Stoichiometry of a half-turnover of band 3, the chloride transport protein of human erythrocytes

The kinetics of human red blood cell Cl transport have been studied under nonequilibrium conditions to determine whether or not an outward Cl gradient can recruit the transport protein from an inward-facing to an outward-facing configuration. Three kinds of evidence are consistent with this outward recruitment. First, the initial net Cl efflux into a Cl-free phosphate medium is independent of the intracellular Cl concentration in the range 20-170 mM. Second, an outward Cl gradient strongly enhances the inhibitory potency of DNDS (4,4'-dinitro-2,2'-stilbene disulfonate), which suggests that DNDS binds primarily to outward-facing states. Finally, we have estimated the number of Cl ions transported during the putative outward recruitment. Resealed red cell ghosts containing only 70 muM 36Cl were resuspended at 0 degrees C in a Cl-free, HCO3-free Na2SO4 medium. In the first 10 s, or approximately 10(6) Cl ions per ghost, followed by a much slower further loss of Cl. The rapid loss of 10(6) Cl ions per ghost, which is abolished by pretreatment with DIDS (4,4'-diisothiocyano-2,2'-stilbene disulfonate), appears to represent the Cl that is transported during the first half-turnover of the transport cycle. These data are strong evidence that the influx and efflux events in the catalytic cycle for anion transport do not take place simultaneously, and that the stoichiometry of the transport cycle is close to one pair of anions exchanged per band 3 monomer.     

ADP+orthophosphate (P(i)) stimulates an Na/K pump-mediated coefflux of P(i) and Na in human red blood cell ghosts

The Na/K pump in human red blood cells that normally exchanges 3 Nai for 2 Ko is known to continue to transport Na in a ouabain-sensitive and ATP-dependent manner when the medium is made free of both Nao and Ko. Although this Na efflux is called "uncoupled" because of removal of ions to exchange with, the efflux has been shown to be comprised of a coefflux with cellular anions. The work described in this paper presents a new mode of operation of uncoupled Na efflux. This new mode not only depends upon the combined presence of ADP and intracellular orthophosphate (P(i))i but the Na efflux that is stimulated to occur is coeffluxed with (P(i))i. These studies were carried out with DIDS- treated resealed red cell ghosts, suspended in buffered (NMG)2SO4, that were made to contain, in addition to other constituents, varying concentrations of ADP and P(i) together with Na2 SO4, MgSO4 and hexokinase. While neither ADP nor P(i) was effective alone, ouabain- sensitive uncoupled Na efflux, (measured with 22Na) could be activated by [ADP+P(i)] where the K0.5 for ADP in the presence of 10 mmol (P(i))i/liter ghosts was 100-200 mumol/liter ghosts and the K0.5 for (P(i))i, in the presence of 500 mumol ADP/liter ghosts was 3-4 mmol/liter ghosts. [ADP+P(i)] activation of this Na efflux could be inhibited by as little as 2 mumol ATP/liter ghosts but the inhibition could be relieved by the addition of 50 mM glucose, given entrapped hexokinase. While ouabain-sensitive Na efflux was found to be coeffluxed with P(i) (measured with entrapped [32P]H3PO4), this was not so for SO4 (measured with 35SO4). The stoichiometry of Na to P(i) efflux was found to be approximately 2 to 1. Na efflux as well as (P(i))i efflux were both inhibited by 10 mM Nao (K0.5 approximately equal to 4 mM). But, whereas 20 mM Ko (K0.5 approximately equal to 6 mM) inhibited the efflux of (P(i))i, as would be expected from previous work, Na efflux was actually increased. When Ko influx was measured in this situation there was a 1 for 1 exchange of Nai for Ko, that is, of course, downhill with respect to the gradient of each ion. Surprisingly AsO4 was unable to replace P(i) for activation of Na efflux but Na efflux could be inhibited by vanadate and oligomycin. In terms of mechanism, it is likely that ADP acts to promote the formation of the phosphoenzyme (EP) by (P(i))i that would otherwise be inhibited by Nai.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Sodium pump-catalyzed sodium-sodium exchange associated with ATP hydrolysis

Inside-out red cell membrane vesicles have been used to study sodium interactions with the ATP-dependent sodium pump at sites accessible to both membrane surfaces. ATP-dependent 22Na+ influx (equivalent to efflux from cells) shows sigmoid dependence on extravesicular Na+ concentration. This is observed both in the absence of intravesicular cations and in the presence of intravesicular K or Rb ions. The kinetic behavior is similar to that observed earlier with intact cells, (Garay, R. P., and Garrahan, P. J. (1973) J. Physiol. (Lond.) 231, 297-325) and is consistent with a ratio of close to three Na ions transported per molecule of ATP hydrolyzed. With vesicles having relatively high intravesicular sodium concentration, (approximately 50 mM NaCl), the sodium pump effects an ATP-dependent sodium efflux coupled to sodium influx and to strophanthidin-sensitive ATP hydrolysis. The influx:efflux stoichiometry is approximately 1:1, and the influx:ATP hydrolysis ratio is close to 3. This ATP-dependent exchange has a higher affinity for vanadate than ATP plus ADP-dependent sodium exchange. It is concluded that this sodium-sodium exchange mode resembles sodium-potassium exchange whereby intravesicular sodium, i.e. sodium at the extracellular surface, at relatively high concentration, behaves like potassium.     

Sodium pump-mediated ATP:ADP exchange. The sided effects of sodium and potassium ions

Resealed human red cell ghosts containing caged ATP (Kaplan et al., 1978) and [3H]ADP were irradiated at 340 nm. The photochemical release of free ATP initiated a rapid transphosphorylation reaction (ATP:ADP exchange), a component of which is inhibited by ouabain. The reaction rate was measured by following the rate of appearance of [3H]ATP. The sodium pump-mediated ATP:ADP exchange reaction showed high-affinity stimulation by Mg ions (less than 10 microM) and was inhibited at higher levels. At optimal [Mg], extracellular Na (Nao) had a biphasic effect. Nao progressively inhibited the reaction rate between 0 and 10 mM and stimulated at higher levels. Intracellular Na (Nai) activated the reaction; the rate was maximal when Nai was 1 mM and remained unaltered up to 115 mM Nai at constant Nao. Extracellular K ions (Ko) inhibited the reaction; at high Nao, half-maximal inhibition was observed with 0.9 mM Ko. Lio inhibited the exchange rate with a lower affinity than Ko; half-maximal inhibition was produced by approximately 50 mM Lio. Intracellular K ions were without dramatic effect on the reaction rate in the concentration range where Ko inhibited completely. The relationship between these observations and previous studies on porous preparations is discussed, as well as the extent to which these observations support the hypothesis that the sodium pump-mediated ATP:ADP exchange reaction accompanies the Na:Na exchange transport mode of the sodium pump.     

Functional carboxyl groups in the red cell anion exchange protein. Modification with an impermeant carbodiimide

Anion exchange in human red blood cell membranes was inactivated using the impermeant carbodiimide 1-ethyl-3-(4-azonia-4,4-dimethylpentyl)-carbodiimide (EAC). The inactivation time course was biphasic: at 30 mM EAC, approximately 50% of the exchange capacity was inactivated within approximately 15 min; this was followed by a phase in which irreversible exchange inactivation was approximately 100-fold slower. The rate and extent of inactivation was enhanced in the presence of the nucleophile tyrosine ethyl ester (TEE), suggesting that the inactivation is the result of carboxyl group modification. Inactivation (to a maximum of 10% residual exchange activity) was also enhanced by the reversible inhibitor of anion exchange 4,4'-dinitrostilbene-2,2'-disulfonate (DNDS) at concentrations that were 10(3)-10(4) times higher than those necessary for inhibition of anion exchange. The extracellular binding site for stilbenedisulfonates is essentially intact after carbodiimide modification: the irreversible inhibitor of anion exchange 4,4'-diisothiocyanostilbene-2,2'-disulfonate (DIDS) eliminated (most of) the residual exchange activity: DNDS inhibited the residual (DIDS-sensitive) Cl- at concentrations similar to those that inhibit Cl- exchange of unmodified membranes: and Cl- efflux is activated by extracellular Cl-, with half-maximal activation at approximately 3 mM Cl-, which is similar to the value for unmodified membranes. But the residual anion exchange function after maximum inactivation is insensitive to changes of extra- and intracellular pH between pH 5 and 7. The titratable group with a pKa of approximately 5.4, which must be deprotonated for normal function of the native anion exchanger, thus appears to be lost after EAC modification.     

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.     

pH dependence of phosphate transport across the red blood cell membrane after modification by dansyl chloride

Dansylation of the red blood cell membrane inhibits monovalent anion transport as measured by means of 36C1 and enhances divalent anion transport as measured by means of 35SO4 (Legrum, Fasold and Passow (1980) Hoppe-Seyler's Z. Physiol. Chem. 361, 1573-1590 and Lepke and Passow (1982) J. Physiol. (London) 328, 27-48). In the present work the effect of dansylation on phosphate equilibrium exchange was studied over the pH range where the ratio between monovalent and divalent phosphate anions varies. At high pH, phosphate equilibrium exchange was enhanced; at low pH, exchange was inhibited. The pH maximum of phosphate equilibrium exchange, seen at pH 6.3 in untreated ghosts is now replaced by a plateau. The inverse effects of dansylation on the rates of exchange at high and low pH suggest that both monovalent and divalent phosphate anions are accepted as substrates by the anion transport protein. A tentative attempt to obtain a quantitative estimate of the ratio of monovalent and divalent phosphate transport indicates that in the untreated red cell membrane over the pH range 7.2-8.5 the transport of HPO42- is negligible compared to the transport of H2PO4-.     

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.     

Effects of N-ethylmaleimide on ouabain-insensitive cation fluxes in human red cell ghosts

In red cells of several species, the sulfhydryl reagent N-ethylmaleimide activates a Cl- -dependent, ouabain-resistant K+ transport pathway. Here we report our attempts to demonstrate ouabain-resistant Cl- -dependent K+ fluxes stimulated by N-ethylmaleimide in resealed human red cell ghosts using Rb+ as a K+ analogue. In contrast to intact cells, the rate constants of the base level Rb+ efflux in ghosts were similar in NaNO3 and NaCl (okRb = 0.535 +/- 0.079 h-1 and 0.534 +/- 0.085 h-1, respectively), while 1 mM N-ethylmaleimide stimulated Rb+ efflux strongly in NaNO3 (okRb = 14.26 +/- 1.32 h-1) and moderately in NaCl (okRb = 2.73 +/- 0.54 h-1). This effect was dependent on the presence of internal ATP. Stimulation of Rb+ efflux was observed in the presence of greater than or equal to 0.2 mM N-ethylmaleimide and increased at pH values approaching 8.0, consistent with titration of SH groups. N-Ethylmaleimide-stimulated Rb+ efflux was approx. 50% inhibited by 100 microM quinine sulfate whereas 1 microM bumetanide had no effect. In NaCl the N-ethylmaleimide-stimulated efflux saturated with initial internal ghost Rb+ concentration, but rates increased linearly in NaNO3. Replacement of external Na+ with glucamine or choline decreased the N-ethylmaleimide-stimulated Rb+ efflux, suggesting a role for external Na+. N-Ethylmaleimide-stimulated Rb+ efflux was greater in buffers with lipophilic anions such as SCN- or NO3- than in solutions with Cl- or acetate. However, the cation selectivity of the pathway studied was low, as Li+ efflux was also stimulated by N-ethylmaleimide. We conclude that the effect of N-ethylmaleimide on ouabain-resistant cation effluxes of human red cell ghosts is very different from the selective action of N-ethylmaleimide on Rb+ influxes in intact red cells.     

An immunological study of band 3, the anion transport protein of the human red blood cell membrane

Band 3, the predominant membrane-spanning polypeptide and purported anion transport protein of human red cells, was isolated by a new procedure which utilized selective solubilization and anion exchange chromatography on Affi-Gel 102 in 0.5% and Triton X-100/0.03% sodium dodecyl sulfate. Rabbit anti-serum prepared against the purified protein reacted with human and monkey band 3 but gave no immunoprecipitate with membrane proteins from several non-primate species. The antiserum was directed solely towards a portion of the cytoplasmic pole of the band 3 polypeptide contained within a 23,000 dalton amino-terminal fragment, as shown by agglutination, absorption, double diffusion and immunoprecipitation techniques. Saturation of both surfaces of resealed erythrocyte ghosts with the anti-band 3 antiserum had no significant effect on chloride transport. Our data define the topographically-limited immunogenicity of human band 3 in rabbits, demonstrate a lack of immunological cross-reactivity of band 3 between primates and non-primates, and support the hypothesis that the cytoplasmic domain of band 3 is not intimately involved in anion transport.     

Phosphate from the phosphointermediate (EP) of the human red blood cell Na/K pump is coeffluxed with Na, in the absence of external K

This study is concerned with Na/K pump-mediated phosphate efflux that occurs during uncoupled Na efflux in human red blood cells. Uncoupled Na efflux is known to be a ouabain-sensitive mode of the Na/K pump that occurs in the absence of external Nao and Ko. Because this efflux (measured with 22Na) is also inhibited by 5 mM Nao, the efflux can be separated into a Nao-sensitive and a Nao-insensitive component. Previous work established that the Nao-sensitive efflux is actually comprised of an electroneutral coefflux of Na with cellular anions, such as SO4 (as 35SO4). The present work focuses on the Nao-insensitive component in which the principal finding is that orthophosphate (P(i)) is coeffluxed with Na in a ouabain-sensitive manner. This P(i) efflux can be seen to occur, in the absence of Ko, in both DIDS-treated intact cells and resealed red cell ghosts. This efflux of P(i) was shown to be derived directly from the pump's substrate, ATP, by the use of resealed ghosts made to contain both ATP and P(i) in which either the ATP or the P(i) were labeled with, respectively, [gamma-32P]ATP or [32P]H3PO4. (These resealed ghosts also contained Na, Mg, P(i), SO4, Ap5A, as well as an arginine kinase/creatine kinase nucleotide regenerating system for the control of ATP and ADP concentrations, and were suspended usually in (NMG)2SO4 at pH 7.4.) It was found that 32P was only coeffluxed with Na when the 32P was contained in [gamma-32P]ATP and not in [32P]H3PO4. This result implies that the 32P that is released comes from ATP via the pump's phosphointermediate (EP) without commingling with the cellular pool of P(i). Ko (as K2SO4) inhibits this 32P efflux as well as the Nao-sensitive 35SO4 efflux, with a K0.5 of 0.3-0.4 mM. The K0.5 for inhibition of P(i) efflux by Ko is not influenced by Nao, nor can Nao act as a congenor for Ko in any of the flux reactions involving Ko. The stoichiometry of Na to SO4 and Na to P(i) efflux is approximately 2:1 under circumstances where the stoichiometry of Na effluxed to ATP utilized is 3:1. From these and other results reported, it is suggested that there are two types of uncoupled Na efflux that differ from each other on the basis of their sensitivity to Nao, the source (cellular vs substrate) and kind of anion (SO4 vs P(i)) transported.(ABSTRACT TRUNCATED AT 400 WORDS)     

Succinate transport in Bacillus subtilis. Dependence on inorganic anions

Cations were generally ineffective in stimulating succinate transport in a succinate dehydrogenase mutant of Bacillus subtilis unless accompanied by polyvalent anions; phosphate and sulfate being particularly active. The K_m values for the phosphate or sulfate requirement were approx. 3 mM.Biphasic kinetics were characteristic of both the succinate (K_m values 0.1 and 1 mM), and inorganic phosphate (K_m values 0.1 and 3 mM) transport system(s). The phosphate transport system(s) was repressed by high inorganic phosphate and a coordinate increase in the transport of phosphate, arsenate, and phosphate-stimulated succinate transport accompanied growth in low phosphate media.A class of arsenate resistant mutants were simultaneously defective in the transport of arsenate, phosphate and succinate when cells were repressed for phosphate transport, however, the transport of these ions was regained in these mutants when grown in low phosphate media. Organic phosphate esters did not stimulate succinate transport in arsenate resistant mutants but were effective after growth in low phosphate media. Growth under phosphate limitation permitted the simultaneous regain of both phosphate and sulfate dependent succinate transport activities whereas sulfate limitation alone was ineffective.Succinate was not transported by an anion exchange diffusion mechanism since phosphate efflux was low or absent during succinate transport.The transport of C₄-dicarboxylates in B. subtilis is strongly stimulated by intracellular polyvalent anions. The absence of an anion permeability mechanism precludes succinate transport but partial escape from this restriction is mediated by the derepression of a phosphate transport system.     

Functional characterization of anion transport system isolated from human erythrocyte membranes.

The anion transport system of human red blood cells was isolated in vesicles containing the original lipids of the membrane and predominantly the 95,000-dalton polypeptides (Band 3) associated with intralipid particles. The vesicles display various characteristic properties of anion permeation closely resembling those of the native system. The properties include energy of activation, pH dependence, anion sleectivity, sensitivity to specific inhibitors, and exchange and net rates of sulfate transport. Based on these and other criteria, the functional properties of isolated vesicles could be equated with those of the intact cell system. Direct support for the involvement of 95,000-dalton polypeptides in permeation functions is provided.     

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.     

Evidence that inhibitors of anion exchange induce a transmembrane conformational change in band 3

The transport inhibitor, eosin 5-maleimide, reacts specifically at an external site on the membrane-bound domain of the anion exchange protein, Band 3, in the human erythrocyte membrane. The fluorescence of eosin-labeled resealed ghosts or intact cells was found to be resistant to quenching by CsCl, whereas the fluorescence of labeled inside-out vesicles was quenched by about 27% at saturating CsCl concentrations. Since both Cs+ and eosin maleimide were found to be impermeable to the red cell membrane and the vesicles were sealed, these results indicate that after binding of the eosin maleimide at the external transport site of Band 3, the inhibitor becomes exposed to ions on the cytoplasmic surface. The lifetime of the bound eosin maleimide was determined to be 3 ns both in the absence and presence of CsCl, suggesting that quenching is by a static rather than a dynamic (collisional) mechanism. Intrinsic tryptophan fluorescence of erythrocyte membranes was also investigated using anion transport inhibitors which do not appreciably absorb light at 335 nm. Eosin maleimide caused a 25% quenching and 4,4'-dibenzamidodihydrostilbene-2,2'-disulfonate) caused a 7% quenching of tryptophan fluorescence. Covalent labeling of red cells by either eosin maleimide or BIDS (4-benzamido-4'-isothiocyanostilbene-2,2'-disulfonate) caused an increase in the susceptibility of membrane tryptophan fluorescence to quenching by CsCl. The quenching constant was similar to that for the quenching of eosin fluorescence and was unperturbed by the presence of 0.5 M KCl. Neither NaCl nor Na citrate produced a large change in the relative magnitude of the tryptophan emission. The tryptophan residues that can be quenched by CsCl appear to be different from those quenched by eosin or BIDS and are possibly located on the cytoplasmic domain of Band 3. The results suggest that a conformational change in the Band 3 protein accompanies the binding of certain anion transport inhibitors to the external transport site of Band 3 and that the inhibitors become exposed on the cytoplasmic side of the red cell membrane.     

Effects of altering the ATP/ADP ratio on pump-mediated Na/K and Na/Na exchanges in resealed human red blood cell ghosts

Resealed human red blood cell ghosts were prepared to contain a range of ADP concentrations at fixed ATP concentrations and vice versa. ATP/ADP ratios ranging from approximately 0.2 to 50 were set and maintained (for up to 45 min) in this system. ATP and ADP concentrations were controlled by the addition of either a phosphoarginine- or phosphocreatine-based regenerating system. Ouabain-sensitive unidirectional Na efflux was determined in the presence and absence of 15 mM external K as a function of the nucleotide composition. Na/K exchange was found to increase to saturation with ATP (K 1/2 approximately equal to 250 microM), whereas Na/Na exchange (measured in K-free solutions) was a saturating function of ADP (K 1/2 approximately equal to 350 microM). The elevation of ATP from approximately 100 to 1,800 microM did not appreciably affect Na/Na exchange. In the presence of external Na and a saturating concentration of external K, increasing the ADP concentration at constant ATP was found to decrease ouabain-sensitive Na/K exchange. The decreased Na/K exchange that still remained when the ADP/ATP ratio was high was stimulated by removal of external Na. Assuming that under normal substrate conditions the reaction cycle of the Na/K pump is rate-limited by the conformational change associated with the release of occluded K [E2 X (K) X ATP----E1 X ATP + K], increasing ADP inhibits the rate of these transformations by competition with ATP for the E2(K) form. A less likely alternative is that inhibition is due to competition with ATP at the high-affinity site (E1). The acceleration of the Na/K pump that occurs upon removing external Na at high levels of ADP evidently results from a shift in the forward direction of the transformation of the intermediates involved with the release of occluded Na from E1P X (Na). Thus, the nucleotide composition and the Na gradient can modulate the rate at which the Na/K pump operates.     

Proton-activated rubidium transport catalyzed by the sodium pump

Although the sodium pump normally exchanges three sodium for two potassium ions, experiments with inside-out red cell membrane vesicles show that the stoichiometry is reduced when the cytoplasmic sodium concentration is decreased to less than 1 mM. The present study was designed to gain insight into the question whether other monovalent cations, particularly protons, can act as sodium congeners in effecting pump-mediated potassium transport (ATP-dependent rubidium efflux from inside-out vesicles). The results show that at low cytoplasmic sodium concentration, an increase in proton concentration effects a further reduction in sodium:rubidium stoichiometry, to a value less than the minimal expected (1Na+:3Rb+). Furthermore, when vesicles containing 86RbCl are incubated in nominally sodium-free medium. ATP-dependent net rubidium efflux (normal influx) occurs when the pH is reduced from approximately 7.0 to 6.2 or less. This efflux is inhibited by strophanthidin and vanadate. These experiments support the notion that the sodium pump can operate as an ATP-dependent proton-activated rubidium (potassium) pump without obligatory countertransport of sodium ions.     

Ca-induced K transport in human red blood cell ghosts containing arsenazo III. Transmembrane interactions of Na, K, and Ca and the relationship to the functioning Na-K pump

Increasing free intracellular Ca (Cai) from less than 0.1 microM to 10 microM by means of A23187 activated Ca-stimulated K transport and inhibited the Na-K pump in resealed human red cell ghosts. These ghosts contained 2 mM ATP, which was maintained by a regenerating system, and arsenazo III to measure Cai. Ca-stimulated K transport was activated 50% at 2-3 microM free Cai and the Na-K pump was inhibited 50% by 5-10 microM free Cai. Free Cai from 1 to 8 microM stimulated K efflux before it inhibited the Na-K pump, dissociating the effect of Ca on the two systems. 3 microM trifluoperazine inhibited Ca-stimulated K efflux and 0.5 mM quinidine reduced Na-K pumping by 50%. In other studies, incubating fresh intact cells in solutions containing Ca and 0.5 microM A23187 caused the cells to lose K heterogeneously. Under the same conditions, increasing A23187 to 10 microM initiated a homogeneous loss of K. In ATP-deficient ghosts containing Cai equilibrated with A23187, K transport was activated at the same free Cai as in the ghosts containing 2 mM ATP. Neither Cao nor the presence of an inward Ca gradient altered the effect of free Cai on the permeability to K. In these ghosts, transmembrane interactions of Na and K influenced the rate of Ca-stimulated K efflux independent of Na- and K-induced changes in free Cai or sensitivity to Cai. At constant free Cai, increasing Ko from 0.1 to 3 mM stimulated K efflux, whereas further increasing Ko inhibited it. Increasing Nai at constant Ki and free Cai markedly decreased the rate of efflux at 2 mM Ko, but had no effect when Ko was greater than or equal to 20 mM. These transmembrane interactions indicate that the mechanism underlying Ca-stimulated K transport is mediated. Since these interactions from either side of the membrane are independent of free Cai, activation of the transport mechanism by Cai must be at a site that is independent of those responsible for the interaction of Na and K. In the presence of A23187, this activating site is half-maximally stimulated by approximately 2 microM free Ca and is not influenced by the concentration of ATP. The partial inhibition of Ca-stimulated K efflux by trifluoperazine in ghosts containing ATP suggests that calmodulin could be involved in the activation of K transport by Cai.(ABSTRACT TRUNCATED AT 400 WORDS)     

Membrane transport of anandamide through resealed human red blood cell membranes

The use of resealed red blood cell membranes (ghosts) allows the study of the transport of a compound in a nonmetabolizing system with a biological membrane. Transmembrane movements of anandamide (N-arachidonoylethanolamine, arachidonoylethanolamide) have been studied by exchange efflux experiments at 0 degrees C and pH 7.3 with albumin-free and albumin-filled human red blood cell ghosts. The efflux kinetics is biexponential and is analyzed in terms of compartment models. The distribution of anandamide on the membrane inner to outer leaflet pools is determined to be 0.275 +/- 0.023, and the rate constant of unidirectional flux from inside to outside is 0.361 +/- 0.023 s(-1). The rate constant of unidirectional flux from the membrane to BSA in the medium ([BSA]o) increases with the square root of [BSA]o in accordance with the theory of an unstirred layer around ghosts. Anandamide passed through the red blood cell membrane very rapidly, within seconds. At a molar ratio of anandamide to BSA of <1, membrane binding of anandamide increases with increasing temperatures between 0 degrees C and 37 degrees C, and the equilibrium dissociation constants are in the nanomolar range. The nature of membrane binding and the mechanism of membrane translocation are discussed.