Endogenous energy supply to the plasma membrane of dark aerobic cyanobacterium Anacystis nidulans: ATPase-independent efflux of H+ and Na+ from respiring cells

The ejection of protons from oxygen-pulsed cells and the gradients of Na+ concentration (Na+o/Na+i at 150 mM external NaCl) and proton electrochemical potential (delta mu H+) across the plasma membrane of Anacystis nidulans were studied in response to dark endogenous energy supply. Saturating concentrations of the F0F1-ATPase inhibitors dicyclohexylcarbodiimide (F0) and 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (F1) eliminated oxidative phosphorylation and lowered the ATP level from 2.6 +/- 0.15 to 0.7 +/- 0.1 nmol/mg dry wt while overall O2 uptake and delta mu H+ were much less affected. H+ efflux was inhibited only 60 to 75%. Aerobic Na+o/Na+i ratios (5.9 +/- 0.6) under these conditions remained 50% above the anaerobic level (2.1 +/- 0.2). Increasing concentrations of the electron transport inhibitors CO and KCN depressed H+ efflux and O2 uptake in parallel, with a pronounced discontinuity of the former at inhibitor concentrations, which reduced ATP levels from 2.6 to 0.8 nmol/mg dry wt, resulting in an abrupt shift of the apparent H+/O ratios from 4.0 +/- 0.3 to 1.9 +/- 0.2. Similarly, with KCN and CO the Na+o/Na+i ratios paralleled decreasing respiration rates more closely than decreasing ATP pool sizes. Ejection of protons also was observed when intact spheroplasts were pulsed with horse heart ferrocytochrome c or ferricyanide; the former reaction was inhibited, the latter was increased, by 1 mM KCN. Measurements of the proton motive force (delta mu H+) across the plasma membrane showed a strong correlation with respiration rates rather than ATP levels. It is concluded that the plasma membrane of intact A. nidulans can be directly energized by proton-translocating respiratory electron transport in the membrane and that part of this energy may be used by a Na+/H+ antiporter for the active exclusion of Na+ from the cell interior.     

The proton motive force generated in Leuconostoc oenos by L-malate fermentation.

In cells of Leuconostoc oenos, the fermentation of L-malic acid generates both a transmembrane pH gradient, inside alkaline, and an electrical potential gradient, inside negative. In resting cells, the proton motive force ranged from -170 mV to -88 mV between pH 3.1 and 5.6 in the presence Of L-malate. Membrane potentials were calculated by using a model for probe binding that accounted for the different binding constants at the different pH values at the two faces of the membrane. The delta psi generated by the transport of monovalent malate, H-malate-, controlled the rate of fermentation. The fermentation rate significantly increased under conditions of decreased delta psi, i.e., upon addition of the ionophore valinomycin in the presence of KCl, whereas in a buffer depleted of potassium, the addition of valinomycin resulted in a hyperpolarization of the cell membrane and a reduction of the rate of fermentation. At the steady state, the chemical gradient for H-malate- was of the same magnitude as delta psi. Synthesis of ATP was observed in cells performing malolactic fermentation.     

Magnitude of the proton moving force of Staphylococcus aureus cells and features of the interaction of staphylococci with phages

The magnitude of the transmembrane electrical potential difference and the proton gradient across the energy-transducing membrane of Staphylococcus aureus were determined. The delta psi value was shown to rise from 100 to 160 mV upon alkalinization of the medium within the pH range of 5.0-8.0; at the same time, the pH value dropped from 90 to 40 mV. The proton motive force magnitude remained within the range of 191-198 mV at the pH values under study. Membrane potential generation took place, when the respiratory chain and H+-ATPase were operative. An addition of phages to cell suspensions resulted in a decrease of the membrane potential magnitude. Phage infection was effectively suppressed by inhibitors which affect the proton motive force generation in cell membranes of staphylococci.     

Oxygen taxis and proton motive force in Salmonella typhimurium

The aerotactic response of Salmonella typhimurium SL3730 has been quantitatively correlated with a change in the proton motive force (delta p) as measured by a flow-dialysis technique. At pH 7.5, the membrane potential (delta psi) in S. typhimurium changed from -162 +/- 13 to -111 +/- 15 mV when cells grown aerobically were made anaerobic, and it returned to the original value when the cells were returned to aerobiosis. The delta pH across the membrane was zero. At pH 5.5, delta psi was -70 mV in aerobiosis and -20 mV in anaerobiosis, and delta pH was -118 and -56 mV for aerobic and anaerobic cells, respectively. A decrease in delta p resulted in increased tumbling, and an increase in delta p resulted in a smooth swimming response at either pH. Inhibition of aerotaxis at pH 7.5 by various concentrations of KCN correlated with a decreased delta p, due to a decreased delta psi in aerobiosis and little change in delta psi in anaerobiosis. At concentrations up to 100 mM, 2,4-dinitrophenol decreased delta psi, but did not inhibit aerotaxis because the difference between delta psi in aerobic and anaerobic cells remained constant. Considered as a whole, the results indicate that aerotaxis in S. typhimurium is mediated by delta p.     

Map location of the pcbA mutation and physiology of the mutant.

The obligate aerobe Cowpea Rhizobium sp. strain 32H1 in axenic culture is able to fix N2 when grown under 0.2% O2 but not when grown under 21% O2. It was, therefore, of interest to investigate ATP synthesis in these cells grown under the two conditions. When respiring in buffers having pHs ranging from 6 to 8.5, cells grown under either O2 tension maintained an intracellular pH more alkaline than the exterior. The transmembrane chemical gradient of H+ (delta pH) was essentially the same under both conditions of growth, decreasing from ca. 90 mV at medium pH 6 to ca. 30 mV at pH 8.5. However, the transmembrane electrical gradient (delta psi) was significantly higher in cells grown under 21% O2 (150 to 166 mV) than in cells grown under 0.2% O2, the latter being 16 mV at pH 6 and increasing to 88 mV at pH 8.5. Therefore, the proton motive force of 21% O2-grown cells ranged from 237 mV at external pH 6 to 185 mV at pH 8.5, compared with a proton motive force of 114 to 121 mV in the 0.2% O2-grown cells. The cells grown in 0.2% O2 had the same proton motive force whether tested at 21 or at 0.2% O2. The phosphorylation potential, calculated from the intracellular ATP, ADP, and Pi concentrations, was 424 mV in the 21% O2-grown cells and 436 mV in the 0.2% O2-grown cells. Thus, the 21% O2-grown cells translocated 1.8 to 2.3 H+/ATP synthesized by the H+-ATPase, whereas the H+/ATP ratio for 0.2% O2-grown cells was 3.7 to 3.8.     

Transmembrane Proton Electrochemical Gradients in Dark Aerobic and Anaerobic Cells of the Cyanobacterium (Blue-Green Alga) Anacystis nidulans: Evidence for Respiratory Energy Transduction in the Plasma Membrane

The transmembrane proton electrochemical potential gradient Δμ_H+ in whole cells of Anacystis nidulans was measured in aerobic and anaerobic dark conditions using the distribution, between external medium and cell interior, of radioactively labeled weak acids (acetylsalicyclic acid, 5,5-dimethyloxazolidine-2,4-dione) or bases (imidazole, methylamine), and permeant ions (tetraphenylphosphonium cation, thiocyanate anion), as determined by flow dialysis. Alternatively, the movements across the plasma membrane of ΔpH-indicating atebrin or 9-aminoacridine, and of ΔΨ-indicating 8-anilino-l-naphthalenesulfonate were qualitatively followed by fluorescence measurements. Attempts were made to discriminate between the individual chemiosmotic gradients across the cytoplasmic (plasmalemma) and the intracytoplasmic (thylakoid) membranes. By use of the ionophores nigericin, monensin, and valinomycin, the components of the proton motive force, namely the proton concentration gradient ΔpH and the electric membrane potential ΔΨ were shown to be mutually exchangeable within the range of external pH values tested (3.2-11.0). Both components were depressed by the uncoupler carbonylcyanide m-chlorophenylhydrazone, though inhibition of ΔpH was much more pronounced than that of ΔΨ, notably in the alkaline pH₀ range. The total proton electrochemical gradient across the plasma membrane was significantly higher in aerobic than in anaerobic cells and increased markedly (i.e. became more negative) towards lower pH₀ values. This increase was paralleled by a similar increase in the rate of endogenous respiration of the cells. At the same time the ATPase inhibitor dicyclohexylcarbodiimide only slightly affected the proton motive force across the plasma membrane of aerobic cells. The results will be discussed in terms of a respiratorily competent plasma membrane in Anacystis nidulans.     

Effects of aerobiosis and nitrogen source on the proton motive force in growing Escherichia coli and Klebsiella pneumoniae cells.

The electrochemical gradient of hydrogen ions, or proton motive force (PMF), was measured in growing Escherichia coli and Klebsiella pneumoniae in batch culture. The electrical component of the PMF (delta psi) and the chemical component (delta pH) were calculated from the cellular accumulation of radiolabeled tetraphenylphosphonium, thiocyanate, and benzoate ions. In both species, the PMF was constant during exponential phase and decreased as the cells entered stationary phase. Altering the growth rate with different energy substrates had no effect on the PMF. The delta pH (alkaline inside) varied with the pH of the culture medium, resulting in a constant internal pH. During aerobic growth in media at pH 6 to 7, the delta psi was constant at 160 mV (negative inside). The PMF, therefore, was 255 mV in cells growing at pH 6.3, and decreased progressively to 210 mV in pH 7.1 cultures. K. pneumoniae cells and two E. coli strains (K-12 and ML), including a mutant deficient in the H+-translocating ATPase and a pleiotropically energy-uncoupled mutant with a normal ATPase, had the same PMF during aerobic exponential phase. During anaerobic growth, however, both species had delta psi values equal to 0. Therefore, the PMF in anaerobic cells consisted only of the delta pH component, which was 75 mV or less in cells growing at pH 6.2 or greater. These data thus met the expectation that cells deriving metabolic energy from respiration have a PMF above a threshold value of about 200 mV when the ATPase functions in the direction of H+ influx and ATP synthesis; in fermenting cells, a PMF below a threshold value was expected since the enzyme functions in the direction of H+ extrusion and ATP hydrolysis. K. pneumoniae cells growing anaerobically had no delta psi whether the N source added was N2, NH+4 or one of several amino acids; the delta pH was unaffected. Therefore, any energy cost incurred by the process of nitrogen fixation could not be detected as an alteration of the proton gradient.     

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.     

Proton motive force across the membrane of Mycoplasma gallisepticum and its possible role in cell volume regulation.

A proton motive force (delta (-) microH+) of 70 to 130 mV was measured across the membrane of Mycoplasma gallisepticum cells. The membrane potential was measured utilizing the lipid-soluble cation tetraphenylphosphonium. The method was validated by showing that in the presence of valinomycin the ratio of the concentrations (in/out) of tetraphenylphosphonium agreed well with those for K+ and Rb+. The pH gradient was calculated from the measured distribution ratio of benzoic acid. The proton motive force was approximately the same in cells harvested at early exponential, midexponential, and stationary phases of growth. The proportion of pH gradient to membrane potential varied with external pH. In the absence of glucose, cells incubated in an isosmotic NaCl solution showed low adenosine triphosphate and delta (-) microH+ levels and a tendency to swell and lyse compared with cells incubated with added glucose. It is concluded that energy is required for normal cell volume regulation.     

Proton motive force in growing Streptococcus lactis and Staphylococcus aureus cells under aerobic and anaerobic conditions.

Measurements of the electrochemical gradient of hydrogen ions, which gives rise to the proton motive force (PMF), were carried out with growing Streptococcus lactis and Staphylococcus aureus cells. The facultative anaerobe was chosen in order to compare the PMF of cells growing aerobically and anaerobically. It was expected that during aerobic growth the cells would have a higher PMF than during anaerobic growth, because the H+-translocating ATPase (BF0F1) operates in the direction of H+ influx and ATP synthesis during respiration, whereas under anaerobic conditions the BF0F1 hydrolyzes glycolytically generated ATP and establishes the proton gradient by extruding H+. The electrical component of the PMF, delta psi, and the chemical gradient of H+, delta pH, were measured with radiolabeled tetraphenylphosphonium and benzoate ions. In both S. lactis and S. aureus cells, the PMF was constant during the exponential phase of batch growth and decreased in the stationary phase. In both species of bacteria, the exponential-phase PMF was not affected by varying the growth rate by adding different sugars to the medium. The relative contributions of delta psi and delta pH to the PMF, however, depended on the pH of the medium. The internal pH of S. aureus was constant at pH 7.4 to 7.6 under all conditions of growth tested. Under aerobic conditions, the delta psi of exponential phase S. aureus remained fairly constant at 160 to 170 mV. Thus, the PMF was 250 to 270 mV in cells growing aerobically in media at pH 6 and progressively lower in media of higher pH, reaching 195 to 205 mV at pH 7. Under anaerobic conditions, the delta psi ranged from 100 to 120 mV in cells at pH 6.3 to 7, resulting in a PMF of 150 to 140 mV. Thus, the mode of energy metabolism (i.e., respiration versus fermentation) and the pH of the medium are the two important factors influencing the PMF of these gram-positive cells during growth.     

The effects of partial and selective reduction in the components of the proton-motive force on lactose uptake in Escherichia coli.

The relationship between the steady state lactose accumulation (delta plac) and the magnitude of the membrane potential (delta psi) and pH gradient (delta pH) has been studied at pHo5.5 and pHo7.5. An attempt has been made to differentiate between two possible means by which lactose accumulation may be reduced below the proton-motive force (delta p). Firstly, that delta psi and delta pH are not equivalent in driving lactose transport and secondly, that 'slip' reactions (beta-galactoside exit via the carrier without a proton) may reduce accumulation. The data support the latter; however, our conclusions are tempered by the observation that the apparent stoichiometry (delta plac/delta p) increases to a value of at least 2 at values of delta p below 130 mV.     

Proton motive force and Na+/H+ antiport in a moderate halophile.

The influence of pH on the proton motive force of Vibrio costicola was determined by measuring the distributions of triphenylmethylphosphonium cation (membrane potential, delta psi) and either dimethyloxazolidinedione or methylamine (osmotic component, delta pH). As the pH of the medium was adjusted from 5.7 to 9.0, the proton motive force steadily decreased from about 170 to 100 mV. This decline occurred, despite a large increase in the membrane potential to its maximum value at pH 9.0, because of the loss of the pH gradient (inside alkaline). The cytoplasm and medium were of equal pH at 7.5; membrane permeability properties were lost at the pH extremes of 5.0 and 9.5. Protonophores and monensin prevented the net efflux of protons normally found when an oxygen pulse was given to an anaerobic cell suspension. A Na+/H+ antiport activity was measured for both Na+ influx and efflux and was shown to be dissipated by protonophores and monensin. These results strongly favor the concept that respiratory energy is used for proton efflux and that the resulting proton motive force may be converted to a sodium motive force through Na+/H+ antiport (driven by delta psi). A role for antiport activity in pH regulation of the cytosol can also explain the broad pH range for optimal growth, extending to the alkaline extreme of pH 9.0.     

Effects of K+ on the proton motive force of Bradyrhizobium sp. strain 32H1.

In previous studies, respiring Bradyrhizobium sp. strain 32H1 cells grown under 0.2% O2, conditions that derepress N2 fixation, were found to have a low proton motive force of less than -121 mV, because of a low membrane potential (delta psi). In contrast, cells grown under 21% O2, which do not fix N2, had high proton motive force values of -175 mV or more, which are typical of respiring bacteria, because of high delta psi values. In the present study, we found that a delta psi of 0 mV in respiring cells requires growth in relatively high-[K+] media (8 mM), low O2 tension, and high internal [K+]. When low-[O2], high-[K+]-grown cells were partially depleted of K+, the delta psi was high. When cells were grown under 21% O2 or in media low in K+ (50 microM K+), the delta psi was again high. The transmembrane pH gradient was affected only slightly by varying the growth or assay conditions. In addition, low-[O2], high-[K+]-grown cells had a greater proton permeability than did high-[O2]-grown cells. To explain these findings, we postulate that cells grown under conditions that derepress N2 fixation contain an electrogenic K+/H+ antiporter that is responsible for the dissipation of the delta psi. The consequence of this alteration in K+ cycling is rerouting of proton circuits so that the putative antiporter becomes the major pathway for H+ influx, rather than the H+-ATP synthase.     

The electrochemical proton potential of Bacillus alcalophilus.

Bacillus alcalophilus strain ATCC 27647 showed usual growth characteristics, when inoculated at pH 10.4. The cells entered the logarithmic phase at pH 10.3, and as growth continued, the pH dropped further to a value of 8.8 in the stationary phase. B. alcalophilus strain DSM 485 showed comparable growth only in the initial phase after the addition to fresh medium. The small initial growth period was succeeded by a long lag phase, where the pH continuously dropped. The cells resumed growth after the pH was about 10.0 and continued to grow accompanied by a further decrease of external pH. The bioenergetic parameters measured in the initial growth phase of the two strains at high pH (10.1-10.3) were nearly the same, i.e. delta pH = +97 to +110 mV, delta psi = -206 to -213 mV and delta microH+ = -109 to -103 mV. The inverted proton gradient of about 1.7-1.9 at high pH decreased, as the external pH dropped during growth. This led to an increase of the proton motive force (delta microH+), although the membrane potential (delta psi) also declined. The ATP/ADP ratio of strain DSM 485 was high (4.5-5.5) at fast growth during the initial and second growth period. The ratio declined to about 1.5 at the end of the lag phase. At the initial growth phase and at the end of the lag phase, the delta microH+ was, however, the same (approximately -106 mV) and considerably lower than in the middle of the second growth period (approximately -140 mV). Fast growth, therefore, correlates with a high ATP/ADP ratio but not necessarily with a high delta microH+. Addition of gramicidin or carbonylcyanide m-chlorophenylhydrazone stopped growth of B. alcalophilus strain DSM 485 at pH 10.3 or 9.5 and gramicidin immediately decreased the internal ATP/ADP ratio from 4.5 to 1.2 at pH 10.3.     

Ammonium/urea-dependent generation of a proton electrochemical potential and synthesis of ATP in Bacillus pasteurii.

The influence of ammonium and urea on the components of the proton electrochemical potential (delta p) and de novo synthesis of ATP was studied with Bacillus pasteurii ATCC 11859. In washed cells grown at high urea concentrations, a delta p of -56 +/- 29 mV, consisting of a membrane potential (delta psi) of -228 +/- 19 mV and of a transmembrane pH gradient (delta pH) equivalent to 172 +/- 38 mV, was measured. These cells contained only low amounts of potassium, and the addition of ammonium caused an immediate net decrease of both delta psi and delta pH, resulting in a net increase of delta p of about 49 mV and de novo synthesis of ATP. Addition of urea and its subsequent hydrolysis to ammonium by the cytosolic urease also caused an increase of delta p and ATP synthesis; a net initial increase of delta psi, accompanied by a slower decrease of delta pH in this case, was observed. Cells grown at low concentrations of urea contained high amounts of potassium and maintained a delta p of -113 +/- 26 mV, with a delta psi of -228 +/- 22 mV and a delta pH equivalent to 115 +/- 20 mV. Addition of ammonium to such cells resulted in the net decrease of delta psi and delta pH without a net increase in delta p or synthesis of ATP, whereas urea caused an increase of delta p and de novo synthesis of ATP, mainly because of a net increase of delta psi. The data reported in this work suggest that the ATP-generating system is coupled to urea hydrolysis via both an alkalinization of the cytoplasm by the ammonium generated in the urease reaction and a net increase of delta psi that is probably due to an efflux of ammonium ions. Furthermore, the findings of this study show that potassium ions are involved in the regulation of the intracellular pH and that ammonium ions may functionally replace potassium to a certain extent in reducing the membrane potential and alkalinizing the cytoplasm.     

Simultaneous measurements of proton motive force, delta pH, membrane potential, and H+/O ratios in intact Escherichia coli.

An instrument is described that enables the simultaneous monitoring of proton motive force (PMF), membrane potential (delta psi), the delta pH across a membrane, oxidase activity, proton movements, and H+/O ratios. We have studied the relationship existing among these parameters of energy transduction as a critical condition is changed during an experiment. The major findings are: (a) In the pH range of 4.5 to 7.5, increasing the external pH causes an increase in delta psi, internal pH, and oxidase activity, a decrease in H+/O ratio, and a peak-plateau in PMF from pH 5.5 to 6.6 where delta pH is converted to delta psi. (b) An increase in [K+] from 1 to 100 mM, in the presence of 0.5 microM valinomycin, causes the conversion of delta psi to delta pH, a gradual decline in PMF and an increase in H+/O ratio, internal pH, and oxidase activity. (c) Increasing valinomycin concentration from 0 to 2.5 microM, in the presence of 50 mM [K+], causes a decline in delta psi from 125 to 0 mV, and an increase in delta pH from 35 to 70 mV. From 2.5 to 10 microM, the delta pH and the PMF (which it solely represents), stay constant, H+/O ratio increases mainly from 0 to 0.5 microM and much more slowly from 2.5 to 10 microM. (d) Oxygen at only 10% of its concentration in air-saturated buffer can support the generation of 90% or more of the delta psi, delta pH, and PMF generated in an air-saturated solution. (e) The return of extruded protons to the cell (referred to here as "suck-back") represents a complicated process driven by delta psi and influenced by a variety of factors. (f) H+/O ratios measured by the kinetic technique used here are much higher than those measured by standard oxygen pulse techniques.     

Estimation of the cytoplasmic pH of Coxiella burnetii and effect of substrate oxidation on proton motive force.

The magnitude of the proton motive force generated during in vitro substrate oxidation by Coxiella burnetii was examined. The intracellular pH of C. burnetii varied from about 5.1 to 6.95 in resting cells over an extracellular pH range of 2 to 7. Similarly, delta psi varied from about 15 mV to -58 mV over approximately the same range of extracellular pH. Both components of the proton motive force increased during substrate oxidation, resulting in an increase in proton motive force from about -92 mV in resting cells to -153 mV in cells metabolizing glutamate at pH 4.2. The respiration-dependent increase in proton motive force was blocked by respiratory inhibitors, but the delta pH was not abolished even by the addition of proton ionophores such as carbonyl cyanide-m-chlorophenyl hydrazone or 2,4-dinitrophenol. Because of this apparently passive component of delta pH maintenance, the largest proton motive force was obtained at an extracellular pH too low to permit respiration. C. burnetii appears, therefore, to behave in many respects like other acidophilic bacteria. Such responses are proposed to contribute to the extreme resistance of C. burnetii to environmental conditions and subsequent activation upon entry into the phagolysosome of eucaryotic cells in which this organism multiplies.     

Transmembrane pH gradient and membrane potential in Clostridium acetobutylicum during growth under acetogenic and solventogenic conditions

The proton motive force and its electrical and chemical components were determined in Clostridium acetobutylicum, grown in a phosphate-limited chemostat, using [14C]dimethyloxazolidinedione and [14C]benzoic acid as transmembrane pH gradient (delta pH) probes and [14C]triphenylmethylphosphonium as a membrane potential (delta psi) indicator. The cells maintained an internal-alkaline pH gradient of approximately 0.2 at pH 6.5 and 1.5 at pH 4.5. The delta pH was essentially constant between pH 6.5 and 5.5 but increased considerably at lower extracellular pH values down to 4.5. Hence, the intracellular pH fell from 6.7 to 6.0 as the external pH was lowered from 6.5 to 5.5 but did not decrease further when the external pH was decreased to 4.5. The transmembrane electrical potential decreased as the external pH decreased. At pH 6.5, delta psi was approximately -90 mV, whereas no negative delta psi was detectable at pH 4.5. The proton motive force was calculated to be -106 mV at pH 6.5 and -102 mV at pH 4.5. The ability to maintain a high internal pH at a low extracellular pH suggests that C. acetobutylicum has an efficient deacidification mechanism which expresses itself through the production of neutral solvents.     

Transmembrane pH gradient and membrane potential in Clostridium acetobutylicum during growth under acetogenic and solventogenic conditions.

The proton motive force and its electrical and chemical components were determined in Clostridium acetobutylicum, grown in a phosphate-limited chemostat, using [14C]dimethyloxazolidinedione and [14C]benzoic acid as transmembrane pH gradient (delta pH) probes and [14C]triphenylmethylphosphonium as a membrane potential (delta psi) indicator. The cells maintained an internal-alkaline pH gradient of approximately 0.2 at pH 6.5 and 1.5 at pH 4.5. The delta pH was essentially constant between pH 6.5 and 5.5 but increased considerably at lower extracellular pH values down to 4.5. Hence, the intracellular pH fell from 6.7 to 6.0 as the external pH was lowered from 6.5 to 5.5 but did not decrease further when the external pH was decreased to 4.5. The transmembrane electrical potential decreased as the external pH decreased. At pH 6.5, delta psi was approximately -90 mV, whereas no negative delta psi was detectable at pH 4.5. The proton motive force was calculated to be -106 mV at pH 6.5 and -102 mV at pH 4.5. The ability to maintain a high internal pH at a low extracellular pH suggests that C. acetobutylicum has an efficient deacidification mechanism which expresses itself through the production of neutral solvents.     

The rate of ATP-synthesis as a function of delta pH and delta psi catalyzed by the active, reduced H(+)-ATPase from chloroplasts.

The H(+)-ATPase from chloroplasts was brought into the active, reduced state. Then, an electrochemical potential difference of protons across the thylakoid membranes was generated by an acid-base transition, delta pH, combined with a K+/valinomycin diffusion potential, delta psi. The initial rate of ATP synthesis was measured with a rapid-mixing quenched-flow apparatus in the time-range between 20-150 ms. The rate of ATP synthesis depends in a sigmoidal way on delta pH. Increasing diffusion potentials shifts the delta pH-dependencies to lower delta pH values. Analysis of the data indicate that the rate of ATP synthesis depends on the electrochemical potential difference of protons irrespective of the relative contribution of delta pH and delta psi.