Kinetic characterization of the unisite catalytic pathway of seven beta-subunit mutant F1-ATPases from Escherichia coli

We have studied the kinetics of "unisite" ATP hydrolysis and synthesis in seven mutant Escherichia coli F1-ATPase enzymes. The seven mutations are distributed over a 105-residue segment of the catalytic nucleotide-binding domain in beta-subunit and are: G142S, K155Q, K155E, E181Q, E192Q, M209I, and R246C. We report forward and reverse rate constants and equilibrium constants in all seven mutant enzymes for the four steps of unisite kinetics, namely (i) ATP binding/release, (ii) ATP hydrolysis/synthesis, (iii) Pi release/binding, and (iv) ADP release/binding. The seven mutant enzymes displayed a wide range of deviations from normal in both rate and equilibrium constants, with no discernible common pattern. Notably, steep reductions in Kd ATP were seen in some cases, the value of Kd Pi was high, and K2 (ATP hydrolysis/synthesis) was relatively unaffected. Significantly, when the data from the seven mutations were combined with previous data from two other E. coli F1-beta-subunit mutations (D242N, D242V), normal E. coli F1, soluble and membranous mitochondrial F1, it was found that linear free energy relationships obtained for both ATP binding/release (log k+1 versus log K1) and ADP binding/release (log k-4 versus log K-4). Two conclusions follow. 1) The seven mutations studied here cause subtle changes in interactions between the catalytic nucleotide-binding domain and substrate ATP or product ADP. 2) The mitochondrial, normal E. coli, and nine total beta-subunit mutant enzymes represent a continuum in which subtle structural differences in the catalytic site resulted in changes in binding energy; therefore insights into the nature of energy coupling during ATP hydrolysis and synthesis by F1-ATPase may be ascertained by detailed studies of this group of enzymes.     

Catalytic sites of Escherichia coli F1-ATPase. Characterization of unisite catalysis at varied pH.

Using manual rapid-mixing procedures in which small, equal volumes of Escherichia coli F1-ATPase and [gamma-32P]ATP were combined at final concentrations of 2 and 0.2 microM, respectively (i.e., unisite catalysis conditions), it was shown that greater than or equal to 66% of the 32P became bound to the enzyme, with the ratio of bound ATP/bound Pi equal to 0.4 and the rate of dissociation of bound [32P]Pi equal to 3.5 x 10(-3) s-1, similar to previously published values. Azide is known to inhibit cooperative but not unisite catalysis in F1-ATPase [Noumi, T., Maeda, M., & Futai, M. (1987) FEBS Lett. 213, 381-384]. In the presence of 1 mM sodium azide, 99% of the 32P became bound to the enzyme, with the ratio of bound ATP/bound Pi being 0.57. These experiments demonstrated that when conditions are used which minimize cooperative catalysis, most or all of the F1 molecules bind substoichiometric ATP tightly, hydrolyze it with retention of bound ATP and Pi, and release the products slowly. The data justify the validity of previously published rate constants for unisite catalysis. Unisite catalysis in E. coli F1-ATPase was studied at varied pH from 5.5 to 9.5 using buffers devoid of phosphate. Rate constants for ATP binding/release, ATP hydrolysis/resynthesis, Pi release, and ADP binding/release were measured; the Pi binding rate constant was inferred from the delta G for ATP hydrolysis. ATP binding was pH-independent; ATP release accelerated at higher pH. The highest KaATP (4.4 x 10(9) M-1) was seen at physiological pH 7.5.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification of F1-ATPase with impaired catalytic activity from partial revertants of Escherichia coli uncA mutant strains

It is shown that F1-ATPase preparations having impaired catalytic rates may be purified from partial revertants of uncA mutant strains of Escherichia coli. Recovery of catalytic activity in the partial revertant F1 was accompanied by recovery of alpha in equilibrium beta intersubunit conformational interaction, supporting the hypothesis that such interaction is required for normal catalysis in F1. The specific ATPase activities of the partial revertant F1 preparations were in the range 1-29% of normal, and some of the preparations showed unusual insensitivity to inhibitors. The properties of a new uncA mutant F1 preparation (uncA498) which has approximately half of normal catalytic rate are also briefly described.     

Properties of F1-ATPase from the uncD412 mutant of Escherichia coli.

Properties of purified F1-ATPase from Escherichia coli mutant strain AN484 (uncD412) have been studied in an attempt to understand why the amino acid substitution in the beta-subunit of this enzyme causes a tenfold reduction from normal MgATP hydrolysis rate. In most properties that were studied, uncD412 F1-ATPase resembled normal E. coli F1-ATPase. Both enzymes were found to contain a total of six adenine-nucleotide-binding sites, of which three were found to be non-exchangeable and three were exchangeable (catalytic) sites. Binding of the non-hydrolysable substrate analogue adenosine 5'-[beta gamma-imido]triphosphate (p[NH]ppA) to the three exchangeable sites showed apparent negative co-operativity. The binding affinities for p[NH]ppA, and also ADP, at the exchangeable sites were similar in the two enzymes. Both enzymes were inhibited by efrapeptin, aurovertin and p[NH]ppA, and were inactivated by dicyclohexylcarbodi-imide, 4-chloro-7-nitrobenzofurazan and p-fluorosulphonyl-benzoyl-5'-adenosine. Km values for CaATP and MgATP were similar in the two enzymes. uncD412 F1-ATPase was abnormally unstable at high pH, and dissociated into subunits readily with consequent loss of activity. The reason for the impairment of catalysis in uncD412 F1-ATPase cannot be stated with certainty from these studies. However we discuss the possibility that the mutation interrupts subunit interaction, thereby causing a partial impairment in the site-site co-operativity which is required for 'promotion' of catalysis in this enzyme.     

Effect of the epsilon-subunit on nucleotide binding to Escherichia coli F1-ATPase catalytic sites.

The influence of the epsilon-subunit on the nucleotide binding affinities of the three catalytic sites of Escherichia coli F1-ATPase was investigated, using a genetically engineered Trp probe in the adenine-binding subdomain (beta-Trp-331). The interaction between epsilon and F1 was not affected by the mutation. Kd for binding of epsilon to betaY331W mutant F1 was approximately 1 nM, and epsilon inhibited ATPase activity by 90%. The only nucleotide binding affinities that showed significant differences in the epsilon-depleted and epsilon-replete forms of the enzyme were those for MgATP and MgADP at the high-affinity catalytic site 1. Kd1(MgATP) and Kd1(MgADP) were an order of magnitude higher in the absence of epsilon than in its presence. In contrast, the binding affinities for MgATP and MgADP at sites 2 and 3 were similar in the epsilon-depleted and epsilon-replete enzymes, as were the affinities at all three sites for free ATP and ADP. Comparison of MgATP binding and hydrolysis parameters showed that in the presence as well as the absence of epsilon, Km equals Kd3. Thus, in both cases, all three catalytic binding sites have to be occupied to obtain rapid (Vmax) MgATP hydrolysis rates.     

F1F0-ATPase from Escherichia coli with mutant F0 subunits. Partial purification and immunoprecipitation of F1F0 complexes

Previously identified mutations in subunits a and b of the F0 sector of the F1F0-ATPase from Escherichia coli are further characterized by isolating detergent-solubilized, partially purified F1F0 complexes from cells bearing these mutations. The composition of the various F1F0 complexes was judged by quantitating the amount of each subunit present in the detergent-solubilized preparations. The composition of the F0 sectors containing altered polypeptides was determined by quantitating the F0 subunits that were immunoprecipitated by antibodies directed against the F1 portion. In this way, the relative amounts of F0 subunits (a, b, c) which survived the isolation procedure bound to F1 were determined for each mutation. This analysis indicates that both missense mutations in subunit a (aser206----leu and ahis245----tyr) resulted in the isolation of F1F0 complexes with normal subunit composition. The nonsense mutation in subunit a (atyr235----end) resulted in isolation of a complex containing the b and c subunits. The bgly131----asp mutation in the b subunit results in an F0 complex which does not assemble or survive the isolation. The isolated F1F0 complex containing the mutation bgly9----asp in the b subunit was defective in two regards: first, a reduction in F1 content relative to F0 and second, the absence of the a subunit. Immunoprecipitations of this preparation demonstrated that F1 interacts with both c and mutant b subunits. A strain carrying the mutation, bgly9----asp, and the compensating suppressor mutation apro240----leu (previously shown to be partially unc+) yielded an F1F0 ++ complex that remained partially defective in F1 binding to F0 but normal in the subunit composition of the F0 sector. The assembly, structure, and function of the F1F0-ATPase is discussed.     

Thermodynamic analyses of the catalytic pathway of F1-ATPase from Escherichia coli. Implications regarding the nature of energy coupling by F1-ATPases

Thermodynamic properties of 12 different F1-ATPase enzymes were analyzed in order to gain insights into the catalytic mechanism and the nature of energy coupling to delta mu H+. The enzymes were normal soluble Escherichia coli F1, a group of nine beta-subunit mutant soluble E. coli F1 enzymes (G142S, K155Q, K155E, E181Q, E192Q, M209I, D242N, D242V, R246C), and both soluble and membrane-bound bovine heart mitochondrial F1. Unisite activity was studied by use of Gibbs free energy diagrams, difference energy diagrams, and derivation of linear free energy relationships. This allowed construction of binding energy diagrams for both the unisite ATP hydrolysis and ATP synthesis reaction pathways, which were in agreement. The binding energy diagrams showed that the step of Pi binding is a major energy-requiring step in ATP synthesis, as is the step of ATP release. It is suggested that there are two major catalytic enzyme conformations, and ATP- and an ADP-binding conformation. The effects of the mutations on the rate-limiting steps of multisite as compared to unisite activity were correlated, suggesting a direct link between the rate-limiting steps of the two types of activity. Multisite activity was analyzed by Arrhenius plots and by study of relative promotion from unisite to multisite rate. Changes in binding energy due to mutation were seen to have direct effects on multisite catalysis. From all the data, a model is derived to describe the mechanism of ATP synthesis. ATP hydrolysis, and energy coupling to delta mu H+ in F1F0-ATPases.     

The kinetic and structural changes of the mitochondrial F1-ATPase with temperature

Mitochondrial F1-ATPase shows a break in the Arrhenius plot with an increase of the activation energy below 17 degrees C, this may imply that the F1-ATPase undergoes a conformational change at this temperature. Further, a structural change of the F1-ATPase is indicated by analysis of the intrinsic fluorescence at 307 nm between 33 and 11 degrees C and also by evaluation of the circular dichroism spectra of the enzyme at temperatures below and above the temperature corresponding to the discontinuity of the Arrhenius plot. It is therefore suggested that F1-ATPase exists in two temperature dependent conformational states to which different catalytic properties may be assigned.     

Rotation of Escherichia coli F(1)-ATPase.

By applying the same method used for F(1)-ATPase (TF(1)) from thermophilic Bacillus PS3 (Noji, H., Yasuda, R., Yoshida, M., and Kinosita, K., Jr. (1997) Nature 386, 299-302), we observed ATP-driven rotation of a fluorescent actin filament attached to the gamma subunit in Escherichia coli F(1)-ATPase. The torque value and the direction of the rotation were the same as those observed for TF(1). F(1)-ATPases seem to share common properties of rotation irrespective of the sources.     

Interaction of Escherichia coli F1-ATPase with dicyclohexylcarbodiimide-binding polypeptide

Antibody raised against the N,N'-dicyclohexylcarbodiimide (DCCD)-binding polypeptide of Escherichia coli bound to the cytoplasmic surface of the cell membrane. A weak reaction was seen with everted vesicles of the thermophile PS3. Rat-liver mitochondrial membranes did not react with the antibody. Reaction of the isolated DCCD-binding polypeptide with the antibody was prevented by oxidation of methionine residues or cleavage of the polypeptide with cyanogen bromide. Modification of the arginine residues of the DCCD-binding polypeptide did not affect interaction with the antibody. Purified F1-ATPase of E. coli bound to the isolated DCCD-binding polypeptide as shown by solid-phase radioimmune assay. Binding involved the alpha and/or beta subunits of F1 and the arginine residues of the polar central region of the DCCD-binding polypeptide. Our results are consistent with a looped arrangement of the DCCD-binding polypeptide in the membrane in which the carboxyl- and amino-terminal regions of the molecule are at the periplasmic surface and the polar central region, interacting with F1, is at the cytoplasmic surface of the cell membrane.     

On the location and function of tyrosine beta 331 in the catalytic site of Escherichia coli F1-ATPase.

1) Using a combination of site-directed mutagenesis and fluorescence spectroscopy we have studied the location and function of residue beta Y331 in the catalytic site of Escherichia coli F1-ATPase. The fluorescent analog lin-benzo-ADP was used as a catalytic-site probe, and was found to bind to three sites in normal F1, with Kd1 = 0.20 microM and Kd2,3 = 5.5 microM. lin-Benzo-ATP was a good substrate for hydrolysis. 2) The mutants investigated were beta Y331F, L, A and E. kcat/KM for ATP hydrolysis in purified F1 was reduced according to the series Y greater than or equal to F greater than L greater than A greater than E, with E being severely impaired; concomitant decreases in binding affinity for lin-benzo-ADP were seen. 3) Fluorescence properties of lin-benzo-ADP bound to F1 differed widely, depending on the residue present at position beta 331. Red shifts of excitation and emission spectra occurred with F and L residues, but not with Y, A, or E. There was strong quenching of fluorescence with wild-type (Y), partial quenching with A, and no quenching with F, L, or E. 4) We conclude that (a) the environment around the bound adenine moiety in the catalytic site is nonpolar, (b) residue beta 331 is part of the adenine-binding subdomain and when tyrosine is the residue, the phenolic hydroxyl makes direct interaction with the fluorophore, (c) an aromatic residue is not absolutely required at position beta 331 for catalytic function, but an increase in polarity leads to functional impairment, and (d) in terms of fluorescence response of bound lin-benzo-ADP all three catalytic sites behaved the same. 5) F1 from mutant beta Y297F bound lin-benzo-ADP with the same fluorescence and binding characteristics as normal F1, and catalytic properties were similar to normal. Therefore, there was no reason to conclude that residue beta Y297 is involved in binding the adenine moiety of ATP.     

Epsilon subunit of Escherichia coli F1-ATPase: effects on affinity for aurovertin and inhibition of product release in unisite ATP hydrolysis

The epsilon subunit of Escherichia coli F1-ATPase is a tightly bound but dissociable partial inhibitor of ATPase activity. The effects of epsilon on the enzyme were investigated by comparing the ATPase activity and aurovertin binding properties of the epsilon-depleted F1-ATPase and the epsilon-replete complex. Kinetic data of multisite ATP hydrolysis were analyzed to give the best fit for one, two, or three kinetic components. Each form of F1-ATPase contained a high-affinity component, with a Km near 20 microM and a velocity of approximately 1 unit/mg. Each also exhibited a component with a Km in the range of 0.2 mM. The velocity of this component was 25 units/mg for epsilon-depleted ATPase but only 4 units/mg for epsilon-replete enzyme. The epsilon-depleted enzyme also contained a very low affinity component not present in the epsilon-replete enzyme. In unisite hydrolysis studies, epsilon had no effect on the equilibrium between substrate ATP and product ADP.P1 at the active site but reduced the rate of product release 15-fold. These results suggest that epsilon subunit slows a conformational change that is required to reduce the affinity at the active site, allowing dissociation of product. It is suggested that inhibition of multisite hydrolysis by epsilon is also due to a reduced rate of product release. epsilon-depleted F1-ATPase showed little of no modulation of aurovertin fluorescence by added ADP and ATP. Aurovertin fluorescence titrations in buffer containing ethylenediaminetetraacetic acid (EDTA) revealed that epsilon-depleted enzyme had high affinity for aurovertin (Kd less than 0.1 microM) regardless of the presence of nucleotides.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structural and Functional Features of the Escherichia coli F 1 -ATPase

The structural organization and overall dimensions of the Escherichia coli F₁-ATPase in solutionhas been analyzed by synchroton X-ray scattering. Using an independent ab initio approach,the low-resolution shape of the hydrated enzyme was determined at 3.2 nm resolution. Theshape permitted unequivocal identification of the volume occupied by the _{3 3} complex ofthe atomic model of the ECF₁-ATPase. The position of the ^ and subunits were found byinteractive fitting of the solution scattering data and by cross-linking studies. Laser-inducedcovalent incorporation of 2-azido-ATP established a direct relationship between nucleotidebinding affinity and the different interactions between the stalk subunits and with the threecatalytic subunits () of the F₁-ATPase. Mutants of the ECF₁-ATPase with the introductionof Trp-for-Tyr replacement in the catalytic site of the complex made it possible to monitorthe activated state for ATP synthesis (ATP conformation) in which the and subunits arein close proximity to the subunits and the ADP conformation, with the stalk subunits arelinked to the subunit.     

Oxidative phosphorylation in Escherichia coli. Characterization of mutant strains in which F1-ATPase contains abnormal beta-subunits.

To facilitate study of the role of the beta-subunit in the membrane-bound proton-translocating ATPase of Escherichia coli, we identified mutant strains from which an F1-ATPase containing abnormal beta-subunits can be purified. Seventeen strains of E. coli, characterized by genetic complementation tests as carrying mutations in the uncD gene (which codes for the beta-subunit), were studied. The majority of these strains (11) were judged to be not useful, as their membranes lacked ATPase activity, and were either proton-permeable as prepared or remained proton-impermeable after washing with buffer of low ionic strength. A further two strains were of a type not hitherto reported, in that their membranes had ATPase activity, were proton-impermeable as prepared, and were not rendered proton-permeable by washing in buffer of low ionic strength. Presumably in these two strains F1-ATPase is not released in soluble form by this procedure. F1-ATPase of normal molecular size were purified from strains AN1340 (uncD478), AN937 (uncD430), AN938 (uncD431) and AN1543 (uncD484). F1-ATPase from strain AN1340 (uncD478) had 15% of normal specific Mg-dependent ATPase activity and 22% of normal ATP-synthesis activity. The F1-ATPase preparations from strains AN937, AN938 and AN1543 had respectively 1.7%, 1.8% and 0.2% of normal specific Mg-dependent ATPase activity, and each of these preparations had very low ATP-synthesis activity. The yield of F1-ATPase from the four strains described was almost twice that obtained from a normal haploid strain. The kinetics of Ca-dependent ATPase activity were unusual in each of the four F1-ATPase preparations. It is likely that these four mutant uncD F1-ATPase preparations will prove valuable for further experimental study of the F1-ATPase catalytic mechanism.     

Loss of unisite and multisite catalyses by Escherichia coli F1 through modification with adenosine tri- or tetraphosphopyridoxal

Pyridoxal phosphate (PLP) and adenosine diphospho (AP2-PL)-, triphospho (AP3-PL)-, and tetraphospho (AP4-PL)-pyridoxals (Tagaya, M., and Fukui, T. (1986) Biochemistry 25, 2958-2964) were tested as potential affinity probes for F1 ATPase of Escherichia coli. Both AP3-PL and AP4-PL bound and inhibited F1 ATPase, whereas PLP and AP2-PL were weak inhibitors. The concentrations of AP3-PL and AP4-PL for half-maximal inactivations of the multisite (steady state) ATPase activity were both 18 microM. The binding of these reagents to a reactive lysyl residue(s) was confirmed from the difference absorption spectra, and the stoichiometry of binding of [3H]AP3-PL to F1 at the saturating level was about 1 mol/mol F1. The analogue bound to both the alpha subunit (about two-thirds of the radioactivity) and the beta subunit (about one-third of the radioactivity). No inactivation of multisite ATPase activity or binding of AP3-PL was observed in the presence of ATP. F1 modified with about one mol of AP3-PL had essentially no uni- and multisite hydrolysis of ATP. The rate of binding of ATP decreased to 10(-2) of that of unmodified F1, and the rate of release of ATP was about two times faster. The equilibrium F1 X ATP in equilibrium F1 X ADP X Pi was shifted toward F1 X ATP, and no promotion of ATP hydrolysis at unisite was observed with excess ATP. These results suggest that the AP3-PL or AP4-PL bound to an active site, and catalysis by the two remaining sites was completely abolished.     

Effect of dicyclohexylcarbodiimide on unisite and multisite catalytic activities of the adenosinetriphosphatase of Escherichia coli

The inhibitory effect of dicyclohexylcarbodiimide (DCCD) on the activity of the adenosine-triphosphatase of Escherichia coli (ECF1) has been examined in detail. DCCD reacted with ECF1 predominantly in beta subunits with a maximum of 2 mol of reagent per mole of ECF1 being incorporated in these subunits. Ninety-five percent inhibition of steady-state or multistate ATPase activity required incorporation of 1 mol of DCCD per mole of enzyme into beta subunits. Seventy-five percent inhibition of the initial rate of unisite catalysis was only obtained after incorporation of 2 mol of DCCD per mole of ECF1 into beta subunits. Analyses of the kinetics of unisite catalysis and nucleotide binding experiments both indicate that DCCD binds outside the substrate ATP binding site. Inhibition by this reagent appears to be due in part to an effect on the catalytic sites but mainly to the blocking of cooperativity between these sites.     

The role of beta-Arg-182, an essential catalytic site residue in Escherichia coli F1-ATPase.

Beta-Arg-182 in Escherichia coli F1-ATPase (beta-Arg-189 in bovine mitochondrial F1) is a residue which lies close to catalytic site bound nucleotide (Abrahams et al. (1994) Nature 370, 621-628). Here we investigated the role of this residue by characterizing two mutants, betaR182Q and betaR182K. Oxidative phosphorylation and steady-state ATPase activity of purified F1 were severely impaired by both mutations. Catalytic site nucleotide-binding parameters were measured using the fluorescence quench of beta-Trp-331 that occurred upon nucleotide binding to purified F1 from betaR182Q/betaY331W and betaR182K/betaY331W double mutants. It was found that (a) beta-Arg-182 interacts with the gamma-phosphate of MgATP, particularly at catalytic sites 1 and 2, (b) beta-Arg-182 has no functional interaction with the beta-phosphate of MgADP or with the magnesium of the magnesium-nucleotide complex in the catalytic sites, and (c) beta-Arg-182 is directly involved in the stabilization of the catalytic transition state. In these features the role of beta-Arg-182 resembles that of another positively charged residue in the catalytic site, the conserved lysine of the Walker A motif, beta-Lys-155. A further role of beta-Arg-182 is suggested, namely involvement in conformational change at the catalytic site beta-alpha subunit interface that is required for multisite catalysis.     

A mutation altering the kinetic responses of the yeast mitochondrial F1-ATPase

Nucleotide-binding proteins, including the mitochondrial F1-ATPase, the ras proteins, and the G-proteins, contain a homologous glycine-rich sequence that is thought to constitute part of the active site. This study reports the effects of a single amino acid replacement of Thr197 to Ser197, which is located at the hinge region of this putative loop, in the yeast Saccharomyces cerevisiae F1-ATPase. This replacement resulted in a 3-fold increase in the specific activity of the enzyme, eliminated the stimulatory effects of oxyanions, and modulated the effects of the inhibitor NaN3 while having little effect on the uni-site ATPase. These results indicate a role of the glycine-rich loop in many of the kinetic responses of the F1-ATPase.     

Chemical modification of F1-ATPase by dicyclohexylcarbodiimide: application to analysis of the stoichiometry of subunits in Escherichia coli F1

N,N'-Dicyclohexylcarbodiimide (DCCD) covalently binds to the beta subunit of Escherichia coli F1-ATPase (BF1). The ATPase activity is fully inhibited when 1 mol of DCCD is bound/mol of BF1, in spite of the fact that BF1 contains several beta subunits [Satre, M., Lunardi, J., Pougeois, R., & Vignais, P.V. (1979) Biochemistry 18, 3134-3140]. Advantage was taken of the reactivity of DCCD with respect to BF1 to determine the exact stoichiometry of the beta subunits in BF1. Two methods were used. The first one was based on the fact that modification of the beta subunit by DCCD results in the disappearance of one negative charge, due to the binding of DCCD to a carboxyl group of the beta subunit. The nonmodified and the modified beta subunits were separated by electrofocusing, and the percentage of modified beta subunits was assessed as a function of the percentage of ATPase inactivation. The second method relied on direct comparison, after inactivation of BF1 by [14C]DCCD, of the specific radioactivities of the whole BF1 and the isolated beta subunits. Both methods indicate that each molecule of BF1 contains three beta subunits.