The noncompetitive inhibitor WW781 senses changes in erythrocyte anion exchanger (AE1) transport site conformation and substrate binding.

WW781 binds reversibly to red blood cell AE1 and inhibits anion exchange by a two-step mechanism, in which an initial complex (complex 1) is rapidly formed, and then there is a slower equilibration to form a second complex (complex 2) with a lower free energy. According to the ping-pong kinetic model, AE1 can exist in forms with the anion transport site facing either inward or outward, and the transition between these forms is greatly facilitated by binding of a transportable substrate such as Cl(-). Both the rapid initial binding of WW781 and the formation of complex 2 are strongly affected by the conformation of AE1, such that the forms with the transport site facing outward have higher affinity than those with the transport site facing inward. In addition, binding of Cl(-) seems to raise the free energy of complex 2 relative to complex 1, thereby reducing the equilibrium binding affinity, but Cl(-) does not compete directly with WW781. The WW781 binding site, therefore, reveals a part of the AE1 structure that is sensitive to Cl(-) binding and to transport site orientation, in addition to the disulfonic stilbene binding site. The relationship of the inhibitory potency of WW781 under different conditions to the affinities for the different forms of AE1 provides information on the possible asymmetric distributions of unloaded and Cl(-)-loaded transport sites that are consistent with the ping-pong model, and supports the conclusion from flux and nuclear magnetic resonance data that both the unloaded and Cl(-)-loaded sites are very asymmetrically distributed, with far more sites facing the cytoplasm than the outside medium. This asymmetry, together with the ability of WW781 to recruit toward the forms with outward-facing sites, implies that WW781 may be useful for changing the conformation of AE1 in studies of structure-function relationships.

NIP- and NAP-taurine bind to external modifier site of AE1 (band 3), at which iodide inhibits anion exchange.

External iodide (I-o) inhibits AE1 (band 3)-mediated anion exchange in human red blood cells by binding to a noncompetitive inhibitory site, the external halide modifier site. External N-(4-azido-2-nitrophenyl)-2-aminoethyl sulfonate (NAP-taurine) and N-(4-isothiocyano-2-nitrophenyl)-2-aminoethyl sulfonate (NIP-taurine) also inhibit Cl- exchange noncompetitively. Increasing I-o decreases the inhibitory potency of NIP-taurine in a competitive fashion; this effect is not due to I- binding to the transport site, which has little effect on the NIP-taurine affinity. Bis(sulfosuccinimidyl)-suberate (BSSS) abolishes the noncompetitive inhibitory effect of I-o and greatly reduces the inhibitory effect of NAP-taurine. Together with previous work, these data suggest that external halides, such as I-, Br-, and probably also Cl-, bind to the same noncompetitive inhibitory site as do NAP- and NIP-taurine and that these reagents can be used to label the halide modifier site. Lys-539, a probable reaction site of BSSS, lies within the same segment of AE1 that is labeled by NAP-taurine and thus may be part of the modifier site.

WW-781, a potent reversible inhibitor of red cell Cl- flux, binds to band 3 by a two-step mechanism.

WW-781 ([3-methyl-1-p-sulfophenyl-5-pyrazolone-(4)]-[1,3-dibutylbarbit uric acid]-pentamethine oxonol), a fluorescent dye that has been used for measuring membrane potentials by optical methods, inhibits human red blood cell Cl- exchange, which is mediated by the membrane protein known as band 3 or capnophorin. The inhibition is slowly reversible upon removal of WW-781 from the medium, with a half time of approximately 4.7 min in 150 mM Cl- medium at 0 degrees C. The mechanism of inhibition by WW-781 involves a two-step binding reaction. WW-781 binds rapidly to band 3 to form an initial complex, which can also rapidly dissociate. Formation of this initial complex is followed by the much slower formation of a second complex (with a rate constant of approximately 1.1 min-1), probably involving a protein conformational change, through which WW-781 is more tightly bound to band 3. At low concentrations, WW-781 inhibits Cl- exchange with a stoichiometry of 1 WW-781 molecule per band 3 monomer, suggesting that under these conditions the binding of WW-781 is highly selective for the band 3 protein.

Kinetics of DIDS inhibition of HL-60 cell anion exchange rules out ping-pong model with slippage.

According to the ping-pong model of band 3-mediated anion exchange, the transport protein has a single transport site, which can exist in either an inward-facing or an outward-facing conformation. Anions bind to these unloaded forms of the carrier, and translocation takes place only when a suitable anion is bound to the transport site. In a previous paper [Am. J. Physiol. 257 (Cell Physiol. 26): C520-C527, 1989], we had shown that the substrate kinetics of Cl-Cl exchange in the promyelocytic HL-60 cell cannot be explained by this simple ping-pong model of anion exchange but is consistent with a simultaneous model according to which both extracellular and intracellular anions must bind before simultaneous translocation can take place. In the present paper we show that external 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS) inhibits anion exchange in HL-60 cells by competing with Cl- for binding to the outward-facing transport site. Furthermore, there is a linear dependence of the slope of the Dixon plot for inhibition by DIDS on the reciprocal of the intracellular Cl- concentration. This result clearly rules out a simple ping-pong scheme. In addition, the data also rule out a ping-pong model in which some translocation of the unloaded carrier is allowed (ping-pong model with slippage). The observed inhibition kinetics can be modeled by a simultaneous model of Cl-Cl exchange with competitive inhibition by DIDS.

Cl-Cl exchange in promyelocytic HL-60 cells follows simultaneous rather than ping-pong kinetics.

The intra- and extracellular chloride concentration dependencies of the rate of Cl-Cl exchange in human promyelocytic leukemic HL-60 cells were studied by means of radioactive isotope (36Cl) efflux measurements. Efflux of isotope from cells follows an exponential time course. The Cl-Cl exchange flux follows Michaelis-Menten kinetics as a function of both intra- and extracellular chloride concentrations. The ratio of the maximum exchange velocity to the apparent Michaelis constant for both extracellular and intracellular substrate increases as a function of trans Cl concentration, indicating that Cl-Cl exchange in the HL-60 cell does not follow ping-pong kinetics. A kinetic scheme in which extracellular and intracellular chloride ions bind in random order to the transporter and are then translocated simultaneously can adequately model the experimental data.

Flufenamic acid senses conformation and asymmetry of human erythrocyte band 3 anion transport protein.

With Cl as substrate, the human red blood cell anion transport (band 3) protein can exist in four conformations: Ei, with the transport site facing the cytoplasm; Eo, with the transport site facing the external medium; and ECli and EClo, the corresponding forms loaded with Cl. Flufenamic acid (FA), an inhibitor that binds to an external site different from the transport site, binds to Eo with a dissociation constant of 0.0826 +/- 0.0049 (SE) microM. Binding of iodide or sulfate to the external-facing transport site reduces the affinity by 1.66 or 14.3-fold, respectively. Changing from Eo to Ei lowers the affinity by 3.7-fold, and binding of cytoplasmic iodide to Ei further decreases the affinity by 5.5-fold. Thus changes in orientation of the transport site and substrate binding, even at the opposite side of the membrane, cause sufficient conformational changes in band 3 to affect FA binding substantially. If the possible effects of Cl binding to the transport site on FA affinity are estimated from the iodide data, the dependence of FA inhibitory potency on Cl concentrations inside and outside the cell suggests that there are at least 6.5 times as many inward-facing as outward-facing Cl-loaded transport sites. This information can be used to calculate the distribution of capnophorin among the various conformations under different circumstances and to devise conditions for recruiting the transport molecules toward a particular conformation.

pH homeostasis in promyelocytic leukemic HL60 cells.

By measuring the membrane potential using the influx of the lipophilic cation tetraphenylphosphonium and intracellular pH using 2,7-biscarboxy-ethyl-5(6)-carboxyfluorescein and the distribution of the weak acid 5,5-dimethyl-2,4-oxazolidinedione, we have determined that intracellular pH is 0.9-1.1 pH units above electrochemical equilibrium in undifferentiated HL60 cells, indicating that these cells actively extrude proton equivalents. The Na/H exchanger is not the system responsible for keeping the pH above the electrochemical equilibrium, since adding inhibitors of this transport system (dimethylamiloride and ethylisopropylamiloride) or removing the extracellular sodium has no effect on intracellular pH. In contrast, the addition of the Cl/HCO3 exchange inhibitors H2 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) or pentachlorophenol (PCP) causes a drop in intracellular pH, and the removal of extracellular chloride in the presence of bicarbonate leads to a large intracellular alkalinization, which indicates a role for the anion exchanger in pH homeostasis in these cells. In addition, we find that the intracellular chloride concentration is about one order of magnitude above electrochemical equilibrium. We conclude that an H2DIDS and PCP inhibitable system, probably the Cl/HCO3 exchanger, is at least partially responsible for keeping intracellular pH above electrochemical equilibrium in HL60 cells under resting conditions. We also find no change in intracellular pH when cells differentiate along the granulocytic pathway (having been induced by the addition of dimethylsulfoxide or of retinoic acid), which indicates that changes in intracellular pH are not causally related to cell differentiation.

Interactions of NIP-taurine, NAP-taurine, and Cl- with the human erythrocyte anion exchange system.

N-(4-isothiocyano-2-nitrophenyl)-2-aminoethanesulfonate (NIP-taurine), a newly synthesized isothiocyano derivative of N-(4-azido-2-nitrophenyl)-2-aminoethanesulfonate (NAP-taurine), is a potent inhibitor of human erythrocyte chloride exchange. At 0 degrees C, the inhibition is reversible, but at 37 degrees C, NIP-taurine inhibits irreversibly, indicating that it may be a useful label for its binding site. When present at the outside of the cell, NIP-taurine binds with low affinity to a site that seems to be the Cl- transport site (on the basis of its affinity for Cl-) and with much higher affinity to a different site, MN, which has a much lower affinity for Cl-. In this respect, NIP-taurine resembles NAP-taurine, and an analysis of interactions between these two probes is consistent with the idea that they bind to the same two sites. The affinity of NIP-taurine for the high-affinity MN site is enhanced by about fourfold when the transport protein, band 3, is in the conformation with the transport site facing outward (Eo), as compared with the conformation with the transport site facing inward (Ei). External Cl-, but not cytoplasmic Cl-, competes with NIP-taurine for binding to the external, high affinity site. Thus NIP-taurine provides a label for an external site, at which Cl- and perhaps other anions bind, which is separate from both the transport site and the cytoplasmic modifier site at which high Cl- concentrations inhibit Cl- exchange.