence of competing SO4(2-). We conclude that the enthalpy changes associated with Cl- - or SO4(2-)-binding are negligible as compared to the Ea values observed. It was possible, therefore, to calculate the thermodynamic parameters defined by transition-state theory for the transition of the anion-loaded transport protein to the activated state for Cl-, Br- and SO4(2-) below and above the temperatures at which the breaks in the Arrhenius plots are seen. We found in both regions a high positive activation entropy, resulting in a low free enthalpy of activation. Thus the internal energy required for carrying the complex between anion and transport protein over the rate-limiting energy barrier is largely compensated for by an increase of randomness in the protein and/or its aqueous environment.

Effects of high hydrostatic pressure on 'passive' monovalent cation transport in human red cells

The effects of high hydrostatic pressure (up to 400 ATA) on the 'passive' (defined as ouabain + bumetanide + EGTA-insensitive) influx and efflux of radiotracer cations (K+ Rb+, Na+, Cs+) has been studied in human red cells suspended at different medium tonicities giving altered cell volumes. Under all conditions studied, cation permeability was raised at pressure, and at least two distinct components were found to comprise this flux. Thus, increasing pressure caused a generalized increase in cation permeability which was unaffected by the anion present, demonstrated linear concentration dependence, and was reduced with cell swelling, and stimulated a specific KCl pathway which was Cl- dependent, demonstrated saturation kinetics with raised [K]0 and was increased with cell swelling. High hydrostatic pressure caused a significant alteration to red cell morphology from the normal biconcave disc to cup-shaped forms and it is proposed that this is associated with the unmasking of the volume-sensitive KCl system.