Probes of inhibition of <Emphasis Type="Italic">Escherichia coli</Emphasis> F<Subscript>1</Subscript>-ATPase by 7-chloro-4-nitrobenz-2-oxa-1,3-diazole in the presence of MgADP and MgATP support a bi-site mechanism of ATP hydrolysis by the enzyme

Binding of MgADP and MgATP to Escherichia coli F₁-ATPase (EcF₁) has been assessed by their effects on extent of the enzyme inhibition by 7-chloro-4-nitrobenz-2-oxa-1,3-diazole (NBD-Cl). MgADP at low concentrations (K _d 1.3 μM) promotes the inhibition, whereas at higher concentrations (K _d 0.7 mM) EcF₁ is protected from inhibition. The mutant βY331W-EcF₁ requires much higher MgADP, K _d of about 10 mM, for protection. Such MgADP binding was not revealed by fluorescence quenching measurements. MgATP partially protects EcF1 from inactivation by NBD-Cl, but the enzyme remains sensitive to NBD-Cl in the presence of MgATP at concentrations as high as 10 mM. The activating anion selenite in the absence of MgATP partially protects EcF₁ from inhibition by NBD-Cl. A complete protection of EcF₁ from inhibition by NBD-Cl has been observed in the presence of both MgATP and selenite. The results support a bi-site catalytic mechanism for MgATP hydrolysis by F₁-ATPases and suggest that stimulation of the enzyme activity by activating anions is due to the anion binding to a catalytic site that remains unoccupied at saturating substrate concentration.     

ATP binding and hydrolysis steps of the uni-site catalysis by the mitochondrial F1-ATPase are affected by inorganic phosphate

The effect of inorganic phosphate (P_i) on uni-site ATP binding and hydrolysis by the nucleotide-depleted F₁-ATPase from beef heart mitochondria (ndMF₁) has been investigated. It is shown for the first time that P_i decreases the apparent rate constant of uni-site ATP binding by ndMF₁ 3-fold with the K_d of 0.38 ± 0.14 mM. During uni-site ATP hydrolysis, P_i also shifts equilibrium between bound ATP and ADP + P_i in the direction of ATP synthesis with the K_d of 0.17 ± 0.03 mM. However, 10 mM P_i does not significantly affect ATP binding during multi-site catalysis.     

The complex of mitochondrial F1-ATPase with the natural inhibitor protein is unable to catalyze single-site ATP hydrolysis

Interaction of mitochondrial F₁-ATPase with the isolated natural inhibitor protein resulting in the inhibition of multi-site ATP hydrolysis is accompanied by the loss of activity at low ATP concentrations when single-site hydrolysis should occur. Catalytic site occupancy by [¹⁴C]nucleotides in F₁-ATPase during steady-state [¹⁴C]ATP hydrolysis, which is saturated in parallel with single-site catalysis, is prevented after blocking the enzyme with the inhibitor protein.     

A unique mechanism of curcumin inhibition on F1 ATPase

ATP synthase (F-ATPase) function depends upon catalytic and rotation cycles of the F₁ sector. Previously, we found that F₁ ATPase activity is inhibited by the dietary polyphenols, curcumin, quercetin, and piceatannol, but that the inhibitory kinetics of curcumin differs from that of the other two polyphenols (Sekiya et al., 2012, 2014). In the present study, we analyzed Escherichia coli F₁ ATPase rotational catalysis to identify differences in the inhibitory mechanism of curcumin versus quercetin and piceatannol. These compounds did not affect the 120° rotation step for ATP binding and ADP release, though they significantly increased the catalytic dwell duration for ATP hydrolysis. Analysis of wild-type F₁ and a mutant lacking part of the piceatannol binding site (γΔ277–286) indicates that curcumin binds to F₁ differently from piceatannol and quercetin. The unique inhibitory mechanism of curcumin is also suggested from its effect on F₁ mutants with defective β–γ subunit interactions (γMet23 to Lys) or β conformational changes (βSer174 to Phe). These results confirm that smooth interaction between each β subunit and entire γ subunit in F₁ is pertinent for rotational catalysis.     

Acceleration of the ATP-binding rate of F1-ATPase by forcible forward rotation

F₁-ATPase (F₁) is a reversible ATP-driven rotary motor protein. When its rotary shaft is reversely rotated, F₁ produces ATP against the chemical potential of ATP hydrolysis, suggesting that F₁ modulates the rate constants and equilibriums of catalytic reaction steps depending on the rotary angle of the shaft. Although the chemomechanical coupling scheme of F₁ has been determined, it is unclear how individual catalytic reaction steps depend on its rotary angle. Here, we report direct evidence that the ATP-binding rate of F₁ increases upon the forward rotation of the rotor, and its binding affinity to ATP is enhanced by rotation.     

Subunit a of the F1F0 ATP Synthase Requires YidC and SecYEG for Membrane Insertion

The insertion of inner membrane proteins in Escherichia coli occurs almost exclusively via the SecYEG pathway, while some membrane proteins require the membrane protein insertase YidC. In vitro analysis demonstrates that subunit a of the F₁F₀ ATP synthase (F₀a) is strictly dependent on Ffh, SecYEG and YidC for its membrane insertion but independent of the proton motive force. The insertion of the first transmembrane segment of F₀a also depends on Ffh and SecYEG but not on YidC, whereas the insertion is strongly dependent on the proton motive force, unlike the full-length F₀a protein. These data demonstrate an extensive role of YidC in the assembly of the F₀ sector of the F₁F₀ ATP synthase.     

Inhibitory Mg-ADP—Fluoroaluminate Complexes Bound to Catalytic Sites of F1-ATPases: Are They Ground-State or Transition-State Analogs?

Schemes are proposed for coupling sequential opening and closing the three catalytic sites of F₁ to rotation of the subunit during ATP synthesis and hydrolysis catalyzed by the F_oF₁-ATP synthase. A prominent feature of the proposed mechanisms is that the transition state during ATP synthesis is formed when a catalytic site is in the process of closing and that the transition state during ATP hydrolysis is formed when a catalytic site is in the process of opening. The unusual kinetics of formation of Mg-ADP—fluoroaluminate complexes in one or two catalytic sites of nucleotide-depleted MF₁ and wild-type and mutant ₃₃ subcomplexes of TF₁ are also reviewed. From these considerations, it is concluded that Mg-ADP—fluoroaluminate complexes formed at catalytic sites of isolated F₁-ATPases or F₁ in membrane-bound F_oF₁ are ground-state analogs.     

The phototroph-specific β-hairpin structure of the γ subunit of FoF1-ATP synthase is important for efficient ATP synthesis of cyanobacteria

The F_oF₁ synthase produces ATP from ADP and inorganic phosphate. The γ subunit of F_oF₁ ATP synthase in photosynthetic organisms, which is the rotor subunit of this enzyme, contains a characteristic β-hairpin structure. This structure is formed from an insertion sequence that has been conserved only in phototrophs. Using recombinant subcomplexes, we previously demonstrated that this region plays an essential role in the regulation of ATP hydrolysis activity, thereby functioning in controlling intracellular ATP levels in response to changes in the light environment. However, the role of this region in ATP synthesis has long remained an open question because its analysis requires the preparation of the whole F_oF₁ complex and a transmembrane proton-motive force. In this study, we successfully prepared proteoliposomes containing the entire F_oF₁ ATP synthase from a cyanobacterium, Synechocystis sp. PCC 6803, and measured ATP synthesis/hydrolysis and proton-translocating activities. The relatively simple genetic manipulation of Synechocystis enabled the biochemical investigation of the role of the β-hairpin structure of F_oF₁ ATP synthase and its activities. We further performed physiological analyses of Synechocystis mutant strains lacking the β-hairpin structure, which provided novel insights into the regulatory mechanisms of F_oF₁ ATP synthase in cyanobacteria via the phototroph-specific region of the γ subunit. Our results indicated that this structure critically contributes to ATP synthesis and suppresses ATP hydrolysis.     

Molecular Basis of ADP Inhibition of Vacuolar (V)-type ATPase/Synthase

Reduction of ATP hydrolysis activity of vacuolar-type ATPase/synthase (V₀V₁) as a result of ADP inhibition occurs as part of the normal mechanism of V₀V₁ of Thermus thermophilus but not V₀V₁ of Enterococcus hirae or eukaryotes. To investigate the molecular basis for this difference, domain-swapped chimeric V₁ consisting of both T. thermophilus and E. hirae enzymes were generated, and their function was analyzed. The data showed that the interaction between the nucleotide binding and C-terminal domains of the catalytic A subunit from E. hirae V₁ is central to increasing binding affinity of the chimeric V₁ for phosphate, resulting in reduction of the ADP inhibition. These findings together with a comparison of the crystal structures of T. thermophilus V₁ with E. hirae V₁ strongly suggest that the A subunit adopts a conformation in T. thermophilus V₁ different from that in E. hirae V₁. This key difference results in ADP inhibition of T. thermophilus V₁ by abolishing the binding affinity for phosphate during ATP hydrolysis.     

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.     

Modulation of nucleotide binding to the catalytic sites of thermophilic F1-ATPase by the ε subunit: Implication for the role of the ε subunit in ATP synthesis

Effect of ε subunit on the nucleotide binding to the catalytic sites of F₁-ATPase from the thermophilic Bacillus PS3 (TF₁) has been tested by using α₃β₃γ and α₃β₃γε complexes of TF₁ containing βTyr341 to Trp substitution. The nucleotide binding was assessed with fluorescence quenching of the introduced Trp. The presence of the ε subunit weakened ADP binding to each catalytic site, especially to the highest affinity site. This effect was also observed when GDP or IDP was used. The ratio of the affinity of the lowest to the highest nucleotide binding sites had changed two orders of magnitude by the ε subunit. The differences may relate to the energy required for the binding change in the ATP synthesis reaction and contribute to the efficient ATP synthesis.     

Role of alphaPhe-291 residue in the phosphate-binding subdomain of catalytic sites of Escherichia coli ATP synthase

The role of αPhe-291 residue in phosphate binding by Escherichia coli F₁F₀-ATP synthase was examined. X-ray structures of bovine mitochondrial enzyme suggest that this residue resides in close proximity to the conserved βR246 residue. Herein, we show that mutations αF291D and αF291E in E. coli reduce the ATPase activity of F₁F₀ membranes by 350-fold. Yet, significant oxidative phosphorylation activity is retained. In contrast to wild-type, ATPase activities of mutants were not inhibited by MgADP-azide, MgADP-fluoroaluminate, or MgADP-fluoroscandium. Whereas, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD-Cl) inhibited wild-type ATPase essentially completely, ATPase in mutants was inhibited maximally by ∼75%, although reaction still occurred at residue βTyr-297, proximal to αPhe-291 in the phosphate-binding pocket. Inhibition characteristics supported the conclusion that NBD-Cl reacts in βE (empty) catalytic sites, as shown previously by X-ray structure analysis. Phosphate protected against NBD-Cl inhibition in wild-type but not in mutants. In addition, our data suggest that the interaction of αPhe-291 with phosphate during ATP hydrolysis or synthesis may be distinct.     

Met23Lys mutation in subunit gamma of FOF1-ATP synthase from Rhodobacter capsulatus impairs the activation of ATP hydrolysis by protonmotive force

H⁺-F_OF₁-ATP synthase couples proton flow through its membrane portion, F_O, to the synthesis of ATP in its headpiece, F₁. Upon reversal of the reaction the enzyme functions as a proton pumping ATPase. Even in the simplest bacterial enzyme the ATPase activity is regulated by several mechanisms, involving inhibition by MgADP, conformational transitions of the ε subunit, and activation by protonmotive force. Here we report that the Met23Lys mutation in the γ subunit of the Rhodobacter capsulatus ATP synthase significantly impaired the activation of ATP hydrolysis by protonmotive force. The impairment in the mutant was due to faster enzyme deactivation that was particularly evident at low ATP/ADP ratio. We suggest that the electrostatic interaction of the introduced γLys23 with the DELSEED region of subunit β stabilized the ADP-inhibited state of the enzyme by hindering the rotation of subunit γ rotation which is necessary for the activation.     

Vanadyl as a Probe of the Function of the F1-ATPase-Mg2+ Cofactor

The Mg²⁺ dependent asymmetry of the F₁-ATPase catalytic sites leads to the differences in affinity for nucleotides and is an essential component of the binding-change mechanism. Changes in metal ligands during the catalytic cycle responsible for this asymmetry were characterized by vanadyl (V ^IV + O)²⁺, a functional surrogate for Mg²⁺. The ⁵¹V-hyperfine parameters derived from EPR spectra of VO²⁺ bound to specific sites on F₁ provide a direct probe of the metal ligands. Site-directed mutations of metal ligand residues cause measurable changes in the ⁵¹V-hyperfine parameters of the bound VO²⁺, thereby providing a means to identification. Initial binding of the metal–nucleotide to the low-affinity catalytic site conformation results in metal coordination by hydroxyl groups from the P-loop threonine and catch-loop threonine. Upon conversion to the high-affinity conformation, carboxyl groups from the Walker homology B aspartate and MF₁E197 become ligands in lieu of the hydroxyl groups.     

Relationships of inosine triphosphate and bicarbonate effects on F1 ATPase to the binding change mechanism

Two interesting previously reported properties of mitochondrial F₁ ATPase have been confirmed and have been examined by¹⁸O exchange measurements to assess if they are consistent with sequential participation of catalytic sites during ATP hydrolysis. These are the ability of HCO ₃ ^– to increase reaction rate with apparent loss of cooperative interaction between subunits and the ability of ITP to accelerate the hydrolysis of a low concentration of ATP. The effect of HCO ₃ ^– was tested at concentrations of ATP lower than previous measurements. The activation disappeared when ATP was reduced to 0.1 µM. The HCO ₃ ^– activation at higher ATP concentrations did not change the extent of reversal of the cleavage of tightly bound ATP at the catalytic site, as measured by the average number of water oxygens incorporated with each P_i formed when 5 or 10 µM ATP is hydrolyzed. The data are consistent with sequential site participation with HCO ₃ ^– acceleration of ADP departure after a binding change that stops¹⁸O exchange and loosens ADP binding.When ITP concentration was lowered during net ITP hydrolysis by F₁ ATPase an increase in water oxygen incorporation into P_i formed is observed, as noted previously for ATP hydrolysis. The acceleration of the cleavage of a constant low concentration of [-¹⁸O]ATP by concomitant hydrolysis of increasing concentrations of ITP was accompanied by a decrease in water oxygen incorporation with each P_i formed from the ATP. These results add to evidence for the binding change mechanism for F₁ ATPase with sequential participation of catalytic sites.     

Sequential assembly of photosynthetic units in Rhodobacter sphaeroides as revealed by fast repetition rate analysis of variable bacteriochlorophyll a fluorescence

The development of functional photosynthetic units in Rhodobacter sphaeroides was followed by near infra-red fast repetition rate (IRFRR) fluorescence measurements that were correlated to absorption spectroscopy, electron microscopy and pigment analyses. To induce the formation of intracytoplasmic membranes (ICM) (greening), cells grown aerobically both in batch culture and in a carbon-limited chemostat were transferred to semiaerobic conditions. In both aerobic cultures, a low level of photosynthetic complexes was observed, which were composed of the reaction center and the LH1 core antenna. Interestingly, in the batch cultures the reaction centers were essentially inactive in forward electron transfer and exhibited low photochemical yields F_V/F_M, whereas the chemostat culture displayed functional reaction centers with a rather rapid (1-2 ms) electron transfer turnover, as well as a high F_V/F_M of ∼0.8. In both cases, the transfer to semiaerobiosis resulted in rapid induction of bacteriochlorophyll a synthesis that was reflected by both an increase in the number of LH1-reaction center and peripheral LH2 antenna complexes. These studies establish that photosynthetic units are assembled in a sequential manner, where the appearance of the LH1-reaction center cores is followed by the activation of functional electron transfer, and finally by the accumulation of the LH2 complexes.     

The molecular mechanism of ATP synthesis by F1F0-ATP synthase

ATP synthesis by oxidative phosphorylation and photophosphorylation, catalyzed by F₁F₀-ATP synthase, is the fundamental means of cell energy production. Earlier mutagenesis studies had gone some way to describing the mechanism. More recently, several X-ray structures at atomic resolution have pictured the catalytic sites, and real-time video recordings of subunit rotation have left no doubt of the nature of energy coupling between the transmembrane proton gradient and the catalytic sites in this extraordinary molecular motor. Nonetheless, the molecular events that are required to accomplish the chemical synthesis of ATP remain undefined. In this review we summarize current state of knowledge and present a hypothesis for the molecular mechanism of ATP synthesis.     

Catalytic site occupancy during ATP hydrolysis by MF1-ATPase. Evidence for alternating high affinity sites during steady-state turnover

The mechanism of ATP hydrolysis by the solubilized mitochondrial ATPase (MF1) has been studied under conditions where catalytic turnover occurs at one site, uni-site catalysis (obtained when enzyme is in excess of substrate), or at two sites, bi-site catalysis (obtained when substrate is in excess of enzyme). Pulse-chase experiments support the conclusion that the sites which participate in bi-site catalysis are the same as those which participate in uni-site catalysis. Upon addition of ATP in molar excess to MF1, label that was bound under uni-site conditions dissociates at a rate equal to the rate of bi-site catalysis. Similarly, when medium ATP is removed, label that was bound under bi-site conditions dissociates at a rate equal to the rate of uni-site catalysis. Evidence that a high affinity catalytic site equivalent to the one observed under uni-site conditions participates as an intermediate in bi-site catalysis includes the demonstration of full occupancy of a catalytically competent site during steady-state turnover at nanomolar concentrations of ATP. Improved measurements of the interaction of ADP at a high affinity catalytic site have lead to the revision of several of the rate constants that define uni-site catalysis. The rate constant for unpromoted dissociation of ADP is equal to that for Pi (4 X 10(-3) s-1). The rate of binding ADP at a high affinity chaseable site (Kd = 1 nM) is equal to the rate of binding ATP (4 X 10(6) M-1 s-1). The rate of catalysis obtained when substrate binding at one site promotes product release from an adjacent site (bi-site catalysis) is up to 100,000-fold faster than unpromoted product release (uni-site catalysis).     

猪心线粒体Fo的纯化、重建及其质子转运功能

比较了猪心线粒体F_oF₁-ATPase膜部分F_o的四种纯化方法.结果表明,用NaBr从亚线粒体除去F_oF₁-ATPase的水溶性部分F₁-ATPase后,再以CHAPS增溶,并经蔗糖梯度离心,可获得高纯度的F_o.SDS-聚丙烯酰胺凝胶电泳鉴定表明,纯化的F_o含有b、OSCP（寡霉素敏感授予蛋白）、d、a、e、F₆、IF₁、A6L和c等9种亚基.用去污剂稀释法将纯化的F_o在脂质体上重建后,重建F_o表现较高的被动转运质子活性.这为在体外深入研究F_o的活性、构象与膜脂的关系,以及F_o与F₁-ATPase的组装等提供了很好的实验模型.     

Kinetic studies of ATP synthase: The case for the positional change mechanism

The mitochondrial ATP synthases shares many structural and kinetic properties with bacterial and chloroplast ATP synthases. These enzymes transduce the energy contained in the membrane's electrochemical proton gradients into the energy required for synthesis of high-energy phosphate bonds. The unusual three-fold symmetry of the hydrophilic domain, F₁, of all these synthases is striking. Each F₁ has three identical subunits and three identical subunits as well as three additional subunits present as single copies. The catalytic site for synthesis is undoubtedly contained in the subunit or an , interface, and thus each enzyme appears to contain three identical catalytic sites. This review summarizes recent isotopic and kinetic evidence in favour of the concept, originally proposed by Boyer and coworkers, that energy from the proton gradient is exerted not directly for the reaction at the catalytic site, but rather to release product from a single catalytic site. A modification of this binding change hypotheses is favored by recent data which suggest that the binding change is due to a positional change in all three subunits relative to the remaining subunits of F₁ and F₀ and that the vector of rotation is influenced by energy. The positional change, or rotation, appears to be the slow step in the process of catalysis and it is accelerated in all F₁F₀ ATPases studied by substrate binding and by the proton gradient. However, in the mammalian mitochondrial enzyme, other types of allosteric rate regulation not yet fully elucidated seem important as well.