Proton electrochemical gradient and rate of controlled respiration in mitochondria

The correlation between deltamuH, the proton electrochemical potential difference, and the rate of controlled respiration is analyzed. deltamuH (the proton concentration gradient) is measured on the distribution of [3H]acetate, and deltapsi (the membrane potential) on the distribution of 86Rb+, 45Ca2+ and [3H]triphenylmethylphosphonium used either alone or simultaneously. The effects of the addition of ADP + hexokinase (state-3 ADP) and of carbonylcyanide trifluoromethoxyphenylhydrazone (state-3 uncoupler) on respiration and deltamuH are not equivalent: the uncoupler depresses deltamuH more than ADP at equivalent respiratory rates. The effects of the additions of nigericin-valinomycin and of ionophore A23187 (state-3 cation transport) and of carbonylcyanide trifluoromethoxy-phenylhydrazone (state 3-uncoupler) on respiration and deltamuH are also not equivalent: the uncoupler depresses deltamuH more than A23187 and nigericin + valinomycin at equivalent respiratory rate. A23187 is very efficient in stimulating respiration with negligible deltamuH changes.     

Proton electrochemical gradient and phosphate potential in submitochondrial particles.

The aerobic uptake of inorganic ions, such as 86Rb+ or 125I-, by submitochondrial particles, is about one order of magnitude lower than the uptake of organic ions, such as acridines or 8-anilino-1-naphthalene sulphonate. The values of deltapH, the transmembrane pH differential, and deltapsi, the transmembrane membrane potential are between 60 and 100 mV when calculated on the inorganic ions and between 150 and 240 mV when calculated on the organic ions. The discrepancy between the deltapH and deltapsi values from organic and inorganic ions is large at high but not at low ion/protein ratios. 2. In the absence of weak bases and strong acids the values of deltamuH, the proton electrochemical potential difference, are close to 100 mV and the magnitude of deltapH and deltapsi are similar. Weak bases decrease deltapH and enhance deltapsi. Strong acids decrease deltapsi and enhance deltapH. Interchangeability of deltapH with deltapsi occurs at low concentrations of weak bases and strong acids. High concentrations of weak bases and strong acids cause depression of deltamuH. 3. Concentrations of weak bases capable of abolishing deltapH, do not affect ATP synthesis. Concentrations of strong acids capable of abolishing deltapsi affect only slightly ATP synthesis. Concentrations of weak bases and strong acids capable of causing a decline of deltapH + deltapsi inhibit ATP synthesis. 4. Depression of deltamuH is paralleled by inhibition of ATP synthesis and decline of deltaGp, the phosphate potential. Abolition of ATP synthesis occurs only when deltamuH is below 20 mV. The deltaGp/deltamuH ratio increases hyperbolically with the decrease of deltamuH.     

Reconstruction of highly purified proton-translocating pyrophosphatase from Rhodospirillum rubrum

Using the freezing-thawing procedure, a highly purified preparation of PPase from R. rubrum chromatophore membranes was incorporated into soybean phospholipid liposomes. The activity of reconstituted PPase was increased in the presence of the uncoupler, FCCP, and the antibiotics, valinomycin (+KCl) and nigericin (+KCl). Oligomycin did not exert any inhibiting action, while imidodiphosphate and NaF significantly decreased the activity of the PPase incorporated into the liposomes. Preincubation of both PPase and ATPase prior to their incorporation into the liposomes did not affect the activity of the reconstituted enzyme. It was concluded that the PPase from R. rubrum chromatophores when incorporated into the liposomes may function as a proton pump independently of the ATPase.     

Role of proton motive force in genetic transformation of Bacillus subtilis

This study explored the role of the proton motive force in the processes of DNA binding and DNA transport of genetic transformation of Bacillus subtilis 168 strain 8G-5 (trpC2). Transformation was severely inhibited by the ionophores valinomycin, nigericin, and 3,5-di-tert-4-hydroxybenzylidenemalononitrite (SF-6847) and by tetraphenylphosphonium. The ionophores valinomycin and nigericin also severely inhibited binding of transforming DNA to the cell envelope, whereas SF-6847 and carbonylcyanide-p-trifluoromethoxyphenylhydrazone hardly affected binding. The proton motive force, therefore, does not contribute to the process of DNA binding, and valinomycin and nigericin interact directly with the DNA binding sites at the cell envelope. The effects of ionophores, weak acids, and tetraphenylphosphonium on the components of the proton motive force and on the entry of transforming DNA after binding to the cell envelope was investigated. DNA entry, as measured by the amount of DNase I-resistant cell-associated [3H]DNA and by the formation of DNA breakdown products, was severely inhibited under conditions of a small proton motive force and also under conditions of a small delta pH and a high electrical potential. These results suggest that the proton motive force and especially the delta pH component functions as a driving force for DNA uptake in transformation.     

Regulation of gastric acid secretion via modulation of a chloride conductance

When gastric microsomes were purified from resting and stimulated rabbit mucosae, they were found to be generally similar in (H+ + K+)-ATPase activity, peptide composition in single-dimension sodium dodecyl sulfate-gel electrophoresis, and in size. In the stimulated vesicles, optimal proton transport activity was found at pH 7.4, 20-50 mM KCl, and 1 mM ATP-Mg. However, in the case of resting vesicles, the presence of valinomycin and an inward Cl-gradient was also necessary for Mg-ATP-dependent proton transport. Measurement of K+ and Cl-diffusion potentials using 3,3-dipropylthiadicarboxocyanine iodide as a potential sensitive dye showed that both resting and stimulated vesicles developed K+ gradient-dependent potentials in the presence of an impermeant anion, but that Cl- gradient-dependent potentials were observed only in the stimulated preparation. 86Rb+ self-exchange was found in both types of vesicles, but Cl- self-exchange was confined to vesicles derived from stimulated mucosae. Putative inhibitors of anion conductance such as furosemide and anthracene 9-carboxylic acid blocked proton transport, Cl- conductance, 36Cl- uptake, and Cl- exchange. The inhibition of proton transport was overcome by valinomycin. ATPase activity in the presence of nigericin, an H+:K+ exchanger, was unaffected by these inhibitors. K+ conductance, Rb+ uptake, and Rb+ exchange were insensitive to these inhibitors. Thus, activation of acid secretion by the stimulated parietal cell appears to involve at least the appearance of a discrete Cl- conductance in the pump-associated membrane.     

Energetics of Leucyl-Leucine Hydrolysis in Streptococcus cremoris Wg(2)

The hydrolysis of the dipeptide leucyl-leucine by whole cells of Streptococcus cremoris Wg(2) was dependent on the presence of the energy source lactose. Incubation of cells with uncouplers or ATPase inhibitors prevented the increase of peptidase activity upon the addition of lactose. Incubation with the ionophore nigericin resulted in decreased peptide hydrolysis activity, while incubation with valinomycin led to increased hydrolysis activity. In the presence of nigericin the DeltapH component of the proton motive force was decreased, while the electrical potential was increased. With valinomycin, the electrical potential was collapsed and the DeltapH was increased. When the external pH was decreased from 8 to 5, the rate of peptide hydrolyzing activity by whole cells increased with increasing DeltapH component. In contrast, the peptide hydrolyzing activity in the cell extract decreased with decreasing external pH. These results indicate that the DeltapH component of the proton motive force determines the leucyl-leucine hydrolyzing activity in S. cremoris Wg(2).     

Factors affecting the development of the capacity for ATP formation in isolated chloroplasts

Full development of the capacity for ATP formation in isolated thylakoid membranes coincides with the beginning of illumination. Indeed, the yield of ATP per ms of illumination is about twice as great during the first 15 ms of high-intensity illumination as it is thereafter. The presence of valinomycin and K⁺ prevents the formation of a membrane potential (as indicated by the obliteration of most of the change in absorbance at 518 nm) and at the same time delays the formation of the capacity for ATP synthesis for many milliseconds. Presumably, phosphorylation is initially dependent on a rapidly formed membrane potential, whereas after a delay a ΔpH sufficient to drive ATP formation forms. The actual duration of this delay depends on the phosphoryl group transfer potential (i.e., ΔG_ATP) of the ATP-synthesizing reaction. If the delay in the presence of valinomycin and K⁺ represents the time required to develop a ΔpH capable of driving phosphorylation by itself, then the effect of ΔG_ATP on the duration of the delay suggests that the onset of phosphorylation is determined by the magnitude of the electrochemical potential of protons and not by factors affecting the activation of the coupling factor enzyme. The initial ATP formation, which is almost entirely dependent on the electrical potential, should not be affected by the electrically neutral exchange of cations catalyzed by nigericin. When the external pH is 7.0 this seems to be true, since the ATP synthesis which is initially sensitive to valinomycin and K⁺ is largely insensitive to nigericin and K⁺. However, when the external pH is 8.0 the response to nigericin is exactly the opposite and the ATP formation which is sensitive to valinomycin is also abolished by nigericin. These data suggest that there may be either an energetic requirement for both a ΔpH and membrane potential at alkaline pH or a non-energetic requirement for a minimum proton activity in the initiation of phosphorylation.     

The lysosomal proton pump is electrogenic

Lysosomes were purified approximately 40-fold from rat kidney cortex by differential and Percoll density gradient centrifugation. In a sucrose medium, the lysosomes quenched the fluorescence of the potential sensitive dye diS-C3-(5) (3,3'-dipropylthiocarbo-cyanine iodide) in a time-dependent manner, indicating that the dye accumulates within the lysosomal interior. After treatment of the lysosomes with valinomycin, the dye fluorescence displayed a logarithmic dependence upon the external K+ concentration; thus, the fluorescence signal provides a semiquantitative measure of the lysosomal membrane potential (delta psi). In the absence of valinomycin, lysosomal quenching of diS-C3-(5) fluorescence was partially reversed by agents which collapse the lysosomal pH gradient (ammonium sulfate, chloroquine, and K nigericin), suggesting that the proton gradient across the lysosomal membrane contributes to delta psi. A rapid increase in diS-C3-(5) fluorescence, indicative of an increase in delta psi, was observed upon the addition of Mg-ATP to the lysosomes. The ATP-dependent fluorescence change was inhibited by protonophores, K valinomycin, permeable anions, and N-ethylmaleimide, but was unaffected by ammonium sulfate, K nigericin, or sodium vanadate. Oligomycin had no effect at concentrations below 2 micrograms/ml; at higher concentrations, oligomycin partially inhibited the fluorescence response to Mg-ATP, but it also inhibited the fluorescence response to K valinomycin, suggesting that it had modified the permeability of the lysosomal membrane. Dicylohexylcarbodiimide behaved similarly to oligomycin. Mg-ATP also altered the lysosomal distribution of 86Rb+ (in the presence of valinomycin) and S[14C]CN-, consistent with an increase in the potential of the lysosomal interior of 40-50 mV. The results demonstrate that the lysosomal proton pump is electrogenic.     

Energy dependent hydrogen ion accumulation in submitochondrial particles.

The fluorescence quenching of 9-aminoacridine (9AA) in suspension of beef heart EDTA submitochondrial particles was studied and was used to calculate the pH gradient between these particles and the medium. This pH gradient, which is energy dependent, is also dependent strongly on the presence of anion species in the medium. It is 2.2 pH units in acetate medium and can be as high as 3.6 units in the presence of other highly lyophilic anions. The anions tested were found to be effective in the following order: SCN- greater than I- greater than NO3- greater than Br- greater than Cl-. The validity of the deltapH calculations was confirmed by comparison with deltapH values calculated from NH4+ uptake. In contrast, calculations based on quinacrine (QA) fluorescence quenching under the same assumption used for 9AA did not agree with NH4+ measurements and show quantitative and in some cases even qualitative differences. Both carbonyl cyanide p-trifluoromethoxyphenylhydrazone and NH4+ decreased deltapH significantly. When the rate of electron transport is slow, i.e., with succinate as substrate or with NADH and low concentration of rotenone, very low concentration of nigericin (less than 20 ng/ml) decreased deltapH. Under these conditions, valinomycin antagonized the nigericin effect and restored deltapH to its original value. Upon increasing nigericin concentration (greater than 100 ng/ml) the valinomycin effect is gradually replaced by a slower response of further reduction of deltapH.     

Temperature jump as a new technique to study the kinetics of fast transport of protons across membranes

Application of a temperature jump (2.5 degrees C) to a suspension of liposomes, having phosphate (delta pK/delta T approximately 0.005) as the internal buffer and tris(hydroxymethyl)aminomethane (delta pK/delta T approximately 0.031) as the external buffer, created a delta pH (pHin - pHout) of positive sign in ca. 5 microseconds. Decay of this delta pH was monitored by using the fluorescent pH indicator 8-hydroxy-1,3,6-pyrenetrisulfonic acid entrapped inside the liposome. This technique is useful to study transmembrane proton movement in the time range 5 microseconds-10 s at physiological pH values. The kinetics of proton transport aided by ion carriers such as nigericin, monensin, carbonyl cyanide m-chlorophenylhydrazone (CCCP), and valinomycin were studied by our method. The electrogenic nature of transport by CCCP and valinomycin and electroneutral ion transport by nigericin and monensin were shown. From the kinetics of proton transport aided by gramicidin, the time-averaged single-channel conductance of gramicidin channels was estimated to be (2.1 +/- 0.5) X 10(-16) S for H+ at pH 7.5.     

In vitro translocation of protein across Escherichia coli membrane vesicles requires both the proton motive force and ATP

The energy requirement for protein translocation across membrane was studied with inverted membrane vesicles from an Escherichia coli strain that lacks all components of F1F0-ATPase. An ompF-lpp chimeric protein was used as a model secretory protein. Translocation of the chimeric protein into membrane vesicles was totally inhibited in the presence of carbonyl cyanide m-chlorophenylhydrazone (CCCP) or valinomycin and nigericin and partially inhibited when either valinomycin or nigericin alone was added. Depletion of ATP with glucose and hexokinase resulted in the complete inhibition of the translocation process, and the inhibition was suppressed by the addition of ATP-generating systems such as phosphoenolpyruvate-pyruvate kinase or creatine phosphate-creatine kinase. These results indicate that both the proton motive force and ATP are required for the translocation process. The results further suggest that both the membrane potential and the chemical gradient of protons (delta pH), of which the proton motive force is composed, participate in the translocation process.     

Effect of 2,4-dinitrophenol and ionophores on growth and methanogenesis inMethanobacterium thermoautotrophicum

2,4-Dinitrophenol and gramicidin D completely inhibited growth and methanogenesis inMethanobacterium thermoautotrophicum. At low K⁺ concentrations valinomycin inhibited growth and methanogenesis relatively slightly, at high K⁺ concentrations (0.1m KCl) growth was inhibited completely and methanogenesis by about 50%. Monensin and nigericin inhibited growth completely; methanogenesis was inhibited like with valinomycin at high K⁺ concentrations. The results can be interpreted in terms of Mitchell’s chemiosmotic theory as follows. The protonmotive force inM. thermoautotrophicum is the basic source of energy for endergonic processes. Dissipation of the electrical component of protonmotive force may probably be compensated by an increased generation of the proton gradient. However, the osmotic component is essential for growth ofM. thermoautotrophicum.     

Energetics of Leucyl-Leucine Hydrolysis in Streptococcus cremoris Wg2

The hydrolysis of the dipeptide leucyl-leucine by whole cells of Streptococcus cremoris Wg₂ was dependent on the presence of the energy source lactose. Incubation of cells with uncouplers or ATPase inhibitors prevented the increase of peptidase activity upon the addition of lactose. Incubation with the ionophore nigericin resulted in decreased peptide hydrolysis activity, while incubation with valinomycin led to increased hydrolysis activity. In the presence of nigericin the ΔpH component of the proton motive force was decreased, while the electrical potential was increased. With valinomycin, the electrical potential was collapsed and the ΔpH was increased. When the external pH was decreased from 8 to 5, the rate of peptide hydrolyzing activity by whole cells increased with increasing ΔpH component. In contrast, the peptide hydrolyzing activity in the cell extract decreased with decreasing external pH. These results indicate that the ΔpH component of the proton motive force determines the leucyl-leucine hydrolyzing activity in S. cremoris Wg₂.     

pH-dependent changes in proton:substrate stoichiometries during active transport in Escherichia coli membrane vesicles.

Experiments are presented in which the proton electrochemical gradient (deltamuH+) IN Escherichia coli membrane vesicles (interior negative and alkaline) was measured under a variety of conditions and compared with steady-state levels of accumulation of lactose, proline, D-lactate, and glucose-6-P measured under identical conditions. Accumulation of lactose and proline is proportional to the magnitude of deltamuH+ at pH 5.5, where the pH gradient (deltapH) and the electrical potential (deltapsi) both contribute to deltamuH+, and at pH 7.5, where deltapsi represents the only component of deltamuH+. Moreover, the proportionality constants between deltamuH+ and lactose or proline accumulation indicate that the proton:substrate stoichiometries are 1:1 at pH 5.5 and 2:1 at pH 7.5. Evidence is also presented which indicates that the functional group responsible for the increase in proton:proline stoichiometry has a pK of approximately 6.8. Accumulation of D-lactate and glucose-6-P is directly related to the magnitude of deltapH at pH 5.5, and stoichiometry values of one and approximately 1.7 are obtained for D-lactate and glucose-6-P, respectively, at this pH. At pH 7.5, on the other hand, accumulation of each organic acid bears a linear relationship to deltapsi, and proton:substrate stoichiometries of unity are observed in both instances. The results are consistent with the models discussed by Rottenberg (Rottenberg, H. (1976), FEBS Lett. 66, 159).     

An estimation of the light-induced electrochemical potential difference of protons across the membrane of Halobacterium halobium.

The light-dependent uptake of triphenylmethylphosphonium (TPMP+) and of 5,5-dimethyloxazolidine-2,4-dione (DMO) by starved purple cells of Halobacterium halobium was investigated. DMO uptake was used to calculate the pH difference (deltapH) across the membrane, and TPMP+ was used as an index of the electrical potential difference, deltapsi. Under most conditions, both in the light and in the dark, the cells are more alkaline than the medium. In the light at pH 6.6, deltapH amounts to 0.6-0.8 pH unit. Its value can be increased to 1.5-2.0 by either incubating the cells with TPMP+ (10(-3) M) or at low external pH (5.5). --deltapH can be lowered by uncoupler or by nigericin. The TPMP+ uptake by the cells indicates a large deltapsi across the membrane, negative inside. It was estimated that in the light, at pH 6.6, deltapsi might reach a value of about 100 mV and that consequently the electrical equivalent of the proton electrochemical potential difference, deltamuH+/F, amounts under these conditions to about 140 mV. The effects of different ionophores on the light-drive proton extrusion by the cells were in agreement with the effects of these compounds on --deltapH.     

Thermodynamics of the electrochemical proton gradient in bovine heart submitochondrial particles.

The electrical and chemical components of the electrochemical proton gradient of submitochondrial particles can be monitored simultaneously by continuously recording optical signals from the probes oxonol-VI and 9-aminoacridine. Either respiration or ATP hydrolysis causes a red shift in the absorption spectrum of oxonol-VI indicative of a membrane potential and a decrease of the fluorescence of 9-aminoacridine indicative of a pH gradient. The magnitude of the membrane potential and pH gradient formed by respiring submitochondrial particles can be modulated by the thermodynamic phosphorylation potential (deltaGp) of the adenine nucleotide system. deltaGp is the Gibbs free energy of ATP synthesis and is defined by the relationship deltaGp = -deltaG'o + RTln([ATP]/[ADP][Pi] where deltaG'o is the standard free energy of ATP hydrolysis. Increasing values of deltaGp cause an increase in the steady state magnitudes of both the membrane potential and pH gradient. Thermodynamic phosphorylation potential titration experiments indicate that the electrochemical proton gradient normally maintained by respiring submitochondrial particles has an energy equivalent to 10.5 to 10.9 kcal/mol.     

Transmembrane electrical potential affects the lipid composition of Acholeplasma laidlawii

In membranes of Acholeplasma laidlawii, lipid composition is regulated as a function of several stimuli affecting the volume and length of the hydrocarbon chains and the hydrocarbon-water interfacial area. This regulation is vizualized as changes in the relative amounts of the major polar lipids monoglucosyl diglyceride and diglucosyl diglyceride. These lipids form reversed hexagonal and lamellar phases with water, respectively. However, mixtures of the two lipids, in the molar proportions found in the A. laidlawii membrane, form a lamellar phase. By adjustment of the glycolipid ratio as a response to environmental stimuli, a certain stability of the lamellar membrane is maintained. In growing cells with oleoyl membrane lipids, a transmembrane electrical potential of approximately -50 mV (inside negative), but no transmembrane pH difference, was found. Addition of the K+ ionophore valinomycin caused a rapid and dose-dependent hyperpolarization remaining for at least 7 h. Simultaneously, a rapid and lasting metabolic decrease in the ratio monoglucosyl diglyceride/diglucosyl diglyceride occurred. The increase in potential and the decrease in the lipid ratio were both reversed in a dose-dependent manner by extracellular KCl. Likewise, the lipophilic cation tetraphenylphosphonium caused a dose-dependent decrease in membrane potential and an increase in the monoglucosyl diglyceride/diglucosyl diglyceride ratio, respectively. The ionophores monensin and particularly nigericin had similar but less pronounced effects on the potential and lipid ratios as valinomycin. The uncoupler carbonyl cyanide m-chlorophenylhydrazone had no effect on cell growth, membrane potential, or lipid regulation at 10 microM. These dissimilar structures and the low concentrations used make a direct disturbance of drug molecules on lipid packing in membranes less likely.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton movements and electric potential generation in reconstituted ATPase proteoliposomes from the thermophilic cyanobacterium Synechococcus 6716

ATP hydrolysis-induced proton translocation and electric potential generation have been studied in ATPase proteoliposomes by means of various optical probes. The proteoliposomes consisted of reconstituted ATPase complex and native lipid mixture isolated from the thermophilic cyanobacterium Synechococcus 6716 [Van Walraven et al. (1983) Eur. J. Biochem. 137, 101-106]. The native cartenoids and added oxonol VI served as probes for the electric membrane potential generated by the net charge separation (negative outside, positive inside). Their responses, with similar half-times as 9-tetradecylamino-6-chloro-2-methoxyacridine, are sensitive to valinomycin and stimulated by nigericin, as expected. The proton concentrations of extraliposomal and intraliposomal aqueous spaces were monitored by neutral red and cresol red; for internal measurements these pH indicators were trapped inside the vesicles during detergent dialysis. Internal acidification and external alkalinization induced by ATP hydrolysis are inhibited by nigericin and enhanced by valinomycin; at the commonly used higher valinomycin concentrations the neutral red response becomes transient, while the much slower cresol red response is diminished right from its onset. At smaller preset pH gradients both ATP hydrolysis activity and neutral red response are diminished. At increasing MgCl2 concentrations the neutral red responses are slowed down and the cresol red responses are slightly enhanced; this is observed for both internal and external dye responses. Neutral red permeation through the membrane is insignificant under our experimental conditions but is enhanced at temperatures below the lipid-phase transition. In the case of externally added neutral red the non-permeant buffer Hepes is only effective at high MgCl2 concentration, whereas some external cresol red response is visible only at high MgCl2 concentration in the presence of Hepes. The kinetics of the pH indicator and electric potential probe responses clearly distinguish fast interfacial and intra-membrane proton displacements from slow bulk proton equilibration. The data are summarized in a model that supports the importance of localized proton displacements for the primary energy-transducing events.     

Energy coupling to nitrate uptake into the denitrifying cells of Paracoccus denitrificans

This study deals with the effects of the agents that dissipate the individual components of the proton motive force (short-chain fatty acids, nigericin, and valinomycin) upon the methyl viologen-coupled nitrate reductase activity in intact cells. Substitution of butyrate or acetate for chloride in Tris-buffered assay media resulted in a marked inhibition at pH 7. In a Tris-chloride buffer of neutral pH, the reaction was almost fully inhibitable by nigericin. Alkalinisation increased the IC₅₀ value for nigericin and decreased the maximal inhibition attained. Both types of inhibitions could be reversed by the permeabilisation of cells or by the addition of nitrite, and that caused by nigericin disappeared at high extracellular concentrations of potassium. These data indicate that nitrate transport step relies heavily on the pH gradient at neutral pH. Since the affinity of cells for nitrate was strongly diminished by imposing an inside-positive potassium (or lithium) diffusion potential at alkaline external pH, a potential dependent step may be of significance in the transporter cycle under these conditions. Experiments with sodium-depleted media provided no hints for Na⁺ as a possible H⁺ substitute.     

Effects of salts and ionophores on proline transport in a moderately halopholic halotolerant bacterium

The effect of salt on proline uptake in a moderately halophilic halotolerant bacterium was studied. Cells were grown either on low salt or high salt media. A correlation was found between the salt concentrations in the growth media and the optimal concentration for uptake. The uptake rate was stimulated 2--3-fold by NaCl, as compared to KCl. The Km, V and activation energies values for proline uptake, as well as the external pH effect, were similar in low-salt-grown cells and high-salt-grown cells. This suggests that the halotolerance of the transport system is not due to alterations of the system during growth at various conditions, but rather to its intrinsic ability to function under extreme environmental conditions. The uptake was inhibited by cyanide and carbonyl cyanide m-chlorophenylhydrazone, but not by arsenate, indicating that the electrochemical proton gradient (delta mu- H+), generated by respiration, is the main driving force for proline transport. In low-salt-grown cells, at pH 6.0, partial inhibition was exerted by nigericin or valinomycin, whereas at pH 8.0 the uptake was inhibited by valinomycin only. Similar, although less pronounced effects were found in high-salt-grown cells. The data suggest that at pH 6.0 proline transport is driven by delta mu- H+ (composed of electrical potential (delta psi) and pH gradient), whereas at pH 8.0 delta psi is the main driving force. Procedures of pretreatment with EDTA were developed to enable the penetration of the ionophores into the cells.