Action of local anaesthetics on passive and energy-linked ion translocation in the inner mitochondrial membrane

The effect of dibucaine on passive and respiration-driven ion translocation and oxidative phosphorylation in submitochondrial particles from beef-heart has been studied.Dibucaine inhibited the nigericin-mediated H⁺/K⁺ exchange diffusion and the electrogenic, valinomycin-mediated K⁺ translocation in submitochondrial particles.The local anaesthetic exerted a direct stimulatory effect on the respiration-driven proton uptake and on the passive proton-diffusion reactions. The increase of the respiration-linked proton turnover caused by dibucaine was accompanied by uncoupling of oxidative phosphorylation. It is concluded that spontaneous noncoupled as well as ionophoremediated K⁺ translocation in mitochondria occurs across phospholipid bilayer regions of the membrane whilst other components of the membrane would be specifically involved in active and passive proton translocation across the membrane.The results indicate that polar groups of membrane phospholipids play an important role in energy conservation and transfer in the mitochondrial membrane.     

Respiration-driven proton translocation in micrococcus denitrificans

The polarity and stoichiometry of respiration-driven proton translocation was studied by electrometric and spectrophotometric techniques inMicrococcus denitrificans in the context of the energy transduction mechanism in bacterial oxidative phosphorylation.

1. Protons are ejected through the plasma membrane during respiratory pulses and thereafter diffuse slowly back.
2. In presence of ionic species mobile across the membrane (K⁺-valinomycin, K⁺-gramicidin, or SCN^?), limiting→H⁺/O quotients of 8 were obtained with endogenous respiratory substrates, and the rate of translocation (14·3 μg ions of H⁺/sec g cell dry weight) was commensurate with that of respiration optimally stimulated by FCCP at an →H⁺/O quotient of 8.
3. The rate of decay of the proton pulses was greatly increased by FCCP, but there was little or no effect on the →H⁺/O quotient characteristic of the respiratory system.
4. Various interpretations of the observations are discussed, and it is concluded that respiration is probably coupled directly or indirectly to electrogenic proton translocation. The observations are compatible with the chemiosmotic hypothesis of coupling between respiration and phosphorylation.

     

Factors affecting proton translocation by facultative methylotrophs

The general properties of respiration-driven proton translocation by the two facultative methylotrophs, Pseudomonas AM1 and Pseudomonas extorquens, were similar to those of other bacteria. The stoichiometry of H⁺ extruded/O atom consumed ($\text{H}\text{←}{}^{\mathrm{+}}\text{O}$) during respiration with a particular substrate depended, however, on the concentration of the permeant anion SCN^? used to abolish the membrane potential and on the physiological state of the organism. This variability makes the use of proton translocation data of dubious value in the elucidation of electron-transport pathways, at least in these species, unless the physiological condition of the organisms can be accurately described and reproduced. Methanol oxidation was inhibited by SCN^? but substitution of valinomycin for most of the SCN^? during pulse oxidant experiments allowed measurement of proton translocation when methanol was the substrate. Starved organisms were used to eliminate ambiquity as to whether added test substrates or endogenous reserve materials were being oxidised. Viability remained high during starvation and endogenous O₂ uptake remained detectable long after endogenously driven proton translocation was undetectable. In the absence of endogenously driven proton translocation, measured $\text{H}\text{←}{}^{\mathrm{+}}\text{O}$ stoichiometries differed substantially from those when it was present, suggesting that the physiological state of the organisms is an essential parameter in assessing proton translocation data.     

H and k electrogenic exchanges in corn roots

The membrane potential difference, the net H⁺ exchange rate, the K⁺ net flux, and the K⁺ (⁸⁶Rb⁺) influx were measured in excised corn roots as functions of the K⁺ concentration in the medium at various pH values, in the presence of poorly permeant anions. The roots behaved as a K⁺/H⁺ exchange system. By comparing the results in normal or hypoxic conditions, or in the presence of vanadate, it was possible to distinguish the active components of membrane potential and transports from the passive ones. The magnitude of the electrogenic potential was not related to the active H⁺ extrusion rate. At pH 6, the variations of the electrogenic potential resulted from variations of the stoichiometry of the active H⁺/K⁺ exchange. The same relationship between this stoichiometry and the K⁺ concentration was observed in conditions ensuring different membrane polarizations (pH 6, pH 4, or pH 6 with fusicoccin). Both metabolic and Mg-ATPase specific inhibitors stopped the active H⁺ transport and the net K⁺ influx. Nevertheless, the tracer influx in the presence of vanadate remained higher than the passive influx calculated from the permeability coefficient determined in hypoxia. It is proposed that vanadate uncouples the K⁺ moiety of the H⁺/K⁺ antiport and allows it to mediate isotopic exchanges.     

Mechanism of active shrinkage in mitochondria II. Coupling between strong electrolyte fluxes

1. Addition of succinate to valinomycin-treated mitochondria incubated in KCl causes a large electrolyte penetration. The process depends on a steady supply of energy and involves a continuous net extrusion of protons. Rates of respiration and of electrolyte penetration proceed in a parallel manner.2. A passive penetration of K⁺ salt of permeant anions occurs in respiratory-inhibited mitochondria after addition of valinomycin. Addition of succinate at the end of the passive swelling starts an active extrusion of anions and cations with restoration of the initial volume. The shrinkage is accompanied by a slow reuptake of protons. The initiation of the active shrinkage correlates with the degree of stretching of the inner membrane. The extrusion of electrolytes is inhibited by nigericin, while it is only slightly sensitive to variations of the valinomycin concentration larger than two orders of magnitude.3. Passive swelling and active shrinkage occurs also when K⁺ is replaced by a large variety of organic cations. The rate of organic cation penetration is enhanced by tetraphenylboron, while the rate of electrolyte extrusion is insensitive to variation of the tetraphenylboron concentration.4. Active shrinkage, either with K⁺ or organic cation salts, is inhibited by weak acids. The phosphate inhibition is removed by SH inhibitors. The active shrinkage is also inhibited by mersalyl to an extent of about 60%.5. Three models of active shrinkage are discussed: (a) mechanoprotein, (b) electrogenic proton pump, and (c) proton-driven cation anion pump.     

Respiration-driven proton translocation in rat liver mitochondria

1. Pulses of acidity of the outer aqueous phase of rat liver mitochondrial suspensions induced by pulses of respiration are due to the translocation of H⁺ (or OH⁻) ions across the osmotic barrier (M phase) of the cristae membrane and cannot be attributed to the formation (with acid production) of a chemical intermediate that subsequently decomposes. 2. The effective quantity of protons translocated per bivalent reducing equivalent passing through the succinate-oxidizing and β-hydroxybutyrate-oxidizing spans of the respiratory chain are very close to 4 and 6 respectively. These quotients are constant between pH5·5 and 8·5 and are independent of changes in the ionic composition of the mitochondrial suspension medium provided that the conditions permit the accurate experimental measurement of the proton translocation. 3. Apparent changes in the →H⁺/O quotients may be induced by conditions preventing the occurrence of the usual backlash; these apparent changes of →H⁺/O are attributable to a very fast electrically driven component of the decay of the acid pulses that is not included in the experimental extrapolations. 4. Apparent changes in the →H⁺/O quotients may also be induced by the presence of anions, such as succinate, malonate and phosphate, or by cations such as Na⁺. These apparent changes of →H⁺/O are due to an increase in the rate of the pH-driven decay of the acid pulses. 5. The uncoupling agents, 2,4-dinitrophenol, carbonyl cyanide p-trifluoromethoxyphenylhydrazone and gramicidin increase the effective proton conductance of the M phase and thus increase the rate of decay of the respiration-driven acid pulses, but do not change the initial →H⁺/O quotients. The increase in effective proton conductance of the M phase caused by these uncouplers accounts quantitatively for their uncoupling action; and the fact that the initial →H⁺/O quotients are unchanged shows that uncoupler-sensitive chemical intermediates do not exist between the respiratory-chain system and the effective proton-translocating mechanism. 6. Stoicheiometric acid–base changes associated with the activity of the regions of the respiratory chain on the oxygen side of the rotenone- and antimycin A-sensitive sites gives experimental support for a suggested configuration of loop 3.     

Acid-base titration across the plasma membrane ofMicrococcus denitrificans: Factors affecting the effective proton conductance and the respiratory rate

The object of this work was to measure the effective proton conductance of the plasma membrane ofMicrococcus denitrificans under various conditions and to investigate possible connections between respiration and proton translocation.

1. Pulsed acid-base titrations of suspensions ofM. denitrificans in a medium containing the permeant thiocyanate ion, or when K⁺ ion permeability was induced by valinomycin in a KCl medium, showed that the normal effective proton conductance of the membrane system was less than 1 μmho/cm².
2. A pH-overshoot artefact was suppressed by adding carbonic anhydrase.
3. The effective proton conductance was increased by the uncoupler FCCP in the same concentration range as was required to stimulate respiration. Concentrations of FCCP above 1·5 μM inhibited respiration after an initial stimulation.
4. The effective proton conductance in presence of 2 μM FCCP was at least 17 μmho/cm².
5. The quantitative relationships between the respiratory rate, the stoichiometry of respiration-driven proton translocation, and the effective proton conductance of the membrane of the cells are compatible with the suggestion that stimulation of respiration by FCCP is due to a release of back-pressure exerted by a protonmotive potential on the respiratory chain system in the membrane. Only one amongst other possible explanations of the stimulation of respiration by FCCP is, however, excluded.

     

Mycochromone decreases ATP-driven proton translocation in plant plasma membrane- and tonoplast-enriched vesicles

Abstract Mycochromone, a metabolite produced by Mycosphaerella rosigena, inhibits the ATP-dependent proton translocation and the ATP-generated electrical potential in pea stem tonoplast-enriched vesicles, without affecting the H⁺/K⁺ exchange induced by nigericin or an artificially imposed proton gradient. The inhibition is dependent on the time of pre-incubation and mycochromone concentration. In addition, mycochromone inhibits the ATP-dependent proton translocation in radish plasma membrane-enriched vesicles, though it does not alter ATPase activity (evaluated by hydrolysis of ATP) in either type of plant vesicle. Mycochromone seems to act on the H⁺ channels for proton translocation of the H⁺-pumping ATPase localized on plasmalemma and tonoplast, without affecting the catalytic site of ATP hydrolysis.     

A Mg2+-stimulated ATPase in platelet alpha-granule membranes: possible involvement in proton translocation

Isolated porcine platelet α granules display a Mg²⁺-stimulated ATPase activity. The enzyme is membrane bound and several criteria suggest that it is intrinsic to the α granules, rather than arising from contamination with other structures. Characterization of the ATPase revealed an apparent K_m for ATP of 198 μm. Other nucleotides are also hydrolyzed by the enzyme, though at a slower rate. The enzyme has an absolute requirement for divalent cations, and both Mg²⁺ (apparent K_m 0.93 mm) and Ca²⁺ (apparent K_m 0.95 mm) can activate it. Maximal hydrolysis rates are higher with Mg²⁺ than with Ca²⁺. Micromolar Ca²⁺ in the presence of maximally stimulating Mg²⁺ concentrations produces a small additional enhancement of activity. The Mg²⁺ ATPase has a broad activity maximum between pH 6.5 and 8.5, and an activation energy of 11.8 Kcal/mol. Several independent observations suggest that the ATPase could be involved in H⁺ translocation across the granule membrane: (a) the activity is stimulated upon disrupting membrane continuity by either hypotonic lysis or addition of nondenaturing detergents; (b) proton ionophores enhance the activity in intact but not in disrupted α granules; (c) permeating anions stimulate the ATPase more than slowly permeant or impermeant ones; (d) addition of NH₃ (as either NH₄Cl or (NH₄)₂SO₄) activates enzyme activity; (e) silicotungstate and disulfonic stilbene derivatives, which are inhibitors of other H⁺-transporting ATPases, also inhibit the α-granule enzyme. These findings are compared with the reported properties of H⁺ pumps of other storage and secretory organelles.     

ATP-dependent and ionophore-induced proton translocation in pea stem microsomal vesicles

The presence of an electrogenic pump in pea stem microsomal vesicles has already been demonstrated, but no evidence on the nature of the electrogenic ion has been presented (Rasi-Caldogno, F., De Michelis, M.I. and Pugliarello, M.C. (1981) Biochim. Biophys. Acta 642, 37–45). In this work we tested the usefulness of the ΔpH probe Acridine orange to monitor both ATP-dependent and ionophore-induced H⁺ fluxes in pea stem microsomal vesicles. The H⁺/K⁺ exchanger nigericin causes a marked uptake of protons into the vesicles that can be followed, with similar results, both as Acridine orange absorbance changes and pH changes of the external medium. ATP induces an uptake of Acridine orange into the vesicles which is reversed by FCCP and abolished by the presence of Triton X-100 in the incubation medium, thus indicating an inward, ATP-driven, H⁺ translocation. The ATP-dependent acridine orange uptake is Mg²⁺-requiring and KCl-stimulated. Such activity is inhibited by two specific ATPase inhibitors, dicyclohexylcarbodiimide and diethylstilbestrol, while it is unaffected by oligomycin and Na₃VO₄. These results show that Acridine orange is a useful probe to measure pH gradients in our membrane system and are consistent with the hypothesis that an ATPase of plasmalemma may act as a proton pump.     

Functional analysis of amino acids of the Na+/H+ exchanger that are important for proton translocation

The Na⁺/H⁺ exchanger is an integral membrane protein found in the plasma membrane of eukaryotic and prokaryotic cells. In eukaryotes it functions to exchange one proton for a sodium ion. In mammals it removes intracellular protons while in plants and fungal cells the plasma membrane form removes intracellular sodium in exchange for extracellular protons. In this study we used the Na⁺/H⁺ exchanger of Schizosaccharomyces pombe (Sod2) as a model system to study amino acids critical for activity of the protein. Twelve mutant forms of the Na⁺/H⁺ exchanger were examined for their ability to translocate protons as assessed by a cytosensor microphysiometer. Mutation of the amino acid Histidine 367 resulted in defective proton translocation. The acidic residues Asp145, Asp178, Asp266 and Asp267 were important in the proton translocation activity of the Na⁺/H⁺ exchanger. Mutation of amino acids His98, His233 and Asp241 did not significantly impair proton translocation by the Na⁺/H⁺ exchanger. These results confirm that polar amino acids are important in proton flux activity of Na⁺/H⁺ exchangers.     

Apparent inhibition of Na+/H+ exchange by amiloride and harmaline in acridine orange studies

Amiloride and harmaline were tested as inhibitors of proton movements in brush-border membrane vesicles from rat kidney cortex. Transmembrane pH differences were visualized using acridine orange. Fluorescence quenching due to Na⁺ gradient-driven intravesicular acidification was inhibited by amiloride and harmaline. However, a similar inhibition was observed for the Na⁺ gradient-driven electrogenic proton movements in the presence of gramicidin. Moreover, amiloride and harmaline decreased the fluorescence signal of electrogenic proton movements driven by a K⁺ gradient in the presence of valinomycin. The degree of inhibition of intravesicular acidification by both drugs was concentration dependent. Half-maximal inhibition (I₅₀) of Na⁺/H⁺ exchange and K⁺ gradient-driven proton movements occurred at 0.21 and 0.6 amiloride, respectively. The I₅₀ for harmaline was 0.21 mM in both cases. Amiloride also decreased the initial quenching of acridine orange fluorescence due to a preset pH gradient without affecting the rate of dissipation of the pH gradient. This effect was independent of the buffer capacity. In contrast, harmaline seemed to dissipate pH gradient in the same way as a permeant buffer. Amiloride and harmaline led to a concentration-dependent fluorescence decrease even in aqueous solution. The results suggest an interaction of amiloride and harmaline with acridine orange which overlaps a possible specific inhibition of Na⁺/H⁺ exchange by these drugs.     

Demonstration of the electrogenicity of proton translocation during the phosphorylation step in gastric H+K+-ATPase

Summary Membrane fragments containing the H⁺K^–-ATPase from parietal cells have been adsorbed to a planar lipid membrane. The transport activity of the enzyme was determined by measuring electrical currents via the capacitive coupling between the membrane sheets and the planar lipid film. To initiate the pump currents by the ATPase a light-driven concentration jump of ATP from caged ATP was applied as demonstrated previously for Na⁺K⁺-ATPase (Fendler, K., Grell, E., Haubs, M., Bamberg, E. 1985.EMBO J. 4:3079–3085). Since H⁺K⁺-ATPase is an electroneutrally working enzyme no stationary pump currents were observed in the presence of K⁺. By separation of the H⁺ and K⁺ transport steps of the reaction cycle, however, the electrogenic step of the phosphorylation could be measured. This was achieved in the absence of K⁺ or at low concentrations of K⁺. The observed transient current is ATP dependent which can be assigned to the proton movement during the phosphorylation. From this it was conclueded that the K⁺ transport during dephosphorylation is electrogenic, too, in contrast to the Na⁺K⁺-ATPase where the K⁺ step is electroneutral. The transient current was measured at different ionic conditions and could be blocked by vanadate and by the H⁺K⁺-ATPase specific inhibitor omeprazole. An alternative mechanism for activation of this inhibitor is discussed.     

Iron respiration-driven proton translocation in aerobic bacteria

Washed cell suspensions of Aquaspirillum magnetotacticum MS-1, A. itersonii E12639, Bacillus subtilis 6633, and Escherichia coli CSH27 translocated protons in response to the added oxidant O2 or NO3-, with triphenylmethylphosphonium bromide as the permeant ion. Iron respiration-driven proton translocation was observed in A. magnetotacticum MS-1, B. subtilis, and E. coli but not in a nonmagnetic strain of A. magnetotacticum (strain NM-1A) or with A. itersonii. Proton translocation to Fe3+ was totally inhibited by 500 microM NaN3 or 0.5 microM carbonyl cyanide m-chlorophenylhydrazone.     

On the mechanism of H+ translocation by mitochondrial H+-ATPase. Studies with chemical modifier of tyrosine residues

In this paper a detailed study of the effect of nitration of tyrosine residues by tetranitromethane on H⁺ conduction and other reactions catalyzed by the H⁺-ATPase complex in phosphorylating submitochondrial particles, uncoupled particles, and the purified complex is presented. Tetranitromethane treatment of submitochondrial particles results in marked inhibition of ATP hydrolysis, ATP-³³P_i exchange, and proton conduction by the H⁺-ATPase complex. These effects are caused by nitration of tyrosine residues of H⁺-ATPase complex as shown by the appearance of the absorption peak at 360 nm (specific for nitrotyrosine formation) and inhibition of ATP hydrolysis and ATP-³³P_i exchange in the complex purified from tetranitromethane-treated particles. H⁺ conduction in phospholipid vesicles inlaid with F₀ is also inhibited by tetranitromethane treatment. These observations indicate that tyrosine residue(s) of F₀ are critically involved in energy-linked proton translocation in the ATP-ase complex.     

Proton translocation of the bovine chromaffin-granule membrane.

Bovine chromaffin granules were lysed and their membranes resealed to give osmotically sensitive 'ghosts'. These swell in the presence of salts and MgATP. It is shown that this is due to proton entry accompanied by anions. The rate of swelling depends on the anion present, but swelling is not limited to media containing permeant anions. It is quite marked in solutions of sulphates, phosphates and acetates. It is not uncoupler-sensitive, suggesting that at least one component of swelling is due to coupled proton and anion entry (non-electrogenic proton translocation). Direct measurements of transmembrane pH and potential gradients generated in the presence of MgATP shows that these are rapidly established in sucrose media, and are rather little affected by the presence of salts. They contribute roughly equally to the total protonmotive force. The potential gradient is establihsed very rapidly, but the pH gradient is generated over several minutes. The gradients are not completely dissipated by uncoupler, and it is shown that, in media containing sulphate but no permeant anion, sulphate can be taken up by the 'ghosts'. There thus appear to be two mechanisms of proton translocation across the membrane, both dependent on ATP hydrolysis: an electrogenic transfer of protons, and proton movement linked to an anion transporter of broad specificity.     

Energy-dependent accumulation of the uncoupler picrate and proton flux in submitochondrial particles

In the presence of ATP and oxidizable substrate, submitochondrial particles accumulate up to 7 nmol of picrate/mg of protein. Half of this value is reached at 5 μM picrate in the medium, and maximal energy-dependent accumulation occurs at 25 μM picrate. Mitochondrial proton fluxes calculated under such conditions are 0.80 and 1.08 pmol H⁺/cm²·sec at 10 μM and 25 μM picrate, respectively. These values are similar to those reported for state 4, and are therefore not large enough for uncoupling by picrate through proton translocation. The energy-dependent spectral response of oxonol VI is reversed to 50 % by 40 μM picrate, suggesting that abolishment of membrane potential is responsible for uncoupling of submitochondrial particles by picrate.     

Regeneration and inhibition of proton pumping activity of bacteriorhodopsin blue membrane by cationic amine anesthetics

Bacteriorhodopsin (bR) is the prototype of an integral membrane protein with seven membrane-spanning α-helices and serves as a model of the G-protein-coupled drug receptors. This study is aimed at reaching a greater understanding of the role of amine local anesthetic cations on the proton transport in the bR protein, and furthermore, the functional role of “the cation” in the proton pumping mechanism. The effect of the amine anesthetic cations on the proton pump in the bR blue membrane was compared with those by divalent (Ca²⁺, Mg²⁺ and Mn²⁺) and monovalent metal cations (Li⁺, Na⁺, K⁺ and Cs⁺), which are essential for the correct functioning of the proton pumping of the bR protein. The results suggest that the interacting site of the divalent cation to the bR membrane may differ from that of the monovalent metal cation. The electric current profile of the bR blue membrane in the presence of the amine anesthetic cations was biphasic, involving the generation and inhibition of the proton pumping activity in a concentration-dependent manner. The extent of the regeneration of the proton pump by the additives increased in the order of monovalent metal cation<monovalent amine anesthetic cation<divalent metal cation. We found that organic cations such as the amine anesthetics can also regenerate the proton pump in the bR protein. The inhibition of proton transport in the bR protein by the anesthetic cations was elucidated using the wild type, the E204Q and the D96N mutated bRs. The hydrophobic interaction of the amine anesthetics with the bR protein plays an important part in inhibiting the bR proton pump.     

Characterization of a proton pump from pea stem microsomes

Abstract The present work deals with the characterization of an ATP-dependent proton translocation monitored by the ΔpH probe acridine orange. The ATP-dependent proton translocation has an optimum activity at pH 6.5 and is substrate specific for ATP. It is stimulated by Cl⁻, HCO₃⁻ and Br⁻, but is insensitive to several monovalent cations. Divalent cations (Mg²⁺ or Mn²⁺) are required for proton translocation, while in the presence of Ca²⁺ no uptake is observed. NO₃⁻, NO₂⁻ and citrate strongly inhibit proton uptake. On the contrary, F⁻, SO₄²⁻, malate, pyruvate, succinate, oxalate and acetate have no inhibitory effect. Proton uptake is stimulated by valinomycin and unaffected by molybdate. Two thiols, dithioerythritol and dithiothreitol, are able partially to prevent the FCCP-abolished proton uptake or partially restore the ATP-dependent proton translocation in FCCP-collapsed vesicles. It is suggested that pea stem microsomes possess an electrogenic ATPase, acting as a proton pump, which, on the basis of its characteristics, can be tentatively associated with membranes of tonoplast origin.     

Stoichiometry of proton translocation coupled to substrate oxidation in plant mitochondria

The proton translocation coupled to the electron flux from succinate, exogenous NADH, and NAD⁺-linked substrates (malate and isocitrate) to cytochrome c and to oxygen was studied in purified potato (Solanum tuberosum) mitochondria using oxygen and ferricyanide pulse techniques. In the presence of valinomycin plus K⁺ (used as a charge compensating cation), optimum values of H⁺/2 e⁻ were obtained when low amounts of electron acceptors (oxygen or ferricyanide) were added to the mitochondria (1-2 nanogram [2 e⁻] equivalents per milligram protein). The stoichiometry of proton translocation to electron flux was unaffected in the presence of N-ethylmaleimide, an inhibitor of the Pi/H⁺ symport. With succinate as substrate, H⁺/2 e⁻ ratios were 4.0 ± 0.2 and 3.7 ± 0.3 with oxygen and ferricyanide as electron acceptors, respectively. With exogenous NADH, H⁺/2e⁻ ratios were 4.1 ± 0.9 and 3.4 ± 0.2, respectively. The proton translocation coupled to the oxidation of NAD⁺-linked substrates (malate, isocitrate) was dependent upon the presence of adenylates (ADP, AMP, or ATP). For malate (+ glutamate) oxidation the observed H⁺/2 e⁻ ratios were increased from 3.6 ± 2.2 to 6.5 ± 0.5 in the presence of 20 micromolar ADP.