Effect of pCMBS on anion transport in human red cell membranes.

The kinetics of binding of the mercurial sulfhydryl reagent, pCMBS (p-chloromercuribenzene sulfonate), to the extracellular site(s) at which pCMBS inhibits water and urea transport across the human red cell membrane, have previously been characterized. To determine whether pCMBS binding alters Cl- transport, we measured Cl-/NO3- exchange by fluorescence enhancement, using the dye SPQ (6-methoxy-N-(3-sulfopropyl)quinolinium). An essentially instantaneous extracellular phase of pCMBS inhibition is followed by a much slower intracellular phase, correlated with pCMBS permeation. We attribute the instantaneous phase to competitive inhibition of Cl- binding to band 3 by the pCMBS anion. The ID50 of 2.0 +/- 0.1 mM agrees with other organic sulfonates, but is very much greater than that of pCMBS inhibition of urea and water transport, showing that pCMBS reaction with water and urea transport inhibition sites has no effect on anion exchange. The intracellular inhibition by 1 mM pCMBS (1 h) is apparently non-competitive with Ki = 5.5 +/- 6.3 mM, presumably an allosteric effect of pCMBS binding to an intracellular band 3-related sulfhydryl group. After N-ethylmaleimide (NEM) treatment to block these band 3 sulfhydryl groups, there is apparent non-competitive inhibition with Ki = 2.1 +/- 1.2 mM, which suggests that pCMBS reacts with one of the NEM-insensitive sulfhydryl groups on a protein that links band 3 to the cytoskeleton, perhaps ankyrin or bands 4.1 and 4.2.     

Control of red cell urea and water permeability by sulfhydryl reagents

The binding constant for pCMBS (p-chloromercuribenzenesulfonate) inhibition of human red cell water transport has been determined to be 160 +/- 30 microM and that for urea transport inhibition to be 0.09 +/- 0.06 microM, indicating that there are separate sites for the two inhibition processes. The reaction kinetics show that both processes consist of a bimolecular association between pCMBS and the membrane site followed by a conformational change. Both processes are very slow and the on rate constant for the water inhibition process is about 10(5) times slower than usual for inhibitor binding to membrane transport proteins. pCMBS binding to the water transport inhibition site can be reversed by cysteine while that to the urea transport inhibition site can not be reversed. The specific stilbene anion exchange inhibitor, DBDS (4,4'-dibenzamidostilbene-2,2'-disulfonate) causes a significant change in the time-course of pCMBS inhibition of water transport, consistent with a linkage between anion exchange and water transport. Consideration of available sulfhydryl groups on band 3 suggests that the urea transport inhibition site is on band 3, but is not a sulfhydryl group, and that, if the water transport inhibition site is a sulfhydryl group, it is located on another protein complexed to band 3, possibly band 4.5.     

Interaction of thiourea with band 3 in human red cell membranes

Summary Although urea transport across the human red cell membrane has been studied extensively, there is disagreement as to whether urea and water permeate the red cell by the same channel. We have suggested that the red cell anion transport protein, band 3, is responsible for both water and urea transport. Thiourea inhibits urea transport and also modulates the normal inhibition of water transport produced by the sulfhydryl reagent,pCMBS. In view of these interactions, we have looked for independent evidence of interaction between thiourea and band 3. Since the fluorescent stilbene anion transport inhibitor, DBDS, increases its fluorescence by two orders of magnitude when bound to band 3 we have used this fluorescence enhancement to study thiourea/band 3 interactions. Our experiments have shown that there is a thiourea binding site on band 3 and we have determined the kinetic and equilibrium constants describing this interaction. Furthermore,pCMBS has been found to modulate the thiourea/band 3 interaction and we have determined the kinetic and equilibrium constants of the interaction in the presence ofpCMBS. These experiments indicate that there is an operational complex which transmits conformational signals among the thiourea,pCMBS and DBDS sites. This finding is consistent with the view that a single protein or protein complex is responsible for all the red cell transport functions in which urea is involved.     

Water transport in human red cells: effects of 'non-inhibitory' sulfhydryl reagents

The water diffusional permeability of human red blood cells following exposure to various sulfhydryl group (SH) reagents have been studied using a nuclear magnetic resonance technique. Exposure of red blood cells up to 12 mM N-ethylmaleimide (NEM) or 10 mM 5,5'-dithio-bis(2-nitrobenzoic acid) (DTNE) alone does not affect water diffusion. In contrast, when DTNB treatment follows a preincubation of the cells with NEM, a small (18% at 37 degrees C) but significant inhibition of water permeability occurs. The NEM and DTNB treatment of the cells caused no change of the cell shape and volume or of the cell water volume. Consequently, the inhibition observed after NEM and DTNB treatment has a real significance.     

Inhibition of hexose transport in the human erythrocyte by 5, 5′-dithiobis(2-nitrobenzoic acid): Role of an exofacial carrier sulfhydryl group

Summary The sulfhydryl reagent 5, 5-dithiobis (2-nitrobenzoic acid) (DTNB) was used to study the functional role of an exofacial sulfhydryl group on the human erythrocyte hexose carrier. Above 1mm DTNB rapidly inhibited erythrocyte 3-O-methylglucose influx, but only to about half of control rates. Efflux was also inhibited, but to a lesser extent. Uptake inhibition was completely reversed by incubation and washing with 10mm cysteine, whereas it was only partially reduced by washing in buffer alone, suggesting both covalent and noncovalent interactions. The covalent thiol-reversible reaction of DTNB occurred on the exofacial carrier, since (i) penetration of DTNB into cells was minimal, (ii) blockade of potential uptake via the anion transporter did not affect DTNB-induced hexose transport inhibition, and (iii) DTNB protected from transport inhibition by the impermeant sulfhydryl reagent glutathione-maleimide-I. Maltose at 120mm accelerated the covalent transport inhibition induced by DTNB, whereas 6.5 m cytochalasin B had the opposite effect, indicating under the one-site carrier model that the reactive sulfhydryl is on the outward-facing carrier but not in the substrate-binding site. In contrast to glutathione-maleimide-I, however, DTNB did not restrict the ability of the carrier to reorient inwardly, since it did not affect equilibrium cytochalasin B binding. Thus, carrier conformation determines exposure of the exofacial carrier sulfydryl, but reaction of this group may not always lock the carrier in an outward-facing conformation.     

Inhibition of anion transport in human red blood cells by 5,5′-dithiobis(2-nitrobenzoic acid)

The uptake of [³²P]phosphate into human red blood cells was inhibited ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 0.6}\text{mM}$) by the sulfhydryl reagent 5,5′-dithiobis(2-nitrobenzoic acid) (DTNB). 2-Nitro-5-thiobenzoic acid (NTB), the reduced form of DTNB, was a less potent inhibitor ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 7}\text{mM}$). The inhibition of anion transport by DTNB could be reversed by washing DTNB-treated cells with isotonic buffer, or by incubating DTNB-treated cells with 2-mercaptoethanol, which converted DTNB to NTB. DTNB competitively inhibited the binding of 4-[¹⁴C]-benzamido-4′-aminostilbene-2,2′-disulfonate, a potent inhibitor of anion transport ($\text{K}{}_{\mathrm{<mtext>i</mtext>}}\text{= 1?2 μ}\text{M}$), to band 3 protein in cells and ghost membranes. These results suggest that the stilbene-disulfonate binding site in band 3 protein can readily accommodate the organic anion DTNB, and that inhibition by DTNB was not due to reaction with an essential sulfhydryl group.     

Site of red cell cation leak induced by mercurial sulfhydryl reagents

It has been suggested that the human red cell anion transport protein, band 3, is the site not only of the cation leak induced in human red cells by treatment with the sulfhydryl reagent pCMBS ($\text{p-}\text{chloromercuribenzene sulfonate}$) but is also the site for the inhibition of water flux induced by the same reagent. Our experiments indicate that $\text{N-}\text{ethylmaleimide}$, a sulfhydryl reagent that does not inhibit water transport, also does not induce a cation leak. We have found that the profile of inhibition of water transport by mercurial sulfhydryl reagents is closely mirrored by the effect of these same reagents on the induction of the cation leak. In order to determine whether these effects are caused by band 3 we have reconstituted phosphatidylcholine vesicles containing only purified band 3. Control experiments indicate that these band 3 vesicles do not contain ($\text{Na}{}^{\mathrm{+}}\text{+}\text{K}{}^{\mathrm{+}}\text{)-}\text{ATPase}$ as measured by ATP dephosphorylation. pCMBS treatment caused a significant increase in the cation leak in this preparation, consistent with the view that the pCMBS-induced cation leak in whole red cells is mediated by band 3.     

Water permeability in human erythrocytes: identification of membrane proteins involved in water transport

The water permeability of human erythrocytes has been monitored by nuclear magnetic resonance (NMR) before and after treatment of the cells with various sulfhydryl reagents. Preincubation of the cells with N-ethylmaleimide (NEM), a non-inhibitory sulfhydryl reagent, results in a faster and more sensitive inhibition of water exchange by mercurials. The inhibition of water exchange by p-chloromercuribenzene sulfonate (PCMBS) was maximal at a binding of approximately 10 nmol PCMBS per mg protein when non-specific sulfhydryl groups are blocked by NEM. Inhibition by PCMBS has been correlated with the binding of 203Hg to erythrocyte membrane proteins. A significant binding of label to band 3 and the polypeptides in band 4.5 occurs, with approximately 1 mol of mercurial bound per mol of protein. Inhibition of water transport by sulfhydryl reagents does not induce major morphological changes in the cells as assessed by freeze-fracture and scanning electron microscopy.     

Quenching of red cell tryptophan fluorescence by mercurial compounds

Intrinsic tryptophan fluorescence in red cell ghost membranes labeled with N-ethylmaleimide (N-EM) is quenched in a dose-dependent manner by the organic mercurial p-chloromercuribenzene sulfonate (p-CMBS). Fluorescence lifetime analysis shows that quenching occurs by a static mechanism. Binding of p-CMBS occurs by a rapid (less than 5 s) biomolecular association (dissociation constant K1 = 1.8 mM) followed by a slower unimolecular transition with forward rate constant k2 = 0.015 s-1 and reverse rate constant k-2 = 0.0054 s-1. Analysis of the temperature dependence of k2 gives delta H = 6.5 kcal/mol and delta S = -21 eu. The mercurial compounds p-chloromercuribenzoic acid, p-aminophenylmercuric acetate, and mercuric chloride quench red cell tryptophan fluorescence by the same mechanism as p-CMBS does; the measured k2 value was the same for each compound, whereas K1 varied. p-CMBS also quenches the tryptophan fluorescence in vesicles reconstituted with purified band 3, the red cell anion exchange protein, in a manner similar to that in ghost membranes. These experiments define a mercurial binding site on band 3 in ghosts treated with N-EM and establish the binding mechanism to this site. The characteristics of this p-CMBS binding site on band 3 differ significantly from those of the p-CMBS binding site involved in red cell water and urea transport inhibition.     

Reactivities of sulfhydryl groups in native and metal-free aminoacylase I

Aminoacylase I from porcine kidney (EC 3.5.1.14) contains seven cysteine residues per subunit. Three sulfhydryl groups are accessible to modification by 4-hydroxymercuribenzoate (p-MB). The kinetics of the reaction suggest that only one of these groups affects acylase activity when modified by p-MB. Its reaction rate increases 2-3-fold when the essential metal ion of aminoacylase is removed. Modification of metal-free apoenzyme by N-ethylmaleimide (NEM) abolishes its activity without impairing Zn2+ binding. This indicates that the sulfhydryl group reacting with NEM is not directly coordinated to the metal. DTNB (5,5'-Dithio-bis(2-nitrobenzoate), Ellman's reagent) also modifies three sulfhydryl groups per subunit. In this case, the reactivities of native aminoacylase and apoenzyme are not significantly different. N-Hydroxy-2-aminobutyrate, a strong aminoacylase inhibitor, substantially increases the reactivity of the slowest reacting sulfhydryl in both native enzyme and metal-free aminoacylase. It appears that binding of the inhibitor or removal of the metal ion induces conformational changes of the amino-acylase active site that render a buried sulfhydryl group more accessible to modification.     

Sulfhydryl groups of an extramitochondrial acetyl-CoA hydrolase from rat liver

An extramitochondrial acetyl-CoA hydrolase (EC 3.1.2.1) purified from rat liver was inactivated by heavy metal cations (Hg2+, Cu2+, Cd2+ and Zn2+), which are known to be highly reactive with sulfhydryl groups. Their order of potency for enzyme inactivation was Hg2+ greater than Cu2+ greater than Cd2+ greater than Zn2+. This enzyme was also inactivated by various sulfhydryl-blocking reagents such as p-hydroxymercuribenzoate (PHMB), N-ethylmaleimide (NEM), 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB), and iodoacetate (IAA). DL-Dithiothreitol (DTT) reversed the inactivation of this enzyme by DTNB markedly, and that by PHMB slightly, but did not reverse the inactivations by NEM, DTNB and IAA. Benzoyl-CoA (a substrate-like competitive inhibitor) and ATP (an activator) greatly protected acetyl-CoA hydrolase from inactivation by PHMB, NEM, DTNB and IAA. These results suggest that the essential sulfhydryl groups are on or near the substrate binding site and nucleotide binding site. The enzyme contained about four sulfhydryl groups per mol of monomer, as estimated with DTNB. When the enzyme was denatured by 4 M guanidine-HCl, about seven sulfhydryl groups per mol of monomer reacted with DTNB. Two of the four sulfhydryl groups of the subunit of the native enzyme reacted with DTNB first without any significant inactivation of the enzyme, but its subsequent reaction with the other two sulfhydryl groups seemed to be involved in the inactivation process.     

Effect of ligands on the reactivity of essential sulfhydryls in brain hexokinase. Possible interaction between substrate binding sites.

Inactivation of bovine brain mitochondrial hexokinase by 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB), a sulfhydryl specific reagent, has been investigated. The study shows that the inactivation of the enzyme by DTNB proceeds by way of prior binding of the reagent to the enzyme and involves the reaction of 1 mol of DTNB with a mol of enzyme. At stoichiometric levels of DTNB, the inactivation of the enzyme is accompanied by the formation of a disulfide bond. But it is not clear whether the disulfide bond or the mixed disulfide intermediate formed prior to it causes inactivation. On the basis of considerable protection afforded by glucose against this inactivation it is tentatively concluded that the sulfhydryl residues involved in this inactivation are at the glucose binding site of the enzyme, although other possibilities are not ruled out. An analysis of effects of various substrates and inhibitors on the kinetics of inactivation and sulfhydryl modification by DTNB has led to the proposal that the binding of substrates to the enzyme is interdependent and that glucose and glucose 6-phosphate produce slow conformational changes in the enzyme. Protective effects by ligands have been employed to calculate their dissociation constant with respect to the enzyme. The data also indicate that glucose 6-phosphate and inorganic phosphate share the same locus on the enzyme as the gamma phosphate of ATP and that nucleotides ATP and ADP bind to the enzyme in the absence of Mg2+.     

Accessibility of the N-ethylmaleimide-unreactive sulfhydryl of human erythrocyte Band 3

The human erythrocyte anion exchange protein, Band 3, was reacted with N-ethylmaleimide (NEM) in cells to a stoichiometry of 5.3 mol NEM per mol Band 3, indicating that all NEM-reactive cysteines in Band 3 were labeled. Quantitatively NEM-blocked Band 3 was still able to bind to and be eluted by reducing agents from a mercurial affinity resin, [p-(chloromercuribenzamido)ethylene]amino-Sepharose. Reaction of NEM-blocked Band 3 with p-chloromercuribenzoate (pCMB) did not prevent binding to the resin due to exchange of pCMB for the immobilized mercurial. pCMB has been reported to inhibit water and urea permeation across the red cell membrane, and this has been attributed to reaction with a NEM-reactive sulfhydryl in Band 3. The interaction of Band 3 with the immobilized ligand directly demonstrates the reaction of NEM-blocked Band 3 with a mercurial and indicates that the NEM-unreactive, pCMB-reactive sulfhydryl residue is accessible to within approximately equal to 12 A (the distance from the solid support to the Hg) of the surface of the solubilized Band 3 protein.     

Relation between red cell anion exchange and urea transport

The new distilbene compound, DCMBT (4,4'-dichloromercuric-2,2,2',2'-bistilbene tetrasulfonic acid) synthesized by Yoon et al. (Biochim. Biophys. Acta 778 (1984) 385-389) was used to study the relation between urea transport and anion exchange in human red cells. DCMBT, which combines properties of both the specific stilbene anion exchange inhibitor, DIDS, and the water and urea transport inhibitor, pCMBS, had previously been shown to inhibit anion transport almost completely and water transport partially. We now report that DCMBT also inhibits urea transport almost completely and that covalent DIDS treatment reverses the inhibition. These observations provide support for the view that a single protein or protein complex modulates the transport of water and urea and the exchange of anions through a common channel.     

Relation between red cell anion exchange and urea transport

The new distilbene compound, DCMBT (4,4′-dichloromercuric-2,2,2′,2′-bistilbene tetrasulfonic acid) synthesized by Yoon et al. (Biochim. Biophys. Acta 778 (1984) 385–389) was used to study the relation between urea transport and anion exchange in human red cells. DCMBT, which combines properties of both the specific stilbene anion exchange inhibitor, DIDS, and the water and urea transport inhibitor, pCMBS, had previously been shown to inhibit anion transport almost completely and water transport partially. We now report that DCMBT also inhibits urea transport almost completely and that covalent DIDS treatment reverses the inhibition. These observations provide support for the view that a single protein or protein complex modulates the transport of water and urea and the exchange of anions through a common channel.     

Modifications of the binding properties of the human VIP receptor of IGR39 cells by sulfhydryl reagents.

The effects of specific sulfhydryl reagents, N-ethylmaleimide (NEM), p-chloromercuribenzoic acid (PCMB) and 5-5'-dithiobis(2-nitrobenzoic acid) (DTNB), were tested on the vasoactive intestinal peptide (VIP) receptor binding capacity of the human superficial melanoma-derived IGR39 cells. On intact cell monolayers NEM and PCMB inhibit the specific [125I]VIP binding in a time and dose-dependent manner while DTNB has no effect at any concentration tested. Inhibitory effects of NEM and PCMB on high and low affinity VIP receptor are not identical. With NEM-treated cells, only low affinity sites remained accessible to the ligand. Their affinity constant is not modified. With PCMB-treated cells, the binding capacity of high affinity sites is reduced by 56% while the binding capacity of low affinity sites is not significantly affected. For both types of binding sites, the affinity constants remain in the same range of that of untreated cells. On cells made permeable by lysophosphatidylcholine, DTNB is able to inhibit the specific [125I]VIP binding in a time and dose-dependent manner. The three sulfhydryl reagents stabilize the preformed [125I]VIP receptor complex whose dissociation in the presence of native VIP is significantly reduced. Labeling of free SH groups with tritiated NEM after preincubation of cells with DTNB and VIP made possible the characterization of reacting SH groups which probably belong to the receptor. Taken together, these data allow us to define three classes of sulfhydryl groups. In addition, it is shown that high and low affinity sites have different sensibility to sulfhydryl reagents.     

Chemical modification of the mitochondrial ornithine/citrulline carrier by SH reagents: effects on the transport activity and transition from carrier to pore-like function

The transport activity of the purified and reconstituted ornithine/citrulline carrier from rat liver mitochondria was correlated to modification of its sulfhydryl groups by various reagents. Both the ornithine/ornithine (antiport) and the ornithine/H(+) (unidirectional) transport modes catalysed by the ornithine/citrulline carrier were inhibited by methanethiosulfonates, mercurial reagents, N-ethylmaleimide (NEM) and 5,5'-dithiobis(2-nitrobenzoate) (DTNB). The treatment of the ornithine/citrulline carrier with mercurial reagents, at concentrations above 5 microM, caused the induction of an additional (pore-like) transport mode, characterized by loss of substrate specificity and a transport activity higher than that of the unmodified carrier. The S-S forming reagent Cu(2+)-phenanthroline inhibited the transport catalysed by the carrier, indicating the presence of close sulfhydryl groups. The effect of consecutive addition of the various reagents revealed a peculiar aspect of the ornithine/citrulline carrier, i.e. the presence of three distinct populations of sulfhydryl groups. The first was responsible for the inhibition of the physiological transport modes by methanethiosulfonates, NEM and DTNB and low concentrations (<5 microM) of mercurials; the second population was responsible for the transition to the pore-like activity induced by higher concentrations (>5 microM) of mercurials; the third population was involved in S-S bridge formation.     

Effect of PCMBS on water transfer across biological membranes

P-chloromercuriphenylsulfonate, PCMBS, and 5, 5′ dithiobis-(2-nitrobenzoic acid), DTNB at a concentration of 1 mM are found to inhibit the rate of water transport across human red cell membrane. In addition PCMBS inhibits the rates of transport of small hydrophilic but not hydrophobic nonelectrolytes. Other sulfhydryl reagents such as N-ethylmaleimide and iodoacetamide have no significant effect on the rate of water transfer in these cells. The results suggest that there are at least two populations of membrane bound SH-groups which differ in their topical location which participate in the control of water transfer. One is located closer to the outer surface of the membrane, and thus is readily accessible to PCMBS while the other component is probably located in the membrane interior. These two populations can be dissociated by pH. The effect of PCMBS on water transfer can be greatly influenced by pH and temperature. The main effect of temperature and pH is on the permeability of the membrane to the drug. The same concentration of PCMBS is also found to inhibit to a lesser degree water transfer across other biological membranes.     

Kinetic independence between red cell anion exchange and urea transport

Urea equilibrium exchange fluxes were measured in human red cells under conditions which recruit the anion transporter into an outward-facing or an inward-facing state (with respect to the anion transport site). Regardless of these conditions, urea transport always occurred at the same rate: 41 +/- 2 mol.(kg cell solids.min)-1 with 1.5 M urea at 0 degrees C. These data suggest that the pathway on the band-3 protein which mediates anion transport is kinetically uncoupled from urea transport and is probably not involved in the transport of urea across the red cell membrane.