Plasmalemma redox activity and h extrusion: I. Activation of the h-pump by ferricyanide-induced potential depolarization and cytoplasm acidification

Ferricyanide reduction by Elodea densa leaves, in the dark, is associated with: (a) acidification of the medium; (b) decrease (about 0.2-0.3 units) of intracellular pH (measured in cell sap, cytoplasm, and vacuole); (c) depolarization of the transmembrane potential; (d) net efflux of K⁺ to the medium. Ferricyanide-induced acid secretion is markedly increased by the presence of fusicoccin (FC), and this effect is severely inhibited by the proton pump inhibitors erythrosine B and vanadate. In the presence of ferricyanide FC-induced H⁺ extrusion no longer requires the presence of K⁺ in the medium. The (ferricyanide reduced)/(H⁺ extruded) ratio varies from about 2, in the absence of FC, to about 1 when the toxin is present, and to more than 4, when ATP-driven H⁺ extrusion is inhibited by erythrosine B or by vanadate. Fusicoccin markedly reduces K⁺ release to the medium. The ratio (ferricyanide reduced)/(H⁺ extruded + K⁺ released) approaches unity under all of the three conditions considered. These results indicate that ferricyanide reduction depends on a plasmalemma system transporting only electrons to the extracellular acceptor, with consequent potential depolarization and cytoplasm acidification. Most of the protons released in the cytoplasm would be secondarily extruded by the ATP-driven pump, stimulated by both intracellular acidification and depolarization. K⁺ efflux would depend on potential depolarization.     

Inhibition of trans-membrane hexacyanoferrate III reductase activity and proton secretion of maize (Zea mays L.) roots by thenoyltrifluoroacetone

Summary Intact plants can reduce external oxidants by an appearingly trans-membrane electron transport. In vivo an increase in net medium acidification accompanies the reduction of the apoplastic substrate. Up to now, several NAD(P)H dehydrogenases,b-type cytochromes, and a phylloquinone have been identified and partially purified from plant plasma membranes. The occurrence of a quinone in the plasma membrane of maize roots supports the hypothetical model of a proton-transferring redox system, i.e., an electron transport chain with a quinone as mobile electron and proton carrier. In the present study the trans-membrane electron transport system of intact maize (Zea mays L.) roots was investigated. Flow-through and ionostat systems have been used to estimate the electron and proton transport activity of this material. Application of 4,4,4-trifluoro-1-(2-thienyl)-butane-1,3-dione (thenoyltrifluoroacetone) inhibited the reduction of ferricyanide in the incubation solution of intact maize roots up to 70%. This inhibition could not be washed off by rinsing the roots with fresh incubation medium. The acidification of the medium induced after ferricyanide application was inhibited to about 62%. The effects of thenoyltrifluoroacetone on proton fluxes in the absence of ferricyanide have been characterized in a pH-stat system. The net medium acidification by maize roots was inhibited up to 75% by thenoyltrifluoroacetone in the absence of ferricyanide, while dicumarol inhibited net acidification completely. The inhibition of H⁺-ATPase activity was estimated with plasma membrane vesicles isolated by phase partitioning and treated with 0.05% (w/v) Brij 58. ATP-dependent proton gradients and P_i release were measured after preincubation with the effectors. The proton pumping activity by those plasma membrane vesicles was inhibited by dicumarol (53.6%) and thenoyltrifluoroacetone (77.8%), while the release of P_i was unaffected by both inhibitors.Abbreviations Brij 58 polyoxyethylene 20-cetyl ether - duroquinone tetramethyl-p-benzoquinone - HCF III hexacyanoferrate III - TTFA thenoyltrifluoroacetone - vitamin K₁ 2-methyl-3-phytyl-1,4-naphthoquinone - vitamin K₃ 2-methyl-1,4-naphthoquinone     

Relationship between Electron Transport across the Plasmalemma and a pH Decrease in the Bulk Medium

The hypothesis is tested that acidification of the bulk medium during transplasmalemma electron transport to ferricyanide is due solely to a requirement for charge balance. According to this hypothesis, reduction of the trivalent anion, ferricyanide, to the tetravalent anion, ferrocyanide, results in a charge difference that is balanced by protons. A coulometric device is used that rapidly and efficiently reoxidizes ferrocyanide to ferricyanide, thus maintaining a constant charge in the bulk medium. Oat (Avena sativa L. cv Garry) mesophyll protoplasts are chosen as experimental material to facilitate ferricyanide reduction and the concomitant ferrocyanide reoxidation by the coulometric device. The kinetics of ferricyanide reduction and proton excretion by protoplasts are similar to those of other cell types and tissues. Rates of net proton excretion are identical regardless of whether the ferrocyanide is simultaneously reoxidized. We conclude that acidification may occur during transplasmalemma electron transport when there is no change in negative charge of the bulk medium.     

Proton efflux from corn roots induced by tripropyltin

Tripropyltin restores medium acidification by washed corn root tissue in which electrogenic H⁺ efflux has been blocked by ATPase inhibitors or injury. However, the restored H⁺ efflux is not electrogenic and will not drive K⁺ influx, and, by itself, tripropyltin is inhibitory to K⁺ influx. Tripropyltin elicits a 5-fold increase in endogenous chloride efflux, and Cl⁻/OH⁻ exchange can, thus, account for the observed acidification of the medium. This explanation cannot be applied equally to the acidification produced by the K⁺/H⁺ exchanging ionophore nigericin.     

Transplasma-membrane ferricyanide reduction in sycamore cells. Characterization of the system and inhibition by some phenyl biscarbamates

Evidence is presented for the presence of a transplasma-membrane redox system in sycamore cells, which were found able to reduce external ferricyanide. This reduction induced a simultaneous acidification of the external medium, with a H⁺/e⁻ stoichiometry of 0.925. Ferricyanide reduction was accompanied by a slight reduction of potassium uptake (15% inhibition). The transmembrane electron transport was inhibited by oligomycin and quinacrine; the effect of the latter inhibitor was only temporary, owing to its progressive absorption by the cells.At 100 μM, several derivatives of the herbicide phenmedipham were able to inhibit the growth of sycamore cells. These compounds inhibited the external acidification induced by fusicoccin, without interfering with the integrity of the plasmalemma. They had no effect on the phosphohydrolase activity of a microsomal fraction enriched in plasmalemma ATPase. They were not uncouplers of oxidative phosphorylation, and appeared as poor inhibitors of mitochondrial electron transfer (I₅₀ > 100 μM). In intact cell suspension, they inhibited both the reduction of ferricyanide and the accompanying acidification of the external medium (I₅₀ = 32 μM). Moreover, they could induce a reversal of the functioning of the redox system, which consequently induced ferrocyanide oxidation.     

Ascorbic acid efflux and re-uptake in endothelial cells: maintenance of intracellular ascorbate

Entry of vitamin C or ascorbate into most tissues requires its movement across the endothelial cell barrier of vessels. If trans-cellular ascorbate movement occurs, then it should be evident as ascorbate efflux from endothelial cells. Cultured EA.926 endothelial cells that had been loaded to about 3.5 mM intracellular ascorbate lost 70–80% of ascorbate to the medium over several hours at 37°C via a non-saturable process that was insensitive to anion transport inhibitors and thiol reagents. Oxidation of this extracellular ascorbate by ascorbate oxidase or ferricyanide enhanced apparent ascorbate efflux, suggesting that efflux of the vitamin was countered in part by its re-uptake on ascorbate transporters. Although basal ascorbate efflux was not calcium-dependent, increased entry of calcium into the cells enhanced ascorbate release. These results support the hypothesis that ascorbate efflux reflects trans-endothelial cell ascorbate movement out of the blood vessel.     

alpha-Adrenergic stimulation of trans-sarcolemma electron efflux in perfused rat heart. Possible regulation of Ca2+-channels by a sarcolemma redox system

The role of trans-sarcolemma membrane electron efflux in the alpha-adrenergic control of Ca2+ influx in perfused rat heart was examined. Electron efflux was measured by monitoring the rate of reduction of extracellular ferricyanide and compared with changes in contractility, as an indirect assessment of changes in cytoplasmic Ca2+ concentration. Methoxamine and phenylephrine each increased the rate of ferricyanide reduction from 80 to approx. 114 nmol/min per g wet wt. of heart, with half-maximal activation occurring at 10 microM for each agonist. Activation of the rate of ferricyanide reduction by both 10 microM methoxamine and 10 microM phenylephrine was blocked by the alpha-adrenergic antagonist, phenoxybenzamine, but not by the beta-antagonist, propranolol. Stimulation of the rate of ferricyanide reduction by the alpha-agonist coincided with the increase in contractility, each reaching maximum values at approx. 80 s. Removal of the alpha-agonists led to parallel decreases in contractility and the rate of reduction, each returning to pre-stimulation values in approx. 400 s. In addition, the relationship between Ca2+ and ferricyanide reduction was examined. Perfusion of the heart with medium containing 6 mM CaCl2 significantly increased contractility and the rate of ferricyanide reduction. Perfusion of the heart with low Ca2+ diminished contractility, did not affect the rate of ferricyanide reduction, but amplified the stimulatory effect of methoxamine on this rate. The increase in ferricyanide reduction by alpha-adrenergic agonists resulted from a change in the apparent Vmax, indicative of an increase in electron efflux sites in the plasma membrane. It is concluded that alpha-adrenergic control of electron efflux closely parallels changes in contractility and therefore changes in the cytoplasmic concentration of Ca2+. The data suggest that alpha-agonist-mediated changes in electron efflux may lead to Ca2+ influx.     

Nature of the light-induced h efflux and na uptake in cyanobacteria

We investigated the nature of the light-induced, sodium-dependent acidification of the medium and the uptake of sodium by Synechococcus. The rate of acidification (net H⁺ efflux) was strongly and specifically stimulated by sodium. The rates of acidification and sodium uptake were strongly affected by the pH of the medium; the optimal pH for both processes being in the alkaline pH range. Net proton efflux was severely inhibited by inhibitors of adenosine triphosphatase activity, energy transfer, and photosynthetic electron transport, but was not affected by the presence of inorganic carbon (C_i). Light and C_i stimulated the uptake of sodium, but the stimulation by C_i was observed only when C_i was present at the time sodium was provided. Amiloride, a potent inhibitor of Na⁺/H⁺ antiport and Na⁺ channels, stimulated the rate of acidification but inhibited the rate of sodium uptake. It is suggested that acidification might stem from the activity of a light dependent proton excreting adenosine triphosphatase, while sodium transport seems to be mediated by both Na⁺/H⁺ antiport and Na⁺ uniport.     

Growth and proton-potassium exchange in Enterococcus hirae: protonophore effect and the role of oxidation-reduction potential

Enterococcus hirae ATCC 9790 are able to grow under anaerobic conditions during the fermentation of sugars (pH 8.0) in the presence of the protonophore carbonylcyanide-m-chlorophenylhydrazone at a lesser specific growth rate. As bacteria grow, the acidification of the external medium and a drop in the redox potential from positive to negative (up to -220 mV) values occur. The reducer dithiothreitol, which maintains the negative values of the redox potential, increases the growth rate and acidification of the medium, recovering thereby the effect of the protonophore (without interacting with it). Conversely, the impermeable oxidizer ferricyanide, while maintaining positive values of the redox potential, inhibits the bacterial growth. These results indicate the role of the proton-motive force and importance of reducing processes in bacterial growth. The proton-potassium exchange is inhibited by carbonylcyanide-m-chlorophenylhydazone but is restored with dithiothreitol. Dithiothreiol is able to substitute the proton-motive force; however, ferricyanide and dithiothreitol may also directly affect the bacterial membrane.     

α-Adrenergic stimulation of trans-sarcolemma electron efflux in perfused rat heart. Possible regulation of Ca2+-channels by a sarcolemma redox system

The role of trans-sarcolemma membrane electron efflux in the α-adrenergic control of Ca²⁺ influx in perfused rat heart was examined. Electron efflux was measured by monitoring the rate of reduction of extracellular ferricyanide and compared with changes in contractility, as an indirect assessment of changes in cytoplasmic Ca²⁺ concentration. Methoxamine and phenylephrine each increased the rate of ferricyanide reduction from 80 to approx. 114 nmol/min per g wet wt. of heart, with half-maximal activation occurring at 10 μM for each agonist. Activation of the rate of ferricyanide reduction by both 10 μM methoxamine and 10 μM phenylephrine was blocked by the α-adrenergic antagonist, phenoxybenzamine, but not by the β-antagonist, propranolol. Stimulation of the rate of ferricyanide reduction by the α-agonist coincided with the increase in contractility, each reaching maximum values at approx. 80 s. Removal of the α-agonists led to parallel decreases in contractility and the rate of reduction, each returning to pre-stimulation values in approx. 400 s. In addition, the relationship between Ca²⁺ and ferricyanide reduction was examined. Perfusion of the heart with medium containing 6 mM CaCl₂ significantly increased contractility and the rate of ferricyanide reduction. Perfusion of the heart with low Ca²⁺ diminished contractility, did not affect the rate of ferricyanide reduction, but amplified the stimulatory effect of methoxamine on this rate. The increase in ferricyanide reduction by α-adrenergic agonists resulted from a change in the apparent V_max, indicative of an increase in electron efflux sites in the plasma membrane. It is concluded that α-adrenergic control of electron efflux closely parallels changes in contractility and therefore changes in the cytoplasmic concentration of Ca²⁺. The data suggest that α-agonist-mediated changes in electron efflux may lead to Ca²⁺ influx.     

Growth and proton-potassium exchange in the bacterium Enterococcus hirae: the effect of protonophore and the role of redox potential

The bacterium Enterococcus hirae is able to grow under anaerobic conditions during sugar fermentation (pH 8.0) in the presence of the protonophore carbonyl cyanide m-chlorophenylhydrazone at a considerably lower specific rate. Bacterial growth was accompanied by acidification of the medium and a drop in its redox potential from positive to negative values (by −220 mV). We showed that the reducer dithiothreitol, which determines negative values of the redox potential, accelerates bacterial growth and enhances acidification of the medium, abolishing the effect of the protonophore without binding to dithiothreitol. Conversely, the nonpenetrating oxidant ferricyanide, which maintained positive values of the redox potential, suppressed bacterial growth. These results are indicative of the role of the proton-motive force and the importance of reductive processes in bacterial growth. The proton-potassium exchange is inhibited in the presence of carbonyl cyanide m-chlorophenylhydrazone and recovers in the presence of dithiothreitol. Dithiothreitol can substitute for the proton-motive force; however, both ferricyanide and dithiothreitol may have a direct effect on the bacterial membrane.     

Root tip-dependent, active riboflavin secretion by Hyoscyamus albus hairy roots under iron deficiency.

Hyoscyamus albus hairy roots with/without an exogenous gene (11 clones) were established by inoculation of Agrobacterium rhizogenes. All clones cultured under iron-deficient condition secreted riboflavin from the root tips into the culture medium and the productivity depended on the number and size of root tips among the clones. A decline of pH was observed before riboflavin production and root development. By studying effects of proton-pump inhibitors, medium acidification with external organic acid, and riboflavin addition upon pH change and riboflavin productivity, we indicate that riboflavin efflux is not directly connected to active pH reduction, and more significantly active riboflavin secretion occurs as a response to an internal requirement in H. albus hairy roots under iron deficiency.     

Kinetics of glutamate efflux in rat liver mitochondria

The transport of glutamate was studied in isolated rat liver mitochondria preloaded with glutamate in the presence of respiratory inhibitors. Glutamate efflux was initiated by dilution of the loaded mitochondria into a glutamate-free medium, and the rate of transport was measured by following the disappearance of glutamate from the mitochondrial matrix following rapid centrifugation through silicone oil. Glutamate efflux was inhibited extensively by bromcresol purple and partially by N-ethylmaleimide, compounds which are both known to inhibit mitochondrial glutamate uptake. The efflux process was stereospecific for L-glutamate and exhibited an activation energy of 19.2 kcal/mol. The rate of glutamate efflux was not affected by changes in the mitochondrial membrane potential. However, a good correlation was observed between the rate of glutamate efflux and the matrix pH, the efflux rate being stimulated by a decrease in matrix pH in the range from 8.0 to 7.2. In contrast, acidification of the incubation medium in the pH range 7.4 to 6.5 inhibited the rate of glutamate efflux. A kinetic analysis was made of the efflux reaction by a computer curve-fitting procedure which fits the experimental data to an integrated rate equation (Williamson, J.R., and Viale, R.O. (1979) Methods Enzymol. 56, 252-278). The results indicated that a fall in the matrix pH primarily caused a decrease in the K'm for matrix glutamate, with little change in V'max. In contrast, a low external pH had an effect on the V'max but not on the K'm for intramitochondrial glutamate. The results are in agreement with a symmetrical sequential model of glutamate transport where the glutamate anion binds to the protonated carrier.     

Active extrusion of potassium in the yeast Saccharomyces cerevisiae induced by low concentrations of trifluoperazine

Trifluoperazine (TFP), the antipsychotic drug, induces substantial K+ efflux, membrane hyperpolarization and inhibition of H+-ATPase in the yeast Saccharomyces cerevisiae. Investigations on the mechanism of these effects revealed two different processes observed at different incubation conditions. At an acidic pH of 4.5 and an alkaline pH of 7.5, K+ efflux was accompanied by substantial proton influx which led to intracellular acidification and dissipation of delta psi formed by cation efflux. The results indicated nonspecific changes in membrane permeability. Similar results were also observed when cells were incubated at pH 5.5-6.0 with higher concentrations of TFP (above 75 microM). On the other hand, low concentrations of TFP (30-50 microM) at pH 5.5-6.0 caused marked membrane hyperpolarization and K+ efflux unaccompanied by the efflux of other cations and by H+ influx. Our experiments indicate that under these conditions K+ efflux was an active process. (1) K+ efflux proceeded only in the presence of a metabolic substrate and was inhibited by metabolic inhibitors. (2) When 0.3-0.9 mM-KCl was present in the medium at pH 6.0, the concentration of K+ within the cells (measured at the end of the incubation with TFP) was much lower than the theoretical concentration of Kin+ if the distribution of K+ between medium and cell water was at equilibrium (at zero electrochemical gradient). (3) Valinomycin decreased the net K+ efflux and decreased the membrane hyperpolarization induced by TFP, probably by increasing the flux of K+ into the cells along its electrochemical gradient. (4) Conditions which led to active K+ efflux also led to a marked decrease in cellular ATP level. The results indicate that under a specific set of conditions TFP induces translocation of K+ against its electrochemical gradient.     

Redox activities in plasma membrane vesicles isolated from papaya (Carica papaya) leaves

Plasma membrane vesicles were isolated from papaya (Carica papaya) leaf cells by a two-phase partition system. Redox activities of these vesicles were determined by ferricyanide reduction and NADH oxidation. Ferricyanide reductase activity was accompanied by continuous acidification of the medium and was stimulated by fusicoccin. NADH oxidase activity was inhibited by catalase.Abbreviations FC fusicoccin - PCMBS parachloromercuri-benzenesulfonic acid     

Transmembrane ferricyanide reduction in carrot cells

Carrot cells (Daucus carota) grown in tissue culture are capable of reducing the non-permeable electron acceptor, ferricyanide, with concomitant proton extrusion from the cell. Optimum conditions for transmembrane ferricyanide reduction include a pH of 7.0-7.5 in a medium containing 10 mM each KCl, NaCl and CaCl2. Data are shown to prove that transmembrane ferricyanide reduction is an enzymatic process. It does not depend on the secretion of phenolics from the cell within the time limits of the assay (10 min). The presence of broken cells and cell fragments are excluded on the basis of stimulation or only slight inhibition by mitochondrial inhibitors. However, transmembrane ferricyanide reduction by carrot cells is inhibited about 50% by various glycolysis inhibitors, which are presumed to reduce the internal levels of NADH. Treatment of cells with p-diazoniumbenzenesulfonic acid, a non-permeant membrane modifying agent, also inhibits transmembrane ferricyanide reduction more than 90%. The data presented support the existence of a transplasma membrane redox system in carrot cells.     

Plasmalemma redox activity and h extrusion in roots of fe-deficient cucumber plants

Cucumber plants (Cucumis sativus L.) with incipient Fe deficiency showed increased root capacity to reduce chelated Fe³⁺ compared to Fe-sufficient plants. When Fe-ethylenediaminete-traacetate was added to the root medium of the Fe-deficient plants, the reductase activity was associated with acidification of the medium and an increase in the net apparent K⁺ efflux. In the presence of the H⁺-ATPase inhibitor N,N′-dicyclohexylcarbodiimide the net apparent H⁺ efflux was completely suppressed, though some reductase activity was preserved, and the net apparent K⁺ efflux was significantly increased. The inhibition of the reductase activity by N,N′-dicyclohexylcarbodiimide was similar whether the pH of the medium was buffered or not. Anoxia and the protonophore carbonyl cyanide m-chlorophenyl hydrazone also caused a similar inhibition of the reductase activity. It is proposed that this redox system transports electrons only and that its activity is inhibited by plasmamembrane depolarization and anoxia. The H⁺ and K⁺ efflux associated with the reductase activity may be a result of the plasmamembrane depolarization it causes.     

Proton-translocating ATPase and lysosomal cystine transport

A proton-translocating ATPase was identified in highly purified lysosomes from Epstein-Barr virus-transformed human lymphoblasts. Activity of this ATPase caused acidification of highly purified, fluorescein isothiocyanate dextran-loaded lysosomes and correlated with the ATP-dependent efflux of lysosomal cystine. The lysosomal ATPase was distinct from mitochondrial F1-ATPase in its responses to a variety of inhibitors. Although ATP-dependent lysosomal cystine efflux is not demonstrable in cultured lymphoblasts from individuals with nephropathic cystinosis, ATPase activity and acidification in lysosomes from these cells is comparable to that in noncystinotic lysosomes. ATPase activity in lymphoblasts from normal individuals was 543 +/- 79 nmol/mg/min while in lymphoblasts from cystinotic individuals this activity was 541 +/- 25 nmol/mg/min. ATP-dependent acidification of lysosomes from normals was -0.5 +/- 0.1 pH units compared to -0.5 +/- 0.1 pH units in cystinotic lysosomes. Activity of the lysosomal proton-translocating ATPase is a necessary, but not sufficient, condition for lysosomal cystine efflux.     

Pyridine nucleotide oxidation by a plasma membrane fraction from red beet (Beta vulgaris L.) storage tissue

The potential role of pyridine nucleotide oxidation in the energization and/or regulation of membrane transport was examined using sealed plasma membrane vesicles isolated from red beet (Beta vulgaris L.) storage tissue. In this system, pyridine nucleotide oxidation, which was enhanced in the presence of ferricyanide, occurred. In the presence or absence of ferricyanide, the oxidation of NADH was several-fold greater than the oxidation of NADPH, indicating that it was the preferred substrate for oxidation in this system. Ferricyanide reduction coupled to NADH oxidation did not require the transmembrane movement of reducing equivalents since ferricyanide incorporated inside the vesicles could not be reduced by NADH added externally to the vesicles, unless the vesicles were made leaky by the addition of 0.05% (v/v) Triton X-100. Using fluorescent probes for the measurement of transmembrane pH gradients and membrane potentials, it was determined that NADH oxidation did not result in the production of a proton electrochemical gradient or have any effect upon the proton electrochemical gradient produced by the plasma membrane H+-ATPase. The oxidation of NADH in the presence of ferricyanide did result in the acidification of the reaction medium. This acidification was unaffected by the addition of Gramicidin D and stimulated by the addition of 0.05% (v/v) Triton X-100, suggesting a scalar (nonvectorial) production of protons in the oxidation/reduction reaction. The results of this study suggest that the oxidation of pyridine nucleotides by plasma membrane vesicles is not related to energization of transport at the plasma membrane or modulation of the activity of the plasma membrane H+-ATPase.     

The mechanism of intracellular acidification induced by glucose in Saccharomyces cerevisiae

Addition of glucose or fructose to cells of Saccharomyces cerevisiae adapted to grow in the absence of glucose induced an acidification of the intracellular medium. This acidification appeared to be due to the phosphorylation of the sugar since: (i) glucose analogues which are not efficiently phosphorylated did not induce internal acidification; (ii) glucose addition did not cause internal acidification in a mutant deficient in all the three sugar-phosphorylating enzymes; (iii) fructose did not affect the intracellular pH in a double mutant having only glucokinase activity; (iv) glucose was as effective as fructose in inducing the internal pH drop in a mutant deficient in phosphoglucose isomerase activity; and (v) in strains deficient in two of the three sugar-phosphorylating activities, there was a good correlation between the specific glucose- or fructose-phosphorylating activity of cell extracts and the sugar-induced internal acidification. In addition, in whole cells any of the three yeast sugar kinases were capable of mediating the internal acidification described. Glucose-induced internal acidification was observed even when yeast cells were suspended in growth medium and in cells suspended in buffer containing K+, which supports the possible signalling function of the glucose-induced internal acidification. Evaluation of internal pH by following fluorescence changes of fluorescein-loaded cells indicated that the change in intracellular pH occurred immediately after addition of sugar. The apparent Km for glucose in this process was 2 mM. Changes in both the internal and external pH were determined and it was found that the internal acidification induced by glucose was followed by a partial alkalinization coincident with the initiation of H+ efflux. This reversal of acidification could be due to the activity of the H+-ATPase, since it was inhibited by diethylstilboestrol. Coincidence between internal alkalinization and the H+ efflux was also observed after addition of ethanol.