Homologous sugar transport proteins in Escherichia coli and their relatives in both prokaryotes and eukaryotes

Separate proteins for proton-linked transport of D-xylose, L-arabinose, D-galactose, L-rhamnose and L-fucose into Escherichia coli are being studied. By cloning and sequencing the appropriate genes, the amino acid sequences of proteins for D-xylose/H+ symport (XylE), L-arabinose/H+ symport (AraE), and part of the protein for D-galactose/H+ symport (GalP) have been determined. These are homologous, with at least 28% identical amino acid residues conserved in the aligned sequences, although their primary sequences are not similar to those of other E. coli transport proteins for lactose, melibiose, or D-glucose. However, they are equally homologous to the passive D-glucose transport proteins from yeast, rat brain, rat adipocytes, human erythrocytes, human liver, and a human hepatoma cell line. The substrate specificity of GalP from E. coli is similar to that of the mammalian glucose transporters. Furthermore, the activities of GalP, AraE and the mammalian glucose transporters are all inhibited by cytochalasin B and N-ethylmaleimide. Conserved residues in the aligned sequences of the bacterial and mammalian transporters are identified, and the possible roles of some in sugar binding, cation binding, cytochalasin binding, and reaction with N-ethylmaleimide are discussed. Each protein is independently predicted to form 12 hydrophobic, membrane-spanning alpha-helices with a central hydrophilic segment, also comprised of alpha-helix. This unifying structural model of the sugar transporters shares features with other ion-linked transport proteins for citrate or tetracycline.     

Proton-linked L-fucose transport in Escherichia coli.

1. Addition of L-fucose to energy-depleted anaerobic suspensions of Escherichia coli elicited an uncoupler-sensitive alkaline pH change diagnostic of L-fucose/H+ symport activity. 2. L-Galactose or D-arabinose were also substrates, but not inducers, for the L-fucose/H+ symporter. 3. L-Fucose transport into subcellular vesicles was dependent upon respiration, displayed a pH optimum of about 5.5, and was inhibited by protonophores and ionophores. 4. These results showed that L-fucose transport into E. coli was energized by the transmembrane electrochemical gradient of protons. 5. Neither steady state kinetic measurements nor assays of L-fucose binding to periplasmic proteins revealed the existence of a second L-fucose transport system.     

Proton-linked D-xylose transport in Escherichia coli.

The addition of xylose to energy-depleted cells of Escherichia coli elicited an alkaline pH change which failed to appear in the presence of uncoupling agents. Accumulation of [14C]xylose by energy-replete cells was also inhibited by uncoupling agents, but not by fluoride or arsenate. Subcellular vesicles of E. coli accumulated [14C]xylose provided that ascorbate plus phenazine methosulfate were present for respiration, and this accumulation was inhibited by uncoupling agents or valinomycin. Therefore, the transport of xylose into E. coli appears to be energized by a proton-motive force, rather than by a phosphotransferase or directly energized mechanism. Its specificity for xylose as inducer and substrate and the genetic location of a xylose-H+ transport-negative mutation near mtl showed that the xylose-H+ system is distinct from other proton-linked sugar transport systems of E. coli.     

Anaerobic transport of amino acids coupled to the glycerol-3-phosphate-fumarate oxidoreductase system in a cytochrome-deficient mutant of Escherichia coli.

The uptake of proline and glutamine by cytochrome-deficient cells of Escherichia coli SASX76 grown aerobically on glucose or anaerobically on pyruvate was stimulated by these two substrates. Pyruvate could not stimulate transport in the glucose-grown cells. Uptake of these amino acids energized by glucose was inhibited by inhibitors of the Ca2+, Mg2+-stimulated ATPase such as DCCD, pyrophosphate, and azide, and by the uncouplers CCCP and 2,4-dinitrophenol. Glycerol (or glycerol 3-phosphate) in the presence of fumarate stimulated the transport of proline and glutamine under anaerobic conditions in cytochrome-deficient cells but not in membrane vesicles prepared from these cells although glycerol 3-phosphate-fumarate oxidoreductase activity could be demonstrated in the vesicle preparation. In contrast, in vesicles prepared from cytochrome-containing cells of E. coli SASX76 amino acid transport was energized under anaerobic conditions by this system. Inhibitors of the Ca2+, Mg2+-activated ATPase and uncoupling agents inhibited the uptake of proline and glutamine in cytochrome-deficient cells dependent on the glycerol-fumarate oxidoreductase system. Ferricyanide could replace fumarate as an electron acceptor to permit transport of phenylalanine in cytochrome-deficient or cytochrome-containing cells under anaerobic conditions. It is concluded that in cytochrome-deficient cells using glucose, pyruvate, or glycerol in the presence of fumarate, transport of both proline and glutamine under under anaerobic conditions is energized by ATP through the Ca2+, Mg2+-activated ATPase. In cytochrome-containing cells under anaerobic conditions electron transfer between glycerol and fumarate can also drive transport of these amino acids.     

The association of proton movement with galactose transport into subcellular membrane vesicles of Escherichia coli.

1. Subcellular membrane vesicles were prepared from a strain of Escherichia coli constitutive for the GalP galactose-transport system. 2. The addition of substrates of the GalP transport system to vesicle suspensions promoted alkaline pH changes, which provided direct evidence for the coupling of sugar and proton transport. 3. Respiration-energized galactose transport was progressively inhibited at pH values above 6.0, and was abolished by agents that render the membrane permeable to protons. 4. The combined effects of valinomycin, the nigericin-like compound A217 and pH on galactose transport suggested that both delta pH and delta psi components of the protonmotive force contributed to energization of galactose transport. 5. These results substantiate the conclusion that the GalP transport system operates by a chemiosmotic mechanism.     

Identification of the AraE transport protein of Escherichia coli.

1. Two arabinose-inducible proteins are detected in membrane preparations from strains of Escherichia coli containing arabinose-H+ (or fucose-H+) transport activity; one protein has an apparent subunit relative molecular mass (Mr) of 36 000-37 000 and the other has Mr 27 000. 2. An araE deletion mutant was isolated and characterized; it has lost arabinose-H+ symport activity and the arabinose-inducible protein of Mr 36 000, but not the protein of Mr 27 000. 3. An araE+ specialized transducing phage was characterized and used to re-introduce the araE+ gene into the deletion strain, a procedure that restores both arabinose-H+ symport activity and the protein of Mr 36,000. 4. N-Ethylmaleimide inhibits arabinose transport and partially inhibits arabinose-H+ symport activity. 5. N-Ethylmaleimide modifies an arabinose-inducible protein of Mr 36 000-38 000, and arabinose protects the protein against the reagent. 6. These observations identify an arabinose-transport protein of Escherichia coli as the product of the araE+ gene. 7. The protein was recognized as a single spot staining with Coomassie Blue after two-dimensional gel electrophoresis.     

Kinetic analysis of simultaneously occurring proton-sorbose symport and passive sorbose transport in Saccharomyces fragilis

Sorbose transport in Saccharomyces fragilis takes place both via an active sugar-H+ symport system and via facilitated diffusion. To establish whether the two modes of transport proceed via the same transporter or via two different carriers, the kinetic consequences of both models were investigated. The kinetic equations for initial transport were derived for three possible reaction sequences with respect to sugar and H+ binding to the symport carrier: random binding and obligatory ordered binding with either sugar or H+ binding first, yielding six sets of kinetic parameters. Analysis of experimental data of sorbose transport in S. fragilis showed the existence of separate carriers for active, sorbose-H+ symport and facilitated diffusion. Furthermore, it could be concluded that the symport carrier shows random binding of sugar and H+. In recent literature, a similar combination of active and passive sugar transport in Rhodotorula gracilis and Chlorella vulgaris was interpreted as two modes of action of the same carrier, viz., active symport via the protonated, and facilitated diffusion via the unprotonated carrier. Analysis of the experimental data according to the criteria presented in this paper showed, however, that this supposition is untenable and that two different carriers must also be involved in these micro-organisms.     

Light-induced glutamate transport in Halobacterium halobium envelope vesicles. II. Evidence that the driving force is a light-dependent sodium gradient.

Illumination of cell envelope vesicles from H. halobium causes the development of protonmotive force and energizes the uphill transport of glutamate. Although the uncoupler, p-trifluoromethoxycarbonyl cyanide phenylhydrazone (FCCP), and the membrane-permeant cation, triphenylmethylphosphonium (TPMP+), are inhibitory to the effect of light, the time course and kinetics of the production of the energized state for transport, and its rate of decay after illumination, are inconsistent with the idea that glutamate accumulation is driven directly by the protonmotive force. Similarities between the light-induced transport and the Na+-gradient-induced transport of glutamate in these vesicles suggest that the energized state for the amino acid uptake in both cases consists of a transmembrane Na+ gradient (Na+out/Na+in greater than 1). Rapid efflux of 22Na from the envelope vesicles is induced by illumination. FCCP and TPMP+ inhibit the light-induced efflux of Na+ but accelerate the post-illumination relaxation of the Na+ gradient created, suggesting electrogenic antiport of Na+ with another cation, or electrogenic symport with an anion. The light-induced protonmotive force in the H. halobium cell envelope vesicles is thus coupled to Na+ efflux and thereby indirectly to glutamate uptake as well.     

Mechanism of proline transport in Escherichia coli K12. III. Inhibition of membrane potential-driven proline transport by syn-coupled ions and evidence for symmetrical transition states of the 2H+/proline symport carrier

Specific inhibition of 2H+/proline symport by syn-coupled ions (Na+, Li+, and H+) was investigated using cytoplasmic membrane vesicles prepared from the proline carrier-overproducing strain MinS/ pLC4 -45 of Escherichia coli K12. The 2H+/proline symport driven by the membrane potential generated via respiration with 20 mM ascorbate/Tris, 0.1 mM phenazine methosulfate was specifically inhibited by Na+. The inhibition by Na+ was described by a fully noncompetitive mechanism, and the apparent Ki for Na+ was 15 mM. A linear correlation between the apparent Vmax and the apparent Kd was observed. Li+ stimulated the transport activity 2-fold at 10 mM and inhibited it at concentrations above 50 mM. H+ caused fully noncompetitive inhibition of 2H+/proline symport, and its apparent Ki was 0.6 microM. These results indicate that the concentrations of Na+ and H+ strictly and independently regulate the amount of the active C state carrier responsible for 2H+/proline symport driven by the membrane potential by inhibiting the transition from the C* state carrier which exhibits Na+- and H+-dependent binding of proline and is predominant in nonenergized conditions.     

Replacement of the glucose phosphotransferase transport system by galactose permease reduces acetate accumulation and improves process performance of Escherichia coli for recombinant protein production without impairment of growth rate

Acetate accumulation under aerobic conditions is a common problem in Escherichia coli cultures, as it causes a reduction in both growth rate and recombinant protein productivity. In this study, the effect of replacing the glucose phosphotransferase transport system (PTS) with an alternate glucose transport activity on growth kinetics, acetate accumulation and production of two model recombinant proteins, was determined. Strain VH32 is a W3110 derivative with an inactive PTS. The promoter region of the chromosomal galactose permease gene galP of VH32 was replaced by the strong trc promoter. The resulting strain, VH32GalP+ acquired the capacity to utilize glucose as a carbon source. Strains W3110 and VH32GalP+ were transformed for the production of recombinant TrpLE-proinsulin accumulated as inclusion bodies (W3110-PI and VH32GalP+-PI) and for production of soluble intracellular green fluorescent protein (W3110-pV21 and VH32GalP+-pV21). W3110-pV21 and VH32GalP+-pV21 were grown in batch cultures. Maximum recombinant protein concentration, as determined from fluorescence, was almost four-fold higher in VH32GalP+-pV21, relative to W3110-pV21. Maximum acetate concentration reached 2.8 g/L for W3110-pV21 cultures, whereas a maximum of 0.39 g/L accumulated in VH32GalP+-pV21. W3110-PI and VH32GalP+-PI were grown in batch and fed-batch cultures. Compared to W3110-PI, the engineered strain maintained similar production and growth rate capabilities while reducing acetate accumulation. Specific glucose consumption rate was lower and product yield on glucose was higher in VH32GalP+-PI fed-batch cultures. Altogether, strains with the engineered glucose uptake system showed improved process performance parameters for recombinant protein production over the wild-type strain.     

A proton gradient is the driving force for uphill transport of lactate in human placental brush-border membrane vesicles

The characteristics of lactate transport in brush-border membrane vesicles isolated from normal human full-term placentas were investigated. Lactate transport in these vesicles was Na+-independent, but was greatly stimulated when the extravesicular pH was made acidic. In the presence of an inwardly directed H+ gradient ([H+]o greater than [H+]i), transient uphill transport of lactate could be demonstrated. This H+ gradient-dependent stimulation was not a result of a H+ diffusion potential. Transport of lactate in the presence of the H+ gradient was not inhibited by 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid or by furosemide, ruling out the participation of an anion exchanger in placental lactate transport. Many monocarboxylates strongly interacted with the lactate transport system, whereas, with the single exception of succinate, dicarboxylates did not. The monocarboxylates pyruvate and lactate, but not the dicarboxylate succinate, when present inside the vesicles, were able to exert a trans-stimulatory effect on the uptake of radiolabeled lactate. Kinetic analyses provided evidence for a single transport system with a Kt of 4.1 +/- 0.4 mM for lactate and a Vmax of 54.2 +/- 9.9 nmol/mg of protein/30 s. Pyruvate inhibited lactate transport competitively, by reducing the affinity of the system for lactate without altering the maximal velocity. It is concluded that human placental brush-border membranes possess a transport system specific for lactate and other monocarboxylates and that this transport system is Na+-independent and is energized by an inwardly directed H+ gradient. Lactate-H+ symport rather than lactate-OH- antiport appears to be the mechanism of the H+ gradient-dependent lactate transport in these membranes.     

Maintenance of glucagon-stimulated system A amino acid transport activity in rat liver plasma membrane vesicles

Plasma membrane vesicles prepared from intact rat liver or isolated hepatocytes retain transport activity by systems A, ASC, N, and Gly. Selective substrates for these systems showed a Na+-dependent overshoot indicative of energy-dependent transport, in this instance, driven by an artificially-imposed Na+ gradient. Greater than 85% of Na+-dependent 2-aminoisobutyric acid (AIB) uptake was blocked by an excess of 2-(methylamino)isobutyric acid (MeAIB) with an apparent Ki of 0.6 mM. Intact hepatocytes obtained from glucagon-treated rats exhibited a stimulation of system A activity and plasma membrane vesicles isolated from those same cells partially retained the elevated activity. Transport activity induced by substrate starvation of cultured hepatocytes was also evident in membrane vesicles prepared from those cells. The membrane-bound glucagon-stimulated system A activity decays rapidly during incubation of vesicles at 4 degrees C (t1/2 = 13 h), but not at -75 degrees C. Several different inhibitors of proteolysis were ineffective in blocking the decay of transport activity. Hepatic system N transport activity was also elevated in plasma membrane vesicles from glucagon-treated rats, whereas system ASC was essentially unchanged. The results indicate that both glucagon and adaptive regulation cause an induction of amino acid transport through a plasma membrane-associated protein.     

Amino acid transport in kidney epithelial cell line (MDCK): characteristics of Na+/amino acid symport in membrane vesicles and basolateral localization in cell monolayers

Na+-stimulated amino acid transport was investigated in MDCK kidney epithelial cell monolayers and in isolated membrane vesicles. When transport polarity was assessed in confluent polarized epithelial cell monolayers cultured on Nucleopore filters and mounted between two lucite chambers, Na+-stimulated transport of 2-(methylamino)isobutyric acid (MeAIB), a substrate specific for the A system, was predominantly localized on the basolateral membrane. Na+-stimulated amino acid transport activity was maximal in subconfluent cultures, and was substantially reduced after confluence. A membrane vesicle preparation was isolated from confluent MDCK cell cultures which was enriched in Na+-stimulated MeAIB transport activity and Na+,K+,ATPase activity, a basolateral marker, but was not enriched in apical marker enzyme activities or significantly contaminated by mitochondria. Na+-coupled amino acid transport activity assayed in vesicles exhibited a marked dependence on external pH, with an optimum at pH 7.4. The pattern of competitive interactions among neutral amino acids was characteristic of A system transport. Na+-coupled MeAIB and AIB transport in vesicles was electrogenic, stimulated by creation of an interior-negative membrane potential. The Na+ dependence of amino acid transport in vesicles suggested a Na+ symport mechanism with a 1:1 stoichiometry between Na+ and amino acid.     

pH dependence of the Coxiella burnetii glutamate transport system.

The transport of glutamate, apparently a primary energy source for Coxiella burnetii, has been examined. C. burnetii is shown to possess a pH-dependent active transport system for L-glutamate with an apparent Kt of 61.1 microM and Vmax of 8.33 pmol/s per mg at pH 3.5. Both L-glutamine and L-asparagine competitively inhibited transport of glutamate, but D-glutamate, L-aspartate, L-glutamate-gamma-methyl ester, methionine sulfoximine, or alpha-ketoglutarate did not compete. This transport system is both temperature and energy dependent. Uptake of glutamate is highly sensitive to uncouplers of oxidative phosphorylation such as 2,4-dinitrophenol and carbonyl cyanide-m-chlorophenyl hydrazone that decrease the proton motive force across the cytoplasmic membrane. ATPase inhibitors such as dicyclohexylcarbodiimide or metabolic poisons such as KCN, NaF, or arsenite were much less effective as inhibitors of glutamate transport. Uptake of glutamate did not appear to be coupled to Na+ symport as in Escherichia coli since no monovalent cation requirement could be demonstrated. Instead, the Vmax of glutamate transport showed good correlation with the transmembrane pH gradient (delta pH). From these results, we propose that L-glutamate transport by C. burnetii is energized via a proton motive force.     

Potassium transport system of Rhodopseudomonas capsulata

Rhodopseudomonas capsulata required potassium (or rubidium or cesium as analogs of potassium) for growth. These cations were actively accumulated by the cells by a process following Michaelis-Menten saturation kinetics. The monovalent cation transport system had Km's of 0.2 mM K+, 0.5 mM Rb+, and 2.6 mM Cs+. The rates of uptake of substrates by the potassium transport system varied with the age of the culture, although the affinity constant for the substrates remained constant. The maximal velocity of uptake of K+ was lower in aerobically grown cells than in photosynthetically grown cells, although the Km's for K+ and for Rb+ were about the same.     

Citrate transport in Klebsiella pneumoniae

Sodium ions were specifically required for citrate degradation by suspensions of K. pneumoniae cells which had been grown anaerobically on citrate. The rate of citrate degradation was considerably lower than the activities of the citrate fermentation enzymes citrate lyase and oxaloacetate decarboxylase, indicating that citrate transport is rate limiting. Uptake of citrate into cells was also Na+ -dependent and was accompanied by its rapid metabolism so that the tricarboxylic acid was not accumulated in the cells to significant levels. The transport could be stimulated less efficiently by LiCl. Li+ ions were cotransported with citrate into the cells. Transport and degradation of citrate were abolished with the uncoupler [4-(trifluoromethoxy)phenylhydrazono]propanedinitrile (CCFP). After releasing outer membrane components and periplasmic binding proteins by cold osmotic shock treatment, citrate degradation became also sensitive towards monensin and valinomycin. The shock procedure had no effect on the rate of citrate degradation indicating that the transport is not dependent on a binding protein. Citrate degradation and transport were independent of Na+ ions in K. pneumoniae grown aerobically on citrate and in E. coli grown anaerobically on citrate plus glucose. An E. coli cit+ clone obtained by transformation of K. pneumoniae genes coding for citrate transport required Na specifically for aerobic growth on citrate indicating that the Na-dependent citrate transport system is operating. Na+ and Li+ were equally effective in stimulating citrate degradation by cell suspensions of E. coli cit+. Citrate transport in membrane vesicles of E. coli cit+ was also Na+ dependent and was energized by the proton motive force (delta micro H+). Dissipation of delta micro H+ or its components delta pH or delta psi by ionophores either totally abolished or greatly inhibited citrate uptake. It is suggested that the systems energizing citrate transport under anaerobic conditions are provided by the outwardly directed cotransport of metabolic endproducts with protons yielding delta pH and by the decarboxylation of oxaloacetate yielding delta pNa+ and delta psi. In citrate-fermenting K. pneumoniae an ATPase which is activated by Na+ was not found. The cells contain however a proton translocating ATPase and a Na+/H+ antiporter in their membrane.     

Effect of the membrane potential on the Mg2+,ATP-dependent transport of Ca2+ across smooth muscle sarcolemma

The effect of the membrane potential (K(+)-valinomycin system) on the Mg2+, ATP-dependent transport of Ca2+ in inside-out vesicles of myometrium sarcolemma has been studied. The membrane potential was identified by using a cyanine potential-sensitive probe, diS-C3-(5). In the presence of valinomycin (5.10(-8) M) the inside-out directed K+ gradient (delta psi = -86 mV, with a negative charge inside) stimulated the initial rate of the energy-dependent accumulation of Ca2+ transfer whereas the oppositely directed K+ gradient (delta psi = +72 mV, with a positive charge inside) had no effect on this process. The K+ gradient was formed by isotonic substitution of K+ in intra- or extravesicular space for choline +. At the same time, in the absence of K+ gradient the Mg2+, ATP-dependent accumulation of Ca2+ in membrane vesicles did not depend on the chemical nature of the cations (K+ or choline+) used for isotonicity. The decrease of delta psi from 0 to -86 mV affects the initial rate of Ca2+ accumulation but not the maximal content of the accumulated cation. Preliminary dissipation of the membrane potential (delta psi = -86 mV) in Mg2(+)-free isotonic (with respect of K+ and choline+) media containing ATP and Ca2+ resulted in the inhibition of Mg2+, ATP-dependent Ca2+ transport induced by subsequent addition of Mg2+. These results indicate that the negative (intravesicular) electrical potential activates the Ca-pump of smooth muscle sarcolemma. This activation is based on the increase in the turnover number of the Ca2+ transporting system but not on its affinity for the transfer substrate. The use of the absolute reaction rates theory made it possible to establish that the Ca-pump effectuates the transport of a single positive charge in inside-out vesicles of smooth muscle plasma membranes, i.e., the energy-dependent transport of Ca2+ occurs either as a symport (with an anion (Cl-) or an antiport with a monovalent cation (K+) or a proton. It is assumed that the potential dependence of the Ca-pump in the smooth muscle plasma membrane plays a role in the realization of effects of mediators and physiologically active substances that are manifested as stimulation of the contractile response and depolarization of the sarcolemma. In is quite probable that the delta psi-dependent Ca-pump is also responsible for the maintenance of intracellular homeostasis of monovalent cations (K+, H+, Cl-) in smooth muscle tissues.     

Calcium transport driven by a proton gradient and inverted membrane vesicles of Escherichia coli.

Calcium transport into inverted vesicles of Escherichia coli was observed to occur without an exogenous energy source when an artificial proton gradient was used. The orientation of the proton gradient was acid inside and alkaline outside. Either phosphate or oxalate was necessary for transport, as was found for respiratory-driven or ATP-driven uptake (Tsuchiya, T., and Rosen, B.P. (1975) J. Biol. Chem. 250, 7687-7692). Phosphate accumulation was found to occur in conjunction with calcium accumulation. Calcium transport driven by an artificial proton gradient was stimulated by dicyclohexylcarbodiimide, an inhibitor of the Mg2+ATPase (EC 3.6.1.3). Valinomycin, which catalyzes electrogenic potassium movement, stimulated calcium accumulation, while nigericin, which catalyzes electroneutral exchange of potassium and protons, inhibited both artificial proton gradient-driven transport and respiratory-driven transport. Other properties of the proton gradient-driven system and the previously reported energy-linked calcium transport system are similar, indicating that calcium is transported by the same carrier whether energy is supplied through an artificial proton gradient or an energized membrane state. These results suggest the existence of a calcium/proton antiport.     

Calcium transport in membrane vesicles of Bacillus subtilis.

Right-side-out membrane vesicles of Bacillus subtilis W23 grown on tryptone-citrate medium accumulated Ca2+ under aerobic conditions in the presence of a suitable electron donor. Ca2+ uptake was an electrogenic process which was completely inhibited by carbonyl cyanide m-chlorophenylhydrazone or valinomycin and not by nigericin. This electrogenic uptake of calcium was strongly dependent on the presence of phosphate and magnesium ions. The system had a low affinity for Ca2+. The kinetic constants in membrane vesicles were Km = 310 microM Ca2+ and Vmax = 16 nmol/mg of protein per min. B. subtilis also possesses a Ca2+ extrusion system. Right-side-out-oriented membrane vesicles accumulated Ca2+ upon the artificial imposition of a pH-gradient, inside acid. This system had a high affinity for Ca2+; Km = 17 microM Ca2+ and Vmax = 3.3 nmol/mg of protein per min. Also, a membrane potential, inside positive, drove Ca2+ transport via this Ca2+ extrusion system. Evidence for a Ca2+ extrusion system was also supplied by studies of inside-out-oriented membrane vesicles in which Ca2+ uptake was energized by respiratory chain-linked oxidation of NADH or ascorbate-phenazine methosulfate. Both components of the proton motive force, the pH gradient and the membrane potential, drove Ca2+ transport via the Ca2+ extrusion system, indicating a proton-calcium antiport system with a H+ to Ca2+ stoichiometry larger than 2. The kinetic parameters of this Ca2+ extrusion system in inside-out-oriented membranes were Km = 25 microM and Vmax = 0.7 nmol/mg of protein per min.     

L-malate transport and proton symport in vesicles prepared from Pseudomonas putida

In vesicles from glucose-grown Pseudomonas putida, L-malate is transported by nonspecific physical diffusion. L-Malate also acts as an electron donor and generates a proton motive force (delta p) of 129 mV which is composed of a membrane potential (delta psi) of 60 mV and a delta pH of 69 mV. In contrast, vesicles from succinate-grown cells transport L-malate by a carrier-mediated system with a Km value of 14.3 mM and a Vmax of 313 nmol X mg protein-1 X min-1, generate no delta psi, delta pH, or delta p when L-malate is the electron donor, and produce an extravesicular alkaline pH during the transport of L-malate. A kinetic analysis of this L-malate-induced proton transport gives a Km value of 16 mM and a Vmax of 667 nmol H+ X mg protein-1 X min-1. This corresponds to a H+/L-malate ratio of 2.1. The failure to generate a delta p in these vesicles is considered, therefore, to be consistent with the induction in succinate-grown cells of an electrogenic proton symport L-malate transport system.