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.     

Stimulation of ATP synthesis in Halobacterium halobium R1 by light-induced or artificially created proton electrochemical potential gradients across the cell membrane

The relationship between proton movement and phosphorylation in Halobacterium halobium R₁ has been investigated under anaerobic conditions. The light-induced changes in the bacteriorhodopsin are accompanied by proton movements across the cell membrane which result in pH changes in the suspending medium. The initial alkaline shift is shown to be closely paralleled by (and hence correlated with) ATP synthesis. Acidification of the medium in the presence of valinomycin, under conditions of low external potassium, brings about ATP synthesis in the dark.     

Photophosphorylation in cell envelope vesicles from Halobacteriumhalobium

We have prepared vesicles from cell envelope membranes of $\text{Halobacterium}\text{halobium}$ strains R₁ and ET-15 which are able to synthesize ATP in response to illumination. This photophosphorylation is inhibited by dicyclohexylcarbodiimide (DCCD) and by phloretin. ATP synthesis in L vesicles from the R₁ strain (which contain bacteriorhodopsin) is inhibited by the protonophore 1799 but not by valinomycin. In M vesicles from the R₁ strain and in ET-15 vesicles (both contain halorhodopsin) photophosphorylation is inhibited by both 1799 and valinomycin. These data are consistent with the idea that light-driven ATP synthesis can be coupled to the electrochemical H⁺ gradient generated by bacteriorhodopsin or by halorhodopsin through the membrane potential component of protonmotive force.     

Ammonium uptake kinetics in root and leaf cells of Zostera marina L.

Ammonium uptake rates and the mechanism for ammonium transport into the cells have been analysed in Zostera marina L. In the cells of this species, a proton pump is present in the plasmalemma, which maintains the membrane potential. However, this seagrass shows a high-affinity transport mechanism both for nitrate and phosphate which is dependent on sodium and is unique among angiosperms. We have then analysed if the transport of another N form, ammonium, is also dependent of sodium. First, we have studied ammonium transport at the cellular level by measurements of membrane potentials, both in epidermal root cells and mesophyll cells. And second, we have monitored uptake rates in whole leaves and roots by depletion experiments. The results showed that ammonium is taken up by a high-affinity transport system both in root and leaf cells, although two different of kinetics could be discerned in mesophyll cells (with affinity constants of 2.2 ± 1.1 μM NH₄⁺, in the range 0.01-10 μM NH₄⁺, and 23.2 ± 7.1 μM NH₄⁺, at concentrations between 10 and 500 μM NH₄⁺). However, only one kinetic could be observed in epidermal root cells, which showed a K_m = 11.2 ± 1.0 μM NH₄⁺, considering the whole ammonium concentration range assayed (0.01-500 μM NH₄⁺). The higher affinity of leaf cells for ammonium was consistent with the higher uptake rates observed in leaves, with respect to roots, in depletion experiments at 10 μM NH₄⁺ initial concentration. However, when an initial concentration of 100 μM was assayed, the difference between uptake rates was reduced, but still being higher in leaves. Variations in proton or sodium-electrochemical gradient did not affect ammonium uptake, suggesting that the transport of this nutrient is not driven by these ions and that the ammonium transport mechanism could be different to the transport of nitrate and phosphate in this species.     

Energy-linked activities in reconstituted yeast adenosine triphosphatase proteoliposome. Adenosine triphosphate formation coupled with electron flow between ascorbate and ferricyanide.

(1) Conditions are described wherein the yeast oligomycin-sensitive adenosine triphosphatase (ATPase) complex can be reconstituted together with phospholipids to yield extremely high rates of ATP-³²P_j exchange. The vesicles so formed exhibit proton uptake upon addition of Mg²⁺-ATP and a relatively slow decay of the proton gradient. (2) The stimulation of ATP-³²P_i exchange by valinomycin + K⁺ reported previously (Ryrie, I. J. (1975) Arch. Biochem. Biophys. 168, 704–711) is apparently not simply due to a diffusion potential. The findings suggest that an electroimpelled, valinomycin-dependent migration of K⁺ may occur together with the electrogenic movements of protons during ATP hydrolysis and synthesis to establish optimal energized conditions for ATP-³²P_i exchange. (3) An artificial oxidative phosphorylation system in the reconstituted vesicles is described: [³²P]ATP formation from ADP and ³²P_i is shown to be linked with electron flow between external ascorbate and internal ferricyanide where a permeable proton carrier, such as phenazine methosulfate, is used to establish a proton gradient. That the yeast ATPase is capable of net ATP synthesis has also been demonstrated in a light-dependent reaction using ATPase proteoliposomes reconstituted together with bacteriorhodopsin.     

A peptide containing residues 26-44 of tau protein impairs mitochondrial oxidative phosphorylation acting at the level of the adenine nucleotide translocator

Having confirmed that adenovirus-mediated overexpression of NH₂-tau fragment lacking the first 25 aminoacids evokes a potent neurotoxic effect, sustained by protracted stimulation of NMDA receptors, in primary neuronal cultures we investigated whether and how chemically synthesized NH₂-derived tau peptides, i.e. NH₂-26-44 and NH₂-1-25 fragments, affect mitochondrial function. We tested both fragments on each step of the processes leading to ATP synthesis via oxidative phosphorylation: i) electron flow via the respiratory chain from physiological substrates to oxygen with the activity of each individual complex of the respiratory chain investigated in some detail, ii) membrane potential generation arising from externally added succinate and iii) the activity of both the adenine nucleotide translocator and iv) ATP synthase. Oxidative phosphorylation is not affected by NH₂-1-25 tau fragment, but dramatically impaired by NH₂-26-44 tau fragment. Both cytochrome c oxidase and the adenine nucleotide translocator are targets of NH₂-26-44 tau fragment, but adenine nucleotide translocator is the unique mitochondrial target responsible for impairment of oxidative phosphorylation by the NH₂-26-44 tau fragment, which then exerts deleterious effects on cellular availability of ATP synthesized into mitochondria.     

Function, structure and regulation of the vacuolar (H+)-ATPases

The vacuolar ATPases (or V-ATPases) are ATP-driven proton pumps that function to both acidify intracellular compartments and to transport protons across the plasma membrane. Intracellular V-ATPases function in such normal cellular processes as receptor-mediated endocytosis, intracellular membrane traffic, prohormone processing, protein degradation and neurotransmitter uptake, as well as in disease processes, including infection by influenza and other viruses and killing of cells by anthrax and diphtheria toxin. Plasma membrane V-ATPases are important in such physiological processes as urinary acidification, bone resorption and sperm maturation as well as in human diseases, including osteopetrosis, renal tubular acidosis and tumor metastasis. V-ATPases are large multi-subunit complexes composed of a peripheral domain (V₁) responsible for hydrolysis of ATP and an integral domain (V₀) that carries out proton transport. Proton transport is coupled to ATP hydrolysis by a rotary mechanism. V-ATPase activity is regulated in vivo using a number of mechanisms, including reversible dissociation of the V₁ and V₀ domains, changes in coupling efficiency of proton transport and ATP hydrolysis and changes in pump density through reversible fusion of V-ATPase containing vesicles. V-ATPases are emerging as potential drug targets in treating a number of human diseases including osteoporosis and cancer.     

brp and blh are required for synthesis of the retinal cofactor of bacteriorhodopsin in Halobacterium salinarum

Bacteriorhodopsin, the light-driven proton pump of Halobacterium salinarum, consists of the membrane apoprotein bacterioopsin and a covalently bound retinal cofactor. The mechanism by which retinal is synthesized and bound to bacterioopsin in vivo is unknown. As a step toward identifying cellular factors involved in this process, we constructed an in-frame deletion of brp, a gene implicated in bacteriorhodopsin biogenesis. In the Deltabrp strain, bacteriorhodopsin levels are decreased approximately 4.0-fold compared with wild type, whereas bacterioopsin levels are normal. The probable precursor of retinal, beta-carotene, is increased approximately 3.8-fold, whereas retinal is decreased by approximately 3.7-fold. These results suggest that brp is involved in retinal synthesis. Additional cellular factors may substitute for brp function in the Deltabrp strain because retinal production is not abolished. The in-frame deletion of blh, a brp paralog identified by analysis of the Halobacterium sp. NRC-1 genome, reduced bacteriorhodopsin accumulation on solid medium but not in liquid. However, deletion of both brp and blh abolished bacteriorhodopsin and retinal production in liquid medium, again without affecting bacterioopsin accumulation. The level of beta-carotene increased approximately 5.3-fold. The simplest interpretation of these results is that brp and blh encode similar proteins that catalyze or regulate the conversion of beta-carotene to retinal.     

ATP synthesis catalyzed by a V-ATPase: an alternative pathway for energy conservation operating in plant vacuoles?

The electrochemical H⁺ gradient generated in tonoplast vesicles isolated from maize seeds was found to be able to drive the reversal of the catalytic cycle of both vacuolar H⁺-pumps (Façanha and de Meis, 1998). Here we describe the reversibility of the vacuolar V-type H⁺-ATPase (V-ATPase) even in the absence of the H⁺ gradient in a water-Me₂SO co-solvent mixture, resulting in net synthesis of [γ-³²P]ATP from [³²P]P_i and ADP. The water-Me₂SO (5 to 20 %) media promoted inhibition of both PP_i hydrolysis and synthesis reactions whereas it slightly affected the ATP hydrolysis and clearly stimulated the ATP synthesis, which was unaffected by uncoupling agents (FCCP, Triton X-100 or NH₄⁺). This effect of Me₂SO on the ATP⇔³²P exchange reaction seems to be related to a decrease of the apparent K_m of the V-ATPase for P_i. The results are in accordance to the concept that the energetics of ATP synthesis catalysis depends on the solvation energies interacting in the enzyme microenvironment. A possible physiological significance of this phenomenon for the metabolism of desiccation-tolerant plant cells is discussed.Key words: bind energy, proton pumps, proton gradient, DMSO, corn seeds, V₁V₀-ATPase, membrane bound H⁺-pyrophosphatase     

Factors defining the functional coupling of bacteriorhodopsin and ATP synthase in liposomes

Optimal conditions for the co-reconstitution of bacteriorhodopsin and yeast mitochondria ATP synthase were determined. Reconstitution was achieved with a quick two-step procedure. Preparations obtained by this method displayed in optimal cases 2–3-times higher activities (up to 500 nmol ATP/min per mg protein) compared with maximal values reported in the literature, when light-driven ATP synthesis was measured under similar conditions. The final activities depended on the purification method used for the ATP synthase, and it is shown that the oligomycin-sensitive ATP hydrolysis activity was not a good measure for the ability of the ATP synthase preparations to perform ATP synthesis after co-reconstitution. Light-driven ATP synthesis activities depended also on the type of phospholipid used, soybean phospholipid giving the best results. A close relation to the bacteriorhodopsin proton pump activity was found. Using different phospholipids, different $\text{H}{}^{\mathrm{+}}\text{ATP}$ ratios were found, calculated from ATP synthesis activities and initial and steady-state light-driven proton pump activities. From this, together with the findings that the ATP synthase displayed the same ATP hydrolysis and ATP-³²P_i exchange activities with these different phospholipids used, it is concluded that the protein distribution for the two proteins among the liposomes is different relative to each other for the different phospholipids. The light-driven ATP synthesis activity did not correlate with the variation in leakiness of the membrane for protons when different phospholipids were used. An explanation is given by the finding that at high light intensities, the ATP synthesis became independent of the presence of protonophore.     

Light-induced generation of a protonmotive force and Ca2+-transport in membrane vesicles of Streptococcus cremoris fused with bacteriorhodopsin proteoliposomes

The light-driven primary proton pump bacteriorhodopsin has been incorporated in the cytoplasmic membrane of Streptococcus cremoris, in order to generate a protonmotive force across these membranes. This has been achieved by fusion of S. cremoris membrane vesicles with bacteriorhodopsin proteoliposomes. This fusion occurred when both preparations were mixed at low pH (less than 6.0), as shown by sucrose density gradient centrifugation and by dilution of fluorescent phospholipids incorporated into the bacteriorhodopsin proteoliposomes. Fusion was strongly enhanced by the presence of negatively charged phospholipids in the liposomal bilayer. When proteoliposomes were used that showed light-dependent proton uptake, the orientation of bacteriorhodopsin in the fused membranes was inside-out with respect to the in vivo orientation in Halobacterium halobium. Consequently, in the light a ΔΨ, interior positive and a ΔpH, interior acid were generated. This protonmotive force could drive calcium uptake in the fused membranes. The uptake increased hyperbolically with increasing light intensity and was abolished by bleaching of bacteriorhodopsin. Addition of the ionophore valinomycin stimulated calcium uptake and led to an increase of the ΔpH. Calcium uptake was strongly decreased in the dark and in the light in the presence of uncouplers, nigericin or both valinomycin and nigericin.     

Regulation of proton leakage from broken chloroplasts by CF0.

Measurements of proton translocation in CF₁-depleted, N, N′-dicyclohexylcarbodiimide-resealed broken chloroplasts were made under different light intensities. Kinetic analysis of the data shows that the outward leakage of accumulated protons through CF₀ is still dependent on light intensity with a first-order rate constant equal to mR₀, where R₀ is the initial rate of proton uptake which normally increases with light intensity and m is a characteristic constant which is independent of proton gradient and light intensity. Measurements of proton translocation in these modified chloroplasts cross-linked with glutaraldehyde under illumination and in the dark respectively suggest that the light-dependent proton leakage through CF₀ is regulated by conformation change in the membrane. It is proposed that the ovserved regulation of proton leakage through the CF₁.CF₀ complex in native chloroplasts is for optimizing the steady state synthesis of ATP under different light intensities.     

Two possible roles of bacteriorhodopsin; a comparative study of strains of Halobacterium halobium differing in pigmentation.

The light-induced changes in pH and ATP level were compared for cell suspensions between strains of Halobacterium halobium differing in pigmentation after growth under the same conditions. Upon illumination, red cells which contained no detectable amount of bacteriorhodopsin showed only a pH increase, which, in the case of purple cells containing bacteriorhodopsin, was followed by a spontaneous pH decrease during illumination. Pre-incubation of cells at 75° for 5 min depressed the pH increase in both cells. Pre-illumination of cells with hydroxylamine depressed the pH decrease in purple cells. Whenever the pH increase was observed, the cellular ATP level increased. The presence of a bacteriorhodopsin different from that in the purple membrane is postulated.     

Bacterial chimeras and reversible phosphorylation: the work of Walther Stoeckenius

In 1971, Walther Stoeckenius discovered that Halobacterium halobium contains a purple pigment that is chemically similar to rhodopsin and works as a light-driven proton pump. This discovery set Stoeckenius on a research path centered on bacteriorhodopsin, which included the creation of a bovine-soybean-halobacteria chimera that was able to produce ATP when exposed to light and the discovery of a class of proteins that are phosphorylated in a light-dependent manner.Reconstitution of Purple Membrane Vesicles Catalyzing Light-driven Proton Uptake and Adenosine Triphosphate Formation (Racker, E., and Stoeckenius, W. (1974) J. Biol. Chem. 249, 662–663)Light-regulated Retinal-dependent Reversible Phosphorylation of Halobacterium Proteins (Spudich, J. L., and Stoeckenius, W. (1980) J. Biol. Chem. 255, 5501–5503)Walther Stoeckenius was born in 1921 in Giessen, Germany. He earned an M.D. degree from the University of Hamburg in 1950, after which he spent 18 months doing clinical work as an intern. In 1952, he began postdoctoral work at the Institute for Tropical Medicine in Hamburg, using electron microscopy to study the development of pox viruses. Two years later, he joined the Department of Pathology at the University of Hamburg as an assistant professor and became Docent for Pathology in 1958. At Hamburg, Stoeckenius continued to use electron microscopy to explore the fine structure of cells and the lipid membrane.In 1959, Stoeckenius left Germany to become a research associate in Keith Porter''s laboratory at Rockefeller University. After a few months, he became an assistant professor at Rockefeller, remaining there for 8 years and eventually becoming an associate professor. He continued to work on membrane structure, studying Halobacterium halobium, until he accepted a professorship at the University of California, San Francisco in 1967.In San Francisco, Stoeckenius focused more on biochemical techniques rather than electron microscopy. In collaboration with Dieter Oesterhelt, he discovered that H. halobium contains a purple pigment (bacteriorhodopsin) that is chemically similar to rhodopsin (1) and plays an important role in light energy storage in halobacteria, working as a light-driven proton pump (2).This discovery led to a collaboration with Journal of Biological Chemistry (JBC) Classic author Efraim Racker (3) in which Stoeckenius and Racker created a thoroughly unnatural vesicle. As reported in the first JBC Classic reprinted here, they used sonication to recombine membrane lipids from soybeans, bacteriorhodopsin from halobacteria, and ATPase from beef mitochondria. The resulting artificial vesicles were able to produce ATP when exposed to light. The chimeric vesicles also formed a simple model system for a biological proton pump capable of generating ATP from ADP and P_i.Stoeckenius continued to study bacteriorhodopsin and its light-driven proton uptake in bacteria. As reported in the second JBC Classic reprinted here, he discovered that phosphorylation is regulated by light absorbed by bacteriorhodopsin (4). Using [³²P]orthophosphate pulse labeling, Stoeckenius and John Spudich identified a class of phosphoproteins in H. halobium. Exposing labeled whole cells to light resulted in rapid dephosphorylation of two of the proteins, which were rapidly rephosphorylated upon darkening of the cells. The light sensitivity of the proteins was responsive to the presence of retinal, indicating that the dephosphorylation depended on rhodopsin-like (retinal-containing) photoreceptors.Stoeckenius currently is Professor Emeritus in the Department of Biochemistry and Biophysics and the Cardiovascular Research Institute at the University of California, San Francisco. He was elected to the National Academy of Sciences in 1978.     

Formation of ATP by the adenosine triphosphatase complex from spinach chloroplasts reconstituted together with bacteriorhodopsin

The energy-linked ATPase complex has been isolated from spinach chloroplasts. This protein complex contained all the subunits of the chloroplast coupling factor (CF₁) as well as several hydrophobic components. When the activated complex was reconstituted with added soybean phospholipids, it catalyzed the exchange of radioactive inorganic phosphate with ATP. Sonication of the complex into proteoliposomes together with bacteriorhodopsin yielded vesicles that catalyzed light-dependent ATP formation. Both the ³²P_i-ATP exchange reactions and ATP formation were sensitive to uncouplers such as 3-tert-butyl-5,2′-dichloro-4′-nitrosalicylanilide, bis-(hexafluoroacetonyl)acetone and carbonyl cyanide-p-trifluoromethoxyphenyl-hydrazone, that act to dissipate a proton gradient. The energy transfer inhibitors dicyclohexylcarbodiimide, triphenyltin chloride and 2-β-d-glucopyranosyl-4,6′-dihydroxydihydrochalcone were also effective inhibitors of both reactions.     

The mechanism of rotating proton pumping ATPases

Two proton pumps, the F-ATPase (ATP synthase, F_oF₁) and the V-ATPase (endomembrane proton pump), have different physiological functions, but are similar in subunit structure and mechanism. They are composed of a membrane extrinsic (F₁ or V₁) and a membrane intrinsic (F_o or V_o) sector, and couple catalysis of ATP synthesis or hydrolysis to proton transport by a rotational mechanism. The mechanism of rotation has been extensively studied by kinetic, thermodynamic and physiological approaches. Techniques for observing subunit rotation have been developed. Observations of micron-length actin filaments, or polystyrene or gold beads attached to rotor subunits have been highly informative of the rotational behavior of ATP hydrolysis-driven rotation. Single molecule FRET experiments between fluorescent probes attached to rotor and stator subunits have been used effectively in monitoring proton motive force-driven rotation in the ATP synthesis reaction. By using small gold beads with diameters of 40-60 nm, the E. coli F₁ sector was found to rotate at surprisingly high speeds (> 400 rps). This experimental system was used to assess the kinetics and thermodynamics of mutant enzymes. The results revealed that the enzymatic reaction steps and the timing of the domain interactions among the β subunits, or between the β and γ subunits, are coordinated in a manner that lowers the activation energy for all steps and avoids deep energy wells through the rotationally-coupled steady-state reaction. In this review, we focus on the mechanism of steady-state F₁-ATPase rotation, which maximizes the coupling efficiency between catalysis and rotation.     

Modeling the membrane potential generation of bacteriorhodopsin

The archaeon Halobacterium salinarum can grow phototrophically with only light as its energy source. It uses the retinal containing and light-driven proton pump bacteriorhodopsin to enhance the membrane potential which drives the ATP synthase. Therefore, a model of the membrane potential generation of bacteriorhodopsin is of central importance to the development of a mathematical model of the bioenergetics of H. salinarum. To measure the current produced by bacteriorhodopsin at different light intensities and clamped voltages, we expressed the gene in Xenopus laevis oocytes. We present current-voltage measurements and a mathematical model of the current-voltage relationship of bacteriorhodopsin and its generation of the membrane potential. The model consists of three intermediate states, the BR, L, and M states, and comparisons between model predictions and experimental data show that the L to M reaction must be inhibited by the membrane potential. The model is not able to fit the current-voltage measurements when only the M to BR phase is membrane potential dependent, while it is able to do so when either only the L to M reaction or both reactions (L to M and M to BR) are membrane potential dependent. We also show that a decay term is necessary for modeling the rate of change of the membrane potential.     

Photophosphorylation Associated with Photosystem II: III. Characterization of Uncoupling, Energy Transfer Inhibition, and Proton Uptake Reactions Associated with Photosystem II Cyclic Photophosphorylation

A number of uncouplers and energy transfer inhibitors suppress photosystem II cyclic photophosphorylation catalyzed by either a proton/electron or electron donor. Valinomycin and 2,4-dinitrophenol also inhibit photosystem II cyclic photophosphorylation, but these compounds appear to act as electron transport inhibitors rather than as uncouplers. Only when valinomycin, KCl, and 2,4-dinitrophenol were added simultaneously to phosphorylation reaction mixtures was substantial uncoupling observed. Photosystem II noncyclic and cyclic electron transport reactions generate positive absorbance changes at 518 nm. Uncoupling and energy transfer inhibition diminished the magnitude of these absorbance changes. Photosystem II cyclic electron transport catalyzed by either p-phenylenediamine or N,N,N′,N′-tetramethyl-p-phenylenediamine stimulated proton uptake in KCN-Hg-NH₂OH-inhibited spinach (Spinacia oleracea L.) chloroplasts. Illumination with 640 nm light produced an extent of proton uptake approximately 3-fold greater than did 700 nm illumination, indicating that photosystem II-catalyzed electron transport was responsible for proton uptake. Electron transport inhibitors, uncouplers, and energy transfer inhibitors produced inhibitions of photosystem II-dependent proton uptake consistent with the effects of these compounds on ATP synthesis by the photosystem II cycle. These results are interpreted as indicating that endogenous proton-translocating components of the thylakoid membrane participate in coupling of ATP synthesis to photosystem II cyclic electron transport.     

Mitochondrial hyperpolarization during chronic complex I inhibition is sustained by low activity of complex II,III, IV and V

The mitochondrial oxidative phosphorylation (OXPHOS) system consists of four electron transport chain (ETC) complexes (CI–CIV) and the F_oF₁-ATP synthase (CV), which sustain ATP generation via chemiosmotic coupling. The latter requires an inward-directed proton-motive force (PMF) across the mitochondrial inner membrane (MIM) consisting of a proton (ΔpH) and electrical charge (Δψ) gradient. CI actively participates in sustaining these gradients via trans-MIM proton pumping. Enigmatically, at the cellular level genetic or inhibitor-induced CI dysfunction has been associated with Δψ depolarization or hyperpolarization. The cellular mechanism of the latter is still incompletely understood. Here we demonstrate that chronic (24 h) CI inhibition in HEK293 cells induces a proton-based Δψ hyperpolarization in HEK293 cells without triggering reverse-mode action of CV or the adenine nucleotide translocase (ANT). Hyperpolarization was associated with low levels of CII-driven O₂ consumption and prevented by co-inhibition of CII, CIII or CIV activity. In contrast, chronic CIII inhibition triggered CV reverse-mode action and induced Δψ depolarization. CI- and CIII-inhibition similarly reduced free matrix ATP levels and increased the cell's dependence on extracellular glucose to maintain cytosolic free ATP. Our findings support a model in which Δψ hyperpolarization in CI-inhibited cells results from low activity of CII, CIII and CIV, combined with reduced forward action of CV and ANT.