Distances between the b-subunits in the tether domain of F(0)F(1)-ATP synthase from E. coli

The arrangement of the b-subunits in the holo-enzyme F(0)F(1)-ATP synthase from E. coli is investigated by site-directed mutagenesis spin-label EPR. F(0)F(1)-ATP synthases couple proton translocation with the synthesis of ATP from ADP and phosphate. The hydrophilic F(1)-part and the hydrophobic membrane-integrated F(0)-part are connected by a central and a peripheral stalk. The peripheral stalk consists of two b-subunits. Cysteine mutations are introduced in the tether domain of the b-subunit at b-40, b-51, b-53, b-62 or b-64 and labeled with a nitroxide spin label. Conventional (9 GHz), high-field (95 GHz) and pulsed EPR spectroscopy reveal: All residues are in a relatively polar environment, with mobilities consistent with helix sites. The distance between the spin labels at each b-subunit is 2.9 nm in each mutant, revealing a parallel arrangement of the two helices. They can be in-register but separated by a large distance (1.9 nm), or at close contact and displaced along the helix axes by maximally 2.7 nm, which excludes an in-register coiled-coil model suggested previously for the b-subunit. Binding of the non-hydrolysable nucleotide AMPPNP to the spin-labeled enzyme had no significant influence on the distances compared to that in the absence of nucleotides.     

Interaction of the Thermoplasma acidophilum A1A0-ATP synthase peripheral stalk with the catalytic domain

The peripheral stalk of the archaeal ATP synthase (A₁A₀)-ATP synthase is formed by the heterodimeric EH complex and is part of the stator domain, which counteracts the torque of rotational catalysis. Here we used nuclear magnetic resonance spectroscopy to probe the interaction of the C-terminal domain of the EH heterodimer (E_CT1H_CT) with the N-terminal 23 residues of the B subunit (B_NT). The data show a specific interaction of B_NT peptide with 26 residues of the E_CT1H_CT domain, thereby providing a molecular picture of how the peripheral stalk is anchored to the A₃B₃ catalytic domain in A₁A₀.

Structured summary

MINT-7260681: Hct (refseq:NP_393485), Ect1 (uniprotkb:Q9HM68) and Bnt (uniprotkb:Q9HM64) physically interact (MI:0915) by nuclear magnetic resonance (MI:0077)     

Structure of the cytosolic part of the subunit b-dimer of Escherichia coli F0F1-ATP synthase

The structure of the external stalk and its function in the catalytic mechanism of the F₀F₁-ATP synthase remains one of the important questions in bioenergetics. The external stalk has been proposed to be either a rigid stator that binds F₁ or an elastic structural element that transmits energy from the small rotational steps of subunits c to the F₁ sector during catalysis. We employed proteomics, sequence-based structure prediction, molecular modeling, and electron spin resonance spectroscopy using site-directed spin labeling to understand the structure and interfacial packing of the Escherichia coli b-subunit homodimer external stalk. Comparisons of bacterial, cyanobacterial, and plant b-subunits demonstrated little sequence similarity. Supersecondary structure predictions, however, show that all compared b-sequences have extensive heptad repeats, suggesting that the proteins all are capable of packing as left-handed coiled-coils. Molecular modeling subsequently indicated that b₂ from the E. coli ATP synthase could pack into stable left-handed coiled-coils. Thirty-eight substitutions to cysteine in soluble b-constructs allowed the introduction of spin labels and the determination of intersubunit distances by ESR. These distances correlated well with molecular modeling results and strongly suggest that the E. coli subunit b-dimer can stably exist as a left-handed coiled-coil.     

Structure and dynamics of the force-generating domain of myosin probed by multifrequency electron paramagnetic resonance

Spin-labeling and multifrequency EPR spectroscopy were used to probe the dynamic local structure of skeletal myosin in the region of force generation. Subfragment 1 (S1) of rabbit skeletal myosin was labeled with an iodoacetamide spin label at C707 (SH1). X-and W-band EPR spectra were recorded for the apo state and in the presence of ADP and nucleotide analogs. EPR spectra were analyzed in terms of spin-label rotational motion within myosin by fitting them with simulated spectra. Two models were considered: rapid-limit oscillation (spectrum-dependent on the orientational distribution only) and slow restricted motion (spectrum-dependent on the rotational correlation time and the orientational distribution). The global analysis of spectra obtained at two microwave frequencies (9.4 GHz and 94 GHz) produced clear support for the second model and enabled detailed determination of rates and amplitudes of rotational motion and resolution of multiple conformational states. The apo biochemical state is well-described by a single structural state of myosin (M) with very restricted slow motion of the spin label. The ADP-bound biochemical state of myosin also reveals a single structural state (M*, shown previously to be the same as the post-powerstroke ATP-bound state), with less restricted slow motion of the spin label. In contrast, the extra resolution available at 94 GHz reveals that the EPR spectrum of the S1.ADP.V_i-bound biochemical state of myosin, which presumably mimics the S1.ADP.P_i state, is resolved clearly into three spectral components (structural states). One state is indistinguishable from that of the ADP-bound state (M*) and is characterized by moderate restriction and slow motion, with a mole fraction of 16%. The remaining 84% (M**) contains two additional components and is characterized by fast rotation about the x axis of the spin label. After analyzing EPR spectra, myosin ATPase activity, and available structural information for myosin II, we conclude that post-powerstroke and pre-powerstroke structural states (M* and M**) coexist in the S1.ADP.V_i biochemical state. We propose that the pre-powerstroke state M** is characterized by two structural states that could reflect flexibility between the converter and N-terminal domains of myosin.     

Movements of the epsilon-subunit during catalysis and activation in single membrane-bound H(+)-ATP synthase

F0F1-ATP synthases catalyze proton transport-coupled ATP synthesis in bacteria, chloroplasts, and mitochondria. In these complexes, the epsilon-subunit is involved in the catalytic reaction and the activation of the enzyme. Fluorescence-labeled F0F1 from Escherichia coli was incorporated into liposomes. Single-molecule fluorescence resonance energy transfer (FRET) revealed that the epsilon-subunit rotates stepwise showing three distinct distances to the b-subunits in the peripheral stalk. Rotation occurred in opposite directions during ATP synthesis and hydrolysis. Analysis of the dwell times of each FRET state revealed different reactivities of the three catalytic sites that depended on the relative orientation of epsilon during rotation. Proton transport through the enzyme in the absence of nucleotides led to conformational changes of epsilon. When the enzyme was inactive (i.e. in the absence of substrates or without membrane energization), three distances were found again, which differed from those of the active enzyme. The three states of the inactive enzyme were unequally populated. We conclude that the active-inactive transition was associated with a conformational change of epsilon within the central stalk.     

Molecular Dynamics Simulations of the Rotary Motor F0 under External Electric Fields across the Membrane

The membrane-bound component F₀, which is a major component of the F₀F₁-ATP synthase, works as a rotary motor and plays a central role in driving the F₁ component to transform chemiosmotic energy into ATP synthesis. We conducted molecular dynamics simulations of b₂-free F₀ in a 1-palmitoyl-2-oleoyl-phosphatidylcholine lipid bilayer for tens of nanoseconds with two different protonation states of the cAsp-61 residue at the interface of the a-c complex in the absence of electric fields and under electric fields of ±0.03 V/nm across the membrane. To our surprise, we observed that the upper half of the N-terminal helix of the c₁ subunit rotated about its axis clockwise by 30°. An energetic analysis revealed that the electrostatic repulsion between this N-terminal helix and subunit c₁₂ was a major contributor to the observed rotation. A correlation map analysis indicated that the correlated motions of residues in the interface of the a-c complex were significantly reduced by external electric fields. The deuterium order parameter (S_CD) profile calculated by averaging all the lipids in the F₀-bound bilayer was not very different from that of the pure bilayer system, in agreement with recent ²H solid-state NMR experiments. However, by delineating the lipid properties according to their vicinity to F₀, we found that the S_CD profiles of different lipid shells were prominently different. Lipids close to F₀ formed a more ordered structure. Similarly, the lateral diffusion of lipids on the membrane surface also followed a shell-dependent behavior. The lipids in the proximity of F₀ exhibited very significantly reduced diffusional motion. The numerical value of S_CD was anticorrelated with that of the diffusion coefficient, i.e., the more ordered lipid structures led to slower lipid diffusion. Our findings will help elucidate the dynamics of F₀ depending on the protonation state and electric field, and may also shed some light on the interactions between the motor F₀ and its surrounding lipids under physiological conditions, which could help to rationalize its extraordinary energy conversion efficiency.     

The b Subunits in the Peripheral Stalk of F1F0 ATP Synthase Preferentially Adopt an Offset Relationship

The peripheral stalk of F₁F₀ ATP synthase is essential for the binding of F₁ to F_O and for proper transfer of energy between the two sectors of the enzyme. The peripheral stalk of Escherichia coli is composed of a dimer of identical b subunits. In contrast, photosynthetic organisms express two b-like genes that form a heterodimeric peripheral stalk. Previously we generated chimeric peripheral stalks in which a portion of the tether and dimerization domains of the E. coli b subunits were replaced with homologous sequences from the b and b′ subunits of Thermosynechococcus elongatus (Claggett, S. B., Grabar, T. B., Dunn, S. D., and Cain, B. D. (2007) J. Bacteriol. 189, 5463–5471). The spatial arrangement of the chimeric b and b′ subunits, abbreviated Tb and Tb′, has been investigated by Cu²⁺-mediated disulfide cross-link formation. Disulfide formation was studied both in soluble model polypeptides and between full-length subunits within intact functional F₁F₀ ATP synthase complexes. In both cases, disulfides were preferentially formed between Tb_A83C and Tb′_A90C, indicating the existence of a staggered relationship between helices of the two chimeric subunits. Even under stringent conditions rapid formation of disulfides between these positions occurred. Importantly, formation of this cross-link had no detectable effect on ATP-driven proton pumping, indicating that the staggered conformation is compatible with normal enzymatic activity. Under less stringent reaction conditions, it was also possible to detect b subunits cross-linked through identical positions, suggesting that an in-register, nonstaggered parallel conformation may also exist.F₁F₀ ATP synthases are found in the inner mitochondrial membrane, the thylakoid membrane of chloroplasts, and the cytoplasmic membrane of bacteria (1–4). These enzymes are responsible for harnessing an electrochemical gradient of protons across the membranes for the synthesis of ATP. In Escherichia coli F₁F₀ ATP synthase, the membrane-embedded F₀ sector is composed of subunits ab₂c₁₀ and a soluble F₁ portion composed of subunits α₃β₃γδϵ. The F₀ sector houses a proton channel located principally in the a subunit, and the flow of protons through F₀ generates torque used to rotate the c₁₀ subunit ring relative to the ab₂ subunits. The F₁ γ and ϵ subunits are bound to the c₁₀ ring and form the central or rotor stalk. Catalytic sites are located at the interfaces of each αβ pair in F₁. The γ subunit extends into the center of the α₃β₃ hexamer, creating an asymmetry in the conformations of the αβ pairs (5). It is the rotation of the γ subunit and the resulting sequential conformational changes in each αβ pair that provides the driving force for the synthesis of ATP at the catalytic sites. The α₃β₃ hexamer is held stationary relative to the rotary stalk by the peripheral stalk consisting of the b₂δ subunits.The peripheral stalk is essential for binding F₁ to F₀ and for coupling proton translocation to catalytic activity (6–8). In the E. coli enzyme, the peripheral stalk is a dimer of identical b subunits. The stalk has been conceptually divided into functional domains called the membrane domain (b_M1-I33), the tether domain (b_E34-A61), the dimerization domain (b_T62-K122), and the F₁-binding domain (b_Q123-L156) (9). Although there is ample evidence of direct protein-protein interactions between b subunits within the membrane, dimerization, and F₁-binding domains, there is remarkably little evidence of tight packing between the b subunits in the tether domain. In fact, electron spin resonance studies suggested that the tether domains of the two b subunits may be separated by more than 20 Å in the F₁F₀ complex (10, 11). Much of what is known about the structure of the stalk has been inferred from analysis of the properties of polypeptides modeling segments of the b subunit. The structure of a peptide modeling the membrane domain, b_M1-E34, has been determined by NMR (12), and a peptide based on the dimerization domain, b_T62-K122, has been determined by x-ray diffraction (13). Both polypeptides assumed α-helical conformations, but neither structure directly revealed b subunit dimerization interactions. Recently, Priya et al. (14) reported a low resolution structure of a b_M22-L156 dimer, but the extended conformation appears to be slightly too long to accurately reflect the dimensions of the peripheral stalk within the F₁F₀ complex.Molecular modeling efforts supported by a variety of biochemical and biophysical experiments have yielded competing right-handed coiled coil (15, 16) and left-handed coiled coil (17, 18) models for the peripheral stalk. The parallel two-stranded left-handed coiled coli is a well known structure characterized by knobs-into-holes packing of the side chains of the two helices that are aligned in-register. An in-register conformation implies that any specific amino acid on the b subunit-subunit interface would occupy a position immediately adjacent to its counterpart in the other b subunit. In contrast, del Rizzo et al. (16) proposed a novel parallel right-handed coiled coil with the helices of the two b subunits offset by approximately one and a half turns of an α helix. This staggered model positions the two identical residues contributed by each of the b subunits in a homodimer into differing environments and at considerable distance from one another. Sequence analyses have been offered in support of both models (16, 18). In terms of experimental support, cross-linking studies of polypeptides have provided evidence that dimer packing could be in-register at many sites starting from residue Ala⁵⁹ and continuing to the carboxyl termini in model b_Y24–L156 dimers and in b_D53–K122 dimers (9, 16). Cross-linking at a few of the carboxyl-proximal positions has been confirmed within intact F₁F₀ ATP synthase complexes (19, 20). Recent electron spin resonance distance measurements on b_24–156 have also been interpreted as support for the in-register arrangement (17, 18). Conversely, work with polypeptides modeling the b subunit has generated evidence favoring a staggered conformation in this section of the dimer (15, 16, 21). In mixtures of dimerization domain polypeptides with cysteines incorporated at different sites, disulfides preferentially formed between positions that were 4–7 residues apart. For example, b_D53–L156 dimers were covalently locked into the offset conformation by the formation of disulfide bridges between cysteines introduced at positions b_A79 and b_R83 as well as b_R83 and b_A90 (15). These staggered dimers were more stable, melted with higher cooperativity, and bound soluble F₁ with higher affinity than b_D53–L156 dimers fixed in the in-register arrangement. Moreover, active and coupled F₁F₀ complexes were assembled with heterodimeric peripheral stalks using b subunits with tether domains varying in length by as many as 14 amino acids (22). These F₁F₀ complexes had peripheral stalks that were by definition out of register, at least within the tether domain.In contrast to the homodimer of identical b subunits observed in the peripheral stalk of E. coli, photosynthetic organisms express two b-like subunits, b and b′, that are thought to form heterodimeric peripheral stalks in F₁F₀ ATP synthase. Previously, we generated heterodimeric peripheral stalks within the E. coli F₁F₀ by constructing chimeric b subunits (23). Segments of the tether and dimerization domains of the E. coli b subunit were replaced with the homologous regions of the Thermosynechococcus elongatus b and b′ subunits. The chimeric subunits formed heterodimeric peripheral stalks that were incorporated into intact, functional F₁F₀ ATP synthase complexes. The most active chimeric enzymes had T. elongatus primary sequences replacing residues b_E39–I86 of the E. coli b subunit. For simplicity, these chimeric subunits will be referred to here as Tb and Tb′.The ability to generate F₁F₀ ATP synthases with Tb/Tb′ heterodimeric peripheral stalks provided a means to investigate the positions of the two subunits in the peripheral stalk. In the present work, we show that the Tb and Tb′ subunits assumed preferred positions relative to one another within the F₁F₀ complex. The staggered conformation appears to be a favored and functional conformation for the peripheral stalk. However, within a population of F₁F₀ complexes, some complexes with peripheral stalks in the in-register conformation are likely to exist.     

Nucleotide-dependent displacement and dynamics of the α-1 helix in kinesin revealed by site-directed spin labeling EPR

In kinesin X-ray crystal structures, the N-terminal region of the α-1 helix is adjacent to the adenine ring of the bound nucleotide, while the C-terminal region of the helix is near the neck-linker (NL). Here, we monitor the displacement of the α-1 helix within a kinesin monomer bound to microtubules (MTs) in the presence or absence of nucleotides using site-directed spin labeling EPR. Kinesin was doubly spin-labeled at the α-1 and α-2 helices, and the resulting EPR spectrum showed dipolar broadening. The inter-helix distance distribution showed that 20% of the spins have a peak characteristic of 1.4–1.7 nm separation, which is similar to what is predicted from the X-ray crystal structure, albeit 80% were beyond the sensitivity limit (>2.5 nm) of the method. Upon MT binding, the fraction of kinesin exhibiting an inter-helix distance of 1.4–1.7 nm in the presence of AMPPNP (a non-hydrolysable ATP analog) and ADP was 20% and 25%, respectively. In the absence of nucleotide, this fraction increased to 40–50%. These nucleotide-induced changes in the fraction of kinesin undergoing displacement of the α-1 helix were found to be related to the fraction in which the NL undocked from the motor core. It is therefore suggested that a shift in the α-1 helix conformational equilibrium occurs upon nucleotide binding and release, and this shift controls NL docking onto the motor core.     

De-novo modeling and ESR validation of a cyanobacterial FoF1-ATP synthase subunit bb′ left-handed coiled coil

The structure and functional role of the dimeric external stalk of F_oF₁-ATP synthases have been very actively researched over the last years. To understand the function, detailed knowledge of the structure and protein packing interactions in the dimer is required. In this paper we describe the application of structural prediction and molecular modeling approaches to elucidate the structural packing interaction of the cyanobacterial ATP synthase external stalk. In addition we present biophysical evidence derived from ESR spectroscopy and site directed spin labeling of stalk proteins that supports the proposed structural model. The use of the heterodimeric bb′ dimer from a cyanobacterial ATP synthase (Synechocystis sp. PCC 6803) allowed, by specific introduction of spin labels along each individual subunit, the evaluation of the overall tertiary structure of the subunits by calculating inter-spin distances. At defined positions in both b and b′ subunits, reporter groups were inserted to determine and confirm inter-subunit packing. The experiments showed that an approximately 100 residue long section of the cytoplasmic part of the bb′-dimer exists mostly as an elongated α-helix. The distant C-terminal end of the dimer, which is thought to interact with the δ-subunit, seemed to be disordered in experiments using soluble bb′ proteins. A left-handed coiled coil packing of the dimer suggested from structure prediction studies and shown to be feasible in molecular modeling experiments was used together with the measured inter-spin distances of the inserted reporter groups determined in ESR experiments to support the hypothesis that a significant portion of the bb′ structure exists as a left-handed coiled coil.     

Residue specific partitioning of KL4 into phospholipid bilayers

KL₄, which has demonstrated success in the treatment of respiratory distress, is a synthetic helical, amphipathic peptide mimetic of lung surfactant protein B. The unusual periodicity of charged residues within KL₄ and its relatively high hydrophobicity distinguish it from canonical amphipathic helical peptides. Here we utilized site specific spin labeling of both lipids and the peptide coupled with EPR spectroscopy to discern the effects of KL₄ on lipid dynamics, the residue specific dynamics of hydrophobic regions within KL₄, and the partitioning depths of specific KL₄ residues into the DPPC/POPG and POPC/POPG lipid bilayers under physiologically relevant conditions. KL₄ induces alterations in acyl chain dynamics in a lipid-dependent manner, with the peptide partitioning more deeply into DPPC-rich bilayers. Combined with an earlier NMR study of changes in lipid dynamics on addition of KL₄ (V.C. Antharam et al., 2009), we are able to distinguish how KL₄ affects both collective bilayer motions and intramolecular acyl chain dynamics in a lipid-dependent manner. EPR power saturation results for spin labeled lipids demonstrate that KL₄ also alters the accessibility profiles of paramagnetic colliders in a lipid-dependent manner. Measurements of dynamics and depth parameters for individual spin-labeled residues within KL₄ are consistent with a model where the peptide partitions deeply into the lipid bilayers but lies parallel to the bilayer interface in both lipid environments; the depth of partitioning is dependent on the degree of lipid acyl chain saturation within the bilayer.     

Mitochondrial F1Fo-ATP Synthase: The Small Subunits e and g Associate with Monomeric Complexes to Trigger Dimerization

Mitochondrial F₁F_o-ATP synthase catalyzes the formation of ATP from ADP and inorganic phosphate. The enzyme is found in monomeric, dimeric and higher oligomeric forms in the inner mitochondrial membrane. Dimerization of ATP synthase complexes is a prerequisite for the generation of larger oligomers that promote membrane bending and formation of tubular cristae membranes. Two small proteins of the membrane-embedded F_o-domain, subunit e (Su e; Atp21) and Su g (Atp20), were identified as dimer-specific subunits of yeast ATP synthase and shown to be required for stabilization of the dimers. We have identified two distinct monomeric forms of yeast ATP synthase. Su e and Su g are present not only in the dimer but also in one of the monomeric forms. We demonstrate that Su e and Su g sequentially assemble with monomeric ATP synthase to form a dimerization-competent primed monomer. We conclude that association of Su e and Su g with monomeric F₁F_o-ATP synthase represents an initial step of oligomer formation.     

Remarkable stability of the proton translocating F1FO-ATP synthase from the thermophilic cyanobacterium Thermosynechococcus elongatus BP-1

For functional characterization, we isolated the F₁F_O-ATP synthase of the thermophilic cyanobacterium Thermosynechococcus elongatus. Because of the high content of phycobilisomes, a combination of dye-ligand chromatography and anion exchange chromatography was necessary to yield highly pure ATP synthase. All nine single F₁F_O subunits were identified by mass spectrometry. Western blotting revealed the SDS stable oligomer of subunits c in T. elongatus. In contrast to the mass archived in the database (10,141 Da), MALDI-TOF-MS revealed a mass of the subunit c monomer of only 8238 Da. A notable feature of the ATP synthase was its ability to synthesize ATP in a wide temperature range and its stability against chaotropic reagents. After reconstitution of F₁F_O into liposomes, ATP synthesis energized by an applied electrochemical proton gradient demonstrated functional integrity. The highest ATP synthesis rate was determined at the natural growth temperature of 55 °C, but even at 95 °C ATP production occurred. In contrast to other prokaryotic and eukaryotic ATP synthases which can be disassembled with Coomassie dye into the membrane integral and the hydrophilic part, the F₁F_O-ATP synthase possessed a particular stability. Also with the chaotropic reagents sodium bromide and guanidine thiocyanate, significantly harsher conditions were required for disassembly of the thermophilic ATP synthase.     

Interactions of subunits Asa2, Asa4 and Asa7 in the peripheral stalk of the mitochondrial ATP synthase of the chlorophycean alga Polytomella sp.

Mitochondrial F₁F_O-ATP synthase of chlorophycean algae is a complex partially embedded in the inner mitochondrial membrane that is isolated as a highly stable dimer of 1600 kDa. It comprises 17 polypeptides, nine of which (subunits Asa1 to 9) are not present in classical mitochondrial ATP synthases and appear to be exclusive of the chlorophycean lineage. In particular, subunits Asa2, Asa4 and Asa7 seem to constitute a section of the peripheral stalk of the enzyme. Here, we over-expressed and purified subunits Asa2, Asa4 and Asa7 and the corresponding amino-terminal and carboxy-terminal halves of Asa4 and Asa7 in order to explore their interactions in vitro, using immunochemical techniques, blue native electrophoresis and affinity chromatography. Asa4 and Asa7 interact strongly, mainly through their carboxy-terminal halves. Asa2 interacts with both Asa7 and Asa4, and also with subunit α in the F₁ sector. The three Asa proteins form an Asa2/Asa4/Asa7 subcomplex. The entire Asa7 and the carboxy-terminal half of Asa4 seem to be instrumental in the interaction with Asa2. Based on these results and on computer-generated structural models of the three subunits, we propose a model for the Asa2/Asa4/Asa7 subcomplex and for its disposition in the peripheral stalk of the algal ATP synthase.     

Comparative EPR and thermoluminescence study of anoxic photoinhibition in Photosystem II particles

Photosystem II particles were exposed to 800 W m^–2 white light at 20 °C under anoxic conditions. The F_o level of fluorescence was considerably enhanced indicating formation of stable-reduced forms of the primary quinone electron acceptor, Q_A. The F_m level of fluorescence declined only a little. The g=1.9 and g=1.82 EPR forms characteristic of the bicarbonate-bound and bicarbonate-depleted semiquinone-iron complex, Q_A ^–Fe²⁺, respectively, exhibited differential sensitivity against photoinhibition. The large g=1.9 signal was rapidly diminished but the small g=1.82 signal decreased more slowly. The S₂-state multiline signal, the oxygen evolution and photooxidation of the high potential form of cytochrome b-559 were inhibited approximately with the same kinetics as the g=1.9 signal. The low potential form of oxidized cytochrome b-559 and Signal II_slow arising from Tyr_D ⁺ decreased considerably slower than the g=1.9 semiquinone-iron signal. The high potential form of oxidized cytochrome b-559 was diminished faster than the low potential form. Photoinhibition of the g=1.9 and g=1.82 forms of Q_A was accompanied with the appearance and gradual saturation of the spin-polarized triplet signal of P 680. The amplitude of the radical signal from photoreducible pheophytin remained constant during the 3 hour illumination period. In the thermoluminescence glow curves of particles the Q band (S₂Q_A ^– charge recombination) was almost completely abolished. To the contrary, the C band (Tyr_D ⁺Q_A ^– charge recombination) increased a little upon illumination. The EPR and thermoluminescence observations suggest that the Photosystem II reaction centers can be classified into two groups with different susceptibility against photoinhibition.Abbreviations C band thermoluminescence band associated with Tyr-D⁺Q _a ^– charge recombination - Chl chlorophyll - DCMU 3-(3,4-dichlorophenyl)-1,1-dimethylurea - EPR electron paramagnetic resonance - F_o initial fluorescence - F_m maximum fluorescence - Q band thermoluminescence band originating from S₂Q _a -charge recombination - Q _a the primary quinone electron acceptor of PS II - P 680 the primary electron donor chlorophyll of PS II - S₂ oxidation state of the water-splitting system - Phe pheophytin - TL thermoluminescence - Tyr _d redox active tyrosine-160 of the D₂ protein     

Substrate-metal interactions at the active site of kidney (Na+ + K+)-ATPase characterized by Mn(II) electron paramagnetic resonance

Electron paramagnetic resonance spectra at 35 GHz of Mn²⁺ ion bound to highly purified membrane-bound (Na⁺ + K⁺)-ATPase from sheep kidney medulla are much narrower than the corresponding spectra at 9 GHz. As a result, the sensitivity of the enzyme-Mn²⁺ spectrum to added substrates is much greater at the higher frequency. ATP and AMP-PNP, which caused very little broadening at low frequency, effect dramatic decreases in intensity of the Mn²⁺ EPR signal at 35 GHz. On the other hand, virtually no changes are observed upon addition of ADP and AMP, suggesting that the γ-phosphate of ATP plays a key role in the interaction between Mn²⁺ and ATP on the enzyme. The data indicate that ATP and AMP-PNP, binding at low affinity substrate sites, induce a severe distortion of the Mn²⁺ coordination geometry. The data also support the suggestion that the enzyme-bound Mn²⁺ does not enter into a typical M²⁺-ATP complex in this system.     

Production of fully assembled and active Aquifex aeolicus F1FO ATP synthase in Escherichia coli

Background

F₁F_O ATP synthases catalyze the synthesis of ATP from ADP and inorganic phosphate driven by ion motive forces across the membrane. A number of ATP synthases have been characterized to date. The one from the hyperthermophilic bacterium Aquifex aeolicus presents unique features, i.e. a putative heterodimeric stalk. To complement previous work on the native form of this enzyme, we produced it heterologously in Escherichia coli.

Methods

We designed an artificial operon combining the nine genes of A. aeolicus ATP synthase, which are split into four clusters in the A. aeolicus genome. We expressed the genes and purified the enzyme complex by affinity and size-exclusion chromatography. We characterized the complex by native gel electrophoresis, Western blot, and mass spectrometry. We studied its activity by enzymatic assays and we visualized its structure by single-particle electron microscopy.

Results

We show that the heterologously produced complex has the same enzymatic activity and the same structure as the native ATP synthase complex extracted from A. aeolicus cells. We used our expression system to confirm that A. aeolicus ATP synthase possesses a heterodimeric peripheral stalk unique among non-photosynthetic bacterial F₁F_O ATP synthases.

Conclusions

Our system now allows performing previously impossible structural and functional studies on A. aeolicus F₁F_O ATP synthase.

General significance

More broadly, our work provides a valuable platform to characterize many other membrane protein complexes with complicated stoichiometry, i.e. other respiratory complexes, the nuclear pore complex, or transporter systems.     

Disulfide linkage in the coiled-coil domain of subunit H of A1AO ATP synthase from Methanocaldococcus jannaschii and the NMR structure of the C-terminal segment H85-104

The C-terminal residues 98-104 are important for structure stability of subunit H of A₁A_O ATP synthases as well as its interaction with subunit A. Here we determined the structure of the segment H_85-104 of H from Methanocaldococcus jannaschii, showing a helix between residues Lys90 to Glu100 and flexible tails at both ends. The helix-helix arrangement in the C-terminus was investigated by exchange of hydrophobic residues to single cysteine in mutants of the entire subunit H (H_I93C, H_L96C and H_L98C). Together with the surface charge distribution of H_85-104, these results shine light into the A-H assembly of this enzyme.     

Manipulating the Length of the <Emphasis Type="Italic">b</Emphasis> Subunit F<Subscript>1</Subscript> Binding Domain in F<Subscript>1</Subscript>F<Subscript>0</Subscript> ATP Synthase from <Emphasis Type="Italic">Escherichia coli</Emphasis>

The peripheral stalk of F₁F₀ ATP synthase is composed of a parallel homodimer of b subunits that extends across the cytoplasmic membrane in F₀ to the top of the F₁ sector. The stalk serves as the stator necessary for holding F₁ against movement of the rotor. A series of insertions and deletions have been engineered into the hydrophilic domain that interacts with F₁. Only the hydrophobic segment from {val-121} to {ala-132} and the extreme carboxyl terminus proved to be highly sensitive to mutation. Deletions in either site apparently abolished enzyme function as a result of defects is assembly of the F₁F₀ complex. Other mutations manipulating the length of the sequence between these two areas had only limited effects on enzyme function. Expression of a b subunit with insertions with as few as two amino acids into the hydrophobic segment also resulted in loss of F₁F₀ ATP synthase. However, a fully defective b subunit with seven additional amino acids could be stabilized in a heterodimeric peripheral stalk within a functional F₁F₀ complex by a normal b subunit.     

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.     

Insights into ATP Synthase Structure and Function Using Affinity and Site-Specific Spin Labeling

A variety of different approaches has been used during the last couple of decades to investigatestructure and function relationships within the catalytic portion of the F₀F₁-ATP synthase andof its interactions with the proton-translocator F₀. In our group, we employ ESR spectroscopywith the use of stable organic radicals, so-called spin labels, as reporter groups. The radicalsare either attached to substrates/ligands or specifically inserted into the protein structure bysite-specific spin labeling. Both approaches bear intrinsic advantages for their special usesand result in the specific information that is available through ESR, e.g., structural changesdue to binding of effector molecules (e.g., Mg²⁺ ions), conformational transitions duringcatalytic turnover, distance information on radicals bound at 20 Å or less, and information onthe binding characteristics of labeled substrates. This review summarizes the results of a varietyof different approaches we have used during the last years to study, with the help of ESRspectroscopy, the structure of the nucleotide binding sites of F₁-ATPases of different originsas well as interactions with F₀ subunits.