A model for conformational coupling of membrane potential and proton translocation to ATP synthesis and to active transport.

Acceptance of a membrane potential and/or a proton gradient as a possible means of transmitting energy from oxidations to ATP synthesis rests in part on a satisfactory hypothesis for how the potential or proton gradient could drive ATP synthesis. Recognition that energy input may drive ATP synthesis by change in binding of reactants at the catalytic site has led to the suggestions presented in this paper. These are that in oxidative phosphorylation and photophosphorylation, the requisite conformational changes may be coupled to exposure of charged groups to different sides of the membrane. The cycle of charged group exposure or movement may be driven by the membrane potential or, through protonation and deprotonation, may be coupled to proton translocation across the membrane. Effects of proton gradient and membrane potential may be additive. Similar conformational coupling suggestions may explain proton translocation coupled to ATP cleavage and active transport of metabolites coupled to membrane potential, proton gradients of ATP cleavage.     

Evidence for chemiosmotic coupling of electron transport to ATP synthesis in spinach chloroplasts

In spinach chloroplasts it has been shown that (1) the size of the proton gradient under phosphorylating conditions is smaller than under non-phosphorylating conditions; (2) ADP, ATP or Dio-9, added under non-phosphorylating conditions, decrease the rate of electron transport but increase the size of the proton gradient; (3) ADP, ATP or Dio-9 inhibit not only electron transport but also the rate of decay of the proton gradient; (4) the H⁺/e⁻ ratio under non-phosphorylating conditions is 1.0. It is not affected by ADP, ATP or Dio-9.

These results show that protons pass out of the thylakoids at the site of ATP synthesis and that this leakage is inhibited by ADP, ATP or Dio-9, compounds that interact with the site of ATP synthesis. As these compounds do not alter the H⁺/e⁻ ratio the formation of the proton gradient must be an intermediate between electron transport and ATP synthesis. These data are in support of the chemiosmotic theory of coupling of electron transport to ATP synthesis.     

Discrimination between transmembrane ion gradient-driven and electron transfer-driven ATP synthesis in the methanogenic bacteria

As with Methanococcus voltae [(1986) FEBS Lett. 200, 177–180], ATP synthesis in Methanobacterium thermoautotrophicum (ΔH) can be driven by the imposition of a sodium gradient, but only in the presence of a counterion. Monensin (but not SF6847) inhibits this synthesis. Methanogenic electron transfer-driven ATP synthesis, however, is insensitive to the combination of these two ionophores. In M. voltae, 117 μM diethylstilbestrol effectively inhibits both membrane potential- and sodium gradient-driven ATP synthesis, but has no effect on ATP production coupled to methanogenesis. In Mb. thermoautotrophicum (ΔH), a similar pattern of inhibition is exhibited by harmaline, an inhibitor of sodium-linked membrane transport systems. We conclude that ATP-driven sodium translocation and electron transfer-driven ATP synthesis are accomplished by separate entities, at least for these two only distantly related species of methanogen.     

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.     

Anaerobic respiration and energy conservation in Paracoccus denitrificans. Functioning of iron-sulfur centers and the uncoupling effect of nitrite.

1. Electron paramagnetic resonance spectra at 8-60 K of NADH-reduced membrane particles prepared from Paracoccus denitrificans grown anaerobically with nitrate as terminal electron acceptor show the presence of iron-sulfur centers 1-4 in the NADH-ubiquinone segment of the respiratory chain. In addition resonance lines at g = 2.058, g = 1.953 and g = 1.88 are detectable in the spectra of succinate-reduced membranes at 15 K, which are attributed to the iron-sulfur-containing nitrate reductase. 2. Sulphate-limited growth under anaerobic conditions does not affect the iron-sulfur pattern of NADH dehydrogenase or nitrate reductase. Furthermore respiratory chain-linked electron transport and its inhibition by rotenone are not influenced. These results contrast those observed for sulphate-limited growth of P. denitrificans under aerobic conditions [Eur. J. Biochem. (1977) 81, 267-275]. 3. Proton translocation studies of whole cells indicate that nitrite increases the proton conductance of the cytoplasmic membrane, resulting in a collapse of the proton gradient across the membrane. Nitrite accumulates under anaerobic growth conditions with nitrate as terminal electron acceptor; the extent of accumulation depends on the specific growth conditions. Thus the low efficiencies of respiratory chain-linked energy conservation observed during nitrate respiration [Arch. Microbiol. (1977) 112, 17-23] can be explained by the uncoupling action of nitrite.     

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 flux through the chloroplast ATP synthase is altered by cleavage of its gamma subunit

Electron transport, the proton gradient and ATP synthesis were determined in thylakoids that had been briefly exposed to a low concentration of trypsin during illumination. This treatment cleaves the gamma subunit of the ATP synthase into two large fragments that remain associated with the enzyme. Higher rates of electron transport are required to generate a given value of the proton gradient in the trypsin-treated membranes than in control membranes, indicating that the treated membranes are proton leaky. Since venturicidin restores electron transport and the proton gradient to control levels, the proton leak is through the ATP synthase. Remarkably, the synthesis of ATP by the trypsin-treated membranes at saturating light intensities is only slightly inhibited even though the proton gradient is significantly lower in the treated thylakoids. ATP synthesis and the proton gradient were determined as a function of light intensity in control and trypsin-treated thylakoids. The trypsin-treated membranes synthesized ATP at lower values of the proton gradient than the control membranes. Cleavage of the gamma subunit abrogates inhibition of the activity of the chloroplast ATP synthase by the epsilon subunit. Our results suggest that overcoming inhibition by the epsilon subunit costs energy.     

Monoclonal antibodies against the lac carrier protein from Escherichia coli. 1. Functional studies

The effects of various monoclonal antibodies against purified lac carrier protein on carrier-mediated lactose transport were studied in right-side-out membrane vesicles and in proteoliposomes reconstituted with purified lac carrier protein. Out of more than 60 monoclonal antibodies tested, only one antibody, designated 4B1, inhibits transport. Furthermore, the nature of the inhibition is highly specific in that the antibody inhibits only those transport reactions that involve net proton translocation (i.e., active transport, carrier-mediated influx and efflux under nonenergized conditions, and lactone-induced proton influx). In contrast, the antibody has little effect on equilibrium exchange and no effect on generation of the proton electrochemical gradient or on the ability of the carrier to bind a high-affinity ligand. Clearly, therefore, the antibody alters the relationship between lactose and proton translocation at the level of the lac carrier protein. When entrance counterflow is studied with external [1-14C]lactose at saturating and subsaturating concentrations, it is apparent that antibody 4B1 mimics the effects of deuterium oxide [Viitanen, P., Garcia, M.L., Foster, D.L., Kaczorowski, G. J., & Kaback, H.R. (1983) Biochemistry 22, 2531]. That is, the antibody has no effect on the rate or extent of counterflow when external lactose is saturating but stimulates the efficiency of counterflow when external lactose is below the apparent Km. It seems likely, therefore, that the antibody either inhibits the rate of deprotonation or alters the equilibrium between protonated and deprotonated forms of the carrier. Monovalent Fab fragments prepared from antibody 4B1 inhibit transport in a manner that is similar qualitatively to that of the intact antibody.(ABSTRACT TRUNCATED AT 250 WORDS)     

Energy transduction in intact synaptosomes. Influence of plasma-membrane depolarization on the respiration and membrane potential of internal mitochondria determined in situ.

A method is described, based on the differential accumulation of Rb+ and methyltriphenylphosphonium, for the simultaneous estimation of the membrane potentials across the plasma membrane of isolated nerve endings (synaptosomes), and across the inner membrane of mitochondria within the synaptosomal cytoplasm. These determinations, together with measurements of respiratory rates, and ATP and phosphocreatine concentrations, are used to define the bioenergetic behaviour of isolated synaptosomes under a variety of conditions. Under control conditions, in the presence of glucose, the plasma and mitochondrial membrane potentials are respectively 45 and 148mV. Addition of a proton translocator induces a 5-fold increase in respiration, and abolishes the mitochondrial membrane potential. The addition of rotenone to inhibit respiration does not affect the plasma membrane potential, and only lowers the mitochondrial membrane potential to 128mV. Evidence is presented that ATP synthesis by anaerobic glycolysis is sufficient under these conditions to maintain ATP-dependent processes, including the reversal of the mitochondrial ATP synthetase. Addition of oligomycin under non-respiring conditions leads to a complete collapse of the mitochondrial potential. Even under control conditions the plasma membrane (Na+ + K+)-dependent ATPase is responsible for a significant proportion of the synaptosomal ATP turnover. Veratridine greatly increases respiration, and depolarizes the plasma membrane, but only slightly lowers the mitochondrial membrane potential. High K+ and ouabain also lower the plasma membrane potential without decreasing the mitochondrial membrane potential. In non-respiring synaptosomes, anaerobic glycolysis is incapable of maintaining cytosolic ATP during the increased turnover induced by veratridine, and the mitochondrial membrane potential collapses. It is concluded that the internal mitochondria must be considered in any study of synaptosomal transport.     

Membrane-related processes and overall energy metabolism inTrypanosoma brucei and other kinetoplastid species

An electrochemical proton gradient exists across the plasma membrane and the mitochondrial membrane of the bloodstream form ofTrypanosoma brucei. The membrane potential across the plasma membrane and the regulation of the internal pH depend on the temperature.Leishmania donovani regulates its internal pH and maintains a constant electrochemical proton gradient across its plasma membrane under all conditions examined. The mitochondrion of theT. brucei bloodstream form is energized, even though the reactions taking place in it do not result in net ATP synthesis and the Kreb's cycle and the respiratory chain are absent. Glucose is transported across the plasma membrane ofT. brucei by a facilitated diffusion carrier, that can transport a wider range of substrates than its mammalian counterparts. Pyruvate exits the cell via a facilitated diffusion transporter as well. Conflicting evidence exists for the mechanism of glucose transport inL. donovani; biochemical evidence suggests proton/glucose symport, while facilitated diffusion is indicated by physiological data.     

Proton flux through the chloroplast ATP synthase is altered by cleavage of its gamma subunit

Electron transport, the proton gradient and ATP synthesis were determined in thylakoids that had been briefly exposed to a low concentration of trypsin during illumination. This treatment cleaves the γ subunit of the ATP synthase into two large fragments that remain associated with the enzyme. Higher rates of electron transport are required to generate a given value of the proton gradient in the trypsin-treated membranes than in control membranes, indicating that the treated membranes are proton leaky. Since venturicidin restores electron transport and the proton gradient to control levels, the proton leak is through the ATP synthase. Remarkably, the synthesis of ATP by the trypsin-treated membranes at saturating light intensities is only slightly inhibited even though the proton gradient is significantly lower in the treated thylakoids. ATP synthesis and the proton gradient were determined as a function of light intensity in control and trypsin-treated thylakoids. The trypsin-treated membranes synthesized ATP at lower values of the proton gradient than the control membranes. Cleavage of the γ subunit abrogates inhibition of the activity of the chloroplast ATP synthase by the ε subunit. Our results suggest that overcoming inhibition by the ε subunit costs energy.     

Bioenergetics of Carbon Assimilation in Intact Chloroplasts: Coupling of Proton to Electron Transport at the Ratio H+/e=3 Is Incompatible with H+/ATP=3 in ATP Synthesis

During a transition from aerobic to largely anaerobic conditionslight-saturated carbon assimilation of intact chloroplasts wasnot decreased although both the transthylakoid proton gradientand ATP levels declined. After a dark period under anaerobiosis,illumination failed to initiate carbon assimilation. ATP increasedonly transiently in the light and then returned to the darklevel. Under such conditions, the addition of electron acceptorssuch as oxygen, oxalacetate or nitrite resulted in the increaseof ATP levels and carbon assimilation was initiated. Assimilationcontinued under anaerobiosis in the presence of reduced protongradients and reduced ATP levels after electron acceptors addedin addition to bicarbonate were reduced. Cyclic electron transport was inhibited when anaerobiosis didnot permit linear electron transport. It was induced in thissituation by micromolar concentrations of oxygen or when, underanaerobiosis, DCMU decreased PSII activity. Oxygen inhibitedcyclic electron transport by draining electrons from the cyclicpathway only when electron donation from PSII was weak. Theobservations give evidence of the delicate redox balance requiredfor cyclic electron transport. Since H⁺/e=3 in linear electron transport, the observationsof effective carbon reduction under a decreased transthylakoidproton gradient and decreased levels of ATP are incompatiblewith H⁺/ATP=2 or 3. They are compatible with H⁺/ATP=4. (Received May 1, 1995; Accepted October 3, 1995)     

Observation of calcium-dependent unidirectional rotational motion in recombinant photosynthetic F1-ATPase molecules

ATP hydrolysis and synthesis by the F(0)F(1)-ATP synthase are coupled to proton translocation across the membrane in the presence of magnesium. Calcium is known, however, to disrupt this coupling in the photosynthetic enzyme in a unique way: it does not support ATP synthesis, and CaATP hydrolysis is decoupled from any proton translocation, but the membrane does not become leaky to protons. Understanding the molecular basis of these calcium-dependent effects can shed light on the as yet unclear mechanism of coupling between proton transport and rotational catalysis. We show here, using an actin filament gamma-rotation assay, that CaATP is capable of sustaining rotational motion in a highly active hybrid photosynthetic F(1)-ATPase consisting of alpha and beta subunits from Rhodospirillum rubrum and gamma subunit from spinach chloroplasts (alpha(R)(3)beta(R)(3)gamma(C)). The rotation was found to be similar to that induced by MgATP in Escherichia coli F(1)-ATPase molecules. Our results suggest a possible long range pathway that enables the bound CaATP to induce full rotational motion of gamma but might block transmission of this rotational motion into proton translocation by the F(0) part of the ATP synthase.     

Effects of dinitrophenol and oligomycin on the coupling between anaerobic metabolism and anaerobic sodium transport by the isolated turtle bladder

Dinitrophenol (1 x 10^-5 M) has been found to inhibit anaerobic sodium transport by the isolated urinary bladder of the fresh water turtle. Concurrently, anaerobic glycolysis was stimulated markedly. However, tissue ATP levels diminished only modestly, remaining at approximately 75% of values observed under anaerobic conditions without DNP. The utilization of glucose (from endogenous glycogen) corresponded closely to that predicted from the molar quantities of lactate formed. Thus the glycolytic pathway was completed in the presence of DNP and if ATP were synthesized normally during glycolysis, synthesis should have been increased. On the other hand, the decrease in Na transport should have decreased ATP utilization. Oligomycin did not block sodium transport either aerobically or anaerobically, but ATP concentrations did decrease. When anaerobic glycolysis was blocked by iodoacetate, pyruvate did not sustain sodium transport thus suggesting that no electron acceptors were available in the system. Two explanations are entertained for the anaerobic effect of DNP: (a) Stimulation by DNP of plasma membrane as well as mitochondrial ATPase activity; (b) inhibition of a high energy intermediate derived from glycolytic ATP or from glycolysis per se. The arguments relevant to each possibility are presented in the text. Although definitive resolution is not possible, we believe that the data favor the hypothesis that there was a high energy intermediate in the anaerobic system and that this intermediate, rather than ATP, served as the immediate source of energy for the sodium pump.     

Glucose uptake by the cellulolytic ruminal anaerobe Bacteroides succinogenes.

Glucose uptake by Bacteroides succinogenes S85 was measured under conditions that maintained anaerobiosis and osmotic stability. Uptake was inhibited by compounds which interfere with electron transport systems, maintenance of proton or metal ion gradients, or ATP synthesis. The most potent inhibitors were proton and metal ionophores. Oxygen strongly inhibited glucose uptake. Na+ and Li+, but not K+, stimulated glucose uptake. A variety of sugars, including alpha-methylglucoside, did not inhibit glucose uptake. Only cellobiose and 2-deoxy-D-glucose were inhibitory, but neither behaved as a competitive inhibitor. Metabolism of both sugars appeared to be responsible for the inhibition. Cells grown in cellobiose medium transported glucose at one-half the rate of glucose-grown cells. Spheroplasts transported glucose as well as whole cells, indicating glucose uptake is not dependent on a periplasmic glucose-binding protein. Differences in glucose uptake patterns were detected in cells harvested during the transition from the lag to the log phase of growth compared with cells obtained during the log phase. These differences were not due to different mechanisms for glucose uptake in the cell types. Based on the results of this study, B. succinogenes contains a highly specific, active transport system for glucose. Evidence of a phosphoenolpyruvate-glucose phosphotransferase system was not found.     

Effect of magnesium on ATP-generating and ATP-utilizing reactions in Ehrlich ascites tumour cells

The effect of magnesium on the energy metabolism of Ehrlich ascites tumour cells was investigated using a method which allows to change the cellular content of magnesium rapidly at constant low calcium concentration. Cells, which have lost some of their magnesium, accumulate lactate slightly faster than non-treated cells. Mg-loading of these cells decreases the glycolytic flux rates to about 20% under aerobic and anaerobic conditions. The corresponding changes of some glycolytic metabolites suggest an inhibition of the HK-PFK-system. A similar inhibitory effect of Mg on O2-consumption in the absence and presence of glucose to about 20% and 15%, respectively, was observed. Despite the inhibition of the ATP-generating systems the ATP concentration increases under all conditions investigated, indicating an inhibition of ATP consuming systems. From experiments in the presence of ouabain, which inhibits the aerobic glycolysis to about 40% and 20%, in Mg-depleted and Mg-loaded cells, respectively, it is concluded that magnesium affects the active monovalent cation transport. Removal of magnesium increases the activity of the (Na+-K+)-ATPase and vice versa, presumably via changes of the cell membrane permeability.     

The organisation of proton motive and non-proton motive redox loops in prokaryotic respiratory systems

Respiration is fundamental to the aerobic and anaerobic energy metabolism of many prokaryotic and most eukaryotic organisms. In principle, the free energy of a redox reaction catalysed by a membrane-bound electron transport chain is transduced via the generation of an electrochemical ion (usually proton) gradient across a coupling membrane that drives ATP synthesis. The proton motive force (pmf) can be built up by different mechanisms like proton pumping, quinone/quinol cycling or by a redox loop. The latter couples electron transport to a net proton transfer across the membrane without proton pumping. Instead, charge separation is achieved by quinone-reactive enzymes or enzyme complexes whose active sites for substrates and quinones are situated on different sides of the coupling membrane. The necessary transmembrane electron transport is usually accomplished by the presence of two haem groups that face opposite sides of the membrane. There are many different enzyme complexes that are part of redox loops and their catalysed redox reactions can be either electrogenic, electroneutral (non-proton motive) or even pmf-consuming. This article gives conceptual classification of different operational organisations of redox loops and uses this as a platform from which to explore the biodiversity of quinone/quinol-cycling redox systems.     

Synthesis of adenosine triphosphate by an artificially imposed electrochemical proton gradient in bovine heart submitochondrial particles.

Submitochondrial particles subjected to an artificially imposed electrochemical proton gradient consisting of a pH gradient (acid to base transition) and membrane potential (low to high K-+ transition in the presence of valinomycin) catalyzed the net synthesis of 2.5 nmol of [-32P]ATP per mg of protein from ADP and 32-Pi. Optimal reaction conditions included incubation of submitochondrial particles in malonate at pH 5.0 with valinomycin in the absence of added K-+, followed by a rapid transition to pH 7.5 and 100 mM K-+. ATP synthesis continued for about 6 s and was sensitive to uncouplers or oligomycin but insensitive to inhibitors of electron transport. Lower amounts of ATP were formed by either the pH gradient (25%) of K-+ gradient (15%) alone. These results demonstrate that an electrochemical gradient of protons can drive the synthesis of ATP by reversal of the proton-translocating ATPase independent of electron transport.     

Uncoupling of Ca2+ transport in sarcoplasmic reticulum as a result of labeling lipid amino groups and inhibition of Ca2+-ATPase activity by modification of lysine residues of the Ca2+-ATPase polypeptide

Limited labeling of amino groups with fluorescamine in fragmented sarcoplasmic reticulum vesicles inhibits Ca2+-ATPase activity and Ca2+ transport. Under the labeling conditions used, 80% of the label reacts with phosphatidylethanolamine and 20% with the Ca2+-ATPase polypeptide. This degree of labeling does not result in vesicular disruption or in loss of vesicular proteins and does not increase the membrane permeability to Ca2+. Fluorescamine labeling of a purified Ca2+-ATPase devoid of aminophospholipids also inhibits Ca2+-ATPase activity, suggesting that labeling of lysine residues of the enzyme polypeptide is responsible for the inhibition of Ca2+-ATPase activity in sarcoplasmic reticulum. Fluorescamine labeling interferes with phosphoenzyme formation and decomposition in both the native vesicles and the purified enzyme; addition of ATP during labeling, and with less effectiveness ADP or AMP, protects both partial reaction steps. Addition of a nonhydrolyzable ATP analog protects phosphoenzyme formation but not decomposition. The inhibition of Ca2+ transport but not of Ca2+-ATPase occurs in sarcoplasmic reticulum vesicles labeled in the presence of ATP, indicating that the transport reaction is uncoupled from the Ca2+-ATPase reaction. The inhibition of Ca2+ transport but not of Ca2+-ATPase activity is also found in sarcoplasmic reticulum vesicles in which only phosphatidylethanolamine has reacted with fluorescamine. Furthermore, the extent of labeling of phosphatidylethanolamine is correlated with the inhibition of Ca2+ transport rates. The inhibition of Ca2+ transport is a reflection of the inhibition of Ca2+ translocation and is not due to an increase in Ca2+ efflux. We propose that labeling of phosphatidylethanolamine perturbs the lipid environment around the enzyme, producing a specific defect in the Ca2+ translocation reaction.     

Stimulation of protein synthesis in cultured heart muscle cells by glucose.

Glucose stimulated the rate of incorporation of [3H]leucine into HCLO4-insoluble fraction of cultured rat heart muscle cells under both aerobic and anaerobic conditions. In the aerobic system the incorporation proceeded at a constant rate during 3h of incubation with and without glucose whereas in the anaeorbic system the incorporation ceased after approx. 60 min and could be renewed only by the addition of glucose. No correlation was found to exist between the above effect of glucose on protein synthesis and glucose-dependent changes in the intracellular ATP concentration. The extent of the stimulation of protein synthesis was related to the concentration of glucose. The effect of glucose was suppressed by cycloheximide but was not affected by actinomycin D. Glucose had no effect on the rate of transport of alpha-aminoisobutyric acid. Mannose also stimulated [3H]leucine incorporation. Substances that did not produce lactate were ineffective. Iodoacetate inhibited the stimulatory effect of glucose, but pyruvate, which by itself had no apprecialbe stimulatory action, relieved the inhibition induced by iodoacetate. There was no concomitant change in the concentration of ATP when iodoacetate inhibition was reversed by pyruvate. L-Lactate or other intermediates of energy metabolism could not relieve the inhibitory effect of iodoacetate.