Reactivity of the sulphydryl groups of the mitochondrial phosphate carrier

The rate of reaction of - SH groups of the mitochondrial phosphate carrier with 5,5'-dithiobis(2-nitrobenzoic acid) (Nbs2) and N-ethylmaleimide (MalNEt) was followed by measuring the inhibition of phosphate transport. The changes in the rate of reaction caused by alterations of the ionic composition of the matrix were compared with changes of the total intramitochondrial phosphate content, the intramitochondrial K+ content and the value of intramitochondrial pH. The ionic composition was manipulated by addition of valinomycin to non-respiring or to respiring mitochondria and by addition of inorganic phosphate to respiring and non-respiring mitochondria. From all these variables it was the changes of the intramitochondrial pH which correlated with the - SH group reactivity. Internal acidification decreased and internal alkalinization increased the rate of reaction of mitochondrial phosphate carrier with both Nbs2 and MalNEt. Nbs2 did not penetrate the inner mitochondrial membrane as assayed by determination of the acid-soluble thiol content of the matrix. From this fact it follows that the Nbs2-reactive SH groups of the carrier were accessible from the outer surface of the inner membrane in our experiments. It is concluded that intramitochondrial pH modifies the reactivity of the externally oriented - SH groups indirectly. A hypothesis is presented according to which protonation and deprotonation of the carrier molecule on the inner side could induce a conformational change of the whole protein altering also the microenvironment of the - SH groups near the opposite surface.     

Chemical modification of the brown-fat-mitochondrial uncoupling protein with tetranitromethane and N-ethylmaleimide. A cysteine residue is implicated in the nucleotide regulation of anion permeability

Treatment of brown adipose tissue mitochondria with tetranitromethane or N-ethylmaleimide decreases the affinity with which inhibitory nucleotide GDP binds to the tissue-specific uncoupling protein. Both reagents modify cysteine residues which are 'accessible' and 'buried' to 5,5'-dithio-bis(2-nitrobenzoic acid) (Nbs2). Modification of the single Nbs2-accessible residue correlates with the loss of high-affinity binding sites for GDP. Tetranitromethane does not affect the Cl- or H+ permeability of the protein in the absence of nucleotide, while N-ethylmaleimide increases both by 70-80%. Bound GDP is a less effective inhibitor of Cl- permeability after N-ethylmaleimide or tetranitromethane treatment, but retains much of the ability to inhibit H+ permeation.     

Affinity chromatography of heavy meromyosin subfragment-1 reacted with thiol reagents.

Separation of heavy meromyosin subfragment-1 treated with N-ethyl maleimide (MalNEt) into native -SH1- and -(SH1, SH2)-blocked protein populations could be achieved by affinity chromatography on agarose-ATP columns in the presence of Mg2+ or Ca2+. Covalent bridging of the two -SH groups by p-phenylenedimaleimide gave a product which has the same affinity of binding to ATP columns as the doubly blocked MalNEt preparation. Treatment with p-phenylenedimaleimide abolished binding to immobilized F-actin columns, whereas modifications by MalNEt did not affect adsorption by this chromatographic medium. Affinity chromatography on immobilized nucleotide and actin columns is suggested as an analytical tool in the study of the involvement of thiol groups in the myosin active site and its conformation.     

Sulfhydryl groups are involved in H+ translocation via the uncoupling protein of brown adipose tissue mitochondria

Mersalyl inhibits H+ transport via the uncoupling protein (UP) in brown adipose tissue (BAT) mitochondria estimated as swelling in potassium acetate (Ki 67 microM) or as valinomycin-induced H+ extrusion in K2SO4 (Ki 55 microM) and KCl. The swelling in KCl is depressed only slightly. Some other SH-reagents (p-hydroxymercuribenzoate, 5,5'-dithiobis(2-nitrobenzoate) and thiolyte DB), but not hydrophobic reagents (N-ethylmaleimide and eosin-5-maleimide), exhibit analogous inhibition. Thus an essential SH-group localized at the water-accessible cytosolic surface of UP was found to be involved in H+ transport via UP but not in Cl- transport.     

The reactivity and function of cysteine residues in rabbit liver aldolase B

Rabbit liver aldolase B (D-fructose-1,6-bisphosphate D-glyceraldehyde-3-phosphate-lyase, EC 4.1.2.13) contains 8 SH groups/subunit and no disulfide bonds. In the native enzyme 3 SH groups/subunit are titrable with 5,5'-dithiobis(2-nitrobenzoic) acid (Nbs2), 2,2'-dithiodipyridine and N-ethylmaleimide, whereas p-mercuribenzoate is able to react with 4 thiol groups per subunit. Among the three thiol groups titrable with Nbs2, two react 'fast' with simple second-order kinetics, one reacts 'slow' and for this thiol group saturation kinetics is observed, suggesting a reversible binding of Nbs2 to the enzyme prior to covalent modification. It is shown that this binding most likely occurs via ionic interactions in the region close to the active site. The kinetic differentiation between the two 'fast' reacting groups is possible by kinetic analysis of the release of Nbs residues from the modified enzyme. Modification of all exposed SH groups of aldolase B results in 14-32% loss of enzymatic activity. The complete inactivation of liver aldolase by 1 mM p-mercuribenzoate reported previously (Waud, J.M., Feldman, E. and Schray, K.J. (1981) Arch. Biochem. Biophys. 206, 292-295) is shown to be caused by a nonspecific reaction of this reagent used in large excess. It is concluded that this isoenzyme differs from muscle aldolase in the reactivity of exposed SH groups, the mechanisms of the interaction with modifying agents and also in the effect of SH group modification on the enzymatic activity.     

Interaction of a new fluorescent reagent with sulfhydryl groups of the (Na+ + K+)-stimulate ATPase.

The (Na+ + K+)-ATPase enzyme of rat brain microsomes can be reversibly inhibited by a new fluorescent sulfhydryl (SH) probe, dimethylaminoaphthalenecysteine-Hg+ (Dn-cys-Hg+). This reagent is more reactive than N-ethylamaleimide (MalNEt) toward membrane sulfhydryl groups. A procedure using the two SH reagents sequentially seems to permit a more selective labelling of the SH groups involved in the (Na+ + K+)-ATPase than is possible by using MalNEt alone. Brain microsomes treated by this method incorporate the fluorescent label within or near the active site of the enzyme. When the probe was bound a blue shift of its fluorescence emission maximum (from 540 to 495 nm) and a 20-fold increase in relative fluorescence occurred. This indicates that the Dn moiety is within a very non-polar region of the membrane.     

Differential interaction of fatty acids and fatty acyl CoA esters with the purified/reconstituted brown adipose tissue mitochondrial uncoupling protein

Proteoliposomes containing highly purified uncoupling protein generated by a modified purification/reconstitution procedure carried out active GDP dependent proton conductance. It was further established that long chain acyl CoA esters as well as fatty acids stimulated proton influx by the uncoupling protein, and, moreover, that the acyl CoA esters were partially effective in overcoming the inhibition by GDP. GDP binding to the purified uncoupling protein was inhibited by acyl CoA esters but not fatty acids. Phenylglyoxal which prevents GDP binding to the uncoupling protein eliminated the acyl CoA but not the fatty acid effect on proton conductance. These results substantiate the fact that nucleotides and acyl CoA esters act at the same regulatory site on the uncoupling protein, whereas, fatty acids act at a separate site. The properties of the purified/reconstituted uncoupling protein confirm they are identical to those inherent in brown adipose tissue mitochondria.     

Reactive sulfhydryl groups of sarcoplasmic reticulum ATPase. I. Location of a group which is most reactive with N-ethylmaleimide

Ca2+-Transporting ATPase of rabbit skeletal muscle sarcoplasmic reticulum contains several SH groups which are reactive with N-ethylmaleimide (MalNEt) at pH 7.0. The location of the one which is most reactive with MalNEt (SHN, Kawakita et al. J. Biochem. 87, 609 (1980)) was identified on the amino acid sequence of the ATPase. SHN was labeled by reacting sarcoplasmic reticulum membranes with [14C] MalNEt to a labeling density of 1 mol/mol ATPase. [14C]MalNEt-labeled membranes were digested with thermolysin and 14C-labeled SHN peptides were fractionated by Sephadex LH-20 chromatography to give two major peaks of radioactivity. [14C]-MalNEt-labeled peptides were further purified to homogeneity by C18-reversed phase HPLC. Two radioactive peptides containing modified cysteine (Cys), Leu-Gly-Cys-Thr-Ser and Val-Cys-Lys-Met, were finally obtained in roughly equal amounts and in reasonable recovery. Both of these sequences were found in the amino acid sequence of Ca2+-transporting ATPase (Brandl et al. Cell 44, 597 (1986)), and Cys344 and Cys364 were identified as the targets of MalNEt-modification. Thus, 0.5 mol/mol ATPase of each Cys residue actually reacted rapidly with MalNEt under the conditions leading to SHN-modification. Modification of either one with MalNEt may negatively affect the reactivity of the other. Both of the highly reactive SH groups are located in the neighborhood of Asp351, the phosphorylation site of ATPase.     

Dependence of the coupling of dopamine receptors to G proteins on the protein redox state in the neural plasma membranes of pond snail

Binding analysis using [3H]dopamine has shown that reduction of protein thiol groups with dithiothreitol (DTT) led to a dual effect on the receptors. First, the amount of dopamine-binding sites on the membranes and their affinity to the ligand were decreased. Second, the affinity of the receptors to [3H]dopamine was enhanced in the presence of GDP. Binding of D(1) antagonist [3H]SCH23390 to dopamine receptors increased following DTT treatment, opposite to the case with D(1) agonist [3H]SKF38393. The displacement of [3H]GDP by GTPgammaS was depressed by dopamine. Stimulation of [3H]GDP binding by dopamine was potentiated after incubation with DTT. Membrane nitrosylation eliminated the reciprocal dependence of GDP and dopamine binding to the membranes. It is suggested that binding of dopamine to the receptors can lead to both stimulation and inhibition of G protein activity, and the ratio of these effects depends on the reduction and oxidation of sulfhydryl groups of membrane proteins. Thiol reduction potentiated inhibitory action of dopamine receptors on coupled G proteins, and nitrosylation led to their uncoupling.     

Group-selective reagent modification of the sodium- and chloride-coupled glycine transporter under native and reconstituted conditions.

Glycine transporter from rat brain stem and spinal cord is inactivated by specific sulfhydryl reagents. Modification of lysine residues also promotes a decrease of the transporter activity but in a lesser extent than that promoted by thiol group reagents. Mercurials showed a more marked inhibitory effect than maleimide derivatives. SH groups display a similar reactivity for p-chloromercuribenzenesulfonate (pCMBS) and mersalyl in synaptosomal membrane vesicles and proteoliposomes reconstituted with the solubilized transporter. However, different reactivity is observed with N-ethylmaleimide (MalNEt), the greatest effect being attained in membrane vesicles. The rate of inactivation by pCMBS and MalNEt is pseudo-first-order showing time- and concentration-dependence. pCMBS and MalNEt decrease the Vmax for glycine transport and to a lesser extent act on the apparent Km. Treatment with dithiothreitol (DTT) of the transporter modified by pCMBS results in a complete restoration of transporter activity indicating that the effect exercised by the reagent is specific for cysteine residues on the protein. It is concluded that SH groups are involved in the glycine transporter function and that these critical residues are mostly located in a relatively hydrophilic environment of the protein.     

New substrates and competitive inhibitors of the Cl- translocating pathway of the uncoupling protein of brown adipose tissue mitochondria

A large number of new substrates for anion uniport by the uncoupling protein of brown adipose tissue mitochondria have been found. These include alkylsulfonates, alkylsulfates and their derivatives, benzenesulfonate, oxohalogenides, hypophosphate, hexafluorophosphate, and pyruvate. Although the spectrum of anion selectivity is far wider than had previously been suspected, there are strong structural requirements for transport. The anion must be monovalent, and polar groups must not be attached to alkyl or aryl chains. The most striking finding is that transport increases dramatically with anion hydrophobicity. Anions that are transported are shown to compete with Cl- for transport by the reconstituted uncoupling protein. For each anion, the Ki for GDP inhibition of transport increases with its rate of transport and correlates inversely with its Ki for competitive inhibition of Cl- transport. For alkylsulfonates, transport rate, Ki for GDP inhibition, and Ki for inhibition of Cl- transport each depend monotonically on alkyl chain length. These findings suggest several new hypotheses relating to the molecular mechanism of transport through uncoupling protein and suggest explanations for observed functional differences among porters belonging to the same gene family.     

Effect of modification of sulfhydryl groups in soybean beta-amylase on the interaction with substrate and inhibitors

Methyl 2,4-dinitrophenyl disulfide (MDPS) is shown to be an effective methanethiolating reagent for sulfhydryl groups in proteins via thiol-disulfide exchange reaction. It reacts with the two reactive sulfhydryl groups (SH1 and SH2) in soybean beta-amylase. A decrease of the enzymatic activity accompanies the methanethiolation of SH2. After complete methanethiolation of SH2, the modified enzyme still has 9% of the initial activity. Modification of SH2 with cyanide and iodoacetamide reduces the enzymatic activity to 65 and 2% of the initial activity, respectively. Apparently, the residual activity depends upon the size of the substituent at SH2. The modified enzymes still have the almost same Km values for amylopectin and Kd values for enzyme-maltose and enzyme-cyclohexaamylose complexes as the native enzyme. In contrast to maltose and cyclohexaamylose, the Kd value of the enzyme-glucose complex increases in the order of cyanide-, MDPS-, and iodoacetamide-modified enzymes, indicating that SH2 is located near the binding site of glucose. It is proposed from the subsite structure of soybean beta-amylase that the position of SH2 and the glucose binding site is around subsite 1, where the nonreducing ends of the substrate bind productively.     

Importance of SH groups in catalysis by bovine brain acid phosphatase.

The rate of inactivation of acid phosphatase (EC 3.1.3.2) from bovine brain by dithiobis-(2-nitrobenzoic acid) (Nbs2) is identical to the rate of titration of one of the two SH groups of this enzyme. The rate of inactivation of the enzyme by Nbs2 is pH dependent and, at 300 mM NaCl, can be described by the reaction of a single SH group of pK 8.4. At low ionic strength the pK determined from the k inactivation vs. pH profile is 7.7 and the results deviate markedly from the predicted values at pH values less than or equal to 6. The decrease of V upon addition of salts is paralleled by the decrease of inactivation rate by Nbs2. The relevance of SH groups in catalysis by bovine brain acid phosphatase is discussed in terms of these data.     

Effect of pH and KCl on aggregation state and sulphydryl groups reactivity of rat skeletal muscle AMP deaminase

The effects of pH and KCl on sedimentation properties and SH groups reactivity of rat skeletal muscle AMP deaminase have been investigated. The values obtained for apparent molecular weight are consistent with an association of AMP deaminase subunits in response to increasing KCl concentration. Increasing pH value from 6.0 to 8.0 causes a reduction in the apparent molecular weight of the enzyme at high KCl concentration, which can be interpreted as due to a deprotonation-induced isomerization process. Removal of Zn2+ from AMP deaminase has effect similar to alkalinization in modifying the sedimentation properties of the enzyme. In the native enzyme at high K+ concentration about 7, 9 and 12 SH groups can be titrated with Nbs2, approximately 1, 2 and 4 SH groups reacting as fast sets, at pH 6.0, 7.0 and 8.0, respectively. Substitution of the 12 SH groups reactive with Nbs2 at pH 8.0 has no effect on the pH-dependent allosteric behaviour of the enzyme. Removal of K+ causes considerable changes in the reactivity of AMP deaminase towards Nbs2, unmasking a class of additional SH groups, so that the total number of titratable SH groups approaches that of 30 determined in denaturing conditions. In the enzyme previously treated with N-ethylmaleimide to alkylate the fast reacting class of SH groups, the class of additional SH groups are substituted by Nbs2 at basic pH, but not at acidic pH, with a concomitant reduction of the enzyme activity.     

Acute effects of a beta-adrenoceptor agonist (BRL 26830A) on rat brown-adipose-tissue mitochondria. Increased GDP binding and GDP-sensitive proton conductance without changes in the concentration of uncoupling protein.

GDP binding, proton conductance and the specific concentration of uncoupling protein were measured in brown-adipose-tissue mitochondria of rats treated acutely with the novel beta-agonist, BRL 26830A. At 1 h after dosing with BRL 26830A, mitochondrial GDP binding was increased more than 2-fold. The increase in binding resulted from an increase in the number of binding sites. An iterative analysis of Scatchard binding data suggested that there is only one high-affinity GDP-binding site (Kd 0.3 microM) in brown-adipose-tissue mitochondria. The acute increase in GDP binding produced by treatment with BRL 26830A occurred without any alteration in the specific mitochondrial concentration of uncoupling protein, as determined by radioimmunoassay. Treatment with the beta-agonist did, however, lead to a small increase in the GDP-sensitive component of mitochondrial proton conductance. These results indicate that GDP-binding sites on uncoupling protein can be rapidly unmasked after treatment with a brown-fat-specific beta-agonist, and that the increase in binding reflects an increase in the activity of the mitochondrial proton-conductance pathway.     

Investigation of the effect of metal ions on the reactivity of thiol groups in human 5-aminolaevulinate dehydratase.

The reaction of human 5-aminolaevulinate dehydratase with 5,5'-dithiobis-(2-nitrobenzoic acid) (Nbs2) results in the release of 4 molar equivalents of 5-mercapto-2-nitrobenzoic acid (Nbs) per subunit. Two of the thiol groups reacted very rapidly (groups I and II), and their rate constants were determined by stopped-flow spectrophotometry; the other two thiol groups (groups III and IV) were observed by conventional spectroscopy. Titration of the enzyme with a 1 molar equivalent concentration of Nbs2 resulted in the release of 2 molar equivalents of Nbs and the concomitant formation of an intramolecular disulphide bond between groups I and II. Removal of zinc from the holoenzyme increased the reactivity of groups I and II without significantly affecting the rate of reaction of the other groups. The reactions of the thiol groups in both the holoenzyme and apoenzyme were little affected by the presence of Pb2+ ions at concentrations that strongly inhibit the enzyme, suggesting that Zn2+ and Pb2+ ions may have independent binding sites. Protein fluorescence studies with Pb2+ and Zn2+ have shown that the binding of both metal ions results in perturbation of the protein fluorescence.     

Control of uncoupling protein in brown-fat mitochondria by purine nucleotides. Chemical modification by diazobenzenesulfonate

The uncoupling protein (UP) of isolated brown adipose tissue mitochondria was studied with respect to the mechanism of control of UP function by purine nucleotides. Passive transport of H+ and Cl- was followed simultaneously in a KCl medium. With both GDP and ATP a higher sensitivity of Cl- transport (apparent Ki = 2.2 microM and 4.7 microM respectively) than of H+ transport (apparent Ki = 7.7 microM and 34 microM respectively) was observed. Chemical modification of isolated mitochondria by diazobenzenesulfonate (DABS) up to 75 mumol/mg protein did not affect the transport, its ionic selectivity and regulation by endogenous free fatty acids. In contrast, the sensitivity to purine nucleotides of both H+ and Cl- translocation was decreased (apparent Ki increased 71 and 47 times respectively). DABS decreased the affinity of [3H]GDP for the specific nucleotide-binding site on mitochondria (Kd increased from 2.7 microM to 13 microM) and depressed, to a smaller extent, the GDP-binding capacity. Correlation between occupancy of the specific nucleotide-binding site by GDP and inhibition of transport yielded a linear relationship for Cl- transport in control mitochondria. For H+ transport in the control, and for both H+ and Cl- transports in DABS-treated mitochondria, a biphasic correlation was obtained. The results show that different structural parts of UP are involved in transport and its control by the regulatory ligands and that, in addition to binding of purine nucleotides to UP, the inhibition of ion transport by purine nucleotides depends on an intrinsic factor modulating the inhibitory effect.     

Relationship between tubulin SH groups and bound guanine nucleotides.

Guanine nucleotides bound to both the non-exchangeable sites (N sites) and exchangeable sites (E sites) of tubulin were completely released after 7 moles of SH groups per tubulin subunit (55,000 molecular weight) had reacted with PCMPS. The blockage of 2 moles of SH groups in the glycerol-reassembly buffer or 1 mole of SH groups in glycerol-free reassembly buffer resulted in complete loss of tubulin polymerizability. However, under both sets of experimental conditions, the amount of guanine nucleotides released from the E sites was less than 8% and the loss of total guanine nucleotides was only 5%. Addition of GSH did not induce reassociation of released guanine nucleotides, although it restored tubulin polymerizability. These results indicate that the loss of tubulin polymerizability on blockage of the SH groups was not due to dissociation of bound guanine nucleotides and that the binding sites of the nucleotides were independent of the SH groups in tubulin required for polymerization. Furthermore, blockage of SH groups did not change the ratio of GTP to GDP bound to tubulin.     

Reconstitution of the uncoupling protein of brown adipose tissue mitochondria. Demonstration of GDP-sensitive halide anion uniport

The fluorescent anion indicator 6-methoxy-N-(3-sulfopropyl)quinolinium was trapped in proteoliposomes reconstituted with purified 32-kDa uncoupling protein and used to detect GDP-sensitive uniports of Cl-, Br-, and I-. Transport of these halide anions was rapid and potential-dependent. F- and nitrate were found to inhibit Cl- uptake competitively, suggesting that these anions are also substrates for transport. This preparation also exhibited H+(OH-) transport, showing that the reconstituted uncoupling protein possesses both halide and H+ transport functions, as is observed in intact brown adipose tissue mitochondria. Cl- transport was inhibited to the residual level observed in liposomes without protein when GDP was present on both sides of the membrane. Cl- transport was inhibited by about 50% when GDP was present only on one side of the membrane. We infer that uncoupling protein reconstitutes into proteoliposomes with a 1:1 ratio of sidedness orientation. The Km values for Cl- uniport were 100 and 65 mM, respectively, in GDP-loaded and non-GDP-loaded vesicles. Participation of the inner membrane anion channel in the observed transport is rendered unlikely by the fact that this carrier is insensitive to GDP. A variety of additional experiments probing for inner membrane anion channel yielded uniformly negative results, confirming the absence of contamination by this protein. Our results therefore demonstrate that the uncoupling protein mediates anion translocation, a function previously reported as lacking in the reconstituted system.     

Side-chain dynamics of the SAP SH2 domain correlate with a binding hot spot and a region with conformational plasticity

X-linked lymphoproliferative disease is caused by mutations in the protein SAP, which consists almost entirely of a single SH2 domain. SAP interacts with the Tyr281 site of the T<-->B cell signaling protein SLAM via its SH2 domain. Interestingly, binding is not dependent on phosphorylation but does involve interactions with residues N-terminal to the Tyr. We have used 15N and 2H NMR relaxation experiments to investigate the motional properties of the SAP SH2 domain backbone amides and side-chain methyl groups in the free protein and complexes with phosphorylated and non-phosphorylated peptides derived from the Tyr281 site of SLAM. The most mobile methyl groups are in side-chains with large RMSD values between the three crystal structures of SAP, suggesting that fast time-scale dynamics in side-chains is associated with conformational plasticity. The backbone amides of two residues which interact with the C-terminal part of the peptides experience fast time-scale motions in the free SH2 domain that are quenched upon binding of either the phosphorylated or non-phosphorylated peptide. Of most importance, the mobility of methyl groups in and around the binding site for residues in the N-terminus of the peptide is significantly restricted in the complexes, underscoring the dominance of this interaction with SAP and demonstrating a correlation between changes in rapid side-chain motion upon binding with local binding energy.