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.     

Torque Transmission Mechanism via DELSEED Loop of F1-ATPase

F₁-ATPase (F₁) is an ATP-driven rotary motor in which the three catalytic β subunits in the stator ring sequentially induce the unidirectional rotation of the rotary γ subunit. Many lines of evidence have revealed open-to-closed conformational transitions in the β subunit that swing the C-terminal domain inward. This conformational transition causes a C-terminal protruding loop with conserved sequence DELSEED to push the γ subunit. Previous work, where all residues of DELSEED were substituted with glycine to disrupt the specific interaction with γ and introduce conformational flexibility, showed that F₁ still rotated, but that the torque was halved, indicating a remarkable impact on torque transmission. In this study, we conducted a stall-and-release experiment on F₁ with a glycine-substituted DELSEED loop to investigate the impact of the glycine substitution on torque transmission upon ATP binding and ATP hydrolysis. The mutant F₁ showed a significantly reduced angle-dependent change in ATP affinity, whereas there was no change in the equilibrium for ATP hydrolysis. These findings indicate that the DELSEED loop is predominantly responsible for torque transmission upon ATP binding but not for that upon ATP hydrolysis.     

The role of the betaDELSEED motif of F1-ATPase: propagation of the inhibitory effect of the epsilon subunit

In F(1)-ATPase, a rotary motor enzyme, the region of the conserved DELSEED motif in the beta subunit moves and contacts the rotor gamma subunit when the nucleotide fills the catalytic site, and the acidic nature of the motif was previously assumed to play a critical role in rotation. Our previous work, however, disproved the assumption (Hara, K. Y., Noji, H., Bald, D., Yasuda, R., Kinosita, K., Jr., and Yoshida, M. (2000) J. Biol. Chem. 275, 14260-14263), and the role of this motif remained unknown. Here, we found that the epsilon subunit, an intrinsic inhibitor, was unable to inhibit the ATPase activity of a mutant thermophilic F(1)-ATPase in which all of the five acidic residues in the DELSEED motif were replaced with alanines, although the epsilon subunit in the mutant F(1)-ATPase assumed the inhibitory form. In addition, the replacement of basic residues in the C-terminal region of the epsilon subunit by alanines caused a decrease of the inhibitory effect. Partial replacement of the acidic residues in the DELSEED motif of the beta subunit or of the basic residues in the C-terminal alpha-helix of the epsilon subunit induced a partial effect. We here conclude that the epsilon subunit exerts its inhibitory effect through the electrostatic interaction with the DELSEED motif of the beta subunit.     

The regulator of the F1 motor: inhibition of rotation of cyanobacterial F1-ATPase by the epsilon subunit

The chloroplast-type F(1) ATPase is the key enzyme of energy conversion in chloroplasts, and is regulated by the endogenous inhibitor epsilon, tightly bound ADP, the membrane potential and the redox state of the gamma subunit. In order to understand the molecular mechanism of epsilon inhibition, we constructed an expression system for the alpha(3)beta(3)gamma subcomplex in thermophilic cyanobacteria allowing thorough investigation of epsilon inhibition. epsilon Inhibition was found to be ATP-independent, and different to that observed for bacterial F(1)-ATPase. The role of the additional region on the gamma subunit of chloroplast-type F(1)-ATPase in epsilon inhibition was also determined. By single molecule rotation analysis, we succeeded in assigning the pausing angular position of gamma in epsilon inhibition, which was found to be identical to that observed for ATP hydrolysis, product release and ADP inhibition, but distinctly different from the waiting position for ATP binding. These results suggest that the epsilon subunit of chloroplast-type ATP synthase plays an important regulator for the rotary motor enzyme, thus preventing wasteful ATP hydrolysis.     

Human F1-ATPase: molecular cloning of cDNA for the beta subunit

F1-ATPase is the major enzyme for ATP synthesis, and its beta subunit is the catalytic site. To date, no full-length cDNA for the eukaryotic F1 gene has been reported. Human F1 was studied because of its importance in medicine and cell biology. Here we report molecular cloning of a full-length cDNA for the human F1 beta subunit and purification of the human F1 beta subunit. The HeLa cell cDNA library constructed in an expression vector gamma gt11 was screened with antiserum against the yeast F1 beta subunit. One of the positive phage DNAs containing the human F1 beta gene and its flanking regions (1.8 kilobase pairs) was sequenced by the dideoxy chain termination method. The open reading frame started from a putative signal presequence, which was rich in both serine and arginine. There was a homologous segment in the signal presequence of human ornithine transcarbamoylase and that of F1 beta. The precursor of F1 beta was expressed in E. coli harboring a plasmid which had been constructed with T5 promotor and the F1 beta cDNA. Both the precursor and mature form of F1 beta were detected in HeLa cells in a pulse-chase experiment. The amino acid sequence of 480 residues (51,568.3 daltons) following the presequence was highly homologous with that of mature beef heart F1 beta (97.5%) and E. coli F1 beta (71.7%), but the codon usage in the human gene was very different from those of reported genes coding for F1 beta of other species.     

Suppression mutations in the defective beta subunit of F1-ATPase from Escherichia coli

The Escherichia coli mutant of the proton-translocating ATPase KF11 (Kanazawa, H., Horiuchi, Y., Takagi, M., Ishino, Y., and Futai, M. (1980) J. Biochem. (Tokyo) 88, 695-703) has a defective beta subunit with serine being replaced by phenylalanine at codon 174. Four suppression mutants (RE10, RE17, RE18, and RE20) from this strain capable of growth on minimal plate agar supplemented by succinate were isolated. The original point mutation at codon 174 was intact in these strains. Additional point mutations, Ala-295 to Thr, Gly-149 to Ser, Leu-400 to Gln, Ala-295 to Pro, for RE10, RE17, RE18, and RE20, respectively, were identified by the polymerase chain reaction and sequencing. These mutations, except for RE10, were confirmed as a single mutation conferring a suppressive phenotype by genetic suppression assay using KF11 as the host cells. The results indicated that Ser-174 has functional interaction with Gly-149, Ala-295, and Leu-400. The residues are located within the previously estimated catalytic domain of the beta subunit, indicating that this domain is indeed folded for the active site of catalytic function. Growth rates of the revertants in the minimal medium with succinate increased compared with that of KF11, showing that ATP synthesis recovered to some extent. The ATP hydrolytic activity in the revertant membranes increased in RE17 and RE20 but did not in RE10 and RE18, suggesting that synthesis and hydrolysis are not necessarily reversible in the proton-translocating ATPase (F1F0).     

Reconstituted F1-ATPase complexes containing one impaired beta subunit are ATPase-active

Homogeneous populations of hybrid alpha 3 beta 3 gamma complexes of the thermostable F1-ATPase containing one, two, or three copies of the mutationally impaired beta subunits were produced using the solid phase reconstitution method. Two kinds of mutated beta subunits were used for the reconstitution, one of which lacked the ability to bind any adenine nucleotides. The complexes containing one impaired beta and two wild-type beta subunits retained a significant amount of ATPase activity with cooperative kinetics, whereas those containing two or three impaired beta subunits showed very little ATPase activity. These results imply that the catalysis of steady-state ATP hydrolysis can proceed even if one of the three beta subunits in F1-ATPase is not functional.     

Molecular dissection of the beta subunit of F1-ATPase into peptide fragments.

Partial digestion of the native beta subunit of F1-ATPase from the thermophilic Bacillus strain PS3 by three different proteases produced a limited number of peptide fragments. In most cases, the peptides remained associated, and the gross structure of the beta subunit was not destroyed. Furthermore, most peptides were able to reassociate into the form of the beta subunit after denaturating urea treatment. Therefore, the cleaved sites are most likely located in water-exposed loop regions in the tertiary structure of the protein. Almost all peptides were analyzed, and 17 cleaved sites were determined. From the analysis of the distribution of cleaved sites and deletions or insertions in the multiple amino acid sequence alignment of proteins homologous to the beta subunit, locations of five loops and four candidate loops in the beta subunit are suggested. There are two large loops in the central region of the beta subunit sequence, and dicyclohexylcarbodiimide-reactive Glu190 is located in one of them. Tyr341, involved in putative catalytic ATP binding, is also found in one of the loops. Then, taking cleaved sites as a reference, two kinds of expression plasmids, each of which carried genes of two complementary peptide fragments, 1-193 and 198-473 or 1-284 and 285-473, were constructed and expressed in Escherichia coli. For each plasmid, two peptides were coexpressed, associated into a stable beta subunit form in E. coli cells, and purified without dissociation. When these beta subunits were denatured by urea and applied to polyacrylamide gel without denaturant, a protein band with the same mobility as that of the beta subunit appeared, indicating that reassociation of peptide fragments into the form of the beta subunit occurred upon removal of urea. These beta subunits retained the ability to reconstitute the alpha 3 beta 3 gamma complexes even though the efficiency of reconstitution and the recovered ATPase activities were decreased. These complexes were stable at high or low temperature, and ATPase activities were sensitive to inhibition by N3-.     

The yeast F1-ATPase beta subunit precursor contains functionally redundant mitochondrial protein import information.

The NH2 terminus of the yeast F1-ATPase beta subunit precursor directs the import of this protein into mitochondria. To define the functionally important components of this import signal, oligonucleotide-directed mutagenesis was used to introduce a series of deletion and missense mutations into the gene encoding the F1-beta subunit precursor. Among these mutations were three nonoverlapping deletions, two within the 19-amino-acid presequence (delta 5-12 and delta 16-19) and one within the mature protein (delta 28-34). Characterization of the mitochondrial import properties of various mutant F1-beta subunit proteins containing different combinations of these deletions showed that import was blocked only when all three deletions were combined. Mutant proteins containing all possible single and pairwise combinations of these deletions were found to retain the ability to direct mitochondrial import of the F1-beta subunit. These data suggest that the F1-beta subunit contains redundant import information at its NH2 terminus. In fact, we found that deletion of the entire F1-beta subunit presequence did not prevent import, indicating that a functional mitochondrial import signal is present near the NH2 terminus of the mature protein. Furthermore, by analyzing mitochondrial import of the various mutant proteins in [rho-] yeast, we obtained evidence that different segments of the F1-beta subunit import signal may act in an additive or cooperative manner to optimize the import properties of this protein.     

The epsilon subunit and inhibitory monoclonal antibodies interact with the carboxyl-terminal region of the beta subunit of Escherichia coli F1-ATPase

The epitopes of two classes of monoclonal antibody and the binding site for the epsilon subunit have been mapped to the carboxyl-terminal region of the beta subunit of Escherichia coli F1-ATPase using partial CNBr cleavage, weak acid hydrolysis, and Western blots. One class of antibody, B-I, inhibits ATPase activity; the other class, B-II, recognizes an epitope not exposed on the surface of intact F1. Data from two-dimensional gels and blots of beta cleaved with CNBr/weak acid showed that the B-I epitope lies between Asp-381 and the carboxyl-terminal Leu-459, and the B-II epitope lies between Asp-345 and Met-380. Weak acid hydrolysis of the beta-epsilon product obtained by cross-linking F1 with a water-soluble carbodiimide yielded a fragment containing epsilon and a 13-kDa carboxyl-terminal fragment of beta indicating that epsilon interacts with this portion of beta as well. Fab fragments from the B-I antibody beta-6 could be cross-linked to the epsilon subunit in native F1 by various cross-linking agents demonstrating that the antibody and the epsilon subunit occupy adjacent, nonoverlapping sites on the beta subunit. Implications of these results for the roles of the epsilon subunit and of the carboxyl-terminal region of the beta subunit in F1 are discussed.     

The F subunit of Thermus thermophilus V1-ATPase promotes ATPase activity but is not necessary for rotation

V(1)-ATPase from the thermophilic bacterium Thermus thermophilus is a molecular rotary motor with a subunit composition of A(3)B(3)DF, and its central rotor is composed of the D and F subunits. To determine the role of the F subunit, we generated an A(3)B(3)D subcomplex and compared it with A(3)B(3)DF. The ATP hydrolyzing activity of A(3)B(3)D (V(max) = 20 s(-1)) was lower than that of A(3)B(3)DF (V(max) = 31 s(-1)) and was more susceptible to MgADP inhibition during ATP hydrolysis. A(3)B(3)D was able to bind the F subunit to form A(3)B(3)DF. The C-terminally truncated F((Delta85-106)) subunit was also bound to A(3)B(3)D, but the F((Delta69-106)) subunit was not, indicating the importance of residues 69-84 of the F subunit for association with A(3)B(3)D. The ATPase activity of A(3)B(3)DF((Delta85-106)) (V(max) = 24 s(-1)) was intermediate between that of A(3)B(3)D and A(3)B(3)DF. A single molecule experiment showed the rotation of the D subunit in A(3)B(3)D, implying that the F subunit is a dispensable component for rotation itself. Thus, the F subunit binds peripherally to the D subunit, but promotes V(1)-ATPase catalysis.     

F1-ATPase, the C-terminal end of subunit gamma is not required for ATP hydrolysis-driven rotation

ATP hydrolysis by the isolated F(1)-ATPase drives the rotation of the central shaft, subunit gamma, which is located within a hexagon formed by subunits (alphabeta)(3). The C-terminal end of gamma forms an alpha-helix which properly fits into the "hydrophobic bearing" provided by loops of subunits alpha and beta. This "bearing" is expected to be essential for the rotary function. We checked the importance of this contact region by successive C-terminal deletions of 3, 6, 9, 12, 15, and 18 amino acid residues (Escherichia coli F(1)-ATPase). The ATP hydrolysis activity of a load-free ensemble of F(1) with 12 residues deleted decreased to 24% of the control. EF(1) with deletions of 15 or 18 residues was inactive, probably because it failed to assemble. The average torque generated by a single molecule of EF(1) when loaded by a fluorescent actin filament was, however, unaffected by deletions of up to 12 residues, as was their rotational behavior (all samples rotated during 60 +/- 19% of the observation time). Activation energy analysis with the ensemble revealed a moderate decrease from 54 kJ/mol for EF(1) (full-length gamma) to 34 kJ/mol for EF(1)(gamma-12). These observations imply that the intactness of the C terminus of subunit gamma provides structural stability and/or routing during assembly of the enzyme, but that it is not required for the rotary action under load, proper.     

The structural basis for unidirectional rotation of thermoalkaliphilic F1-ATPase

The ATP synthase of the thermoalkaliphilic Bacillus sp. TA2.A1 operates exclusively in ATP synthesis direction. In the crystal structure of the nucleotide-free alpha(3)beta(3)gamma epsilon subcomplex (TA2F(1)) at 3.1 A resolution, all three beta subunits adopt the open beta(E) conformation. The structure shows salt bridges between the helix-turn-helix motif of the C-terminal domain of the beta(E) subunit (residues Asp372 and Asp375) and the N-terminal helix of the gamma subunit (residues Arg9 and Arg10). These electrostatic forces pull the gamma shaft out of the rotational center and impede rotation through steric interference with the beta(E) subunit. Replacement of Arg9 and Arg10 with glutamines eliminates the salt bridges and results in an activation of ATP hydrolysis activity, suggesting that these salt bridges prevent the native enzyme from rotating in ATP hydrolysis direction. A similar bending of the gamma shaft as in the TA2F(1) structure was observed by single-particle analysis of the TA2F(1)F(o) holoenzyme.     

Inter-subunit rotation and elastic power transmission in F0F1-ATPase

ATP synthase (F-ATPase) produces ATP at the expense of ion-motive force or vice versa. It is composed from two motor/generators, the ATPase (F1) and the ion translocator (F0), which both are rotary steppers. They are mechanically coupled by 360 degrees rotary motion of subunits against each other. The rotor, subunits gamma(epsilon)C10-14, moves against the stator, (alphabeta)3delta(ab2). The enzyme copes with symmetry mismatch (C3 versus C10-14) between its two motors, and it operates robustly in chimeric constructs or with drastically modified subunits. We scrutinized whether an elastic power transmission accounts for these properties. We used the curvature of fluorescent actin filaments, attached to the rotating c ring, as a spring balance (flexural rigidity of 8.10(-26) N x m2) to gauge the angular profile of the output torque at F0 during ATP hydrolysis by F1. The large average output torque (56 pN nm) proved the absence of any slip. Angular variations of the torque were small, so that the output free energy of the loaded enzyme decayed almost linearly over the angular reaction coordinate. Considering the three-fold stepping and high activation barrier (>40 kJ/mol) of the driving motor (F1) itself, the rather constant output torque seen by F0 implied a soft elastic power transmission between F1 and F0. It is considered as essential, not only for the robust operation of this ubiquitous enzyme under symmetry mismatch, but also for a high turnover rate under load of the two counteracting and stepping motors/generators.     

The binding of aurovertin to isolated beta subunit of F1 (mitochondrial ATPase). Stoicheiometry of beta subunit in F1.

1. Beef-heart mitochondrial ATPase (F1) is inactivated and dissociated by incubation with 0.85 M LiCl. ATP partly protects against inactivation. Three dissociation products could be identified after chromatography on diethylaminoethylcellulose: the delta subunit which is not adsorbed, the beta subunit which may be eluted from the column, and the alpha and gamma subunits which remain bound to the column. 2. Aurovertin binds to dissociated F1 with a fluorescence enhancement equal to about 30% that found with F1. Unlike intact F1 which shows two kinetically separated phases of fluorescence enhancement, only a fast phase is found with dissociated enzyme. 3. Fluorescence measurements at varying aurovertin and protein concentrations indicate that aurovertin binds to dissociated F1 in a simple 3-component reaction with dissociation constant 0.4 muM. There are two indistinguishable binding sites, calculated on the basis of the initial F1 concentration before dissociation. 4. The beta subunit was isolated from dissociated F1 by DEAE-cellulose chromatography. It has no ATPase activity but reacts with aurovertin with a fluorescence enhancement similar to that of dissociated F1. 5. The isolated beta subunit contains one aurovertin binding site with a dissociation constant of 0.56 muM. 6. It is concluded that F1 contains two beta subunits.     

Proton-powered subunit rotation in single membrane-bound F0F1-ATP synthase

Synthesis of ATP from ADP and phosphate, catalyzed by F(0)F(1)-ATP synthases, is the most abundant physiological reaction in almost any cell. F(0)F(1)-ATP synthases are membrane-bound enzymes that use the energy derived from an electrochemical proton gradient for ATP formation. We incorporated double-labeled F(0)F(1)-ATP synthases from Escherichia coli into liposomes and measured single-molecule fluorescence resonance energy transfer (FRET) during ATP synthesis and hydrolysis. The gamma subunit rotates stepwise during proton transport-powered ATP synthesis, showing three distinct distances to the b subunits in repeating sequences. The average durations of these steps correspond to catalytic turnover times upon ATP synthesis as well as ATP hydrolysis. The direction of rotation during ATP synthesis is opposite to that of ATP hydrolysis.     

The nucleotide-independent Fe(III)-binding site is located on beta subunit of the mitochondrial F(1)-ATPase

The need for methods to identify disease biomarkers is underscored by the survival-rate of patients diagnosed at early stages of cancer progression. Surface enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF MS) is a novel approach to biomarker discovery that combines two powerful techniques: chromatography and mass spectrometry. One of the key features of SELDI-TOF MS is its ability to provide a rapid protein expression profile from a variety of biological and clinical samples. It has been used for biomarker identification as well as the study of protein-protein, and protein-DNA interaction. The versatility of SELDI-TOF MS has allowed its use in projects ranging from the identification of potential diagnostic markers for prostate, bladder, breast, and ovarian cancers and Alzheimer's disease, to the study of biomolecular interactions and the characterization of posttranslational modifications. In this minireview we discuss the application of SELDI-TOF MS to protein biomarker discovery and profiling.     

Interaction between aurovertin and adenine nucleotide binding sites on mitochondrial F1-ATPase and the isolated beta subunit

The effect of aurovertin on the binding parameters of ADP and ATP to native F1 from beef heart mitochondria in the presence of EDTA has been explored. Three exchangeable sites per F1 were titrated by ADP and ATP in the absence or presence of aurovertin. Curvilinear Scatchard plots for the binding of both ADP and ATP were obtained in the absence of aurovertin, indicating one high affinity site (Kd for ADP = 0.6-0.8 microM; Kd for ATP = 0.3-0.5 microM) and two lower affinity sites (Kd for ADP = 8-10 microM; Kd for ATP = 7-10 microM). With a saturating concentration of aurovertin capable of filling the three beta subunits of F1, the curvilinearity of the Scatchard plots was decreased for ATP binding and abolished for ADP binding, indicating homogeneity of ADP binding sites in the F1-aurovertin complex (Kd for ADP = 2 microM). When only the high affinity aurovertin site was occupied, maximal enhancement of the fluorescence of the F1-aurovertin complex was attained with 1 mol of ADP bound per mol of F1 and maximal quenching for 1 mol of ATP bound per mol of F1. When the F1-aurovertin complex was incubated with [3H]ADP followed by [14C]ATP, full fluorescence quenching was attained when ATP had displaced the previously bound ADP. In the case of the isolated beta subunit, both ADP and ATP enhanced the fluorescence of the beta subunit-aurovertin complex. The Kd values for ADP and ATP in the presence of EDTA were 0.6 mM and 3.7 mM, respectively; MgCl2 decreased the Kd values to 0.1 mM for both ADP and ATP. It is postulated that native F1 possesses three equivalent interacting nucleotide binding sites and exists in two conformations which are in equilibrium and recognize either ATP (T conformation) or ADP (D conformation). The negative interactions between the nucleotide binding sites of F1 are strongest in the D conformation. Upon addition of aurovertin, the site-site cooperativity between the beta subunits of F1 is decreased or even abolished.