Chloride in the human erythrocyte

K-Cl cotransport, pH, and role of Mg in volume-clamped low-K sheep erythrocytes: three equilibrium states

Ouabain-resistant K efflux and Rb influx in Cl and NO3 media were studied in volume-clamped low-K (LK) sheep red blood cells (SRBC) with normal and experimentally reduced cytoplasmic Mg (Mgi) levels as function of pH and at 37 degrees C. Sucrose was added to solutions with constant ionic strength and variable pH to maintain normal cell volume. Cl-dependent ouabain-resistant K(Rb) fluxes (K-Cl cotransport) at unity relative cell volume exhibited a maximum at pH approximately 7 in normal-Mgi LK cells consistent with the apparent acid pH activation reported for human erythrocytes. However, in LK SRBC with Mgi lowered by A-23187 and an external Mg chelator, K(Rb)-Cl cotransport was reversibly activated as the pH was raised from 6.5 to 9. The alkaline pH effect on Cl-dependent Rb influx in low-Mgi LK SRBC was due to a 10-fold rise in the maximum velocity values without a major change in the Km values. The pH dependence of the experimental flux reversal point, i.e., the extracellular Rb concentration at which no net K-Cl cotransport occurs, approximately paralleled that of the flux reversal point predicted from the ratio of the ion products, in both control and low-Mgi LK cells, albeit with a small displacement to higher extracellular Rb concentration at all pH values. The kinetic data can be explained by a general minimum three-state equilibrium in which deprotonation recruits transporters from a resting R state into the active A state modified by Mgi to an inactive I state.(ABSTRACT TRUNCATED AT 250 WORDS)

How do the polyene macrolide antibiotics affect the cellular membrane properties?

In the 1970's great strides were made in understanding the mechanism of action of amphotericin B and nystatin: the formation of transmembrane pores was clearly demonstrated in planar lipid monolayers, in multilamellar phospholipid vesicles and in Acholeplasma laidlawii cells and the importance of the presence and of the nature of the membrane sterol was analyzed. For polyene antibiotics with shorter chains, a mechanism of membrane disruption was proposed. However, recently obtained data on unilamellar vesicles have complicated the situation. It has been shown that: membranes in the gel state (which is not common in cells), even if they do not contain sterols may be made permeable by polyene antibiotics, several mechanisms may operate, simultaneously or sequentially, depending on the antibiotic/lipid ratio, the time elapsed after mixing and the mode of addition of the antibiotic, there is a rapid exchange of the antibiotic molecules between the vesicles. Although pore formation is apparently involved in the toxicity of amphotericin B and nystatin, it is not the sole factor which contributes to cell death, since K+ leakage induced by these antibiotics is separate from their lethal action. The peroxidation of membrane lipids, which has been demonstrated for erythrocytes and Candida albicans cells in the presence of amphotericin B, may play a determining role in toxicity concurrently with colloid osmotic effect. On the other hand, it has been shown that the action of polyene antibiotics on cells is not always detrimental: at sub-lethal concentrations these drugs stimulate either the activity of some membrane enzymes or cellular metabolism. In particular, some cells of the immune system are stimulated. Furthermore, polyene antibiotics may act synergistically with other drugs, such as antitumor or antifungal compounds. This may occur either by an increased incorporation of the drug, under the influence of a polyene antibiotic-induced change of membrane potential, for example, or by a direct interaction of both drugs. That fungal membranes contain ergosterol while mammalian cell membranes contain cholesterol, has generally been considered the basis for the selective toxicity of amphotericin B and nystatin for fungi. Actually, in vitro studies have not always borne out this assumption, thereby casting doubt on the use of polyene antibiotics as antifungal agents in mammalian cell culture media.(ABSTRACT TRUNCATED AT 400 WORDS)

Anion transport systems in the plasma membrane of vertebrate cells

In the case of the red blood cell, anion transport is a highly specific one-for-one exchange catalyzed by a major membrane protein known as band 3 or as capnophorin. This red cell anion-exchange system mediates the Cl-(-)HCO3- exchange responsible for most of the bicarbonate transport capacity of the blood. The rapidly expanding knowledge of the molecular biology and the transport kinetics of this specialized transport system is very briefly reviewed in Section III. Exchange diffusion mechanisms for anions are found in many cells other than erythrocytes. The exchange diffusion system in Ehrlich cells has several similarities to that in red cells. In several cell types (subsection IV-B), there is evidence that intracellular pH regulation depends on Cl-(-)HCO3- exchange processes. Anion exchange in other single cells is described in Section IV, and its role in pH regulation is described in Section VII. Anion exchange mechanism operating in parallel with, and only functionally linked to Na+-H+ or K+-H+ exchange mechanisms can also play a role in cell volume regulation as described in Section VII. In the Ehrlich ascites cell and other vertebrate cells, electroneutral anion transfer has been found to occur also by a cotransport system for cations and chloride operating in parallel with the exchange diffusion system. The cotransport system is capable of mediating secondary active chloride influx. In avian red cells, the cotransport system has been shown to be activated by adrenergic agonists and by cyclic AMP, suggesting that the cotransport is involved in regulatory processes (see subsection V-A.). In several cell types, cotransport systems are activated and play a role during volume regulation, as described in Section V and in Section VII. It is also likely that this secondary active cotransport of chloride plays a significant role for the apparently active extrusion of acid equivalents from certain cells. If a continuous influx of chloride against an electrochemical gradient is maintained by a cotransport system, the chloride disequilibrium can drive an influx of bicarbonate through the anion exchange mechanism, as described in Section VII. Finally, even the electrodiffusion of anions is shown to be regulated, and in Ehrlich cells and human lymphocytes an activation of the anion diffusion pathway plays a major role in cell volume regulation as described in Section VI and subsection VII-B.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of the Band 3 substrate site in human red cell ghosts by NDS-TEMPO, a disulfonatostilbene spin probe: the function of protons in NDS-TEMPO and substrate-anion binding in relation to anion transport

NDS-TEMPO is a specific disulfonatostilbene spin label for the Band 3 substrate site (K.F. Schnell, W. Elbe, J. Käsbauer & E. Kaufmann, Biochim. Biophys. Acta 732:266-275, 1983). The pH dependence of NDS-TEMPO binding and of chloride and sulfate binding was studied in resealed human erythrocyte ghosts. pH was varied from 6.0 to 9.0. The ESR spectra from NDS-TEMPO-labeled red cell ghosts exhibited a strong immobilization of membrane-bound NDS-TEMPO. Changes of pH had no effect upon the mobility of membrane-bound NDS-TEMPO. A mutual competition between NDS-TEMPO binding and the binding of the substrate-anions, chloride and sulfate, was observed throughout the entire pH range. The maximal number of NDS-TEMPO binding sites per cell was in the range of 9.0 X 10(5) to 1.10 X 10(6) and was found to be insusceptible to changes of pH. The NDS-TEMPO/substrate-site and the chloride/substrate-site dissociation constants amounted to 1.25 microM and to 17 mM and were independent of pH from pH 6.0 to 8.0, while the sulfate/substrate-site dissociation constant displayed a strong pH dependency with a maximum of approximately 50 mM at about pH 7.0. The NDS-TEMPO inhibition constants from the chloride and the sulfate flux experiments were 0.5 microM (0 degree C) and 1.8 microM (25 degrees C), respectively, and are in close accordance with the NDS-TEMPO/substrate-site dissociation constants. Our studies provide strong evidence for the assumption that NDS-TEMPO binds in fact to the substrate site of Band 3. They show that the strong pH dependence of the chloride and of the sulfate transport cannot result from the pH dependency of substrate-anion binding, but point to the participation of ionizable regulator sites in transport catalysis. These regulator sites seem to be positioned outside the substrate site of the Band 3 transport domain.

Concentration dependence of the chloride selfexchange and homoexchange fluxes in human red cell ghosts

The concentration dependence of the unidirectional chloride flux in human red cell ghosts was studied under selfexchange and under homoexchange conditions. Under selfexchange conditions the intracellular concentration of chloride [Cl]in is equal to the extracellular concentration [Cl]ex and [Cl]in and [Cl]ex are raised concomitantly. Under homoexchange conditions [Cl]in or [Cl]ex were varied separately at a fixed trans-concentration of chloride. The chloride fluxes were calculated from the rate of the tracer efflux and the intracellular chloride. All experiments were executed in isotonic (330 mosM) KCl/K-citrate/sorbitol solutions containing 0-100 mM KCl, 40 mM K-citrate and different concentrations of sorbitol for isoosmotic substitution. The chloride selfexchange and the chloride homoexchange fluxes exhibit a pure saturation kinetics. The halfsaturation constant for the chloride selfexchange was approximately 20 mM, the maximal flux was approx. 3.5 X 10(-4) mol/(min . g cells). The apparent chloride halfsaturation constants from the homoexchange experiments were in the range of 0.9-4.5 mM for the outer and of 5.5-14.5 mM (0 degree C, pH 7.3) for the inner membrane surface, both halfsaturation constants increase with increasing trans-concentrations. At infinite trans-concentrations of chloride, the halfsaturation constant for the outer and the inner membrane surface amounts to approximately 5 mM and approximately 15 mM, respectively. The slope of the double reciprocal plots of flux versus cis-chloride concentration decreases with increasing trans-concentration of chloride. The kinetics of the chloride transport provides evidence for a carrier mediated transport mechanism with a single reciprocating transport site. The translocation of the loaded carrier appears to be much faster than the translocation of the unloaded carrier.(ABSTRACT TRUNCATED AT 250 WORDS)

Rainbow trout red cells in vitro

Washed rainbow trout erythrocytes incubated at 14 degrees C in Eagle's minimal essential medium and Cortland saline displayed sharp reductions in volume and water content, nucleoside triphosphate, K+ and Cl- concentrations. Mg2+ and, to a lesser extent, Na+ concentrations increased. Cellular to medium Cl- ratios were indicative of membrane hyperpolarization. Morphological irregularities were also observed. Oxygen consumption and hemoglobin system organization were not grossly affected. Supplementation with pyruvate stabilized nucleoside triphosphate concentrations for at least 24 hr, and reduced rates of volume and compositional change to some extent. Addition of norepinephrine at physiologically realistic levels led to stabilization of Cl- content and reductions in Mg2+ accumulation and water loss. Transient but modest increases in K+ and Ca2+ were coupled, under these circumstances, with some decrease in Na+ concentration. Factors which may contribute to the dysfunctional status of these cells in vitro are discussed.

Concentration dependence of the unidirectional sulfate and phosphate flux in human red cell ghosts under selfexchange and under homoexchange conditions

The concentration dependence of the sulfate and the phosphate selfexchange and homoexchange fluxes was studied in resealed red cell ghosts (25 degrees C, pH 7.3). The selfexchange fluxes were calculated from the rate constant of the tracer back-exchange and from the intracellular substrate anion content. The homoexchange fluxes were determined from the initial cis-to-trans tracer fluxes and the initial specific substrate anion activities at the cis-membrane side. Sulfate and phosphate concentrations ranging from approx. 2-100 mM were employed. The selfexchange fluxes of sulfate and of phosphate exhibit sigmoidal flux/concentration curves. The apparent Hill coefficients were in the range of 1.2-1.4 indicating a type of positive cooperativity. Under homoexchange conditions the positive cooperativity of the flux/concentration curves disappears. The outward homoexchange fluxes of sulfate and phosphate display a saturation kinetics with Hill coefficients close to 1.0. The inward homoexchange fluxes exhibit a negative type of cooperativity with Hill coefficients smaller than 1.0. The sulfate and the phosphate half-saturation concentrations for the outer and the inner membrane surface are equal in size and amount to approx. 35 mM for sulfate and to approx. 110 mM for phosphate, respectively. The positive cooperativity of the unidirectional sulfate and phosphate fluxes under selfexchange conditions and the disappearance of the positive cooperativity under homoexchange conditions indicate a cooperativity of the translocation process. The saturation of the outward homoexchange flux and the negative cooperativity of the inward homoexchange flux suggest a substrate anion binding according to the law of mass action at the inner and a negative cooperativity of substrate anion binding at the outer membrane surface.

Electron spin resonance studies on the inorganic-anion-transport system of the human red blood cell. Binding of a disulfonatostilbene spin label (NDS-TEMPO) and inhibition of anion transport

The disulfonatostilbene spin label, NDS-TEMPO, was synthesized (purity over 96%) and the binding of the spin label to human red-cell ghosts was studied. NDS-TEMPO is readily absorbed to the membrane surface. Both pretreatment of the ghosts with FDNB and DIDS and the presence of DNDS completely prevent the binding of NDS-TEMPO to red-cell ghosts. Chloride and sulfate competitively inhibit the binding of NDS-TEMPO. Conversely, NDS-TEMPO is a strong, competitive inhibitor of chloride and of sulfate transport. The dissociation constants of NDS-TEMPO from the ESR studies were in the range 1.0-2.0 microM (pH 7.6, 20 degrees C). The inhibition constants of NDS-TEMPO as obtained from the flux experiments were in the range 0.5-2.5 microM (pH 7.3, 25 degrees C). The close accordance of the NDS-TEMPO dissociation constants from the ESR studies with the NDS-TEMPO inhibition constants from the flux measurements indicate a specific labeling of the inorganic-anion-transport system.

Transport of benzenesulfonic acid derivatives through the rat erythrocyte membrane

Transport of benzenesulfonic acid derivatives through the rat erythrocyte membrane was studied. The transport properties, such as pH-dependence and effects of reagents reacting with amino-groups, were similar to those to anions like Cl- through the human erythrocyte membrane. The rate of transport of anions through rat erythrocyte membranes is higher than through those of other mammals, such as guinea pig and bovine erythrocyte membranes. This relatively high rate of transport makes the rat erythrocyte membrane suitable for use in comparative studies on the transport of slowly penetrating substances, such as organic anions. The transport velocities of benezenesulfonic acid derivatives were compared with their physico-chemical properties. It was shown that the hydrophobicity has no effect on the transport, but the electronic property has a significant effect: the transport rate is mainly dependent on the e- donor capacities. This feature is the inverse to the well-known inhibitory effect of these derivatives on other anion transport: the inhibition is mainly dependent on the e- acceptor capacities. It is suggested that the transport is regulated by the binding capacity of anions to the transport site.

Characteristics of doxorubicin transport in human red blood cells

The doxorubicin (Adriamycin) transport was investigated by measuring the net efflux of dororubicin from loaded erythrocytes into doxorubicin-free media at 37 degree C. The doxorubicin concentration in the cell water was kept low (5-10 mumol/l). The doxorubicin transport increased with increasing pH. The approx. pKa of the doxorubicin amino group was 7.6(37 degree C, ionic strength 0.15). Phloretin, l-alcohols and local anaesthetics increased doxorubicin transport after the fashion of the effect of these drugs on membrane transport of lipophilic compounds. Several inhibitors of facilitated transport systems in erythrocytes did not affect doxorubicin transport. The calcium and magnesium concentration in the cell water (0-2 mmol/l) did not affect doxorubicin transport. It appears that doxorubicin transport in human erythrocytes takes place by free diffusion of the electrically uncharged (unprotonated) doxorubicin molecule through the lipid domain of the cell membrane.

Phosphate transport in human red blood cells: concentration dependence and pH dependence of the unidirectional phosphate flux at equilibrium conditions

The concentration dependence and the pH dependence of the phosphate transport across the red cell membrane were investigated. The unidirectional phosphate fluxes were determined by measuring the 32P-phosphate self-exchange in amphotericin B (5 mumol/liter) treated erythrocytes at 25 degrees C. The flux/concentration curves display an S-shaped increase at low phosphate concentrations, a concentration optimum in the range of 150 to 200 mM phosphate and a self-inhibition at high phosphate concentrations. The apparent half-saturation concentrations, P(0.5), range from 50 to 70 mM and are little affected by pH. The self-inhibition constants, as far as they can be estimated, range from 400 to 600 mM. The observed maximal phosphate fluxes exhibit a strong pH dependence. At pH 7.2, the actual maximal flux is 2.1 X 10(-6) moles . min-1 . g cells-1. The ascending branches of the flux/concentration curves were fitted to the Hill equation. The apparent Hill coefficients were always in the range of 1.5-2.0. The descending branches of the flux/concentration curves appear to follow the same pattern of concentration response. The flux/pH curves were bell-shaped and symmetric with regard to their pH dependence. The pH optimum is at approximately pH 6.5-6.7. The apparent pK of the activator site is in the range of 7.0 to 7.2, while the apparent pK for the inactivating site is in the range of 6.2 to 6.5. The pK-values were not appreciably affected by the phosphate concentration. According to our studies, the transport system possesses two transport sites and probably two modifier sites as indicated by the apparent Hill coefficients. In addition, the transport system has two proton binding sites, one with a higher pK that activates and one with a lower pK that inactivates the transport system. Since our experiments were executed under self-exchange conditions, they do not provide any information concerning the location of these sites at the membrane surfaces.

The kinetics of anion equilibrium exchange across the red blood cell membrane as measured by means of 35S thiocyanate

Up to a SCN- concentration of about 110 mM, the concentration dependence of SCN- equilibrium exchange in human red cell ghosts can be represented by the superimposition of two flux components. One component shows saturation kinetics, the other does not. The saturable component has an activation enthalpy of 105 kJ/mole, exhibits a trans acceleration by Cl- and can be inhibited by H2DIDS. The nonsaturable component has a much lower activation enthalpy of 33 kJ/mole, is slightly reduced in trans acceleration experiments with Cl- and insensitive to H2DIDS but susceptible to inhibition by phloretin. At SCN- concentrations exceeding 110 mM, the saturable component undergoes irreversible self inhibition while the nonsaturable component remains unaltered. The half saturation concentration of the saturable flux component increases with decreasing pH from 3.0 mM at pH 7.4 to 13.3 mM at pH 6.0. Over this pH range, the maximal flux is only slightly increased from 19 x 10(-12) to 22 x 10(-12) moles x cm-2 x sec-1. The nonsaturable flux component also increases slightly. In accordance with previous observations of Wieth (J. Physiol. (London) 207:563-580, 1970), we find that SCN- increases K+ and Na+ permeability. The induced cation-permeability is considerably smaller than the SCN- exchange and the latter does not show the paradoxical temperature dependence that is known to pertain to the former.

Enhancement of anion equilibrium exchange by dansylation of the red blood cell membrane

Dansylation of resealed red cell ghosts enhances the band 3 protein-mediated equilibrium exchange of sulfate ions. After dansylation, the specific anion transport inhibitor 4,4'-diisothiocyanato-dihydrostilbene 2,2'-disulfonate (H2DIDS) is still capable of combining with its original binding site on the band 3 protein and of producing the same high degree of inhibition of sulfate exchange as in the untreated red cell ghost. Nevertheless, dansylation causes allosteric effects at the H2DIDS-binding site that exhibit themselves by an increased susceptibility to dinitrophenylation of one of the amino acid residues that is involved in the covalent bond formation with H2DIDS and a decrease of the apparent KI values for two reversibly acting inhibitors that are known to produce their effects at the H2DIDS-binding site of the band 3 protein. The degree of enhancement of divalent anion exchange depends on both the pH that existed during dansylation and the pH at which the anion equilibrium exchange across the dansylated membrane is measured. The effect of dansylation reaches a broad maximum around ph 6.6. In untreated ghosts, divalent anion equilibrium exchange passes through a maximum around pH 6.3. After dansylation under optimal conditions at pH 6.6, anion equilibrium exchange as measured below the maximum of pH 6.3 is much less enhanced than above the maximum. Under suitable experimental conditions, the maximum may be replaced by a plateau that extends up to at least pH 8.5. At this pH, the enhancement is about 100-fold. Thus, the pH dependence of divalent anion exchange becomes more similar to that of monovalent anion exchange. The apparent activation enthalpies for sulfate-equilibrium exchange across the modified membrane, as measured at pH 6.3 and 7.9, are indistinguishable, independent of temperature between 0 and 37 degrees C and amount to 146 kj/mol. This is similar to the activation enthalpies measured in the untreated membrane. The mode of action of dansyl chloride is discussed on the basis of currently considered mechanisms of divalent anion transport, for which the pertinent equations are presented.

Chloride transport by self-exchange and by KCl salt diffusion in gramicidin-treated red blood cells

The permeability of gramicidin-treated human red blood cell membranes to K+ and Cl- has been measured at normal ionic strength (1) by tracer exchange at steady-state distribution of salt, and (2) by net transport of salt in the presence of a salt concentration gradient. Under both conditions KCl was the only inorganic salt in cells and medium. In the studies of self-exchanges the electrical driving force on the ions was zero. Calculaton of permeability coefficients from net salt transport was simplified because the experiment was designed as a special case of the Nerst-Planck diffusion regime, i.e. the single salt case. Gramicidin altered the cell membranes from being anion to become cation selective. Gramicidin increased the potassium exchange without affecting the chloride exchange measurably. The chloride exchange showed saturation kinetics as does chloride exchange in normal cells. The net transport of KCl in the presence of a constant concentration gradient increased to a constant value with increasing gramicidin concentration. At high gramicidin concentrations (0 degree C, pH 7.2) the "chloride permeability coefficient" calculated from tracer exchange (1.9 x 10(-6) cm/s) was 290 times the chloride permeability coefficient calculated from net salt transport (0.65 x 10(-8) cm/s). The latter value corresponds to a chloride conductance of 4.2 x 10(-6) ohm-1 cm-2. The chloride permeability coefficient was 2.1 x 10(-6) cm/s at 25 degrees C (pH 6.8) indicating a value of 3 for the Q25. It appears that normal red cells are anion selective in the sense that anion permeability exceeds cation permeability with a factor of more than a hundred between 0 degrees C and body temperature. The anion exchange, i.e. the Hamburger shift, is a tightly coupled transport process which is several orders of magnitude faster than anion transport by salt diffusion.

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 transport in red blood cells. I. Chemical properties of anion recognition sites as revealed by structure-activity relationships of aromatic sulfonic acids

The present study is concerned with the chemical factors that determine the inhibitory properties of reversible aromatic sulfonic acids on sulfate exchange system of human red blood cells. Two series of compounds were tested for inhibitory potencies: benzene sulfonic acid (BS) and 2,2'-disulfonic stilbene (DS) derivatives, each series with substituent groups such as Cl, OH, NH2, NO2, NNN, N-acetamido, and N-benzoamido. As judged by various kinetic criteria, all congeners of BS and DS appear to have common sites of action in the anion transport system. The range of inhibitory potencies, as defined by the concentration required to produce 50% inhibition (ID50), varied over a 10(4) range (ID50:2-50,000 microM). The degree of inhibition was correlated with two physicochemical properties of the substituent groups: (a) lipophilicity, as judged by the pi values (Hansch factor) of the groups; and (b) the electronic character, as judged by sigma values (Hammett factor) of the groups. Optimal correlations were obtained with a linear combination of the two factors. Based on the above structure-activity relationships and on a comparison between the inhibitory properties of congeners of BS and DS, we suggest that the microenvironment of substrate recognition sites bears a positive multipolar character and possesses functionally essential groups with electron donor capacity embedded in a hydrophobic area.

Anion transport in red blood cells. III. Sites and sidedness of inhibition by high-affinity reversible binding probes

Studies of binding of the reversible inhibitor DNDS (for abbreviations, see Nomenclature) and red blood cell membranes revealed 8.6 +/- 0.7 x 10(5) high-affinity binding sites per cell (KD = 0.8 +/- 0.4 muM). Under conditions of "mutual depletion," inhibition studies of anion exchange revealed 8.0 +/- 0.7 x 10(5) DNDS inhibitory sites per cell (KD = 0.87 +/- 0.04 muM). Binding and kinetics studies with DNDS indicate that there are 0.8 -- 0.9 x 10(6) functional anion transport sites per blood cell. The transport of DNDS displayed high temperature and concentration dependencies, chemical specificity, susceptibility to inhibition by DIDS, and differences between egress and ingress properties. Under conditions of no DNDS penetration (e.g., 0 degrees C), inhibition of anion exchange by DNDS showed marked sidedness from the outside inhibitions and were demonstrable at micromolar concentrations, whereas from the inside no inhibition occurred even at millimolar concentrations. The asymmetry of DNDS transport properties and the sidedness of binding and inhibition suggest that anion transport sites have a very low affinity for or are inaccessible to DNDS at the inner membrane face. The site of DNDS permeation, although susceptible to DIDS, is apparently not the site of anion exchange.

Asymmetry of the chloride transport system in human erythrocyte ghosts

The concentration dependence of the unidirectional chloride flux and the inhibition of the unidirectional chloride flux by sulfate were studied in human red cell ghosts. The concentration dependence of the unidirectional chloride flux and its inhibition by sulfate were asymmetric. The unidirectional chloride flux can be saturated from the inner and from the outer membrane surface. For the inner membrane surface, lower chloride half-saturation constants were obtained than for the outer membrane surface. The inhibition of the unidirectional chloride flux by sulfate is competitive. In contrast to the chloride half-saturation constants, the inhibition constants of sulfate for the inner membrane surface were higher than the inhibition constants of sulfate for the outher membrane surface. Either there are fixed anion binding sites at the inner and at the outer membrane surface which control the access of anions to a pore, or there is a mobile carrier which is in contact with both membrane surfaces. The asymmetry of the concentration response and of the inhibition of the unidirectional chloride flux suggest that the anion binding sites at the inner and at the outer membrane surface differ with respect to their affinities for chloride and for sulfate. Alternatively, the asymmetry of the chloride transport system could indicate an asymmetric distribution of a mobile anion carrier across the erythrocyte membrane.

Hypertonic cryohemolysis: ionophore and pH effects

Human erythrocytes suspended at 37 degrees C in hypertonic solution of either electrolytes or nonelectrolytes undergo hemolysis when the temperature is lowered toward 0 degrees C (Green, F.A., Jung, C.Y. 1977 J. Membrane Biol. 33:249). In the present studies this hypertonic cryohemolysis was profoundly affected by the pH of incubation, and was completely abolished at ph 5. In hypertonic NaCl, there was an apparent pH optimum at 6--6.5. In hypertonic sucrose, on the other hand, hemolysis increased progressively with increasing pH between 6 and 9. Amphotericin B inhibited hypertonic cryohemolysis in NaCl or KCl solution. No inhibiting effect of amphotericin B was observed when hypertonicity was due to sodium sulfate or sucrose. Valinomycin also inhibited hypertonic cryohemolysis in KCl, but did not affect the process in NaCl or sucrose solution. SITS (4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonate) and phloretin interfered with this valinomycin effect, whereas phlorizin did not. These results indicate that dissipation of an osmotic gradient across membranes may be responsible for the inhibition of the hemolysis by these inophores. Iso-osmotic cell shrinkage induced by valinomycin in 150 mM NaCl solution did not result in cryohemolysis.