Unmasking of an essential thiol during function of the membrane-bound enzyme II of the phosphenolpyruvate beta-glucoside phosphotransferase system of Escherichia coli.

beta-Glucoside transport by phosphoenolpyruvate-hexose phosphotransferase system in Escherichia coli is inactivated in vivo by thiol reagents. This inactivation is strongly enhanced by the presence of transported substrates. In a system reconstituted from soluble and membrane-bound components, only the particulate component, the membrane-bound enzyme IIbgl appeared as the target of N-ethylmaleimide inaction. The same feature was found in the case of methyl-alpha-D-glucoside uptake via enzyme IIglc. It is shown that the sensitizing effect of substrates is specific and not generalized, methyl-alpha-D-glucoside only sensitizes enzyme IIglc and p-nitrophenyl-beta-D-glucoside only sensitizes enzyme IIbgl towards N-ethylmaleimide inactivation. The inactivation of enzyme IIbgl by thiol reagents is also promoted in vivo by fluoride inhibition of phosphoenolpyruvate synthesis. In toluene-treated bacteria, the presence of phosphoenolpyruvate protects against inactivation by thiol reagents of p-nitrophenyl-beta-D-glucoside phosphorylation. Both results suggest that the inactivator resistent form of enzyme IIbgl is an energized form of the enzyme.     

Sugar transport by the bacterial phosphotransferase system. Characterization of the sulfhydryl groups and site-specific labeling of enzyme I

Enzyme I is the first protein of the phospho transfer sequence in the bacterial phosphoenolpyruvate:glycose phosphotransferase system. This protein exhibits a temperature-dependent monomer/dimer equilibrium. The nucleotide sequence of Escherichia coli ptsI indicates four -SH residues per subunit (Saffen, D. W., Presper, K. A., Doering, T. L., and Roseman, S. (1987) J. Biol. Chem. 262, 16241-16253). In the present experiments, the sulfhydryl groups of the E. coli enzyme were studied with various -SH-specific reagents. Titration of Enzyme I with 5,5'-dithiobis-2-nitrobenzoic acid also revealed four reacting -SH groups. The kinetics of the 5,5'-dithiobis-2-nitrobenzoic acid reaction with Enzyme I exhibit biphasic character, with pseudo-first order rate constants of 2.3 x 10(-2)/s and 2.3 x 10(-3)/s at pH 7.5, at room temperature. Fractional amplitudes associated with the rate constants were 25 +/- 5% for the fast and 75 +/- 5% for the slow rate. The "slow" rate was influenced by ligands that react with Enzyme I (the protein HPr, Mg2+, Mg2+ plus P-enolpyruvate), and also by temperature (at the temperature range where the monomer/dimer association occurs). The fractional ratio of the two rates remained at 1:3 under these conditions. Thus, under all conditions tested, two classes of -SH groups were detected, one reacting more rapidly than the other three -SH groups. Modification of the "fast" -SH group results in an active enzyme capable of forming dimer, whereas modification of the slow -SH groups results in inactive and monomeric Enzyme I. The enzyme was labeled with pyrene maleimide under conditions where only the more reactive sulfhydryl group was derivatized. Hydrolysis by trypsin followed by reverse-phase high performance liquid chromatography analysis of the peptide mixture resulted in only one fluorescent peak. This peak was not observed when the more reactive sulfhydryl residue was protected prior to pyrene maleimide labeling. Amino acid sequencing of the fluorescent peak indicated that the more reactive residue is the C-terminal amino acid residue, cysteine 575. The results provide a means for selectively labeling Enzyme I with a fluorophore at a single site while retaining full catalytic activity.     

Membrane integrity and phospholipid movement influence the base exchange reaction in rat liver microsomesý

Properties of Ca2+-stimulated incorporation of amincalcohols, serine and ethanolamine, into phospholipids, and factors regulating the reaction were studied in endoplasmic reticulum membranes isolated from rat liver. In contrast to apparent Km values for either aminoalcohol, maximal velocities of the reaction were significantly affected by Ca2+ concentration. No competition between these two soluble substrates used at equimolar concentrations close to their Km values was observed, suggesting the existence of two distinct phospholipid base exchange activities. The enzyme utilizing the electrically neutral serine was not sensitive to changes of membrane potential evoked by valinomycin in the presence of KCI. On the other hand, when positively charged ethanolamine served as a substrate, the enzyme activity was inhibited by 140 mM KCI and this effect was reversed by valinomycin. The rates of inhibition of phospholipid base exchange reactions by various thiol group modifying reagents were al so found to differ. Cd2+ and lipophylic p-chloromercuribenzoic acid at micromolar concentrations were most effective. It can be suggested that -SH groups located within the hydrophobic core of the enzymes molecules are essential for the recognition of membrane substrates. However, the influence of the -SH group modifying reagents on the protein-facilitated phospholipid motion across endoplasmic reticulum membranes can not be excluded, since an integral protein-mediated transverse movement of phospholipids within the membrane bilayer and Ca2+-mediated changes in configuration of the phospholipid polar head groups seem to be a regulatory step of the reaction. Indeed, when the membrane integrity was disordered by detergents or an organic solvent, the reaction was inhibited, although not due to the transport of its water-soluble substrates is affected, but due to modulation of physical state of the membrane bilayer and, in consequence, the accessibility of phospholipid molecules.     

Effect of thiol reagents and ionizing radiation on the permeability of erythrocyte membrane for spin-labeled non-electrolytes

Four different thiol reagents: p-chloromercuribenzoic acid (pCMB), mercuric chloride (HgCl2), N-ethylmaleimide (NEM), and 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) were employed as agents modifying the transport of a hydrophilic and hydrophobic non-electrolyte spin labels: 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPOL) and 2,2,6,6-tetramethylpiperidine-1-oxyl (TEMPO) into bovine erythrocytes. Gamma-irradiation of erythrocytes amplified the effects of pCMB, HgCl2 and NEM of inhibition of TEMPOL transport and attenuated them in the case of TEMPO transport. These results suggest that the transport of TEMPOL across the erythrocyte membrane is controlled by both superficially and more deeply located membrane -SH groups while only superficial -SH groups control the transport of TEMPO. The lower extent of inhibition of TEMPO transport indicates a higher contribution of diffusion through the lipid phase to the transport of TEMPO across the erythrocyte membrane as compared with TEMPOL.     

Evidence for the existence of a channel in the glucose-specific carrier EIIGlc of the Salmonella typhimurium phosphoenolpyruvate-dependent phosphotransferase system

The effect of membrane-impermeable sulfhydryl reagents on glucose-specific enzyme II (EIIGlc) activity has been studied in Salmonella typhimurium whole cells and in properly sealed inverted cytoplasmic membrane vesicles. Glutathione N-hexylmaleimide and N-polymethylenecarboxymaleimides inactivate methyl alpha-D-glucopyranoside (alpha-MeGlc) transport and phosphorylation in whole cell preparations at a dithiol that can be protected by oxidizing reagents, trivalent arsenicals, or phosphorylation of EIIGlc. Accessibility to this activity-linked site is restricted to small apolar reagents or to polar reagents with a hydrophobic spacer between the polar group and the reactive maleimide moiety. These same reagents inactivate alpha-MeGlc phosphorylation in inverted cytoplasmic membrane vesicles. Inhibition results from reaction at a dithiol that can be protected by nonpermeant mercurials, oxidants, and arsenicals as well as by phosphorylation of EII. The characteristics of this site are virtually identical with those of the activity-linked dithiol elucidated in intact cells. No evidence could be found for a second activity-linked site on the other side of the membrane when the permeable reagent N-ethylmaleimide was used. Since only one activity-linked dithiol can be detected with sealed inverted membrane vesicles or intact cells and it is accessible to membrane-impermeable sulfhydryl reagents from both sides of the cytoplasmic membrane, we suggest that it is located in a channel constructured by the carrier and that the channel spans the membrane. A second dithiol, not essential for activity, is located near the outer surface of the cytoplasmic membrane.     

Comparative inhibition studies of the phosphotransferase and glycerophosphate acylation systems in membrane vesicles of Escherichia coli

Purified membrane vesicles were treated with various reagents specific for different amino acid side-chains. Titration of sulfhydryl groups with specific reagents shows that the sulfhydryl content of membrane vesicles as estimated directly is similar to that found by treating spheroplasts or cells and then isolating the membrane vesicles. The blocking of sulfhydryl groups specifically inhibits the α-methylglucoside transport system (phosphotransferase system), whereas the glycerophosphate acylation system is not affected. The kinetics of inhibition of the first system show that a high reactivity of the sulfhydryl groups is involved. Inhibition of the acyltransferase activity by sulfhydryl reagents occurs only on partial denaturation of the membranes induced by mild sonication, heat or toluene treatment. The Inhibition is at the level of the glycerol 3-phosphate:acyl thioester acyltransferase.The effects of sonication and/or sulfhydryl reagents were measured by sulfhydryl titration, by assays of NADH oxidase and d-lactate dehydrogenase activities, as well as by 1-anilino-8-naphthalene sulfonate binding. The results support the hypothesis that the acyltransferase system is embedded within the membrane and that the readily accessible permease system is closer to (or at) the surface of the membrane.     

Topography and functions of sulfhydryl groups of the human erythrocyte glucose transport mechanism

Summary Membrane-impermeant and -permeant maleimides were applied to characterize the location and function of the sulfhydryl (SH) groups essential for the facilitated diffusion mediated by the human erythrocyte glucose transport protein. Three such classes have been identified. Type I SH is accessible to membrane-impermeant reagents at the outer (exofacial) surface of the intact erythrocyte. Alkylation of this class inhibits glucose transport; D-glucose and cytochalasin B protect against the alkylation. Type II SH is located at the inner (endofacial) surface of the membrane and is accessible to the membrane-impermeant reagent glutathione maleimide only after lysis of the erythrocyte. D-glucose enhances, while cytochalasin B reduces, the alkylation of Type II SH by maleimides. Reaction of Types I and II SH with an impermeant maleimide increases the half-saturation concentration for binding of D-glucose to erythrocyte membranes. By contrast, inactivation of Type III SH markedly decreases the half-saturation concentration for the binding of D-glucose and other transported sugars. Type III SH is inactivated by the relatively lipid-soluble reagents N-ethylmaleimide (NEM) and dipyridyl disulfide, but not by the impermeant glutathione maleimide. Type III SH is thus located in a hydrophobic membrane domain. A kinetic model constructed to explain these observations indicates that Type III SH is required for the translocation event in a hydrophobic membrane domain which leads to the dissociation of glucose bound to transport sites at the membrane surfaces.     

The vectorial orientation of human monoamine oxidase in the mitochondrial outer membrane.

1. The localization of monoamine oxidase in the mitochondrial outer membrane was studied in preparations of human liver mitochondrial and brain-cortex non-synaptosomal and synaptosomal mitochondria. 2. Immunochemical accessibility in iso-osmotic and hypo-osmotic mitochondrial preparations was used to localize the enzyme. 3. It was shown that the immunochemically accessible tyramine-oxidizing activity was distributed approximately equally on both surfaces of the membrane in human liver and brain-cortex non-synaptosomal mitochondria. However, the immunochemically accessible beta-phenethylamine-oxidizing activity was situated predominantly on the outer surface, and the immunochemically accessible 5-hydroxytryptamine-oxidizing activity was situated predominantly on the inner surface of the mitochondrial outer membrane in liver and brain-cortex non-synaptosomal mitochondrial preparations. 4. Considerable variation in the distribution of the enzyme in preparations of synaptosomal mitochondria was seen. 5. The simplest model consistent with our observations is that, in liver and brain-cortex non-synaptosomal mitochondria, the tyramine-oxidizing activity is distributed on both sides of the mitochondrial outer membrane, the beta-phenethylamine-oxidizing activity is located on the outer surface of the outer membrane and the 5-hydroxytryptamine-oxidizing activity is located on the inner surface of the mitochondria outer membrane.     

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.     

The role of sulfhydryl groups in functioning of components of adenylate cyclase signal system in smooth muscles of the mollusk Anodonta cygnea (effect of N-ethylmaleimide and p-chloromercuribenzoic acid)]

The alkylating agent N-ethylameimide and the sulfhydryl group blocker p-chloromercuribenzoic acid (CPMA) inhibited in dose-dependent manner both basal activity of adenylyl cyclase (AC) and its activity stimulated by non-hormonal substances (forskolin, sodium fluoride, guanylilimidodiphosphate) in smooth muscles of the freshwater bivalve mollusk Anodonta cygnea. The double increase (from 30 to 60 min) in the time of preincubation of a sarcolemmal membrane fraction with ethylmaleimide and CPMA led to an essential increase in enzyme inhibition (especially for CPMA). 50 mM SH-containing reagent beta-mercaptoethanol (ME) partially restored the AC activity, inhibited by N-ethylmaleimide and CPMA, except when these two latter reagents were in high concentrations (1-10 and 0.5 mM, respectively). The data obtained point to the key role of cysteine SH-groups in regulation of the functional activity of proteins, components of the adenylyl cyclase system--AC and heterotrimeric G-proteins.     

Influence of liposome charge and composition on their interaction with human blood serum proteins

The roles of sulfhydryl and disulfide groups in the specific binding of synthetic cannabinoid CP-55,940 to the cannabinoid receptor in membrane preparations from the rat cerebral cortex have been examined. Various sulfhydryl blocking reagents including p-chloromercuribenzoic acid (p-CMB), N-ethylmaleimide (NEM), o-iodosobenzoic acid (o-ISB), and methyl methanethiosulfonate (MMTS) inhibited the specific binding of [³H]CP-55,940 to the cannabinoid receptor in a dose-dependent manner. About 80–95% inhibition was obtained at a 0.1 mM concentration of these reagents. Scatchard analysis of saturation experiments indicates that most of these sulfhydryl modifying reagents reduce both the binding affinity (K_d) and capacity (B_max). On the other hand, DL-dithiothreitol (DTT), a disulfide reducing agent, also irreversibly inhibited the specific binding of [³H]CP-55,940 to the receptor and about 50% inhibition was obtained at a 5 mM concentration. Furthermore, 5mM DTT was abelt to dissociate 50% of the bound ligand from the ligand-receptor complex. The marked inhibition of [³H]CP-55,940 binding by sulfhydryl reagents suggests that at least one free sulfhydryl group is essential to the binding of the ligand to the receptor. In addition, the inhibition of the binding by DTT implies that besides free sulfhydryl group(s), the integrity of a disulfide bridge is also important for [³H]CP-55,940 binding to the cannabinoid receptor.     

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.     

Rhodopsin-G-protein interactions monitored by resonance energy transfer

Resonance energy transfer measurements were implemented to monitor the specific interactions between G-protein and rhodopsin in phospholipid vesicles reconstituted with the purified proteins. Fluorescently labeled G-protein was extracted from bleached rod outer segments (ROS) reacted with several sulfhydryl reagents: N-(1-pyrenyl)maleimide (P), monobromobimane (B), 7-(diethylamino)-3-(4-maleimidylphenyl)-4-methylcoumarin (C), and N-(4-anilino-1-naphthyl)maleimide (A). Limited labeling of ROS, resulting in the modification of less than a single -SH residue per G-protein molecule and less than 0.2 residue per rhodopsin, did not impair the specific in situ interactions between rhodopsin and G-protein. This was demonstrated by preservation of their light-activated tight association and Gpp(NH)p binding and their fast dissociation with excess GTP. The distribution of fluorescent label among the three subunits of G-protein revealed a highly reactive -SH group in the gamma subunit accessible to labeling when G-protein was bound specifically to bleached rhodopsin. Recombination of purified fluorescent derivatives of G-protein with purified rhodopsin reconstituted in lipid vesicles restored the light-activated Gpp(NH)p binding to a level comparable to that measured with unlabeled G-protein. Similar observations were obtained with ROS depleted of peripheral proteins. Likewise, modification of up to two -SH groups per rhodopsin molecule with the fluorescent reagents did not affect the functional recombination of G-protein with rhodopsin in reconstituted lipid vesicles or in depleted ROS. Interactions between rhodopsin and G-protein were monitored by resonance energy transfer measurements, with the following fluorescent conjugates as donor/acceptor couples: P-rhodopsin/C-G-protein, P-rhodopsin/B-G-protein, and P-G-protein/C-rhodopsin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on Mitochondrial Proteins. II. Localization of Components in the inner membrane labelling with diazobenzenesulfonate,a non-penetrating probe

The topography of the inner membrane of rat liver mitochondria was studied using a probe, diazobenzenesulfonate, which interacts preferentially with surface components. Inner membranes were examined both in a native orientation as found in the intact mitochondrion or in an inverted state as found in isolated inner membranes prepared by sonication.Enzyme inactivation as a consequence of diazobenzenesulfonate labeling was employed to determine the localization of a number of inner membrane activities. In inner membranes labeled on the outer surface, NADH and succinate oxidation were strongly inhibited while ATPase and $\text{ascorbate}\text{-N,N,N′,N′-}\text{tetramethyl}\text{-p-}\text{phenylene-diamine}$ (TMPD) oxidase activities were unaffected. In inner membranes labeled on the inner surface. ATPase and succinate oxidation were inactivated while NADH oxidation and ascorbate-TMPD oxidase were unaffected. Succinate dehydrogenase was inhibited only by labeling the inner surface while NADH dehydrogenase was inhibited to a similar extent by treatment of either surface.Sodium dodecylsulfate-polypeptides (66 000 and 26 000) on the outer surface of the inner membrane and five polypeptides (80 000, 66 000, 51 000-48 000, and 26 000) on the inner surface. These results indicate a highly asymmetric localization of inner membrane components.     

Dual Electron Microscopic Localization of Mitochondrial Creatine Kinase in Brain Mitochondria

Mitochondrial creatine kinase in brain mitochondria appears to be located at two different intramitochondrial sites. By using immunogold-labeling techniques, a peripheral immunoreactivity was localized between the two boundary membranes, while an additional, central immunoreactivity was found at the crista surface. The peripheral enzyme was accessible to the antibodies after treatment of the brain mitochondria with 100-300 μg digitonin/mg mitochondrial protein, which left 75% of the activity bound to the membranes. Electron microscopic analyses revealed that 43% of the labeled, peripheral creatine kinase was bound at those places where outer membrane vesicles remained attached to the inner envelope membrane, suggesting that the enzyme is in involved in contact formation between outer and inner mitochondrial membranes. Postembedding staining of mitochondria on thin sections of brain tissue or in the isolated state led to the observation of a second location of creatine kinase inside the mitochondria, along the cristae, which was not accessible to the antibodies in isolated, digitonin-treated mitochondria.     

Conformational features of bovine heart mitochondrial transhydrogenase

Both purified and functionally reconstituted bovine heart mitochondrial transhydrogenase were treated with various sulfhydryl modification reagents in the presence of substrates. In all cases, NAD+ and NADH had no effect on the rate of inactivation. NADP+ protected transhydrogenase from inactivation by 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in both systems, while NADPH slightly protected the reconstituted enzyme but stimulated inactivation in the purified enzyme. The rate of N-ethylmaleimide (NEM) inactivation was enhanced by NADPH in both systems. The copper-(o-phenanthroline)2 complex [Cu(OP)2] inhibited the purified enzyme, and this inhibition was substantially prevented by NADP+. Transhydrogenase was shown to undergo conformational changes upon binding of NADP+ or NADPH. Sulfhydryl quantitation with DTNB indicated the presence of two sulfhydryl groups exposed to the external medium in the native conformation of the soluble purified enzyme or after reconstitution into phosphatidylcholine liposomes. In the presence of NADP+, one sulfhydryl group was quantitated in the nondenatured soluble enzyme, while none was found in the reconstituted enzyme, suggesting that the reactive sulfhydryl groups were less accessible in the NADP+-enzyme complex. In the presence of NADPH, however, four sulfhydryl groups were found to be exposed to DTNB in both the soluble and reconstituted enzymes. NEM selectively reacted with only one sulfhydryl group of the purified enzyme in the absence of substrates, but the presence of NADPH stimulated the NEM-dependent inactivation of the enzyme and resulted in the modification of three additional sulfhydryl groups. The sulfhydryl group not modified by NEM in the absence of substrates is not sterically hindered in the native enzyme as it can still be quantitated by DTNB or modified by iodoacetamide.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of alcohol dehydrogenase with tert-butylhydroperoxide: stimulation of the horse liver and inhibition of the yeast enzymes

Preincubation of horse liver alcohol dehydrogenase (HLADH) with the oxidative agent, tert-butyl hydroperoxide (tBOOH) results in a twofold stimulation of the ethanol dehydrogenase activity of this enzyme. This stimulation was dependent on tBOOH concentration up to 100 mM; above this concentration tBOOH did not further stimulate ethanol oxidation by HLADH. Active-site-directed reagents and classical ADH binary complexes were used to probe the possible mechanism of this activating effect. The rate and extent of stimulation by tBOOH is strongly reduced by binary complexes with NAD(+) or NADH, whose pyrophosphate groups bind to Arg-47 and Arg-369. In contrast stimulation by tBOOH was not prevented by AMP or the sulfhydryl reagents dithiothreitol and glutathione, suggesting, respectively, a lack of role for Lys-228 and sulfhydryl group oxidation in the stimulation by tBOOH. In contrast to the liver enzyme, treatment of yeast ADH (YADH) with tBOOH irreversibly inhibited its ethanol dehydrogenase activity. Inhibition of YADH by tBOOH approximated first-order rate kinetics with respect to enzyme at fixed concentrations of tBOOH between 0.5 to 300 mM. Four -SH groups per molecule of YADH were modified by tBOOH, whereas only two -SH groups were modified in HLADH. The stimulation of HLADH by tBOOH is suggested to be due to destabilization of the catalytic Zn-coordination sphere and amino acids associated with coenzyme binding in the active site, while inactivation of YADH appears to be associated with -SH group oxidation by the peroxide.     

Reactive cysteine residue of bovine brain glutamate dehydrogenase isoproteins

Protein chemical studies of glutamate dehydrogenase isoproteins (GDH I and GDH II) from bovine brain reveal that one cystein residue is accessible for reaction with thiol-modifying reagent. Reaction of the two types of GDH isoproteins with p-chloromercuribenzoic acid resulted in a time-dependent loss of enzyme activity. The inactivation followed pseudo first-order kinetics with the second-order rate constant of 83 M(-1) s(-1) and 75 M(-1) s(-1) for GDH I and GDH II, respectively. The inactivation was partially prevented by preincubation of the glutamate dehydrogenase isoproteins with NADH. A combination of 10 mM 2-oxoglutarate with 2 mM NADH gave complete protection against the inactivation. There were no significant differences between the two glutamate dehydrogenase isoproteins in their sensitivities to inactivation by p-chloromercuribenzoic indicating that the microenvironmental structures of the GDH isoproteins are very similar to each other. Allosteric effectors such as ADP and GTP had no effects on the inactivation of glutamate dehydrogenase isoproteins by thiol-modifying reagents. By a combination of peptide mapping analysis and labeling with [14C] p-chloromercuribenzoic acid, a reactive cystein residue was identified as Cys323 in the overall sequence. The cysteine residue was clearly identical to sequences of other GDH species known.     

A study of the dependence of the human erythrocyte glucose transport system on membrane sulfhydryl groups

Summary A brief review of the data relating the glucose transport system and other membrane functions of red cells to surface sulfhydryl groups is presented. The effect of a variety of sulfhydryl reagents on glucose efflux rates from loaded red cells was studied. Neither iodoacetate nor iodoacetamide at 5mm inhibited efflux. Several maleimide derivatives and disulfides inhibited efflux in 0.7 to 2.0mm concentrations. Organomercury compounds, on the other hand, were active in the 0.07 to 0.1mm range. These data suggest that, if sulfhydryl groups are important in the glucose efflux process, they are not equally accessible to the above reagents; and that the primary effect of these reagents may be on structural elements near membrane sulfhydryl groups.     

Localization of Erythrocyte Membrane Sulfhydryl Groups Essential for Glucose Transport

The reactions of three organic mercurial compounds, chlormerodrin, parachloromercuribenzoate (PCMB), and parachloromercuribenzenesulfonate (PCMBS) with intact red blood cells, hemolyzed red cells, hemoglobin solutions, and hemoglobin-free ghosts have been characterized. Both PCMB and PCMBS react with only 2 to 3 sulfhydryl groups per mole of hemoglobin in solution, whereas chlormerodrin reacts with 6 to 7. In hemoglobin-free ghosts, however, all three reagents react with a similar number of sulfhydryl groups, approximately 4 x 10^-17 moles per cell, or about 25 per cent of the total stromal sulfhydryl groups, which react with inorganic mercuric chloride. In the intact cell the membrane imposes a diffusion barrier; chlormerodrin and PCMB penetrate slowly, whereas PCMBS does not. Kinetic studies of chlormerodrin binding to intact cells reveal that the majority of stromal sulfhydryl groups is located inside the diffusion barrier, with only 1 to 1.5 per cent (or 1 to 1,400,000 sites per cell) located outside of this barrier. Reaction of PCMBS with intact cells is limited to this small fraction on the outer membrane surface. All three reagents are capable of inhibiting glucose transport in the red cell. With chlormerodrin and PCMBS it was demonstrated that the inhibition results from interactions with the sulfhydryl groups located on the outer surface of the membrane.