Amino acid transport in whole cells and membrane vesicles of Arthrobacter pyridinolis

Arginine, and several other amino acids, can only support growth of Arthrobacter pyridinolis if malate is also present in the medium. Arginine is transported by a high affinity lysine-arginine-ornithine-type transport system which is stimulated by malate in both whole cells and vesicles, is respiration-coupled, and appears to depend upon a respiration-generated membrane potential but not on a ΔpH. Arginine is also transported by a low-affinity system which transports canavanine. Studies of an arginine auxotroph suggest that the lysine-arginine-ornithine system may be the system of major physiological significance for arginine transport. Phenylalanine is one of a few amino acids which can act as sole source of carbon for A. pyridinolis. Transport of phenylalanine occurs by two kinetically distinct systems. Both of these transport systems are respiration-coupled, are not appreciably stimulated by malate either in cells or vesicles, but are markedly stimulated by ascorbate-phenazine methosulfate. Studies with inhibitors indicate that the transport systems for phenylalanine utilize both a ΔpH and a membrane potential.     

Induction of the phosphoenolpyruvate: hexose phosphotransferase system associated with relative anaerobiosis in an obligate aerobe.

Arthrobacter pyridinolis possesses alternative transport systems for D-fructose: a respiration-coupled transport system whereby D-fructose transport occurs with concomitant oxidation of L-malate, and a phosphoenolpyruvate: D-fructose phosphotransferase system. Studies of D-fructose uptake by whole cells in the presence and absence of cyanide demonstrate that respiration-coupled transport is used almost exclusively during the first half of logarithmic growth, after which it accounts for only 15-20% of D-fructose uptake. Phosphotransferase levels are low during log phase, peak during late log, and then slowly decline. In a mutant of A. pyridinolis which requires delta-aminolevulinic acid for growth, the growth rate, cell cytochrome content, and activity of the respiration-coupled transport system increased with increasing concentrations of delta-aminolevulinic acid up to 50 microgram/ml. By contrast, phosphotransferase activity was highest in cells grown on limiting delta-aminolevulinic acid. L-Malate, which stimulates respiration-coupled transport, repressed the phosphotransferase system. The respiratory activity and the ability to release CO2 from internalized d-fructose was consistently low in D-fructose-grown cells. A cyanide-resistant cytochrome, tentatively identified as cytochrome d, appeared in the late exponential phase of growth. Isocitrate lyase activity, required for aerobic growth of this organism, declined markedly during the late exponential phase. Thus the phosphotransferase system is maximally induced, in this obligate aerobe, under conditions of relative anaerobiosis during which metabolism is primarily fermentative.     

Mechanisms of active transport in isolated bacterial membrane vesicles. XII. Active transport by a mutant of Escherichia coli uncoupled for oxidative phosphorylation

Amino acid and β-galactoside transport activity catalyzed by whole cells and membrane vesicles prepared from an Escherichia coli mutant uncoupled for oxidative phosphorylation is comparable to the activity of analogous preparations from the parent strain. Valinomycin-induced rubidium uptake is also similar in membrane vesicles prepared from wild-type and mutant cells. The properties of the transport systems in mutant vesicles are the same as those of wild-type vesicles with respect to electron donors which stimulate transport, and with respect to inhibition by anoxia, cyanide, and 2,4-dinitrophenol.Magnesium ion markedly stimulates the ATPase activity of wild-type membrane vesicles and ethylenediaminetetraacetate markedly inhibits. However, these compounds have relatively slight effects on either the initial rate or extent of transport. Dicyclohexylcarbodiimide does not inhibit respiration-dependent transport despite inhibition of the calcium, magnesium-activated ATPase activity of wild-type vesicles.These results confirm earlier observations indicating that oxidative phosphorylation is not involved in respiration-linked active transport.     

Defective transport in S-adenosylmethionine synthetase mutants of Escherichia coli

The transport of several metabolites is decreased in mutant strains of Escherichia coli (Met K, E4 and E40), which contain decreased levels of S-adenosylmethionine synthetase. The rates and extents of uptake for lysine, leucine, methionine, and α-methylglucoside in both whole cells and membrane vesicles isolated from these mutants are 2- to 10-fold lower than in corresponding preparations from wild-type cells, although proline uptake is normal. The addition of S-adenosylmethionine to cultures of strain E40 can partially restore the rate and extent of lysine uptake. Lysine transport is lower in mutant vesicles in the presence of either d-lactate, succinate, α-hydroxylbutyrate, or NADH even though these substrates are oxidized at rates comparable to those in wild-type vesicles. This suggests that the defect is not related to the ability of vesicles to oxidize electron donors, but is very likely related to the ability of mutant vesicles to couple respiration to lysine transport. In addition, temperature-induced efflux of α-methylglucoside phosphate and dinitrophenol-induced efflux of lysine are similar in both the mutant and wild-type membranes, indicating that the barrier properties of the membrane and the activity of the lysine carrier are normal.     

Effects of colicin A and staphylococcin 1580 on amino acid uptake into membrane vesicles of Escherichia coli and Staphylococcus aureus

Staphylococcin 1580 increased the relative amount of diphosphatidylglycerol and decreased the amount of phosphatidylglycerol in cells of Staphlococcus aureus, while the amounts of lysylphosphatidylglycerol, phosphatidic acid and total phospholipid remained constant.Treatment of cells of Escherichia coli and S. aureus with colicin A and staphylococcin 1580, respectively, did not affect proton impermeability but subsequent addition of carbonylcyanide-m-chlorophenylhydrazone resulted in a rapid influx of protons into the cells.Bacteriocin-resistant and -tolerant mutants of E. coli and S. aureus were isolated. The bacteriocins caused leakage of amino acids preaccumulated into membrane vesicles of resistant mutants and had no significant effect on membrane vesicles of tolerant mutants.The uptake of amino acids into membrane vesicles was inhibited by both bacteriocins, irrespective of the electron donors applied. The bacteriocin inhibition was noncompetitive. The bacteriocins did not affect oxygen consumption and dehydrogenases in membrane vesicles.Both bacteriocins suppressed the decrease in the fluorescence of 1-anilino-8-naphthalene sulfonate caused by d-lactate or α-glycerol phosphate when added to membrane vesicles.It is concluded that the bacteriocins uncouple the transport function from the electron transport system.     

Restoration of active calcium transport in vesicles of an Mg2+-ATPase mutant of Escherichia coli by wild-type Mg2+-ATPase.

Strain NR70, a mutant of $\text{E. coli}$ lacking the Mg²⁺-adenosine triphosphatase (E.C. 3.6.1.3.) was previously shown to be defective in amino acid and sugar transport in whole cells and right-side-out membrane vesicles. It is shown here that the mutant is also deficient in the uptake of calcium into inverted membrane vesicles. Treatment of inverted vesicles from the wild-type strain with ethylenediamine tetraacetate removes the Mg²⁺-adenosine triphosphatase and results in an inability to transport calcium. Addition of a crude fraction containing the wild-type Mg²⁺-adenosine triphosphatase restores active uptake of calcium both to vesicles from the mutant and depleted vesicles from the wild-type.     

An Hg-sensitive channel mediates the diffusional component of glucose transport in olive cells

In several organisms solute transport is mediated by the simultaneous operation of saturable and non-saturable (diffusion-like) uptake, but often the nature of the diffusive component remains elusive. The present work investigates the nature of the diffusive glucose transport in Olea europaea cell cultures. In this system, glucose uptake is mediated by a glucose-repressible, H⁺-dependent active saturable transport system that is superimposed on a diffusional component. The latter represents the major mode of uptake when high external glucose concentrations are provided. In glucose-sufficient cells, initial velocities of d- and l-[U-¹⁴C]glucose uptake were equal and obeyed linear concentration dependence up to 100 mM sugar. In sugar starved cells, where glucose transport is mediated by the saturable system, countertransport of the sugar pairs 3-O-methyl-d-glucose/d-[U-¹⁴C]glucose and 3-O-methyl-d-glucose/3-O-methyl-d-[U-¹⁴C]glucose was demonstrated. This countertransport was completely absent in glucose-sufficient cells, indicating that linear glucose uptake is not mediated by a typical sugar permease. The endocytic inhibitors wortmannin-A and NH₄Cl inhibited neither the linear component of d- and l-glucose uptake nor the absorption of the nonmetabolizable glucose analog 3-O-methyl-d-[U-¹⁴C]glucose, thus excluding the involvement of endocytic mediated glucose uptake. Furthermore, the formation of endocytic vesicles assessed with the marker FM1-43 proceeded at a very slow rate. Activation energies for glucose transport in glucose sufficient cells and plasma membrane vesicles were 7 and 4 kcal mol^− 1, respectively, lower than the value estimated for diffusion of glucose through the lipid bilayer of phosphatidylethanolamine liposomes (12 kcal mol^− 1). Mercury chloride inhibited both the linear component of sugar uptake in sugar sufficient cells and plasma membrane vesicles, and the incorporation of the fluorescent glucose analog 2-NBDG, suggesting protein-mediated transport. Diffusive uptake of glucose was inhibited by a drop in cytosolic pH and stimulated by the protein kinase inhibitor staurosporine. The data demonstrate that the low-affinity, high-capacity, diffusional component of glucose uptake occurs through a channel-like structure whose transport capacity may be regulated by intracellular protonation and phosphorylation/dephosphorylation.     

Functional symmetry of the β-galactoside carrier in escherichia coli

Cytoplasmic membrane vesicles with either normal or inverted orientation were prepared from Escherichia coli. The lactose transport activity of these vesicle preparations was compared. The parameters measured were net efflux, counterflux, and K⁺/valinomycin-induced active uptake of lactose. With membrane vesicles derived from both wild-type and cytochrome-deficient strains the right-side-out and inverted membrane preparations showed similar rates of lactose flux in all assays. According to these criteria, the activity of the β-galactoside transport protein is inherently symmetrical.One major difference was observed between the native and inverted vesicle preparations: the inverted vesicles had approximately twice the specific activity of native vesicles in the counterflux and K⁺/valinomycin-induced uptake assays. This difference can be largely ascribed to the presence in the normal vesicle preparation of vesicles with a high passive permeability to lactose. Such vesicles are apparently absent from the inverted vesicle preparations.     

Solubilization of a functionally active proline carrier from membranes of Escherichia coli with an organic solvent.

A proline transport carrier was extracted from the membranes of Escherichia coli with acidic n-butanol. Vesicles reconstituted from the butanol extract and E. coli phospholipids and preloaded with K⁺ showed rapid uphill uptake of proline when energy was supplied as a membrane potential introduced by K⁺-diffusion via valinomycin. Proline uptake by the reconstituted vesicles, like that of intact cells and isolated membrane vesicles, was inhibited by 3,4-dehydroproline, SH reagents, and a proton conducting uncoupler. Reconstituted vesicles of mutants defective in proline transport showed little or no proline uptake. The proline carrier was partially purified from the extract and separated from the bulk of phospholipids on Sephadex LH-20.     

Transport of α-aminoisobutyrate by cells and membrane vesicles of Pseudomonas fluorescens

The transport of α-aminoisobutyrate into Pseudomonas fluorescens NCIB 8865 and membrane vesicles prepared from this organism has been studied. Uptake by cells was mediated by two active transport systems with different apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ values, while transport into membrane vesicles was mediated by a single component. The effect of inhibitors on the energy-coupling mechanism for α-aminoisobutyrate transport in these systems suggests that a membrane potential may play a significant role in supporting α-aminoisobutyrate transport. The magnitude of the membrane potential in the vesicle system, and the sensitivity of its generation to inhibitors, has been measured using ¹³⁷Cs in the presence of valinomycin. Direct attempts to demonstrate a proton-symport mechanism for α-aminoisobutyrate transport were negative.     

Helminthosporium maydis T Toxin Decreased Calcium Transport into Mitochondria of Susceptible Corn

The effects of purified Helminthosporium maydis T (HmT) toxin on active Ca²⁺ transport into isolated mitochondria and microsomal vesicles were compared for a susceptible (T) and a resistant (N) strain of corn (Zea mays). ATP, malate, NADH, or succinate could drive ⁴⁵Ca²⁺ transport into mitochondria of corn roots. Ca²⁺ uptake was dependent on the proton electrochemical gradient generated by the redox substrates or the reversible ATP synthetase, as oligomycin inhibited ATP-driven Ca²⁺ uptake while KCN inhibited transport driven by the redox substrates. Purified native HmT toxin completely inhibited Ca²⁺ transport into T mitochondria at 5 to 10 nanograms per milliliter while transport into N mitochondria was decreased slightly by 100 nanograms per milliliter toxin. Malate-driven Ca²⁺ transport in T mitochondria was frequently more inhibited by 5 nanograms per milliliter toxin than succinate or ATP-driven Ca²⁺ uptake. However, ATP-dependent Ca²⁺ uptake into microsomal vesicles from either N or T corn was not inhibited by 100 nanograms per milliliter toxin. Similarly, toxin had no effect on proton gradient formation ([¹⁴C]methylamine accumulation) in microsomal vesicles. These results show that mitochondrial and not microsomal membrane is a primary site of HmT toxin action. HmT toxin may inhibit formation of or dissipate the electrochemical proton gradient generated by substrate-driven electron transport or the mitochondrial ATPase, after interacting with a component(s) of the mitochondrial membrane in susceptible corn.     

Glucose transport in membrane vesicles from Azotobacter vinelandii,: Properties of the glucose carrierin situ

The active transport of d-glucose by membrane vesicles prepared from Azotobactervinelandii strain O is coupled to the oxidation of l-malate. The glucose carrier, but not the energy coupling system of the vesicles, is induced by growth of the cells on d-glucose medium. Vesicles isolated from A. vinelandii grown in the presence of sucrose or acetate accumulate glucose at less than 7% of the rate observed for vesicles from glucose-grown cells. Nevertheless, vesicles from sucrose- or acetate-grown cells transport sucrose or calcium, respectively, in the presence of malate.The transport system expressed in vesicles from glucose-cultured cells is highly specific for d-glucose. Studies of glucose analog uptake and of the competitive effect of analogs reveal that: (i) The glucose carrier is stereospecific. (ii) The affinity of hexoses for the transport system is inversely related to the bulk of substituents on the pyranose ring, especially at the C-1 and C-2 positions, (iii) The most effective competitors, 6-deoxyglucose and 2-deoxyglucose, exhibit affinities only 10–20% that of d-glucose for the transport system, (iv) Phloretin, but not phlorizin, is a competitive inhibitor of glucose transport, having an apparent K_i of 9 μm at pH 7.0. These latter findings suggest a similarity of the glucose transport system of fxA. vinelandii and those of eukaryotes with regard to the glucose carrier.     

Hexose and amino acid transport by chicken embryo fibroblasts infected with temperature-sensitive mutant of rous sarcoma virus: Comparison of transport properties of whole cells and membrane vesicles

The effect of transformation on hexose and amino acid transport has been studied using whole cells and membrane vesicles of chicken embryo fibroblasts infected with the temperature-sensitive mutant of the Rous sarcoma virus, TS-68. In whole cells, TS-68-infected chicken embryo fibroblasts cultured at the permissive temperature (37°C) had a 2-fold higher rate of 2-deoxy-d-glucose uptake than the same cells cultured at the non-permissive temperature (41°C). However, both the non-transformed and transformed cells had comparable rates of α-aminoisobutyric acid transport. Membrane vesicles, isolated from TS-68-infected chicken embryo fibroblasts cultured at 41°C or 37°C, displayed carrier-mediated, intravesicular uptake of d-glucose and α-aminoisobutyric acid. Membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 37°C had an approx. 50% greater initial rate of stereospecific hexose uptake than the membrane vesicles from fibroblasts cultured at 41°C. The two types of membrane vesicle had similar uptake rates of α-aminoisobutyric acid. The results of hexose and amino acid uptake by the membrane vesicles correlated well with those observed with the whole cells. K_m values for stereospecific d-glucose uptake by the membrane vesicles from TS-68-infected chicken embryo fibroblasts cultured at 41 and 37°C were similar, but the V value was greater for the membrane vesicles from TS-68-infected cells cultured at 37°C. Cytochalasin B competitively inhibited stereospecific hexose uptake in both types of membrane vesicle. These findings suggest that the membrane vesicles retained many of the features of hexose and amino acid transport observed in whole cells, and that the increased rate of hexose transport seen in the virallytransformed chicken embryo fibroblasts was due to an increase in the number or availability of hexose carriers.     

l-Cystine transport by papain-treated rat renal brush-border membrane vesicles

In papain-treated rat renal brush-border membrane vesicles, cystine uptake was enhanced under sodium gradient conditions. This effect was not observed when sodium was equilibrated across the vesicle membrane or when sodium was completely absent from the incubation medium. The increased rate of cystine uptake occurred within the first two minutes of incubation and coincided with the period of increased flux of sodium known to occur after papain treatment. Under sodium gradient conditions, the V_max of cystine uptake by treated vesicles was 65% greater while the K_m was 25% lower than the value observed in untreated membranes. The increased cystine uptake after papain treatment occurred when medium cystine was in the electroneutral form. In the absence of a sodium gradient, cystine uptake by control membranes was insensitive to changes in membrane potential and this was unaltered after papain treatment. Exposure of the membranes to papain also resulted in a profound decrease in cystine binding which occurs in native membranes incubated with cystine. The fact that cystine uptake is unchanged under sodium equilibration and even enhanced under sodium gradient conditions suggests that the component of cystine binding is not essential for cystine transport and may represent non-specific binding to membrane proteins.     

Localization of membrane proteins in membrane vesicles of Bacillus subtilis.

Electrons can be transferred to the respiratory chain in whole cells and in membrane vesicles of Bacillus subtilis W 23 by the membrane impermeable electron donor reduced 5-N-methyl-phenazonium-3-sulfonate as efficiently as by the membrane permeable electron donor reduced 5-N-methyl-phenazonium methyl-sulfate, indicating that the respiratory chain is accessible from the outside of the membrane.Succinate is oxidized by whole cells and membrane vesicles at a low rate and does not energize transport of l-glutamate. In the presence of 5-N-methyl-phenazonium-3-sulfonate or 5-N-methyl-phenazonium methyl-sulfate, the oxidation rate and the rate of l-glutamate transport are increased considerably. The electrons are transferred directly from succinic dehydrogenase to these acceptors. Succinic dehydrogenase must therefore be exposed to the outside surface of the membrane in both membrane vesicles and whole cells. The exposure of succinic dehydrogenase to the outside is also indicated by the observations that only a 5% increase in the oxidation rates of succinate-5-N-methyl-phenazonium methylsulfate and succinate-5-N-methyl-phenazonium-3-sulfonate is observed upon solubilization of the membrane with the nonionic detergent Brij-58. Furthermore, treatment of membrane vesicles with trypsin decreases by more than 95% these oxidation rates.NADH is oxidized at a high rate and energizes transport of l-glutamate in whole cells and membrane vesicles effectively. The NADH-oxidation is not effected by trypsin treatment of the vesicles indicating that the oxidation occurs at the inside-surface of the membrane. Trypsin treatment of the vesicles, however, significantly decreases the rate of l-glutamate transport driven by NADH. Therefore component(s) of the transport system for l-glutamate must be effected by trypsin treatment. No apparent differences could be observed in the localization of membrane-bound functions between membrane vesicles and whole cells. This strongly supports the contention that the vesicle membrane of B. subtilis has the same orientation as the cytoplasmic membrane of whole cells.     

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 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.     

Glycodeoxycholate transport in brush border membrane vesicles isolated from rat jejunum and ileum

The transport of the bile salt, glycodeoxycholate, was studied in vesicles derived from rat jejunal and ileal brush border membranes using a rapid filtration technique. The uptake was osmotically sensitive, linearly related to membrane protein and resembled d-glucose transport. In ileal, but not jejunal, vesicles glycodeoxycholate uptake showed a transient vesicle/medium ratio greater than 1 in the presence of an initial sodium gradient. The differences between glycodeoxycholate uptake in the presence and absence of a Na⁺ gradient yielded a saturable transport component. Kinetic analysis revealed a $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ value similar to that described previously in everted whole intestinal segments and epithelial cells isolated from the ileum. These findings support the existence of a transport system in the brush border membrane that: (1) reflects kinetics and characteristics of bile salt transport in intact intestinal preparations, and (2) catalyzes the co-transport of Na⁺ and bile salt across the ileal membrane in a manner analogous to d-glucose transport.     

Selective Inhibition of Active Uptake of Sucrose into Plasma Membrane Vesicles by Polyclonal Sera Directed against a 42 Kilodalton Plasma Membrane Polypeptide

Several polyclonal sera were raised in rabbits and in mice against putative sucrose carrier proteins, i.e. a 42 kilodalton (O Gallet, R Lemoine, C Larsson, S Delrot [1989] Biochim Biophys Acta 978: 56-64) and a 62 kD (KG Ripp, PV Viitanen, WD Hitz, VR Fransceschi [1988] Plant Physiol 88: 1435-1445) polypeptide of the plasma membrane. The effects of these sera on the active uptake of sucrose and of valine into purified plasma membrane vesicles from sugar beet (Beta vulgaris L.) leaves and roots were studied. At a dilution of 1/50, the anti-42 kilodalton sera consistently inhibited sucrose uptake in plasma membranes from leaves or from roots. They had no effect on valine uptake. Under the same experimental conditions, the anti-62 kilodalton sera had no effect on active uptake of sucrose. The data further support the view that a 42 kilodalton polypeptide is a component of the transport system mediating sucrose uptake across the plasma membrane of plant cells.