Control of rotation of the F<Subscript>1</Subscript>F<Subscript>O</Subscript>-ATP synthase nanomotor by an inhibitory α-helix from unfolded ε or intrinsically disordered ζ and IF<Subscript>1</Subscript> proteins

The ATP synthase is a ubiquitous nanomotor that fuels life by the synthesis of the chemical energy of ATP. In order to synthesize ATP, this enzyme is capable of rotating its central rotor in a reversible manner. In the clockwise (CW) direction, it functions as ATP synthase, while in counter clockwise (CCW) sense it functions as an proton pumping ATPase. In bacteria and mitochondria, there are two known canonical natural inhibitor proteins, namely the ε and IF₁ subunits. These proteins regulate the CCW F₁F_O-ATPase activity by blocking γ subunit rotation at the α_DP/β_DP/γ subunit interface in the F₁ domain. Recently, we discovered a unique natural F₁-ATPase inhibitor in Paracoccus denitrificans and related α-proteobacteria denoted the ζ subunit. Here, we compare the functional and structural mechanisms of ε, IF₁, and ζ, and using the current data in the field, it is evident that all three regulatory proteins interact with the α_DP/β_DP/γ interface of the F₁-ATPase. In order to exert inhibition, IF₁ and ζ contain an intrinsically disordered N-terminal protein region (IDPr) that folds into an α-helix when inserted in the α_DP/β_DP/γ interface. In this context, we revised here the mechanism and role of the ζ subunit as a unidirectional F-ATPase inhibitor blocking exclusively the CCW F₁F_O-ATPase rotation, without affecting the CW-F₁F_O-ATP synthase turnover. In summary, the ζ subunit has a mode of action similar to mitochondrial IF₁, but in α-proteobacteria. The structural and functional implications of these intrinsically disordered ζ and IF₁ inhibitors are discussed to shed light on the control mechanisms of the ATP synthase nanomotor from an evolutionary perspective.     

Unidirectional regulation of the F1FO-ATP synthase nanomotor by the ζ pawl-ratchet inhibitor protein of Paracoccus denitrificans and related α-proteobacteria

The ATP synthase is a reversible nanomotor that gyrates its central rotor clockwise (CW) to synthesize ATP and in counter clockwise (CCW) direction to hydrolyse it. In bacteria and mitochondria, two natural inhibitor proteins, namely the ε and IF₁ subunits, prevent the wasteful CCW F₁F_O-ATPase activity by blocking γ rotation at the α_DP/β_DP/γ interface of the F₁ portion. In Paracoccus denitrificans and related α-proteobacteria, we discovered a different natural F₁-ATPase inhibitor named ζ. Here we revise the functional and structural data showing that this novel ζ subunit, although being different to ε and IF₁, it also binds to the α_DP/β_DP/γ interface of the F₁ of P. denitrificans. ζ shifts its N-terminal inhibitory domain from an intrinsically disordered protein region (IDPr) to an α-helix when inserted in the α_DP/β_DP/γ interface. We showed for the first time the key role of a natural ATP synthase inhibitor by the distinctive phenotype of a Δζ knockout mutant in P. denitrificans. ζ blocks exclusively the CCW F₁F_O-ATPase rotation without affecting the CW-F₁F_O-ATP synthase turnover, confirming that ζ is important for respiratory bacterial growth by working as a unidirectional pawl-ratchet PdF₁F_O-ATPase inhibitor, thus preventing the wasteful consumption of cellular ATP. In summary, ζ is a useful model that mimics mitochondrial IF₁ but in α-proteobacteria. The structural, functional, and endosymbiotic evolutionary implications of this ζ inhibitor are discussed to shed light on the natural control mechanisms of the three natural inhibitor proteins (ε, ζ, and IF₁) of this unique ATP synthase nanomotor, essential for life.     

The structure of F1-ATPase from Saccharomyces cerevisiae inhibited by its regulatory protein IF1

The structure of F₁-ATPase from Saccharomyces cerevisiae inhibited by the yeast IF₁ has been determined at 2.5 Å resolution. The inhibitory region of IF₁ from residues 1 to 36 is entrapped between the C-terminal domains of the α_DP- and β_DP-subunits in one of the three catalytic interfaces of the enzyme. Although the structure of the inhibited complex is similar to that of the bovine-inhibited complex, there are significant differences between the structures of the inhibitors and their detailed interactions with F₁-ATPase. However, the most significant difference is in the nucleotide occupancy of the catalytic β_E-subunits. The nucleotide binding site in β_E-subunit in the yeast complex contains an ADP molecule without an accompanying magnesium ion, whereas it is unoccupied in the bovine complex. Thus, the structure provides further evidence of sequential product release, with the phosphate and the magnesium ion released before the ADP molecule.     

The affinity purification and characterization of ATP synthase complexes from mitochondria

The mitochondrial F₁-ATPase inhibitor protein, IF₁, inhibits the hydrolytic, but not the synthetic activity of the F-ATP synthase, and requires the hydrolysis of ATP to form the inhibited complex. In this complex, the α-helical inhibitory region of the bound IF₁ occupies a deep cleft in one of the three catalytic interfaces of the enzyme. Its N-terminal region penetrates into the central aqueous cavity of the enzyme and interacts with the γ-subunit in the enzyme''s rotor. The intricacy of forming this complex and the binding mode of the inhibitor endow IF₁ with high specificity. This property has been exploited in the development of a highly selective affinity procedure for purifying the intact F-ATP synthase complex from mitochondria in a single chromatographic step by using inhibitor proteins with a C-terminal affinity tag. The inhibited complex was recovered with residues 1–60 of bovine IF₁ with a C-terminal green fluorescent protein followed by a His-tag, and the active enzyme with the same inhibitor with a C-terminal glutathione-S-transferase domain. The wide applicability of the procedure has been demonstrated by purifying the enzyme complex from bovine, ovine, porcine and yeast mitochondria. The subunit compositions of these complexes have been characterized. The catalytic properties of the bovine enzyme have been studied in detail. Its hydrolytic activity is sensitive to inhibition by oligomycin, and the enzyme is capable of synthesizing ATP in vesicles in which the proton-motive force is generated from light by bacteriorhodopsin. The coupled enzyme has been compared by limited trypsinolysis with uncoupled enzyme prepared by affinity chromatography. In the uncoupled enzyme, subunits of the enzyme''s stator are degraded more rapidly than in the coupled enzyme, indicating that uncoupling involves significant structural changes in the stator region.     

The Inhibitor Protein (IF1) of the F1F0-ATPase Modulates Human Osteosarcoma Cell Bioenergetics

The bioenergetics of IF₁ transiently silenced cancer cells has been extensively investigated, but the role of IF₁ (the natural inhibitor protein of F₁F₀-ATPase) in cancer cell metabolism is still uncertain. To shed light on this issue, we established a method to prepare stably IF₁-silenced human osteosarcoma clones and explored the bioenergetics of IF₁ null cancer cells. We showed that IF₁-silenced cells proliferate normally, consume glucose, and release lactate as controls do, and contain a normal steady-state ATP level. However, IF₁-silenced cells displayed an enhanced steady-state mitochondrial membrane potential and consistently showed a reduced ADP-stimulated respiration rate. In the parental cells (i.e. control cells containing IF₁) the inhibitor protein was found to be associated with the dimeric form of the ATP synthase complex, therefore we propose that the interaction of IF₁ with the complex either directly, by increasing the catalytic activity of the enzyme, or indirectly, by improving the structure of mitochondrial cristae, can increase the oxidative phosphorylation rate in osteosarcoma cells grown under normoxic conditions.     

Regulation of the F1F0-ATP Synthase Rotary Nanomotor in its Monomeric-Bacterial and Dimeric-Mitochondrial Forms

The F₁F₀-adenosine triphosphate (ATP) synthase rotational motor synthesizes most of the ATP required for living from adenosine diphosphate, Pi, and a proton electrochemical gradient across energy-transducing membranes of bacteria, chloroplasts, and mitochondria. However, as a reversible nanomotor, it also hydrolyzes ATP during de-energized conditions in all energy-transducing systems. Thus, different subunits and mechanisms have emerged in nature to control the intrinsic rotation of the enzyme to favor the ATP synthase activity over its opposite and commonly wasteful ATPase turnover. Recent advances in the structural analysis of the bacterial and mitochondrial ATP synthases are summarized to review the distribution and mechanism of the subunits that are part of the central rotor and regulate its gyration. In eubacteria, the ε subunit works as a ratchet to favor the rotation of the central stalk in the ATP synthase direction by extending and contracting two α-helixes of its C-terminal side and also by binding ATP with low affinity in thermophilic bacteria. On the other hand, in bovine heart mitochondria, the so-called inhibitor protein (IF₁) interferes with the intrinsic rotational mechanism of the central γ subunit and with the opening and closing of the catalytic β-subunits to inhibit its ATPase activity. Besides its inhibitory role, the IF₁ protein also promotes the dimerization of the bovine and rat mitochondrial enzymes, albeit it is not essential for dimerization of the yeast F₁F₀ mitochondrial complex. High-resolution electron microscopy of the dimeric enzyme in its bovine and yeast forms shows a conical shape that is compatible with the role of the ATP synthase dimer in the formation of tubular the cristae membrane of mitochondria after further oligomerization. Dimerization of the mitochondrial ATP synthase diminishes the rotational drag of the central rotor that would decrease the coupling efficiency between rotation of the central stalk and ATP synthesis taking place at the F₁ portion. In addition, F₁F₀ dimerization and its further oligomerization also increase the stability of the enzyme to natural or experimentally induced destabilizing conditions.     

Putative ammo-terminal presequence for β-subunit of plant mitochondrial F1ATPase deduced from the amino-terminal sequence of the mature subunit

The α- and β-subunits of sweet potato mitochondrial F₁ATPase were purified from the F₁ complex by gel filtration and ion-exchange high-performance liquid chromatography. Isoelectric focussing and N-terminal amino acid sequencing indicated that the purified β-subunit contains at least two polypeptides similar to each other. The N-terminal 18 amino acid sequence of the β-subunit showed homology to the amino acid sequence of the tobacco mitochondrial F₁ATPase β-subunit precursor deduced from the nucleotide sequence [(1985) EMBO J. 4, 2159-2165] between residues 56 and 73, suggesting that the N-terminal 55 amino acids of the tobacco precursor constitute the presequence required for mitochondrial targetting.     

The Inhibitory Mechanism of the ζ Subunit of the F1FO-ATPase Nanomotor of Paracoccus denitrificans and Related α-Proteobacteria

The ζ subunit is a novel inhibitor of the F₁F_O-ATPase of Paracoccus denitrificans and related α-proteobacteria. It is different from the bacterial (ϵ) and mitochondrial (IF₁) inhibitors. The N terminus of ζ blocks rotation of the γ subunit of the F₁-ATPase of P. denitrificans (Zarco-Zavala, M., Morales-Ríos, E., Mendoza-Hernández, G., Ramírez-Silva, L., Pérez-Hernández, G., and García-Trejo, J. J. (2014) FASEB J. 24, 599–608) by a hitherto unknown quaternary structure that was first modeled here by structural homology and protein docking. The F₁-ATPase and F₁-ζ models of P. denitrificans were supported by cross-linking, limited proteolysis, mass spectrometry, and functional data. The final models show that ζ enters into F₁-ATPase at the open catalytic α_E/β_E interface, and two partial γ rotations lock the N terminus of ζ in an “inhibition-general core region,” blocking further γ rotation, while the ζ globular domain anchors it to the closed α_DP/β_DP interface. Heterologous inhibition of the F₁-ATPase of P. denitrificans by the mitochondrial IF₁ supported both the modeled ζ binding site at the α_DP/β_DP/γ interface and the endosymbiotic α-proteobacterial origin of mitochondria. In summary, the ζ subunit blocks the intrinsic rotation of the nanomotor by inserting its N-terminal inhibitory domain at the same rotor/stator interface where the mitochondrial IF₁ or the bacterial ϵ binds. The proposed pawl mechanism is coupled to the rotation of the central γ subunit working as a ratchet but with structural differences that make it a unique control mechanism of the nanomotor to favor the ATP synthase activity over the ATPase turnover in the α-proteobacteria.     

Availability to monoclonal antibodies of antigenic sites of the α and β subunits in active,denatured or membrane-bound mitochondrial F1-ATPase

The binding of five monoclonal antibodies to mitochondrial F₁-ATPase has been studied. Competition experiments between monoclonal antibodies demonstrate that these antibodies recognize four different antigenic sites and provide information on the proximity of these sites. The accessibility of the epitopes has been compared for F₁ integrated in the mitochondrial membrane, for purified β-subunit and for purified F₁ maintained in its active form by the presence of nucleotides or inactivated either by dilution in the absence of ATP or by urea treatment. The three anti-β monoclonal antibodies bound more easily to the β-subunit than to active F₁, and recognized equally active F₁ and F₁ integrated in membrane, indicating that their antigenic sites are partly buried similarly in purified or membrane-bound F₁ and better exposed in the isolated β-subunit. In addition, unfolding F₁ by urea strongly increased the binding of one anti-β monoclonal antibody (14 D₅) indicating that this domain is at least partly shielded inside the β-subunit. One anti-α monoclonal antibody (20 D₆) bound poorly to F₁ integrated in the membrane, while the other (7 B₃) had a higher affinity for F₁ integrated in the membrane than for soluble F₁. Therefore, 20 D₆ recognizes an epitope of the α-subunit buried inside F₁ integrated in the membrane, while 7 B₃ binds to a domain of the α-subunit well exposed at the surface of the inner face of the mitochondrial membrane.     

Regulatory proteins of F1F0-ATPase: Role of ATPase inhibitor

An intrinsic ATPase inhibitor inhibits the ATP-hydrolyzing activity of mitochondrial F₁F₀-ATPase and is released from its binding site on the enzyme upon energization of mitochondrial membranes to allow phosphorylation of ADP. The mitochondrial activity to synthesize ATP is not influenced by the absence of the inhibitor protein. The enzyme activity to hydrolyze ATP is induced by dissipation of the membrane potential in the absence of the inhibitor. Thus, the inhibitor is not responsible for oxidative phosphorylation, but acts only to inhibit ATP hydrolysis by F₁F₀-ATPase upon deenergization of mitochondrial membranes. The inhibitor protein forms a regulatory complex with two stabilizing factors, 9K and 15K proteins, which facilitate the binding of the inhibitor to F₁F₀-ATPase and stabilize the resultant inactivated enzyme. The 9K protein, having a sequence very similar to the inhibitor, binds directly to F₁ in a manner similar to the inhibitor. The 15K protein binds to the F₀ part and holds the inhibitor and the 9K protein on F₁F₀-ATPase even when one of them is detached from the F₁ part.     

NMR Structures of α-Proteobacterial ATPase-Regulating ζ-Subunits

NMR structures of ζ-subunits, which are recently discovered α-proteobacterial F₁F₀-ATPase-regulatory proteins representing a Pfam protein family of 246 sequences from 219 species (PF07345), exhibit a four-helix bundle, which is different from all other known F₁F₀-ATPase inhibitors. Chemical shift mapping reveals a conserved ADP/ATP binding site in ζ-subunit, which mediates long-range conformational changes related to function, as revealed by the structure of the Paracoccus denitrificans ζ-subunit in complex with ADP. These structural data suggest a new mechanism of F₁F₀-ATPase regulation in α-proteobacteria.     

Regulation of the mitochondrial ATPasein situ in cardiac muscle: Role of the inhibitor subunit

The mitochondrial F₁-ATPase inhibitor protein, IF₁, binds to subunits of the F₁-ATPase bothin vitro andin situ under nonenergizing conditions, i.e., under conditions that allow a net hydrolysis of ATP by the mitochondrial ATPase to take place. This reversible IF₁ binding occurs in a wide variety of cell types including (anaerobic) baker's yeast cells and (ischemic) mammalian cardiomyocytes under conditions that limit oxidative phosphorylation. The binding of inhibitor results in a marked slowing of ATP hydrolysis by the undriven mitochondrial ATP synthase. An apparent main function of this reversible IF₁ binding, at least in cells that undergo aerobic-anaerobic switching, is the mitigation of a wasteful hydrolysis of ATP produced by glycolysis during anoxic or ischemic intervals, by the mitochondrial ATPase. While this apparent main function is probably of considerable importance in cells that normally either can or must undergo aerobic-anaerobic switching such as baker's yeast cells and skeletal myocytes, one wonders why a full complement of IF₁ has been retained in certain cells that normally do not undergo such aerobic-anaerobic switching, cells such as adult mammalian cardiomyocytes of many species. While some mammalian species have, indeed, not retained a functional complement of IF₁ in their cardiomyocytes, those that have can benefit significantly from its presence during intervals of myocardial ischemia.This mini-review is dedicated to the memory of Professor Efraim Racker.     

Effects of Zn2+ on the activity and binding of the mitochondrial ATPase inhibitor protein,IF1

Zn²⁺ caused a noninhibitory binding of IF₁ to mitochondrial membranes in both rabbit heart SMP and intact rabbit heart mitochondria. This Zn²⁺-induced IF₁ binding required the presence of at least trace amounts of MgATP and was essentially independent of pH between 6.2 and 8.2. Addition of Zn²⁺ after the formation of fully inhibited IF₁-ATPase complexes very slowly reversed IF₁-mediated ATPase inhibition without causing significant IF₁ release from the membranes. When Zn²⁺ was added during the state 4 energization of ischemic mitochondria in which IF₁ was already functionally bound, it slowed somewhat energy-driven ATPase activation. This slowing was probably due to the fairly large depressing effect Zn²⁺ had upon membrane potential development, but Zn²⁺ did not decrease the degree of ATPase activation eventually reached at 20 min of state 4 incubation. Zn²⁺ also preempted normal IF₁ release from the membranes, causing what little inhibitor that was released to rebind to the enzyme in noninhibitory IF₁-ATPase complexes. The data suggest that IF₁ can interact with the ATPase in two ways or through two kinds of sites: (a) a noninhibitory interaction involving a noninhibitory IF₁ conformation and/or and IF₁ docking site on the enzyme and (b) an inhibitory interaction involving an inhibitory IF₁ conformation and/or a distinct ATPase activity regulatory site. Zn²⁺ appears to have the dual effect of stabilizing the noninhibitory IF₁-ATPase interaction and possibily a noninhibitory IF₁ conformation while concomitantly preventing the formation of an inhibitory IF₁-ATPase interaction and possibly an inhibitory IF₁ conformation, regardless of pH. While the data do not rule out direct effects of Zn²⁺ on either free IF₁ or the free enzyme, they suggest that Zn²⁺ cannot interact readily with either the inhibitor or the enzyme once functional IF₁-ATPase complexes are formed.     

Amputation of a C-terminal helix of the γ subunit increases ATP-hydrolysis activity of cyanobacterial F1 ATP synthase

F₁ is a soluble part of F_oF₁-ATP synthase and performs a catalytic process of ATP hydrolysis and synthesis. The γ subunit, which is the rotary shaft of F₁ motor, is composed of N-terminal and C-terminal helices domains, and a protruding Rossman-fold domain located between the two major helices parts. The N-terminal and C-terminal helices domains of γ assemble into an antiparallel coiled-coil structure, and are almost embedded into the stator ring composed of α₃β₃ hexamer of the F₁ molecule. Cyanobacterial and chloroplast γ subunits harbor an inserted sequence of 30 or 39 amino acids length within the Rossman-fold domain in comparison with bacterial or mitochondrial γ. To understand the structure–function relationship of the γ subunit, we prepared a mutant F₁-ATP synthase of a thermophilic cyanobacterium, Thermosynechococcus elongatus BP-1, in which the γ subunit is split into N-terminal α-helix along with the inserted sequence and the remaining C-terminal part. The obtained mutant showed higher ATP-hydrolysis activities than those containing the wild-type γ. Contrary to our expectation, the complexes containing the split γ subunits were mostly devoid of the C-terminal helix. We further investigated the effect of post-assembly cleavage of the γ subunit. We demonstrate that insertion of the nick between two helices of the γ subunit imparts resistance to ADP inhibition, and the C-terminal α-helix is dispensable for ATP-hydrolysis activity and plays a crucial role in the assembly of F₁-ATP synthase.     

Suppression of mitochondrial ATPase inhibitor protein (IF1) in the liver of late septic rats

Sepsis and ensuing multiple organ failure continue to be the most leading cause of death in critically ill patients. Despite hepatocyte-related dysfunctions such as necrosis, apoptosis as well as mitochondrial damage are observed in the process of sepsis, the molecular mechanism of pathogenesis remains uncertain. We recently identified one of the differentially expressed genes, mitochondrial ATPase inhibitor protein (IF1) which is down-regulated in late septic liver. Hence, we further hypothesized that the variation of IF1 protein may be one of the causal events of the hepatic dysfunction during late sepsis. The results showed that the elevated mitochondrial F₀F₁-ATPase activity is concomitant with the decline of intramitochondrial ATP concentration in late septic liver. In addition, the key finding of this study showed that the mRNA and the mitochondrial content of IF1 were decreased in late sepsis while no detectable IF1 was found in cytoplasm. When analyzed by immunoprecipitation, it seems reasonable to imply that the association capability of IF1 with F₁-ATPase β-subunit is not affected. These results confirm the first evidence showing that the suppression of IF1 expression and subsequent elevated mitochondrial F₀F₁-ATPase activity might contribute to the bioenergetic failure in the liver during late sepsis.     

The interaction of nucleotides with F1-ATPase inactivated with 4-chloro-7-nitrobenzofurazan

In common with the F₁-ATPase from other sources, yeast mitochondrial F₁-ATPase was inhibited by 4-chloro-7-nitrobenzofurazan. Total inhibition of the F₁-ATPase activity was compatible with the modification of a single tyrosine residue per F₁-ATPase molecule. Radioactive labelling experiments localized this modification on a β-subunit. The inactive modified enzyme retained the capacity to bind the photoaffinity label 8-azido-1,N⁶-etheno-ATP, which has previously been shown to bind nucleotide sites of low affinity. As well, the inactive modified enzyme bound MgATP with high affinity, yielding a K_d of 14 μM. The results are consistent with the hypothesis of alternating, or cooperative, site catalysis by F₁-ATPase.     

Role of the DELSEED Loop in Torque Transmission of F1-ATPase

F₁-ATPase is an ATP-driven rotary motor that generates torque at the interface between the catalytic β-subunits and the rotor γ-subunit. The β-subunit inwardly rotates the C-terminal domain upon nucleotide binding/dissociation; hence, the region of the C-terminal domain that is in direct contact with γ—termed the DELSEED loop—is thought to play a critical role in torque transmission. We substituted all the DELSEED loop residues with alanine to diminish specific DELSEED loop-γ interactions and with glycine to disrupt the loop structure. All the mutants rotated unidirectionally with kinetic parameters comparable to those of the wild-type F₁, suggesting that the specific interactions between DELSEED loop and γ is not involved in cooperative interplays between the catalytic β-subunits. Glycine substitution mutants generated half the torque of the wild-type F₁, whereas the alanine mutant generated comparable torque. Fluctuation analyses of the glycine/alanine mutants revealed that the γ-subunit was less tightly held in the α₃β₃-stator ring of the glycine mutant than in the wild-type F₁ and the alanine mutant. Molecular dynamics simulation showed that the DELSEED loop was disordered by the glycine substitution, whereas it formed an α-helix in the alanine mutant. Our results emphasize the importance of loop rigidity for efficient torque transmissions.     

Characterization of two cDNA clones encoding isozymes of the F1F0-ATPase inhibitor protein of rice mitochondria

Two cDNA clones encoding F₁F₀-ATPase inhibitor proteins, which are loosely associated with the F₁ part of the mitochondrial F₁F₀-ATPase, were characterized from rice (Oryza sativa L. cv. Nipponbare). A Northern hybridization showed that the two genes (designated as IF ₁ -1 and IF ₁ -2) are transcribed in all the organs examined. However, the steady-state mRNA levels varied among organs. A comparison of the deduced amino acid sequences of the two IF ₁ genes and the amino acid sequence of the mature IF₁ protein from potato revealed that IF₁-1 and IF₁-2 have N-terminal extensions with features that are characteristic of a mitochondrial targeting signal. To determine the subcellular localization of the gene products, the IF₁-1 or IF₁-2 proteins were fused in frame to the green fluorescent protein (GFP) or the fused GFP-β-glucuronidase, and expressed transiently in onion or dayflower epidermal cells. Localized fluorescence was detected in mitochondria, confirming that the two IF₁ proteins are targeted to mitochondria. Received: 9 July 1999 / Accepted: 17 August 1999     

Rotary catalysis of the stator ring of F1-ATPase

F₁-ATPase is a rotary motor protein in which 3 catalytic β-subunits in a stator α₃β₃ ring undergo unidirectional and cooperative conformational changes to rotate the rotor γ-subunit upon adenosine triphosphate hydrolysis. The prevailing view of the mechanism behind this rotary catalysis elevated the γ-subunit as a “dictator” completely controlling the chemical and conformational states of the 3 catalytic β-subunits. However, our recent observations using high-speed atomic force microscopy clearly revealed that the 3 β-subunits undergo cyclic conformational changes even in the absence of the rotor γ-subunit, thus dethroning it from its dictatorial position. Here, we introduce our results in detail and discuss the possible operating principle behind the F₁-ATPase, along with structurally related hexameric ATPases, also mentioning the possibility of generating hybrid nanomotors. This article is part of a Special Issue entitled: 17th European Bioenergetics Conference (EBEC 2012).     

In vitro and in vivo studies of F0F1ATP synthase regulation by inhibitor protein IF1 in goat heart

A method has been developed to allow the level of F₀F₁ATP synthase capacity and the quantity of IF₁ bound to this enzyme be measured in single biopsy samples of goat heart. ATP synthase capacity was determined from the maximal mitochondrial ATP hydrolysis rate and IF₁ content was determined by detergent extraction followed by blue native gel electrophoresis, two-dimensional SDS-PAGE and immunoblotting with anti-IF₁ antibodies.Anaesthetized open-chest goats were subjected to ischemic preconditioning and/or sudden increases of coronary blood flow (CBF) (reactive hyperemia). When hyperemia was induced before ischemic preconditioning, a steep increase in synthase capacity, followed by a deep decrease, was observed. In contrast, hyperemia did not affect synthase capacity when applied after ischemic preconditioning. Similar effects could be produced in vitro by treatment of heart biopsy samples with anoxia (down-regulation of the ATP synthase) or high-salt or high-pH buffers (up-regulation). We show that both in vitro and in vivo the same close inverse correlation exists between enzyme activity and IF₁ content, demonstrating that under all conditions tested the only significant modulator of the enzyme activity was IF₁. In addition, both in vivo and in vitro, 1.3-1.4 mol of IF₁ was predicted to fully inactivate 1 mol of synthase, thus excluding the existence of significant numbers of non-inhibitory binding sites for IF₁ in the F₀ sector.