Essential disulfide and sulfhydryl groups for organic cation transport in renal brush-border membranes

The disulfide reducing agent, dithiothreitol (DTT) and the sulfhydryl-modifying reagents p-chloromercuribenzenesulfonic acid and N-ethylmaleimide (NEM) were employed to assess the role of disulfide and sulfhydryl groups in organic cation transport. The transport of N1-[3H]methylnicotinamide (NMN), a prototypic organic cation, was examined employing brush-border membrane vesicles isolated from the outer cortex of canine kidneys. DTT inhibited NMN transport reversibly with an IC50 of 250 microM/mg of protein. 5 mM NMN protected against DTT inactivation. The specificity of substrate protection was demonstrated by showing that D-glucose had no effect on the DTT inactivation of NMN transport and conversely that NMN had no effect on the DTT inactivation of D-glucose transport. Disulfide bonds reduced by DTT could be reoxidized by washing with excess buffer or by addition of 0.02% H2O2 thereby restoring NMN transport. p-Chloromercuribenzenesulfonic acid reversibly inactivated NMN transport with an IC50 of 25 microM/mg of protein. 5mM NMN protected against inactivation. NEM irreversibly inactivated transport with an IC50 of 250 microM/mg of protein. The rate of NMN inactivation by NEM followed pseudo-first order reaction kinetics. A replot of the data gave a linear relationship between the apparent rate constants and the NEM concentration with a slope of 1.3. The data are consistent with a simple bimolecular reaction mechanism and imply that one molecule of NEM inactivates 1 sulfhydryl group/active transport unit. The presence of 5 mM NMN affected the rate of NEM (2.5 mM) inactivation: the t1/2 values for inactivation in the presence and absence of substrate were 7.3 and 2.0 min, respectively. The results demonstrate an essential requirement for disulfide and sulfhydryl groups.     

Arginyl and histidyl groups are essential for organic anion exchange in renal brush-border membrane vesicles

The effect of side chain modification on the organic anion exchanger in the renal brush-border membrane was examined to identify what amino acid residues constitute the substrate binding site. One histidyl-specific reagent, diethyl pyrocarbonate (DEPC), and 2 arginyl-specific reagents, phenylglyoxal and 2,3-butanedione, were tested for their effect on the specifically mediated transport of p-amino[3H]hippurate (PAH), a prototypic organic anion. The specifically mediated transport refers to the difference in the uptake of [3H]PAH in the absence and presence of a known competitive inhibitor, probenecid, and was examined in brush-border membrane vesicles isolated from the outer cortex of canine kidneys. The experiments were performed utilizing a rapid filtration assay. DEPC, phenylglyoxal, and 2,3-butanedione inactivated the specifically mediated PAH transport, i.e. probenecid inhibitable transport with IC50 values of 160, 710, and 1780 microM, respectively. The rates of PAH inactivation by DEPC and phenylglyoxal were suggestive of multiple pseudo first-order reaction kinetics and were consistent with a reaction mechanism whereby more than 1 arginyl or histidyl residue is inactivated. Furthermore, PAH (5 mM) did not affect the rate of phenylglyoxal inactivation. In contrast, PAH (5 mM) affected the rate of DEPC inactivation. The modification by DEPC was specific for histidyl residues since transport could be restored by treatment with hydroxylamine. The results demonstrate that histidyl and arginyl residues are essential for organic anion transport in brush-border membrane vesicles. We conclude that the histidyl residue constitutes the cationic binding site for the anionic substrate, whereas the arginyl residue(s) serves to guide the substrate to or away from the histidyl site.     

Sulfhydryl groups are essential for organic cation exchange in rabbit renal basolateral membrane vesicles

The effect of N-ethylmaleimide (NEM), an irreversible sulfhydryl modifying reagent, on the transport of organic cations in the renal basolateral membrane was examined. The studies were conducted examining the exchange of [3H]tetraethylammonium (TEA) for unlabeled TEA in basolateral membrane vesicles isolated from the outer cortex of rabbit kidneys. NEM inactivated TEA transport in a dose-dependent fashion with an IC50 value of 260 microM. The rate of TEA transport inactivation followed apparent pseudo-first-order reaction kinetics. A replot of the data gave a linear relationship between the apparent rate constants and the NEM concentration with a slope of 4.0. The data imply that inactivation involves the binding of at least four molecules of NEM per active transport unit. This is most consistent with the presence of four sulfhydryl groups at this site. The substrate TEA displayed a dose-dependent enhancement of NEM inactivation, with 50% enhancement occurring at 365 microM TEA. Another organic cation, N1-methylnicotinamide, known to share a common transport mechanism with the TEA/TEA exchanger is also capable of increasing the reactivity of sulfhydryl groups to NEM. These results demonstrate that there are essential sulfhydryl groups for organic cation transport in the basolateral membrane. In addition, the capability of organic cations to alter the susceptibility to sulfhydryl modification suggests that these groups may have a dynamic role in the transport process.     

p-Chloromercuribenzenesulfonic acid stimulation of chloride-dependent sodium and potassium transport in human red blood cells

The organic mercurial p-chloromercuribenzensulfonic acid (PCMBS) reversibly increases fluxes of sodium and potassium across the human red blood cell membrane. We examined the effect of different monovalent anions on cation fluxes stimulated by PCMBS. A substantial portion of the fluxes of both cations was found to have a specific anion requirement for chloride or bromide, and was not observed when chloride was replaced by nitrate, acetate or methylsulfate. The chloride-dependent component of the cation fluxes was only observed when the cells were exposed to PCMBS concentrations of 0.5 mM or greater. Furosemide (1 mM) did not inhibit the PCMBS-stimulated cation fluxes. The observed anion specificity is directly associated with the transport process rather than PCMBS binding to the membrane. A portion of the potassium transport stimulated by PCMBS appears to involve K+-K+ exchange; however, Na+ + K+ cotransport is not stimulated by this sulfhydryl reagent.     

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.     

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.     

Alloxan stimulates p-aminohippurate uptake in renal basal-lateral membranous vesicles

In renal basal-lateral membranous vesicles, the probenecid-sensitive p-aminohippurate uptake was stimulated by alloxan. This stimulation of uptake was observed only after a lag period of 15 seconds, and it reached a maximal value after one minute. Stimulation was increased by 1 mM to 5 mM alloxan in a linear fashion. The effect was maximal and constant between 5 mM and 20 mM alloxan. Alloxan affected neither the glucose space of the vesicle nor the rate of transport or diffusion of glutamate, another organic anion. The mechanism of stimulation by alloxan was not clear. Its effect was blocked by the sulfhydryl reagent N-ethylmaleimide and weakly mimicked by H2O2, an oxidizing reagent. However, ninhydrin, a structural analogue of alloxan which reacts with sulfhydryl groups, and glucose, a neutral structural analogue of alloxan, failed to stimulate probenecid-sensitive uptake.     

Evidence indicating that pig renal phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane

Phosphate-activated glutaminase in intact pig renal mitochondria was inhibited 50-70% by the sulfhydryl reagents mersalyl and N-ethylmaleimide (0.3-1.0 mM), when assayed at pH 7.4 in the presence of no or low phosphate (10 mM) and glutamine (2 mM). However, sulfhydryl reagents added to intact mitochondria did not inhibit the SH-enzyme beta-hydroxybutyrate dehydrogenase (a marker of the inner face of the inner mitochondrial membrane), but did so upon addition to sonicated mitochondria. This indicates that the sulfhydryl reagents are impermeable to the inner membrane and that regulatory sulfhydryl groups for glutaminase have an external localization here. The inhibition observed when sulfhydryl reagents were added to intact mitochondria could not be attributed to an effect on a phosphate carrier, but evidence was obtained that pig renal mitochondria have also a glutamine transporter, which is inhibited only by mersalyl and not by N-ethylmaleimide. Mersalyl and N-ethylmaleimide showed nondistinguishable effects on the kinetics of glutamine hydrolysis, affecting only the apparent Vmax for glutamine and not the apparent Km calculated from linear Hanes-Woolf plots. Furthermore, both calcium (which activates glutamine hydrolysis), as well as alanine (which has no effect on the hydrolytic rate), inhibited glutamine transport into the mitochondria, indicating that transport of glutamine is not rate-limiting for the glutaminase reaction. Desenzitation to inhibition by mersalyl and N-ethylmaleimide occurred when the assay was performed under optimal conditions for phosphate activated glutaminase (i.e. in the presence of 150 mM phosphate, 20 mM glutamine and at pH 8.6). Desenzitation also occurred when the enzyme was incubated with low concentrations of Triton X-100 which did not affect the rate of glutamine hydrolysis. Following incubation with [14C]glutamine and correction for glutamate in contaminating subcellular particles, the specific activity of [14C]glutamate in the mitochondria was much lower than that of the surrounding incubation medium. This indicates that glutamine-derived glutamate is released from the mitochondria without being mixed with the endogenous pool of glutamate. The results suggest that phosphate-activated glutaminase has a functionally predominant external localization in the inner mitochondrial membrane.     

Inhibitory effect of diethyl pyrocarbonate on the H+/organic cation antiport system in rat renal brush-border membranes

We examined the effect of diethyl pyrocarbonate (DEPC), a histidine-specific reagent, on the H+/organic cation antiport system in brush-border membrane vesicles isolated from the rat renal cortex. Pretreatment of membrane vesicles with DEPC resulted in the inhibition of tetraethylammonium transport. This inhibition was reversed by subsequent treatment with hydroxylamine, but not with dithiotreitol. In contrast, the uptake of p-aminohippurate, a typical organic anion, was not inhibited by DEPC pretreatment. In the absence of an H+ gradient, pretreatment with DEPC inhibited the uptake of tetraethylammonium at pH 6.0-7.0, but not at pH 7.5. The Vmax value of tetraethylammonium uptake at pH 7.0 was decreased without any change in the Km value, but the kinetic parameters at pH 7.5 were unchanged. Unlabeled tetraethylamonium did not protect against the inhibition by DEPC. These results suggest that histidine residues in the organic cation carrier are essential for transport at acidic and neutral pH values, but not at alkaline pH values, and that histidine residues play an important role as regulatory sites in the H+/organic cation antiport system rather than as binding sites for organic cations.     

l-Glutamine transport in native vesicles isolated from Ehrlich ascites tumor cell membranes

Native vesicles isolated from Ehrlich ascites tumor cells accumulate glutamine by means of Na⁺-dependent transport systems; thiocyanate seems to be the more effective anion. The apparent affinity constant for the process was 0.38 mM. The Arrhenius plot gave an apparent activation energy of 12.3 kJ/mol. The structural analogs of glutamine, acivicin (2.5 mM) and azaserine (2.5 mM), inhibited the net uptake by 67 and 70%, respectively. The sulfhydryl reagents mersalyl, PCMBS, NEM, and DTNB also inhibited net uptake, suggesting that sulfhydryl groups may be involved in the activity of the carrier protein. A strong inhibition was detected when the vesicles were incubated in the presence of alanine, cysteine, or serine; in addition, histidine, but not glutamate or leucine, had a negative effect on glutamine transport.     

System A transport activity in normal rat hepatocytes and transformed liver cells: substrate protection from inactivation by sulfhydryl-modifying reagents

The transport of amino acids by normal rat hepatocytes and several hepatoma cell lines has been examined for inactivation by various protein-modifying reagents, including the sulfhydryl-preferring reagents N-ethylmaleimide (NEM) and p-chloromercuribenzene sulfonate (PCMBS). Uptake of 2-aminoisobutyric acid (AIB), a specific probe for hepatic System A-mediated transport, was equally sensitive to inhibition by the organic mercurial PCMBS in each of the cell types tested. In contrast, the sensitivity of System A to inactivation by NEM was substantially different among the five cell types. Normal hepatocytes showed the greatest sensitivity, while the hepatoma cells varied in their responsiveness from moderate to no inhibition. PCMBS inactivated greater than 85% of the System A activity in rat H4 hepatoma cells within 10 min (t1/2 = 3 min). The inhibition by PCMBS was rapidly reversed by treatment of the cells with dithiothreitol. Amino acids showing a high affinity for System A protected the transport system from inactivation, whereas non-substrates produced little or no protection. Amino acid-dependent protection was stereospecific and system-specific. L-norleucine competitively inhibited AIB uptake (Ki = 1.9 +/- 0.1 mM) in H4 cells and also protected System A from PCMBS-dependent inactivation (half-maximal protection occurred at an amino acid concentration of 0.6 +/- 0.1 mM). N-bromosuccinimide was completely ineffective as an inhibitor of System A activity in hepatocytes, whereas treatment of H4 rat hepatoma cells with this reagent resulted in greater than 95% inhibition.     

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.     

The hexose transporters at the plasma membrane and the tonoplast of transformed plant cells: kinetic characterization of two distinct carriers.

The plasma membrane hexose transporter and the tonoplast hexose transporter from heterotrophically grown transformed Nicotiana tabacum cells have been studied in vitro using membrane vesicles for trans-zero transport studies. In highly purified phase-partitioned outside-out plasma membrane vesicles (PMV) the hexose transporter showed an apparent Km value of 230 microM (substrate: 3-O-methyl-D-glucose (3-OMG); pHi 7.2/pHo 7.2), which was reduced to 120 microM when a pH gradient was imposed (pHo 5.7/pHi 7.2). However, the Vmax value was not affected indicating that no stable pH gradient was formed. Uptake experiments with 14C-labelled acetate supported this interpretation. Transport was insensitive to N-ethylmaleimide (NEM; up to 1 mM concentration) and p-chloromercuribenzene sulfonate (PCMBS; up to 500 microM), whereas the tonoplast hexose transporter (in mixed inside / out and outside / out vesicles) was inhibited by NEM in a substrate-protectable manner, and PCMBS was also inhibitory. Kinetically two components with apparent Km values of 6 and 20 mM could be distinguished for the tonoplast hexose transporter. Substrate specificities of both transporters were similar except for D-galactose and D-fructose. The results indicate structural differences between the tonoplast and plasma membrane hexose transporters in plants.     

Melibiose carrier of Escherichia coli: use of cysteine mutagenesis to identify the amino acids on the hydrophilic face of transmembrane helix 2.

The melibiose carrier from Escherichia coli is a galactoside-cation symporter. Based on both experimental evidence and hydropathy analysis, 12 transmembrane helices have been assigned to this integral membrane protein. Transmembrane helix 2 contains several charged and polar amino acids that have been shown to be essential for the cation-coupled transport of melibiose. Starting with the cysteine-less melibiose carrier, we have individually substituted cysteine for amino acids 39-66, which includes the proposed transmembrane helix 2. In the resulting derivative carriers, we measured the transport of melibiose, determined the effect of the hydrophilic sulfhydryl reagent, p-chloromercuribenzenesulfonic acid (PCMBS), on transport in intact cells and inside out vesicles, and examined the ability of melibiose to protect the carrier from inactivation by the sulfhydryl reagent. We found a set of seven positions in which the reaction with the sulfhydryl reagent caused partial or complete loss of carrier function measured in intact cells or inside-out vesicles. The presence of melibiose protected five of these positions from reaction with PCMBS. The reaction of two additional positions with PCMBS resulted in the partial loss of transport function only in inside-out vesicles. Melibiose protected these two positions from reaction with the reagent. Together, the PCMBS-sensitive sites and charged residues assigned to helix 2 form a cluster of amino acids that map in three rows with each row comprised of every fourth residue. This is the pattern expected of residues that are part of an alpha-helical structure and thus the rows are tilted at an angle of 25 degrees to the helical axis. We suggest that these residues line the path of melibiose and its associated cation through the carrier.     

pH sensitivity of H+/organic cation antiport system in rat renal brush-border membranes

We examined the pH sensitivity of the H+/organic cation antiport system in brush-border membranes isolated from rat renal cortex. The uptake of tetraethylammonium, a typical organic cation, in the absence of an H+ gradient had a marked pH dependence with an optimum pH of 7.0, while the uptake of p-aminohippurate, an organic anion, and D-glucose was almost consistent in the pH range of 6.0-8.0. The decreased tetraethylammonium uptake by brush-border membrane vesicles, suspended in an acidic pH buffer or an alkaline pH buffer, was completely recovered by subsequent treatment of the vesicles with a pH 7.0 buffer. The pH sensitivity of tetraethylammonium uptake was not changed in the presence of either carbonyl cyanide p-trifluoromethoxyphenylhydrazone, a protonophore, or valinomycin (voltage-clamped condition). Kinetic parameters of tetraethylammonium uptake were changed in a pH-dependent manner, although Eadie-Hofstee plots of tetraethylammonium uptake were linear in the pH range of 6.0-8.0, indicating the existence of one mode of transport system at various pH values. At an acidic pH, the Km was increased without any change in Vmax value, compared with the values at pH 7.0. On the other hand, at an alkaline pH, the Vmax was decreased without a change in Km value. These results suggest that the H+/organic cation antiport system in renal brush-border membranes is very sensitive to pH (optimum pH of 7.0), in contrast to organic anion and D-glucose transport systems, and that pH is an important factor to regulate the activity of the H+/organic cation antiport system, as well as H+ gradient (a driving force).     

Properties of a mutant lactose carrier of Escherichia coli with a Cys148----Ser148 substitution

The cysteine residue at position 148 in the lactose carrier protein of Escherichia coli has been replaced by serine using oligonucleotide-directed, site-specific mutagenesis of the lac Y gene. The mutant carrier is incorporated into the cytoplasmic membrane to the same extent as the wild-type carrier, confers a lactose-positive phenotype on cells, and actively transports lactose and other galactosides. However, the maximum rate of transport for several substrates is reduced by a factor of 6-10 while the apparent affinity is reduced by a factor of 2-4. Carrier activity in the mutant is much less sensitive to sulfhydryl reagents (HgCl2, p-(chloromercuri)benzenesulfonate and N-ethylmaleimide) than in the wild type, and beta-D-galactosyl 1-thio-beta-D-galactoside does not protect the mutant carrier against slow inactivation by N-ethylmaleimide. It is concluded that the Cys148 residue is not essential for carrier-catalyzed galactoside: proton symport and that its alkylation presumbly prohibits access of the substrate to the binding site by steric hindrance. A serine residue at position 148 in the amino acid sequence appears to alter the protein structure in such a way that one or more sulfhydryl groups elsewhere in the protein become accessible to alkylating agents thereby inhibiting transport. Recently, Trumble et al. [(1984) Biochem. Biophys. Res. Commun. 119, 860-867] arrived at similar conclusions by investigating a mutant carrier with a Cys148----Gly148 replacement.     

Inhibition of Amino Acid Transport in Rabbit Intestine by p-Chloromercuriphenyl Sulfonic Acid

Influx of phenylalanine across the brush border of rabbit intestine is markedly reduced by treatment with 5 mM p-chloromercuriphenyl sulfonate (PCMBS). The effect is rapidly and completely reversed by dithiothreitol. Phenylalanine influx into PCMBS-treated tissue can be competitively inhibited by other neutral amino acids and follows saturation kinetics. PCMBS causes an increase in the apparent Michaelis constant from the value observed in control tissue but does not alter the maximal influx significantly. Treatment of the tissue with PCMBS leads to a significant reduction in the Na-sensitivity of the transport, and a number of results indicate that the major effect of the reagent is to cause a marked reduction in the affinity of the transport system for Na. The transport system can be partially protected against reaction with PCMBS by phenylalanine and tryptophan but not by methionine or norleucine. The results suggest that PCMBS reacts with a sulfhydryl group in the region of the transport site and may alter conformational changes associated with the binding of substrates.     

Hexose transport in L6 rat myoblasts. II. The effects of sulfhydryl reagents

The importance of sulfhydryl groups for hexose transport in undifferentiated L6 rat myoblasts was investigated. N-ethylmaleimide (NEM) and p-chloromer-curibenzenesulfonic acid (pCMBS) inhibited 2-deoxy-D-glucose (2-DOG) transport in a time and concentration-dependent manner. The inhibition produced by both reagents was virtually complete within 5 min, although neither reagent inhibited transport more than 70–80% regardless of the concentrations or incubation times used. Furthermore, the inhibition of 2-DOG transport by pCMBS or NEM could not be prevented by simultaneous preincubation of cells with 20 mM D-glucose or 20 mM 2-DOG. This suggests that sulfhydryl groups required for transport are separate from the hexose binding and transport site. By comparing the effects of the membrane impermeant pCMBS to those of the membrane permeant NEM, cell surface sulfhydryl groups were shown to be essential for hexose binding and transport. In contrast to the inhibition of 2-DOG transport, pCMBS and NEM had much less of an effect on 3-O-methyl-D-glucose (3-OMG) transport. For example, 1 mM NEM inhibited 2-DOG transport by 66%, whereas 3-OMG transport was inhibited by only 7%. This supports the suggestion that these hexose analogues may be transported by different carriers. Kinetic analysis of transport shows that treatment of cells with 1 mM NEM or 1 pCMBS results in inactivation of the high affinity 2-DOG transport system, whereas the low affinity transport system is unaffected. 3-OMG is preferentially transported by the low affinity system.     

Evidence for inherent differences in the system A carrier from normal and transformed liver tissue. Differential inactivation and substrate protection in membrane vesicles and reconstituted proteoliposomes

Plasma membrane vesicles isolated from intact rat liver (normal hepatocyte) or cultured rat H4 hepatoma cells retain Na+-dependent uptake of 2-aminoisobutyric acid mediated by System A. The carrier was inactivated in normal liver membrane vesicles by either N-ethylmaleimide (NEM) or p-chloromercuribenzene sulfonate (PCMBS). The concentrations required to produce half-maximal inhibition were approximately 370 and 110 microM for NEM and PCMBS, respectively. In contrast, transport of System A in H4 hepatoma membrane vesicles was sensitive to PCMBS (K 1/2 = 180 microM), yet totally unaffected by NEM at concentrations up to 5 mM. Substrate-dependent protection from PCMBS activation was observed for the System A activity in H4 hepatoma membranes, but not in vesicles from normal hepatocytes. Subsequent inactivation of the substrate-protected carrier by sulfhydryl-specific reagents, added following the removal of the protective amino acid, suggests that one or more cysteine residues become less reactive in the presence of System A substrates. Treatment of solubilized membrane proteins with NEM prior to reconstitution into artificial proteoliposomes showed that the selective inactivation by NEM of the carrier in normal liver membranes is not dependent on the lipid environment or on the integrity of the plasma membrane. The results support the hypothesis that there are inherent differences in the System A carriers that are present in normal and transformed liver tissue.     

Investigation of the relation of the pH-dependent dissociation of malate dehydrogenase to modification of the enzyme by N-ethylmaleimide.

The pH-dependent dissociation of porcine heart mitochondrial malate dehydrogenase (L-malate:NAD+ oxidoreductase, EC 1.1.1.37) has been further characterized using the technique of sedimentation velocity ultracentrifugation. The increased rate and specificity of the inactivation of mitochondrial malate dehydrogenase by the sulfhydryl reagent N-ethylmaleimide has been correlated with the pH-dependent dissociation of the enzyme. Data obtained using NAD+ and its component parts to reassociate the enzyme and also to protect the enzyme from inactivation by N-ethylmaleimide suggest that the sulfhydryl residues being modified by N-ethylmaleimide are inaccessible when the enzyme is in its dimeric form. A dissociation curve for the pH-dependent dissociation suggests that a limited number of residues are being protonated concomitant with dissociation of the enzyme. An apparent pKa of 5.3 has been determined for this phenomenon. Studies using enzyme modified by the sulfhydryl reagent N-ethylmaleimide indicate that selective modification of essential sulfhydryl residues alters the proper binding of NADH.