Intracellular pH and the kinetics of Rb+ uptake by yeast non-carrier versus mobile carrier-mediated uptake

The effect of changes in the intracellular pH upon the concentration dependence of the Rb⁺ uptake by yeast is investigated. It is shown, that the uptake of Rb⁺ can be described by a mechanism in which the total concentration of primary binding sites at the outer side of the membrane is independent of the intracellular ligand composition and of the membrane potential, and the influx rate constants depend upon the intracellular pH and/or upon the membrane potential. It is argued that the involvement of a mobile carrier mechanism is not likely.     

Kinetics of ion translocation across charged membranes mediated by a two-site transport mechanism. Effects of polyvalent cations upon rubidium uptake into yeast cells.

(1) The effect of surface charge upon the kinetics of monovalent cation translocation via a two-site mechanism is investigated theroretically. (2) According to the model dealt with, typical relations are expected for the dependence of the kinetic parameters of the translocation process upon the concentration of a polyvalent cation, differing essentially from those derived for the case in which the membrane carries no excess charge. (3) Even when a polyvalent cation does not compete with the substrate cation for binding to the translocation sites, apparently competitive inhibition may occur when the membrane is negatively charged. (4) The model is tested experimentally by studying the effects of the polyvalent cations Mg2+, Sr2+, Ca2+, Ba2+ and Al3+ upon Rb+ uptake into yeast cells at pH 4.5 A good applicability is found. (5) Equimolar concentrations of polyvalent cations reduce the rate of the Rb+ uptake into yeast cells in the order Mg2+ less than Sr2+ less than Ca2+ less than Ba2+ less than Al3+. (6) The conclusion is reached that the reduction in the rate of Rb+ uptake caused by the polyvalent cations applied results mainly from screening of the negative fixed charges on the membrane surface and binding to these negative sites rather than competition with Rb+ for the transport sites. (7) The results of our investigation indicate the affinity of the alkaline-earth cations for the negative fixed charges on the surface to the yeast cell membrane increases in the orther Mg2+ less than Sr2 less than Ca2+ less than Ba2+. (8) Probably mainly phosphoryl groups determine the net charge on the membrane of the yeast cell at a medium pH of 4.5.     

Kinetics of Ca2+ and Sr2+ uptake by yeast. Effects of pH, cations and phosphate.

The uptake of Ca2+ and Sr2+ by the yeast Saccharomyces cerevisiae is energy dependent, and shows a deviation from simple Michaelis-Menten kinetics. A model is discussed that takes into account the effect of the surface potential and the membrane potential on uptake kinetics. The rate of Ca2+ and Sr2+ uptake is influenced by the cell pH and by the medium pH. The inhibition of uptake at low concentration of Ca2+ and Sr2+ at low pH may be explained by a decrease of the surface potential. The inhibition of Ca2+ and Sr2+ uptake by monovalent cations is independent of the divalent cation concentration. The inhibition shows saturation kinetics, and the concentration of monovalent cation at which half-maximal inhibition is observed, is equal to the affinity constant of this ion for the monovalent cation transport system. The inhibition of divalent cation uptake by monovalent cations appears to be related to depolarization of the cell membrane. Phosphate exerts a dual effect on uptake of divalent cations: and initial inhibition and a secondary stimulation. The inhibition shows saturation kinetics, and the inhibition constant is equal to the affinity constant of phosphate for its transport mechanism. The secondary stimulation can only partly be explained by a decrease of the cell pH, suggesting interaction of intracellular phosphate, or a phosphorylated compound, with the translocation mechanism.     

Sodium influx rate and ouabain-sensitive rubidium uptake in isolated guinea pig atria.

1. Ouabain-sensitive 86Rb+ uptake by tissue preparations has been used as an estimate of Na+ pump activity. This uptake, however, may be a measure of the Na+ influx rate, rather than capacity of the Na+ pump, since intracellular Na+ concentration is a determinant of the active Na+/Rb+ exchange reaction under certain conditions. This aspect was examined by studying the effect of altered Na+ influx rate on ouabain-sensitive 86Rb+ uptake in atrial preparations of guinea pig hearts. 2. Electrical stimulation markedly enhanced ouabain-sensitive 86Rb+ uptake without affecting nonspecific, ouabain-insensitive uptake. Paired-pulse stimulation studies indicate that the stimulation-induced enhancement of 86Rb+ uptake is due to membrane depolarizations, and hence related to the rate of Na+ influx. 3. Alterations in the extracellular Ca2+ concentration failed to affect the 86Rb+ uptake indicating that the force of contraction does not influence 86Rb+ uptake. 4. Reduced Na+ influx by low extracellular Na+ concentration decreased 86Rb+ uptake, and an increased Na+ influx by a Na+-specific ionophore, monensin, enhanced 86Rb+ uptake in quiescent atria. 5. Grayanotoxins, agents that increase transmembrane Na+ influx, and high concentrations of monensin appear to have inhibitory effects on ouabain-sensitive 86Rb+ uptake in electrically stimulated and in quiescent atria. 6. Electrical stimulation or monensin enhanced ouabain binding to (Na+ + K+)-ATPase and also increased the potency of ouabain to inhibit 86Rb+ uptake indicating that the intracellular Na+ available to the Na+ pump is increased under these conditions. 7. The ouabain-sensitive 86Rb+ uptake in electrically stimulated atria was less sensitive to alterations in the extracellular Na+ concentration, temperature and monensin than that in quiescent atria. 8. These results indicate that the rate of Na+ influx is the primary determinant of ouabain-sensitive 86Rb+ uptake in isolated atria. Electrical stimulation most effectively increases the Na+ available to the Na+ pump system. The ouabain-sensitive 86Rb+ uptake by atrial preparations under electrical stimulation at a relatively high frequency seems to represent the maximal capacity of the Na+ pump in this tissue.     

Interaction of phosphate with monovalent cation uptake in yeast.

The uptake of monovalent cations by yeast via the monovalent cation uptake mechanism is inhibited by phosphate. The inhibition of Rb+ uptake shows saturation kinetics and the phosphate concentration at which half-maximal inhibition is observed is equal to the Km of phosphate for the sodium-independent phosphate uptake mechanism. The kinetic coefficients of Rb+ and TI+ uptake are affected by phosphate: the maximal rate of uptake is decreased and the apparent affinity constants for the translocation sites are increased. In the case of Na+ uptake, the inhibition by phosphate may be partly or completely compensated by stimulation of Na+ uptake via a sodium-phosphate cotransport mechanism. Phosphate effects a transient stimulation of the efflux of the lipophilic cation dibenzyldimethylammonium from preloaded yeast cells and a transient inhibition of dibenzyldimethylammonium uptake. Possibly, the inhibition of monovalent cation uptake in yeast can be explained by a transient depolarization of the cell membrane by phosphate.     

Insulin stimulation of (Na+,K+)-adenosine triphosphatase-dependent 86Rb+ uptake in rat adipocytes

Insulin stimulated the uptake of 86Rb+ (a K+ analog) in rat adipocytes and increased the steady state concentration of intracellular potassium. Half-maximal stimulation occurred at an insulin concentration of 200 pM. Both basal- and insulin-stimulated 86Rb+ transport rates depended on the concentration of external K+, external Na+, and were 90% inhibited by 10(-3) M ouabain and 10(-3) M KCN, indicating that the hormone was activating the (Na+,K+)-ATPase. Insulin had no effect on the entry of 22Na+ or exit of 86Rb+. Kinetic analysis demonstrated that insulin acted by increasing the maximum velocity, Vmax, of 86Rb+ entry. Inhibition of the rate of Rb+ uptake by ouabain was best described by a biphasic inhibition curve. Scatchard analysis of ouabain binding to intact cells indicated binding sites with multiple affinities. Only the rubidium transport sites which exhibited a high affinity for ouabain were stimulated by insulin. Stimulation required insulin binding to an intact cell surface receptor, as it was reversible by trypsinization. We conclude that the uptake of 86Rb+ by the (Na+,K+)-ATPase is an insulin-sensitive membrane transport process in the fat cell.     

The effect of intracellular pH on the rate of hexose uptake in Chlorella.

The rate of hexose uptake by Chlorella is reduced by uncouplers such as carbonyl cyanide p-trifluoromethoxyphenyl hydrazone or dinitrophenol even before concentration equilibrium is reached. The addition of uncouplers changes the membrane potential and the intracellular pH. The membrane potential does not influence the initial velocity of net sugar uptake, whereas manipulation of the cell pH by means of dimethyloxazolidinedione or by butyric acid uncovered a dramatic influence of cell pH on the rate of hexose uptake: at pH values of 7.5--6.8 maximal rate of uptake is observed but at more acid pH a strong inhibition takes place with virtually total blockage of uptake at pH 6.1. The decrease of cell pH to 6.1 in the presence of carbonyl cyanide p-trifluoromethoxyphenyl hydrazone could therefore account for the decrease in hexose transport rate. It was shown that the intracellular pH as such determines the rate of uptake and not the pH difference between inside and outside; the transport rate did not correlate with delta pH.     

Kinetics of Ca2+ and Sr2+ uptake by yeast. Effects of pH,cations and phosphate

The uptake of Ca²⁺ and Sr²⁺ by the yeast Saccharomyces cerevisiae is energy dependent, and shows a deviation from simple Michaelis-Menten kinetics. A model is discussed that takes into account the effect of the surface potential and the membrane potential on uptake kinetics.The rate of Ca²⁺ and Sr²⁺ uptake is influenced by the cell pH and by the medium pH. The inhibition of uptake at low concentrations of Ca²⁺ and Sr²⁺ at low pH may be explained by a decrease of the surface potential.The inhibition of Ca²⁺ and Sr²⁺ uptake by monovalent cations is independent of the divalent cation concentration. The inhibition shows saturation kinetics, and the concentration of monovalent cation at which half-maximal inhibition is observed, is equal to the affinity constant of this ion for the monovalent cation transport system. The inhibition of divalent cation uptake by monovalent cations appears to be related to depolarization of the cell membrane.Phosphate exerts a dual effect on uptake of divalent cations: and initial inhibition and a secondary stimulation. The inhibition shows saturation kinetics, and the inhibition constant is equal to the affinity constant of phosphate for its transport mechanism. The secondary stimulation can only partly be explained by a decrease of the cell pH, suggesting interaction of intracellular phosphate, or a phosphorylated compound, with the translocation mechanism.     

Choline uptake into the malaria parasite is energized by the membrane potential

The uptake by the intraerythrocytic malaria parasite of the phospholipid precursor choline was investigated in parasites 'isolated' from their host cells by saponin permeabilization of the erythrocyte membrane. Choline is transported across the parasite plasma membrane then phosphorylated and thereby trapped within the parasite. Choline influx was inhibited competitively by quinine. It increased with increasing extracellular pH, decreased on depolarization of the parasite plasma membrane with a protonophore or by increasing extracellular [K+], and increased in response to hyperpolarization of the membrane by decreasing extracellular [K+] or by addition of the K+ channel blocker Cs+. In ATP-depleted parasites choline was taken up but not phosphorylated. Under these conditions, imposition of an inwardly negative membrane potential using the K+ ionophore valinomycin resulted in the accumulation of choline to an intracellular concentration more than 15-fold higher than the extracellular concentration. Choline influx is therefore an electrogenic process, energized by the parasite plasma membrane potential.     

Alteration of 86Rb+ influx and efflux following depletion of membrane sterol in L-cells

Ouabain-sensitive uptake of 86Rb+ (an analogue of K+) was enhanced in L-cells that had been treated with 25-hydroxycholesterol or 7-ketocholesterol in order to deplete their sterol concentration. Ouabain-insensitive Rb+ efflux also increased in the sterol-depleted cells and the intracellular concentration of K+ diminished while the concentration of Na+ increased. All of these effects of 25-hydroxycholesterol were counteracted by the addition of mevalonate to the culture medium. Despite the evidence for increased active Rb+ transport in the 25-hydroxycholesterol-treated cells, the level of sodium and potassium ion-activated adenosine triphosphatase ((Na+ + K+)-activated ATPase) activity measured in homogenates and plasma membrane preparations from the treated cells was not significantly different from the control values. Rb+ uptake was more sensitive to ouabain inhibition in sterol-depleted cells than in control cells, although ATPase activity in plasma membrane fractions isolated from treated cells was not more sensitive to ouabain inhibition than was that from control cells. It is possible that the ability of the oxygenated sterols to inhibit DNA synthesis and cell division (Kandutsch, A. A., and Chen, H. W. (1977) J. Biol. Chem. 252, 409-415) is related to their effects upon cellular ion transport.     

A calmodulin dependent Ca2+-activated K+ channel in the adipocyte plasma membrane

Increased membrane permeability (conductance) that is specific for K+ and directly activated by Ca2+ ions, has been identified in isolated adipocyte plasma membranes using the K+ analogue, 86Rb+. Activation of these K+ conductance pathways (channels) by free Ca2+ was concentration dependent with a half-maximal effect occurring at 32 +/- 4 nM free Ca2+ (n = 7). Addition of calmodulin further enhanced the Ca2+ activating effect on 86Rb+ uptake (K+ channel activity). Ca2+-dependent 86Rb+ uptake was inhibited by tetraethylammonium ion and low pH. It is concluded that the adipocyte plasma membrane possesses K+ channels that are activated by Ca2+ and amplified by calmodulin.     

Energy-driven uptake of the neurotoxin 1-methyl-4-phenylpyridinium into chromaffin granules via the catecholamine transporter

Chromaffin granules take up and concentrate 1-methyl-4-phenylpyridinium (MPP+) through a temperature-sensitive and saturable mechanism. The uptake displays an apparent Km of 51.2 microM and a Vmax of 7.1 nmol/min/mg of protein. MPP+ uptake is markedly depressed in the absence of ATP or by inhibition of the membrane Mg2+-dependent ATPase, and it is completely blocked by reserpine. Reversal of the membrane potential by carbonyl cyanide m-chlorophenylhydrazone or dissipation of the pH gradient in the presence of nigericin plus potassium ions produces a marked inhibition of MPP+ uptake indicating that the process is dependent upon the integrity of the transmembrane proton electrochemical gradient generated and maintained by the membrane Mg2+-dependent ATPase. Furthermore, the data shows that a permanently charged compound is capable of entering the granule through the catecholamine carrier.     

Low-affinity potassium uptake system in the archaeon Methanobacterium thermoautotrophicum: overproduction of a 31-kilodalton membrane protein during growth on low-potassium medium.

During growth on low-K+ medium (1 mM K+), Methanobacterium thermoautotrophicum accumulated K+ up to concentration gradients ([K+]intracellular/[K+]extracellular) of 25,000- to 50,000-fold. At these gradients ([K+]extracellular of < 20 microM), growth ceased but could be reinitiated by the addition of K+ or Rb+. During K+ starvation, the levels of a protein with an apparent molecular weight of 31,000 increased about sixfold. The protein was associated with the membrane and could be extracted by detergents. Cell suspensions of M. thermoautotrophicum obtained after K+-limited growth catalyzed the transport of both K+ and Rb+ with apparent Km and Vmax values of 0.13 mM and 140 nmol/min/mg, respectively, for K+ and 3.4 mM and 140 nmol/min/mg, respectively, for Rb+. Rb+ competitively inhibited K+ uptake with an inhibitor constant of about 10 mM. Membranes of K+-starved cells did not exhibit K+-stimulated ATPase activity. Immunoblotting with antisera against Escherichia coli Kdp-ATPase did not reveal any specific cross-reactivity against membrane proteins of K+-starved cells. Cells of M. thermoautotrophicum grown at a high potassium concentration (50 mM) catalyzed K+ and Rb+ transport at similar apparent Km values (0.13 mM for K+ and 3.3 mM for Rb+) but at significantly lower apparent Vmax values (about 60 nmol/min/mg for both K+ and Rb+) compared with K+-starved cells. From these data, it is concluded that the archaeon M. thermoautotrophicum contains a low-affinity K+ uptake system which is overproduced during growth on low-K+ medium.     

Adsorption of radionuclides on silica and their uptake by rice plants from silica-multitracer solutions: the effects of pH

We investigated the effect of solution pH on the adsorption on silica of a mixture radionuclides 83Rb, 85Sr, 54Mn, 65Zn, 88Y, and 75Se generated from irradiation of Ag in a 135-MeV/nucleon 12C beam accelerated by the RIKEN Ring Cyclotron and 137Cs obtained commercially. Then, we related these findings to their uptake by a rice plant (Oryza sativa L. cv. Koshihikari) from a silica-multitracer solution at pH 4.3 +/- 0.2 and at 5.3 +/- 0.2. To evaluate both adsorption and uptake, precisely we used a multitracer technique that simultaneously tracked the movements of all of the radionuclides. There was an increase in the uptake of Rb, Cs, Sr, Mn, and Zn by the rice plants with the increase in pH from 4.3 to 5.3. By contrast, the uptake of Y and Se was less at the higher pH. Our findings suggest that the uptake of these elements is governed by their transport systems on the plasma membrane and by their affinity to silica, both of which are regulated by H+ concentration.     

The effect of lysosomotrophic bases and inhibitors of transglutaminase on iron uptake by immature erythroid cells

The mechanism by which weak bases block iron uptake by immature erythroid cells was investigated using rabbit and rat reticulocytes and erythroblasts from the fetal rat liver. A large variety of bases was found to inhibit iron uptake but to have a much smaller or no effect on transferrin uptake by the cells. Quinacrine and chloroquine were active at the lowest concentrations. Dansylcadaverine, an inhibitor of transglutaminase, was also active at low concentration. However, the results do not indicate a role for transglutaminase in the iron uptake process. Instead they show that the major effect of the bases is to inhibit iron release from transferrin molecules on or within the cells. The possible mechanism of this effect was investigated by measurement of intracellular ATP levels, intracellular pH and by morphological studies utilizing fluorescent and electron microscopy. The bases caused little change in ATP levels, but elevated intracellular pH, probably due to accumulation within intracellular vesicles, which were shown to accumulate fluorescent weak bases, to swell under the action of the bases and to be the site of intracellular localization of transferrin. It is concluded that the bases tested in this work inhibit iron release from transferrin in intracellular vesicles by increasing their pH rather than by blocking transglutaminase and thereby restricting endocytosis. Reduction of transferrin uptake by the cells when it occurs is probably due to inhibition of recycling of transferrin receptors to the outer cell membrane.     

Energetics of l-proline uptake by Saccharomyces cerevisiae

l-Proline is transported into the yeast Saccharomyces cerevisiae against a concentration gradient of up to 135:1, the gradient decreasing with increasing proline concentration and suspension density. The concentrative uptake is practically unaffected by inhibitors, except antimycin. It is markedly reduced by anaerobic conditions. Uptake of l-proline, either by normal cells or in the presence of inhibitors, elicits no alkalification of the medium (estimated by pH and conductivity measurements) and no membrane depolarization (estimated by distribution of tetraphenylphosphonium). There is no relationship between the electrochemical potential gradient of protons and the measured accumulation ratios of proline. Likewise, intracellular ATP levels bear little relation to the accumulation. If, based on analogy with other yeasts and bacteria, l-proline is symported with H⁺ ions the process must occur in local domains of the membrane where both the ΔpH and the membrane potential may differ substantially from those measured in the bulk solution.     

Effect of osmolality on 86Rb+ uptake and release by Leishmania donovani.

Promastigotes from late-log phase cultures of Leishmania donovani were washed and resuspended in Hanks' Balanced Salt Solution without glucose or phenyl red but with 20 mM (N-[2-hydroxyethyl] piperazine-N'-[2-ethanesulfonic acid]) (HEPES) (HBSS-, 305 mOsm/kg). They were then added to a solution containing 86Rb such that the final osmolality and ionic composition was as desired. Samples were taken at known times and the amount of intracellular 86Rb was measured. Similarly, experiments were performed in which 86Rb was added to the cultures about 18 hr before collection, and the amount of 86Rb released from the washed cells was measured. Under iso-osmotic conditions only about 1.3% of the intracellular 86Rb was released in 900 sec. This increased about 4-fold if the osmolality was reduced from 305-153 mOsm/kg. This is much slower than the very rapid release of alanine in response to hypo-osmotic stress, indicating that alanine release is not via a non-specific pore. Reducing the temperature from 26 degrees C to 3-4 degrees C completely inhibits 86Rb release under iso-osmotic conditions and largely inhibits it under hypo-osmotic conditions. The rate of 86Rb release was not sensitive to K+ concentration and was not altered if chloride was replaced by sulfamate. Ouabain had no effect on either 86Rb uptake or release, but carbonylcyanide P-trifluoromethoxyphenylhydrazone (FCCP) reduced the rate of 86Rb release and, after about a 300 sec exposure, completely inhibited 86Rb uptake. Amiloride partially inhibited 86Rb release, but had no effect on uptake. A decrease in pH from 7.1-5.9 had little effect on 86Rb release under iso-osmotic conditions and slightly increased the rate of release under hypo-osmotic conditions, but it decreased the rate of uptake under both iso-osmotic and hypo-osmotic conditions. Cells taken from 3-day stationary phase cultures released 86Rb more slowly under iso-osmotic conditions than cells from late log phase cultures, but were more responsive to hypo-osmotic stress than were log phase cells. These data appear to rule out an [Na-K-Cl] transporter or a [K-Cl] cotransporter as the means of K+ release, but are consistent with the possibility that a K+/H+ exchanger is present. The possibility that other carrier systems may be present is also discussed.     

Phenazine methosulfate stimulation of ouabain-sensitive Rb+ uptake by HeLa cells: effects of respiratory inhibitors, anaerobiosis, and ascorbate

phenazine methosulfate (PMS) stimulates ouabain-sensitive Rb+ uptake by HeLa cells. This stimulation cannot be attributed to the effect of the dye on the intracellular Na+ or ATP content. Respiratory inhibitors, such as 5 mM NaCN and 5 microM rotenone, and anaerobic conditions enhance the stimulation of Rb+ uptake by PMS. Cellular respiration is stimulated, but lactate production is reduced in the presence of PMS, irrespective of the presence of respiratory inhibitors. Cellular NADH is oxidized markedly on addition of PMS plus inhibitors, but it is not affected by addition of the inhibitors only. In the presence of a high concentration of PMS, PMS-stimulated ouabain-sensitive Rb+ uptake is inhibited by addition of ascorbate. From these results it is concluded that Na+K-pump activity is closely related to the cellular redox state.     

Internal pH can regulate Ca2+ uptake and the acrosome reaction in sea urchin sperm

The egg jelly-induced acrosome reaction of sea urchin sperm is accompanied by intracellular alkalinization and Ca2+ entry. We have previously shown that in the absence of egg jelly, NH4Cl, which increases intracellular pH (pHi), induces Ca2+ uptake and the acrosome reaction in sperm of the sea urchin, Strongylocentrotus purpuratus. Here we show that at a constant concentration of NH4Cl (20 mM) in seawater, sperm react less as external pH is lowered from the normal 8 to 7.25. The pH dependence of the NH4Cl response is not very sensitive to temperatures between 12 and 17 degrees C. NH4Cl (15-50 mM) stimulates Ca2+ uptake and acrosome reactions in sperm suspended in Na+-free seawater, a condition known to inhibit the inductive effect of jelly. Jelly does not further stimulate Ca2+ uptake of sperm preincubated in NH4Cl, indicating that once the permeability to Ca2+ is increased by raising the pHi, the jelly has no further effect. We have used the membrane potential-sensitive dye 3,3'-dipropylthiadicarbocyanine iodide to follow the membrane potential change that occurs when NH4Cl is added. Depolarization (25 mV) is associated with the acrosome reaction when either the natural inducer, egg jelly, or NH4Cl is added to sperm. Response to both inducers is inhibited under conditions known to abolish the acrosome reaction, i.e., low-pH seawater and nisoldipine. These results indicate that the NH4Cl-induced depolarization that accompanies the reaction is probably due to the opening of channels that allow Ca2+ to enter the cell and not to the depolarization by NH4+ ions. High-K+ seawater, which depolarizes sperm, and tetraethylammonium, a K+ channel blocker, inhibit the jelly-induced depolarization and the acrosome reaction, but do not inhibit NH4Cl-induced changes. It has already been shown that nigericin promotes Ca2+ entry and the acrosome reaction in sea urchin sperm. We found that the action of this ionophore depends on the pH of normal seawater. In the absence of external Na+ (replaced by choline), nigericin does not induce the reaction and does not stimulate Ca2+ uptake.     

Membrane potential dependence of Fe(III) uptake by mouse duodenum

Intestinal iron uptake by mouse duodenal fragments is inhibited in the absence of oxygen and glucose from the incubation medium and by a variety of metabolic inhibitors. The mechanism of energy coupling to iron uptake is, however, unclear. In vitro experiments using duodenal fragments showed Fe3+ uptake to be markedly inhibited, in a reversible fashion, by the replacement of incubation medium Na+ by K+. Addition of phloridzin to the medium failed to affect iron uptake, suggesting that the above effect was not a consequence of reduced glucose uptake. Substitution of Na+ by Rb+ also potently reduced duodenal iron uptake. Replacement of medium NaCl by either mannitol or choline chloride had no significant effect on Fe3+ uptake, thus excluding the possibility of the Fe3+ uptake process being Na+-dependent. Similar observations were made with duodenal fragments from animals with enhanced Fe3+ absorption, due to chronic hypoxia. Valinomycin (1-5 microM) increased the uptake of both glucose and Fe3+. Higher concentrations (22.5 microM) of the ionophore were inhibitory. In vivo studies (tied-off segments) using Rb+-containing medium confirmed the inhibitory effects of univalent cations on Fe3+ absorption. Enhanced absorption of Fe3+ was also demonstrable in vivo, with low concentrations of valinomycin and nigericin added to the luminal medium. These observations suggest that the Fe3+ uptake process may be dependent on the brush-border membrane potential.