Inhibition of anion permeability of sarcoplasmic reticulum vesicles by stilbene derivatives and the identification of an inhibitor-binding protein

The permeability of sarcoplasmic reticulum vesicles to sulfate ions was inhibited by diisothiocyano-1,2-diphenylethane-2,2′-disulfonic acid (H₂DIDS), which is a potent inhibitor of anion permeability in red blood cell membrane. The amount of H₂DIDS bound to the vesicles was determined by using [³H]-H₂DIDS. Apparent half inhibition of sulfate permeation was observed on the binding of 2.5 μmol/g protein. SDS-polyacrylamide gel electrophoresis of the vesicles treated with [³H]H₂DIDS showed that about 10% of the total bound H₂DIDS corresponds to a 100 000-dalton protein, but the remaining 90% to non-protein components. The content of the H₂DIDS-binding protein was about 0.5 μmol/g protein. These results suggest that the H₂DIDS-binding protein is different from the calcium pump protein and is possibly an anion transport system similar to band 3 in red blood cell membrane.     

Identification of the Cl− transport site of human red blood cells by a kinetic analysis of the inhibitory effects of a chemical probe

H₂DIDS, the dihydro analog of DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid) can interact covalently with membrane sites, resulting in an irreversible inhibition of anion exchange. At low temperatures (0°C) and for relatively short times, however, its interaction is largely reversible, so that a kinetic analysis of the nature of its inhibitory effect on Cl^? self exchange can be performed. The effects of variations in the chloride concentration on the inhibitory potency of H₂DIDS are consistent with the concept that Cl^? and H₂DIDS compete for the transport site of the anion exchange system. The value of K_i for H₂DIDS is 0.046 μM, indicating that H₂DIDS has a higher affinity for the transport system than any other inhibitor so far examined. If, as seems probable, the covalent labelling of H₂DIDS occurs at the same site as the reversible binding, H₂DIDS can be used as a covalent label for the transport site. The specific localization of H₂DIDS in the band-3 protein thus indicates that this protein participates directly in anion exchange.     

Specific drug sensitive transport pathways for chloride and potassium ions in steady-state ehrlich mouse ascites tumor cells

A major aim of this investigation was to determine whether, in steady-state ascites cells, Cl^? transport can be partitioned into a furosemide-sensitive cotransport with K⁺ and a separate 4,4′-isothiocyanostilbene-2,2′-disulfonic acid (DIDS) sensitive self-exchange. Both Cl^? and K⁺ fluxes were studied. The furosemide- and Cl^? sensitive K⁺ fluxes were equivalent, both in normal ionic media and when the external K⁺ concentration, [K⁺]_o, was varied from 4 to 30 mM. The stoichiometry of the furosemide-sensitive Cl^? and K⁺ fluxes was 2 Cl^?: 1 K⁺ at 0.1 and 0.5 mM drug levels but increased to 3 Cl^? : 1 K⁺ at 1.0 mM furosemide. DIDS at 0.1 mM had no effect on the K⁺ exchange rate but inhibited Cl^? exchange by $\text{39\% ± 2}$ (S.E.). The effects of DIDS and 0.5 mM furosemide on Cl^? transport were additive but 1.0 mM furosemide and DIDS had overlapping inhibitory actions. Thus furosemide acts on components of K⁺ and Cl^? transport which are linked to each other, but the drug also inhibits an additional DIDS-sensitive Cl^? pathway, when present at higher concentrations. The dependence of the furosemide-sensitive K⁺ and Cl^? transport on [K⁺]_o was also studied; both fluxes fell as the [K⁺]_o increased. The latter results recall those in an earlier study by Hempling (Hempling, H.G. (1962) J. Cell. Comp. Physiol. 60, 181–198).     

Cl− transport in apical plasma membrane vesicles isolated from bovine tracheal epithelium

The Cl^? transport properties of the luminal border of bovine tracheal epithelium have been investigated using a highly purified preparation of apical plasma membrane vesicles. Transport of Cl^? into an intravesicular space was demonstrated by (1) a linear inverse correlation between Cl^? uptake and medium osmolarity and (2) complete release of accumulated Cl^? by treatment with detergent. The rate of Cl^? uptake was highly temperature-sensitive and was enhanced by exchange diffusion, providing evidence for a carrier-mediated transport mechanism. Transport of Cl^? was not affected by the ‘loop’ diuretic bumetanide or by the stilbene-derivative anion-exchange inhibitors SITS (4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid) and DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid). In the presence of the impermeant cation, tetramethylammonium (TMA⁺), uptake of Cl^? was minimal; transport was stimulated equally by the substitution of either K⁺ or Na⁺ for TMA⁺. Valinomycin in the presence of K⁺ enhanced further Cl^? uptake, while amiloride reduced Na⁺-stimulated Cl^? uptake towards the minimal level observed with TMA⁺. These results suggest the following conclusions: (1) the tracheal vesicle membrane has a finite permeability to both Na⁺ and K⁺; (2) the membrane permeability to the medium counterion determines the rate of Cl^? uptake; (3) Cl^? transport is not specifically coupled with either Na⁺ or K⁺; and, finally (4) Cl^? crosses the tracheal luminal membrane via an electrogenic transport mechanism.     

The amino acid conjugate formed by the interaction of the anion transport inhibitor 4,4′-diisothiocy ano-2,2′- stilbenedisulfonic acid (DIDS) with band 3 protein from human red blood cell membranes

The specific anion transport inhibitor 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid (DIDS) and its reduced analog (H₂DIDS), when irreversibly bound to band 3 protein of the red blood cell membrane, form amino acid conjugates through interaction with the ?-amino group of a particular lysine residue. The specific residue is located in a transmembrane segment of band 3 protein and appears to be a close neighbor of the transport site.     

Small-intestinal Na+/d-glucose cotransport. Inactivation of sugar transport and phlorizin binding by thiol-group and amino-group reagents

It has previously been shown that mercurials acting from the cytoplasmic side or from within the hydrophobic part of the membrane inactivate the small intestinal Na⁺/d-glucose cotransporter by blocking essential SH-groups (Klip, A., Grinstein, S. and Semenza, G. (1979) Biochim. Biophys. Acta 558, 233–245). Another (set of) sulfhydryl(s) which are critical for phlorizin binding and sugar transport function and which may lie on the luminal side of the brush border membrane, can be blocked by DTNB and 4,4′-dithiopyridine but not by $\text{N-}\text{ethylmaleimide}$. In addition, modification of amino groups by fluorescamine, reductive methylation and (under certain conditions) DIDS also lead to inactivation of the carrier's binding and transport functions. No evidence was obtained that any of the above groups is directly involved in the binding of either Na⁺/d-glucose or phlorizin, since none of these compounds prevented inactivation of the cotransporter.     

Interaction of phloretin with the anion transport protein of the red blood cell membrane

Phloretin is an inhibitor of anion exchange and glucose and urea transport in human red cells. Equilibrium binding and kinetic studies indicate that phloretin binds to band 3, a major integral protein of the red cell membrane. Equilibrium phloretin binding has been found to be competitive with the binding of the anion transport inhibitor, 4,4′-dibenzamido-2,2′-disulfonic stilbene (DBDS), which binds specifically to band 3. The apparent binding (dissociation) constant of phloretin to red cell ghost band 3 in 28.5 mM citrate buffer, pH 7.4, 25°C, determined from equilibrium binding competition, is $\text{1.8 ± 0.1}\text{μM}$. Stopped-flow kinetic studies show that phloretin decreases the rate of DBDS binding to band 3 in a purely competitive manner, with an apparent phloretin inhibition constant of $\text{1.6 ± 0.4}\text{μM}$. The pH dependence of equilibrium binding studies show that it is the charged, anionic form of phloretin that competes with DBDS binding, with an apparent phloretin inhibition constant of 1.4 μM. The phloretin binding and inhibition constants determined by equilibrium binding, kinetic and pH studies are all similar to the inhibition constant of phloretin for anion exchange. These studies suggest that phloretin inhibits anion exchange in red cells by a specific interaction between phloretin and band 3.     

Pyruvate flux into resealed ghosts from human erythrocytes

The kinetics of pyruvate transport across the isolated red blood cell membrane were studied by a simple and precise spectrophotometric method: following the oxidation of NADH via lactate dehydrogenase trapped within resealed ghosts. The initial rate of pyruvate entry was linear. Influx was limited by saturation at high pyruvate concentration. Pyruvate influx was greatly stimulated by increasing ionic strength in the outer but not the inner aqueous compartment. The $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ ranged from 15.0 mM at $\text{μ = 0.05}$ to 3.7 mM at $\text{μ = 0.01}$, while the $\text{V}$ went from $\text{0.611 · 10}{}^{-15}$ to $\text{0.137 · 10}{}^{-15}\text{mol}\text{·}\text{min}{}^{-1}\text{·}\text{ghost}{}^{-1}$. Ionic strength was shown to affect the translocation step and not pyruvate binding. The energy of activation of pyruvate flux into resealed ghosts was 25 kcal/mol, similar to that found in intact red blood cells. Inhibitors of pyruvate influx included such anions as thiocyanate, chloride, bicarbonate, α-cyanocinnamate, salicylate and ketomalonate (but not acetate); noncompetitive inhibitors were phloretin, 1-fluoro-2,4-dinitrobenzene, 4-acetamido-4′-isothiocyanate-stilbene-2,2′-disulfonic acid and o-phenanthroline/CuSO₄ mixtures. The last reagent, known to induce disulfide links in certain membrane proteins, blocked the ionic strength stimulation of pyruvate influx in this study.     

A relationship between anion transport and a structural transition of the human erythrocyte membrane

Scanning microcalorimetry was employed as an aid in examining some structural features of the anion transport system in red blood cell vesicles. Two structural transitions were previously shown to be sensitive to several covalent and non-covalent inhibitors of anion transport in red cells. In this study, these transitions were selectively removed, either thermally or enzymatically, and the subsequent effect on ³⁵SO₄^2? efflux in red cell vesicles was determined. It is shown that removal of one of these transitions (B₂) has a negligible inhibitory effect on anion transport. Cytoplasmic, intermolecular disulfide linkages between band 3 dimers are known to form during the B₂ transition. The integrity of the 4,4′-diisothiocyanostilbene-2,2′-disulfonate-sensitive C transition, on the other hand, is shown to be a requirement for anion transport. The localized region of the membrane giving rise to this transition contains the transmembrane segment of band 3, as well as membrane phospholipids. The calorimetric results suggest a structure of band 3 which involves independent structural domains, and are consistent with the transmembrane segment playing a direct role in the transport process.     

Formation of aqueous pores in the human erythrocyte membrane after oxidative cross-linking of spectrin by diamide

Oxidation of erythrocyte membrane SH-groups by diamide and tetrathionate induces cross-linking of spectrin (Haest, C.W.M., Kamp, D., Plasa, G. and Deuticke, B. (1977) Biochim. Biophys. Acta 469, 226–230). This cross-linking was now shown to go along with a concentration- and time-dependent enhancement of membrane permeability for hydrophilic nonelectrolytes and ions. The enhancement is specific for oxidative SH-group modifications, is reversible by reduction of the induced disulfides, can be suppressed by a very brief pre-treatment of the cells with low concentrations of $\text{N-}\text{ethylmaleimide}$ and is strongly temperature-dependent. The pathway of the induced permeability discriminates nonelectrolytes on the basis of molecular size and exhibits a very low activation energy ($\text{E}{}_{\mathrm{<mtext>a</mtext>}}\text{3–8}\text{kcal/mol}$). These findings are reconcilable with the formation of a somewhat inhomogeneous population of aqueous pores with radii probably $\text{? 0.65}\text{nm}$. Estimated pore numbers vary with the size of the probe molecule. Assuming a diffusion coefficient as in bulk water within the pore, at least 20 pores per cell have to be postulated; more realistic lower diffusion coefficients increase that number. Alterations of the lipid domain by changes of cholesterol contents and insertion of hexanol or nonionic detergents alter the number or size of the pores. Since aggregation of skeletal and intrinsic membrane proteins also occurs after the SH-oxidation, in parallel to the formation of membrane leaks, one may consider (a) defects in the disturbed bilayer interface, (b) a mismatch between lipid and intrinsic proteins or (c) channels inbetween aggregated intrinsic proteins as structures forming the pores induced by diamide treatment.     

Inhibition of anion transport in the red blood cell by anionic amphiphilic compounds I. Determination of the flufenamate-binding site by proteolytic dissection of the band 3 protein

Flufenamate, a non-steroidal anti-inflammatory drug, is a powerful inhibitor of anion transport in the human erythrocyte ($\text{I}{}_{50}\text{= 6·10}{}^{\mathrm{?7}}\text{M}$). The concentration dependence of the binding to ghosts reveals two saturable components. [¹⁴C]Flufenamate binds with high affinity ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}{}_1\text{= 1.2·10}{}^{\mathrm{?7}}\text{M}$) to 8.5·10⁵ sites per cell (the same value as the number of band 3 protein per cell); it also binds, with lower affinity ($\text{K}{}_{\mathrm{<mtext>d</mtext>}}{}_2\text{= 10}{}^{\mathrm{?4}}\text{M}$) to a second set of sites (4.6·10⁷ per cell). Pretreatment of cells with 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid (SITS), a specific inhibitor of anion transport, prevents [¹⁴C]flufenamate binding only to high affinity sites. These results suggest that high affinity sites are located on the band 3 protein involved in anion transport. Extracellular chymotrypsin and pronase at low concentration cleave the 95 kDa band 3 into 60 kDa and 35 kDa fragments without affecting either anion transport or [¹⁴C]flufenamate binding. Splitting by trypsin at the inner membrane surface of the 60 kDa chymotryptic fragment into 17 kDa transmembrane fragment and 40 kDa water-soluble fragment does not affect [¹⁴C]flufenamate binding. In contrast degradation at the outer membrane surface of the 35 kDa fragment by high concentration of pronase or papain decreases both anion transport capacity and number of high affinity binding sites for [¹⁴C]flufenamate. Thus it appears that 35 kDa peptide is necessary for both anion transport and binding of the inhibitors and that the binding site is located in the membrane-associated domain of the band 3 protein.     

The effects of anion transport inhibitors on structural transitions in erythrocyte membranes

Red blood cell membranes have been labeled with several covalent and non-covalent inhibitors of anion transport and their heat capacity profiles determined as a function of temperature. Covalent inhibitors include the amino reactive agents 4,4′-diisothiocyanostilbene-2,2′-disulfonic acid, 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid, pyridoxal phosphate and 1-fluoro-2,4-dinitro benzene. The non-covalent inhibitors include several well known local anesthetics. The study was undertaken in order to identify regions of the membrane involved in anion transport. Covalent modification in all cases resulted in a large upward shift of the C transition, which is believed to involved a localized phospholipid region. Evidence is presented which indicates that Band III protein and this phospholipid region are in close physical proximity on the membrane. Addition of non-covalent inhibitors affects the membrane in either or both of two ways. In some cases, a lowering and broadening of the C transition occurs; in other the B₁ and B₂ transitions are altered. These latter transitions are believed to involve both phospholipid and protein, including Band III. These results may indicate that the non-covalent inhibitors produce their inhibitory effect on anion transport at least in part by interacting with membrane phospholipid.     

Mediated transport of anions in band 3-phospholipid vesicles

Band 3 protein, extracted from human erythrocyte membranes by Triton X-100, was recombined with egg lecithin/cholesterol mixtures to form small unilamellar vesicles at a yield of 15–20%. These systems exhibited sulfate fluxes which were inhibitable by stilbene disulfonates and other inhibitors. Maximal inhibition could only be obtained when inhibitors were present at both membrane surfaces. Inhibitor constants $\text{I}{}_{50}$ were higher than in the native membrane. Quantitatively, transport function was retained at least 60%, as related to the amount of protein involved. Sulfate transport in the recombinates resembled transport in the native membrane with respect to temperature dependence ($\text{E}{}_{\mathrm{<mtext>a</mtext>}}\text{= 29?32}\text{kcal}\text{/}\text{mol}$), pH dependence between pH 6.5 and 7.8, and the relationship between net and exchange fluxes. In contrast to the native cell, concentration dependence was linear up to 80 mM sulfate, which may be indicative of a lowered affinity for the substrate. Lactate transport in these systems, although substantial, was insensitive to stilbene disulfonates as well as to mercurials, indicating that band 3 is not involved in the specific monocarboxylate transfer in the erythrocyte. Anion transport in band 3-lipid recombinates was insensitive to cholesterol between 0 and 27 mol%. Treatment with proteases, while not affecting transport per se, abolished sensitivity to stilbene disulfonate inhibitors. These observations indicate a number of disturbances of band 3 after recombination, in spite of a preservation of the major transport properties.     

The location of a disulfonic stilbene binding site in band 3, the anion transport protein of the red blood cell membrane

The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid, a specific, potent, irreversible inhibitor of anion transport in red blood cells is located in a 15 000 dalton transmembrane segment of band 3, produced by chymotrypsin treatment of ghosts stripped of extrinsic proteins. The segment was cleaved into three fragments of 7000, 4000 and 4000 daltons by CNBr. The C-terminus of the segment is located in the 7000 dalton fragment; the N-terminus in one of the 4000 dalton fragments; and the binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid in the middle 4000 dalton fragment. The latter was cleaved by $\text{N-}\text{bromosuccinimide}$ into two fragments of 2000 daltons. The binding site for 4,4′-diisothiocyano-2,2′-stilbenedisulfonic acid was located on the fragment containing the newly formed N-terminus. It is concluded that the binding site is located about 9000 daltons from the C-terminus (at the outside face of the membrane) and 6000 daltons from the N-terminus (at the cytoplasmic face). In view of the existing evidence that the binding site may be located near the outside face of the membrane, it is suggested that the 15 000 dalton segment is folded, so that it crosses the bilayer three times.     

A second mechanism for sodium extrusion in Halobacterium halobium: a light-driven sodium pump.

Membrane vesicles from a red mutant of $\text{Halobacterium}\text{halobium}$ R₁ accumulate protons when illuminated causing the pH of the suspension to rise. Sodium is extruded from the vesicles and a membrane potential is formed. This potential and the proton uptake are abolished by valinomycin if K⁺ is present. In contrast, Na⁺-efflux is uninhibited by valinomycin even though no membrane potential is detectable and H⁺ influx does not occur. $\text{Bis}$ (hexafluoracetonyl)acetone (1799) stimulates proton uptake but does not abolish membrane potential. We propose that a light-dependent sodium pump is present. Passive proton uptake occurs in response to the electrical gradient created by this light-driven Na⁺ pump in contrast to the $\text{active}$ proton, and passive Na⁺ flux that occurs in response to the light-driven proton pump described in vesicles of the parent strain of $\text{H.}\text{halobium}$ R₁.     

A comparison of intact human red blood cells and resealed and leaky ghosts with respect to their interactions with surface labelling agents and proteolytic enzymes

Resealed ghosts and intact red blood cells were directly compared with respect to their interactions with surface probes and to digestion by pronase. The amount and pattern of labelling of surface proteins by 4.4′-diisothiocyano-2,2′-stilbene disulfonic acid (DIDS) and by pyridoxal phosphate-borohydride (as seen after sodium dodecylsulfate/acrylamide gel electrophoresis) was substantially the same in cells and resealed ghosts under conditions in which a relatively small change would be apparent. In each membrane system, DIDS labels a protein component of apparent molecular weight 95 000 and pyridoxal phosphate labels the same protein plus three glycoprotein components. The sensitivity of surface proteins and of DIDS and pyridoxal phosphate-labelled sites to pronase was also similar in the cells and resealed ghosts. The glycoproteins were digested, in each case, and the 95 000 (molecular weight) protein was largely split into two portions of apparent molecular weights 65 000 and 35 000, with both portions containing DIDS and pyridoxal phosphate binding sites. The pattern of labelling of “leaky” ghosts by pyridoxal phosphate in the presence of hemoglobin was similar to the labelling of intact cells, provided that the pyridoxal phosphate was present on both the outside and inside of the cells. Virtually all of the major protein components visible by staining on acrylamide gels were labelled. It is concluded that none of the probes could detect any substatial differences in reactivity of proteins of the outer surface of the membrane of the ghosts as compared to the cells and that no irreversible changes in membrane protein conformation or arrangement occur as a consequence of lysis and resealing of ghosts, that are detectable by the reported procedures.     

Effects of lanthanum on calcium-dependent phenomena in human red cells

Lanthanum (0.25 mM) does not penetrate into fresh or Mg²⁺-depleted cells, whereas it does into ATP-depleted or $\text{ATP + 2,3-diphosphoglycerate-depleted cells}$, into cells containing more than 3 mM calcium, or cells stored for more than 4 weeks in acid/citrate/dextrose solution. In fresh cells loaded with calcium, extracellular lanthanum blocks the active Ca²⁺-efflux completely and inhibits $\text{(Ca}{}^{\mathrm{2+}}\text{+ Mg}{}^{\mathrm{2+}}\text{)-ATPase}$ (ATP phosphohydrolase, EC 3.6.1.3) activity to about 50%. In Mg²⁺-depleted cells Ca²⁺-Ca²⁺ exchange is inhibited by lanthanum. Ca²⁺-leak is unaffected by lanthanum up to 0.25 mM concentration; higher lanthanum concentrations reduce leak rate. In NaCl medium Ca²⁺-leak ± S.D. amounts to $\text{0.28 ± 0.08 μ}\text{mol/l}$ of cells per min, whereas in KCl medium to $\text{0.15 ± 0.04 μ}\text{mol/l}$ of cells per min at 2.5 mM [Ca²⁺]_e and 0.25 mM [La³⁺]_e pH 7.1.Lanthanum inhibits Ca²⁺-dependent rapid K⁺ transport in ATP-depleted and propranolol-treated red cells, i.e. whenever intracellular calcium is below a critical level. The inhibition of the rapid K⁺ transport can be attributed to protein-lanthanum interactions on the cell surface, since lanthanum is effectively detached from the membrane lipids by propranolol.Lanthanum at 0.2–0.25 mM concentration has no direct effect on the morphology of red cells. The shape regeneration of Ca²⁺-loaded cells, however, is blocked by lanthanum owing to Ca²⁺-pump inhibition. Using lanthanum the transition in cell shape can be quantitatively correlated to intracellular Ca²⁺ concentrations.     

Anion transport in relation to proteolytic dissection of band 3 protein

Sulfate efflux was measured in inside-out vesicles obtained from human red cells. Inhibition was observed in vesicles derived from cells pretreated with DIDS (4,4′-diisothiocyano-2,2′-stilbene disulfonate) or after addition of dipyridamole to the vesicles, both agents being specific and potent inhibitors of anion transport in cells. Trypsinization of the cytoplasmic side of the membrane in order to release a 40 000 dalton fragment from band 3 (the purported anion transport protein) had no effect on sulfate efflux. Further degradation of band 3 to a 17 000 dalton segment, by trypsinization of inside-out vesicles derived from cells that had been pretreated with chymotrypsin, also showed little reduction in transport activity. Furthermore, such vesicles derived from DIDS pretreated cells were inhibited by over 90%. In DIDS-treated cells, the agent is highly localized in band 3. In trypsinized inside-out vesicles, it is largely found in a 55 000 fragment and in trypsinized vesicles derived from cells pretreated with chymotrypsin it is largely located in the 17 000 fragment. The data suggest that both the anion transport and inhibitor binding sites are located in a 17 000 transmembrane segment of band 3.     

Cytosolic pH regulation in perfused rat liver: role of intracellular bicarbonate production

The contribution of metabolic bicarbonate to cytosolic pH (pH_cyto) regulation was studied on isolated perfused rat liver using phosphorus-31 NMR spectroscopy. Removal of external HCO^?₃ decreased proton efflux from 18.6±5.0 to 1.64±0.29 μmol/min per g liver wet weight (w.w.) and pH_cyto from 7.17±0.06 to 6.87±0.06. In the nominal absence of bicarbonate, inhibition of carbonic anhydrase by acetazolamide induced a further decrease of proton efflux of 0.69±0.26 μmol/min per g liver w.w. reflecting a reduction in metabolic CO₂ hydration, and hence a decrease of H⁺ and HCO^?₃ supplies. Even though 27% of the proton efflux was amiloride-sensitive under bicarbonate-free conditions, amiloride did not change pH_cyto, revealing the contribution of additional regulatory processes. Indeed, pH regulation was affected by the combined use of 4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid (SITS) and amiloride since pH_cyto decreased by 0.16±0.05 and proton efflux by 0.60±0.14 μmol/min per g liver w.w. The data suggest that amiloride-sensitive or SITS-sensitive transport activities could achieve, by themselves, pH_cyto regulation. The involvement of two mechanisms, most likely Na⁺/H⁺ antiport and Na⁺:HCO^?₃ symport, was confirmed in the whole organ under intracellular and extracellular acidosis. The evidence of Na-dependent transport of HCO^?₃ in the absence of exogenous bicarbonate implies that the amount of metabolic bicarbonate is sufficient to effectively participate to pH_cyto regulation.     

Labeling of human erythrocyte membranes with eosin probes used for protein diffusion measurements. Inhibition of anion transport and photo-oxidative inactivation of acetylcholinesterase

The binding of eosin-isothiocyanate (eosin-NCS) and iodoacetamido-eosin (IA-eosin) to band 3 proteins in the membrane of human erythrocytes is characterized by studying the effect of these probes on the anion transport system. Although the unbrominated fluorescein precursors do not affect anion transport, both eosin labels are strong inhibitors of sulphate exchange in intact erythrocytes. 50% inhibition is obtained by binding 4.7 · 10⁵ or 6.0 · 10⁵ molecules/cell for eosin-NCS and IA-eosin, respectively. Both eosin probes are irreversibly bound and occupy common binding sites with 4,4′-diisothiocyano-1,2-diphenyl-ethane-2,2′-disulfonic acid (H₂DIDS), although other sites are labeled as well. The inhibition of anion transport is light independent and can therefore not be attributed to a photosensitizing action of the eosin probes. Both eosin derivatives, however, inactivate acetylcholinesterase upon illumination of air-equilibrated samples of hemoglobin-free labeled ghosts. The inactivation of the enzyme is accompanied by the formation of protein aggregates as visualized by polyacrylamide gel electrophoresis. These effects are not observed when intact erythrocytes are illuminated in the presence of eosin probes suggesting a protective effect of hemoglobin during the labeling procedure. Protection of ghosts from photo-oxidation is achieved by displacing air with argon. These results are discussed in relation to the use of these and similar probes to measure protein diffusion in membranes.