Site-directed mutagenesis of stable adenosine triphosphate synthase

Hepatic protein Carbonylation profiles induced by lipid accumulation and oxidative stress for investigating cellular response to non-alcoholic fatty liver disease in vitro

BACKGROUND

Non-alcoholic fatty liver disease (NAFLD) is caused by excessive accumulation of fat within the liver, leading to further severe conditions such as non-alcoholic steatohepatitis (NASH). Progression of healthy liver to steatosis and NASH is not yet fully understood in terms of process and response. Hepatic oxidative stress is believed to be one of the factors driving steatosis to NASH. Oxidative protein modification is the major cause of protein functional impairment in which alteration of key hepatic enzymes is likely to be a crucial factor for NAFLD biology. In the present study, we aimed to discover carbonylated protein profiles involving in NAFLD biology in vitro.

METHODS

Hepatocyte cell line was used to induce steatosis with fatty acids (FA) in the presence and absence of menadione (oxidative stress inducer). Two-dimensional gel electrophoresis-based proteomics and dinitrophenyl hydrazine derivatization technique were used to identify carbonylated proteins. Sequentially, in order to view changes in protein carbonylation pathway, enrichment using Funrich algorithm was performed. The selected carbonylated proteins were validated with western blot and carbonylated sites were further identified by high-resolution LC-MS/MS.

RESULTS

Proteomic results and pathway analysis revealed that carbonylated proteins are involved in NASH pathogenesis pathways in which most of them play important roles in energy metabolisms. Particularly, carbonylation level of ATP synthase subunit α (ATP5A), a key protein in cellular respiration, was reduced after FA and FA with oxidative stress treatment, whereas its expression was not altered. Carbonylated sites on this protein were identified and it was revealed that these sites are located in nucleotide binding region. Modification of these sites may, therefore, disturb ATP5A activity. As a consequence, the lower carbonylation level on ATP5A after FA treatment solely or with oxidative stress can increase ATP production.

CONCLUSIONS

The reduction in carbonylated level of ATP5A might occur to generate more energy in response to pathological conditions, in our case, fat accumulation and oxidative stress in hepatocytes. This would imply the association between protein carbonylation and molecular response to development of steatosis and NASH.

A novel multigene cloning method for the production of a motile ATPase

With the advent of nanotechnology, new functional modules (e.g., nanomotors, nanoprobes) have become essential in several medical fields. Generally, mechanical modulators systems are the principal components of most cutting-edge technologies in modern biomedical applications. However, the in vivo use of motile probes has raised many concerns due to their low sensitivity and non-biocompatibility. As an alternative, biological enzymatic engines have received increased attention. In particular, ATPases, which belong to a class of motile enzymes that catalyze chemical metabolic reactions, have emerged as a promising motor due to their improved biocompatibility and performance. However, ATPases usually suffer from lower functional activity and are difficult to express recombinantly in bacteria relative to their conventional and synthetic competitors. Here, we report a novel functional modified ATPase with both a simple purification protocol and enhanced motile activity. For this mutant ATPase, a new bacterial subcloning method was established. The ATPase-encoding sequence was redesigned so that the mutant ATPase could be easily produced in an Escherichia coli system. The modified thermophilic F1-ATPase (mTF1-ATPase) demonstrated 17.8unit/mg ATPase activity. We propose that derivatives of our ATPase may enable the development of novel in vitro and in vivo synthetic medical diagnostics, as well as therapeutics.

ATP synthase: from single molecule to human bioenergetics

ATP synthase (F(o)F(1)) consists of an ATP-driven motor (F(1)) and a H(+)-driven motor (F(o)), which rotate in opposite directions. F(o)F(1) reconstituted into a lipid membrane is capable of ATP synthesis driven by H(+) flux. As the basic structures of F(1) (alpha(3)beta(3)gammadeltaepsilon) and F(o) (ab(2)c(10)) are ubiquitous, stable thermophilic F(o)F(1) (TF(o)F(1)) has been used to elucidate molecular mechanisms, while human F(1)F(o) (HF(1)F(o)) has been used to study biomedical significance. Among F(1)s, only thermophilic F(1) (TF(1)) can be analyzed simultaneously by reconstitution, crystallography, mutagenesis and nanotechnology for torque-driven ATP synthesis using elastic coupling mechanisms. In contrast to the single operon of TF(o)F(1), HF(o)F(1) is encoded by both nuclear DNA with introns and mitochondrial DNA. The regulatory mechanism, tissue specificity and physiopathology of HF(o)F(1) were elucidated by proteomics, RNA interference, cytoplasts and transgenic mice. The ATP synthesized daily by HF(o)F(1) is in the order of tens of kilograms, and is primarily controlled by the brain in response to fluctuations in activity.

The alpha/beta interfaces of alpha(1)beta(1), alpha(3)beta(3), and F1: domain motions and elastic energy stored during gamma rotation

ATP synthase (F(o)F(1)) consists of F(1) (ATP-driven motor) and F(o) (H(+)-driven motor). F(1) is a complex of alpha(3)beta(3)gammadeltaepsilon subunits, and gamma is the rotating cam in alpha(3)beta(3). Thermophilic F(1) (TF(1)) is exceptional in that it can be crystallized as a beta monomer and an alpha(3)beta(3) oligomer, and it is sufficiently stable to allow alphabeta refolding and reassembly of hybrid complexes containing 1, 2, and 3 modified alpha or beta. The nucleotide-dependent open-close conversion of conformation is an inherent property of an isolated beta and energy and signals are transferred through alpha/beta interfaces. The catalytic and noncatalytic interfaces of both mitochondrial F(1) (MF(1)) and TF(1) were analyzed by an atom search within the limits of 0.40 nm across the alphabeta interfaces. Seven (plus thermophilic loop in TF(1)) contact areas are located at both the catalytic and noncatalytic interfaces on the open beta form. The number of contact areas on closed beta increased to 11 and 9, respectively, in the catalytic and noncatalytic interfaces. The interfaces in the barrel domain are immobile. The torsional elastic strain applied through the mobile areas is concentrated in hinge residues and the P-loop in beta. The notion of elastic energy in F(o)F(1) has been revised. X-ray crystallography of F(1) is a static snap shot of one state and the elastic hypotheses are still inconsistent with the structure, dyamics, and kinetics of F(o)F(1). The domain motion and elastic energy in F(o)F(1) will be elucidated by time-resolved crystallography.

Vanadyl as a probe of the function of the F1-ATPase-Mg2+ cofactor

The Mg2+ dependent asymmetry of the F(1)-ATPase catalytic sites leads to the differences in affinity for nucleotides and is an essential component of the binding-change mechanism. Changes in metal ligands during the catalytic cycle responsible for this asymmetry were characterized by vanadyl (V(IV) + O)2+, a functional surrogate for Mg2+. The (51)V-hyperfine parameters derived from EPR spectra of VO2+ bound to specific sites on F(1) provide a direct probe of the metal ligands. Site-directed mutations of metal ligand residues cause measurable changes in the (51)V-hyperfine parameters of the bound VO2+, thereby providing a means to identification. Initial binding of the metal-nucleotide to the low-affinity catalytic site conformation results in metal coordination by hydroxyl groups from the P-loop threonine and catch-loop threonine. Upon conversion to the high-affinity conformation, carboxyl groups from the Walker homology B aspartate and MF(1)betaE197 become ligands in lieu of the hydroxyl groups.

Structural insight into the cooperativity between catalytic and noncatalytic sites of F1-ATPase

F1-ATPase, the catalytic sector of Fo-F1 ATPases-ATPsynthases, displays an apparent negative cooperativity for ATP hydrolysis at high ATP concentrations which involves noncatalytic and catalytic nucleotide binding sites. The molecular mechanism of such cooperativity is currently unknown. To get further insights, we have investigated the structural consequences of the single mutation of two residues: Q173L in the alpha-subunit and Q170Y in the beta-subunit of the F1-ATPase of the yeast Schizosaccharomyces pombe. These residues are localized in or near the Walker-A motifs of each subunit and their mutation produces an opposite effect on the negative cooperativity. The betaQ170 residue (M167 in beef heart) is located close to the binding site for the phosphate-Mg moiety of the nucleotide. Its replacement by tyrosine converts this site into a close state with increased affinity for the bound nucleotide and leads to an increase of negative cooperativity. In contrast, the alphaQ173L mutation (Q172 in beef heart) abolishes negative cooperativity due to the loss of two H-bonds: one stabilizing the nucleotide bound to the noncatalytic site and the other linking alphaQ173 to the adjacent betaT354, localized at the alpha(DP)-beta(TP) interface. The properties of these mutants suggest that negative cooperativity occurs through interactions between neighbor alpha- and beta-subunits. Indeed, in the beef heart enzyme, (i) the alpha(DP)-beta(TP) interface is stabilized by a vicinal alphaR171-betaD352 salt bridge (ii) betaD352 and betaT354 belong to a short peptidic stretch close to betaY345, the aromatic group of which interacts with the adenine moiety of the nucleotide bound to the catalytic site. We therefore propose that the betaY345-betaT354 stretch (beef heart numbering) constitutes a short link that drives structural modifications from a noncatalytic site to the neighbor catalytic site in which, as a result, the affinity for ADP is modulated.

Assembled F1-(alpha beta ) and Hybrid F1-alpha 3beta 3gamma -ATPases from Rhodospirillum rubrum alpha, wild type or mutant beta, and chloroplast gamma subunits. Demonstration of Mg2+versus Ca2+-induced differences in catalytic site structure and function

Refolding together the expressed alpha and beta subunits of the Rhodospirillum rubrum F(1)(RF(1))-ATPase led to assembly of only alpha(1)beta(1) dimers, showing a stable low MgATPase activity. When incubated in the presence of AlCl(3), NaF and either MgAD(T)P or CaAD(T)P, all dimers associated into closed alpha(3)beta(3) hexamers, which also gained a low CaATPase activity. Both hexamer ATPase activities exhibited identical rates and properties to the open dimer MgATPase. These results indicate that: a) the hexamer, as the dimer, has no catalytic cooperativity; b) aluminium fluoride does not inhibit their MgATPase activity; and c) it does enable the assembly of RrF(1)-alpha(3)beta(3) hexamers by stabilizing their noncatalytic alpha/beta interfaces. Refolding of the RrF(1)-alpha and beta subunits together with the spinach chloroplast F(1) (CF(1))-gamma enabled a simple one-step assembly of two different hybrid RrF(1)-alpha(3)beta(3)/CF(1)gamma complexes, containing either wild type RrF(1)-beta or the catalytic site mutant RrF(1)beta-T159S. They exhibited over 100-fold higher CaATPase and MgATPase activities than the stabilized hexamers and showed very different catalytic properties. The hybrid wild type MgATPase activity was, as that of RrF(1) and CF(1) and unlike its higher CaATPase activity, regulated by excess free Mg(2+) ions, stimulated by sulfite, and inhibited by azide. The hybrid mutant had on the other hand a low CaATPase but an exceptionally high MgATPase activity, which was much less sensitive to the specific MgATPase effectors. All these very different ATPase activities were regulated by thiol modulation of the hybrid unique CF(1)-gamma disulfide bond. These hybrid complexes can provide information on the as yet unknown factors that couple ATP binding and hydrolysis to both thiol modulation and rotational motion of their CF(1)-gamma subunit.

The participation of metals in the mechanism of the F(1)-ATPase

The Mg(2+) cofactor of the F(1)F(0) ATP synthase is required for the asymmetry of the catalytic sites that leads to the differences in affinity for nucleotides. Vanadyl (V(IV)=O)(2+) is a functional surrogate for Mg(2+) in the F(1)-ATPase. The (51)V-hyperfine parameters derived from EPR spectra of VO(2+) bound to specific sites on the enzyme provide a direct probe of the metal ligands at each site. Site-directed mutations of residues that serve as metal ligands were found to cause measurable changes in the (51)V-hyperfine parameters of the bound VO(2+), thereby providing a means by which metal ligands were identified in the functional enzyme in several conformations. At the low-affinity catalytic site comparable to beta(E) in mitochondrial F(1), activation of the chloroplast F(1)-ATPase activity induces a conformational change that inserts the P-loop threonine and catch-loop tyrosine hydroxyl groups into the metal coordination sphere thereby displacing an amino group and the Walker homology B aspartate. Kinetic evidence suggests that coordination of this tyrosine by the metal when the empty site binds substrate may provide an escapement mechanism that allows the gamma subunit to rotate and the conformation of the catalytic sites to change, thereby allowing rotation only when the catalytic sites are filled. In the high-affinity conformation analogous to the beta(DP) site of mitochondrial F(1), the catch-loop tyrosine has been displaced by carboxyl groups from the Walker homology B aspartate and from betaE197 in Chlamydomonas CF(1). Coordination of the metal by these carboxyl groups contributes significantly to the ability of the enzyme to bind the nucleotide with high affinity.

Metal ligation by Walker homology B aspartate betaD262 at site 3 of the latent but not activated form of the chloroplast F(1)-ATPase from Chlamydomonas reinhardtii

Site-directed mutations D262C, D262H, D262N, and D262T were made to the beta subunit Walker Homology B aspartate of chloroplast F(1)-ATPase in Chlamydomonas. Photoautotrophic growth and photophosphorylation rates were 3-14% of wild type as were ATPase activities of purified chloroplast F(1) indicating that betaD262 is an essential residue for catalysis. The EPR spectrum of vanadyl bound to Site 3 of chloroplast F(1) as VO(2+)-ATP gave rise to two EPR species designated B and C in wild type and mutants. (51)V-hyperfine parameters of species C, present exclusively in the activated enzyme state, did not change significantly by the mutations examined indicating that it is not an equatorial ligand to VO(2+), nor is it hydrogen-bonded to a coordinated water at an equatorial position. Every mutation changed the ratio of EPR species C/B and/or the (51)V-hyperfine parameters of species B, the predominant conformation of VO(2+)-nucleotide bound to Site 3 in the latent (down-regulated) state. The results indicate that the Walker Homology B aspartate coordinates the metal of the predominant metal-nucleotide conformation at Site 3 in the latent state but not in the conformation present exclusively upon activation and elucidates one of the specific changes in metal ligation involved with activation.

Functional conformation changes in the TF(1)-ATPase beta subunit probed by 12 tyrosine residues

The effect of nucleotide binding on the structure of the F(1)-ATPase beta subunit from thermophilic bacillus PS-3 (TF(1)beta) was investigated by monitoring the NMR signals of the 12 tyrosine residues. The 3,5-proton resonances of 12 tyrosine residues could be observed for the specifically deuterated beta subunit. The assignment of 3,5-proton resonances of all of the tyrosine residues was accomplished using 14 mutant proteins, in each of which one or two tyrosine residues were replaced by phenylalanine. Binding of Mg. ATP induced an upfield shift of Tyr(341) resonance, suggesting that their aromatic rings are stacked to each other. Besides Tyr(341), the signal shift observed on Mg.ATP binding was restricted to the resonances of Tyr(148), Tyr(199), Tyr(238), and Tyr(307), suggesting that Mg.ATP induces a conformational change in the hinge region. This can be correlated to the change from the open to closed conformations as implicated in the crystal structure. Mg.ADP induced a similar but distinctly different conformational change. Therefore, the intrinsic conformational change in the beta subunit induced by the nucleotide binding is proposed to be one of the essential driving forces for the F(1) rotation. Reconstitution experiments showed that Tyr(277), one of the four conserved tyrosines, is essential to the formation of the alpha(3)beta(3)gamma complex.

Biophysical studies on ATP synthase

The isolation of ATP synthase (F0F1) (82) and F0 (83) 34 years ago finally revealed that F0F1 is a motor composed of F0 (ion-motor, abc subunits) and F1 (ATP-motor, alpha 3 beta 3 gamma delta epsilon subunits) (Fig. 1). The single molecule videotape (4, 5, 65, 66) revealed that gamma epsilon axis of F1 rotates counterclockwise, proceeds by each 2 pi/3 step, and is driven by torque of 42 pN.nm (12) with nearly 100% efficiency (5) (Fig. 4). The motor is composed of a rotor (gamma epsilon-F0-c) and a stator (alpha 3 beta 3 delta-F0-ab), and the rotor is connected to a shaft (gamma epsilon). Since F0F1 is driven by delta microH+ (9, 10, 84), biophysical studies on stable TF0F1 (1, 7) are essential to elucidate the mechanism. These include nanomechanics (4, 5) (Fig. 4), crystallography (2, 3) (Figs. 2 and 3), NMR (51, 52), ESR (56), synchrotron analysis (3, 28), and electrophysiology (10, 25). The KmATP value of rotation is 0.8 microM, with the Vmax of 3.9 rps (5). This corresponds to the bi-site catalysis in proton transport by F0F1 (10, 70, 84). X-ray crystallography of MF1 (2) and the alpha 3 beta 3 oligomer of TF1 (3) (Fig. 2) together with mutation analyses revealed the role of residues in the rotation. The idea of elastic energy store is proposed in alpha 3 beta 3 gamma during the stepping time (up to a few sec) after the ATP binding. Biological studies have partially clarified the genetic and kinetic regulation of the rotation in MF1. Both theories (6, 7, 62, 64, 85) and the biological significance (17) of the intramolecular rotation of F0F1 await further studies, especially those of F0 and minor subunits.

MgATP binding and hydrolysis determinants of NtrC, a bacterial enhancer-binding protein

When phosphorylated, the dimeric form of nitrogen regulatory protein C (NtrC) of Salmonella typhimurium forms a larger oligomer(s) that can hydrolyze ATP and hence activate transcription by the sigma(54)-holoenzyme form of RNA polymerase. Studies of Mg-nucleoside triphosphate binding using a filter-binding assay indicated that phosphorylation is not required for nucleotide binding but probably controls nucleotide hydrolysis per se. Studies of binding by isothermal titration calorimetry indicated that the apparent K(d) of unphosphorylated NtrC for MgATPgammaS is 100 microM at 25 degrees C, and studies by filter binding indicated that the concentration of MgATP required for half-maximal binding is 130 microM at 37 degrees C. Filter-binding studies with mutant forms of NtrC defective in ATP hydrolysis implicated two regions of its central domain directly in nucleotide binding and three additional regions in hydrolysis. All five are highly conserved among activators of sigma(54)-holoenzyme. Regions implicated in binding are the Walker A motif and the region around residues G355 to R358, which may interact with the nucleotide base. Regions implicated in nucleotide hydrolysis are residues S207 and E208, which have been proposed to lie in a region analogous to the switch I effector region of p21(ras) and other purine nucleotide-binding proteins; residue R294, which may be a catalytic residue; and residue D239, which is the conserved aspartate in the putative Walker B motif. D239 appears to play a role in binding the divalent cation essential for nucleotide hydrolysis. Electron paramagnetic resonance analysis of Mn(2+) binding indicated that the central domain of NtrC does not bind divalent cation strongly in the absence of nucleotide.

Intramolecular rotation in ATP synthase: dynamic and crystallographic studies on thermophilic F1

A single molecule of ATP synthase (F0F1) is by itself a rotary motor, the smallest ever found, and this biomotor is driven by an electrochemical potential of H+ (delta microH+). F0F1 is composed of an ion-conducting portion (F0) and a catalytic portion (F1). The major breakthroughs in studies on the mechanochemical coupling have been the direct observation of the rotation of a stable alpha 3 beta 3 gamma complex of thermophilic F1 (TF1), and X-ray crystallography of the alpha 3 beta 3 gamma portion of mitochondrial F1 (MF1) and the alpha 3 beta 3 oligomer of TF1. This review focuses on the dynamics of TF1, demonstrated by a crucial experiment. The torque of the rotation was estimated to be 42 pN.nm from the delta microH+ and frictional force. Important unsolved problems are the crystallography of F0, elastic energy conversion, and the stator and rotor of this biomotor.

The crystal structure of the nucleotide-free alpha 3 beta 3 subcomplex of F1-ATPase from the thermophilic Bacillus PS3 is a symmetric trimer

BACKGROUND

F1-ATPase, an oligomeric assembly with subunit stoichiometry alpha 3 beta 3 gamma delta epsilon, is the catalytic component of the ATP synthase complex, which plays a central role in energy transduction in bacteria, chloroplasts and mitochondria. The crystal structure of bovine mitochondrial F1-ATPase displays a marked asymmetry in the conformation and nucleotide content of the catalytic beta subunits. The alpha 3 beta 3 subcomplex of F1-ATPase has been assembled from subunits of the moderately thermophilic Bacillus PS3 made in Escherichia coli, and the subcomplex is active but does not show the catalytic cooperativity of intact F1-ATPase. The structure of this subcomplex should provide new information on the conformational variability of F1-ATPase and may provide insights into the unusual catalytic mechanism employed by this enzyme.

RESULTS

The crystal structure of the nucleotide-free bacterial alpha 3 beta 3 subcomplex of F1-ATPase, determined at 3.2 A resolution, shows that the oligomer has exact threefold symmetry. The bacterial beta subunits adopt a conformation essentially identical to that of the nucleotide-free beta subunit in mitochondrial F1-ATPase; the alpha subunits have similar conformations in both structures.

CONCLUSIONS

The structures of the bacterial F1-ATPase alpha and beta subunits are very similar to their counterparts in the mitochondrial enzyme, suggesting a common catalytic mechanism. The study presented here allows an analysis of the different conformations adopted by the alpha and beta subunits and may ultimately further our understanding of this mechanism.

Catalytic mechanism of F1-ATPase

The structure of the core catalytic unit of ATP synthase, alpha 3 beta 3 gamma, has been determined by X-ray crystallography, revealing a roughly symmetrical arrangement of alternating alpha and beta subunits around a central cavity in which helical portions of gamma are found. A low-resolution structural model of F0, based on electron spectroscopic imaging, locates subunit a and the two copies of subunit b outside of a subunit c oligomer. The structures of individual subunits epsilon and c (largely) have been solved by NMR spectroscopy, but the oligomeric structure of c is still unknown. The structures of subunits a and delta remain undefined, that of b has not yet been defined but biochemical evidence indicates a credible model. Subunits gamma, epsilon, b, and delta are at the interface between F1 and F0; gamma epsilon complex forms one element of the stalk, interacting with c at the base and alpha and beta at the top. The locations of b and delta are less clear. Elucidation of the structure F0, of the stalk, and of the entire F1F0 remains a challenging goal.

Catalytic activity of the alpha3beta3gamma complex of F1-ATPase without noncatalytic nucleotide binding site

A mutant alpha3beta3gamma complex of F1-ATPase from thermophilic Bacillus PS3 was generated in which noncatalytic nucleotide binding sites lost their ability to bind nucleotides. It hydrolyzed ATP at an initial rate with cooperative kinetics (Km(1), 4 microM; Km(2), 135 microM) similar to the wild-type complex. However, the initial rate decayed rapidly to an inactivated form. Since the inactivated mutant complex contained 1.5 mol of ADP/mol of complex, this inactivation seemed to be caused by entrapping inhibitory MgADP in a catalytic site. Indeed, the mutant complex was nearly completely inactivated by a 10 min prior incubation with equimolar MgADP. Analysis of the progress of inactivation after initiation of ATP hydrolysis as a function of ATP concentration indicated that the inactivation was optimal at ATP concentrations in the range of Km(1). In the presence of ATP, the wild-type complex dissociated the inhibitory [3H]ADP preloaded onto a catalytic site whereas the mutant complex did not. Lauryl dimethylamineoxide promoted release of preloaded inhibitory [3H]ADP in an ATP-dependent manner and partly restored the activity of the inactivated mutant complex. Addition of ATP promoted single-site hydrolysis of 2',3'-O-(2,4,6-trinitrophenyl)-ATP preloaded at a single catalytic site of the mutant complex. These results indicate that intact noncatalytic sites are essential for continuous catalytic turnover of the F1-ATPase but are not essential for catalytic cooperativity of F1-ATPase observed at ATP concentrations below approximately 300 microM.

The alpha3beta3gamma subcomplex of the F1-ATPase from the thermophilic bacillus PS3 with the betaT165S substitution does not entrap inhibitory MgADP in a catalytic site during turnover

The hydrolytic properties of the mutant alpha3(betaT165S)3gamma and wild-type alpha3beta3gamma subcomplexes of TF1 have been compared. Whereas the wild-type complex hydrolyzes 50 microM ATP in three kinetic phases, the mutant complex hydrolyzes 50 microM ATP with a linear rate. After incubation with a slight excess of ADP in the presence of Mg2+, the wild-type complex hydrolyzes 2 mM ATP with a long lag. In contrast, prior incubation of the mutant complex under these conditions does not affect the kinetics of ATP hydrolysis. The ATPase activity of the wild-type complex is stimulated 4-fold by 0. 1% lauryl dimethylamine oxide, whereas this concentration of lauryl dimethylamine oxide inhibits the mutant complex by 25%. Compared with the wild-type complex, the activity of the mutant complex is much less sensitive to turnover-dependent inhibition by azide. This comparison suggests that the mutant complex does not entrap substantial inhibitory MgADP in a catalytic site during turnover, which is supported by the following observations. ATP hydrolysis catalyzed by the wild-type complex is progressively inhibited by increasing concentrations of Mg2+ in the assay medium, whereas the mutant complex is insensitive to increasing concentrations of Mg2+. A Lineweaver-Burk plot constructed from rates of hydrolysis of 20-2000 microM ATP by the wild-type complex is biphasic, exhibiting apparent Km values of 30 microM and 470 microM with corresponding kcat values of 26 and 77 s-1. In contrast, a Lineweaver-Burk plot for the mutant complex is linear in this range of ATP concentration, displaying a Km of 133 microM and a kcat of 360 s-1.

Binding sites for Mg(II) in H(+)-ATPase from Bacillus PS3 and in the alpha 3 beta 3 gamma subcomplex studied by one-dimensional ESEEM and two-dimensional HYSCORE spectroscopy of oxovanadium(IV) complexes: a possible role for beta-His-324

The binding sites for Mg2+ in wild type F1 ATPase (TF1) and in the alpha 3 beta 3 gamma subcomplex from the thermophilic bacterium Bacillus PS3 have been studied by EPR and by ESEEM and HYSCORE spectroscopy of complexes with the oxovanadium cation VO2+. Complexes of metal-depleted TF1 and substoichiometric amounts of VO2+ display low-temperature EPR signals with spectral parameters g parallel = 1.947 and g perpendicular = 1.980, and hyperfine couplings with 51V, A parallel = 169 x 10(-4) cm-1 and A perpendicular = 61 x 10(-4) cm-1, that are indicative of a binding site for VO2+ with nitrogen ligands from the protein. This binding site is probably identical with the metal binding site with strong affinity M1 that has been characterized using Mn2+ in a previous study [Buy, C., Girault, G., & Zimmermann, J. L. (1996) Biochemistry 35, 9880-9891]. The three-pulse ESEEM spectrum of the VO2+ complex with TF1 shows a frequency pattern with spectral properties that are evidence for two nitrogen ligands to the VO2+ with hyperfine couplings A1 = 4.75 MHz and A2 = 6.5 MHz and nuclear quadrupole parameters e2Qq1 = 2.8-3.2 MHz and e2Qq2 = 2.0-2.3 MHz. The ligands are identified as a lysine terminal amine and a histidine imidazole, which are proposed as Lys-164 and His-324 from a beta subunit. The HYSCORE data obtained for the VO.TF1 complex show correlations within each pair of the ESEEM nu dq peaks from the 14N nuclei, confirming the interpretation of the one-dimensional spectra. Evidence for the formation of a ternary complex by addition of VO2+ and ATP to metal-depleted TF1 is shown in the EPR and ESEEM spectra and in the contour plots of the HYSCORE data. Two pairs of correlation patterns are resolved in addition to the peaks from the two 14N ligands, which are interpreted as hyperfine couplings with 31P beta and 31P gamma of the ATP that binds the VO2+ cation. The assignment of the two hyperfine couplings to the specific phosphates, A(31P beta) = 15.5 MHz and A(31P gamma) = 8.7 MHz, in the VO.TF1.ATP complex is proposed by comparison with those measured for VO2+ in solution with ATP at pH 6.3 and 2.3. These results are discussed in light of the previous data with the analogous Mn.TF1 complex, and a model is proposed in which the native Mg2+ in the M1 site is coordinated by the side chain of beta-Lys-164 and is in close proximity to a histidine residue (probably beta-His-324) that may have a critical role. Additional coordination by two phosphates from ATP (probably the beta- and gamma-phosphates) is observed in the ternary complex VO.TF1.ATP. ESEEM and HYSCORE data are also obtained for the analogous complexes VO. alpha 3 beta 3 gamma and VO. alpha 3 beta 3 gamma .ATP that show very similar properties in terms of coordination of the divalent metal cation, except for the lysine ligand that is found to be lost in the ternary complex with ATP. It is suggested that this observation may reflect changes in the metal and nucleotide active sites that are associated with the absence of the delta and epsilon subunits in the subcomplex.

The energy transmission in ATP synthase: from the gamma-c rotor to the alpha 3 beta 3 oligomer fixed by OSCP-b stator via the beta DELSEED sequence

ATP synthase (F0F1) is driven by an electrochemical potential of H+ (delta microH+). F0F1 is composed of an ion-conducting portion (F0) and a catalytic portion (F1). The subunit composition of F1 is a alpha 3 beta 3 gamma delta epsilon. The active alpha 3 beta 3 oligomer, characterized by X-ray crystallography, has been obtained only from thermophilic F1 (TF1). We proposed in 1984 that ATP is released from the catalytic site (C site) by a conformational change induced by the beta DELSEED sequence via gamma delta epsilon-F0. In fact, cross-linking of beta DELSEED to gamma stopped the ATP-driven rotation of gamma in the center of alpha 3 beta 3. The torque of the rotation is estimated to be 420 pN x A from the delta microH+ and H(+)-current through F0F1. The angular velocity (omega) of gamma is the rate-limiting step, because delta microH+ increased the Vmax of H+ current through F0, but not the Km(ATP). The rotational unit of F0 (= ab2c10) is pi/5, while that in alpha 3 beta 3 is 2 pi/3. This difference is overcome by an analog-digital conversion via elasticity around beta DELSEED with a threshold to release ATP. The alpha beta distance at the C site is about 9.6 A (2,8-diN3-ATP), and tight Mg-ATP binding in alpha 3 beta 3 gamma was shown by ESR. The rotational relaxation of TF1 is too rapid (phi = 100 nsec), but the rate of AT(D)P-induced conformational change of alpha 3 beta 3 measured with a synchrotron is close to omega. The ATP bound between the P-loop and beta E188 is released by the shift of beta DELSEED from gamma RGL. Considering the viscosity resistance and inertia of the free rotor (gamma-c), there may be a stator containing OSCP (= delta of TF1) and F0-d to hold free rotation of alpha 3 beta 3.

Conformational dynamics monitored by His-179 and His-200 of isolated thermophilic F1-ATPase beta subunit which reside at the entrance of the 'conical tunnel' in holoenzyme

When monitored by 1H NMR at various pH values, most of the C-2 proton signals from 12 His residues of the isolated beta subunit of thermophilic F1-ATPase (TF1) could be separately observed. Two of them were assigned to His-179 and His-200 which reside at the entrance of a 'conical tunnel' to reach catalytic site in the crystal structure of F1-ATPase. His-200 gave doublet, suggesting that this region is not a rigid alpha-helix in the isolated beta subunit. The binding of Mg.AMP-PNP changed the chemical shifts of His-179 and His-200 significantly. Although His-119 located at the opposite side of the conical tunnel was not affected by the nucleotide-binding, it contributed to the stability of beta subunit and the efficiency of the catalysis of the holoenzyme.

Expression of the wild-type and the Cys-/Trp-less alpha 3 beta 3 gamma complex of thermophilic F1-ATPase in Escherichia coli

The alpha, beta and gamma subunits of F1-ATPase from thermophilic Bacillus PS3 were expressed in Escherichia coli cells simultaneously in large amounts. Most of the expressed subunits assembled into a form of alpha 3 beta 3 gamma complex in E. coli cells and this complex was easily purified to homogeneity. The recombinant alpha 3 beta 3 gamma complex thus obtained showed similar enzymatic properties to the alpha 3 beta 3 gamma complex obtained by in vitro reconstitution from individual subunits (Yokoyama, K. et al. (1989) J. Biol. Chem. 264, 21837-21841) except that the former had several-fold higher ATPase activity than the latter. Using this expression system, a mutant alpha 3 beta 3 gamma complex with no Trp and Cys was generated by replacing alpha Cys193 and alpha Trp463 with Ser and Phe, respectively. This mutant complex was functionally intact, indicating both residues are not essential for catalysis. The Cys-/Trp-less complex is a convenient 'second wild type' enzyme from which one can generate mutants with Trp (as a fluorescent probe) or Cys (as an acceptor of a variety of probes) at desired positions without concern for 'background' Trp and Cys residues.

alpha-Aspartate 261 is a key residue in noncatalytic sites of Escherichia coli F1-ATPase

X-ray structure analysis of the noncatalytic sites of F1-ATPase revealed that residue alpha-Asp261 lies close to the Mg of bound Mg-5'-adenylyl-beta,gamma-imidodiphosphate. Here, the mutation alpha D261N was generated in Escherichia coli and combined with the alpha R365W mutation, allowing nucleotide binding at F1 noncatalytic sites to be specifically monitored by tryptophan fluorescence spectroscopy. Purified alpha D261N/alpha R365W F1-ATPase showed catalytic activity similar to wild-type. An important feature was that, without any resort to nucleotide-depletion procedures, the noncatalytic sites in purified native enzyme were already empty. Binding studies with MgATP, MgADP, and the corresponding free nucleotides led to the following conclusions. Residue alpha-Asp261 interacts with the Mg of Mg-nucleotide in noncatalytic sites and provides a large component of the binding energy (approximately 3 kcal/mol). It is the primary determinant of the preference of noncatalytic sites for Mg-nucleotide. The natural ligands at these sites in wild-type enzyme are the Mg-nucleotides and free nucleotides bind poorly. Under conditions where noncatalytic sites were empty, alpha D261N/alpha R365W F1 showed significant hydrolysis of MgATP. This established unequivocally that occupancy of noncatalytic sites by nucleotide is not required for catalysis.

A minimum catalytic unit of F1-ATPase shows non-cooperative ATPase activity inherent in a single catalytic site with a Km 70 microM

F1-ATPase has three interacting catalytic sites and shows complicated kinetics. Here, we report reconstitution of a complex, most likely composed of one alpha subunit and one beta subunit, with a single catalytic site from thermophilic Bacillus PS3 F1-ATPase on the solid surface. The complex has an ATPase activity which obeys a simple non-cooperative kinetics with a Km(ATP) of 70 microM and a Vmax of 0.1 unit/mg. Different from F1-ATPase, the complex is not inactivated by 7-chrolo-4-nitrobenzofrazan. Thus, the inherent activity attributable to a single catalytic site unaffected by other catalytic sites of F1-ATPase is characterized.

F1-ATPase alpha-subunit made up from two fragments (1-395, 396-503) is stabilized by ATP and complexes containing it obey altered kinetics

Inferred from the crystal structure of mitochondrial F1-ATPase (Abrahams, J.P. et al. (1994) Nature 370, 621-628), the proteinase-sensitive region around Phe-395 of thermophilic F1-ATPase alpha-subunit corresponds to the loop which connects main part of the carboxyl-terminal helical bundle domain with the ATP binding domain. This loop is in contact with the gamma- and adjacent beta-subunits. Two polypeptides corresponding to the sequence 1-395 and 396-503 of the alpha-subunit were expressed in Escherichia coli cells and they were copurified as an apparently functional alpha-subunit (alpha(395/396)) made up of two polypeptides. The isolated alpha(395/396) was stabilized by ATP-Mg, but not by ADP-Mg, although it bound both ATP-Mg and ADP-Mg with similar affinities (Kd, 11 microM and 14 microM, respectively). The alpha(395/396) was reconstitutable into alpha(395/396)3 beta 3 and alpha(395/396)3 beta 3 gamma complexes. Different from the intact the ATP-Mg-induced dissociation into alpha 1 beta 1 heterodimers. ATP hydrolysis by the alpha(395/396)3 beta 3 gamma complex underwent a slow initial phase, whereas the intact alpha 3 beta 3 gamma complex exhibited an accelerated initial phase. Steady-state ATPase activity at various ATP concentrations showed negative cooperativity for the intact alpha 3 beta 3 gamma complex but apparently positive cooperativity for the alpha(395/396)3 beta 3 gamma complex. The ATPase activities at a saturating ATP concentration of the complexes containing the alpha(395/396) were 180% of those containing intact alpha-subunits. These results indicate that a loop around Phe-395 is involved in intersubunit interaction in F1-ATPase.

ADP tethered to tyrosine-beta 345 at the catalytic site of the bovine heart F1-ATPase is converted to tethered AMP by Mg(2+)-dependent hydrolysis when the enzyme is photoinactivated with 2-N3-ADP

Comparison of profiles of radioactive peptides resolved by HPLC from tryptic digests of the bovine heart F1-ATPase depleted of nucleotides (nd-MF1) which had been photoinactivated with 2-N3-[beta-32P]ADP, on the one hand, and 2-[8-3H]ADP, on the other, shows that the beta phosphate of ADP tethered to tyrosine-beta 345 is slowly hydrolyzed in the presence of Mg2+. When nd-MF1 was photoinactivated with 2-N3-[8-3H]ADP in the absence of Mg2+, hydrolysis of the beta phosphate from ADP tethered to tyrosine-beta 345 was not observed. Subsequent addition of Mg2+ initiated conversion of ADP tethered to tyrosine-beta 345 to tethered AMP suggesting that functional groups at the catalytic site participate in the hydrolytic reaction.

Inhibition and inactivation of the F1 adenosinetriphosphatase from Bacillus PS3 by dequalinium and activation of the enzyme by lauryl dimethylamine oxide

The F1-ATPase from Bacillus PS3 (TF1) hydrolyzes 50 microM ATP in three kinetic phases. An initial burst rapidly decelerates to a partially inhibited, intermediate phase, which, in turn, gradually accelerates to an uninhibited, final steady-state rate. Lauryl dimethylamine oxide (LDAO) stimulates the final rate over 4-fold. The stimulatory effect saturates at about 0.1% LDAO. Under these conditions, the intermediate phase is nearly absent. Dequalinium inhibits TF1 reversibly in the dark in the presence or absence of LDAO. The apparent affinity of TF1 for dequalinium increases in the presence of LDAO. Dixon plots of the initial rates of the intermediate phase and the final rates against dequalinium concentration at a series of fixed ATP concentrations in the presence and absence of 0.03% LDAO indicate noncompetitive inhibition in each case. Replots of the slopes of the Dixon plots for the initial rate of the intermediate phase and the final rate against 1/[ATP] reveal apparent Km values of 770 microM and 144 microM, respectively, when obtained in the absence of LDAO. The apparent Km values determined from the data obtained in the presence of LDAO for the same phases are 303 microM and 163 microM, respectively. These results suggest that LDAO stimulates ATPase activity either by increasing the affinity of noncatalytic sites for ATP, which promotes release of inhibitory MgADP from a catalytic site, or by directly promoting release of MgADP from the affected catalytic site. Dequalinium retards this process without affecting the affinity of noncatalytic sites for ATP. When irradiated in the presence of dequalinium, TF1 is rapidly inactivated with an apparent Kd of 12.5 microM in the presence or absence of LDAO.(ABSTRACT TRUNCATED AT 250 WORDS)

Two distinct ATP-binding domains are needed to promote protein export by Escherichia coli SecA ATPase

Six putative ATP-binding motifs of SecA protein were altered by oligonucleotide-directed mutagenesis to try to define the ATP-binding regions of this multifunctional protein. The effects of the mutations were analysed by genetic and biochemical assays. The results show that SecA contains two essential ATP-binding domains. One domain is responsible for high-affinity ATP binding and contains motifs A0 and B0, located at amino acid residues 102-109 and 198-210, respectively. A second domain is responsible for low-affinity ATP binding and contains motifs A3 and a predicted B motif located at amino acid residues 503-511 and 631-653, respectively. The ATP-binding properties of both domains were essential for SecA-dependent translocation ATPase and in vitro protein translocation activities. The significance of these findings for the mechanism of SecA-dependent protein translocation is discussed.

The alpha 3 beta 3 and alpha 1 beta 1 complexes of ATP synthase

Two catalytic structures of H(+)-motive ATP synthase (Fig. 1), the alpha 3 beta 3 oligomer (M(r) = 319,581) and alpha 1 beta 1 promoter (M(r) = 106,527) (Fig. 2), were isolated using high pressure liquid chromatography (Fig. 3) and polyacrylamide gel electrophoresis (Figs. 4 and 5). These were reconstituted from the alpha and beta subunits of thermophilic F1 (TF1), and the alpha 3 beta 3 oligomer was also crystallized. Common to both F1 and the alpha 3 beta 3 oligomer were the nucleotide specificity, the two Km values, the presence of protomer-oligomer activities, and the one-hit--one-kill phenomenon. A synchrotron experiment on the ATP hydrolysis cycle revealed the dynamic shrinkage and expansion of F1(44) that correspond, respectively, to the ATP-induced association and ADP-induced dissociation of the alpha 3 beta 3 oligomer. The oligomer, like mitochondrial F1 and TF1, exhibited two kinds of ATPase activity: one was cooperative and was inhibited by only one inhibitor per hexamer, and the other was inhibited by three inhibitors per hexamer.

The conserved helicase motifs of the herpes simplex virus type 1 origin-binding protein UL9 are important for function

The UL9 gene of herpes simplex virus encodes a protein that specifically recognizes sequences within the viral origins of replication and exhibits helicase and DNA-dependent ATPase activities. The specific DNA binding domain of the UL9 protein was localized to the carboxy-terminal one-third of the molecule (H. M. Weir, J. M. Calder, and N. D. Stow, Nucleic Acids Res. 17:1409-1425, 1989). The N-terminal two-thirds of the UL9 gene contains six sequence motifs found in all members of a superfamily of DNA and RNA helicases, suggesting that this region may be important for helicase activity of UL9. In this report, we examined the functional significance of these six motifs for the UL9 protein through the introduction of site-specific mutations resulting in single amino acid substitutions of the most highly conserved residues within each motif. An in vivo complementation test was used to study the effect of each mutation on the function of the UL9 protein in viral DNA replication. In this assay, a mutant UL9 protein expressed from a transfected plasmid is used to complement a replication-deficient null mutant in the UL9 gene for the amplification of herpes simplex virus origin-containing plasmids. Mutations in five of the six conserved motifs inactivated the function of the UL9 protein in viral DNA replication, providing direct evidence for the importance of these conserved motifs. Insertion mutants resulting in the introduction of two alanines at 100-residue intervals in regions outside the conserved motifs were also constructed. Three of the insertion mutations were tolerated, whereas the other five abolished UL9 function. These data indicate that other regions of the protein, in addition to the helicase motifs, are important for function in vivo. Several mutations result in instability of the mutant products, presumably because of conformational changes in the protein. Taken together, these results suggest that UL9 is very sensitive to mutations with respect to both structure and function, perhaps reflecting its multifunctional character.

The alpha beta complexes of ATP synthase: the alpha 3 beta 3 oligomer and alpha 1 beta 1 protomer

The basic structures of the catalytic portion (F1, alpha 3 beta 3 gamma delta epsilon) of ATP synthase are the alpha 3 beta 3 hexamer (oligomer with cooperativity) and alpha 1 beta 1 heterodimer (protomer). These were reconstituted from the alpha and beta subunits of thermophilic F1 (TF1), and the alpha 3 beta 3 hexamer was crystallized. On electrophoresis, both the dimer and hexamer showed bands with ATPase activity. Using the dimer and hexamer, we studied the nucleotide-dependent rapid molecular dynamics. The formation of the hexamer required neither nucleotide nor Mg. The hexamer was dissociated into the dimer in the presence of MgADP, while the dimer was associated into the hexamer in the presence of MgATP. The hexamer, like mitochondrial F1 and TF1, showed two kinds of ATPase activity: one was cooperative and was inhibited by only one BzADP per hexamer, and the other was inhibited by three BzADP per hexamer.

A model for the catalytic site of F1-ATPase based on analogies to nucleotide-binding domains of known structure

An updated topological model is constructed for the catalytic nucleotide-binding site of the F1-ATPase. The model is based on analogies to the known structures of the MgATP site on adenylate kinase and the guanine nucleotide sites on elongation factor Tu (Ef-Tu) and the ras p21 protein. Recent studies of these known nucleotide-binding domains have revealed several common functional features and similar alignment of nucleotide in their binding folds, and these are used as a framework for evaluating results of affinity labeling and mutagenesis studies of the beta subunit of F1. Several potentially important residues on beta are noted that have not yet been studied by mutagenesis or affinity labeling.

Catalytic sites of Escherichia coli F1-ATPase

The catalytic site of Escherichia coli F1-ATPase is reviewed in terms of structure and function. Structural prediction, biochemical analyses, and mutagenesis experiments suggest that the catalytic site is formed primarily by residues 137-335 of beta-subunit. Subdomains of the site involved in phosphate-bond cleavage/synthesis and adenine-ring binding are discussed. Ambiguities inherent in steady-state catalytic measurements due to catalytic site cooperativity are discussed, and the advantages of pre-steady-state ("unisite") techniques are emphasized. The emergence of a single high-affinity catalytic site occurs as a result of F1-oligomer assembly. Measurements of unisite catalysis rate and equilibrium constants, and their modulation by varied pH, dimethylsulfoxide, and mutations, are described and conclusions regarding the nature of the high-affinity catalytic site and mechanism of catalysis are presented.

Evolution of organellar proton-ATPases

Proton ATPases function in biological energy conversion in every known living cell. Their ubiquity and antiquity make them a prime source for evolutionary studies. There are two related families of H(+)-ATPases; while the family of F-ATPases function in eubacteria chloroplasts and mitochondria, the family of V-ATPases are present in archaebacteria and the vacuolar system of eukaryotic cells. Sequence analysis of several subunits of V- and F-ATPases revealed several of the important steps in their evolution. Moreover, these studies shed light on the evolution of the various organelles of eukaryotes and suggested some events in the evolution of the three kingdoms of eubacteria, archaebacteria and eukaryotes.

Beta subunit of mitochondrial F1-ATPase from the fission yeast. Deduced sequence of the wild type protein and identification of a mutation that increases nucleotide binding

The Schizosaccharomyces pombe nuclear gene, atp2, encoding the beta subunit of the mitochondrial ATP synthase, was sequenced and found to contain a 1575-bp open reading frame. Two adjacent transcription-initiation sites were found at positions 34 and 44 nucleotides upstream of the translation-initiation codon. The deduced polypeptide sequence was composed of 525 amino acid residues (molecular mass = 56875 Da). The mature polypeptide starts at residue 45 (molecular mass = 51,685 Da), indicating the presence of a presequence of 44 residues, presumably involved in mitochondrial targeting. The atp2 mutant B59-1 [Boutry, M. & Goffeau, A. (1982) Eur. J. Biochem. 125, 471-477] and its related revertant allele R4-3 [Jault, J. M., Di Pietro, A., Falson, P., Gautheron, D. C., Boutry, M. & Goffeau, A. (1989) Biochem. Biophys. Res. Commun. 158, 392-399] were also cloned and sequenced. A single nonsense mutation, CAG (Gln170)----TAG (stop) in mutant B59-1, became a missense mutation, TAG (stop)----TAC (Tyr) in revertant R4-3. Gln170 is located between the first and second elements belonging to the nucleotide-binding site. Its substitution by a tyrosine residue increases the enzyme affinity towards ADP, the amount of endogenous nucleotides and the apparent negative cooperativity for ATPase activity.

Site-specific mutagenesis of conserved residues within Walker A and B sequences of Escherichia coli UvrA protein

UvrA is the ATPase subunit of the DNA repair enzyme (A)BC excinuclease. The amino acid sequence of this protein has revealed, in addition to two zinc fingers, three pairs of nucleotide binding motifs each consisting of a Walker A and B sequence. We have conducted site-specific mutagenesis, ATPase kinetic analyses, and nucleotide binding equilibrium measurements to correlate these sequence motifs with activity. Replacement of the invariant Lys by Ala in the putative A sequences indicated that K37 and K646 but not K353 are involved in ATP hydrolysis. In contrast, substitution of the invariant Asp by Asn in the B sequences at positions D238, D513, or D857 had little effect on the in vivo activity of the protein. Nucleotide binding studies revealed a stoichiometry of 0.5 ADP/UvrA monomer while kinetic measurements on wild-type and mutant proteins showed that the active form of UvrA is a dimer with 2 catalytic sites which interact in a positive cooperative manner in the presence of ADP; mutagenesis of K37 but not of K646 attenuated this cooperativity. Loss of ATPase activity was about 75% in the K37A, 86% in the K646A mutant, and 95% in the K37A-K646A double mutant. These amino acid substitutions had only a marginal effect on the specific binding of UvrA to damaged DNA but drastically reduced its ability to deliver UvrB to the damage site. We find that the deficient UvrB loading activity of these mutant UvrA proteins results from their inability to associate with UvrB in the form of (UvrA)2(UvrB)1 complexes. We conclude that UvrA forms a dimer with two ATPase domains involving K37 and K646 and that the work performed by ATP hydrolysis is the delivery of UvrB to the damage site on DNA.