Isolation and Antigenic Characterization of Corn Mitochondrial F(1)-ATPase

Corn mitochondrial F₁-ATPase was purified from submitochondrial particles by chloroform extraction. Enzyme stored in ammonium sulfate at 4°C was substantially activated by ATP, while enzyme stored at −70°C in 25% glycerol was not. Enzyme in glycerol remained fully active (8-9 micromoles P_i released per minute per milligram), while the ammonium sulfate preparations steadily lost activity over a 2-month storage period. The enzyme was cold labile, and inactived by 4 minutes at 60°C. Treatment with octylglucoside resulted in complete loss of activity, while vanadate had no effect on activity. The apparent subunit molecular weights of corn mitochondrial F₁-ATPase were determined by SDS-polyacrylamide gel electrophoresis to be 58,000 (α), 55,000 (β), 35,000 (γ), 22,000 (δ), and 12,000 (ε). Monoclonal and polyclonal antibodies used in competitive binding assays demonstrated that corn mitochondrial F₁-ATPase was antigenically distinct from the chloroplastic CF₁-ATPases of corn and spinach. Monoclonal antibodies against antigenic sites on spinach CF₁-ATPase β and γ subunits were used to demonstrate that those sites were either changed substantially or totally absent from the mitochondrial F₁-ATPase.     

Nucleotide Sequence of the F(1)-ATPase alpha Subunit Gene from Maize Mitochondria

The α subunit of the F₁-ATPase complex of maize is a mitochondrial translational product, presumably encoded by the mitochondrial genome. Based on nucleotide and amino acid homology, we have identified a mitochondrial gene, designated atpα, that appears to code for the F₁-ATPase α subunit of Zea mays. The atpα gene is present as a single copy in the maize. Texas cytoplasm and is actively transcribed. The maize α polypeptide has a predicted length of 508 amino acids and a molecular mass of 55,187 daltons. Amino acid homologies between the maize mitochondrial α subunit and the tobacco chloroplast CF₁ and Escherichia coli α subunits are 54 and 51%, respectively. The origin of the atpα gene is discussed.     

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.     

Protein Kinase C-α Interaction with F0F1-ATPase Promotes F0F1-ATPase Activity and Reduces Energy Deficits in Injured Renal Cells

We showed previously that active PKC-α maintains F₀F₁-ATPase activity, whereas inactive PKC-α mutant (dnPKC-α) blocks recovery of F₀F₁-ATPase activity after injury in renal proximal tubules (RPTC). This study tested whether mitochondrial PKC-α interacts with and phosphorylates F₀F₁-ATPase. Wild-type PKC-α (wtPKC-α) and dnPKC-α were overexpressed in RPTC to increase their mitochondrial levels, and RPTC were exposed to oxidant or hypoxia. Mitochondrial levels of the γ-subunit, but not the α- and β-subunits, were decreased by injury, an event associated with 54% inhibition of F₀F₁-ATPase activity. Overexpressing wtPKC-α blocked decreases in γ-subunit levels, maintained F₀F₁-ATPase activity, and improved ATP levels after injury. Deletion of PKC-α decreased levels of α-, β-, and γ-subunits, decreased F₀F₁-ATPase activity, and hindered the recovery of ATP content after RPTC injury. Mitochondrial PKC-α co-immunoprecipitated with α-, β-, and γ-subunits of F₀F₁-ATPase. The association of PKC-α with these subunits decreased in injured RPTC overexpressing dnPKC-α. Immunocapture of F₀F₁-ATPase and immunoblotting with phospho(Ser) PKC substrate antibody identified phosphorylation of serine in the PKC consensus site on the α- or β- and γ-subunits. Overexpressing wtPKC-α increased phosphorylation and protein levels, whereas deletion of PKC-α decreased protein levels of α-, β-, and γ-subunits of F₀F₁-ATPase in RPTC. Phosphoproteomics revealed phosphorylation of Ser¹⁴⁶ on the γ subunit in response to wtPKC-α overexpression. We concluded that active PKC-α 1) prevents injury-induced decreases in levels of γ subunit of F₀F₁-ATPase, 2) interacts with α-, β-, and γ-subunits leading to increases in their phosphorylation, and 3) promotes the recovery of F₀F₁-ATPase activity and ATP content after injury in RPTC.     

Heterogeneity of Mitochondrial Protein Biogenesis during Primary Leaf Development in Barley

The natural developmental gradient of light-grown primary leaves of barley (Hordeum vulgare L.) was used to analyze the biogenesis of mitochondrial proteins in relation to the age and physiological changes within the leaf. The data indicate that the protein composition of mitochondria changes markedly during leaf development. Three distinct patterns of protein development were noted: group A proteins, consisting of the E1 β-subunit of the pyruvate dehydrogenase complex, ORF156, ORF577, alternative oxidase, RPS12, cytochrome oxidase subunits II and III, malic enzyme, and the α- and β-subunits of F₁-ATPase; group B proteins, consisting of the E1 α-subunit of the pyruvate dehydrogenase complex, isocitrate dehydrogenase, HSP70A, cpn60C, and cpn60B; and group C proteins, consisting of the four subunits of the glycine decarboxylase complex (P, H, T, and L proteins), fumarase, and formate dehydrogenase. All of the proteins increased in concentration from the basal meristem to the end of the elongation zone (20.0 mm from the leaf base), whereupon group A proteins decreased, group B proteins increased to a maximum at 50 mm from the leaf base, and group C proteins increased to a maximum at the leaf tip. This study provides evidence of a marked heterogeneity of mitochondrial protein composition, reflecting a changing function as leaf cells develop photosynthetic and photorespiratory capacity.     

The depletion of F1 subunit ε in yeast leads to an uncoupled respiratory phenotype that is rescued by mutations in the proton-translocating subunits of F0

The central stalk of the ATP synthase is an elongated hetero-oligomeric structure providing a physical connection between the catalytic sites in F₁ and the proton translocation channel in F₀ for energy transduction between the two subdomains. The shape of the central stalk and relevance to energy coupling are essentially the same in ATP synthases from all forms of life, yet the protein composition of this domain changed during evolution of the mitochondrial enzyme from a two- to a three-subunit structure (γ, δ, ε). Whereas the mitochondrial γ- and δ-subunits are homologues of the bacterial central stalk proteins, the deliberate addition of subunit ε is poorly understood. Here we report that down-regulation of the gene (ATP15) encoding the ε-subunit rapidly leads to lethal F₀-mediated proton leaks through the membrane because of the loss of stability of the ATP synthase. The ε-subunit is thus essential for oxidative phosphorylation. Moreover, mutations in F₀ subunits a and c, which slow the proton translocation rate, are identified that prevent ε-deficient ATP synthases from dissipating the electrochemical potential. Cumulatively our data lead us to propose that the ε-subunit evolved to permit operation of the central stalk under the torque imposed at the normal speed of proton movement through mitochondrial F₀.     

Immunological detection of the mitochondrial F1-ATPase α subunit in the matrix of rat liver peroxisomes: A protein involved in organelle biogenesis?

Rat liver peroxisomes contain in their matrix the α-subunit of the mitochondrial F₁-ATPase complex. The identification of this protein in liver peroxisomes has been achieved by immunoelectron microscopy and subcellular fractionation. No β-subunit of the mitochondrial F₁-ATPase complex was detected in the peroxisomal fractions obtained in sucrose gradients or in Nycodenz pelletted peroxisomes. The consensus peroxisomal targeting sequence (Ala-Lys-Leu) is found at the carboxy terminus of the mature α-subunit from bovine heart and rat liver mitochondria. Due to the dual subcellular localization of the α-subunit and to the structural homologies that exist between this protein and molecular chaperones [(1990) Biol. Chem. 265, 7713-7716] it is suggested that the protein should perform another functional role(s) in both organelles, plus to its characteristic involvement in the regulation of mitochondrial ATPase activity.     

Mutations on the N-Terminal Edge of the DELSEED Loop in either the α or β Subunit of the Mitochondrial F1-ATPase Enhance ATP Hydrolysis in the Absence of the Central γ Rotor

F₁-ATPase is a rotary molecular machine with a subunit stoichiometry of α₃β₃γ₁δ₁ε₁. It has a robust ATP-hydrolyzing activity due to effective cooperativity between the three catalytic sites. It is believed that the central γ rotor dictates the sequential conformational changes to the catalytic sites in the α₃β₃ core to achieve cooperativity. However, recent studies of the thermophilic Bacillus PS3 F₁-ATPase have suggested that the α₃β₃ core can intrinsically undergo unidirectional cooperative catalysis (T. Uchihashi et al., Science 333:755-758, 2011). The mechanism of this γ-independent ATP-hydrolyzing mode is unclear. Here, a unique genetic screen allowed us to identify specific mutations in the α and β subunits that stimulate ATP hydrolysis by the mitochondrial F₁-ATPase in the absence of γ. We found that the F446I mutation in the α subunit and G419D mutation in the β subunit suppress cell death by the loss of mitochondrial DNA (ρ^o) in a Kluyveromyces lactis mutant lacking γ. In organello ATPase assays showed that the mutant but not the wild-type γ-less F₁ complexes retained 21.7 to 44.6% of the native F₁-ATPase activity. The γ-less F₁ subcomplex was assembled but was structurally and functionally labile in vitro. Phe446 in the α subunit and Gly419 in the β subunit are located on the N-terminal edge of the DELSEED loops in both subunits. Mutations in these two sites likely enhance the transmission of catalytically required conformational changes to an adjacent α or β subunit, thereby allowing robust ATP hydrolysis and cell survival under ρ^o conditions. This work may help our understanding of the structural elements required for ATP hydrolysis by the α₃β₃ subcomplex.     

One rotary mechanism for F1-ATPase over ATP concentrations from millimolar down to nanomolar

F₁-ATPase is a rotary molecular motor in which the central γ-subunit rotates inside a cylinder made of α₃β₃-subunits. The rotation is driven by ATP hydrolysis in three catalytic sites on the β-subunits. How many of the three catalytic sites are filled with a nucleotide during the course of rotation is an important yet unsettled question. Here we inquire whether F₁ rotates at extremely low ATP concentrations where the site occupancy is expected to be low. We observed under an optical microscope rotation of individual F₁ molecules that carried a bead duplex on the γ-subunit. Time-averaged rotation rate was proportional to the ATP concentration down to 200 pM, giving an apparent rate constant for ATP binding of 2 × 10⁷ M⁻¹s⁻¹. A similar rate constant characterized bulk ATP hydrolysis in solution, which obeyed a simple Michaelis-Menten scheme between 6 mM and 60 nM ATP. F₁ produced the same torque of ~40 pN·nm at 2 mM, 60 nM, and 2 nM ATP. These results point to one rotary mechanism governing the entire range of nanomolar to millimolar ATP, although a switchover between two mechanisms cannot be dismissed. Below 1 nM ATP, we observed less regular rotations, indicative of the appearance of another reaction scheme.     

Different Rates of Synthesis and Degradation of Two Chloroplastic Ammonium-Inducible NADP-Specific Glutamate Dehydrogenase Isoenzymes during Induction and Deinduction in Chlorella sorokiniana Cells

The kinetics of accumulation (per milliliter of culture) of the α- and β- subunits, associated with chloroplast-localized ammonium inducible nicotinamide adenine dinucleotide phosphate-specific glutamate dehydrogenase (NADP-GDH) isoenzymes, were measured during a 3 hour induction of synchronized daughter cells of Chlorella sorokiniana in 29 millimolar ammonium medium under photoautotrophic conditions. The β-subunit holoenzyme(s) accumulated in a linear manner for 3 hours without an apparent induction lag. A 40 minute induction lag preceded the accumulation of the α-subunit holoenzyme(s). After 120 minutes, the α-subunit ceased accumulating and thereafter remained at a constant level (i.e. steady state between synthesis and degradation). From pulsechase experiments, using ³⁵SO₄ and immunochemical procedures, the rate of synthesis of the α-subunit was shown to be greater than the β-subunit during the first 80 minutes of induction. The α- and β-subunits had different rates of degradation during the induction period (t_½ = 50 versus 150 minutes, respectively) and during the deinduction period (t_½ = 5 versus 13.5 minutes) after removal of ammonium from the culture. During deinduction, total NADP-GDH activity decreased with a half-time of 9 minutes. Cycloheximide completely inhibited the synthesis and degradation of both subunits. A model for regulation of expression of the NADP-GDH gene was proposed.     

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 the Protein Kinase Cδ Interaction with the “d” Subunit of F1F0-ATP Synthase in Neonatal Cardiac Myocytes: DEVELOPMENT OF CELL-PERMEABLE,MITOCHONDRIALLY TARGETED INHIBITOR AND FACILITATOR PEPTIDES*

The F₁F₀-ATP synthase provides ∼90% of cardiac ATP, yet little is known regarding its regulation under normal or pathological conditions. Previously, we demonstrated that protein kinase Cδ (PKCδ) inhibits F₁F₀ activity via an interaction with the “d” subunit of F₁F₀-ATP synthase (dF₁F₀) in neonatal cardiac myocytes (NCMs) (Nguyen, T., Ogbi, M., and Johnson, J. A. (2008) J. Biol. Chem. 283, 29831–29840). We have now identified a dF₁F₀-derived peptide (NH₂-²AGRKLALKTIDWVSF¹⁶-COOH) that inhibits PKCδ binding to dF₁F₀ in overlay assays. We have also identified a second dF₁F₀-derived peptide (NH₂-¹¹¹RVREYEKQLEKIKNMI¹²⁶-COOH) that facilitates PKCδ binding to dF₁F₀. Incubation of NCMs with versions of these peptides containing HIV-Tat protein transduction and mammalian mitochondrial targeting sequences resulted in their delivery into mitochondria. Preincubation of NCMs, with 10 nm extracellular concentrations of the mitochondrially targeted PKCδ-dF₁F₀ interaction inhibitor, decreased 100 nm 4β-phorbol 12-myristate 13-acetate (4β-PMA)-induced co-immunoprecipitation of PKCδ with dF₁F₀ by 50 ± 15% and abolished the 30 nm 4β-PMA-induced inhibition of F₁F₀-ATPase activity. A scrambled sequence (inactive) peptide, which contained HIV-Tat and mitochondrial targeting sequences, was without effect. In contrast, the cell-permeable, mitochondrially targeted PKCδ-dF₁F₀ facilitator peptide by itself induced the PKCδ-dF₁F₀ co-immunoprecipitation and inhibited F₁F₀-ATPase activity. In in vitro PKC add-back experiments, the PKCδ-F₁F₀ inhibitor blocked PKCδ-mediated inhibition of F₁F₀-ATPase activity, whereas the facilitator induced inhibition. We have developed the first cell-permeable, mitochondrially targeted modulators of the PKCδ-dF₁F₀ interaction in NCMs. These novel peptides will improve our understanding of cardiac F₁F₀ regulation and may have potential as therapeutics to attenuate cardiac injury.     

Purification and Characterization of the Soluble F(1)-ATPase of Oat Root Mitochondria

The properties of the soluble moiety (F₁) of the mitochondrial H⁺-ATPase from oat roots were examined and compared to those of the native mitochondrial membrane-bound enzyme. The chloroform soluble preparation was purified by Sephadex G-200 and DEAE-cellulose chromatography. The purified F₁ preparation contained major polypeptides corresponding to α, β, γ, δ, and ε of apparent molecular mass 58, 55, 35, 22, and 14 kilodaltons, respectively. The purified F₁-ATPase, like the native enzyme, was inhibited by azide (I₅₀ = 10 micromolar), nitrate (I₅₀ = 7-10 millimolar), 4,4′-diisothiocyano-2,2′-stilbene disulfonic acid (I₅₀ = 1-3 micromolar), and 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (I₅₀ = 3 micromolar). F₁-ATPase activity was stimulated by bicarbonate but not by chloride. In both the native and the F₁-form of the ATPase, ATP was hydrolyzed in preference to GTP. The results indicate that these properties of the native membrane-bound mitochondrial ATPase have been conserved in the purified F₁. In contrast to the membrane-bound enzyme, the F₁-ATPase was not inhibited by oligomycin or by N,N′-dicyclohexylcarbodiimide. The mitochondrial F₁-ATPase from oat roots is analogous to other known F₁F₀-ATPases.     

Thermodynamic Analyses of Nucleotide Binding to an Isolated Monomeric β Subunit and the α3β3γ Subcomplex of F1-ATPase

Rotation of the γ subunit of the F₁-ATPase plays an essential role in energy transduction by F₁-ATPase. Hydrolysis of an ATP molecule induces a 120° step rotation that consists of an 80° substep and 40° substep. ATP binding together with ADP release causes the first 80° step rotation. Thus, nucleotide binding is very important for rotation and energy transduction by F₁-ATPase. In this study, we introduced a βY341W mutation as an optical probe for nucleotide binding to catalytic sites, and a βE190Q mutation that suppresses the hydrolysis of nucleoside triphosphate (NTP). Using a mutant monomeric βY341W subunit and a mutant α₃β₃γ subcomplex containing the βY341W mutation with or without an additional βE190Q mutation, we examined the binding of various NTPs (i.e., ATP, GTP, and ITP) and nucleoside diphosphates (NDPs, i.e., ADP, GDP, and IDP). The affinity (1/K_d) of the nucleotides for the isolated β subunit and third catalytic site in the subcomplex was in the order ATP/ADP > GTP/GDP > ITP/IDP. We performed van’t Hoff analyses to obtain the thermodynamic parameters of nucleotide binding. For the isolated β subunit, NDPs and NTPs with the same base moiety exhibited similar ΔH⁰ and ΔG⁰ values at 25°C. The binding of nucleotides with different bases to the isolated β subunit resulted in different entropy changes. Interestingly, NDP binding to the α₃β(Y341W)₃γ subcomplex had similar K_d and ΔG⁰ values as binding to the isolated β(Y341W) subunit, but the contributions of the enthalpy term and the entropy term were very different. We discuss these results in terms of the change in the tightness of the subunit packing, which reduces the excluded volume between subunits and increases water entropy.     

Inhibition of F1-ATPase Rotational Catalysis by the Carboxyl-terminal Domain of the ? Subunit

Escherichia coli ATP synthase (F₀F₁) couples catalysis and proton transport through subunit rotation. The ϵ subunit, an endogenous inhibitor, lowers F₁-ATPase activity by decreasing the rotation speed and extending the duration of the inhibited state (Sekiya, M., Hosokawa, H., Nakanishi-Matsui, M., Al-Shawi, M. K., Nakamoto, R. K., and Futai, M. (2010) Single molecule behavior of inhibited and active states of Escherichia coli ATP synthase F₁ rotation. J. Biol. Chem. 285, 42058–42067). In this study, we constructed a series of ϵ subunits truncated successively from the carboxyl-terminal domain (helix 1/loop 2/helix 2) and examined their effects on rotational catalysis (ATPase activity, average rotation rate, and duration of inhibited state). As expected, the ϵ subunit lacking helix 2 caused about ½-fold reduced inhibition, and that without loop 2/helix 2 or helix 1/loop 2/helix 2 showed a further reduced effect. Substitution of ϵSer¹⁰⁸ in loop 2 and ϵTyr¹¹⁴ in helix 2, which possibly interact with the β and γ subunits, respectively, decreased the inhibitory effect. These results suggest that the carboxyl-terminal domain of the ϵ subunit plays a pivotal role in the inhibition of F₁ rotation through interaction with other subunits.     

Mitochondrial Free Ca2+ Levels and Their Effects on Energy Metabolism in Drosophila Motor Nerve Terminals

Mitochondrial Ca²⁺ uptake exerts dual effects on mitochondria. Ca²⁺ accumulation in the mitochondrial matrix dissipates membrane potential (_ΔΨ_m), but Ca²⁺ binding of the intramitochondrial enzymes accelerates oxidative phosphorylation, leading to mitochondrial hyperpolarization. The levels of matrix free Ca²⁺ ([Ca²⁺]_m) that trigger these metabolic responses in mitochondria in nerve terminals have not been determined. Here, we estimated [Ca²⁺]_m in motor neuron terminals of Drosophila larvae using two methods: the relative responses of two chemical Ca²⁺ indicators with a 20-fold difference in Ca²⁺ affinity (rhod-FF and rhod-5N), and the response of a low-affinity, genetically encoded ratiometric Ca²⁺ indicator (D4cpv) calibrated against known Ca²⁺ levels. Matrix pH (pH_m) and _ΔΨ_m were monitored using ratiometric pericam and tetramethylrhodamine ethyl ester probe, respectively, to determine when mitochondrial energy metabolism was elevated. At rest, [Ca²⁺]_m was 0.22 ± 0.04 μM, but it rose to ∼26 μM (24.3 ± 3.4 μM with rhod-FF/rhod-5N and 27.0 ± 2.6 μM with D4cpv) when the axon fired close to its endogenous frequency for only 2 s. This elevation in [Ca²⁺]_m coincided with a rapid elevation in pH_m and was followed by an after-stimulus _ΔΨ_m hyperpolarization. However, pH_m decreased and no _ΔΨ_m hyperpolarization was observed in response to lower levels of [Ca²⁺]_m, up to 13.1 μM. These data indicate that surprisingly high levels of [Ca²⁺]_m are required to stimulate presynaptic mitochondrial energy metabolism.     

ATPaseTb2, a Unique Membrane-bound FoF1-ATPase Component,Is Essential in Bloodstream and Dyskinetoplastic Trypanosomes

In the infectious stage of Trypanosoma brucei, an important parasite of humans and livestock, the mitochondrial (mt) membrane potential (Δψ_m) is uniquely maintained by the ATP hydrolytic activity and subsequent proton pumping of the essential F_oF₁-ATPase. Intriguingly, this multiprotein complex contains several trypanosome-specific subunits of unknown function. Here, we demonstrate that one of the largest novel subunits, ATPaseTb2, is membrane-bound and localizes with monomeric and multimeric assemblies of the FoF1-ATPase. Moreover, RNAi silencing of ATPaseTb2 quickly leads to a significant decrease of the Δψ_m that manifests as a decreased growth phenotype, indicating that the F_oF₁-ATPase is impaired. To further explore the function of this protein, we employed a trypanosoma strain that lacks mtDNA (dyskinetoplastic, Dk) and thus subunit a, an essential component of the proton pore in the membrane F_o-moiety. These Dk cells generate the Δψ_m by combining the hydrolytic activity of the matrix-facing F₁-ATPase and the electrogenic exchange of ATP⁴- for ADP³- by the ATP/ADP carrier (AAC). Surprisingly, in addition to the expected presence of F1-ATPase, the monomeric and multimeric F_oF₁-ATPase complexes were identified. In fact, the immunoprecipitation of a F₁-ATPase subunit demonstrated that ATPaseTb2 was a component of these complexes. Furthermore, RNAi studies established that the membrane-bound ATPaseTb2 subunit is essential for maintaining normal growth and the Δψ_m of Dk cells. Thus, even in the absence of subunit a, a portion of the F_oF₁-ATPase is assembled in Dk cells.     

Identification of a Novel Isoform of the Chloroplast-Coupling Factor α-Subunit

Studies were conducted to identify a 64-kD thylakoid membrane protein of unknown function. The protein was extracted from chloroplast thylakoids under low ionic strength conditions and purified to homogeneity by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Four peptides generated from the proteolytic cleavage of the wheat 64-kD protein were sequenced and found to be identical to internal sequences of the chloroplast-coupling factor (CF₁) α-subunit. Antibodies for the 64-kD protein also recognized the α-subunit of CF₁. Both the 64-kD protein and the 61-kD CF₁ α-subunit were present in the monocots barley (Hordeum vulgare), maize (Zea mays), oat (Avena sativa), and wheat (Triticum aestivum); but the dicots pea (Pisum sativum), soybean (Glycine max Merr.), and spinach (Spinacia oleracea) contained only a single polypeptide corresponding to the CF₁ α-subunit. The 64-kD protein accumulated in response to high irradiance (1000 μmol photons m⁻² s⁻¹) and declined in response to low irradiance (80 μmol photons m⁻² s⁻¹) treatments. Thus, the 64-kD protein was identified as an irradiance-dependent isoform of the CF₁ α-subunit found only in monocots. Analysis of purified CF₁ complexes showed that the 64-kD protein represented up to 15% of the total CF₁ α-subunit.     

Structure and Flexibility of the C-Ring in the Electromotor of Rotary FoF1-ATPase of Pea Chloroplasts

A ring of 8–15 identical c-subunits is essential for ion-translocation by the rotary electromotor of the ubiquitous F_OF₁-ATPase. Here we present the crystal structure at 3.4Å resolution of the c-ring from chloroplasts of a higher plant (Pisum sativum), determined using a native preparation. The crystal structure was found to resemble that of an (ancestral) cyanobacterium. Using elastic network modeling to investigate the ring''s eigen-modes, we found five dominant modes of motion that fell into three classes. They revealed the following deformations of the ring: (I) ellipsoidal, (II) opposite twisting of the luminal circular surface of the ring against the stromal surface, and (III) kinking of the hairpin-shaped monomers in the middle, resulting in bending/stretching of the ring. Extension of the elastic network analysis to rings of different c_n-symmetry revealed the same classes of dominant modes as in P. sativum (c₁₄). We suggest the following functional roles for these classes: The first and third classes of modes affect the interaction of the c-ring with its counterparts in F_O, namely subunits a and bb''. These modes are likely to be involved in ion-translocation and torque generation. The second class of deformation, along with deformations of subunits γ and ε might serve to elastically buffer the torque transmission between F_O and F₁.     

Individual Interactions of the b Subunits within the Stator of the Escherichia coli ATP Synthase

F_OF₁ ATP synthases are rotary nanomotors that couple proton translocation across biological membranes to the synthesis/hydrolysis of ATP. During catalysis, the peripheral stalk, composed of two b subunits and subunit δ in Escherichia coli, counteracts the torque generated by the rotation of the central stalk. Here we characterize individual interactions of the b subunits within the stator by use of monoclonal antibodies and nearest neighbor analyses via intersubunit disulfide bond formation. Antibody binding studies revealed that the C-terminal region of one of the two b subunits is principally involved in the binding of subunit δ, whereas the other one is accessible to antibody binding without impact on the function of F_OF₁. Individually substituted cysteine pairs suitable for disulfide cross-linking between the b subunits and the other stator subunits (b-α, b-β, b-δ, and b-a) were screened and combined with each other to discriminate between the two b subunits (i.e. b_I and b_II). The results show the b dimer to be located at a non-catalytic α/β cleft, with b_I close to subunit α, whereas b_II is proximal to subunit β. Furthermore, b_I can be linked to subunit δ as well as to subunit a. Among the subcomplexes formed were a-b_I-α, b_II-β, α-b_I-b_II-β, and a-b_I-δ. Taken together, the data obtained define the different positions of the two b subunits at a non-catalytic interface and imply that each b subunit has a different role in generating stability within the stator. We suggest that b_I is functionally related to the single b subunit present in mitochondrial ATP synthase.