Characterization of amino acid transport in membrane vesicles from the thermophilic fermentative bacterium Clostridium fervidus.

Amino acid transport was studied in membrane vesicles of the thermophilic anaerobic bacterium Clostridium fervidus. Neutral, acidic, and basic as well as aromatic amino acids were transported at 40 degrees C upon the imposition of an artificial membrane potential (delta psi) and a chemical gradient of sodium ions (delta microNa+). The presence of sodium ions was essential for the uptake of amino acids, and imposition of a chemical gradient of sodium ions alone was sufficient to drive amino acid uptake, indicating that amino acids are symported with sodium ions instead of with protons. Lithium ions, but no other cations tested, could replace sodium ions in serine transport. The transient character of artificial membrane potentials, especially at higher temperatures, severely limits their applicability for more detailed studies of a specific transport system. To obtain a constant proton motive force, the thermostable and thermoactive primary proton pump cytochrome c oxidase from Bacillus stearothermophilus was incorporated into membrane vesicles of C. fervidus. Serine transport could be driven by a membrane potential generated by the proton pump. Interconversion of the pH gradient into a sodium gradient by the ionophore monensin stimulated serine uptake. The serine carrier had a high affinity for serine (Kt = 10 microM) and a low affinity for sodium ions (apparent Kt = 2.5 mM). The mechanistic Na+-serine stoichiometry was determined to be 1:1 from the steady-state levels of the proton motive force, sodium gradient, and serine uptake. A 1:1 stoichiometry was also found for Na+-glutamate transport, and uptake of glutamate appeared to be an electroneutral process.     

Energetics of alanine, lysine, and proline transport in cytoplasmic membranes of the polyphosphate-accumulating Acinetobacter johnsonii strain 210A.

Amino acid transport in right-side-out membrane vesicles of Acinetobacter johnsonii 210A was studied. L-Alanine, L-lysine, and L-proline were actively transported when a proton motive force of -76 mV was generated by the oxidation of glucose via the membrane-bound glucose dehydrogenase. Kinetic analysis of amino acid uptake at concentrations of up to 80 microM revealed the presence of a single transport system for each of these amino acids with a Kt of less than 4 microM. The mode of energy coupling to solute uptake was analyzed by imposition of artificial ion diffusion gradients. The uptake of alanine and lysine was driven by a membrane potential and a transmembrane pH gradient. In contrast, the uptake of proline was driven by a membrane potential and a transmembrane chemical gradient of sodium ions. The mechanistic stoichiometry for the solute and the coupling ion was close to unity for all three amino acids. The Na+ dependence of the proline carrier was studied in greater detail. Membrane potential-driven uptake of proline was stimulated by Na+, with a half-maximal Na+ concentration of 26 microM. At Na+ concentrations above 250 microM, proline uptake was strongly inhibited. Generation of a sodium motive force and maintenance of a low internal Na+ concentration are most likely mediated by a sodium/proton antiporter, the presence of which was suggested by the Na(+)-dependent alkalinization of the intravesicular pH in inside-out membrane vesicles. The results show that both H+ and Na+ can function as coupling ions in amino acid transport in Acinetobacter spp.     

Sodium ion-dependent amino acid transport in membrane vesicles of Bacillus stearothermophilus.

Amino acid transport in membrane vesicles of Bacillus stearothermophilus was studied. A relatively high concentration of sodium ions is needed for uptake of L-alanine (Kt = 1.0 mM) and L-leucine (Kt = 0.4 mM). In contrast, the Na(+)-H(+)-L-glutamate transport system has a high affinity for sodium ions (Kt less than 5.5 microM). Lithium ions, but no other cations tested, can replace sodium ions in neutral amino acid transport. The stimulatory effect of monensin on the steady-state accumulation level of these amino acids and the absence of transport in the presence of nonactin indicate that these amino acids are translocated by a Na+ symport mechanism. This is confirmed by the observation that an artificial delta psi and delta mu Na+/F but not a delta pH can act as a driving force for uptake. The transport system for L-alanine is rather specific. L-Serine, but not L-glycine or other amino acids tested, was found to be a competitive inhibitor of L-alanine uptake. On the other hand, the transport carrier for L-leucine also translocates the amino acids L-isoleucine and L-valine. The initial rates of L-glutamate and L-alanine uptake are strongly dependent on the medium pH. The uptake rates of both amino acids are highest at low external pH (5.5 to 6.0) and decline with increasing pH. The pH allosterically affects the L-glutamate and L-alanine transport systems. The maximal rate of L-glutamate uptake (Vmax) is independent of the external pH between pH 5.5 and 8.5, whereas the affinity constant (Kt) increases with increasing pH. A specific transport system for the basic amino acids L-lysine and L-arginine in the membrane vesicles has also been observed. Transport of these amino acids occurs most likely by a uniport mechanism.     

Active amino acid transport in plasma membrane vesicles from Simian virus 40-transformed mouse fibroblasts. Characteristics of electrochemical Na+ gradient-stimulated uptake.

Selectively permeable membrane vesicles isolated from Simian virus 40-transformed mouse fibroblasts catalyzed Na+ gradient-coupled active transport of several neutral amino acids dissociated from intracellular metabolism. Na+-stimulated alanine transport activity accompanied plasma membrane material during centrifugation in discontinuous dextran 110 gradients. Carrier-mediated transport into the vesicle was demonstrated. When Na+ was equilibrated across the membrane, countertransport stimulation of L-[3H]alanine uptake occurred in the presence of accumulated unlabeled L-alanine, 2-aminoisobutyric acid, or L-methionine. Competitive interactions among neutral amino acids, pH profiles, and apparent Km values for Na+ gradient-stimulated transport into vesicles were similar to those previously described for amino acid uptake in Ehrlich ascites cells, which suggests that the transport activity assayed in vesicles is a component of the corresponding cellular uptake process. Both the initial rate and quasi-steady state of uptake were stimulated as a function of a Na+ gradient (external Na+ greater than internal Na+) applied artificially across the membrane and were independent of endogenous (Na+ + K+)-ATPase activity. Stimulation by Na+ was decreased when the Na+ gradient was dissipated by monensin, gramicidin D or Na+ preincubation. Na+ decreased the apparent Km for alanine, 2-aminoisobutyric acid, and glutamine transport. Na+ gradient-stimulated amino acid transport was electrogenic, stimulated by conditions expected to generate an interior-negative membrane potential, such as the presence of the permeant anions NO3- and SCN-. Na+-stimulated L-alanine transport was also stimulated by an electrogenic potassium diffusion potential (K+ internal greater than K+ external) catalyzed by valinomycin; this stimulation was blocked by nigericin. These observations provide support for a mechanism of active neutral amino acid transport via the "A system" of the plasma membrane in which both a Na+ gradient and membrane potential contribute to the total driving force.     

Bioenergetic properties of alkalophilic Bacillus sp. strain C-59 on an alkaline medium containing K2CO3.

Alkalophilic Bacillus sp. strain C-59 could grow well on an alkaline medium containing K2CO3, as well as Na2CO3, but did not grow on K+-depleted medium. Right-side-out membrane vesicles, energized in the absence of Na+, however, could not take up [14C]methylamine actively, while vesicles equilibrated with 10 mM NaCl actively took up [14C]methylamine. The uptake of [14C]serine was also stimulated by the addition of Na+, and the imposition of a sodium gradient caused transient uptake. These results indicated that an Na+/H+ antiporter was involved in pH homeostasis and generation of an electrochemical sodium gradient in strain C-59 even though a growth requirement for Na+ was not evident. The efflux of 22Na+ from 22Na+-loaded vesicles was more rapid at pH 9.5 than at pH 7 in the presence of an electron donor. On the other hand, vesicles at pH 7 showed more rapid efflux than at pH 9.5 when the antiporter was energized by a valinomycin-mediated K+ diffusion potential (inside negative).     

Functional identification of electrogenic Na+-translocating ATPase in the plasma membrane of the halotolerant microalga Dunaliella maritima

The hypothesis that the primary Na+-pump, Na+-ATPase, functions in the plasma membrane (PM) of halotolerant microalga Dunaliella maritima was tested using membrane preparations from this organism enriched with the PM vesicles. The pH profile of ATP hydrolysis catalyzed by the PM fractions exhibited a broad optimum between pH 6 and 9. Hydrolysis in the alkaline range was specifically stimulated by Na+ ions. Maximal sodium dependent ATP hydrolysis was observed at pH 7.5-8.0. On the assumption that the ATP-hydrolysis at alkaline pH values is related to a Na+-ATPase activity, we investigated two ATP-dependent processes, sodium uptake by the PM vesicles and generation of electric potential difference (Deltapsi) across the vesicle membrane. PM vesicles from D. maritima were found to be able to accumulate 22Na+ upon ATP addition, with an optimum at pH 7.5-8.0. The ATP-dependent Na+ accumulation was stimulated by the permeant NO3- anion and the protonophore CCCP, and inhibited by orthovanadate. The sodium accumulation was accompanied by pronounced Deltapsi generation across the vesicle membrane. The data obtained indicate that a primary Na+ pump, an electrogenic Na+-ATPase of the P-type, functions in the PM of marine microalga D. maritima.     

Trimethylamine oxide respiration of Alteromonas putrefaciens NCMB 1735: Na+-stimulated anaerobic transport in cells and membrane vesicles.

Alteromonas putrefaciens NCMB 1735 required the presence of NaCl for anaerobic growth with serine, cysteine, and formate as substrate and trimethylamine oxide ( TMAO ) as external electron acceptor. When lactate was substrate, the organism grew equally well in the absence of NaCl. Anaerobic uptake of glutamate, aspartate, serine, cysteine, and lactate in resting cells was strongly stimulated with NaCl, and cytoplasmic membrane vesicles energized by electron transfer from formate to TMAO displayed active Na+-dependent uptake of serine. The data suggested that participation in transport processes was the only vital function of Na+ in A. putrefaciens. Formate- and TMAO -dependent anaerobic serine uptake in vesicles was sensitive to the protonophore carbonyl cyanide m-chlorophenyl-hydrazone and the ionophores valinomycin and gramicidin. Transport-active vesicles contained cytochromes of b and c type, and both serine uptake and TMAO reduction with formate were inhibited with the electron transfer inhibitor 2-heptyl-4-hydroxyquinoline N-oxide. Thus, reduction of TMAO to trimethylamine in A. putrefaciens appeared to be coupled with a chemiosmotic mechanism of energy conversion.     

Factors affecting the transport of beta-amino acids in rat renal brush-border membrane vesicles. The role of external chloride

The effect of a variety of ions and other solutes on the accumulation of the beta-amino acid, taurine, was examined in rat renal brush-border membrane vesicles. Initial taurine uptake (15 and 30 s) is sodium-dependent with a typical overshoot. This Na+ effect was confirmed by exchange diffusion and gramicidin inhibition of taurine uptake. External K+ or Li+ do not increase taurine accumulation more than Na+-free mannitol, except that the combination of external K+ and Na+ in the presence of nigericin enhances uptake. Of all anions tested, including more permeant (SCN- and NO3-) or less permeant (SO4(2-)), chloride supported taurine accumulation to a significantly greater degree. Preloading vesicles with choline chloride reduced taurine uptake, suggesting that external Cl- stimulates uptake. Since this choline effect could be related to volume change, due to the slow diffusion of choline into vesicles, brush-border membrane vesicles were pre-incubated with LiCl, LiNO3 and LiSO4. Internal LiCl, regardless of the final Na+ anion mixture, reduced initial rate (15 and 60 s) and peak (360 s) taurine uptake. Internal LiNO3 or LiSO4 with external NaCl resulted in similar or higher values of uptake at 15, 60 and 360 s, indicating a role for external Cl- in taurine uptake in addition to Na+ effect. Although uptake by vesicles is greatest at pH 8.0 and inhibited at acidic pH values (pH less than 7.0), an externally directed H+ gradient does not influence uptake. Similarly, amiloride, an inhibitor of the Na+/H+ antiporter, had no influence on taurine accumulation over a wide variety of concentrations or at low Na+ concentrations. Taurine uptake is blocked only by other beta-amino acids and in a competitive fashion. D-Glucose and p-aminohippurate at high concentrations (greater than 10(-3) M) reduce taurine uptake, possibly by competing for sodium ions, although gramicidin added in the presence of D-glucose inhibits taurine uptake even further. These studies more clearly define the nature of the renal beta-amino acid transport system in brush-border vesicles and indicate a role for external Cl- in this uptake system.     

Na+ translocation by the NADH:ubiquinone oxidoreductase (complex I) from Klebsiella pneumoniae

Complex I is the site for electrons entering the respiratory chain and therefore of prime importance for the conservation of cell energy. It is generally accepted that the complex I-catalysed oxidation of NADH by ubiquinone is coupled specifically to proton translocation across the membrane. In variance to this view, we show here that complex I of Klebsiella pneumoniae operates as a primary Na+ pump. Membranes from Klebsiella pneumoniae catalysed Na+-stimulated electron transfer from NADH or deaminoNADH to ubiquinone-1 (0.1-0.2 micromol min-1 mg-1). Upon NADH or deaminoNADH oxidation, Na+ ions were transported into the lumen of inverted membrane vesicles. Rate and extent of Na+ transport were significantly enhanced by the uncoupler carbonylcyanide-m-chlorophenylhydrazone (CCCP) to values of approximately 0.2 micromol min-1 mg-1 protein. This characterizes the responsible enzyme as a primary Na+ pump. The uptake of sodium ions was severely inhibited by the complex I-specific inhibitor rotenone with deaminoNADH or NADH as substrate. N-terminal amino acid sequence analyses of the partially purified Na+-stimulated NADH:ubiquinone oxidoreductase from K. pneumoniae revealed that two polypeptides were highly similar to the NuoF and NuoG subunits from the H+-translocating NADH:ubiquinone oxidoreductases from enterobacteria.     

Energy transduction in Escherichia coli. The effect of chaotropic agents on energy coupling in everted membrane vesicles from aerobic and anaerobic cultures.

1. The transduction of energy from the oxidation of substrates by the electron transport chain or from the hydrolysis of ATP by the Mg2+-ATPase was measured in everted membrane vesicles of Escherichia coli using the energy-dependent quenching of quinacrine fluorescence and the active transport of calcium. 2. Treatment of everted membranes derived from a wild-type strain with the chaotropic agents guanidine-HC1 and urea caused a loss of energy-linked functions and an increase in the permeability of the membrane to protons, as measured by the loss of respiratory-linked proton uptake. 3. The coupling of energy to the quenching of quinacrine fluorescence and calcium transport could be restored by treatment of the membranes with N,N'-dicyclohyexylcarbodiimide. 4. Chaotrope-treated membranes were found to lack Mg2+-ATPase activity. Binding of crude soluble Mg2+-ATPase to treated membranes restored energy-linked functions. 5. Membranes prepared from a wild-type strain grown under anaerobic conditions in the presence of nitrate retained respiration-linked quenching of quinacrine fluorescence and active transport of calcium after treatment with chaotropic agents. 6. Everted membrane vesicles prepared from an Mg2+-ATPase deficient strain lacked respiratory-driven functions when the cells were grown aerobically but were not distinguishable from membranes of the wild-type when both were grown under anaerobic conditions in the presence of nitrate. 7. It is concluded (a) that chaotropic agents solubilize a portion of the Mg2+-ATPase, causing an increase in the permeability of the membrane to protons and (b) that growth under anaerobic conditions in the presence of nitrate prevents the increase in proton permeability caused by genetic or chemical removal of the catalytic portion of the Mg2+-ATPase.     

Na(+)-coupled alternative to H(+)-coupled primary transport systems in bacteria.

Protons are the most common coupling ions in bacterial energy conversions. However, while many organisms, such as the alkaliphilic Bacilli, employ H(+)-bioenergetics for electron transport phosphorylation, they use Na+ as the coupling ion for transport and flagellar movement. The Na+ gradient required for these bioenergetic functions is established by the secondary Na+/H+ antiporter. In contrast, Vibrio alginolyticus and methanogenic bacteria have primary pumps for both H+ and Na+. They use the proton gradient for ATP synthesis while other, less energy-consuming membrane reactions are powered by the Na+ gradient. In a third mode, some anaerobic bacteria possess decarboxylases acting as primary Na+ pumps. For instance, in Klebsiella pneumoniae, the Na+ gradient established by oxaloacetate decarboxylase is used for the uptake of the growth substrate citrate, and Propionigenium modestum consumes the energy of the Na+ gradient formed by methylmalonyl-CoA decarboxylase directly for ATP synthesis.     

Proton-coupledl-lysine uptake by renal brush border membrane vesicles from mullet (Mugil cephalus)

The uptake of the basic amino acid, L-lysine, was studied in brush border membrane vesicles isolated from the kidney of the striped mullet (Mugil cephalus). The uptake of L-lysine was not significantly stimulated by a Na+ gradient and no overshoot was observed. However, when a proton gradient (pHo = 5.5; pHi = 8.3) was imposed across the membrane in the absence of Na+, uptake was transiently stimulated. When the proton gradient was short circuited by the proton ionophore, carbonylcyanide p-triflouromethoxyphenyl hydrazone, proton gradient-dependent uptake of lysine was inhibited. Kinetics of lysine uptake determined under equilibrium exchange conditions indicated that the Vmax increased as available protons increased (2.1 nmol/min/mg protein at pH 7.5 to 3.7 nmol/min/mg at pH 5.5), whereas the apparent Km (4.9 +/- 0.6 mM) was not altered appreciably. When membrane potential (inside negative) was imposed by K+ diffusion via valinomycin, a similar (but smaller) stimulation of lysine uptake was observed. When the membrane potential and the proton gradient were imposed simultaneously, a much higher stimulation in lysine uptake was shown, and the uptake of lysine was approximately the sum of the components measured separately. These results indicate that the uptake mechanism for basic amino acids is different from that of neutral or acidic amino acids and that the proton-motive force can provide the driving force for the uptake of L-lysine into the isolated brush border membrane vesicles.     

Amino acid transport in the thermophilic anaerobe Clostridium fervidus is driven by an electrochemical sodium gradient.

Amino acid transport was studied in membranes of the peptidolytic, thermophilic, anaerobic bacterium Clostridium fervidus. Uptake of the negatively charged amino acid L-glutamate, the neutral amino acid L-serine, and the positively charged amino acid L-arginine was examined in membrane vesicles fused with cytochrome c-containing liposomes. Artificial ion diffusion gradients were also applied to establish the specific driving forces for the individual amino acid transport systems. Each amino acid was driven by the delta psi and delta mu Na+/F and not by the Z delta pH. The Na+ stoichiometry was estimated from the amino acid-dependent 22Na+ efflux and Na(+)-dependent 3H-amino acid efflux. Serine and arginine were symported with 1 Na+ and glutamate with 2 Na+. C. fervidus membranes contain Na+/Na+ exchange activity, but Na+/H+ exchange activity could not be demonstrated.     

Evidence for tripeptide/H+ co-transport in rabbit renal brush-border membrane vesicles.

L-Phe-L-Pro-L-Ala is a tripeptide which is hydrolysable almost exclusively by dipeptidyl peptidase IV in rabbit renal brush-border membrane vesicles. In order to delineate the mechanism of the transport of an intact tripeptide across the brush-border membrane, we studied the characteristics of the uptake of [3H]Phe-Pro-Ala in membrane vesicles in which the activity of dipeptidylpeptidase IV was completely inhibited by treatment with di-isopropyl fluorophosphate. In these vesicles, uptake of radiolabel from the tripeptide was found to be Na(+)-independent, but was greatly stimulated by an inwardly directed H+ gradient. The H(+)-gradient-dependent radiolabel uptake appeared to be an active process, because the time course of uptake exhibited an overshoot phenomenon. The process was also electrogenic, being stimulated by an inside-negative membrane potential. Under the uptake-measurement conditions there was no detectable hydrolysis of [3H]Phe-Pro-Ala in the incubation medium when di-isopropyl fluorophosphate-treated membrane vesicles were used. Analysis of intravesicular contents revealed that the radiolabel inside the vesicles was predominantly (greater than 90%) in the form of intact tripeptide. These data indicate that the uptake of radiolabel from [3H]Phe-Pro-Ala in the presence of an inwardly directed H+ gradient represents almost exclusively uptake of intact tripeptide. Uphill transport of the tripeptide was also demonstrable in the presence of an inwardly directed Na+ or K+ gradient, but only if nigericin was added to the medium. Under these conditions, nigericin, an ionophore for Na+, K+ and H+, was expected to generate a transmembrane H+ gradient. Uptake of Phe-Pro-Ala in the presence of a H+ gradient was inhibited by di- and tri-peptides, but not by free amino acids. It is concluded that tripeptide/H+ co-transport is the mechanism of Phe-Pro-Ala uptake in rabbit renal brush-border membrane vesicles.     

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.     

The sodium/proton antiport system in a newly isolated alkalophilic Bacillus sp.

The pH homeostasis and the sodium/proton antiport system have been studied in the newly isolated alkalophilic Bacillus sp. strain N-6, which could grow on media in a pH range from 7 to 10, and in its nonalkalophilic mutant. After a quick shift in external pH from 8 to 10 by the addition of Na2CO3, the delta pH (inside acid) in the cells of strain N-6 was immediately established, and the pH homeostatic state was maintained for more than 20 min in an alkaline environment. However, under the same conditions, the pH homeostasis was not observed in the cells of nonalkalophilic mutant, and the cytoplasmic pH immediately rose to pH 10. On the other hand, the results of the rapid acidification from pH 9 to 7 showed that the internal pH was maintained as more basic than the external pH in a neutral medium in both strains. The Na+/H+ antiport system has been characterized by either the effect of Na+ on delta pH formation or 22Na+ efflux in Na+-loaded right-side-out membrane vesicles of strain N-6. Na+- or Li+-loaded vesicles exhibited a reversed delta pH (inside acid) after the addition of electron donors (ascorbate plus tetramethyl-p-phenylenediamine) at both pH 7 and 9, whereas choline-loaded vesicles generated delta pHs of the conventional orientation (inside alkaline). 22Na+ was actively extruded from 22Na+-loaded vesicles whose potential was negative at pH 7 and 9. The inclusion of carbonyl cyanide m-chlorophenylhydrazone inhibited 22Na+ efflux in the presence of electron donors. These results indicate that the Na+/H+ antiport system in this strain operates electrogenically over a range of external pHs from 7 to 10 and plays a role in pH homeostasis at the alkaline pH range. The pH homeostasis at neutral ph was studied in more detail. K+ -depleted cells showed no delta pH (acid out) in the neutral conditions in the absence of K+, whereas these cells generated a delta pH if K+ was present in the medium. This increase of internal pH was accompanied by K+ uptake from the medium. These results suggest that electrogenic K+ entry allows extrusion of H+ from cells by the primary proton pump at neutral pH.     

Electrolyte transport across the basolateral membrane of the parietal cells

The ion-transport properties of the basal lateral membranes of intact isolated parietal cells were studied at the cellular and subcellular level. The presence of an amiloride-sensitive Na+:H+ exchange was demonstrated in cells by proton gradient-driven Na+ uptake and by changes in cell pH as monitored by dimethylcarboxylfluorescein fluorescence both in a fluorimeter and on single isolated cells using a fluorescence microscope and an attached intensified photodiode array spectrophotometer. The presence of the Na+:H+ antiport in vesicles was shown both by intravesicular acidification monitored by acridine orange fluorescent quenching and by proton gradient-dependent Na+ uptake. The presence of Cl-:HCO-3 exchange was determined in intact cells by monitoring changes in cell pH due to Cl- uptake and was shown to be 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid- and 4-acetamido-4'-isothiocyanostilbene-2,2'-disulfonic acid-sensitive. In vesicles, Cl-:HCO-3 exchange was demonstrated by Cl- flux measurement. The apparent affinities for both Cl- and HCO-3 on either side of the membrane were determined to be Km Cli = 20 mM, Km Clout = 17.5 mM, Km HCO-3in = 2.5 mM, and Km HCO-3out = 7.5 mM. A K+ conductance in cells and vesicles was demonstrated by monitoring K+ gradient-dependent 86Rb uptake. No evidence was found for the presence of a Cl- conductance in either cells or vesicles but a H+ conductance was found to be present in vesicles but not in intact cells. In the latter, by determining the effect of either Na+ or Cl- gradients on cell pH and by flux calculations it was concluded that the Cl-:HCO-3 exchange was the major passive flux mechanism for pH regulation in this cell type.     

The role of potassium and chloride ions on the Na+/acidic amino acid cotransport system in rat intestinal brush-border membrane vesicles

The Na+/L-glutamate (L-aspartate) cotransport system present at the level of rat intestinal brush-border membrane vesicles is specifically activated by the ions K+ and Cl-. The presence of 100 mM K+ inside the vesicles drastically enhances the uptake rate and the transient intravesicular accumulation (overshoot) of the two acidic amino acids. It has been demonstrated that the activation of the transport system depended only in the intravesicular K+ concentration and that in the absence of any sodium gradient, an outward K+ gradient was unable to influence the Na+/acidic amino acid transport system. It was also found that Cl- could specifically activate the Na+-dependent L-glutamate (L-aspartate) uptake either in the presence or in the absence of K+. Also the effect of Cl- was observed only in the presence of an inward Na+ gradient and it was noted to be higher when chloride ion was present on both sides of the membrane vesicles. No influence (activation or accumulation) was observed in the absence of the Na+ gradient and in the presence of chloride gradient. L-Glutamate uptake measured in the presence of an imposed diffusion potential and in the presence of K+ or Cl- did not show any translocation of net charge.     

Leucine-proton cotransport system in Chang liver cell

The stimulatory effect of an inward H+ gradient on the Na+-independent L-leucine uptake by the plasma membrane vesicles from Chang liver cells (Mohri, T., Mitsumoto, Y., and Ohyashiki, T. (1983) Biochem. Int. 7, 159-167) has been shown to be due to the increase of the Km value without changing the Vmax value in the transport kinetics. The uptake of leucine by the vesicles is accompanied by intravesicular acidification, and a stimulated uptake of leucine by the countertransport with a high concentration of leucine in the vesicles enhances the acidification. All of these uptakes of leucine and proton and their stimulations are amplified by imposing an inward proton gradient. These results suggest appreciably different affinities of proton for the leucine transport carrier in the inner and outer sides of the plasma membrane. A rapid decrease in the cytoplasmic pH was observed only in the first minute of incubation of intact cells with leucine in Na+-containing medium. But the leucine-dependent decrease of the cytoplasmic pH persisted longer when either Na+ in the medium was replaced by choline or amiloride was present along with Na+. Addition of amiloride to Na+-containing medium was inhibitory on the leucine uptake of cells, without effect on the early phase of glycine uptake. We conclude that Chang liver cells are provided in their plasma membrane with an amino acid-H+ cotransport system, and this is coupled to the amiloride-sensitive Na+/H+ exchange system.     

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.