The activity of the ATP synthase from Escherichia coli is regulated by the transmembrane proton motive force

The ATP synthase from Escherichia coli was reconstituted into liposomes from phosphatidylcholine/phosphatidic acid. The proteoliposomes were energized by an acid-base transition and a K(+)/valinomycin diffusion potential, and one second after energization, the electrochemical proton gradient was dissipated by uncouplers, and the ATP hydrolysis measurement was started. In the presence of ADP and P(i), the initial rate of ATP hydrolysis was up to 9-fold higher with pre-energized proteoliposomes than with proteoliposomes that had not seen an electrochemical proton gradient. After dissipating the electrochemical proton gradient, the high rate of ATP hydrolysis decayed to the rate without pre-energization within about 15 s. During this decay the enzyme carried out approximately 100 turnovers. In the absence of ADP and P(i), the rate of ATP hydrolysis was already high and could not be significantly increased by pre-energization. It is concluded that ATP hydrolysis is inhibited when ADP and P(i) are bound to the enzyme and that a high Delta mu(H(+)) is required to release ADP and P(i) and to convert the enzyme into a high activity state. This high activity state is metastable and decays slowly when Delta mu(H(+)) is abolished. Thus, the proton motive force does not only supply energy for ATP synthesis but also regulates the fraction of active enzymes.     

Molecular devices of chloroplast F(1)-ATP synthase for the regulation

In chloroplasts, synthesis of ATP is energetically coupled with the utilization of a proton gradient formed by photosynthetic electron transport. The involved enzyme, the chloroplast ATP synthase, can potentially hydrolyze ATP when the magnitude of the transmembrane electrochemical potential difference of protons (Delta(micro)H(+)) is small, e.g. at low light intensity or in the dark. To prevent this wasteful consumption of ATP, the activity of chloroplast ATP synthase is regulated as the occasion may demand. As regulation systems Delta(micro)H(+) activation, thiol modulation, tight binding of ADP and the role of the intrinsic inhibitory subunit epsilon is well documented. In this article, we discuss recent progress in understanding of the regulation system of the chloroplast ATP synthase at the molecular level.     

A point mutation in atpC1 raises the redox potential of the Arabidopsis chloroplast ATP synthase gamma-subunit regulatory disulfide above the range of thioredoxin modulation

The light-dependent regulation of chloroplast ATP synthase activity depends on an intricate but ill defined interplay between the proton electrochemical potential across the thylakoid membrane and thioredoxin-mediated redox modulation of a cysteine bridge located on the ATP synthase gamma-subunit. The abnormal light-dependent regulation of the chloroplast ATP synthase in the Arabidopsis thaliana cfq (coupling factor quick recovery) mutant was caused by a point mutation (G to A) in the atpC1 gene, which caused an amino acid substitution (E244K) in the vicinity of the redox modulation domain in the gamma-subunit of ATP synthase. Equilibrium redox titration revealed that this mutation made the regulatory sulfhydryl group energetically much more difficult to reduce relative to the wild type (i.e. raised the Em,7.9 by 39 mV). Enzymatic studies using isolated chloroplasts showed significantly lower light-induced ATPase and ATP synthase activity in the mutant compared with the wild type. The lower ATP synthesis capacity in turn restricted overall rates of leaf photosynthesis in the cfq mutant under low light. This work provides in situ validation of the concept that thioredoxin-dependent reduction of the gamma-subunit regulatory disulfide modulates the proton electrochemical potential energy requirement for activation of the chloroplast ATP synthase and that the activation state of the ATP synthase can limit leaf level photosynthesis.     

Electrochemical gradients and energy coupling in photosynthetic bacteria

The electrochemical proton gradient formed during light-induced electron transport in bacterial chromatophores is composed of both a proton concentration gradient and a membrane potential that can interchange under appropriate conditions. Both components, whether light-induced or imposed artificially in the dark, can drive ATP synthesis.     

Regulation of the bacteriorhodopsin photocycle and proton pumping in whole cells of Halobacterium salinarium.

Single-turnover kinetics of the bacteriorhodopsin photocycle and proton-pumping capabilities of whole cells were studied. It was found that the Delta mu (tilde)H+ of the cell had a profound influence on the kinetics and components of the cycle. For example, comparing the photocycle in whole cells to that seen in PM preparations, we found that (1) the single-turnover time of the cycle was increased approximately 10-fold, (2) the mole fraction of M-fast (at high actinic light) decreased from 50 to 20%, and (3) the time constant for M-slow increased significantly. The level of Delta mu(tilde)H+ was dependent on respiration, ATP formation and breakdown, and the magnitude of a pre-existing K+ diffusion gradient. The size of the Delta mu(tilde)H+ could be manipulated by additions of HCN, nigericin, and DCCD (N,N'-dicyclohexylcarbodamide). At higher levels of Delta mu(tilde)H+, further changes in the photocycle were seen. (4) Two slower components of M-decay appeared as major components. (5) The apparent conversion of the M-fast to the O intermediate disappeared. (6) A partial reversal of an early photocycle step occurred. The photocycle of intact cells could be changed to that seen in purple membrane suspensions by the energy-uncoupler CCCP or by lysis of the cells. In fresh whole cells, light-induced proton pumping was not seen until the K+ diffusion potential was dissipated and proton accumulation facilitated by use of a K+-H+ exchanger (nigericin), respiration was inhibited by HCN, and ATP synthesis and breakdown were inhibited by DCCD. In stored cells, the pre-existing K+ diffusion gradient was diminished through slow diffusion, and only DCCD and HCN were required to elicit proton extrusion.     

H+/ATP stoichiometry of proton pump of turtle urinary bladder

Urinary acidification in the turtle urinary bladder is due to a reversible proton-translocating ATPase. To estimate the H+/ATP stoichiometry of this pump, we measured the delta G'ATP in the epithelial cells and the maximum e.m.f. generated by the pump. The latter is the maximal transepithelial electrochemical gradient for protons placed across the epithelium that is needed to nullify the rate of transport and averaged 179 +/- 7 mV. The delta G'ATP averaged 50.1 kJ/mol. The H+/ATP stoichiometry of these bladders was 2.92 +/- 0.1. In other experiments, the bladders were poisoned by iodoacetate and cyanide and a variable transepithelial electrochemical gradient for protons was placed across them. It was noted that ATP synthesis occurred at a transepithelial electrochemical gradient for protons greater than 120 mV. The delta G'ATP in other bladders treated identically averaged 40.0 kJ/mol, giving a H+/ATP stoichiometry of 3.4 +/- 0.1. We conclude that the H+/ATP stoichiometry of the proton pump of turtle urinary bladder is approximately 3.     

Light-induced conformational changes in photosynthetic reaction centers: redox-regulated proton pathway near the dimer

The influence of the hydrogen bonds on the light-induced structural changes were studied in the wild type and 11 mutants with different hydrogen bonding patterns of the primary electron donor of reaction centers from Rhodobacter sphaeroides. Previously, using the same set of mutants at pH 8, a marked light-induced change of the local dielectric constant in the vicinity of the dimer was reported in wild type and in mutants retaining Leu L131 that correlated with the recovery kinetics of the charge-separated state [ Deshmukh et al. (2011) Biochemistry, 50, 340-348]. In this work after prolonged illumination the recovery of the oxidized dimer was found to be multiphasic in all mutants. The fraction of the slowest phase, assigned to a recovery from a conformationally altered state, was strongly pH dependent and found to be extremely long at room temperature, at pH 6, with rate constants of ～10(-3) s(-1). In wild type and in mutants with Leu at L131 the very long recovery kinetics was coupled to a large proton release at pH 6 and a decrease of up to 79 mV of the oxidation potential of the dimer. In contrast, in the mutants carrying the Leu to His mutation at the L131 position, only a negligible fraction of the dimer exhibited lowered potential, the large proton release was not observed, the oxidized dimer recovered 1 or 2 orders of magnitude faster depending on the pH, and the very long-lived state was not or barely detectable. These results are modeled as arising from the loss of a proton pathway from the bacteriochlorophyll dimer to the solvent when His is present at the L131 position.     

Effect of dicyclohexylcarbodiimide on the proton conductance of thylakoid membranes in intact chloroplast

The effects of dicyclohexylcarbodiimide, a potent inhibitor of chloroplast ATPase, on the light-induced electric potential changes in intact chloroplasts of Peperomia metallica and of a hornwort Anthoceros sp. were investigated by means of glass microcapillary electrodes. The characteristics of potential changes induced by flashes or continuous light in chloroplasts of both species are similar except for the phase of potential rise in continuous light, which is clearly biphasic in Anthoceros chloroplasts. Dicyclohexylcarbodiimide at concentration 5 · 10⁻⁵ M completely abolishes the transient potential undershoot in the light-off reaction but has little effect on the peak value of the photoelectric response. The membrane conductance in the light and in the dark was tested by measuring the decay kinetics of flash-generated potential in dark-adapted and preilluminated chloroplasts. In the absence of dicyclohexylcarbodiimide, preillumination causes a significant acceleration of the potential decay. The light-induced changes in the decay kinetics of flash-induced responses were abolished in the presence of dicyclohexylcarbodiimide, whereas the rate of potential decay in dark-adapted chloroplasts was not altered by dicyclohexylcarbodiimide. The results are consistent with the notion that dicyclohexylcarbodiimide diminishes H⁺ conductance of energized thylakoid membranes by interacting with the H⁺ channel of ATPase. The occurrence of a lag (approx. 300 ms) on the plot of potential undershoot (diffusion potential) versus illumination time might suggest the increase in H⁺ permeability coefficient of thylakoid membrane during illumination.     

Electron paramagnetic resonance Signal II in spinach chloroplasts. II. Alternative spectral forms and inhibitor effects on kinetics of Signal II in flashing light

Linewidth and hyperfine structure measurements of the EPR spectrum of Signal II in spinach chloroplasts show that the signal reflects two alternative states. One state is characterized by a 16-G linewidth and four partially resolved hyperfine components. The other state has 19 G linewidth and five partially resolved hyperfine components. It is possible to interconvert these two states by changing the ionic strength of the chloroplast suspension. Both states of Signal II show similar light-induced increases in dark-adapted chloroplasts and respond to 10-μs white light flashes with identical kinetics.

In chloroplasts at room temperature, Signal II dark decays to 50% of its total light-induced level in about 1 h. Single flashes increase the spin concentration in these aged chloroplasts but with decreased effectiveness compared with fresh, dark-adapted chloroplasts. Carbonyl cyanide-m-chlorophenylhydrazone (CCCP) decreases the decay time of Signal II from hours to seconds without appreciably altering the level of Signal II formed in saturating continuous light. However, both the formation time constant and the extent of Signal II increase stimulated by a single saturating flash are decreased in CCCP-treated chloroplasts.

These results are interpreted in terms of the model, proposed in the preceding paper, in which Signal II is generated by oxidation-reduction reactions on the water side of Photosystem II.     

Enhancement of chloroplast energization in Chlorella by treatments inactivating the nitrate-reducing system

Inactivation of the nitrate-reducing system in whole cells of Chlorella vulgaris Bejerinck by darkening, nitrogen starvation, ammonium, or cycloheximide brings cells into a state with a high yield of the millisecond-delayed fluorescence of chlorophyll. Activation of this system by illumination, by adding glucose to dark-adapted cells or nitrate to nitrogen-starved cells brings the cells into a low-yield state. The transitions between the lowand high-yield state induced by alternating light and dark periods are suppressed by tungstate and restored by subsequent molybdate addition. The drop in the delayed-fluorescence yield upon activation of the nitrate-reducing system is associated with the decrease of the amplitude of the electrochemical proton gradient across the thylakoid membrane of the chloroplast, as evidenced by the kinetics of the light-induced adsorption changes at 520 nm. The decrease of the proton gradient may be caused by the electron flow diverting from the cyclic path in photosystem I as a result of the activation of the electron transfer from ferredoxin to nitrite.Abbreviation DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea     

Exogenous energy supply to the plasma membrane of dark anaerobic cyanobacterium Anacystis nidulans: thermodynamic and kinetic characterization of the ATP synthesis effected by an artificial proton motive force

The net synthesis of ATP in dark anaerobic cells of Anacystis nidulans subjected to acid jumps and/or valinomycin pulses was characterized thermodynamically and kinetically. Maximum initial rates of 75 nmol ATP/min per mg dry weight at an applied proton motive force of -350 mV were obtained, the flow-force relationship (rate of ATP synthesis vs applied proton motive force) being linear between -240 and -320 mV irrespective of the source of the proton motive force. The pulse-induced ATP synthesis was inhibited by uncouplers (H+ ionophores) and F0F1-ATPase inhibitors but not by KCN or CO. In order to obtain maximum rates of pulse-induced ATP synthesis both a favorable stationary delta psi (-100 mV at pHo 9, preceding the acid jumps) and a favorable stationary delta pH (+2 units at pHo 4.1, preceding the valinomycin pulse) of the plasma membrane were obligatory, the effects of delta psi and delta pH being strictly additive. Moreover, the pulse-induced ATP synthesis required a minimum total proton motive force of -200 to -250 mV across the plasma membrane; it also required low preexisting phosphorylation potentials corresponding to -400 mV in dark anaerobic, i.e., energy-depleted, cells. The results are discussed in terms of both a reversible H+-ATPase and a respiratory electron transport system occurring in the plasma membrane of intact Anacystis nidulans.     

Light energy conservation processes in Halobacterium halobium cells.

In Halobacterium halobium, proton pumping driven by light or by respiration generates an electrochemical potential difference across the membrane. Energy storage in this form is only transient. Cellular energy transducers competing with proton leaks stabilize this free energy as high energy phosphate bonds, electrochemical potential of other ions, and chemical potential of amino acids and possibly other chemical species. The pH changes induced by light or by respiration in cell suspensions are complicated by proton flows associated with the functioning of the cellular energy transducers. Dominant is the proton inflow coupled to the synthesis of ATP, which has been kinetically resolved. A proton-per-ATP ratio of about 3 is calculated from simultaneous measurements of photophosphorylation and the proton inflow. This value is compatible with the chemiosmotic coupling hypothesis. The time course of the light-induced changes in membrane potential indicates that light-driven pumping increases a dark preexisting potential of about 130 mV only by a small amount (20-30 mV). The complex kinetic features of the membrane potential changes do not closely follow those of the pH changes, indicating that flows of ions other than protons are involved. A qualitative model consistent with the available data is presented. A salient feature of this model is a sudden relaxation of the protonmotive force by a proton inflow through the ATPase when the preexisting protonmotive force is increased by light or respiration and reaches a critical value. The trigger could be either the proton-motive force, the pH gradient, or possibly the internal pH.     

The extent of the stimulated electrical potential decay under phosphorylating conditions and the H+/ATP ratio in Rhodopseudomonas sphaeroides chromatophores following short flash excitation.

1. In chromatophores from Rps. sphaeroides, the stimulation by ADP and Pi of the electric potential decay indicated by the carotenoid shift is greater than the stimulation of the decay of pH change indicated by the colour change of added cresol red under similar conditions. This difference is attributed to H+ consumption during the synthesis of ATP. The ratio of H+ translocated across the membrane to ATP synthesized was estimated to be approximately 1.7 H+/ATP. 2. The stimulation of the electrical potential decay by ADP and Pi was found to be a constant fraction (10%) of the total decay when the flash intensity was varied. No 'critical' or 'threshold' potential was observed. 3. The stimulated electrical potential decay after a second flash, given within a few seconds of the first, was related to the amplitude of the electrical potential produced by the second flash (10%) but neither to the dark time between the flashes, nor to the total extent of the electrical potential above the dark level. These results are consistent with two hypotheses (a) the chromatophores are a mixed population of vesicles, only a small fraction (10%) of which possess an active ATP synthesizing system (b) the activity of the ATP synthesizing system, though driven by a proton motive force, is controlled by electron transport processess. If alternative (a) is correct then the overall single turnover flash yield of 1 ATP per 1470 bacteriochlorophyll measured in (1) would mean that the yield of the active vesicles is approximately 10 ATP per 1470 bacteriochlorophyll or 30 ATP per vesicle. 4. The stimulation of the electrical potential decay by ADP and Pi is approximately 40% less in antimycin-treated chromatophores. It is shown that this is probably a consequence of antimycin-inhibited H+-release on the inside of the chromatophore vesicles following a flash.     

Electrochemical proton gradient and lactate concentration gradient in Streptococcus cremoris cells grown in batch culture.

The lactate concentration gradient and the components of the electrochemical proton gradient (delta micro H+) were determined in cells of Streptococcus cremoris growing in batch culture. The membrane potential (delta psi) and the pH gradient (delta pH) were determined from the accumulation of the lipophilic cation tetraphenylphosphonium and the weak acid benzoate, respectively. During growth the external pH decreased from 6.8 to 5.3 due to the production of lactate. Delta pH increased from 0 to -35 mV, inside alkaline (at an external pH of 5.7), and fell to zero directly after growth stopped. Delta psi was nearly constant at -90 mV during growth and also dissipated within 40 min after termination of growth. The internal lactate concentration decreased from 200 mM at the beginning of growth (at pH 6.8) to 30 mM at the end of growth (at pH 5.3); the external lactate concentration increased from 8 to 30 mM due to the fermentation of lactose. Thus, the lactate gradient decreased from 80 mV to zero as growth proceeded and the external pH decreased. From the data obtained on delta psi, delta pH, and the lactate concentration gradient, the H+/lactate stoichiometry (n) was calculated. The value of n varied with the external pH from 1.9 (at pH 6.8) to 0.9 (at pH values below 6). This implies that especially at high pH values the carrier-mediated efflux of lactate supplies a significant quantity of metabolic energy to S. cremoris cells. At pH 6.8 this energy gain was almost two ATP equivalents per molecule of lactose consumed if the H+/ATP stoichiometry equals 2. These results supply strong experimental evidence for the energy recycling model postulated by Michels et al.     

2-Oxoglutarate transport system in Staphylococcus aureus

2-[(14)C]oxoglutarate uptake in resting cells of Staphylococcus aureus 17810S occurs via two kinetically different systems: (1) a secondary, electrogenic 2-oxoglutarate:H(+) symporter (K(m)=0.105 mM), energized by an electrochemical proton potential (Delta mu H(+)) that is generated by the oxidation of endogenous amino acids and sensitive to ionophores, and (2) a Delta mu H(+)-independent facilitated diffusion system (K(m)=1.31 mM). The 2-oxoglutarate transport system of S. aureus 17810S can be classified as a new member of the MHS (metabolite:H(+) symporter) family. This transporter takes up various dicarboxylic acids in the order of affinity: succinate = malate > fumarate > 2-oxoglutarate > glutamate. Energy conservation with 2-oxoglutarate was studied in starved cells of strain 17810S. Initial transport of 2-oxoglutarate in these cells is energized by Delta mu H(+) generated via hydrolysis of residual ATP. Subsequent oxidation of the accumulated 2-oxoglutarate generates Delta mu H(+) for further, autoenergized transport of this 2-oxoacid and also for Delta mu H(+)-linked resynthesis of ATP. In the cadmium-sensitive S. aureus 17810S, Cd(2+) accumulation strongly inhibits energy conservation with 2-oxoglutarate at the level of Delta mu H(+) generation, without direct blocking of the 2-oxoglutarate transport system or ATP synthase complex. In the cadmium-resistant S. aureus 17810R, Cd(2+) does not affect energy conservation due to its extrusion by the Cd(2+) efflux system (Cd(2+)-ATPase of P-type), which prevents Cd(2+) accumulation.     

Contribution of electric field (Delta psi) to steady-state transthylakoid proton motive force (pmf) in vitro and in vivo. control of pmf parsing into Delta psi and Delta pH by ionic strength

The observed levels of Delta G(ATP) in chloroplasts, as well as the activation behavior of the CF(1)CF(0)-ATP synthase, suggest a minimum transthylakoid proton motive force (pmf) equivalent to a Delta pH of approximately 2.5 units. If, as is commonly believed, all transthylakoid pmf is stored as Delta pH, this would indicate a lumen pH of less than approximately 5. In contrast, we have presented evidence that the pH of the thylakoid lumen does not drop below pH approximately 5.8 [Kramer, D. M., Sacksteder, C. A., and Cruz, J. A. (1999) Photosynth. Res. 60, 151-163], leading us to propose that Delta psi can contribute to steady-state pmf. In this work, it is demonstrated, through assays on isolated thylakoids and computer simulations, that thylakoids can store a substantial fraction of pmf as Delta psi, provided that the activities of ions permeable to the thylakoid membrane in the chloroplast stromal compartment are relatively low and the buffering capacity (beta) for protons of the lumen is relatively high. Measurements of the light-induced electrochromic shift (ECS) confirm the ionic strength behavior of steady-state Delta psi in isolated, partially uncoupled thylakoids. Measurements of the ECS in intact plants illuminated for 65 s were consistent with low concentrations of permeable ions and approximately 50% storage of pmf as Delta psi. We propose that the plant cell, possibly at the level of the inner chloroplast envelope, can control the parsing of pmf into Delta psi and Delta pH by regulating the ionic strength and balance of the chloroplast. In addition, this work demonstrates that, under certain conditions, the kinetics of the light-induced ECS can be used to estimate the fractions of pmf stored as Delta psi and Delta pH both in vitro and in vivo.     

Methanogenesis and ATP synthesis in methanogenic bacteria at low electrochemical proton potentials. An explanation for the apparent uncoupler insensitivity of ATP synthesis

The rate of methane formation from H2 and CO2, the intracellular ATP content and the electrochemical proton potential (delta mu H+) were determined in cell suspensions of Methanobacterium thermoautotrophicum, which were permeabilized for K+ with valinomycin (1.2 mumol/mg protein). In the absence of extracellular K+ the cells formed methane at a rate of 4 mumol min-1 (mg protein)-1, the intracellular ATP content was 20 nmol/mg protein and the delta mu H+ was 200 mV (inside negative). When K+ was added to the suspensions the measured delta mu H+ decreased to the value calculated from the [K+]in/[K+]out ratio. Using this method of delta mu H+ adjustment, it was found that lowering delta mu H+ from 200 mV ([K+]in/[K+]out = 1000) to 100 mV ([K+]in/[K+]out = 40) had no effect on the rate of methane formation and on the intracellular ATP content. At delta mu H+ values below 100 mV ([K+]in/[K+]out less than 40) both the rate of methanogenesis and the ATP content decreased. Methanogenesis completely ceased and the ATP content was 2 nmol/mg when delta mu H+ was adjusted to values lower 50 mV ([K+]in/[K+]out less than 7). The data show that methanogenesis from H2 and CO2 and ATP synthesis in M. thermoautotrophicum are possible at relatively low electrochemical proton potentials. Similar results were obtained with Methanosarcina barkeri. Protonophoric uncouplers like 3,5,3',4'-tetrachlorosalicylanilide (TCS) or 3,5-di-tert-butyl-4-hydroxy-benzylidenemalononitrile (SF 6847) were found not to dissipate delta mu H+ below 100 mV in M. thermoautotrophicum even when used at high concentrations (400 nmol/mg protein). This finding explains the observed uncoupler insensitivity of methanogenesis and ATP synthesis in this organism.     

Influence of electrochemical proton gradient on electron flow in photosystem I of pea leaves

Photoinduced changes in the redox state of photosystem I (PSI) primary donor, chlorophyll P700 were studied by measuring differential absorbance changes of pea leaves at 810 nm minus 870 nm (ΔA ₈₁₀). The kinetics of ΔA ₈₁₀ induced by 5-s pulses of white light were strongly affected by preillumination. In dark-adapted leaves, the light pulse caused a transient oxidation of P700 and its subsequent reduction. An identical pulse, applied after 30-s preillumination with white light, induced sequential appearance of two peaks of P700 oxidation. These kinetic differences of ΔA ₈₁₀ reflect regulatory changes of electron flow on the donor and acceptor sides of PSI induced by illumination of leaf for 20–40 s. The amplitude of ΔA ₈₁₀ second peak depended nonmonotonically on the dark interval preceding illumination: it increased with the length of dark period in the range 3–10 s and decreased upon longer dark intervals. The second wave of ΔA ₈₁₀ disappeared after the treatment with combination of ionophores preventing ΔpH and electric potential formation at the thylakoid membrane. In leaves treated with monensin eliminating ΔpH only, the ΔA ₈₁₀ signals become incompletely reversible and were characterized by slow relaxation in darkness. The results indicate an important role of electrochemical proton gradient in generation of the second wave of light-induced P700 oxidation.