Biotin uptake mechanisms in brush-border and basolateral membrane vesicles isolated from rabbit kidney cortex

Biotin transport was studied using brush-border and basolateral membrane vesicles isolated from rabbit kidney cortex. An inwardly directed Na+ gradient stimulated biotin uptake into brush-border membrane vesicles and a transient accumulation of the anion against its concentration gradient was observed. In contrast, uptake of biotin by basolateral membrane vesicles was found to be Na+-gradient insensitive. Generation of a negative intravesicular potential by valinomycin-induced K+ diffusion potentials or by the presence of Na+ salts of anions of different permeabilities enhanced biotin uptake by brush-border membrane vesicles, suggesting an electrogenic mechanism. The Na+ gradient-dependent uptake of biotin into brush-border membrane vesicles was saturable with an apparent Km of 28 microM. The Na+-dependent uptake of tracer biotin was significantly inhibited by 50 microM biotin, and thioctic acid but not by 50 microM L-lactate, D-glucose, or succinate. Finally, the existence in both types of membrane vesicles of a H+/biotin- cotransport system could not be demonstrated. These results are consistent with a model for biotin reabsorption in which the Na+/biotin- cotransporter in luminal membranes provides the driving force for uphill transport of this vitamin.     

Generation of Na+ electrochemical potential by the Na+-motive NADH oxidase and Na+/H+ antiport system of a moderately halophilic Vibrio costicola

Cells of Vibrio costicola at pH 8.5 generate both membrane potential (inside negative) and delta pH (inside acidic) in the presence of a proton conductor, carbonyl cyanide m-chlorophenylhydrazone (CCCP). The generation of CCCP-resistant membrane potential was inhibited by 2-heptyl-4-hydroxyquinoline-N-oxide that is known to inhibit the Na+-motive NADH oxidase of Vibrio alginolyticus. NADH oxidase, but not lactate oxidase, of inverted membrane vesicles prepared from V. costicola required Na+ for a maximum activity and was inhibited by 2-heptyl-4-hydroxyquinoline-N-oxide. By the oxidation of NADH, inverted membrane vesicles generated concentration gradients of Na+ across the membrane, whose magnitude was always larger than that of delta pH by about 50 mV. In contrast, magnitudes of delta pH and Na+ concentration gradients generated by the oxidation of lactate were similar. Na+ translocation in the presence of lactate was inhibited by CCCP but little affected by valinomycin. On the other hand, Na+ translocation in the presence of NADH was resistant to CCCP and stimulated by valinomycin. Amiloride, an inhibitor for a eucaryotic Na+/H+ antiport system, inhibited the lactate-dependent Na+ translocation but had little effect on the NADH-dependent Na+ translocation. These results indicate that a primary event of lactate oxidation is the translocation of H+, which then causes the generation of Na+ concentration gradients via the secondary Na+/H+ antiport system. We conclude that the NADH oxidase of V. costicola translocates Na+ as an immediate result of respiration, leading to the generation of Na+ electrochemical potential.     

A proton gradient, not a sodium gradient, is the driving force for active transport of lactate in rabbit intestinal brush-border membrane vesicles.

An inward-directed H+ gradient markedly stimulated lactate uptake in rabbit intestinal brush-border membrane vesicles, and uphill transport against a concentration gradient could be demonstrated under these conditions. Uptake of lactate was many-fold greater in the presence of a H+ gradient than in the presence of a Na+ gradient. Moreover, there was no evidence for uphill transport of lactate in the presence of a Na+ gradient. The H+-gradient-dependent stimulation of lactate uptake was not due to the effect of a H+-diffusion potential. The uptake process in the presence of a H+ gradient was saturable [Kt (concn. giving half-maximal transport) for lactate 12.7 +/- 4.5 mM] and was inhibited by many monocarboxylates. It is concluded that a H+ gradient, not a Na+ gradient, is the driving force for active transport of lactate in rabbit intestinal brush-border membrane vesicles.     

Polarized expression of different monocarboxylate transporters in rat medullary thick limbs of Henle.

Extracellular lactic acid is a major fuel for the mammalian medullary thick ascending limb (MTAL), whereas under anoxic conditions, this nephron segment generates a large amount of lactic acid, which needs to be excreted. We therefore evaluated, at both the functional and molecular levels, the possible presence of monocarboxylate transporters in basolateral (BLMVs) and luminal (LMVs) membrane vesicles isolated from rat MTALs. Imposing an inward H(+) gradient induced the transient uphill accumulation of L-[(14)C]lactate in both types of vesicles. However, whereas the pH gradient-stimulated uptake of L-[(14)C]lactate in BLMVs was inhibited by anion transport blockers such as alpha-cyano-4-hydroxycinnamate, 4,4'-diisothiocyanatostilbene-2, 2'-disulfonic acid (DIDS), and furosemide, it was unaffected by these agents in LMVs, indicating the presence of a L-lactate/H(+) cotransporter in BLMVs, but not in LMVs. Under non-pH gradient conditions, however, the uptake of L-[(14)C]lactate in LMVs was transstimulated 100% by L-lactate, but by only 30% by D-lactate. Furthermore, this L-lactate self-exchange was markedly inhibited by alpha-cyano-4-hydroxycinnamate and DIDS and almost completely by 1 mM furosemide, findings consistent with the existence of a stereospecific carrier-mediated lactate transport system in LMVs. Using immunofluorescence confocal microscopy and immunoblotting, the monocarboxylate transporter (MCT)-2 isoform was shown to be specifically expressed on the basolateral domain of the rat MTAL, whereas the MCT1 isoform could not be detected in this nephron segment. This study thus demonstrates the presence of different monocarboxylate transporters in rat MTALs; the basolateral H(+)/L-lactate cotransporter (MCT2) and the luminal H(+)-independent organic anion exchanger are adapted to play distinct roles in the transport of monocarboxylates in MTALs.     

Characterization of Na+-dependent phosphate transport in cardiac sarcolemmal vesicles

Pi uptake by purified bovine cardiac sarcolemmal vesicles was stimulated by an inwardly directed Na+ gradient, but not by such gradients of K+, Rb+, Li+, and choline. When Na+ was present both inside and outside the vesicles, or when Na+ gradient was dissipated by monensin, the Na+-dependent Pi uptake increased with time, reached a peak, and then declined approaching a steady state. The initial rate of Na+-dependent Pi uptake was a saturable function of Pi concentration (Km = 0.5 mM). These findings indicate the existence of a Na+,Pi-cotransporter in the sarcolemma. The Na+-activation curve of the Pi uptake exhibited positive cooperativity, suggesting the requirement for multiple Na+ binding to the functional unit of the carrier. The initial rate of Na+-dependent Pi uptake decreased as extra-vesicular pH increased in the range of 5.5-8.7. The uptake rate increased under conditions that are known or expected to generate an inside-negative membrane potential, indicating that Pi uptake is accompanied by the uptake of positive charge. These results suggest the electrogenic cotransports of two Na+ and one H2PO4-. We conclude that this cotransporter catalyzes the secondary active transport of Pi across the cardiac plasma membrane and regulates myocardial energy metabolism. We also suggest that the cotransporter may control intracellular Na+ and thus be involved in the regulation of trans-sarcolemmal Ca2+ movement and cardiac contractility.     

Kinetic asymmetry of renal Na+-L-lactate cotransport. Characteristic parameters and evidence for a ping pong mechanism of the trans-stimulating exchange by pyruvate

Brush border vesicles prepared from horse renal cortex were used to study the kinetic properties of the Na+-L-lactate carrier on the outer and inner faces of the membrane. Two methods were applied for these measurements (in the absence of an electrical gradient): a direct method using influx and efflux kinetics, and an indirect method applied to trans-stimulated influx kinetics using membrane vesicles preloaded with various pyruvate concentrations (the latter enabled us to observe simultaneously the inner and outer carrier properties). Kinetic parameters obtained by the first method have shown that under sodium lactate chemical gradient, the carrier efficiency (estimated by the ratio of k = Vm/Km) is higher for the influx than efflux, a mechanism indicating a kinetic asymmetry of the transport. This difference remains at chemical equilibrium of solute concentration. The similarity of outer and inner affinity of sodium permits one to conclude that the kinetic asymmetry of the sodium lactate transport is related to the lactate-carrier interaction and not to that of the sodium-carrier. The second method using the pyruvate trans-activation effect (under sodium chemical equilibrium) has shown an affinity of lactate (Kt(out) = 1.1 mM), about 15 times higher for the carrier in the extracellular orientation than that of pyruvate for the carrier in the intracellular orientation (Kt(pyr) = 36 mM). This method has demonstrated a ping pong mechanism for the trans-activation exchange which accounts for a selective pore carrier model like a gated channel. These asymmetric properties are related to the AS glide sequential model (A and S being Na+ and lactate, respectively) proposed previously for the Na-L-lactate cotransport and to a different accessibility of the organic solute but not of the sodium on the two membrane faces.     

Monoclonal antibodies against the renal Na+-D-glucose cotransporter. Identification of antigenic polypeptides and demonstration of functional coupling of different Na+-cotransport systems

Eight monoclonal antibodies are described which are directed against the renal Na+-D-glucose cotransporter. In porcine renal brush-border membranes, the antibodies either bind to one or to three polypeptides which have been identified as components of the Na+-D-glucose cotransporter (Neeb, M., Kunz, U., and Koepsell, H., (1987) J. Biol. Chem. 262, 10718-10727). Their molecular weights and isoelectric points are 75,000 and pH 5.5, 60,000 and pH 5.2, and 47,000 and pH 5.4. Six antibodies were able to influence Na+-dependent D-glucose uptake and/or Na+-dependent high affinity phlorizin binding. In the presence of Na+, the binding of all antibodies to native membrane proteins was altered by D-glucose but not by D-mannose. Since this effect was observed with D-glucose concentrations less than 1 x 10(-8) M, a high affinity D-glucose-binding site on the D-glucose transporter has been implied. Some of the antibodies probably interact also with other Na+-coupled transporters since their binding was altered by micromolar concentrations of L-lactate, L-alanine, or L-glutamate but not by the nontransported control substances D-alanine and D-glutamate. L-lactate increased the binding of one antibody in the absence but not in the presence of D-glucose. Effects of L-lactate and L-alanine on the binding of another antibody were only observed when D-glucose was present. Thus, some epitopes on the Na+-D-glucose cotransporter are altered by D-glucose and also by substrates of other Na+ cotransporters. This finding suggests functional coupling of different Na+-cotransport systems.     

Generation of the electrochemical potential of Na+ by the Na+-motive NADH oxidase in inverted membrane vesicles of Vibrio alginolyticus

Inverted membrane vesicles prepared from Vibrio alginolyticus generated a membrane potential (positive inside) and accumulated Na+ by the oxidation of NADH. Generation of the membrane potential required Na+ and was inhibited by 2-heptyl-4-hydroxyquinoline N-oxide, a specific inhibitor of the Na+-dependent NADH oxidase. Collapse of the membrane potential by valinomycin stimulated the uptake of Na+. In contrast, accumulation of H+ was not detected under all the conditions tested. These results suggest that only Na+ is translocated by the Na+-dependent NADH oxidase of V. alginolyticus.     

Sensitivity of renal brush-border Na+-cotransport systems to anions

The effect of anions on Na+-cotransport of succinate, lactate, glucose, and phenylalanine was studied under voltage clamped conditions in brush-border membrane vesicles prepared from rabbit renal cortex. The initial rate of succinate uptake varied by an order of magnitude depending on the anion: the highest rates were obtained with fluoride and gluconate, and the lowest with iodide. The anion sequence corresponded with the inverse of the anion hydration energies. The kinetics of succinate uptake were measured in the presence of fluoride and chloride. There was no difference in the maximal rates of uptake, but the Kt in fluoride (0.30 mM) was less than half that in chloride (0.70 mM), i.e. Cl- behaved as a competitive inhibitor of succinate transport with a Ki of 150 mM. The uptake of L-lactate, D-glucose and L-phenylalanine was less sensitive to anions, and there was no correlation with hydration energies. We conclude that the anion effects on sugar and amino acid uptakes measured under open-circuit conditions are largely due to variations in membrane potential, but in the case of the dicarboxylate transporter anions behave as weak competitive inhibitors. The specificity of the anion inhibition suggests that the dicarboxylate binding sites have a weak field strength relative to water.     

A monoclonal antibody against a Na(+)-L-glutamate cotransporter from rat brain.

A monoclonal mouse IgM antibody (Z8E9) was raised against the Na(+)-L-glutamate cotransporter from rat brain. In a preparation of brain plasma membrane vesicles, Z8E9 binds specifically to a polypeptide with an apparent molecular weight of 70,000 and inhibits Na+ gradient-dependent L-glutamate cotransport (up to 50%) in brain membrane vesicles. In the membrane vesicles, the antibody does not alter the membrane permeability for Na+ and K+ nor the Na+ gradient-dependent uptake of gamma-aminobutyric acid. Kinetic experiments showed that Z8E9 does not alter the K0.5 values for L-glutamate and Na+ activation of L-glutamate transport. However, an apparent cooperativity observed for L-glutamate activation was increased, and the Vmax of L-glutamate transport was decreased. Immunostaining of rat cerebellum identified antigenic sites of Z8E9 in Golgi epithelial cells and astrocytes (by light and electron microscopy), whereas no labeling at nerve terminals was detected. The data suggest that a component of a Na(+)-L-glutamate cotransporter subtype has been identified that is specific for glia cells in brain.     

Uptake of L-(+)lactate by cell membrane (luminal and contraluminal) isolated from rat small intestine microvilli

L-lactate uptake was measured in vesicles formed by intestinal brush border and baso-lateral membranes, using a rapid filtration technique. In the presence of a Na+ gradient directed into the vesicle, L-lactate can be transiently accumulated in brush border vesicles, but not in baso-lateral ones. The transient L-lactate accumulation does not occur in the presence of a KCl gradient. alpha-cyanocinammic acid strongly inhibits L-lactate uptake in brush border vesicles, but not in baso-lateral ones. These results support the existence of a carrier mediated, Na+ dependent, transport of L-lactate across the brush border membrane.     

HCO3- transport in basolateral membrane vesicles isolated from rat renal cortex

The mechanism of HCO3- translocation across the proximal tubule basolateral membrane was investigated by testing for Na+-HCO3- cotransport using isolated membrane vesicles purified from rat renal cortex. As indicated by 22Na+ uptake, imposing an inwardly directed HCO3- concentration gradient induced the transient concentrative accumulation of intravesicular Na+. The stimulation of basolateral membrane vesicle Na+ uptake was specifically HCO3(-)-dependent as only basolateral membrane-independent Na+ uptake was stimulated by an imposed hydroxyl gradient in the absence of HCO3-. No evidence for Na+-HCO3- cotransport was detected in brush border membrane vesicles. Charging the vesicle interior positive stimulated net intravesicular Na+ accumulation in the absence of other driving forces via a HCO3(-)-dependent pathway indicating the flow of negative charge accompanies the Na+-HCO3- cotransport event. Among the anion transport inhibitors tested, 4-4'-diisothiocyanostilbene-2,2'-disulfonic acid demonstrated the strongest inhibitor potency at 1 mM. The Na+-coupled transport inhibitor harmaline also markedly inhibited HCO3- gradient-driven Na+ influx. A role for carbonic anhydrase in the mechanism of Na+-HCO3- cotransport is suggested by the modest inhibition of HCO3- gradient driven Na+ influx caused by acetazolamide. The imposition of Cl- concentration gradients had a marked effect on HCO3- gradient-driven Na+ influx which was furosemide-sensitive and consistent with the operation of a Na+-HCO3- for Cl- exchange mechanism. The results of this study provide evidence for an electrogenic Na+-HCO3- cotransporter in basolateral but not microvillar membrane vesicles isolated from rat kidney cortex. The possible existence of an additional basolateral membrane HCO3(-)-translocating pathway mediating Na+-HCO3- for Cl- exchange is suggested.     

Voltage and cosubstrate dependence of the Na-HCO3 cotransporter kinetics in renal proximal tubule cells.

The voltage dependence of the kinetics of the sodium bicarbonate cotransporter was studied in proximal tubule cells. This electrogenic cotransporter transports one Na+, three HCO3-, and two negative charges. Cells were grown to confluence on a permeable support, mounted on a Ussing-type chamber, and permeabilized apically to small monovalent ions with amphotericin B. The steady-state, di-nitro-stilbene-di-sulfonate-sensitive current was shown to be sodium and bicarbonate dependent and therefore was taken as flux through the cotransporter. Voltage-current relations were measured as a function of Na+ and HCO3- concentrations between -160 and +160 mV under zero-trans and symmetrical conditions. The kinetics could be described by a Michaelis-Menten behavior with a Hill coefficient of 3 for HCO3- and 1 for Na+. The data were fitted to six-state ordered binding models without restrictions with respect to the rate-limiting step. All ordered models could quantitatively account for the observed current-voltage relationships and the transinhibition by high bicarbonate concentration. The models indicate that 1) the unloaded transporter carries a positive charge; 2) the binding of cytosolic bicarbonate to the transporter "senses" 12% of the electric field in the membrane, whereas its translocation across the membrane "senses" 88% of the field; 3) the binding of Na+ to the cotransporter is voltage independent.     

Insulin regulates Na+/glucose cotransporter activity in rat small intestine

In order to examine the involvement of insulin in the activity of Na+/glucose cotransporter in rat small intestine, we compared Na(+)-dependent uptake of D-glucose by brush-border membrane vesicles prepared from control, streptozotocin-induced diabetic, insulin-treated diabetic and starved diabetic rats. In four groups, the uptake of D-glucose showed a transient overshoot in the presence of Na+ gradient between medium and vesicles (medium greater than vesicles). The overshoot magnitude was increased (1.8-fold of controls) in diabetic brush border membrane vesicles and recovered to the control level by the treatment of diabetic rats with insulin. In contrast, increased uptake of D-glucose in diabetic rats was not recovered by the starvation of diabetic rats although the blood glucose level was the same as that of controls. Furthermore, we attempted to examine phlorizin binding activities among four groups. Scatchard analysis indicated that phlorizin binding to diabetic brush border membrane vesicles was increased (1.6-fold of controls) without a change of the affinity for phlorizin as compared with controls. Increased binding of phlorizin to diabetic brush border membrane vesicles was also recovered to the control level by the treatment of diabetic rats with insulin, but not by starvation. These results suggested that the increased activity of Na+/glucose cotransporter in diabetic rats was due to the increase of the number of cotransporter and that intestinal cotransporter was physiologically controlled by insulin, but not by blood glucose levels.     

Amino acid transport in membrane vesicles from CHO-K1 and alanine-resistant transport mutants

Membrane vesicles were prepared from CHO-K1 and alanine-resistant transport mutants, alar4 and alar4-H3.9. Alar4 is a constitutive mutant of the A system, and alar4-H3.9, derived from alar4, may be the result of amplification of a gene coding for an A-system transporter. Under conditions in which the same membrane potential (interior negative) and Na+ gradient were employed, the mutant vesicles show increases in the A system over that of the parental CHO-K1 cell line, paralleling, but not equivalent to, that found in whole cells. L-system and 5'-nucleotidase activities of these vesicles were similar, indicating that the increased A-system activity of the mutant vesicles is not due to the differential enrichment of the A system in these vesicles. The membrane potential was produced by a K+ diffusion gradient (internal greater than external) in the presence of valinomycin or by the addition of a Na+ salt of a highly permeant anion such as SCN-. Monensin was employed to study the effect of the Na+ gradient on transport and membrane potential. The latter was determined by measuring the uptake of tetraphenylphosphonium ion. A negative membrane potential determines the concentrative ability and the initial velocity of the A system in these vesicles. The concentration of external Na+ has a stimulatory effect on the initial velocity of this system. However, the Na+ gradient (external greater than internal) has no effect on the initial velocity or the membrane potential when the potential is set by valinomycin and high internal K+. Little if any ASC system could be detected in vesicles from CHO-K1.     

Kinetic properties of electrogenic Na+/H+ antiport in membrane vesicles from an alkalophilic Bacillus sp.

The effects of imposed proton motive force on the kinetic properties of the alkalophilic Bacillus sp. strain N-6 Na+/H+ antiport system have been studied by looking at the effect of delta psi (membrane potential, interior negative) and/or delta pH (proton gradient, interior alkaline) on Na+ efflux or H+ influx in right-side-out membrane vesicles. Imposed delta psi increased the Na+ efflux rate (V) linearly, and the slope of V versus delta psi was higher at pH 9 than at pH 8. Kinetic experiments indicated that the delta psi caused a pronounced increase in the Vmax for Na+ efflux, whereas the Km values for Na+ were unaffected by the delta psi. As the internal H+ concentration increased, the Na+ efflux reaction was inhibited. This inhibition resulted in an increase in the apparent Km of the Na+ efflux reaction. These results have also been observed in delta pH-driven Na+ efflux experiments. When Na(+)-loaded membrane vesicles were energized by means of a valinomycin-induced inside-negative K+ diffusion potential, the generated acidic-interior pH gradients could be detected by changes in 9-aminoacridine fluorescence. The results of H+ influx experiments showed a good coincidence with those of Na+ efflux. H+ influx was enhanced by an increase of delta psi or internal Na+ concentration and inhibited by high internal H+ concentration. These results are consistent with our previous contentions that the Na+/H+ antiport system of this strain operates electrogenically and plays a central role in pH homeostasis at the alkaline pH range.     

Effects of changes in sodium electrochemical potential gradient on p-aminohippurate transport in newt kidney

1. The relation between p-aminohippurate uptake and the electrochemical potential gradient of Na+ (delta muNa+) across the peritubular membrane was examined in newt (Triturus pyrrhogaster) kidney. The delta muNa+ was modified by changing cellular Na+ concentration and/or lowering the electrical potential difference across the peritubular membrane (peritubular membrane potential) 2. Elevation of external K+ concentration or addition of alanine at 40 mM to the medium decreased the delta muNa+ mainly through the depolarization of the cells. Addition of 1 mM ouabain resulted in a decrease in the peritubular membrane potential and increase in cellular Na+ concentration, thus decrease in the delta muNa+. 3. p-Aminohippurate uptake decreased in proportion to the decrease in the delta muNa+ under all experimental conditions, indicating that the maintenance of the delta muNa+ is required for p-aminohippurate transport. 4. All three different experimental conditions, high medium K+ concentration, 40 mM alanine or 1 mM ouabain, increased the apparent Michaelis constant, Kt, without affecting the maximal uptake rate, V, for p-aminohippurate. These results suggests that the delta muNa+, largely the peritubular membrane potential, may affect the association and/or dissociation of p-aminohippurate and Na+ at both interfaces of the peritubular membrane of the proximal tubular cells.     

Phosphate transport into brush-border membrane vesicles isolated from rat small intestine.

Uptake of Pi into brush-border membrane vesicles isolated from rat small intestine was investigated by a rapid filtration technique. The following results were obtained. 1. At pH 7.4 in the presence of a NaCl gradient across the membrane (sodium concentration in the medium higher than sodium concentration in the vesicles), phosphate was taken up by a saturable transport system, which was competitively inhibited by arsenate. Phosphate entered the same osmotically reactive space as D-glucose, which indicates that transport into the vesicles rather than binding to the membranes was determined. 2. The amount of phosphate taken up initially was increased about fourfold by lowering the pH from 7.4 to 6.0.3. When Na+ was replaced by K+, Rb+ or Cs+, the initial rate of uptake decreased at pH 7.4 but was not altered at pH 6.0.4. Experiments with different anions (SCN-,Cl-, SO42-) and with ionophores (valinomycin, monactin) showed that at pH 7.4 phosphate transport in the presence of a Na+ gradient is almost independent of the electrical potential across the vesicle membrane, whereas at pH 6.0 phosphate transport involves the transfer of negative charge. It is concluded that intestinal brush-border membranes contain a Na+/phosphate co-transport system, which catalyses under physiological conditions an electroneutral entry of Pi and Na+ into the intestinal epithelial cell. In contrast with the kidney, probably univalent phosphate and one Na+ ion instead of bivalent phosphate and two Na+ ions are transported together.     

A two sodium ion/D-glucose symport mechanism: membrane potential effects on phlorizin binding

Apical membrane vesicles isolated from a continuous renal cell line, LLC-PK1, catalyze electrogenic Na+-stimulated hexose transport and Na+-dependent binding of 3H-labeled 1-[2-(beta-D-glucopyranosyloxy)-4, 6-dihydroxyphenyl]-3-(4-hydroxyphenyl)-1-propanone [( 3H]phlorizin), a competitive ligand of this transport system. Phlorizin was not itself transported across the membrane and thus can serve as a probe of the binding step. The stoichiometry of Na+-dependent phlorizin binding in vesicles was 1:1, whereas Na+/hexose cotransport in vesicles exhibited a 2:1 stoichiometry. Na+ increased the affinity of phlorizin binding without affecting the total number of binding sites. An increased number of Na+-dependent phlorizin binding sites was observed under conditions of interior-negative membrane potential. These results are consistent with a model of the Na+/glucose cotransport cycle in which the unloaded transporter is negatively charged and its orientation influenced by membrane potential. Glucose and one sodium ion interact with the transporter, resulting in an uncharged complex. Binding of a second sodium ion triggers translocation of glucose and both sodium ions via formation of a loaded carrier complex bearing a single positive charge.     

Lactate efflux-induced electrical potential in membrane vesicles of Streptococcus cremoris.

We developed a procedure for isolating membrane vesicles from the homolactic fermentative bacterium Streptococcus cremoris. The membrane vesicles were shown to have a right-side-out orientation by freeze-etch electron microscopy and to be free of cytoplasmic constituents. The membrane vesicles retained their functional properties and accumulated the amino acids L-leucine, L-histidine, and L-alanine in response to a valinomycin-induced potassium diffusion gradient. Studies with these membrane vesicles strongly supported the possibility that there was a proton motive force-generating mechanism by end product efflux (Michels et al., FEMS Lett. 5:357-364, 1979). Lactate efflux from membrane vesicles which were loaded with L-lactate and diluted in a lactate-free medium led to the generation of an electrical potential across the membrane. The results indicate that lactate efflux is an electrogenic process by which L-lactate is translocated with more than one proton.