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.     

Tyrosine transport by membrane vesicles isolated from rat brain

Tyrosine uptake by membrane vesicles derived from rat brain has been investigated. The uptake is dependent on an Na⁺ gradient ([$\text{Na}{}^{\mathrm{+}}\text{]}\text{outside}\text{> [}\text{Na}{}^{\mathrm{+}}\text{]}\text{inside}$). The uptake is transport into an osmotically active space and not a binding artifact as indicated by the effect of increasing the medium osmolarity. The process is stimulated by a membrane potential (negative inside) as demonstrated by the effect of the ionophores valinomycin and carbonyl cyanide $\text{m-}\text{chlorophenylhydrazone}$ and anions with different permeabilities. Kinetic data show that tyrosine is accumulated by two systems with different affinities. Tyrosine uptake is inhibited by the presence of phenylalanine and tryptophan.     

l-Proline transport in Saccharomyces cerevisiae

Transport of l-proline into Saccharomyces cerevisiae K is mediated by two systems, one with a K_T of 31 μM and J_max of 40 nmol · s^?1 · (g dry wt.)^?1, the other with K_T > 2.5 mM and J_max of 150–165 nmol · s^?1 · (g dry wt.)^?1, The kinetic properties of the high-affinity system were studied in detail. It proved to be highly specific, the only potent competitive inhibitors being (i) l-proline and its analogs l-azetidine-2-carboxylic acid, sarcosine, d-proline and 3,4-dehydro-dl-proline, and (ii) l-alanine. The other amino acids tested behaved as noncompetitive inhibitors. The high-affinity system is active, has a sharp pH optimum at 5.8–5.9 and, in an Arrhenius plot, exhibits two inflection points at 15°C and 20–21°C. It is trans-inhibited by most amino acids (but probably only the natural substrates act in a trans-noncompetitive manner) and its activity depends to a considerable extent on growth conditions. In cells grown in a rich medium with yeast extract maximum activity is attained during the stationary phase, on a poor medium it is maximal during the early exponential phase. Some 50–60% of accumulated l-proline can leave cells in 90 min (and more if washing is done repeatedly), the efflux being insensitive to 0.5 mM 2,4-dinitrophenol and uranyl ions, to pH between 3 and 7.3, as well as to the presence of 10–100 mM unlabeled l-proline in the outside medium. Its rate and extent are increased by 1% d-glucose and by 10 μg nystatin per ml.     

Effects of phenothiazines on inhibition of plasma membrane ATPase and hyperpolarization of cell membranes in the yeast Saccharomyces cerevisiae

The transmembranal potential, in Saccharomyces cerevisiae, has been calculated from the distribution of the lipophilic cation tetraphenylphosphonium (TPP⁺) between the intracellular and extracellular water. Trifluoperazine at concentrations of 10 to 50 μM, caused a substantial increase in the membrane potential (negative inside). This increase was observed only in the presence of a metabolic substrate and was eliminated by the addition of the protonophores 2,4-dinitrophenol and sodium azide, removal of glucose, replacement of glucose by the nonmetabolizable analog 3-O-methyl glucose, or by the addition of 100mM KCl. An increase in ⁴⁵CaCl₂ accumulation from solutions of low concentrations (1 μM) was observed under all conditions where membrane potential was increased. Proton ejection activity was monitored by measurements of the rates of the decrease in the pH of unbuffered cell suspensions in the presence of glucose. Trifluoperazine inhibited the changes in medium pH; this inhibition was not the result of an increase in the permeability of cell membranes to protons since in the absence of glucose, trifluoperazine did not cause a change in the rate of pH change generated by proton influx. The activity of plasma membrane ATPase was measured in crude membrane preparations in the presence of sodium azide to inhibit mitochondrial ATPase. Trifluoperazine strongly inhibited the activity of the plasma membrane ATPase. The effect of phenothiazines on transport and on membrane potential reported in this study and in the previous one (Eilam, Y. (1983) Biochim. Biophys. Acta 733, 242–248) were observed only in the presence of a metabolic substrate. The possibility that energy is required for the uptake of phenothiazines into the cells was eliminated by results showing energy-independent uptake of [³H]chlorpromazine. The results strongly suggest that phenothiazines activate energy-dependent K⁺-extrusion pumps, which lead to increased membrane potential. Increased influx of calcium seems to be energized by membrane potential, and therefore stimulated under all conditions where membrane potential is increased. The analog which does not bind to calmodulin, trifluoperazine sulfoxide, had no effect on the cells, but the involvement of calmodulin in the processes altered by trifluoperazine cannot as yet, be determined.     

Uptake and accumulation of Mn2+ and Sr2+ in Saccharomyces cerevisiae

Initial uptake of Mn²⁺ and Sr²⁺ in the yeast Saccharomyces cerevisiae was studied in order to investigate the selectivity of the divalent cation uptake system and the possible involvement of the plasma-membrane ATPase in this uptake. The initial uptake rates of the two ions were not significantly different. This ruled out a direct role of the plasma-membrane ATPase, since this ATPase is specific for Mn²⁺ compared to Sr²⁺. After 1 h uptake, Mn²⁺ had accumulated 10-times more than Sr²⁺. Influx of Mn²⁺ and Sr²⁺ remained unchanged during that time, however. The differences in accumulation level found for Mn²⁺ and Sr²⁺ could be ascribed to a greater efflux of Sr²⁺ as compared with Mn²⁺. Probably this greater efflux of Sr²⁺ was only apparent, since differential extraction of the yeast cells revealed that Mn²⁺ is more compartmentalised than Sr²⁺, giving rise to a lower relative cytoplasmic Mn²⁺ concentration.     

Sodium gradient dependence of proline and glycine uptake in rat renal brush-border membrane vesicles

The sodium-dependent entry of proline and glycine into rat renal brushborder membrane vesicles was examined. The high K_m system for proline shows no sodium dependence. The low K_m system for glycine entry is strictly dependent on a Na⁺ gradient but shows no evidence of the carrier system having any affinity for Na⁺. The low K_m system for proline and high K_m system for glycine transport appear to be shared. Both systems are stimulated by a Na⁺ gradient and appear to have an affinity for the Na⁺. The effect of decreasing the Na⁺ concentration in the ionic gradient is to alter the K_m for amino acid entry and, at low Na⁺ concentrations, to inhibit the V for glycine entry.     

Turnover of protein components of the plasma membrane of Saccharomyces cerevisiae

The peptide composition of plasma membrane in Saccharomyces cerevisiae cells growing at different temperatures between 18 and 38°C was studied using SDS-polyacrylamide gel electrophoresis. Stability of the proteins, both qualitative and quantitative, was observed at the tested temperatures. Treatment for 2 h with cycloheximide decreased by about 50% the amount of a 80 kDa membrane peptide at 18, 23, 28 and 33°C, with no other apparent effects. At 38°C the 80 kDa peptide was not affected by the presence of the drug. Addition of tunicamycin to cultures at concentrations partially inhibitory to growth caused a large accumulation of the 80 kDa peptide in the plasma membrane, which cycloheximide did not modify. Pulse-chase experiments indicated a low rate of turnover of total plasma membranes in cells growing at 18 and 28°C. In contrast, at 38°C about 50% of the radioactivity in plasma membranes disappeared after a 2 h chase. The 80 kDa protein band was the only one with significant differential decay.     

The influence of uncouplers on facilitated diffusion of sorbose in Saccharomyces cerevisiae

Sorbose uptake in Saccharomyces cerevisiae, strain Delft 1, proceeds via mediated passive transport. In the cell sorbose is distributed in at least two compartments. Efflux studies showed that sorbose uptake in one of these compartments is not readily reversible. Uncouplers of oxidative phosphorylation inhibit both transport velocity and steady-state uptake level. It could be shown that these two effects are caused by different modes of action of the uncouplers. None of these two effects could be ascribed to changes of the electrochemical H⁺ gradient or of the intracellular pH. It is suggested that the inhibition of uptake velocity is caused by binding of the uncoupler to the sorbose translocator, thus lowering the transport activity. The uncoupler binding site is probably located at the intracellular fragment of the carrier. The second effect, reduction of the steady-state uptake level, is probably due to blocking of sorbose influx into the compartment that exhibits poor reversibility.     

Derepression of the high-affinity phosphate uptake in the yeast Saccharomyces cerevisiae

Phosphate starvation derepresses a high-affinity phosphate uptake system in Saccharomyces cerevisiae strain A294, while in the same time the low-affinity phosphate uptake system disappears. The protein synthesis inhibitor cycloheximide prevents the derepression, but has no effect as soon as the high-affinity system is fully derepressed. Two other protein synthesis inhibitors, lomofungin and 8-hydroxyquinoline, were found to interfere also with the low-affinity system and with Rb⁺ uptake. After incubation of the yeast cells in the presence of phosphate the high-affinity system is not derepressed, but the $\text{V}{}_{\mathrm{<mtext>max</mtext>}}$ of the low-affinity system has decreased for about 35%. Phosphate supplement after derepression causes the high-affinity system to disappear to a certain extent while in the meantime the low-affinity system reappears. The results are compared with those found in the yeast Candida tropicalis for phosphate uptake.     

Solubilization and reconstitution of the glucose transport system from Saccharomyces cerevisiae

The glucose transport system from Saccharomyces cerevisiae was solubilized from isolated plasma membranes by the nonionic detergent, octylglucoside. The transport system was reconstituted into proteoliposomes with removal of detergent from the extract by dialysis, followed by the addition of asolectin liposomes to the dialyzed proteins with a freeze-thaw and brief bath-sonication step. The reconstituted proteoliposomes exhibit specific carrier-mediated facilitated diffusion of d-glucose, including stimulated equilibrium exchange and influx counterflow. Furthermore, the reconstituted facilitated diffusion system shows substrate specificities similar to those of the intact cell d-glucose transport system.     

Na+/solute symport in membrane vesicles from Bacillus alcalophilus

The characteristics of α-aminoisobutyric acid translocation were examined in membrane vesicles from obligately alkalophilic Bacillus alcalophilus and its non-alkalophilic mutant derivative, KM23. Vesicles from both strains exhibited α-aminoisobutyric acid uptake upon energization with ascorbate and N,N,N′,N′-tetramethyl-p-phenylenediamine. The presence of Na⁺ caused a pronounced reduction in the Km for α-aminoisobutyric acid in wild-type but not KM23 vesicles; the maximum velocity (V) was unaffected in vesicles from both strains. Passive efflux and exchange of α-aminoisobutyric acid from wild-type vesicles were Na⁺-dependent and occurred at comparable rates (with efflux slightly faster than exchange). This latter observation suggests that the return of the unloaded carrier to the inner surface is not rate-limiting for efflux. The rates of α-aminoisobutyric acid efflux and exchange were also comparable in KM23 vesicles, but were Na⁺-independent. Furthermore, in vesicles from the two strains, both efflux and exchange were inhibited by generation of a transmembrane electrochemical gradient of protons, outside positive. This suggests that the ternary complex between solute, carrier, and coupling ion bears a positive charge in both strains even though the coupling ion is changed. Evidence from experiments with an alkalophilic strain that was deficient in l-methionine transport indicated that the porters, i.e., the solute-translocating elements, used by non-alkalophilic mutants are not genetically distinct from those used by the alkalophilic parent; that is, the change in coupling ion cannot be explained by the expression of a completely new set of Na⁺-independent, H⁺-coupled porters upon mutation of B. alcalophilus to non-alkalophily.     

Transport and metabolic effects of α-aminoisobutyric acid in saccharomyces cerevisiae

α-Aminoisobutyric acid is actively transported into yeast cells by the general amino acid transport system. The system exhibits a K_m for α-aminoisobutyric acid of 270 μM, a V_max of 24 nmol/min per mg cells (dry weight), and a pH optimum of 4.1–4.3. α-Aminoisobutyric acid is also transported by a minor system(s) with a V_max of 1.7 nmol/min per mg cells. Transport occurs against a concentration gradient with the concentration ratio reaching over 1000:1 (in/out). The α-aminoisobutyric acid is not significantly metabolized or incorporated into protein after an 18 h incubation. α-Aminoisobutyric acid inhibits cell growth when a poor nitrogen source such as proline is provided but not with good nitrogen sources such as NH₄⁺. During nitrogen starvation α-aminoisobutric acid strongly inhibits the synthesis of the nitrogen catabolite repression sensitive enzyme, asparaginase II. Studies with a mutant yeast strain (GDH-CR) suggest that α-aminoisobutyric acid inhibition of asparaginase II synthesis occurs because α-aminoisobutyric acid is an effective inhibitor of protein synthesis in nitrogen starved cells.     

Stimulation of dehydrogenase synthesis by cadmium in a cadmium-resistant strain of Saccharomyces cerevisiae

The activity of dehydrogenase in Saccharomyces cerevisiae was estimated by reduction of 2,3,5-triphenyltetrazolium chloride. By the adaptation of yeast to cadmium, the high activity of dehydrogenase was observed. Furthermore, the activity of dehydrogenase in Cd-resistant cells was increased by growing in medium containing CdSO₄. However, the activity of dehydrogenase was inhibited by the addition of CdSO₄ to the reaction mixture. The activity of dehydrogenase in Cd-sensitive cells was increased slightly by incubation with low concentrations of CdSO₄.High activity of dehydrogenase in Cd-resistant cells was completely negated by the addition of cycloheximide to the incubation medium. The increase of dehydrogenase activity is due partly to de novo synthesis of protein.     

Properties and regulation of synthesis of two ferredoxins from Rhodopseudomonas capsulata

Two ferredoxins from nitrogen-fixing cells of the phototrophic bacterium Rhodopseudomonas capsulata, strain B10, are purified to a homogeneous state and characterized. The molecular mass of ferredoxin I is about 12 kDa and that of ferredoxin II, 18 kDa. Ferredoxin I contains 8 Fe²⁺ and 8 S^2?; ferredoxin II has 4 Fe²⁺ and 4 S^2? per molecule. The redox potential of ferredoxin I is about ?270 mV and that of ferredoxin II ?419 mV. Ferredoxin I is more labile to the action of O₂, O^?₂, H₂O₂ and heating. The ferredoxins are also different in their absorption and EPR spectra, amino acid composition and electron-transfer activity to Rps. capsulata nitrogenase: both C₂H₂ reduction and H₂ evolution by Rps. capsulata nitrogenase proceed faster in the presence of ferredoxin I than in case of ferredoxin II. Synthesis of ferredoxin I takes place only in Rps. capsulata nitrogen-fixing cells grown in light under anaerobic conditions whereas ferredoxin II formation does not depend on the source of nitrogen or the growth medium, though the amount of ferredoxin II varies with the growth conditions. Its highest level has been found in the cells grown in lactate-limited medium in the presence of CO₂ and light or in the presence of glutamate in darkness under anaerobic conditions.     

The plasma membrane of Saccharomyces cerevisiae Molecular structure and asymmetry

The molecular structure of the plasma membrane of the haploid strain Saccharomyces cerevisiae X-2180 1A has been studied by means of sodium dodecyl sulfate polyacrylamide gel electrophoresis. Protein and glycoprotein components have been identified and their apparent M_r determined. A glycoprotein showing an apparent M_r of 27 500 has been shown to be the main structural component. Treatment of the cells with cycloheximide prior to plasma membrane isolation resulted in a redistribution of the relative amounts of each protein band and a drastic reduction in the number of Schiff positive bands. It is postulated that treatment with this drug rids the plasma membrane of glycoprotein secretory components which are in the process of being secreted to the periplasmic space, thus allowing the study of the basic structural components of the organelle. The electrophoretic pattern of the internal membranes revealed close similarities with that of the plasma membrane and though two-dimensional electrophoresis might disclose greater differences, these similarities suggest a common origin for most of the components of both membranous systems. Finally, radioiodination techniques have been used in studying the asymmetric disposition of some of the components of the plasma membrane. At least five polypeptides were identified as located to the outer layer of the plasma membrane and two more glycopeptides were shown to span across the bilayer.     

Na+ -dependent proline transport in isolated membrane vesicles from the L6 muscle cell line. Stimulation of uptake by intravesicular proline

Membrane vesicles of L6 myoblasts were prepared in order to study the amino acid transport system A. The role of the membrane in the adaptive response of transport to amino acid-supplementation was assessed. The membranes, prepared by N2 cavitation, displayed Na+ (but not K+)-dependent L-proline uptake. An overshoot of L-[3H]proline uptake was observed after exposure of the vesicles to an inward Na+ gradient. Isolated membrane vesicles loaded with 50 microM proline displayed countertransport (stimulation of proline uptake). It is concluded that the adaptive decrease of proline uptake observed in amino acid-supplemented cells cannot be accounted for by trans-inhibition of transport.     

Amino acid uptake in plasma membrane vesicles isolated from proliferating tumor cells and tissues

Summary The transport of L-alanine, a natural substrate of system A, across plasma membrane vesicle preparations has been studied in the early stages of rat DENA-PH hepato-carcinogenesis and in a very undifferentiated rat ascites hepatoma cell line (Yoshida AH-130) in the exponential and stationary phase of growth.Kinetic analyses indicated an increase of the V_max value in DENA-PH-treated rats 30 h after partial hepatectomy as well as in exponential growing Yoshida ascites cells. In DENA-PH-treated rats the Km value was drastically reduced 7 and 60 days after surgery, when enzyme-altered hyperplastic and preneoplastic lesions were present in rat liver. Drastically reduced Km values were also found in Yoshida ascites cells.The results suggest that an altered alanine transporter might take place in liver plasma membranes from carcinogen-treated rats. This appears to occur also in an established tumor cell line, grown in vivo.Abbreviations AAF 2-acetylaminofluorene - DENA diethylnitrosamine - PH partial hepatectomy - PMSF phenylmethanesulfonyl fluoride     

Soluble and membrane-bound thiamine-binding proteins from Saccharomyces cerevisiae

Previous communications from this laboratory have indicated that there exists a thiamine-binding protein in the soluble fraction of Saccharomyces cerevisiae which may be implicated to participate in the transport system of thiamine in vivo.In the present paper it is demonstrated that both activities of the soluble thiamine-binding protein and thiamine transport in S. cerevisiae are greatest in the early-log phase of the growth and decline sharply with cell growth. The soluble thiamine-binding protein isolated from yeast cells by conventional methods containing osmotic shock treatment appeared to be a glycoprotein with a molecular weight of 140 000 by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The apparent $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of the binding for thiamine was 29 nM which is about six fold lower than the apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ (0.18 μM) of thiamine transport. The optimal pH for the binding was 5.5, and the binding was inhibited reversibly by 8 M urea but irreversibly by 8 M urea containing 1% 2-mercaptoethanol. Several thiamine derivatives and the analogs such as pyrithiamine and oxythiamine inhibited to similar extent both the binding of thiamine and transport in S. cerevisiae, whereas thiamine phosphates, 2-methyl-4-amino-5-hydroxymethylpyrimidine and $\text{O-}\text{benzoylthiamine}$ disulfide did not show similarities in the effect on the binding and transport in vivo. Furthermore, it was demonstrated by gel filtration of sonic extract from the cells that a thiamine transport mutant of S. cerevisiae (PT-R₂) contains the soluble binding protein in a comparable amounts to that in the parent strain, suggesting that another protein component is required for the actual translocation of thiamine in the yeast cell membrane. On the other hand, the membrane fraction prepared from S. cerevisiae showed a thiamine-binding activity with apparent $\text{K}{}_{\mathrm{<mtext>d</mtext>}}$ of 0.17μM at optimal pH 5.0 which is almost the same with the apparent $\text{K}{}_{\mathrm{<mtext>m</mtext>}}$ for the thiamine transport system. The membrane-bound thiamine-binding activity was not only repressible by exogenous thiamine in the growth medium, but as well as thiamine transport it was markedly inhibited by both pyrithiamine and $\text{O-}\text{benzoylthiamine}$ disulfide. In addition, it was found that membrane fraction prepared frtom PT-R₂ has the thiamine-binding activity of only 3% of that from the parent strain of S. cerevisiae.These results strongly suggest that membrane-bound thiamine-binding protein may be directly involved in the transport of thiamine in S. cerevisiae.