Sulfate-chloride exchange transport in a glioma cell line

Transport of SO4(2-) was studied in the glioma cell line LRM55 to determine whether it is mediated by the Cl-/HCO3- exchanger or the K+/Cl- cotransporter previously described in these cells (Wolpaw, E.W. and Martin, D.L. (1984) Brain Res. 297, 317-327). 35SO4(2-) influx was saturable with SO4(2-). External SO4(2-) stimulated 35SO4(2-) efflux, indicating an exchange mechanism. External Cl- was a competitive inhibitor of 35SO4(2-) influx. Internal Cl- stimulated 35SO4(2-) influx and external Cl- stimulated 35SO4(2-) efflux, indicating that Cl- is an exchange substrate for the SO4(2-) carrier. Also, SO4(2-) flux was sensitive to SITS, DIDS and furosemide. However, saturating external SO4(2-) did not inhibit 36Cl- influx and did not inhibit 36Cl- efflux via the Cl-/HCO3- exchanger. Moreover, K+ did not stimulate 36Cl- efflux via the Cl-/HCO3- exchanger. Moreover, K+ did not stimulate 35SO4(2-) influx as it does Cl- influx. These findings indicate that SO4(2-) transport into these cells is mediated by an exchange carrier distinct from both the Cl-/HCO3- exchanger and the K+/Cl- cotransporter. While Cl- is an alternative substrate for the SO4(2-) porter, this carrier is responsible for only a minor fraction of total Cl- flux in these cells.     

Characterization of chloride transport pathways in cultured human keratinocytes.

In human keratinocytes, mediated transport of Cl- was found to occur mainly by two mechanisms: an anion exchange and an electrically conductive pathway. The contribution of the anion exchange, which accounted for about 50% of overall Cl- efflux, was assessed either by its sensitivity to inhibition by 4,4'-diisothiocyanatostilbene-2,2'-disulfonic acid (DIDS), and by means of Cl- substitution experiments. The anion exchange exhibited a saturation behaviour over the range 10-135 mM Cl-; Cl- was more efficient than HCO3-, Br- and NO3- in increasing Cl- efflux rate, whereas SO4(2-) and I- inhibited Cl- efflux. The electrically conductive Cl- pathway, which accounted for about 40% of total Cl- efflux, was inhibited by the Cl- channel blocker 5-nitro-2-(3-phenylpropylamino)benzoic acid (NPPB) and was at least partially sensitive to variation of the plasma membrane potential. The Cl- channel was insensitive to elevation in the intracellular concentration of either cyclic AMP and calcium ions. Indomethacin, an inhibitor of the cyclooxygenase, failed to reduce Cl- efflux, whereas nordihydroguaiaretic acid (NDGA), an inhibitor of the lipoxygenase, induced 50% inhibition of Cl- efflux. These results support the conclusion that endogenous production of lipoxygenase-derived arachidonic acid metabolite(s) might be responsible for high basal Cl- permeability in human keratinocytes.     

Effects of membrane potential on electrically silent transport. Potential-independent translocation and asymmetric potential-dependent substrate binding to the red blood cell anion exchange protein

Tracer anion exchange flux measurements have been carried out in human red blood cells with the membrane potential clamped at various values with gramicidin. The goal of the study was to determine the effect of membrane potential on the anion translocation and binding events in the catalytic cycle for exchange. The conditions were arranged such that most of the transporters were recruited into the same configuration (inward-facing or outward-facing, depending on the direction of the Cl- gradient). We found that the membrane potential has no detectable effect on the anion translocation event, measured as 36Cl(-)-Cl- or 36Cl(-)-HCO3- exchange. The lack of effect of potential is in agreement with previous studies on red cells and is different from the behavior of the mouse erythroid band 3 gene expressed in frog oocytes (Grygorczyk, R., W. Schwarz, and H. Passow. 1987. J. Membr. Biol. 99:127-136). A negative potential decreases the potency of extracellular SO4= as an inhibitor of either Cl- or HCO3- influx. Because of the potential-dependent inhibition by SO4=, conditions could be found in which a negative intracellular potential actually accelerates 36Cl- influx. This effect is observed only in media containing multivalent anions. The simplest interpretation of the effect is that the negative potential lowers the inhibitory potency of the multivalent anion by lowering its local concentration near the transport site. The magnitude of the effect is consistent with the idea that the anions move through 10-15% of the transmembrane potential between the extracellular medium and the outward-facing transport site. In contrast to its effect on extracellular substrate binding, there is no detectable effect of membrane potential on the competition between intracellular Cl- and SO4= for transport sites. The lack of effect of potential on intracellular substrate binding suggests that the access pathway leading to the inward-facing transport site is of lower electrical resistance than that leading to the extracellular substrate site.     

The mechanism of anion transport across human red blood cell membranes as revealed with a fluorescent substrate: I. Kinetic properties of NBD-taurine transfer in symmetric conditions

Summary The molecular mechanism of anion exchange across the human red blood cell membrane was assessed with the fluorescent substrate analog NBD-taurine and the method of continuous monitoring of transport by fluorescence. The efflux of NBD-taurine was studied under a variety of experimental conditions such as temperature, pH and anion composition of cells and media. The temperature profile of NBD-taurine transfer from Cl-loaded cells into Cl media resembled that of Cl self-exchange, whereas that of NBD-taurine transfer from sulfate-loaded cells into sulfate media resembled that of sulfate self-exchange. Although the pH profiles of NBD-taurine transfer from Cl-loaded cells into Cl media and that of Cl self-exchange resembled each other, the analogous transfer with sulfate replacing Cl was markedly different. These and other data were analyzed and found to be consistent with a model which comprises the following: (a) a H⁺-titratable group in the carrier mechanism; (b) alteration of transport sites between the two sides of the membrane (i.e., ping-pong kinetics); and (c) transmembrane distribution of transport sites which is modulated by pH. It is shown that NBD-taurine transfer represents a tracer flux of a fluorescent substrate which gives a measure for the presence of monovalent transport sites at the inner surface of the membrane. The latter is markedly affected by the relative concentrations of anions and H⁺ on both sides of the red blood cell membrane.     

35Cl nuclear magnetic resonance line broadening shows that eosin-5-maleimide does not block the external anion access channel of band 3.

It has been suggested that Lys-430 of band 3, with which eosin-5-maleimide (EM) reacts, is located in the external channel through which anions gain access to the external transport site, and that EM inhibits anion exchange by blocking this channel. To test this, we have used 35Cl nuclear magnetic resonance (NMR) to measure Cl- binding to the external transport site in control and EM-treated human red blood cells. Intact cells were used rather than ghosts, because in this case all line broadening (LB) results from binding to external sites. In an NMR spectrometer with a 9.4-T magnetic field, red blood cells at 50% concentration (v/v) in 150 mM Cl- medium at 3 degrees C caused 19.0 +/- 1.2 Hz LB. Of this, 7.9 +/- 0.7 Hz was due to Cl- binding to the high affinity band 3 transport sites, because it was prevented by an apparently competitive inhibitor of anion exchange, 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS). The LB was not due to hemoglobin released from the cells, as little LB remained in the supernatant after cells were removed by centrifugation. Saturable Cl- binding remained in EM-treated cells, although the binding was no longer DNDS-sensitive, because EM prevents binding of DNDS. The lower limit for the rate at which Cl- goes from the binding site to the external medium is 2.15 x 10(5) s-1 for control cells and 1.10 x 10(5) s-1 for EM-treated cells, far higher than the Cl- translocation rate at 3 degrees C (about 400 s-1). Thus, EM does not inhibit Cl- exchange by blocking the external access channel. EM may therefore be useful for fixing band 3 in one conformation for studies of Cl- binding to the external transport site.     

Mechanism of the increase in cation permeability of human erythrocytes in low-chloride media. Involvement of the anion transport protein capnophorin

When human erythrocytes are suspended in low-Cl- media (with sucrose replacing Cl-), there is a large increase in both the net efflux and permeability of K+. A substantial portion (greater than 70% with Cl- less than 12.5 mM) of this K+ efflux is inhibited by the anion exchange inhibitor DIDS (4,4'-diisothiocyanostilbene-2,2'-disulfonic acid). This inhibition cannot be explained as an effect of DIDS on net Cl- permeability (Pcl) and membrane potential, but rather represents a direct effect on the K+ permeability. When cells are reacted with DIDS for different times, the inhibition of K+ efflux parallels that of Cl- exchange, which strongly indicates that the band 3 anion exchange protein (capnophorin) mediates the net K+ flux. Since a noncompetitive inhibitor of anion exchange, niflumic acid, has no effect on net K+ efflux, the net K+ flow does not seem to involve the band 3 conformational change that mediates anion exchange. The data suggest that in low-Cl- media, the anion selectivity of capnophorin decreases so that it can act as a very low-conductivity channel for cations. Na+ and Rb+, as well as K+, can utilize this pathway.     

Identification of cholate as a shared substrate for the unidirectional efflux systems for methotrexate in L1210 mouse cells

The bidirectional transport properties of cholate have been examined in leukemic L1210 mouse cells and compared with the transport of methotrexate. The cell entry of [3H]cholate was Na(+)-independent, linear with increasing concentrations of substrate, enhanced by decreasing pH, and uneffected by excess unlabeled cholate or by various anion-transport inhibitors and hence had the characteristics of passive diffusion or a pH-dependent mediated process with a high Kt for cholate. The efflux of [3H]cholate, however, could be attributed to carrier-mediated and energy-dependent transport. Efflux was rapid (t1/2 = 1.5 min) and could be increased with glucose and decreased with metabolic inhibitors, and it was inhibited by various compounds including bromosulfophthalein, probenecid, prostaglandin A1, reserpine, verapamil, quinidine, diamide, 1-methyl-3-isobutylxanthine and vincristine. The most potent inhibitor was prostaglandin A1, which reduced efflux by 50% at a concentration of 0.10 microM. Half-maximal inhibition by vincristine occurred at 4.8 microM. The maximum extent of inhibition with most of the inhibitors was 95%, although a lower value was observed with bromosulfophthalein (85%). When cholate efflux was compared with the efflux of methotrexate, both processes responded similarly to changes in the metabolic state of the cell. Moreover, the various inhibitors of cholate efflux also inhibited the efflux of methotrexate and the same concentration of each inhibitor was required for half-maximal inhibition of both processes. The efflux of folate and urate also proceeded via outwardly directed, unidirectional processes which were sensitive to bromosulfophthalein and probenecid. The results suggest that L1210 cells have the capacity for the unidirectional extrusion of cholate, methotrexate and probably other large, structurally dissimilar organic anions and that this efflux occurs via two or more very similar transport systems with a broad anion specificity. The function of an organic anion efflux system in vivo may be to facilitate the extrusion of cytotoxic metabolic anions which are too large to exit via the general anion-exchange carrier of these cells. Similarities in inhibitor specificity were also apparent between unidirectional anion efflux in L1210 cells and the drug efflux pump which is over-produced in cells with multidrug resistance.     

Interactions between diphtheria toxin entry and anion transport in Vero cells. I. Anion antiport in Vero cells

In sodium-free buffer of low ionic strength, the uptake of chloride and sulfate in Vero cells was found to occur mainly by antiport which was very sensitive to inhibition by 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid. Efflux of anions from the cells appeared to energize the uptake. While the uptake of Cl- occurred over a wide pH range, that of SO4(2-) showed a clear maximum at pH 6-7. The rate of efflux of 36Cl- and 35SO4(2-) was strongly increased by the presence of permeant anions in the efflux buffer. Preincubation of the cells at slightly alkaline pH strongly increased the rate of C1- efflux into buffers nominally free of permeant anions, as well as the efflux by exchange. This increase did not occur if the cells were depleted for ATP during the preincubation. Depolarization of the cells reduced the rate of efflux into buffers without permeant anions, indicating that the efflux is at least partly due to net, electrogenic, anion transport. The efflux by antiport was not affected by manipulations of the membrane potential, indicating electroneutral exchange. The uptake and efflux were increased to the same extent with increasing temperature, the activation energies were Ea = 25 kcal/mol of Cl- and Ea = 12 kcal/mol of SO4(2-). Similar anion antiport appears to occur in L, baby hamster kidney, and HeLa S3 cells.     

The membrane valve: A consequence of asymmetrical inhibition of membrane carriers. I. Equilibrating transport systems

Facilitated membrane transport systems act as valves, or rectifiers, when the substrate affinities on the two sides of the membrane differ substantially, i.e. when the system is strongly asymmetric. The asymmetry may be intrinsic or imposed by a reversible competitive inhibitor acting on only one side of the membrane. Under non-equilibrium conditions such systems allow net movements of substrate to proceed faster, sometimes much faster, in one direction than the other, though the final equilibrium is unaffected. Obligatory exchange systems may also function as valves when inhibited unsymmetrically, permitting exchange to occur more rapidly with one distribution of substrates than with the reversed distribution. Here, unequal flux rates do not depend on unequal concentrations of the substrate on either side of the membrane, but may also occur with equal concentrations, provided the affinities of the two substrates differ.The kinetic theory leading to these conclusions is given here, and it is shown how individual parameters of a carrier system affect the efficiency, or tightness, of the valve. In addition, simple kinetic tests for the operation of a valve are outlined. Examples are cited of transport systems having inhibitor-binding sites on only one surface of the cell membrane, which could function normally as valves. Systems implicated are glucose transport in various cells, the ADP-ATP exchanger of mitochondria, the anion transporter of erythrocytes, and the Na⁺-K⁺ pump.     

Fluorescence labeling of the human erythrocyte anion transport system. Subunit structure studied with energy transfer

The anion transport system of human red cells was isolated in vesicles containing the original membrane lipids and the 95 000 dalton polypeptides (band 3) by the method of Wolosin et al. (J. Biol. Chem. (1977) 252, 2419–2427). The vesicles have a functional anion transport system since they display sulfate transport that is inhibited by the fluorescent probe 8-anilinonaphthalene 1-sulfonate (ANS) with similar potency as in red cells. The vesicles were labeled with the SH-specific probe fluorescein mercuric acetate (FMA). Labeling lowers FMA fluorescence, and is prevented or reversed by dithiothreitol, suggesting that the reaction is with a thiol group on the protein. Fluorescence titrations show a maximum labeling stoichiometry of 1.3 ± 0.4 mol FMA/mol 95 000 dalton polypeptide. The polarization of bound FMA fluorescence is high indicating that the probe is highly immobilized. Pretreatment with Cu²⁺ + o-phenanthroline under conditions that crosslink band 3 in ghosts decreases FMA labeling 50%. Differences in kinetics of FMA labeling in sealed and leaky vesicles suggest that the reactive SH group is located in the intravesicular portion of the protein (corresponding to the cytoplasmic surface of the red cell) and that FMA can cross the membrane. Inhibitors of anion transport have no effect on FMA labeling kinetics suggesting it is not transported via the anion     

Titration of transport and modifier sites in the red cell anion transport system

This work demonstrates the existence of titratable transport and modifier sites in the anion transport system of human red cells. Effects of alkaline extracellular pH on chloride exchange were studied up to pH 13 at 0 degrees C. The studies revealed two sets of reversible titratable groups. One set, having a pK of or approximately 11, appeared to be identical with the inhibitory halide-binding modifier site. Deprotonation of this site stimulated anion transport. The apparent dissociation constants of chloride and iodide at this modifier site were 0.3 and 0.06 M, respectively, and it was confirmed that the organic sulfonate NAP-taurine inhibits anion transport reversibly by a high-affinity interaction with halide-binding modifier sites at the extracellular side of the membrane. Other groups, with apparent pK of or approximately 12 at chloride concentrations above 0.1 M, were named as "transport sites" because transport function depended totally on their protonation. The apparent pK decreased when extracellular halide concentrations was lowered below 0.1 M. It was dependent of the intracellular chloride concentration, and was equally sensitive to extracellular pH of 13, was fully reversible. Hydroxyl ions were not transported to an appreciable extent by the anion exchange system. The pK values of both sets of groups make it likely that they are both arginyl residues, functioning as anion recognition sites similar to the role of functionally essential arginyl residues observed with numerous enzymes.     

Anion transport in red blood cells. II. Kinetics of reversible inhibition by nitroaromatic sulfonic acids.

The anion exchange system of human red blood cells is highly inhibited and specifically labeled by isothiocyano derivatives of benzene sulfonate (BS) or stilbene disulfonate (DS). To learn about the site of action of these irreversibly binding probes we studied the mechanism of inhibition of anion exchange by the reversibly binding analogs p-nitrobenzene sulfonic acid (pNBS) and 4,4'-dinitrostilbene-disulfonic acid (DNDS). In the absence of inhibitor, the self-exchange flux of sulfate (pH 7.4, 25 degrees C) at high substrate concentration displayed self-inhibitory properties, indicating the existence of two anion binding sites: one a high-affinity transport site and the other a low-affinity modifier site whose occupancy by anions results in a noncompetitive inhibition of transport. The maximal sulfate exchange flux per unit area was JA = (0.69 +/- 0.11) X 10(-10) moles . min-1 . cm-2 and the Michaelis-Menten constants were for the transport site KS = 41 +/- 14 mM and for the modifier site Ks' = 653 +/- 242 mM. The addition to cells of either pNBS at millimolar concentrations or DNDS at micromolar concentrations led to reversible inhibition of sulfate exchange (pH 7.4, 25 degrees C). The relationship between inhibitor concentration and fractional inhibition was linear over the full range of pNBS or DNDS concentrations (Hill coefficient n approximately equal to 1), indicating a single site of inhibition for the two probes. The kinetics of sulfate exchange in the presence of either inhibitor was compatible with that of competitive inhibition. Using various analytical techniques it was possible to determine that the sulfate transport site was the target for the action of the inhibitors. The inhibitory constants (Ki) for the transport sites were 0.45 +/- 0.10 microM for DNDS and 0.21 +/- 0.07 mM for pNBS. From the similarities between reversibly and irreversibly binding BS and DS inhibitors in structures, chemical properties, modus operandi, stoichiometry of interaction with inhibitory sites, and relative inhibitory potencies, we concluded that the anion transport sites are also the sites of inhibition and of labeling of covalent binding analogs of BS and DS.     

Anion exchange and anion-cation co-transport systems in mammalian cells

Electroneutral anion transfer in the Ehrlich ascites tumour cell has been found to occur by two separate mechanisms. One is an exchange diffusion system with many similarities to that found in erythrocytes, e.g. saturation kinetics with 'self-inhibition', a relatively pronounced temperature dependence, competitive interactions of Br-, NO3- and SCN-, and a low conductive PCl- of 4 x 10(-8) cm s-1. The main differences are that the Cl- flux in Ehrlich cells at 38 degrees C is one thousandth of the flux in red cells, and that the specificity of the system is less pronounced. It is suggested that the density of anion exchange sites in Ehrlich cells could be the same as in red blood cells, but with a lower turnover rate. The other system is an anion-cation co-transport system capable of mediating a secondary active Cl- influx. This system has a volume-regulatory function and is activated by a reduction in cell volume and intracellular [Cl-]. The two transport systems can be separated by using DIDS as an inhibitor of anion exchange and bumetanide as an inhibitor of co-transport. Under normal steady-state conditions Cl- flux is dominated by the exchange system. It is suggested that intracellular pH regulation can be achieved by the two systems operating in parallel, because the chloride disequilibrium maintained by the co-transport system can drive an influx of bicarbonate through the exchange mechanism.     

Use of niflumic acid to determine the nature of the asymmetry of the human erythrocyte anion exchange system

Niflumic acid is a noncompetitive inhibitor of chloride exchange, which binds to a site different from the transport or modifier sites. When the internal Cl- concentration is raised, at constant extracellular Cl- , the inhibitory potency of niflumic acid increases. This effect cannot be attributed to changes in membrane potential, but rather it suggests that niflumic acid binds to the anion exchange protein band 3 only when the transport site faces outward. When the chloride gradient is reversed, with Clo greater than Cli , the inhibitory potency of niflumic acid decreases greatly, which indicates that the affinity of niflumic acid for band 3 with the transport site facing inward is almost 50 times less than when the transport site faces outward. Experiments in which Cli = Clo show no significant change in the inhibition by niflumic acid when Cl- is lowered from 150 to 10 mM. These data suggest that the intrinsic dissociation constants for Cl- at the two sides of the membrane are nearly equal. Thus, the chloride- loaded transport sites have an asymmetric orientation like that of the unloaded transport sites, with approximately 15 times more sites facing the inside than the outside. The asymmetry reflects an approximately 1.5 kcal/mol free energy difference between the inward-facing and outward-facing chloride-loaded forms of band 3. High concentrations of chloride (with Cli = Clo), which partially saturate the modifier site, have no effect on niflumic acid inhibition, which indicates that chloride binds equally well to the modifier site regardless of the orientation of the transport site.     

C1/HCO3 exchange in human placental brush border membrane vesicles

Membrane transport pathways for transplacental transfer of CO2/HCO3 were investigated by assessing the possible presence of a Cl/HCO3 exchange mechanism in the maternal-facing membrane of human placental epithelial cells. Cl/HCO3 exchange was tested for in preparations of purified brush border membrane vesicles by 36Cl tracer flux measurements and determinations of acridine orange fluorescence changes. Under 10% CO2/90% N2 the imposition of an outwardly directed HCO3- concentration gradient (pHo 6/pHi 7.5) stimulated Cl- uptake to levels approximately 2-fold greater than observed at equilibrium. Maneuvers designed to offset the development of ion gradient-induced diffusion potentials (valinomycin, Ko = Ki) significantly reduced HCO3- gradient-driven Cl- uptake but concentrative accumulation of Cl- persisted. Early time point determinations performed in the presumed absence of membrane potential suggests the reduced level of HCO3- gradient-driven Cl- uptake resulted from a more rapid dissipation of the HCO3- concentration gradient. Concentrative accumulation of Cl- was not observed in the presence of a pH gradient alone under 100% N2, suggesting a preference of HCO3- over OH- as a substrate for transport. As monitored by acridine orange fluorescence the Cl- gradient-dependent collapse of an imposed pH gradient (pHo 8.5/pHi 6) was accelerated in the presence of CO2/HCO3 when compared with its absence, indicating coupling of HCO3- influx to Cl- efflux. Increasing concentrations of the anion exchange inhibitor 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid were observed to cause a stepwise reduction in HCO3- gradient-driven Cl- uptake (I50 approximately 25 microM) further suggesting the presence of a Cl/HCO3 exchange mechanism. The results of this study provide evidence for a 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid-sensitive Cl/HCO3 exchange mechanism in the maternal-facing membrane of human placental epithelial cells. The identification of an ion-coupled HCO3- transport pathway in placental epithelia may suggest functional roles in mediating transplacental transfer of CO2 as well as maintenance of fetal acid/base balance.     

Asymmetry of the red cell anion exchange system. Different mechanisms of reversible inhibition by N-(4-azido-2-nitrophenyl)-2- aminoethylsulfonate (NAP-taurine) at the inside and outside of the membrane

In the dark, the photoaffinity reagent, N-(4-azido-2-nitrophenyl)-2- aminoethylsulfonate (NAP-taurine), acts as a reversible inhibitor of red cell anion exchange when it is present either within the cell or in the external solution. A detailed analysis of the inhibition kinetics, however, reveals substantial differences in the responses to the probe at the two sides of the membrane. On the inside of the cell, NAP- taurine is a relatively low affinity inhibitor of chloride exchange (Ki = 370 microM). Both the effects of chloride on NAP-taurine inhibition and the affinity of NAP-taurine for the system as a substrate are consistent with the concept that internal NAP-taurine competes with chloride for the substrate site of the anion exchange system. External NAP-taurine, on the other hand, is a far more potent inhibitor of chloride exchange (Ki = 20 microM). It acts at a site of considerably lower affinity for chloride than the substrate site, probably the modifier site, at which halide anions are reported to cause a noncompetitive inhibition of chloride transport. NAP-taurine therefore seems to interact preferentially with either the substrate or modifier site of the transport system, depending on the side of the membrane at which it is present. It is suggested that the modifier site is accessible to NAP-taurine only from the outside whereas the transport site may be accessible from either side.     

Membrane potential and bicarbonate secretion in isolated interlobular ducts from guinea-pig pancreas

The interlobular duct cells of the guinea-pig pancreas secrete HCO(3)(-) across their luminal membrane into a HCO(3)(-)-rich (125 mM) luminal fluid against a sixfold concentration gradient. Since HCO(3)(-) transport cannot be achieved by luminal Cl-/HCO(3)(-) exchange under these conditions, we have investigated the possibility that it is mediated by an anion conductance. To determine whether the electrochemical potential gradient across the luminal membrane would favor HCO(3)(-) efflux, we have measured the intracellular potential (V(m)) in microperfused, interlobular duct segments under various physiological conditions. When the lumen was perfused with a 124 mM Cl- -25 mM HCO(3)(-) solution, a condition similar to the basal state, the resting potential was approximately -60 mV. Stimulation with dbcAMP or secretin caused a transient hyperpolarization (approximately 5 mV) due to activation of electrogenic Na+-HCO(3)(-) cotransport at the basolateral membrane. This was followed by depolarization to a steady-state value of approximately -50 mV as a result of anion efflux across the luminal membrane. Raising the luminal HCO(3)(-) concentration to 125 mM caused a hyperpolarization (approximately 10 mV) in both stimulated and unstimulated ducts. These results can be explained by a model in which the depolarizing effect of Cl- efflux across the luminal membrane is minimized by the depletion of intracellular Cl- and offset by the hyperpolarizing effects of Na+-HCO(3)(-) cotransport at the basolateral membrane. The net effect is a luminally directed electrochemical potential gradient for HCO(3)(-) that is sustained during maximal stimulation. Our calculations indicate that the electrodiffusive efflux of HCO(3)(-) to the lumen via CFTR, driven by this gradient, would be sufficient to fully account for the observed secretory flux of HCO(3)(-).     

The mechanism of anion transport across human red blood cell membranes as revealed with a fluorescent substrate: II. Kinetic properties of NBD-taurine transfer in asymmetric conditions

The transport of inorganic anions across human red blood cell membranes is accomplished by a carrier-like mechanism which involves an electroneutral and obligatory one-for-one anion exchange. The transport kinetics were described by models that involve alternation of single transport sites between the two membrane surfaces. These models predict that each carrier shows either an inward-facing Ei or an outward-facing Eo, conformation, each capable of binding either a monovalent anion or a divalent anion + a proton, to yield an electroneutral translocating complex. Unidirectional transport rates provide, therefore, a measure for the relative concentration of carriers at a given membrane surface. In the present work we assessed how modulation of the transmembrane distribution of carriers by the anion composition of cells and media, and by pH, affect the anion transport system. We have set the system in asymmetric conditions with respect to anions, so that a fast transportable anion (e.g., chloride) was present in one side of the membrane and slow transportable anions (e.g., sulfate, phosphate, oxalate, isethionate, gluconate, HEPES) were present on the other side of the membrane. The skewed distribution of carriers induced in these conditions were assessed by two methods: 1) NBD-taurine transfer which provided a measure for [Ei], the monovalent inward-facing form of the carrier, and 2) inhibition of NBD-taurine transfer by the specific impermeant and competitive inhibitor 4,4'-dinitro-2,2'-stilbene disulfonic acid (DNDS), which provided a measure for the availability of the carrier at the outer membrane surface. In the various symmetric and asymmetric conditions, we found marked differences in transport rates and transport profiles as well as in the susceptibility of the system to inhibition by DNDS. Direct binding studies of DNDS to cells in the various asymmetric conditions supported the conclusion derived from transport studies that transport sites can be recruited towards the membrane surface facing the slow transportable anions.     

Anion transport heterogeneity detected by flow cytometric measurement of NBD-taurine efflux kinetics

NBD-taurine [N-(7-nitrobenzofuran-4-yl) taurine], a fluorescent substrate for the human erythrocyte anion exchange system, has been used to test the feasibility of making flow cytometric measurements of anion transport in K562 erythroleukemic cells. Cells were preloaded by incubation with 20 microM-2mM NBD-taurine, then diluted 10-30-fold, and efflux was monitored by measuring fluorescence intensity (FL) as a function of time using excitation at 488 nm. The observed rate of decrease in fluorescence was sensitive to temperature and also to phloretin, a compound known to inhibit anion transport and other carrier-mediated transport processes. The coefficient of variation (CV) of the fluorescence distribution increased markedly over the efflux period, suggesting heterogeneity of the K562 population with respect to the rate constant for NBD-taurine efflux. This heterogeneity was also reflected in the upward curvature of a first order plot of log (FLt - FL infinity) versus time. Half-times calculated from initial linear portions of the first-order plots were found to decrease as the loading concentration of NBD-taurine was decreased, as predicted for a saturable transport system. NBD-taurine is not an ideal anion transport substrate for flow cytometric studies. It appears to bind to high-affinity sites within the cells with consequent fluorescence quenching, complicating interpretation of kinetic curves at low concentrations.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interactions of bromide, iodide, and fluoride with the pathways of chloride transport and diffusion in human neutrophils

Isolated human neutrophils possess three distinct pathways by which Cl- crosses the plasma membrane of steady state cells: anion exchange, active transport, and electrodiffusion. The purpose of the present work was to investigate the selectivity of each of these separate processes with respect to other external halide ions. (a) The bulk of total anion movements represents transport through an electrically silent anion-exchange mechanism that is insensitive to disulfonic stilbenes, but which can be competitively inhibited by alpha-cyano-4-hydroxycinnamate (CHC; Ki approximately 0.3 mM). The affinity of the external translocation site of the carrier for each of the different anions was determined (i) from substrate competition between Cl- and either Br-, F-, or I-, (ii) from trans stimulation of 36Cl- efflux as a function of the external concentrations of these anions, (iii) from changes in the apparent Ki for CHC depending on the nature of the replacement anion in the bathing medium, and (iv) from activation of 82Br- and 125I- influxes by their respective ions. Each was bound and transported at roughly similar rates (Vmax values all 1.0-1.4 meq/liter cell water.min); the order of decreasing affinities is Cl- greater than Br- greater than F- greater than I- (true Km values of 5, 9, 23, and 44 mM, respectively). These anions undergo 1:1 countertransport for internal Cl-. (b) There is a minor component of total Cl- influx that constitutes an active inward transport system for the intracellular accumulation of Cl- [( Cl-]i approximately 80 meq/liter cell water), fourfold higher than expected for passive distribution. This uptake is sensitive to intracellular ATP depletion by 2-deoxy-D-glucose and can be inhibited by furosemide, ethacrynic acid, and CHC, which also blocks anion exchange. This active Cl- uptake process binds and transports other members of the halide series in the sequence Cl- greater than Br- greater than I- greater than F- (Km values of 5, 8, 15, and 41 mM, respectively). (c) Electrodiffusive fluxes are small. CHC-resistant 82Br- and 125I- influxes behave as passive leak fluxes through low-conductance ion channels: they are nonsaturable and strongly voltage dependent. These anions permeate the putative Cl- channel in the sequence I- greater than Br- greater than Cl- with relative permeability ratios of 2.2:1.4:1, respectively, where PCl approximately 5 X 10(-9) cm/s.