Further investigation on the lateral and transversal proton currents at the thylakoid membrane level by hydrogen-deuterium exchange

Energetically-coupled processes (electron flow, proton uptake and correlated pH gradient) were investigated on envelope-free chloroplasts of lettuce suspended in ¹H₂O or ²H₂O media. Study of the light-intensity and temperature dependencies of these phenomena led to the following observations: 1. At neutral pH, ²H₂O diminishes the transmembrane H⁺ gradient in strong light (chain Photosystem II + Photosystem I) but not in low light; the total H⁺ uptake is increased at all light intensities: the buffering capacity of the inner compartment is increased in heavy water, possibly through enhancement of interactions between membranous titrable groups and the aqueous phase. 2. ²H₂O does not affect the photochemical events of the redox chain, whatever the electron pathway (PSII, PSI or PSII + PSI): only thermal steps are inhibited. The diminution of the apparent quantum yield, sometimes observed, may be ascribed to the dual site of action of the artificial redox carrier (ferricyanide) then used. 3. ²H₂O does not modify the activation energy of the limiting step of the electron flow (PSII + PSI) in uncoupled (44 vs. 47 kJ · mol^?1) or — but less clearly — in coupled, i.e., ‘basal’, state (55 vs. 59 kJ · mol^?1). ²H₂O does not either change the temperature of the phase transition of the membrane (17°C) for the uncoupled flow. However, a low-temperature transition, observed only for the coupled chain, is slightly increased by ²H₂O; this thermal transition is attributed to the freezing of some bound water near the plastoquinone pool. 4. Δp²H is smaller than Δp¹H at all temperatures (PSII + PSI chain). ΔpH is quasi-constant from 0°C to 10°C, then decreases when temperature rises. ²H₂O does not change the activation energy of the dark passive H⁺ efflux, which is almost twice that of the coupled electron flow. The phase transition at low temperature suggests that the proton efflux occurs via two parallel pathways, one temperature-dependent and the other temperature-independent. Except for the increase of the internal buffering capacity, the effects of ²H₂O on the membrane conformation seem limited, as shown by the unchanged activation energies of the electron flow and of the H⁺ leakage. The null activation energy observed at low temperature emphasizes the role of the bound water in these processes; however, the different effects of ²H₂O on the transition temperatures indicate that this bound water has different properties when associated with the translocation sites or with the H⁺ leakage ones. This ‘microcompartmentation’ of the membranes is consistent with the concept of lateral pH heterogeneity we have previously suggested (de Kouchkovsky, Y., and Haraux, F. (1981) Biochem. Biophys. Res. Commun. 99, 205–212). The theoretical computations and the experimental results suggest that in the steady state, the internal pH would be several tenths of a ‘unit’ lower near the plastoquinones than near the H⁺ efflux sites (coupling factors); this difference would be increased when ²H₊ replaces ¹H⁺, owing to the lower mobility of the deuteron. It is concluded that local, and not average, pH (and ΔpH) should be considered for the understanding of the energy transduction processes.     

Chloroplastic ATP synthase optimizes the trade-off between photosynthetic CO2 assimilation and photoprotection during leaf maturation

In the present study, we studied the role of chloroplastic ATP synthase in photosynthetic regulation during leaf maturation. We measured gas exchange, chlorophyll fluorescence, P700 redox state, and the electrochromic shift signal in mature and immature leaves. Under high light, the immature leaves displayed high levels of non-photochemical quenching (NPQ) and P700 oxidation ratio, and higher values for proton motive force (pmf) and proton gradient (ΔpH) across the thylakoid membranes but lower values for the activity of chloroplastic ATP synthase (g_H⁺) than the mature leaves. Furthermore, g_H⁺ was significantly and positively correlated with CO₂ assimilation rate and linear electron flow (LEF), but negatively correlated with pmf and ΔpH. ΔpH was significantly correlated with LEF and the P700 oxidation ratio. These results indicated that g_H⁺ was regulated to match photosynthetic capacity during leaf maturation, and the formation of pmf and ΔpH was predominantly regulated by the alterations in g_H⁺. In the immature leaves, the high steady-state ΔpH increased lumen acidification, which, in turn, stimulated photoprotection for the photosynthetic apparatus via NPQ induction and photosynthetic control. Our results highlighted the importance of chloroplastic ATP synthase in optimizing the trade-off between CO₂ assimilation and photoprotection during leaf maturation.     

The plastoquinone pool as possible hydrogen pump in photosynthesis

The function of the plastoquinone pool as a possible pump for vectorial hydrogen (H⁺ + e^?) transport across the thylakoid membrane has been investigated in isolated spinach chloroplasts. Measurements of three different optical changes reflecting the redox reactions of the plastoquinone, the external H⁺ uptake and the internal H⁺ release led to the following conclusions:(1) A stoichiometric coupling of 1 : 1 : 1 between the external H⁺ uptake, the electron translocation through the plastoquinone pool and the internal H⁺ release (corrected for H⁺ release due to H₂O oxidation) is valid (pH_out = 8, excitation with repetitive flash groups). (2) The rate of electron release from the plastoquinone pool and the rate of proton release into the inner thylakoid space due to far-red illumination are identical over a range of a more than 10-fold variation.These results support the assumption that the protons taken up by the reduced plastoquinone pool are translocated together with the electrons through the pool from the outside to the inside of the membrane. Therefore, the plastoquinone pool might act as a pump for a vectorial hydrogen (H⁺ + e^?) transport. The molecular mechanism is discussed. The differences between this hydrogen pump of chloroplasts and the proton pump of Halobacteria are outlined.     

Membrane potential and delta pH dependency of reverse electron transport-associated hydrogen peroxide production in brain and heart mitochondria

Succinate-driven reverse electron transport (RET) is one of the main sources of mitochondrial reactive oxygen species (mtROS) in ischemia-reperfusion injury. RET is dependent on mitochondrial membrane potential (Δψ_m) and transmembrane pH difference (ΔpH), components of the proton motive force (pmf); a decrease in Δψ_m and/or ΔpH inhibits RET. In this study we aimed to determine which component of the pmf displays the more dominant effect on RET-provoked ROS generation in isolated guinea pig brain and heart mitochondria respiring on succinate or α-glycerophosphate (α-GP). Δψ_m was detected via safranin fluorescence and a TPP⁺ electrode, the rate of H₂O₂ formation was measured by Amplex UltraRed, the intramitochondrial pH (pH_in) was assessed via BCECF fluorescence. Ionophores were used to dissect the effects of the two components of pmf. The K⁺/H⁺ exchanger, nigericin lowered pH_in and ΔpH, followed by a compensatory increase in Δψ_m that led to an augmented H₂O₂ production. Valinomycin, a K⁺ ionophore, at low [K⁺] increased ΔpH and pH_in, decreased Δψ_m, which resulted in a decline in H₂O₂ formation. It was concluded that Δψ_m is dominant over ?pH in modulating the succinate- and α-GP-evoked RET. The elevation of extramitochondrial pH was accompanied by an enhanced H₂O₂ release and a decreased ?pH. This phenomenon reveals that from the pH component not ?pH, but rather absolute value of pH has higher impact on the rate of mtROS formation. Minor decrease of Δψ_m might be applied as a therapeutic strategy to attenuate RET-driven ROS generation in ischemia-reperfusion injury.     

Chloroplastic ATP synthase builds up a proton motive force preventing production of reactive oxygen species in photosystem I

Over‐reduction of the photosynthetic electron transport (PET) chain should be avoided, because the accumulation of reducing electron carriers produces reactive oxygen species (ROS) within photosystem I (PSI) in thylakoid membranes and causes oxidative damage to chloroplasts. To prevent production of ROS in thylakoid membranes the H⁺ gradient (ΔpH) needs to be built up across the thylakoid membranes to suppress the over‐reduction state of the PET chain. In this study, we aimed to identify the critical component that stimulates ΔpH formation under illumination in higher plants. To do this, we screened ethyl methane sulfonate (EMS)‐treated Arabidopsis thaliana, in which the formation of ΔpH is impaired and the PET chain caused over‐reduction under illumination. Subsequently, we isolated an allelic mutant that carries a missense mutation in the γ‐subunit of chloroplastic CF₀CF₁‐ATP synthase, named hope2. We found that hope2 suppressed the formation of ΔpH during photosynthesis because of the high H⁺ efflux activity from the lumenal to stromal side of the thylakoid membranes via CF₀CF₁‐ATP synthase. Furthermore, PSI was in a more reduced state in hope2 than in wild‐type (WT) plants, and hope2 was more vulnerable to PSI photoinhibition than WT under illumination. These results suggested that chloroplastic CF₀CF₁‐ATP synthase adjusts the redox state of the PET chain, especially for PSI, by modulating H⁺ efflux activity across the thylakoid membranes. Our findings suggest the importance of the buildup of ΔpH depending on CF₀CF₁‐ATP synthase to adjust the redox state of the reaction center chlorophyll P700 in PSI and to suppress the production of ROS in PSI during photosynthesis.     

Mammalian Complex I Pumps 4 Protons per 2 Electrons at High and Physiological Proton Motive Force in Living Cells

Mitochondrial complex I couples electron transfer between matrix NADH and inner-membrane ubiquinone to the pumping of protons against a proton motive force. The accepted proton pumping stoichiometry was 4 protons per 2 electrons transferred (4H⁺/2e⁻) but it has been suggested that stoichiometry may be 3H⁺/2e⁻ based on the identification of only 3 proton pumping units in the crystal structure and a revision of the previous experimental data. Measurement of proton pumping stoichiometry is challenging because, even in isolated mitochondria, it is difficult to measure the proton motive force while simultaneously measuring the redox potentials of the NADH/NAD⁺ and ubiquinol/ubiquinone pools. Here we employ a new method to quantify the proton motive force in living cells from the redox poise of the bc₁ complex measured using multiwavelength cell spectroscopy and show that the correct stoichiometry for complex I is 4H⁺/2e⁻ in mouse and human cells at high and physiological proton motive force.     

Reaction centers fromRhodopseudomonas sphaeroides in reconstituted phospholipid vesicles. II. Light-induced proton translocation

Unidirectional light-dependent proton translocation was demonstrated in a suspension of reconstituted reaction center (RC) vesicles supplemented with cytochromec and 2,3-dimethoxy-5-methyl-1,4-benzoquinone (UQ₀), a lipid-and water-soluble quinone. Proton translocation was detected only at alkaline pH. The pH dependence can be accounted for by the slow redox reaction between the reduced quinone (UQ₀H₂) and oxidized cytochromec. This conclusion is based on (i) the pH dependence of partial reactions of the reconstituted proton translocation cycle, measured either optically or electrometrically and (ii) titration studies with cytochromec and UQ₀. At 250 and 25 µM UQ₀ and cytochromec, respectively, maximal proton translocation was observed at pH 9.6. This pH optimum can be extended to a more acidic pH by increasing the concentration of the soluble redox mediators in the reconstituted cyclic electron transfer chain. At the alkaline side of the pH optimum, proton translocation appears to be limited by electron transfer from the endogenous primary to the secondary quinone within the RCs. The light intensity limits the reconstituted proton pump at the optimal pH. The results are discussed in the context of a reaction scheme for the cyclic redox reactions and the associated proton translocation events.Abbreviations RC reaction center - UQ₀/UQ₀H₂ oxidized and reduced form of 2,3-dimethoxy-5-methyl-1,4-benzoquinone - D/D⁺ reduced and oxidized form of the primary electron donor of the RCs - CCCP carbonylcyanide-trichloromethoxy phenylhydrazone - UQ_A/UQ _A ^– oxidized and semiquinone form of the primary electron acceptor of the RCs - UQ_B/UQ _B ^– /UQ_BH₂ oxidized, semiquinone, and reduced form of the secondary electron acceptor of the RCs - LDAO lauryldimethylamine-N-oxide During the course of this study K.J.H. was supported by a grant from the Netherlands Organization for the Advancement of Pure Research (Z.W.O.). This research was supported by grants from the National Institutes of Health (EY-02084) and from the Office of Naval Research (ONR-NOOO 14-79-C 0798) to M. Montal.     

Hormone action on transmembrane electron and h transport

A possible involvement of two different systems in proton translocation was investigated by simultaneous measurement of transmembrane electron flow and proton secretion in a pH-stat combined with a redoxstat. The pH gradient between cytoplasm and apoplast is probably maintained by an H⁺ -pumping ATPase and by a second proton extrusion system, which seems to be linked to a redox chain with NAD(P)H as electron donor. Indole acetic acid inhibits both e⁻ and H⁺ efflux, but only if the `electron draw' from the outside is not too high. The electron draw depends on the hexacyanoferrate level at the plasmalemma surface and on the Ca²⁺ concentration. The inhibiting effect of auxin on e⁻ and H⁺ efflux in the presence of hexacyanoferrate can be only detected at low levels of bivalent cations and of the artificial electron acceptor. The inhibition of e⁻ and H⁺ efflux by auxin requires high oxygen levels. The influence of auxin on both e⁻ and H⁺ transfer disappears below 2 kilopascals O₂, a level which does not influence respiration. Ethanol and fusicoccin do not increase the e⁻ flux, probably because the electron transfer from the plasma membrane to HCF III is the limiting step. If electron transfer is reduced by IAA pretreatment, ethanol increases e⁻ flux. Fusicoccin decreases e⁻ and increases H⁺ efflux if the rates have been lowered previously by indole acetic acid pretreatment. This effect depends on high oxygen levels and is reversible by lowering oxygen pressure. Auxin and Ca²⁺ change e⁻ flow and H⁺ ejection in a 1:1 ratio.     

Conformational changes in coupling factor 1 may control the rate of electron flow in spinach chloroplasts.

The relationship between the rate of electron flow, internal H⁺ concentration and the magnitude of the H⁺ concentration gradient (ΔpH) in chloroplasts illuminated at various light intensities has been examined. At an external pH of 7.0, the internal H⁺ concentration is a linear function of the rate of electron flow except at saturating light intensity. In contrast, at pH 8.1, this relationship between electron flow and internal H⁺ concentration holds only at values of ΔpH below about 2.8 – 2.9 units. At higher ΔpH values, the rate of electron flow increases much more dramatically than the internal H⁺ concentration. ATP (0.1 mM) prevents this increase. It is suggested that at pH 8.1 but not at pH 7.0, the conformation of coupling factor 1 is altered at high ΔpH values. Its altered conformation may result in an increased efflux of H⁺ from the chloroplasts. This notion is supported by the effects of ATP on electron flow and ΔpH as well as the effect of external pH and light intensity on the reactivity of coupling factor 1 to N-ethylmaleimide.     

Hydrogenase activity and proton-motive force generation by Escherichia coli during glycerol fermentation

Proton motive force (Δp) generation by Escherichia coli wild type cells during glycerol fermentation was first studied. Its two components, electrical—the membrane potential (?φ) and chemical—the pH transmembrane gradient (ΔpH), were established and the effects of external pH (pH_ex) were determined. Intracellular pH was 7.0 and 6.0 and lower than pH_ex at pH 7.5 and 6.5, respectively; and it was higher than pH_ex at pH 5.5. At high pH_ex, the increase of ?φ (?130 mV) was only partially compensated by a reversed ΔpH, resulting in a low Δp. At low pH_ex ?φ and consequently Δp were decreased. The generation of Δp during glycerol fermentation was compared with glucose fermentation, and the difference in Δp might be due to distinguished mechanisms for H⁺ transport through the membrane, especially to hydrogenase (Hyd) enzymes besides the F₀F₁-ATPase. H⁺ efflux was determined to depend on pH_ex; overall and N,N’-dicyclohexylcarbodiimide (DCCD)-inhibitory H⁺ efflux was maximal at pH 6.5. Moreover, ΔpH was changed at pH 6.5 and Δp was different at pH 6.5 and 5.5 with the hypF mutant lacking all Hyd enzymes. DCCD-inhibited ATPase activity of membrane vesicles was maximal at pH 7.5 and decreased with the hypF mutant. Thus, Δp generation by E. coli during glycerol fermentation is different than that during glucose fermentation. Δp is dependent on pH_ex, and a role of Hyd enzymes in its generation is suggested.     

Local Control Model of Excitation–Contraction Coupling in Skeletal Muscle

The voltage-activated H⁺ selective conductance of rat alveolar epithelial cells was studied using whole-cell and excised-patch voltage-clamp techniques. The effects of substituting deuterium oxide, D₂O, for water, H₂O, on both the conductance and the pH dependence of gating were explored. D⁺ was able to permeate proton channels, but with a conductance only about 50% that of H⁺. The conductance in D₂O was reduced more than could be accounted for by bulk solvent isotope effects (i.e., the lower mobility of D⁺ than H⁺), suggesting that D⁺ interacts specifically with the channel during permeation. Evidently the H⁺ or D⁺ current is not diffusion limited, and the H⁺ channel does not behave like a water-filled pore. This result indirectly strengthens the hypothesis that H⁺ (or D⁺) and not OH⁻ is the ionic species carrying current. The voltage dependence of H⁺ channel gating characteristically is sensitive to pH_o and pH_i and was regulated by pD_o and pD_i in an analogous manner, shifting 40 mV/U change in the pD gradient. The time constant of H⁺ current activation was about three times slower (τ_act was larger) in D₂O than in H₂O. The size of the isotope effect is consistent with deuterium isotope effects for proton abstraction reactions, suggesting that H⁺ channel activation requires deprotonation of the channel. In contrast, deactivation (τ_tail) was slowed only by a factor ≤1.5 in D₂O. The results are interpreted within the context of a model for the regulation of H⁺ channel gating by mutually exclusive protonation at internal and external sites (Cherny, V.V., V.S. Markin, and T.E. DeCoursey. 1995. J. Gen. Physiol. 105:861–896). Most of the kinetic effects of D₂O can be explained if the pK _a of the external regulatory site is ∼0.5 pH U higher in D₂O.     

Photophosphorylation capacity of stable spheroplast preparations of anabaena

Spheroplasts from Anabaena 7119 (formerly designated Nostoc muscorum) were prepared in the presence of serum albumin in 0.5 molar sucrose. Electron transport and photophosphorylation were preserved (> 70% of the maximum rate for 1 week). The pH profile of electron transport and photophosphorylation in the reactions H₂O → NADP, H₂O → methyl viologen, and H₂O → ferricyanide shows that uncoupling by ammonia is small throughout and increases slightly with higher pH. ADP + Pi increased NADP reduction from H₂O by 2.5-fold. The ratios of ATP formed per electron pair transported ranged from 0.9 to 1.5. Effects of catalase and superoxide dismutase on the overall O₂ balance implicate pseudocyclic electron transport and phosphorylation. The quenching of 9-aminoacridine fluorescence indicates the formation of a Δ pH from 2 to 2.6 during illumination. This pH gradient is abolished by uncouplers; however, complete uncoupling is achieved only by 3-chlorocarbonyl cyanide phenylhydrazone or valinomycin + NH₄⁺. In the presence of NH₄⁺ alone, the membrane potential may act as the driving force for photophosphorylation.     

Functional characterization of the uncoupler-insensitive Na+ pump of the halotolerant bacterium,Ba1

Respiration initiates Na⁺ efflux from Na⁺-preloaded cells of the halotolerant bacterium, Ba₁. This efflux can take place against the concentration and electrochemical gradients. Since it is not inhibited by carbonylcyanide-p-trifluoromethoxyphenyl-hydrazone or N'N'-dicyclohexylcarbodiimide, it seems unlikely that either Δp (electrochemical potential difference of H⁺ across the membrane) generated by the primary proton pump or ATP play a role in the transduction of the energy supplied by electron transport. The electrogenic extrusion of Na⁺ causes passive counterflow of protons and/or simultaneous flux of permeant anions. In the absence of permeant anions the charge compensation attained by influx of protons is not complete. The membrane potential which persists in this case is inside negative and insensitive to uncoupler. The influx of protons builds up a ΔpH of reversed sign (more acid inside), which is insensitive to uncoupler. The simultaneous efflux of Na⁺ and permeant anions diminishes the intracellular salt content and, as a corollary, causes volume contraction. Thus, the respiration-linked, uncoupler-insensitive Na⁺ pump may play a role in the regulation of the intracellular salt content.     

Hv1 Proton Channel Opening Is Preceded by a Voltage-independent Transition

The voltage sensing domain (VSD) of the voltage-gated proton channel Hv1 mediates a H⁺-selective conductance that is coordinately controlled by the membrane potential (V) and the transmembrane pH gradient (ΔpH). Allosteric control of Hv1 channel opening by ΔpH (V-ΔpH coupling) is manifested by a characteristic shift of approximately 40 mV per ΔpH unit in the activation. To further understand the mechanism for V-ΔpH coupling in Hv1, H⁺ current kinetics of activation and deactivation in excised membrane patches were analyzed as a function of the membrane potential and the pH in the intracellular side of the membrane (pH_I). In this study, it is shown for the first time to our knowledge that the opening of Hv1 is preceded by a voltage-independent transition. A similar process has been proposed to constitute the step involving coupling between the voltage-sensing and pore domains in tetrameric voltage-gated channels. However, for Hv1, the VSD functions as both the voltage sensor and the conduction pathway, suggesting that the voltage independent transition is intrinsic to the voltage-sensing domain. Therefore, this article proposes that the underlying mechanism for the activation of Hv1 involves a process similar to VSD relaxation, a process previously described for voltage-gated channels and voltage-controlled enzymes. Finally, deactivation seemingly occurs as a strictly voltage dependent process, implying that the kinetic event leading to opening of the proton conductance are different than those involved in the closing. Thus, from this work it is proposed that Hv1 activity displays hysteresis.     

A study on electron transport-driven proton translocation in Desulfovibrio desulfuricans

Proton translocation by washed cells of the sulfate-reducing bacterium Desulfovibrio desulfuricans strain Essex 6 was studied by means of pH and sulfide electrodes. Reversible extrusion of protons could be induced either by addition of electron acceptors to cells incubated under hydrogen, or by addition of hydrogen to cells incubated in the presence of an appropriate electron acceptor. Proton translocation was increased in the presence of ionophores that dissipate the membrane potential (thiocyanate, methyl triphenylphosphonium cation, but not valinomycin) and was sensitive to the uncoupler carbonylcyanide m-chlorophenylhydrazone (CCCP). Upon micromolar additions of H₂, usually sulfide was formed in stoichiometric amounts, and extrapolated H⁺/H₂ ratios were 1.8±0.5 with sulfate, 2.3±0.3 with sulfite and 0.5±0.1 with thiosulfate. In several experiments hydrogen pulses caused increased proton extrusion not associated with sulfide production. This was a hint that sulfite might be reduced via intermediates. In the absence of H₂S formation, extrapolated H⁺/H₂ ratios were 3.1±0.8 with sulfate, 3.4±1.1 with sulfite, 4.4±0.8 with thiosulfate and 6.3±1.2 with oxygen. Micromolar pulses of electron acceptors to cells incubated under H₂ caused less proton translocation than H₂ pulses in presence of excess of electron acceptor; extrapolated H⁺/H₂ ratios were 1.3±0.4 with sulfite, 3.3±0.9 with nitrite and 4.2±0.5 with oxygen. No proton translocation was observed after micromolar pulses of sulfate, thiosulfate or nitrate to cells incubated under hydrogen in the presence of thiocyanate. Inhibition experiments with CO and CuCl₂ revealed that the hydrogenase activity was localized in the intracellular space, and that no periplasmic hydrogenase was present. The results indicate that D. desulfuricans can generate a proton gradient by pumping protons across the cytoplasmic membrane.Abbreviations APS adenosine 5-phosphosulfate - CCCP carbonyl cyanide m-chlorophenylhydrazone - MTTP⁺ methyl triphenylphosphonium cation     

The enthalpy changes upon hydrolysis of guanosine triphosphate anhydride and ester bonds

The effects of N,N′-dicyclohexylcarbodiimide (DCCD), triphenyltin chloride (TPT), and 3,5-di-tert-butyl-4-hydroxybenzylidenemalonomtrile (SP6847) were tested on the light-dependent activities of Halobacterium halobium R₁mR which contains a new retinal protein pigment designated as halorhodopsin but no bacteriorhodospin. DCCD inhibited ATP synthesis either in the light- or in the dark-aerobic conditions without affecting the light-induced proton uptake (ΔH⁺). Although DCCD lowered the membrane potential under dark-anaerobic conditions, the potential increased in the light as high as the control (the light-dependent membrane potential increment Δψ became apparently larger in the presence of DCCD). TPT had negligible effect on ATP synthesis both in the dark or in the light but inhibited markedly ΔH⁺ and partly Δψ. After R₁mR was treated with DCCD, TPT abolished ΔH⁺ almost completely but Δψ only partly. The remaining Δψ was collapsed by SF6847 with a concomitant proton incorporation (pH increase). These results led to the following postulations: (i) In R₁mR, ATP is synthesized by a H⁺-ATPase coupled either to respiration and/or light energization by halorhodopsin; (ii) the majority of protons are incorporated in the light by a mechanism which differs from H⁺-ATPase but is driven by the Δψ generated by halorhodopsin; (iii) TPT acts in this system as a chloride/hydroxide exchanger; (iv) the uncoupler SF6847 carries protons into cells in response to Δψ.     

Energy-linked conformational change of the mitochondrial membrane measured with the NH2-modifying reagent,acrolein

Application of the NH₂-modifying reagent, acrolein (2-propenal, CH₂ = CHCHO), to the mitochondrial membrane gave the information that amino groups in the mitochondrial membrane in the energized state are more accessible to acrolein than those in the non-energized state. This finding was supported by the following experimental results. Addition of acrolein to the respiring mitochondria gives rise to rapid H⁺ production, which is caused by the reaction of the amino groups in the membrane with acrolein, followed by a slow H⁺ consumption, whereas resting mitochondria produce little H⁺. The H⁺ production is stopped by the addition of NaN₃, antimycin A and 2-thenoyltrifluoroacetone but not by oligomycin. During the course of H⁺ production, O₂ consumption and Ca²⁺ uptake remain completely active, indicating that mitochondrial function is unaffected. The subsequent H⁺ consumption may be closely related to the destruction of the transmembrane proton gradient formed by mitochondrial respiration.     

Steady-state measurements of ΔpH and Δψ in Rhodospirillum rubrum chromatophores by two different methods. Comparison with phosphorylation potential

The pH gradient, ΔpH, and the membrane potential, Δψ, formed during light-induced electron transport in Rhodospirillum rubrum chromatophores were measured by two independent methods: (a) using specific electrodes to monitor light-dependent uptake of NH₄Cl and SCN^? at chromatophore concentrations of about 0.1 mg bacteriochlorophyll/ml and (b) using 9-aminoacridine and 8-anilinonaphthalenesulfonic acid as fluorescent probes for ΔpH and Δψ, respectively, at chromatophore concentrations of about 0.01 mg bacteriochlorophyll/ml. The light intensity was measured and set at a level which saturated the highest bacteriochlorophyll concentration used. The steady-state values obtained with each method under phosphorylating conditions were compared with the phosphorylation potential maintained by the chromatophores under identical conditions. The results indicate that under all conditions employed the ratio $\text{H}{}^{\mathrm{+}}\text{ATP}$ is greater than 2, and varies between 2.4 and 3.4 depending on the method used for estimation of the electrochemical proton gradient.     

The possible role of redox-associated protons in growth of plant cells

The protons excreted by plant cells may arise by two different mechanisms: (1) by the action of the plasma membrane H⁺-ATPase and (2) by plasma membrane redox reactions. The exact proportion from each source is not known, but the plasma membrane H⁺-ATPase is, by far, the major contributor to proton efflux. There is still some question of whether the redox-associated protons produced by NADH oxidation on the inner side of the plasma membrane traverse the membrane in a 1 : 1 relationship with electrons generated in the redox reactions. Membrane depolarization observed in the presence of ferricyanide reduction by plasma membranes of whole cells or tissues or the lag period between ferricyanide reduction and medium acidification argue that only scalar protons may be involved. The other major argument against tight coupling between protons and electrons involves the concept of strong charge compensation. When ferricyanide is reduced to ferrocyanide on the outside of cells or tissues, an extra negative charge arises, which is compensated for by the release of H⁺ or K⁺, so that the total ratio of increased H⁺ plus K⁺ equals the electrons transferred by transmembrane electron transport. These are strong arguments against a tight coupling between electrons and protons excreted by the plasma membrane. On the other hand, there is no question that inhibitor studies provide evidence for two mechanisms of proton generation by plasma membranes. When the H⁺-ATPase activity is totally inhibited, the addition of ferricyanide induces a burst of extra proton excretion, orvice versa, when plasma membrane redox reactions are inhibited, the H⁺-ATPase can function normally. Since plasma membrane redox reactions and associated H⁺ excretion are related to growth, it is possible that in plants the ATPase-generated protons have a different function from redox-associated protons. The H⁺-ATPase-generated protons have been considered for many years to be necessary for cell wall expansion, allowing elongation to take place. A special function of the redox-generated protons may be in initiating proliferative cell growth, based on the presence of a hormone-stimulated NADH oxidase in membranes of soybean hypocotyls and stimulation of root growth by low concentrations of oxidants. Here we propose that this NADH oxidase and the redox protons released by its action control growth. The mechanism for this may be the evolution of protons into a special membrane domain, from which a signal to initiate cell proliferation may originate, independent of the action of the H⁺-ATPase-generated protons. It is also possible that both expansion and proliferative growth are controlled by redox-generated protons.