Evidence from immunological studies of structure-mechanism relationship of F1 and F1F0

Monoclonal and polyclonal antibodies directed against peptides of F₁-ATPase or F₁F₀-ATPase synthase provide new and efficient tools to study structure-function relationships and mechanisms of such complex membrane enzymes. This review summarizes the main results obtained using this approach. Antibodies have permitted the determination of the nature of subunits involved in the complex, their stoichiometry, their organization, neighboring interactions, and vectorial distribution within or on either face of the membrane. Moreover, in a few cases, amino acid sequences exposed on a face of the membrane or buried inside the complex have been identified. Antibodies are very useful for detecting the role of each subunit, especially for those subunits which appear to have no direct involvement in the catalytic mechanism. Concerning the mechanisms, the availability of monoclonal antibodies which inhibit (or activate) ATP hydrolysis or ATP synthesis, which modify nucleotide binding or regulation of activities, which detect specific conformations, etc. brings many new ways of understanding the precise functions. The specific recognition by monoclonal antibodies on the subunit of epitopes in the proximity of, or in the catalytic site, gives information on this site. The use of anti- monoclonal antibodies has shown asymmetry of in the complex as already shown for . In addition, the involvement of with respect to nucleotide site cooperativity has been detected. Finally, the formation of F₁F₀-antibody complexes of various masses, seems to exclude the functional rotation of F₁ around F₀ during catalysis.Abbreviations IF₁ natural protein inhibitor of the ATPase-ATP synthase - OSCP oligomycin sensitivity-conferring protein - DCCD dicyclohexylcarbodiimide - SDS-PAGE sodium dodecylsulfate polyacrylamide gel electrophoreses - F₁ F₁-ATPase, coupling factor F₁ of ATPase - F₁F₀ F₁F₀-ATP synthase, ATPase-ATP synthase complex     

The Structural and Functional Connection between the Catalytic and Proton Translocating Sectors of the Mitochondrial F 1 F 0 -ATP Synthase

The structural and functional connection between the peripheral catalytic F₁ sector and theproton-translocating membrane sector F₀ of the mitochondrial ATP synthase is reviewed. Theobservations examined show that the N-terminus of subunit , the carboxy-terminal and centralregion of F₀I-PVP(b), OSCP, and part of subunit d constitute a continuous structure, the lateralstalk, which connects the peripheries of F₁ to F₀ and surrounds the central element of thestalk, constituted by subunits and . The ATPase inhibitor protein (IF₁) binds at one sideof the F₁F₀ connection. The carboxy-terminal segment of IF₁ apparently binds to OSCP. The42L-58K segment of IF₁, which is per se the most active domain of the protein, binds at thesurface of one of the three / pairs of F₁, thus preventing the cyclic interconversion of thecatalytic sites required for ATP hydrolysis.     

Hypothyroidism Leads to a Decreased Expression of Mitochondrial F0F1-ATP Synthase in Rat Liver

In liver mitochondria isolated from hypothyroid rats, the rate of ATP synthesis is lower than in mitochondria from normal rats. Oligomycin-sensitive ATP hydrolase activity and passive proton permeability were significantly lower in submitochondrial particles from hypothyroid rats compared to those isolated from normal rats. In mitochondria from hypothyroid rats, the changes in catalytic activities of F₀F₁-ATP synthase are accompanied by a decrease in the amount of immunodetected -F₁, F₀1-PVP, and OSCP subunits of the complex. Northern blot hybridization shows a decrease in the relative cytosolic content of mRNA for -F₁ subunit in liver of hypothyroid rats. Administration of 3,5,3-triodo-L-thyronine to the hypothyroid rats tends to remedy the functional and structural defects of F₀F₁-ATP synthase observed in the hypothyroid rats. The results obtained indicate that hypothyroidism leads to a decreased expression of F₀F₁-ATP synthase complex in liver mitochondria and this contributes to the decrease of the efficiency of oxidative phosphorylation.     

Evolutionary relationship between Enterobacteriaceae: comparison of the ATP synthases (F1F0) of Escherichia coli and Klebsiella pneumoniae

The ATP synthase complex of Klebsiella pneumoniae (KF₁F₀) has been purified and characterized. SDS-gel electrophoresis of the purified F₁F₀ complexes revealed an identical subunit pattern for E. coli (EF₁F₀) and K. pneumoniae. Antibodies raised against EF₁ complex and purified EF₀ subunits recognized the corresponding polypeptides of EF₁F₀ and KF₁F₀ in immunoblot analysis. Protease digestion of the individual subunits generated an identical cleavage pattern for subunits , , , , a, and c of both enzymes. Only for subunit different cleavage products were obtained. The isolated subunit c of both organisms showed only a slight deviation in the amino acid composition. These data suggest that extensive homologies exist in primary and secondary structure of both ATP synthase complexes reflecting a close phylogenetic relationship between the two enterobacteric tribes.Abbreviations ACMA 9-amino-6-chloro-2-methoxyacridine - DCCD N,N-dicyclohexylcarbodiimide - FITC fluorescein isothiocyanate - SDS sodium dodecyl sulfate - TTFB 4,5,6,7-tetrachloro-2-trifluoromethylbenzimidazole     

Subunit Organization of the Stator Part of the F 0 Complex from Escherichia coli ATP Synthase

Membrane-bound ATP synthases (F₁F₀) catalyze the synthesis of ATP via a rotary catalyticmechanism utilizing the energy of an electrochemical ion gradient. The transmembrane potentialis supposed to propel rotation of a subunit c ring of F₀ together with subunits and of F₁,hereby forming the rotor part of the enzyme, whereas the remainder of the F₁F₀ complexfunctions as a stator for compensation of the torque generated during rotation. This reviewfocuses on our recent work on the stator part of the F₀ complex, e.g., subunits a and b. Usingepitope insertion and antibody binding, subunit a was shown to comprise six transmembranehelixes with both the N- and C-terminus oriented toward the cytoplasm. By use of circulardichroism (CD) spectroscopy, the secondary structure of subunit b incorporated intoproteoliposomes was determined to be 80% -helical together with 14% turn conformation, providingflexibility to the second stalk. Reconstituted subunit b together with isolated ac subcomplexwas shown to be active in proton translocation and functional F₁ binding revealing the nativeconformation of the polypeptide chain. Chemical crosslinking in everted membrane vesiclesled to the formation of subunit b homodimers around residues bQ37 to bL65, whereas bA32Ccould be crosslinked to subunit a, indicating a close proximity of subunits a and b near themembrane. Further evidence for the proposed direct interaction between subunits a and b wasobtained by purification of a stable ab ₂ subcomplex via affinity chromatography using Histags fused to subunit a or b. This ab ₂ subcomplex was shown to be active in proton translocationand F₁ binding, when coreconstituted with subunit c. Consequences of crosslink formationand subunit interaction within the F₁F₀ complex are discussed.     

Identification of subunits required for the catalytic activity of the F1-ATPase

F₁() complexes containing equimolar ratios of the and subunits have been shown to function as active ATPases, whereas individually isolated and subunits show no real ATPase activity. These results indicate that the single-copy subunits are not required for F₁-ATPase activity. The minimal F₁()-core complexes exhibit, however, lower rates and some different properties from those of their parent whole F₁ or ₃₃ complexes. It is therefore concluded that for obtaining a full spectrum of the characteristic functional properties of an F₁-ATPase the presence of the F₁- subunit is also required. The implications of these findings on the subunit location of both catalytic and noncatalytic nucleotide binding sites is discussed.     

Mutagenic Analysis of the F 0 Stator Subunits

The a and b subunits constitute the stator elements in the F₀ sector of F₁F₀-ATP synthase.Both subunits have been difficult to study by physical means, so most of the information onstructure and function relationships in the a and b subunits has been obtained using mutagenesisin combination with biochemical methods. These approaches were used to demonstrate thatthe a subunit in association with the ring of c subunits houses the proton channel throughF₁F₀-ATP synthase. The map of the amino acids contributing to the proton channel is probablycomplete. The two b subunits dimerize, forming an extended flexible unit in the peripheralstalk linking the F₁ and F₀ sectors. The unique characteristics of specific amino acid substitutionsaffecting the a and b subunits suggested differential effects on rotation during F₁F₀-ATPaseactivity.     

The oligomycin sensitivity conferring protein (OSCP) of beef heart mitochondria: Studies of its binding to F1 and its function

The binding of oligomycin sensitivity conferring protein (OSCP) to soluble beef-heart mitochondrial ATPase (F₁) has been investigated. OSCP forms a stable complex with F₁, and the F₁ · OSCP complex is capable of restoring oligomycin- and DCCD-sensitive ATPase activity to F₁- and OSCP-depleted submitochondrial particles. The F₁ · OSCP complex retains 50% of its ATPase activity upon cold exposure while free F₁ is inactivated by 90% or more. Both free F₁ and the F₁ · OSCP complex release upon cold exposure a part—probably 1 out of 3—of their subunits; whether subunits are also lost is uncertain. The cold-treated F₁ · OSCP complex is still capable of restoring oligomycin- and DCCD-sensitive ATPase activity to F₁- and OSCP-depleted particles. OSCP also protects F₁ against modification of its subunit by mild trypsin treatment. This finding together with the earlier demonstration that trypsin-modified F₁ cannot bind OSCP indicates that OSCP binds to the subunit of F₁ and that F₁ contains three binding sites for OSCP. The results are discussed in relation to the possible role of OSCP in the interaction of F₁ with the membrane sector of the mitochondrial ATPase system.Abbreviations DCCD N,N-dicyclohexylcarbodiimide - OSCP oligomycin sensitivity conferring protein - SDS sodium dodecylsulfate This paper is dedicated to the memory of David E. Green—scholar, pioneer, visionary.     

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.     

Structure of theEscherichia coli ATP synthase and role of the γ and ε subunits in coupling catalytic site and proton channeling functions

The structure of theEscherichia coli ATP synthase has been studied by electron microscopy and a model developed in which the and subunits of the F₁ part are arranged hexagonally (in top view) alternating with one another and surrounding a central cavity of around 35 Å at its widest point. The and subunits are interdigitated in side view for around 60 Å of the 90 Å length of the molecule. The F₁ narrows and has three-fold symmetry at the end furthest from the F₀ part. The F₁ is linked to F₀ by a stalk approximately 45 Å long and 25–30 Å in diameter. The F₀ part is mostly buried in the lipid bilayer. The subunit provides a domain that extends into the central cavity of the F₁ part. The and subunits are in a different conformation when ATP+Mg²⁺ are present in catalytic sites than when ATP+EDTA are present. This is consistent with these two small subunits switching conformations as a function of whether or not phosphate is bound to the enzyme at the position of the phosphate of ATP. We suggest that this switching is the key to the coupling of catalytic site events with proton translocation in the F₀ part of the complex.     

Coupling Proton Movement to ATP Synthesis in the Chloroplast ATP Synthase

The chloroplast F₀F₁-ATP synthase-ATPase is a tiny rotary motor responsible for coupling ATP synthesis and hydrolysis to the light-driven electrochemical proton gradient. Reversible oxidation/reduction of a dithiol, located within a special regulatory domain of the γ subunit of the chloroplast F₁ enzyme, switches the enzyme between an inactive and an active state. This regulatory mechanism is unique to the ATP synthases of higher plants and its physiological significance lies in preventing nonproductive depletion of essential ATP pools in the dark. The three-dimensional structure of the chloroplast F₁ gamma subunit has not yet been solved. To examine the mechanism of dithiol regulation, a model of the chloroplast gamma subunit was obtained through segmental homology modeling based on the known structures of the mitochondrial and bacterial γ subunits, together with de novo construction of the unknown regulatory domain. The model has provided considerable insight into how the dithiol might modulate catalytic function. This has, in turn, suggested a mechanism by which rotation of subunits in F₀, the transmembrane proton channel portion of the enzyme, can be coupled, via the ε subunit, to rotation of the γ subunit of F₁ to achieve the 120° (or 90°+30°) stepping action that is characteristic of F₁ γ subunit rotation.     

Chemical modification of active sites in relation to the catalytic mechanism of F1

Recent studies of chemically modified F₁-ATPases have provided new information that requires a revision of our thinking on their catalytic mechanism. One of the subunits in F₁-ATPase is distinguishable from the other two both structurally and functionally. The catalytic site and regulatory site of the same subunit are probably sufficiently close to each other, and the interaction between the various catalytic and regulatory sites are probably sufficiently strong to raise the uni-site rate of ATP hydrolysis by several orders of magnitude to that of promoted (multi-site) ATP hydrolysis. Although all three subunits in F₁ possess weak uni-site ATPase activity, only one of them () catalyzes promoted ATP hydrolysis. But all three subunits catalyze ATP synthesis driven by the proton flux. Internal rotation of the ₃₃ or ₃ moiety relative to the remainder of the F₀F₁ complex did not occur during oxidative phosphorylation by reconstituted submitochondrial particles.     

Relevance of Divalent Cations to ATP-Driven Proton Pumping in Beef Heart Mitochondrial F0F1-ATPase

The ATP hydrolysis rate and the ATP hydrolysis-linked proton translocation by the F₀F₁-ATPase of beef heart submitochondrial particles were examined in the presence of several divalent metal cations. All Me–ATP complexes tested sustained ATP hydrolysis, although to a different extent. However, only Mg- and Mn-ATP-dependent hydrolysis could sustain a high level of proton pumping activity, as determined by acridine fluorescence quenching. Moreover, the K _m of the Me-ATP hydrolysis-induced proton pumping activity was very similar to the K _m value of Me-ATP hydrolysis. Both oligomycin and DCCD caused the full recovery of the fluorescence, providing clear evidence for the association of Mg-ATP hydrolysis with proton translocation through the F₀F₁-ATPase complex. In contrast, with other Me-ATP complexes, including Ca-ATP as substrate, the proton pumping activity was undetectable, implicating an uncoupling nature for these substrates. Attempts to demonstrate the involvement of the subunit of the enzyme in the coupling mechanism failed, suggesting that the participation of at least the N-terminal segment of the subunit in the coupling mechanism of the mitochondrial enzyme is unlikely.     

The native F0F1-inhibitor protein complex from beef heart mitochondria and its reconstitution in liposomes

A functional F₀F₁ ATP synthase that contains the endogenous inhibitor protein (F₀F₁I) was isolated by the use of two combined techniques [Adolfsen, R., McClung, J.A., and Moudrianakis, E. N. (1975).Biochemistry 14, 1727–1735; Dreyfus, G., Celis, H., and Ramirez, J. (1984).Anal. Biochem. 142, 215–220]. The preparation is composed of 18 subunits as judged by SDS-PAGE. A steady-state kinetic analysis of the latent ATP synthase complex at various concentrations of ATP showed aV _max of 1.28mol min^–1 mg^–1, whereas theV _max of the complex without the inhibitor was 8.3mol min^–1 mg^–1. In contrast, theK _m for Mg-ATP of F₀F₁ I was 148M, comparable to theK _m value of 142M of the F₀F₁ complex devoid of IF₁. The hydrolytic activity of the F₀F₁I increased severalfold by incubation at 60C at pH 6.8, reaching a maximal ATPase activity of 9.5mol min^–1 mg^–1; at pH 9.0 a rapid increase in the specific activity of hydrolysis was followed by a sharp drop in activity. The latent ATP synthase was reconstituted into liposomes by means of a column filtration method. The proteoliposomes showed ATP-Pi exchange activity which responded to phosphate concentration and was sensitive to energy transfer inhibitors like oligomycin and the uncouplerp-trifluoromethoxyphenylhydrazone.     

Molecular switch of F0F1-ATP synthase,G-protein,and other ATP-driven enzymes

Exchange-out of amide tritium from labeled -subunit of ₃₃ complex of F₀F₁-ATP synthase was not accelerated by ATP, suggesting that hemagglutinin-type transition of coiled-coil structure did not occur in -subunit. Local topology of nucleotide binding site and switch II region of G-protein resemble those of F₁- subunit and other proteins which catalyze ATP-triggered reactions. Probably, binding of nucleotide to F₀F₁-ATP synthase induces conformational change of the switch II-like region with transforming subunit structure from open to closed form and this transformation results in loss of hydrogen bonds with the subunit, thus enabling the subunit to move.     

Mutagenesis Studies of the F1F0 ATP Synthase b Subunit Membrane Domain

A homodimer of b subunits constitutes the peripheral stalk linking the F₁ and F₀ sectors of the Escherichia coli ATP synthase. Each b subunit has a single-membrane domain. The constraints on the membrane domain have been studied by systematic mutagenesis. Replacement of a segment proximal to the cytoplasmic side of the membrane had minimal impact on F₁F₀ ATP synthase. However, multiple substitutions on the periplasmic side resulted in defects in assembly of the enzyme complex. These mutants had insufficient oxidative phosphorylation to support growth, and biochemical studies showed little F₁F₀ ATPase and no detectable ATP-driven proton pumping activity. Expression of the b _N2A,T6A,Q10A subunit was also oxidative phosphorylation deficient, but the b _N2A,T6A,Q10A protein was incorporated into an F₁F₀ complex. Single amino acid substitutions had minimal reductions in F₁F₀ ATP synthase function. The evidence suggests that the b subunit membrane domain has several sites of interaction contributing to assembly of F₀, and that these interactions are strongest on the periplasmic side of the bilayer.     

Analysis of myelin proteolipid protein and F0ATPase subunit 9 in normal andjimpy CNS

Membrane fractions and chloroform-methanol (C-M) extracts ofjimpy (jp) and normal CNS at 17–20 days were examined by immunoblot and sequence analysis to determine whether myelin proteolipid protein (PLP) or DM-20 could be detected in jp CNS. No reactivity was detected in jp samples with several PLP antibodies (Abs) except with one Ab to amino acids 109–128 of normal PLP. Proteins in the immunoreactive bands 26 Mr comigrating with PLP were sequenced for the first 10–12 residues. A sequence corresponding to PLP was found in normal CNS, as expected, but not in the band from jp CNS. Our results provide no evidence for an aberrant form of PLP in jp CNS at 17–20 days. This and other studies suggest that the abnormalities in jp brain are not due to toxicity of the mutant jp PLP/DM-20 proteins. Interestingly, a sequence identical to the amino terminus of the mature proton channel subunit 9 of mitochondrial F₀ ATPase was detected in the immunoreactive bands 26 Mr in both normal and jp samples. This identification was supported by reactivity with an Ab to the F₀ subunit and by labeling with dicyclohexylcarbodiimide (DCCD). In contrast to PLP isolated from whole CNS, PLP isolated from myelin was devoid of F₀ subunit 9 based on sequence analysis and lack of reactivity with an Ab to the F₀ subunit, yet still reacted with DCCD. This finding rules out the possibility that contaminating F₀ ATPase gives rise to the DCCD binding exhibited by PLP and confirms the possibility that PLP has proton channel activity, as suggested by Lin and Lees (1,2).Abbreviations used Ab antibody - CM conditioned medium - C M chloroform-methanol - DCCD dicyclohexylcarbodiimide - jp jimpy - Mr mobility (apparent m.w×10^–3) - PLP proteolipid protein - PVDF polyvinylidene difluoride     

ATP synthases: insights into their motor functions from sequence and structural analyses

ATP synthases are motor complexes comprised of F₀ and F₁ parts that couple the proton gradient across the membrane to the synthesis of ATP by rotary catalysis. Although a great deal of information has been accumulated regarding the structure and function of ATP synthases, their motor functions are not fully understood. For this reason, we performed the alignments and analyses of the protein sequences comprising the core of the ATP synthase motor complex, and examined carefully the locations of the conserved residues in the subunit structures of ATP synthases. A summary of the findings from this bioinformatic study is as follows. First, we found that four conserved regions in the sequence of subunit are clustered into three patches in its structure. The interactions of these conserved patches with the and subunits are likely to be critical for energy coupling and catalytic activity of the ATP synthase. Second, we located a four-residue cluster at the N-terminal domain of mitochondrial OSCP or bacterial (or chloroplast) subunit which may be critical for the binding of these subunits to F₁. Third, from the localizations of conserved residues in the subunits comprising the rotors of ATP synthases, we suggest that the conserved interaction site at the interface of subunit c and (mitochondria) or (bacteria and chloroplasts) may be important for connecting the rotor of F₁ to the rotor of F₀. Finally, we found the sequence of mitochondrial subunit b to be highly conserved, significantly longer than bacterial subunit b, and to contain a shorter dimerization domain than that of the bacterial protein. It is suggested that the different properties of mitochondrial subunit b may be necessary for interaction with other proteins, e.g., the supernumerary subunits.     

Fluorometric evidence for control of the activity of F1-adenosinetriphosphatase by ligand-induced conformation change

The effect of ATP on the fluorescence intensity of bovine heart F₁-adenosinetriphosphatase labeled at its essential Lys with 7-chloro-4-nitro-2,1,3-benzoxadiazole (N-NBD-F₁) has been examined in solutions containing different concentrations of ADP. The fluorescence of N-NBD-F₁ is unaffected by ATP in the absence of ADP. But when increasing amounts of ATP are added to a solution of N-NBD-F₁ containing 0.37 or 1.0 mM ADP, the fluorescence of N-NBD-F₁ first decreases and then increases continually as the concentration of ATP is further raised. Parallel measurements of the suppression of the fluorescence of N-NBD-F₁ and the inhibition of the ATPase activity of the unlabeled enzyme by ADP in the presence of ATP show a quantitative correlation between the changes in fluorescence and in ATPase activity. The data are consistent with the model for F₁-ATPase with one principal catalytic subunit for ATP hydrolysis and synthesis, and two auxiliary subunits which control the conformation and hence the catalytic activity of through interaction between all the subunits.     

The coupling of the relative movement of thea andc subunits of the F0 to the conformational changes in the F1-ATPase

F₀F₁-ATPase structural information gained from X-ray crystallography and electron microscopy has activated interest in a rotational mechanism for the F₀F₁-ATPase. Because of the subunit stoichiometry and the involvement of both thea- andc-subunits in the mechanism of proton movement, it is argued that relative movement must occur between the subunits. Various options for the arrangement and structure of the subunits involved are discussed and a mechanism proposed.