Immunochemical analysis of Micrococcus lysodeikticus (luteus) F1-ATPase and its subunits

The F₁-ATPase from Micrococcus lysodeikticus has been purified to 95% protein homogeneity in this laboratory and as all other bacterial F₁s, possesses five distinct subunits with molecular weights ranging from 60 000 to 10 000 (Huberman, M. and Salton, M.R.J. (1979) Biochim. Biophys. Acta 547, 230–240). In this communication, we demonstrate the immunochemical reactivities of antibodies to native and SDS-dissociated subunits with the native and dissociated F₁-ATPase and show that: (1) the antibodies generated to the native or SDS-dissociated subunits react with the native molecule; (2) all of the subunits comprising the F₁ are antigenically unique as determined by crossed immunoelectrophoresis and the Ouchterlony double-diffusion techniques; (3) antibodies to the SDS-denatured individual δ- and ?-subunits can be used to destabilize the interaction of these specific subunits with the rest of the native F₁; and (4) all subunit antibodies as well as anti-native F₁ were found to inhibit ATPase activity to varying degrees, the strongest inhibition being seen with antibodies to the total F₁ and anti-α- and anti-β-subunit antibodies. The interaction of specific subunit antibodies may provide a new and novel way to study further and characterize the catalytic portions of F₁-ATPases and in general may offer an additional method for the examination of multimeric proteins.     

F1-ATPase of Micrococcus lysodeikticus is not a glycoprotein

It has been claimed (Andreu, J.M., Warth, R. and Muñoz, E. (1978) FEBS Lett. 86, 1–5) that the F₁-ATPase of Micrococcus lysodeikticus is a glycoprotein containing mannose and glucose as the principal sugars. Even after extensive purification of M. lysodeikticus F₁-ATPase by DEAE-Sephadex A25 chromatography, carbohydrate contents varying from 2.7 to 10.8% have been found. Concanavalin A-reactive components corresponding to the succinylated lipomannan have been detected and separated from the ATPase in purified F₁ preparations by immunoelectrophoresis (rocket and two-dimensional) through agarose gels containing concanavalin A. Passage of the purified F₁-ATPase through concanavalin A-Sepharose 4B columns removed the carbohydrate component(s) without loss of the specific activity of the ATPase. Mannose was the only sugar detectable by gas-liquid chromatography of the F₁-ATPase before Con A-Sepharose 4B chromatography and it was completely eliminated after chromatography. No qualitative or quantitative changes in the subunit (, β, γ, δ and ε) profiles were detectable when the sodium dodecyl sulfate polyacrylamide gels were scanned by densitometry of F₁-ATPase before and after Con A-Sepharose 4B chromatography. We conclude that there is no evidence of carbohydrate covalently linked to this F₁-ATPase and that this membrane protein is not a glycoprotein. The presence of carbohydrate is attributable to contamination with lipomannan.     

Solubility characteristics of Micrococcus lysodeikticus membrane components in detergents and chaotropic salts analyzed by immunoelectrophoresis

In order to evaluate the effectiveness and selectivity of various reagents in the solubilization of bacterial membranes, membranes of Micrococcus lysodeikticus were treated with detergents and chaotropic agents. The composition of the extracts so obtained was analyzed by rocket and two-dimensional immunoelectrophoretic techniques. Recovery of succinate-, malate-, and reduced nicotinamide adenine dinucleotide- (NADH) dehydrogenases, ATPase, succinylated lipomannan and cytochromes in the extracts was measured. Treatment with a variety of non-denaturing detergents produced extracts that were generally qualitatively uniform although quantitative differences were observed. The degree of extraction of various components was correlated with the hydrophile-lipophile balance. Several chaotropic agents were also evaluated as reagents for membrane solubilization. These agents were less effective in extraction of bulk protein, but produced extracts enriched in some membrane components.     

Coupling factor activity of the purified pea mitochondrial F1-ATPase

The pea cotyledon mitochondrial F₁-ATPase was released from the submitochondrial particles by a washing procedure using 300 mM sucrose /2 mM Tricine (pH 7.4). The enzyme was purified by DEAE-cellulose chromatography and subsequent sucrose density gradient centrifugation. Using polyacrylamide gel electrophoresis under non-denaturing conditions, the purified protein exhibited a single sharp band with slightly lower mobility than the purified pea chloroplast CF₁-ATPase. The molecular weights of pea mitochondrial F₁-ATPase and pea chloroplast CF₁-ATPase were found to be 409 000 and 378 000, respectively. The purified pea mitochondrial F₁-ATPase dissociated into six types of subunits on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Most of these subunits had mobilities different from the subunits of the pea chloroplast CF₁-ATPase. The purified mitochondrial F₁-ATPase exhibited coupling factor activity. In spite of the observed differences between CF₁ and F₁, the mitochondrial enzyme stimulated ATP formation in CF₁-depleted pea chloroplast membranes. Thus, the mitochondrial F₁ was able to substitute functionally for the chloroplast CF₁ in reconstituting photophosphorylation.     

Further studies on F1-ATPase inhibition by local anesthetics

We have measured the inhibitory potencies of several local anesthetics (procaine, lidocaine, tetracaine and dibucaine) and related compounds (chlorpromazine, procainamide and propranolol) on the ATPase activities of bovine heart submitochondrial particles and purified F₁ extracted from these particles. All of these agents cause inhibition of ATPase in F₁ as well as in submitochondrial particles. A linear relationship is found between the log of the octanol/water partition coefficients and the log of the concentrations required for 50% inhibition of F₁. Sedimentation velocity ultracentrifugation and polyacrylamide gel electrophoresis showed that 1.0 mM tetracaine caused partial dissociation of the F₁ complex. Complete reversibility of the enzyme inhibitory effects was demonstrated, however. This work shows that local anesthetics can affect protein structure and enzyme activity without the mediation of lipid.     

Cation requirement for the reconstitution of oligomycin-sensitive ATPase by means of soluble F1-ATPase and F1-depleted submitochondrial particles

Bovine heart submitochondrial particles depleted of F₁ by treatment with urea (‘F₁-depleted particles’) were incubated with soluble F₁-ATPase. The binding of F₁ to the particles and the concomitant conferral of oligomycin sensitivity on the ATPase activity required the presence of cations in the incubation medium. NH⁺₄, K⁺, Rb⁺, Cs⁺, Na⁺ and Li⁺ promoted reconstitution maximally at 40–74 mM, guanidinium⁺ and Tris⁺ at 20–30 mM, and Ca²⁺ and Mg²⁺ at 3–5 mM. The particles exhibited a negative ζ-potential, as determined by microelectrophoresis, and this was neutralized by mono- and divalent cations in the same concentration range as that needed to promote F₁ binding and reconstitution of oligomycin-sensitive ATPase. It is concluded that the cations act by neutralizing negative charges on the membrane surface, mainly negatively charged phospholipids. These results are discussed in relation to earlier findings reported in the literature with F₁-depleted thylakoid membranes and with submitochondrial particles depleted of both F₁ and the coupling proteins F₆ and oligomycin sensitivity-conferring protein.     

Theoretical Analysis of the F1-ATPase Experimental Data

F₁-ATPase is a rotatory molecular motor fueled by ATP nucleotides. Different loads can be attached to the motor axis to show that it rotates in main discrete steps of 120° with substeps of ∼80° and 40°. Experimental data show the dependence on the mean rotational velocity ω with respect to the external control parameters: the nucleotide concentration [ATP] and the friction of the load γ_L. In this work we present a theoretical analysis of the experimental data whose main results are: 1), A derivation of a simple analytical formula for ω([ATP], γ_L) that compares favorably with experiments; 2), The introduction of a two-state flashing ratchet model that exhibits experimental phenomenology of a greater specificity than has been, to our knowledge, previously available; 3), The derivation of an argument to obtain the values of the substep sizes; 4), An analysis of the energy constraints of the model; and 5), The theoretical analysis of the coupling ratio between the ATP consumed and the success of a forward step. We also discuss the compatibility of our approach with recent experimental observations.     

Catalysis-Enhancement via Rotary Fluctuation of F1-ATPase

Protein conformational fluctuations modulate the catalytic powers of enzymes. The frequency of conformational fluctuations may modulate the catalytic rate at individual reaction steps. In this study, we modulated the rotary fluctuation frequency of F₁-ATPase (F₁) by attaching probes with different viscous drag coefficients at the rotary shaft of F₁. Individual rotation pauses of F₁ between rotary steps correspond to the waiting state of a certain elementary reaction step of ATP hydrolysis. This allows us to investigate the impact of the frequency modulation of the rotary fluctuation on the rate of the individual reaction steps by measuring the duration of rotation pauses. Although phosphate release was significantly decelerated, the ATP-binding and hydrolysis steps were less sensitive or insensitive to the viscous drag coefficient of the probe. Brownian dynamics simulation based on a model similar to the Sumi-Marcus theory reproduced the experimental results, providing a theoretical framework for the role of rotational fluctuation in F₁ rate enhancement.     

Classification of nucleotide binding sites on mitochondrial F1-ATPase from yeast

Methods are described to classify nucleotide binding sites of the mitochondrial coupling factor F₁ from yeast on the basis of their affinities and stability properties. High affinity sites or states for ATP and related adenine analogs and low affinity sites or states which bind a broad range of different nucleotide triphosphates are found. The results are discussed in terms of a two site, two cycle scheme, where binding of nucleotide at one site facilitates the release of nucleotide at a second site.     

On chemomechanical coupling of the F1-ATPase molecular motor

F₁-ATPase catalyzes ATP hydrolysis to drive the central γ-shaft rotating inside a hexameric cylinder composed of alternating α and β subunits. Experiments showed that the rotation of γ-shaft proceeds in steps of 120° and each 120°-rotation is composed of an 80° substep and a 40° substep. Here, based on the previously proposed models, an improved physical model for chemomechanical coupling of F₁-ATPase is presented, with which the two-substep rotation is well explained. One substep is driven by the power stroke upon ATP binding, while the other one resulted from the passage of γ-shaft from previous to next adjacent β subunits via free diffusion. Using the model, the dynamics and kinetics of F₁-ATPase, such as the rotating time of each substep, the dwell time at each pause and the rotation rate, are analytically studied. The theoretical results obtained with only three adjustable parameters reproduce the available experimental data well.     

The coupled chemomechanics of the F1-ATPase molecular motor

The enzyme F₁-ATPase is a rotary nanomotor in which the central γ subunit rotates inside the cavity made of α₃β₃ subunits. The experiments showed that the rotation proceeds in steps of 120° and each 120° step consists of 80° and 40° substeps. Here the Author proposes a stochastic wave mechanics of the F₁-ATPase motor and combines it with the structure-based kinetics of the F₁-ATPase to form a chemomechanic coupled model. The model can reproduce quantitatively and explain the experimental observations about the F₁ motor. Using the model, several rate-limited situations about γ subunit rotation are proposed, the effects of the friction and the load on the substeps are investigated and the chemomechanic coupled time during ATP hydrolysis cycle is determined.     

Origin of apparent negative cooperativity of F1-ATPase

In order to get insight into the origin of apparent negative cooperativity observed for F₁-ATPase, we compared ATPase activity and ATPMg binding of mutant subcomplexes of thermophilic F₁-ATPase, α_(W463F)3β_(Y341W)3γ and α_{(K175A/T176A/W463F)3}β_(Y341W)3γ. For α_(W463F)3β_(Y341W)3γ, apparent K_m's of ATPase kinetics (4.0 and 233 μM) did not agree with apparent K_m's deduced from fluorescence quenching of the introduced tryptophan residue (on the order of nM, 0.016 and 13 μM). On the other hand, in case of α_{(K175A/T176A/W463F)3}β_(Y341W)3γ, which lacks noncatalytic nucleotide binding sites, the apparent K_m of ATPase activity (10 μM) roughly agreed with the highest K_m of fluorescence measurements (27 μM). The results indicate that in case of α_(W463F)3β_(Y341W)3γ, the activating effect of ATP binding to noncatalytic sites dominates overall ATPase kinetics and the highest apparent K_m of ATPase activity does not represent the ATP binding to a catalytic site. In case of α_{(K175A/T176A/W463F)3}β_(Y341W)3γ, the K_m of ATPase activity reflects the ATP binding to a catalytic site due to the lack of noncatalytic sites. The Eadie-Hofstee plot of ATPase reaction by α_{(K175A/T176A/W463F)3}β_(Y341W)3γ was rather linear compared with that of α_(W463F)3β_(Y341W)3γ, if not perfectly straight, indicating that the apparent negative cooperativity observed for wild-type F₁-ATPase is due to the ATP binding to catalytic sites and noncatalytic sites. Thus, the frequently observed K_m's of 100-300 μM and 1-30 μM range for wild-type F₁-ATPase correspond to ATP binding to a noncatalytic site and catalytic site, respectively.     

The interaction of nucleotides with F1-ATPase inactivated with 4-chloro-7-nitrobenzofurazan

In common with the F₁-ATPase from other sources, yeast mitochondrial F₁-ATPase was inhibited by 4-chloro-7-nitrobenzofurazan. Total inhibition of the F₁-ATPase activity was compatible with the modification of a single tyrosine residue per F₁-ATPase molecule. Radioactive labelling experiments localized this modification on a β-subunit. The inactive modified enzyme retained the capacity to bind the photoaffinity label 8-azido-1,N⁶-etheno-ATP, which has previously been shown to bind nucleotide sites of low affinity. As well, the inactive modified enzyme bound MgATP with high affinity, yielding a K_d of 14 μM. The results are consistent with the hypothesis of alternating, or cooperative, site catalysis by F₁-ATPase.     

Stimulation of F1-ATPase activity by sodium dodecyl sulfate

F₁-ATPase is a rotary molecular motor in which the γ subunit rotates inside the cylinder made of α₃β₃ subunits. We have studied the effects of sodium dodecyl sulfate (SDS) on the rotational and ATP hydrolysis activities of F₁-ATPase. Bulk hydrolysis activity at various SDS concentrations was examined at 2 mM ATP. Maximal stimulation was obtained at 0.003% (w/v) SDS, the initial (least inhibited) activity being about 1.4 times and the steady-state activity 3-4 times the values in the absence of SDS. Rotation rates observed with a 40-nm gold bead or a 0.29-μm bead duplex as well as the torque were unaffected by the presence of 0.003% SDS. The fraction of beads that rotated, in contrast, tended to increase in the presence of SDS. SDS seems to bring inactive F₁ molecules into an active form but it does not alter or enhance the function of already active F₁ molecules significantly.     

Torque Generation Mechanism of F1-ATPase upon NTP Binding

Molecular machines fueled by NTP play pivotal roles in a wide range of cellular activities. One common feature among NTP-driven molecular machines is that NTP binding is a major force-generating step among the elementary reaction steps comprising NTP hydrolysis. To understand the mechanism in detail,in this study, we conducted a single-molecule rotation assay of the ATP-driven rotary motor protein F₁-ATPase using uridine triphosphate (UTP) and a base-free nucleotide (ribose triphosphate) to investigate the impact of a pyrimidine base or base depletion on kinetics and force generation. Although the binding rates of UTP and ribose triphosphate were 10³ and 10⁶ times, respectively, slower than that of ATP, they supported rotation, generating torque comparable to that generated by ATP. Affinity change of F₁ to UTP coupled with rotation was determined, and the results again were comparable to those for ATP, suggesting that F₁ exerts torque upon the affinity change to UTP via rotation similar to ATP-driven rotation. Thus, the adenine-ring significantly enhances the binding rate, although it is not directly involved in force generation. Taking into account the findings from another study on F₁ with mutated phosphate-binding residues, it was proposed that progressive bond formation between the phosphate region and catalytic residues is responsible for the rotation-coupled change in affinity.     

Studies of the nucleotide-binding sites on the mitochondrial F1-ATPase through the use of a photoactivable derivative of adenylyl imidodiphosphate

(1) $\text{N-4-}\text{Azido}\text{-2-}\text{nitrophenyl}\text{-γ-[}{}^3\text{H]aminobutyryl-Ado}\text{PP[}\text{NH}\text{]P(}\text{NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P)}$ a photoactivable derivative of 5-adenylyl imidodiphosphate (AdoPP[NH]P), was synthesized. (2) Binding of ³H]NAP₄-AdoPP[NH]P to soluble ATPase from beef heart mitochrondria (F₁) was studied in the absence of photoirradiation, and compared to that of $\text{[}{}^3\text{H]Ado}\text{PP[}\text{NH}\text{]P}$. The photoactivable derivative of AdoPP[NH]P was found to bind to F₁ with high affinity, like AdoPP[NH]P. Once $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}$ had bound to F₁ in the dark, it could be released by AdoPP[NH]P, ADP and ATP, but not at all by NAP₄ or AMP. Furthermore, preincubation of F₁ with unlabeled AdoPP[NH]P, ADP, or ATP prevented the covalent labeling of the enzyme by $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}$ upon photoirradiation. (3) Photoirradiation of F₁ by $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}$ resulted in covalent photolabeling and concomitant inactivation of the enzyme. Full inactivation corresponded to the binding of about 2 mol $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}\text{mol F}{}_1$. Photolabeling by NAP₄-AdoPP[NH]P was much more efficient in the presence than in the absence of MgCl₂. (4) Bound $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}$ was localized on the α- and β-subunits of F₁. At low concentrations (less than 10 μM), bound $\text{[}{}^3\text{H]NAP}{}_4\text{-}\text{Ado}\text{PP[}\text{NH}\text{]P}$ was predominantly localized on the α-subunit; at concentrations equal to, or greater than 75 μM, both α- and β-subunits were equally labeled. (5) The extent of inactivation was independent of the nature of the photolabeled subunit (α or β), suggesting that each of the two subunits, α and β, is required for the activity of F₁. (6) The covalently photolabeled F₁ was able to form a complex with aurovertin, as does native F₁. The ADP-induced fluorescence enhancement was more severely inhibited than the fluorescence quenching caused by ATP. The percentage of inactivation of F₁ was virtually the same as the percentage of inhibition of the ATP-induced fluorescence quenching, suggesting that fluorescence quenching is related to the binding of ATP to the catalytic site of F₁.     

Isolation and characterization of a mannan from mesosomal membrane vesicles of Micrococcus lysodeikticus

The carbohydrate content of mesosomal membranes of Micrococcus lysodeikticus has been shown to be consistently higher (about four times) than that of corresponding plasma membrane preparations. Analysis of washed membrane fractions by gas-liquid chromatography indicated that mannose was the major neutral sugar of both types of membrane (accounting for 95 and 89%, respectively, of the mesosomal and plasma membrane carbohydrate). Small amounts of inositol, glucose and ribose were also detected.We have shown by polyacrylamide gel electrophoresis in sodium dodecylsulphate and by precipitation and agar gel diffusion experiments with concanavalin A that a mannan is the major carbohydrate component of both types of membrane. This polymer can be selectively released from mesosomal membranes by a simple procedure involving low ionic strength-shock and heating to 80°C for 1 min, and purified by ultrafiltration and ethanol precipitation.The mannan contains mannose as the only neutral carbohydrate, is not phosphorylated and does not contain significant amounts of amino sugars or uronic acids. Agar gel electrophoresis experiments, however, indicate an anionic polymer whose acidic properties are eliminated upon mild base hydrolysis. Analysis of native mannan by infrared spectroscopy reveals absorption bands attributable to ester carbonyl groups and to carboxylate ions, consistent with the presence of succinyl residues in the polymer (Owen, P. and Salton, M.R.J. (1975) Biochem. Biophys. Res. Commun. 63, 875–880).A sedimentation coefficient of 1.39 S was obtained by analytical ultracentrifugation in 1.0 M NaCl and a value of one reducing equivalent per 50 mannose residues by reduction with NaB³H₄. The polysaccharide was only slightly degraded (2%) by jack bean α-mannosidase and could precipitate 15 times its own weight of concanavalin A.The acidic polymer was also detected in the cell “periplasm” and was secreted from cells grown in defined media during the period of decelerating growth.     

Stoichiometry of the oligomycin-sensitivity-conferring protein (OSCP) in the mitochondrial F0F1-ATPase determined by an immunoelectrotransfer blot technique

The ratio between the amount of oligomycin-sensitivity-conferring protein (OSCP) and the amount of the and β subunits of F₁-ATPase in the mitochondria has been determined by a method combining electrophoresis, electrotransfer and immunotitration with monoclonal antibodies. The peptides separated in SDS-polyacrylamide gel electrophoresis were blotted to nitrocellulose sheets by electrotransfer. The nitrocellulose sheets were incubated with ¹²⁵I-labelled purified monoclonal antibodies specific to various peptides. The ¹²⁵I-labelled immune complexes were located by immunodecoration using peroxidase-conjugated second antibodies and the blotted peptides were revealed with H₂O₂ and -naphthol. The amount of immune complex present on the nitrocellulose was determined by counting the radioactivity present on the spots. The amount of peptide blotted is directly proportional to the amount of protein loaded on the electrophoresis. By comparing standard curves made with the isolated proteins to the values obtained in the presence of various amounts of the membrane-protein complex, one can calculate the content of this peptide in the membrane. It was found that the mitochondrial membrane contains 2 mol of OSCP per mol of F₁.