Reaction of internal forms of the choline carrier of erythrocytes with N-ethylmaleimide: Evidence for a carrier conformational change on complex formation

Summary The choline carrier of human erythrocyte membranes exists in distinguishable outward-facing and inward-facing conformations, and previous studies demonstrated that only the latter reacts with N-ethylmaleimide, producing an irreversible inhibition of transport. We now report experiments to determine the individual reaction rates for the two inward-facing forms: the free carrier and the complex. The pseudo-first-order rate constant for the complex with a substrate analog, di-n-butylaminoethanol, is found to be nearlydouble that for the free carrier, showing that the carrier conformation is altered following addition of a ligand (with 1mm N-ethylmaleimide at pH 6.8, 37°C, the constants are 0.57±0.05 min^–1 and 0.33±0.02 min^–1, respectively). Hence three different conformational states have been distinguished by experiment: (1) the inward-facing free carrier; (2) the inward-facing complex; and (3) the outward-facing carrier.     

The choline carrier of erythrocytes: Location of the NEM-reactive thiol group in the inner gated channel

Summary Choline transport across the human erythrocyte membrane is irreversibly inhibited when N-ethylmaleimide (NEM) reacts with a carrier SH group which is located outside the substrate site, and which is exposed in the inward-facing form of the carrier but prevented from reacting in the outward-facing form. The location of the SH group with respect to the membrane has now been determined by studying the dependence of the NEM-alkylation rate on the intracellular and extracellular pH. The results show that the reactive SH group equilibrates with hydrogen ions in the cytoplasm, but is completely isolated from hydrogen ions in the external medium. With this added evidence it becomes possible to conclude that the SH group is located in the inner gated channel of the choline carrier.     

Evidence for a two-state mobile carrier mechanism in erythrocyte choline transport: Effects of substrate analogs on inactivation of the carrier by N-ethylmaleimide

Summary Choline transport in erythrocytes is irreversibly inhibited by N-ethylmaleimide. The hypothesis that the carrier alternates between outwardfacing and inward-facing forms and that only the latter reacts with the inhibitor (Martin, K. (1971)J. Physiol. (London) 213:647–667; Edwards, P.A. (1973)Biochim. Biophys. Acta 311:123–140) is here subjected to a quantitative test. In this test the effects of a series of substrate analogs upon rates of inactivation and rates of choline exit are compared. By hypothesis the effect of an analog in the external solution on the inactivation rate depends only on how it affects the proportion of the inward-facing carrier. Since¹⁴C-choline efflux is necessarily proportional to the concentration of free carrier in the inward-facing form, the analogs should have related effects on the two rates. In every case the observed effects were identical, whether the analogs accelerated transport or inhibited it. Analysis of the results demonstrates that (1) the transport mechanism depends on the operation of a mobile element; (2) distinguishable inward-facing and outward-facing conformations of the free carrier, carrier-substrate complex, and carrier-inhibitor complex exist, and only the inwardfacing forms react at a significant rate with N-ethylmaleimide; (3) carrier mechanisms involving a single form of free carrier or a single form of carriersubstrate complex are ruled out; and (4) dissociation of the carrier-substrate complex is a rapid step with all substrate analogs.     

Reaction of the glucose carrier of erythrocytes with sodium tetrathionate: Evidence for inward-facing and outward-facing carrier conformations

Summary Sodium tetrathionate reacts with the glucose carrier of human erythrocytes at a rate which is greatly altered in the presence of competitive inhibitors of glucose transport. Inhibitors bound to the carrier on the outer surface of the membrane, either at the substrate site (maltose) or at the external inhibition site (phloretin and phlorizin), more than double the reaction rate. Inhibitors bound at the internal inhibition site (cytochalasin B and androstenedione), protect the system against tetrathionate. After treatment with tetrathionate, the maximum transport rate falls to less than one-third, and the properties of the binding sites are modified in unexpected ways. The affinity of externally bound inhibitors rises: phloretin is bound up to seven times more strongly and phlorizin and maltose twice as strongly. The affinity of cytochalasin B, bound at the internal inhibition site, falls to half while that of androstenedione is little changed. The affinity of external glucose falls slightly. Androstenedione prevents both the fall in transport activity and the increase in phloretin affinity produced by tetrathionate. An inhibitor of anion transport has no effect on the reaction. The observations support the following conclusions: (1) Tetrathionate produces its effects on the glucose transport system by reacting with the carrier on the outer surface of the membrane. (2) The carrier assumes distinct inward-facing and outward-facing conformations, and tetrathionate reacts with only the outward-facing form. (3) The thiol group with which tetrathionate is presumed to react is not present in either the substrate site or the internal or external inhibitor site. (4) In binding asymmetrically to the carrier, a reversible inhibitor shifts the carrier partition between inner and outer forms and thereby raises or lowers the rate of tetrathionate reaction with the system. (5) Reaction with tetrathionate converts the carrier to an altered state in which the conformation at all three binding sites is changed and the rate of carrier reorientation is reduced.     

Mechanism of Long-Chain Free Fatty Acid Protonation at the Membrane-Water Interface

Long-chain free fatty acids (FFAs) play an important role in several physiological and pathological processes such as lipid fusion, adjustments of membrane permeability and fluidity, and the regulation of enzyme and protein activities. FFA-facilitated membrane proton transport (flip-flop) and FFA-dependent proton transport by membrane proteins (e.g., mitochondrial uncoupling proteins) are governed by the difference between FFA’s intrinsic pK_a value and the pH in the immediate membrane vicinity. Thus far, a quantitative understanding of the process has been hampered, because the pK_a value shifts upon moving the FFA from the aqueous solution into the membrane. For the same FFA, pK_a values between 5 and 10.5 were reported. Here, we systematically evaluated the dependence of pK_a values on chain length and number of double bonds by measuring the ζ-potential of liposomes reconstituted with FFA at different pH values. The experimentally obtained intrinsic pK_a values (6.25, 6.93, and 7.28 for DOPC membranes) increased with FFA chain length (C16, C18, and C20), indicating that the hydrophobic energy of transfer into the bilayer is an important pK_a determinant. The observed pK_a decrease in DOPC with increasing number of FFA double bonds (7.28, 6.49, 6.16, and 6.13 for C20:0, C20:1, C20:2, and C20:4, respectively) is in line with a decrease in transfer energy. Molecular dynamic simulations revealed that the ionized carboxylic group of the FFAs occupied a fixed position in the bilayer independent of chain length, underlining the importance of Born energy. We conclude that pK_a is determined by the interplay between the energetic costs for 1) burying the charged moiety into the lipid bilayer and 2) transferring the hydrophobic protonated FFA into the bilayer.     

Transport of alkali cations through thin lipid membranes by (222)C10-Cryptand,an ionizable mobile carrier

Summary The kinetics of K⁺ and Na⁺ transport across the membrane of large unilamellar vesicles (L.U.V.) were compared at two pH's, with two carriers: (222)C ₁₀-cryptand (diaza-1, 10-decyl-5-hexaoxa-4,7,13,16,21,24-bicyclo[8.8.8.]hexacosane) and valinomcyin, i.e. an ionizable macrobicyclic amino polyether and a neutral macrocyclic antibiotic. The rate of cation transport by (222)C₁₀ saturated as cation and carrier concentrations rose. The apparent affinity of (222)C₁₀ for K⁺ was higher and less pH dependent than that for Na⁺ but resembled the affinity of valinomycin for K⁺. The efficiency of (222)C₁₀ transport of K⁺ decreased as the pH fell and the carrier concentration rose, and was about ten times lower than that of valinomycin. Noncompetitive K⁺/Na⁺ transport selectivity of (222)C₁₀ decreased as pH, and cation and carrier concentrations rose, and was lower than that of valinomycin. Transport of alkali cations by (222)C₁₀ and valinomycin was noncooperative. Reaction orders in cationn(S) and carrierm(M) varied with the type of cation and carrier and were almost independent of pH;n(S) andm(M) were not respectively dependent on carrier or cation concentrations. The apparent estimated constants for cation translocation by (222)C₁₀ were higher in the presence of Na⁺ than of K⁺ due to higher carrier saturation by K⁺, and decreased as pH and carrier concentration increased. Equilibrium potential was independent of the nature of carrier and transported cation. Results are discussed in terms of the structural, physicochemical and electrical characteristics of carriers and complexes.     

The choline transport system of erythrocytes. Distribution of the free carrier in the membrane

A method is described, based on the kinetics of transport, for determining the equilibrium distribution of the carrier site on the inner and outer surfaces of the cell membrane, and this method is applied to the choline carrier of human erythrocytes. This method depends on measurement of flux ratios for both entry and exit, i.e., the transport rates of a low concentration of labeled substrate into a solution which contains either no substrate or a saturating concentration of unlabeled substrate. The concentrations of inward-facing and outward-facing carrier are found to be nearly equal, and therefore the 5-fold difference in choline affinity on the inner and outer surfaces of the membrane cannot be explained by an unequal carrier distribution. It is also shown that both reorientation and dissociation of the carrier-substrate complex are far more rapid than reorientation of the free carrier.     

Transport of an anionic substrate by the H+/monosaccharide symport inRhodotorula gracilis: Only the protonated form of the carrier is catalytically active

Summary The yeastRhodotorula gracilis accumulated glucuronate by an H⁺/symport. The transport was electroneutral, driven by the chemical gradient of protons pH. The observed stoichiometry amounted to 1 proton per molecule glucuronate. At pH 4, the half-saturation constantK _T was at its lowest value (K _T =8mm), whereas the maximal velocityV _T reached a maximum (V _T =15 nmol/min×mg dry wt). Monosaccharides competitively inhibited the uptake of glucuronate and vice versa. Hence, the two substrates share the same transport system. The steady-state accumulation of glucuronate reflected the course of the pH gradient. It is concluded that glucuronate is transported as an anionic substrate by the protonated carrier, the driving force being the chemical gradient of the H⁺ (pH). The ternary carrier/H⁺/glc-COOO-complex is electroneutral and independent of the membrane potential. Simultaneous uptake of organic acids (acetic or propionic acid) which is also energized by the pH gradient led to a noncompetitive inhibition of glucuronate transport. Thus, manipulation of the driving force, pH, reducedV _T without affectingK _T . Kinetic and energetic arguments are presented which stronly suggest that only the protonated carrier is catalytically active inR. gracilis.     

Inhibition of an outwardly rectifying anion channel by HEPES and related buffers

Summary The effect of pH buffers and related compounds on the conductance of an outwardly rectifying anion channel has been studies using the patch-clamp technique. Single-channel current-voltage relationships were determined in solutions buffered by trace amounts of bicarbonate and in solutions containing N-substituted taurines (HEPES, MES, BES, TES) and glycines (glycylglycine, bicine and tricine), Tris andbis-Tris at millimolar concentrations. HEPES (pK_a=7.55) reduced the conductance of the channel when present on either side of the membrane. Significant inhibition was observed with 0.6mm HEPES on the cytoplasmic side (HEPES _i ) and this effect increased with [HEPES _i ] so that conductance at the reversal potential was diminished 25% with 10mm HEPES _i )and 70% at very high [HEPES _i ]. HEPES _i block was relieved by applying positive voltage but positive currents were not consistent with a Woodhulltype blocking scheme in that calculated dissociation constants and electrical distances depended on HEPES concentration. Results obtained by varying total HEPES _i concentration at constant [HEPES^–] and vice versa suggest both the anionic and zwitterionic (protonated) forms of HEPES inhibit. Structure-activity studies with related compounds indicate the sulfonate group and heterocyclic aliphatic groups are both required for inhibition from the cytoplasmic side. TES (pK_a=7.54), substituted glycine buffers (pK_a=8.1–8.4) andbis-Tris (pK_a=6.46) had no measurable effect on conductance and appear suitable for use with this channel.     

Efficiency,Na+/K+ selectivity and temperature dependence of ion transport through lipid membranes by (221)C10-Cryptand,an ionizable mobile carrier

Summary The kinetics of Na⁺ and K⁺ transport across the membrane of large unilamellar vesicles (LUV) were determined at two pH's when transport was induced by (221)C₁₀-cryptand (diaza-1,10-decyl-5-pentaoxa-4,7,13,16,21-bicyclo [8.8.5.] tricosane) at various temperatures, and by nonactin at 25°C and (222)C₁₀-cryptand at 20 and 25°C. The rate of Na⁺ and K⁺ transport by (221)C₁₀ saturated with the cation and carrier concentrations. Transport was noncooperative and exhibited selectivity for Na⁺ with respect to K⁺. The apparent affinity of (221)C₁₀ for Na⁺ was higher and less pH-dependent than that for K⁺, and seven times higher than that of (222)C₁₀ for K⁺ ions (20.5vs. 1.7 kcal·mole^–). The efficiency of (221)C₁₀ transport of Na⁺ was pH-and carrier concentration-dependent, and was similar to that of nonactin; its activation energy was similar to that for (222)C₁₀ transport of K⁺ (35.5 and 29.7 kcal · mole^–1, respectively). The reaction orders in cationn(S) and in carrierm(M), respectively, increased and decreased as the temperature rose, and were both independent of carrier or cation concentrations; in most cases they varied slightly with the pH.n(S) varied with the cation at pH 8.7 and with the carrier for Na⁺ transport only, whilem(M) always depended on the type of cation and carrier. Results are discussed in terms of the structural, physico-chemical and electrical characteristics of carriers and complexes.     

Amine ion porter inChara australis: Effects of alkyl substitution and external pH

Summary The rate of transport of amine ions intoChara australis internodes is studied by measuring changes in membrane current when amine solutions are presented to voltage-clamped cells. The dependence of this rate on ion concentration is investigated for a series of alkyl-amine ions: methyl-, ethyl-, isopropyl-, dimethyl-, trimethyl- and tetramethylammonium. A Michaelis-Menten relationship is displayed by all except tri- and tetramethylammonium, where currents are irregular and difficult to reproduce. Evidence suggests that the different ions cross the plasmalemma via a common uniport.K _M values for this porter increase as the amine ion becomes more highly substituted. TheV _m values are similar for all amines and lie within the range 10 to 100 mA m^–2 (for cell potential at –200 mV). The changes inK _M indicate that hydrogen bonding may be involved in the binding interaction.V _m varies with external pH in a way which suggests that an ionizable group on the transport protein with pK_a5.8 directly affects the transport rate.K _M is independent of external pH over the range 4.5 to 10.5     

Properties of the sugar carrier in baker's yeast

A total of 16 hexoses and pentoses were investigated with respect to transport intoSaccharomyces cerevisiae cells. All monosaccharides were transported across the cytoplasmic membrane but only those with an equatorial hydroxyl group in positions 1 and 4 of theC1 chair conformation and those with an equatorial hydroxyl group in position 2 and an equatorial −CH₂OH group in position 5 of the1C chair conformation reached an equilibrium distribution in the entire cell water volume. Other monosaccharides reached a distribution in only 20–66% of the intracellular water. The two groups of sugars are apparently transported by different carriers (either in parallel or in series), each of them showing countertransport and an apparent activation energy of 6,700–7,800 cal/mol. The carrier transporting the perfectly distributing sugars (Group 1) is affected by uranyl nitrate but not by 2,4-dinitrophenol, the other carrier (Group 2) is apparently not susceptible to uranyl ions but is influenced by 2,4-dinitrophenol. The space of distribution of the Group 1 sugars is reduced in hypertonic media in accordance with changes of intracellular water, that of the Group 2 sugars is altered only very slightly. The carriers differ in their kinetic parametres (mobility of the loaded carriers, maximum rate of transport). There is only a very indistinct competition for transport between representatives of the two groups. Preincubation with d-galactose induces the formation or unmasking of a transport system whereafter even the Group 2 sugars reach equilibrium in the entire cell water. Part I. Fol. microbiol. 10: 30, 1965.     

Effects of perfluorinated oxygen carrier application in yeast, fungi and plant cell suspension cultures

The growth of the yeast Saccharomyces cerevisiae, the fungus Rhizopus nigricans and Nicotiana tabacum cells with perfluorodecalin as an oxygen carrier has been studied. The volumetric mass transfer coefficient (k_La) measured by the dynamic method was higher for the perfluorodecalin oxygenation system than for the conventional aeration system. The results show that perfluorocarbon can be successfully used as an efficient gas carrier, especially for the culture of delicate plant cells. The increase in yeast biomass in the suspension culture aerated by perfluorodecalin was as much as 110% higher than in the culture aerated by air. The fungus R. nigricans grew better when the conventional aeration system was used due to the fact that growth of the mycelium is limited by the transport of oxygen by diffusion in the pellets rather than by interfacial oxygen transport. In the case of isolated tobacco cells, an increase of over 350% in biomass growth was observed for the PFC aeration system.     

Citrate uniport by the mitochondrial tricarboxylate carrier: a basis for a new hypothesis for the transport mechanism

The tricarboxylate transport system located in the inner mitochondrial membrane was studied as an isolated protein reconstituted in proteoliposomes. The effects on the transport of citrate by various reagents, specific for different aminoacid residues, were analyzed. In the group of SH reagents, it was found that N-ethylmaleimide is an irreversible inhibitor of the citrate–citrate exchange, while HgCl₂ and the mercurial mersalyl cause a rapid unidirectional efflux of citrate from liposomes. It was demonstrated that NEM and mercurials act on different SH groups. Dithioerythritol is not able to reverse the effect of mersalyl unless another reagent, pyridoxalphosphate, is present. Pyridoxalphosphate itself, a reagent specific for NH₂ residues, is an effective inhibitor of citrate exchange transport, as measured in both influx and efflux, but it has no effect on the mercurial-induced efflux. The same behavior was observed with diethylpyrocarbonate, a reagent specific for histidine and tyrosine residues. Interestingly, a slow basic efflux of internal citrate, in the absence of countersubstrate, was observed in proteoliposomes. Because it is inhibited by the same reagents acting on the exchange process, it is deduced that it is catalyzed by the tricarboxylate carrier. The ability of the carrier to perform a uniport of the substrate suggests the presence of a single substrate binding site on the carrier protein. A preliminary kinetic approach indicates that such a transport model is compatible with this theory.     

Two selective filters in the calcium channel of the molluscan neuron somatic membrane

Modification of the calcium channel of the somatic membrane of molluscan neurons under the influence of EDTA and other Ca-binding agents was investigated. The results showed that there are two selective filters in the calcium channel of this membrane. The first is located near the outer pore of the calcium channel and it binds bivalent cations in the order:pK _Ca:pK _Sr:pK _Ba:pK _Mg=6.6:5.5:4.8:4.2. This external filter regulates selectivity of the channel relative to the charge of the cation and it conjecturally contains several carboxyl groups. The second selective filter lies inside the channel and regulates permeability for ions with a single charge. It is suggested that the structure of the inner filter closely resembles that postulated by Hille for the selective filter of the sodium channel, and that it contains one carboxyl group. The results of investigation of the effect of Ca⁺⁺, Cd⁺⁺, and H⁺ on the fast sodium current of the somatic membrane showed that it is not blocked by these ions, but the decrease observed in its amplitude is connected with a change in the membrane surface potential and a corresponding change in the juxtamembranous concentration of carrier ions. On the basis of the experimental results it is postulated that the selective filter of the fast sodium channel of the molluscan neuron somatic membrane does not contain a carboxyl group.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 15, No. 4, pp. 420–427, July–August, 1983.     

Cysteine substitutions for individual residues in helix VI of the melibiose carrier of Escherichia coli

The melibiose carrier of Escherichia coli is a cytoplasmic membrane protein that mediates the cotransport of galactosides with H⁺, Na⁺, or Li⁺. In this study we used cysteine-scanning mutagenesis to try to gain information about the position of transmembrane helix VI in the three-dimensional structure of the melibiose carrier. We constructed 23 individual cysteine substitutions in helix VI and an adjacent loop of the carrier. The resulting melibiose carriers retained 22–100% of their ability to transport melibiose. We tested the effect of the hydrophilic sulfhydryl reagent p-chloromercuri-benzenesulfonic acid (PCMBS) on the cysteine-substitution mutants and we found that there was no inhibition of melibiose transport in any of the mutants. We suggest that helix VI is imbedded in phospholipid and does not face the aqueous channel through which melibiose passes. Received: 6 March 2001/Revised: 14 May 2001     

Characterization of a potassium carrier in rabbit reticulocyte cell membrane

Summary In this study we present evidence that high ouabain-resistant Rb influx, carried out by the rabbit reticulocyte membrane, is composed of carrier-mediated Rb influx and passive diffusion across the cell membrane. To meet this end, an assay was developed by which the two ouabain-resistant Rb influxes could be measured separately.Whereas theK _m for Rb of the carrier (12.5mm) did not change by increasing the pH, theVm was markedly reduced. At the optimal pH (6.0–6.5) theVm was 6–8 mmol h^–1 liter^–1 and fell to zero at pH 8.0. This may indicate a possible role of H⁺ ions in this transport mechanism.The carrier is inhibited by furosemide and ethacrynic acid, similarly to pump II in the erythrocyte and kidney. In addition, its activity is dependent upon the ionic content of the medium. The K(Rb) carrier appeared not to be involved in an active transport since depletion of ATP had no effect on the carrier activity. The carrier activity was also measured in rabbit erythrocytes and was found to be 10 times lower than that of rabbit reticulocytes. TheK _m for Rb, optimal pH, and high sensitivity to furosemide and ethacrynic acid of the erythrocyte and the reticulocyte carrier are similar.Our study suggests that maturation of reticulocytes to erythrocytes is accompanied by a loss or inactivation of most of a K (or Rb) carrier very active in the reticulocyte cell.     

Hemiacetal stabilization in a chymotrypsin inhibitor complex and the reactivity of the hydroxyl group of the catalytic serine residue of chymotrypsin

The aldehyde inhibitor Z-Ala-Ala-Phe-CHO has been synthesized and shown by ¹³C-NMR to react with the active site serine hydroxyl group of alpha-chymotrypsin to form two diastereomeric hemiacetals. For both hemiacetals oxyanion formation occurs with a pK_a value of ~ 7 showing that chymotrypsin reduces the oxyanion pK_a values by ~ 5.6 pK_a units and stabilizes the oxyanions of both diastereoisomers by ~ 32 kJ mol^− 1. As pH has only a small effect on binding we conclude that oxyanion formation does not have a significant effect on binding the aldehyde inhibitor. By comparing the binding of Z-Ala-Ala-Phe-CHO with that of Z-Ala-Ala-Phe-H we estimate that the aldehyde group increases binding ~ 100 fold. At pH 7.2 the effective molarity of the active site serine hydroxy group is ~ 6000 which is ~ 7 × less effective than with the corresponding glyoxal inhibitor. Using ¹H-NMR we have shown that at both 4 and 25 °C the histidine pK_a is ~ 7.3 in free chymotrypsin and it is raised to ~ 8 when Z-Ala-Ala-Phe-CHO is bound. We conclude that oxyanion formation only has a minor role in raising the histidine pK_a and that the aldehyde hydrogen must be replaced by a larger group to raise the histidine pK_a > 10 and give stereospecific formation of tetrahedral intermediates. The results show that a large increase in the pK_a of the active site histidine is not needed for the active site serine hydroxyl group to have an effective molarity of 6000.     

Direct observation of multiple protonation states in recombinant human purple acid phosphatase

To date, most spectroscopic studies on mammalian purple acid phosphatases (PAPs) have been performed at a single pH, typically pH 5. The catalytic activity of these enzymes is, however, pH dependent, with optimal pH values of 5.5–6.2 (depending on the form). For example, the pH optimum of PAPs isolated as single polypeptides is around pH 5.5, which is substantially lower that of proteolytically cleaved PAPs (ca. pH 6.2). In addition, the catalytic activity of single polypeptide PAPs at their optimal pH values is four to fivefold lower than that of the proteolytically cleaved enzymes. In order to elucidate the chemical basis for the pH dependence of these enzymes, the spectroscopic properties of both the single polypeptide and proteolytically cleaved forms of recombinant human PAP (recHPAP) and their complexes with inhibitory anions have been examined over the pH range 4 to 8. The EPR spectra of both forms of recHPAP are pH dependent and show the presence of three species: an inactive low pH form (pH<pK _a,1), an active form (pK _a,1<pH<pK _a,2), and an inactive high pH form (pH>pK _a,2). The pK _a,1 values observed by EPR for the single polypeptide and proteolytically cleaved forms are similar to those previously observed in kinetics studies. The spectroscopic properties of the enzyme–phosphate complex (which should mimic the enzyme–substrate complex), the enzyme–fluoride complex, and the enzyme–fluoride–phosphate complex (which should mimic the ternary enzyme–substrate–hydroxide complex) were also examined. EPR spectra show that phosphate binds to the diiron center of the proteolytically cleaved form of the enzyme, but not to that of the single polypeptide form. EPR spectra also show that fluoride binds only to the low pH form of the enzymes, in which it presumably replaces a coordinated water molecule. The binding of fluoride and phosphate to form a ternary complex appears to be cooperative.Electronic Supplementary Material Supplementary material is available for this article at     

Isolation of the alanine carrier from the membranes of a thermophilic bacterium and its reconstitution into vesicles capable of transport

A carrier protein mediatine alanine transport was purified from the membranes of the thermophilic bacterium PS3, by ion exchange chromatography in the presence of both Triton X-100 and urea. The alanine carrier was recovered in the nonadsorbed fraction from either DEAE-or CM-cellulose columns, suggesting that its isoelectric point was in the neutral pH region. The final preparation contained virtually no electron transfer components, ATPase, or NADH dehydrogenase. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate revealed that the final preparation consisted of two major protein components with molecular weights of 36,000 and 9,400. Active transport of alanine after incorporation of the alanine carrier into reconstituted proteoliposomes was driven not only by an artificial membrane potential generated by potassium ion diffusion via valinomycin but also by mitochondrial cytochrome oxidase incorporated into the same liposomes and supplemented with both cytochrome c and ascorbic acid. The membrane-integrated portion (TF₀) of the ATPase complex uncoupled alanine transport by conducting protons across the membrane.