The effects of pH on proton sugar symport activity of the lactose permease purified from Escherichia coli

The lactose permease, which catalyzes galactoside-proton symport into Escherichia coli, has been purified and reconstituted in active form into artificial lipid vesicles. The roles of many detergents and phospholipids in solubilization and stabilization of the activity of the permease have been examined with a view to its eventual crystallization. Initial rates of uptake into reconstituted proteoliposomes determined by rapid mixing techniques proved that the activity of the permease can be comparable to that observed in the intact cell, while the best values for uptake rates obtained with conventional techniques were comparable to those reported for vesicles. The activity of the purified protein has been monitored over time periods of hours to weeks. It is shown that, under the best current conditions, the permease retains full activity for 1 to 2 weeks. Although this is still marginal for its crystallization, future improvements can now be assayed by rather stringent criteria. The mechanism of galactoside transport into reconstituted proteoliposome has been investigated by examining the effects of pH on influx into the vesicles. It is shown that the observed effects are entirely consistent with the predictions of a simple model of proton symport. The apparent increase in rate of uptake that is observed in the presence of a pH gradient is not so much due to an acceleration by a component of the protonmotive force as to the relaxation of inhibition by a product (internal protons) of the symport reaction.     

Alternative-substrate inhibition and the kinetic mechanism of the beta-galactoside/proton symport of Escherichia coli.

The effects of competing alternative substrates on the rate of uptake by galactoside/proton symport were investigated. These experiments produced a decrease in apparent maximum velocity with increased alternative-substrate concentration that cannot be accounted for by a simple ordered mechanism. This, together with non-linearities in the variation of the apparent kinetic constants with alternative-substrate concentration, can be accounted for by a random mechanism for galactoside and proton binding.     

Effect of membrane potential on the kinetic parameters of the Na+ or H+ melibiose symport in Escherichia coli membrane vesicles

Comparison of the transport properties of the melibiose permease of E. coli acting as a H+-symport or a Na+-symport has been performed by measuring initial rates of [3H]-melibiose transport or its accumulation in isolated membrane vesicles. The results show strikingly that although the membrane potential primarily drives melibiose accumulation by both types of symport, it selectively affects the apparent affinity constant Kt of the H+-melibiose symport while it specifically changes the maximal rate of transport (Vmax) of the Na+-melibiose symport. It is suggested that modification(s) of some partial reaction constants of a given transport cycle might lead to important changes in the kinetic properties of this transport system.     

The role of ATP in the control of H+-galactoside symport in the yeast Kluyveromyces marxianus.

Transport of methyl beta-D-thiogalactoside and p-nitrophenyl beta-D-galactoside is shown to proceed through the H+-lactose symporter of Kluyveromyces marxianus. Uptake of these compounds is strongly reduced under anaerobic conditions or aerobically in the presence of antimycin. It is shown that antimycin treatment affects p-nitrophenyl beta-D-galactoside uptake in a similar way as it affects the cellular amount of ATP, suggesting regulation of p-nitrophenyl beta-D-galactoside transport by ATP. Also, manipulation of cellular ATP by antimycin treatment followed by glucose incubation, or by aerobic incubation of cells with 2-deoxy-D-glucose, showed a similar dependence of galactoside uptake on the ATP level. Transport of the lipophilic cation tetraphenylphosphonium is affected by ATP variations in a similar way as galactoside influx. It is concluded that ATP regulates H+-galactoside symport by its influence on charge translocation. It is discussed that a membrane ATPase probably plays a central role in the control of the activity of H+-sugar symport.     

Lactose transport system of Streptococcus thermophilus. Functional reconstitution of the protein and characterization of the kinetic mechanism of transport.

The kinetic mechanism of the lactose transport system of Streptococcus thermophilus was studied in membrane vesicles fused with cytochrome c oxidase containing liposomes and in proteoliposomes in which cytochrome c oxidase was coreconstituted with the lactose transport protein. Selective manipulation of the components of the proton (and sodium) motive force indicated that both a membrane potential and a pH gradient could drive transport. The galactoside/proton stoichiometry was close to unity. Experiments which discriminate between the effects of internal pH and delta pH as driving force on galactoside/proton symport showed that the carrier is highly activated at alkaline internal pH values, which biases the transport system kinetically toward the pH component of the proton motive force. Galactoside efflux increased with increasing pH with a pKa of about 8, whereas galactoside exchange (and counterflow) exhibited a pH optimum around 7 with pKa values of 6 and 8, respectively. Imposition of delta pH (interior alkaline) retarded the rate of efflux at any pH value tested, whereas the rate of exchange was stimulated by an imposed delta pH at pH 5.8, not affected at pH 7.0, and inhibited at pH 8.0 and 9.0. The results have been evaluated in terms of random and ordered association/dissociation of galactoside and proton on the inner surface of the membrane. Imposition of delta psi (interior negative) decreased the rate of efflux but had no effect on the rate of exchange, indicating that the unloaded transport protein carries a net negative charge and that during exchange and counterflow the carrier recycles in the protonated form.     

The lactose/H+ carrier of Escherichia coli: lac YUN mutation decreases the rate of active transport and mimics an energy-uncoupled phenotype.

The Escherichia coli K12 strain X71-54 carries the lac YUN allele, coding for a lactose/H+ carrier defective in the accumulation of a number of galactosides [Wilson, Kusch & Kashket (1970) Biochem. Biophys. Res. Commun. 40, 1409-1414]. Previous studies proposed that the lower accumulation in the mutant be due to a faulty coupling of H+ and galactoside fluxes via the carrier. Immunochemical characterization of the carriers in membranes from mutant and parent strains with an antibody directed against the C-terminal decapeptide of the wild-type carrier leads to the conclusion that the mutant carrier is similar to the wild-type in terms of apparent Mr, C-terminal sequence, and level of incorporation into the membrane. The pH-dependence of galactoside transport was compared in the mutant and the parent. At pH 8.0-9.0, mutant and parent behave similarly with respect to the accumulation of beta-D-galactosyl 1-thio-beta-D-galactoside and to the ability to grow on the carrier substrate melibiose. At pH 6.0, both the maximal velocity for active transport and the level of accumulation of beta-D-galactosyl-1-thio-beta-D-galactoside are lower in the mutant. The mutant also is unable to grow on melibiose at pH 5.5. However, at pH 6.0 and low galactoside concentrations, the symport stoichiometry is 0.90 H+ per galactoside in the mutant as compared with 1.07 in the parent. These observations suggest that symport is normal in the mutant and that the lower rate of transport in the mutant is responsible for the phenotype. At higher galactoside concentrations, accumulation is determined not only thermodynamically but also kinetically, contrary to a simple interpretation of the chemiosmotic theory. Therefore lower rates of active transport can mimic the effect of uncoupling H+ and galactoside symport. Examination of countertransport in poisoned cells at pH 6.0 reveals that the rate constants for the reorientation of the loaded and unloaded carrier are altered in the mutant. The reorientation of the unloaded carrier is slower in the mutant. However, the reorientation of the galactoside-H+-carrier complex is slower for substrates like melibiose, but faster for substrates like lactose. These findings suggest that lactose-like and melibiose-like substrates interact with the carrier in slightly different ways.     

Characterisation in vivo of the reactive thiol groups of the lactose permease from Escherichia coli and a mutant; exposure, reactivity and the effects of substrate binding

The reactivity and accessibility of the reactive thiol groups of the native lactose permease and a mutant have been studied in a number of circumstances and with a number of reagents, in particular using the specific thiol-disulphide exchange reaction. Seven different reactive states of the thiol in the native protein have been characterised by their different second-order rate constants. Interconversion between these states is dependent on the magnitude of the protonmotive force, pH and substrate binding. In the absence of galactoside, reactivity is controlled by an ionisation with apparent pKa 9.3. This pKa is not affected by the protonmotive force, but it is lowered in the presence of external galactoside. The conformation adopted by the permease when in equilibrium with saturating galactoside appears to be different from that of the intermediate that accumulates during net turnover. In the former state, the reactivity of the thiol group is depressed, whereas in the latter state it is enhanced. The thiol group of the native protein is buried in a hydrophobic environment that has a dielectric constant considerably lower than that of water. The environment is not greatly perturbed by changes in the magnitude of the protonmotive force, but it is affected by the binding of galactoside. In a strain which carries the YUN mutation (Wilson, T.H. and Kusch, M. (1972) Biochim. Biophys. Acta 255, 786-797), two reactive thiols were characterised. The more reactive of the two is more exposed than the thiol group of the native molecule and is in an environment that has a dielectric constant close to that of water. The less reactive thiol appears to be more deeply buried than that of the native protein. Thus the mutation appears to produce a conformation change in the central portion of the polypeptide chain that results in greater exposure of the reactive thiol to the aqueous environment.     

The transient kinetics of uptake of galactosides into Escherichia coli.

The uptake of galactosides into Escherichia coli via the lactose permease was studied in the time range 0.01-10s by rapid mixing and quenched flow. An initial transient was observed under two conditions. Firstly, a lag in the approach to the steady state was observed at low galactoside concentrations (less than Km). Secondly, a burst of uptake was observed when anaerobic cell suspensions were mixed with aerobic substrate solutions. However, the cause of the burst of uptake appears to be a burst in the rate of respiration. The rate of galactoside uptake during this phase is 10-fold greater than during the steady state.     

Uptake of sucrose by Saccharomyces cerevisiae

Sucrose transport has been shown to occur in several Suc^? and Suc⁺Saccharomyces cerevisiae strains as an energy-dependent process. Assay conditions have been established to avoid both extra- and intracellular hydrolysis of the disaccharide thus allowing the identification of sucrose as such inside the cell immediately after the uptake; acid pH values (4.0–5.0) were optimal for transport although significant uptake was also detected at neutral pH. Transport of sucrose was not dependent on ATP and seemed to be driven by protonmotive force supplied by the electrochemical gradient of protons across the plasma membrane. The actual symport of protons along with sucrose was directly detected by continuous pH measurement of the reaction mixtures and the initial rate of proton movement in the symport process was determined. KC1 inhibited transport of sucrose suggesting that exit of K⁺ ions might well be involved in maintaining the electroneutrality of the process. On the other hand, NaCl stimulated transport by 50% in our experimental conditions. The specificity of sucrose transport was also tested using different disaccharides.     

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.     

Increased Na+-taurine symporter in rat renal brush border membranes: preformed or newly synthesized?

The renal adaptive response to a varied intake of sulfur amino acids is demonstrated by an increase in the initial rate of Na+-taurine symport (cotransport) by rat renal brush border membrane vesicles (BBMVs) after 8-14 days of a low methionine diet. A high (3%) taurine diet reduces Na+-taurine symport. Fasting for 3 days, which depletes renal tubule cell taurine content, also enhances Na+-taurine symport both initially (15 s) and throughout the overshoot. In this study we examine the possibility that a rapid-onset adaptive response is expressed in BBMV, with the increased Na+-taurine symport reflecting the incorporation of preformed symporter into membranes rather than new synthesis. Rats fed the low methionine diet for 14 days were placed on the high taurine diet for 12-18 h; Na+-taurine symport activity fell by 40%. Fasting for 4 h restored low methionine diet levels of Na+-taurine symport activity (92 pmol.mg protein-1.15 s-1), defining a rapidly induced rise in uptake. Colchicine (0.6 mg) was injected prior to fasting in a group of rats because it blocks the incorporation (import) of preformed symporter into the membrane. Animals injected with colchicine had a pattern of BBMV uptake similar to that found in animals switched to the high taurine diet for 18 h. This agent blocked the rapidly induced rise in uptake. Feeding with the high taurine diet for 4 h caused a fall in uptake of 16.5%; colchicine blocked this reduction in uptake. These results indicate that the nephron can respond rapidly to changes in the intake of amino acids, conserving taurine in periods of nutrient lack and excreting excess taurine within 4 h in periods of surfeit. This rapid response is expressed at the brush border surface. The use of cholchicine indicates that the increase or reduction in Na+-taurine symport activity is due to incorporation (import) of transporter into the BBMV rather than to de novo synthesis.     

The role of protons in the mechanism of galactoside transport via the lactose permease of Escherichia coli

The kinetic mechanism of lactose transport across the cytoplasmic membrane has been investigated and the results related to standard models for the lactose-H+ symport reaction using computer simulation. It is shown that the biphasic kinetics reported for lactose uptake (Kaczorowski, G.J. and Kaback, H.R. (1979) Biochemistry 18, 3691-3697) are consistent with random binding of lactose and protons and rapid subsequent translocation of the ternary lactose-H+-permease complex. Such a model is also shown to explain the observed dependence of the kinetic parameters on the magnitude of the protonmotive force. Both sugar and protons are shown to cause product inhibition of lactose flux and the ability of standard models to account for the pattern of inhibition is discussed. Three apparent dissociation constants have been determined for the protonation reactions in the external medium: two (pKa 6.3 and 9.6) control the activity of the permease, whilst the third (pKa 8.3) controls the affinity of the permease for galactosides. A similar set of dissociation constants has been determined for the internal reactions. Again two (pKa 6 and 9.8) control activity and a third (pKa 8.8) controls the affinity for galactosides. The dissociation reactions characterised by pKa 8.3, 8.8, 9.6 and 9.8 are attributed to the dissociation of the substrate (symported) proton from the binary proton-permease complexes (pKa 8.3 and 8.8) and the ternary proton-galactoside-permease complexes (pKa 9.6 and 9.8). The third pair (pKa 6.3 and 6.0) must be interpreted as describing a separate protonation reaction which may have a regulatory or auxiliary role in transport.     

L-aspartate transport in the photosynthetic bacterium Chromatium vinosum

The photosynthetic purple sulfur bacterium Chromatium vinosum appears to contain two active transport systems for L-aspartate. The higher affinity system (S0.5 = 60 microM) appears to be an electrogenic aspartate/H+ symport and the lower affinity system (S0.5 = 220 microM) appears to involve an aspartate/Na+ symport. In addition to a possible role in providing the driving force for aspartate uptake, transmembrane Na+ gradients may also have allosteric effects on aspartate transport in C. vinosum.     

The kinetics of the beta-galactoside-proton symport of Escherichia coli.

beta-Galactoside transport by Escherichia coli occurs with the concomitant uptake of a proton. The kinetics of beta-galactoside uptake at various values of external pH are interpreted in terms of a model in which both the galactoside and the proton are substrates of the transport reaction. The values of some of the kinetic constants for this two-substrate reaction were determined. The observed effects of the protonmotive force on the apparent Michaelis constant for galactoside can be explained in terms of the proton being a substrate of the transport reaction.     

Characterization of a lactose permease mutant that binds IIAGlc in the absence of ligand

Enzyme IIA(Glc) of the Escherichia coli phosphoenolpyruvate:glucose phosphotransferase system plays a direct role in regulating inducible transport systems. Dephosphorylated IIA(Glc) binds directly to lactose permease in a reaction that requires binding of a galactosidic substrate. A double-Cys mutation (Ile129 --> Cys/Lys131 --> Cys) was introduced into helix IV of the permease near the IIA(Glc) binding site in cytoplasmic loop IV/V and in the vicinity of the galactoside binding site at the interface of helices IV, V, and VIII. The mutant no longer requires galactoside for IIA(Glc) binding as demonstrated by both a [(125)I]IIA(Glc) binding assay and a newly developed fluorescence anisotropy assay. Further characterization of the mutant shows that it binds substrate with high affinity, but is almost completely defective in all modes of translocation across the cytoplasmic membrane. The data are consistent with the interpretation that the double mutant is locked in an inward-facing conformation.     

Binding-protein-dependent alanine transport in Rhodobacter sphaeroides is regulated by the internal pH.

The properties of an L-alanine uptake system in Rhodobacter sphaeroides were studied and compared with those of H+/lactose symport in R. sphaeroides 4P1, a strain in which the lactose carrier of Escherichia coli has been cloned and functionally expressed (F. E. Nano, Ph.D. thesis, University of Illinois, Urbana, 1984). Previous studies indicated that both transport systems were active only when electron transfer took place in the respiratory or cyclic electron transfer chain, while uptake of L-alanine also required the presence of K+ (M. G. L. Elferink, Ph.D. thesis, University of Groningen, Groningen, The Netherlands, 1986). The results presented in this paper offer an explanation for these findings. Transport of the nonmetabolizable L-alanine analog 2-alpha-aminoisobutyric acid (AIB) is mediated by a shock-sensitive transport system. The apparently unidirectional uptake of AIB results in accumulation levels which exceed 7 x 10(3). The finding of L-alanine-binding activity in the concentrated crude shock fluid indicates that L-alanine is taken up by a binding-protein-dependent transport system. Transport of the nonmetabolizable lactose analog methyl-beta-D-thiogalactopyranoside (TMG) by the lactose carrier under anaerobic conditions in the dark was observed in cells and membrane vesicles. This indicates that the H+/lactose symport system is active without electron transfer. Uptake of AIB, but not that of TMG, is inhibited by vanadate with a 50% inhibitory concentration of 50 microM, which suggests a role of a phosphorylated intermediate in AIB transport. Uptake of TMG and AIB is regulated by the internal pH. The initial rates of uptake increased with the internal pH, and and pKa values of 7.2 for TMG and 7.8 for AIB. At an internal pH of 7, no AIB uptake occurred, and the rate of TMG uptake was only 30% of the rate at an internal pH of 8. In a previous study, we found that K+ plays an essential role in regulating the internal pH (T. Abee, K. J. Hellingwerf, and W. N. Konings, J. Bacteriol. 170:5647-5653, 1988). The dependence of solute transport in R. sphaeroides on both K+ and activity of an electron transfer chain can be explained by an effect of the internal pH, which subsequently influences the activities of the lactose-and binding-protein-dependent L-alanine transport system.     

The kinetic mechanism of galactoside/H+ cotransport in Escherichia coli

To determine the kinetic mechanism of galactoside active transport by the lactose/H+ cotransporter of Escherichia coli, galactoside binding and transport are studied in the absence and presence of delta mu H+. For several reasons, the substrate beta-D-galactosyl-1-thi-beta-D-galactoside (GalSGal) is preferred over lactose. In the absence of delta mu H+, the cotransporter retains high affinity for GalSGal, and the affinity is the same on both sides of the membrane. At physiological pH, the cotransporter is protonated and the dissociation constant for H+ may be 50 pM. The cosubstrates bind in a random fashion. An isomerization of the cotransporter corresponding to reorientation of the binding sites is rate-determining. When delta mu H+ is imposed, two reorientations become faster, and one becomes slower. The affinity of the cotransporter for GalSGal on both sides of the membrane is unchanged. The inability of the cotransporter to bring the accumulation of galactoside into equilibrium with delta mu H+ at high galactoside concentrations can be explained without postulating uncoupled fluxes of galactoside or H+ across the membrane (leaks). The formation of the ternary carrier-H+-galactoside complex on the cytoplasmic side of the membrane with increasing internal levels of sugar and the rapidity of galactoside exchange inhibit net influx of galactoside and favor exchange. Net transport is slow at high galactoside levels. Thus, the cotransporter can self-regulate transport without uncoupling H+ and galactoside fluxes. Because the values of delta mu H+ during binding and transport studies were measured, these results can be subjected to a quantitative analysis.     

Differences in uncoupling effects associated with the uptake of lactose and dansyl-galactoside in Escherichia coli membrane: Active transport versus specific binding

Cytoplasmic membrane vesicles isolated from Escherichia coli take up dansyl-galactoside, a fluorescent competitive inhibitor of lactose transport, to much lower levels than lactose. An initial interpretation, based on the study of the fluorescent changes accompanying the energy-dependent uptake, was that it represented a one-to-one specific binding to the lac carrier protein which was not followed by transport. Recently, on the basis of a new estimation of the number of lac carrier in the membrane, it has been advanced that the uptake of dansyl-galactoside represents a nonspecific binding on the inner surface of the membrane following transport. We discriminate between the two interpretations by comparing the effects of lactose and dansyl-galactoside uptake on the electrochemical gradient of protons ($\text{Δ}\text{}\text{?}\text{gm}{}_{\mathrm{H}}\text{+}$), generated by the oxidation of substrates, and on the uptake of proline. Indeed, it is known that the rate of lactose transport is such that it leads, as a consequence of the lactose/H⁺ symport, to an observable decrease of $\text{Δ}\text{}\text{?}\text{gm}{}_{\mathrm{H}}\text{+}$, and secondary to this decrease to an inhibition of the uptake of proline transported at much lower rate. We show that the rates of uptake of lactose and dansyl-galactoside by the membrane vesicles are similar; yet the uptake of dansyl-galactoside does not lead to the uncoupling effects which are associated with the uptake of lactose. We discuss the possible reasons for the absence of this uncoupling effect, and we conclude that our data are incompatible with the notion that the energy-dependent uptake of dansyl-galactoside is associated with an active transport involving a dansyl-galactoside/H⁺ symport. On the contrary, the data substantiate the initial interpretation that the energy-dependent uptake of dansyl-galactoside reflects the binding to the lac carrier not followed by transport.     

Effects of the Fenton reagent on transport in yeast

In the facultatively anaerobic yeastSaccharomyces cerevisiae the uptake rate and the accumulation ratio of 2-aminoisobutyric acid was decreased by some 30% by Fenton's reagent (FR), a powerful source of OH… radicals. Likewise, the uptake of glutamic acid, leucine and arginine was diminished. The mediated diffusion of 6-deoxy-d-glucose was not affected. The H⁺ symport of maltose and trehalose was inhibited by some 40% both in the initial rate and in the accumulation ratio. FR had a dramatic inhibitory effect when present during preincubation with 50 mmol/L glucose. In the obligately aerobicLodderomyces elongisporus the uptake of all amino acids tested was decreased by 15–30%, that of 6-deoxy-d-glucose by about 10%. The initial rates of uptake of maltose and trehalose were depressed by FR by 40% and the acceleration of uptake observed after 8 min of incubation, was abolished by FR completely. Acidification rate of the external medium byS. cerevisiae in the presence of glucose or galactose was enhanced three-fold, that after subsequently added K⁺ was substantially decreased. FR appears to have a dual effect on sugar and amino acid transport processes in yeast: (1) it blocks carrier protein synthesis, (2) it inhibits the source of energy for transport. It does not appreciably affect the carrier proteins themselves.     

Site-exposure model for proton-lactose symport in Escherichia coli.

A model is presented for the lactose-proton co-transporter of E. coli. Either proton translocation inwards or galactoside translocation outwards brings about the exposure of galactoside binding sites externally. This alternation in the exposure of the galactoside binding site to either side of the membrane is viewed as the fundamental event in coupled uptake, rather than affinity changes for galactoside.The transporter is proposed to function as a dimer, exhibiting two forms corresponding to the “cis” and the “trans” orientation of the two galactosyl binding sites. A galactoside or a proton gradient brings about conversion of the sites from the “trans” to the “cis” configuration. The two forms can be experimentally differentiated by the accessibility of non-transportable substrate analogs to the galactosyl binding sites.