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)     

Effects of dimethyl sulfoxide on catalysis in Escherichia coli F1-ATPase.

(1) Dimethyl sulfoxide (DMSO) markedly inhibited the Vmax of multisite ATPase activity in Escherichia coli F1-ATPase at concentrations greater than 30% (v/v). Vmax/KM was reduced by 2 orders of magnitude in 40% (v/v) DMSO at pH 7.5, primarily due to reduction of Vmax. The inhibition was rapidly reversed on dilution into aqueous buffer. (2) KdATP at the first, high-affinity catalytic site was increased 1500-fold from 2.3 x 10(-10) to 3.4 x 10(-7) M in 40% DMSO at pH 7.5, whereas KdADP was increased 3.2-fold from 8.8 to 28 microM. This suggests that the high-affinity catalytic site presents a hydrophobic environment for ATP binding in native enzyme, that there is a significant difference between the conformation for ADP binding as opposed to ATP binding, and that the ADP-binding conformation is more hydrophilic. (3) Rate constants for hydrolysis and resynthesis of bound ATP in unisite catalysis were slowed approximately 10-fold by 40% DMSO; however, the equilibrium between bound Pi/bound ATP was little changed. The reduction in catalysis rates may well be related to the large increase in KdATP (less constrained site). (4) Significant Pi binding to E. coli F1 could not be detected either in 40% DMSO or in aqueous buffer using a centrifuge column procedure. (5) We infer, on the basis of the measured constants KaATP, K2 (hydrolysis/resynthesis of ATP), k+3 (Pi release), and KdADP and from estimates of k-3 (Pi binding) that delta G for ATP hydrolysis in 40% DMSO-containing pH 7.5 buffer is between -9.2 and -16.8 kJ/mol.     

Structural alterations and inhibition of unisite and multisite ATP hydrolysis in soluble mitochondrial F1 by guanidinium chloride

The effect of guanidinium chloride (GdnHCl) on the ATPase activity and structure of soluble mitochondrial F1 was studied. At high ATP concentrations, hydrolysis is carried by the three catalytic sites of F1; this reaction was strongly inhibited by GdnHCl concentrations of <50 mM. With substoichiometric ATP concentrations, hydrolysis is catalyzed exclusively by the site with the highest affinity. Under these conditions, ATP binding and hydrolysis took place with GdnHCl concentrations of >100 mM; albeit at the latter concentration, the rate of hydrolysis of bound ATP was lower. Similar results were obtained with urea, although nearly 10-fold higher concentrations were required to inhibit multisite hydrolysis. GdnHCl inhibited multisite ATPase activity by diminishing the V(max) of the reaction without significant alterations of the Km for MgATP. GdnHCl prevented the effect of excess ATP on hydrolysis of ATP that was already bound to the high-affinity catalytic site. With and without 100 mM GdnHCl and 100 microM [3H]ATP in the medium, F1 bound 1.6 and 2 adenine nucleotides per F1, respectively. The effect of GdnHCl on some structural features of F1 was also examined. GdnHCl at concentrations that inhibit multisite ATP hydrolysis did not affect the exposure of the cysteines of F1, nor its intrinsic fluorescence. With 100 mM GdnHCl, a concentration at which unisite ATP hydrolysis was still observed, 0.7 cysteine per F1 became solvent-exposed and small changes in its intrinsic fluorescence of F1 were detected. GdnHCl concentrations on the order of 500 mM were required to induce important decreases in intrinsic fluorescence. These changes accompanied inhibition of unisite ATP hydrolysis. The overall data indicate that increasing concentrations of GdnHCl bring about distinct and sequential alterations in the function and structure of F1. With respect to the function of F1, the results show that at low GdnHCl concentrations, only the high-affinity site expresses catalytic activity, and that inhibition of multisite catalysis is due to alterations in the transmission of events between catalytic sites.     

Adenine nucleotide binding sites on beef heart F1-ATPase. Asymmetry and subunit location

Previously we have shown that beef heart mitochondrial F1 contains a total of six adenine nucleotide binding sites. Three "catalytic" sites exchange bound ligand rapidly during hydrolysis of MgATP, whereas three "noncatalytic" sites do not. The noncatalytic sites behave asymmetrically in that a single site releases bound ligand upon precipitation of F1 with ammonium sulfate. In the present study, we find this same site to be the only noncatalytic site that undergoes rapid exchange of bound ligand when F1 is incubated in the presence of EDTA at pH 8.0. Following 1000 catalytic turnovers/F1, the site retains the unique capacity for EDTA-induced exchange, indicating that the asymmetric determinants are permanent and that the three noncatalytic sites on soluble F1 do not pass through equivalent states during catalysis. Measurements of the rate of ligand binding at the unique noncatalytic site show that uncomplexed nucleotide binds preferentially. At pH 7.5, in the presence of Mg2+, the rate constant for ADP binding is 9 X 10(3) M-1 s-1 and for dissociation is 4 X 10(-4) s-1 to give a Kd = 50 nM. The rate of dissociation is 10 times faster in the presence of EDTA or during MgATP hydrolysis, and it increases rapidly at pH below 7. EDTA-induced exchange is inhibited by Mg2+, Mn2+, Co2+, and Zn2+ but not by Ca2+ and is unaffected by dicyclohexylcarbodiimide modification. The unique noncatalytic site binds 2-azido-ADP. Photolysis results in the labeling of the beta subunit. Photolabeling of a single high-affinity catalytic site under conditions for uni-site catalysis also results in the labeling of beta, but a different pattern of labeled peptides is obtained in proteolytic digests. The results demonstrate the presence of two different nucleotide binding domains on the beta subunit of mitochondrial F1.     

The a subunit ala-217 --> arg substitution affects catalytic activity of F(1)F(0) ATP synthase

A large number of mutations affecting the F(0) sector of Escherichia coli F(1)F(0) ATP synthase have been constructed and characterized. A subset of the missense mutations resulted in fully assembled enzyme complexes blocked in proton translocation and displaying marked decreases in ATP hydrolysis activity. The catalytic activities of one such mutant enzyme, a(ala-217-->arg), have been determined using both multisite and unisite catalysis conditions. As expected, the V(max) of the a(ala-217-->arg) enzyme was reduced under conditions of saturating substrate concentration. However, the F(0) sector amino acid substitution did not affect nucleotide occupancy of the noncatalytic sites. Moreover, the microscopic rate constants measured using unisite methods yielded no significant differences between the intact wild type F(1)F(0) ATP synthase and the a(ala-217-->arg) mutant enzyme. In general, the values for unisite activities in both preparations were very similar to numbers reported in the literature for E. coli F(1)-ATPase. The results suggest that the a(ala-217-->arg) substitution resulted in a defect in catalytic cooperativity and most likely altered the enzyme by inhibiting the rotational mechanism of F(1)F(0) ATP synthase.     

Complete kinetic and thermodynamic characterization of the unisite catalytic pathway of Escherichia coli F1-ATPase. Comparison with mitochondrial F1-ATPase and application to the study of mutant enzymes

A complete analysis is presented of the component rate constants of the "unisite" reaction pathway in normal Escherichia coli F1-ATPase. Gibbs free energy profiles of the unisite reaction pathway were constructed for both normal E. coli F1 and bovine-heart mitochondrial F1, and comparison indicated that E. coli F1 is an ancestral form of the mitochondrial enzyme. Similar kinetic and thermodynamic analyses of the unisite reaction pathway were done for mutant beta-Asn-242 and beta-Val-242 E. coli F1-ATPases. Both mutations affected unisite binding and hydrolysis of MgATP but had little effect on release of products or binding of MgADP. It was apparent that a primary effect of the mutations was on the interaction between the catalytic nucleotide-binding domain and the substrate MgATP. The catalytic transition state [F1-ATP]++ was the most destabilized step in the reaction sequence. Measurements of delta delta G[F1.ATP]++ and linear free energy plots for the catalytic step were consistent with the view that, in normal enzyme, residue beta-Asp-242 accepts an H-bond from the transition-state substrate in order to facilitate catalysis. Both mutations impaired positive catalytic cooperativity. This was caused by energetic destabilization of the catalytic transition state and was an indirect effect, not a direct effect on signal transmission per se between catalytic nucleotide-binding domains on beta-subunits. Therefore, impairment of unisite catalysis and of positive catalytic cooperativity appeared to be linked. This may provide a unifying explanation as to why a series of other, widely separated mis-sense mutations within the catalytic nucleotide-binding domain on F1-beta-subunit, which have been reported to affect unisite catalysis, also impair positive catalytic cooperativity. Linear free energy plots for the ATP-binding step of unisite catalysis demonstrated that beta-Asn-242 and beta-Val-242 mutant enzymes did not suffer any gross disruptive change in structure of the catalytic nucleotide-binding domain, reinforcing the view that impairment of catalysis was due to a localized effect. Such analyses confirmed that six other F1-beta-subunit mutants, previously generated and characterized in this laboratory and thought to have inhibitory side-chain substitutions in the catalytic nucleotide-binding domain, are also devoid of gross structural disruption.     

Tight ATP and ADP binding in the noncatalytic sites of Escherichia coli F1-ATPase is not affected by mutation of bulky residues in the 'glycine-rich loop'

It is shown that ATP dissociates very slowly (koff less than 6.4 x 10(5) s-1, t1/2 greater than 3 h) from the three noncatalytic sites of E. coli F1-ATPase and that ADP dissociates from these three sites in a homogeneous fashion with koff = 1.5 x 10(-4) s-1 (t1/2 = 1.35 h). Mutagenesis of alpha-subunit residues R171 and Q172 in the 'glycine-rich loop' (Homology A) consensus region of the noncatalytic sites was carried out to test the hypothesis that unusually bulky residues at these positions are responsible wholly or partly for the observed tight binding of adenine nucleotides. The mutations alpha Q172G or alpha R171S,Q172G had no effects on ATP or ADP binding to or rates of dissociation from F1 noncatalytic sites. KdATP and KdADP of isolated alpha-subunit were weakened by approximately 1 order of magnitude in both mutants. The results suggest that neither residue alpha R171 nor alpha Q172 interacts directly with bound nucleotide, and show that the presence of bulky residues per se in the glycine-rich loop region of F1-alpha-subunit is not responsible for tight binding in the noncatalytic sites.     

Defective proton ATPase of uncA mutants of Escherichia coli. 5'-Adenylyl imidodiphosphate binding and ATP hydrolysis

The Escherichia coli uncA gene codes for the alpha-subunit of the F1 sector of the membrane proton ATPase. In this work purified soluble F1 enzymes from three mutant strains ( uncA401 , uncA447 , and uncA453 ) have been compared to F1 from a normal strain in respect to (a) binding of 5'-adenylyl imidodiphosphate (AMPPNP) to native enzyme in both the presence and absence of Mg, (b) high-affinity binding of MgATP to native enzyme, (c) total reloading of MgAMPPNP to nucleotide-depleted F1 preparations, (d, e) ability to hydrolyze MgATP at both high MgATP concentrations (d) (steady-state conditions) and low MgATP concentrations (e) where substrate hydrolysis occurs under nonsteady-state (" unisite ") conditions, and (f) sensitivity of steady-state ATPase activities to inhibitors of normal F1-ATPase activity. uncA mutant F1 showed normal stoichiometry of MgAMPPNP binding to both native (three sites per F1) and nucleotide-depleted preparations (six sites per F1). Native uncA F1 preparations showed lower-than-normal affinity for MgAMPPNP and MgATP at the first site filled. Binding of AMPPNP in the absence of Mg was similar to normal, except that no increase in affinity for AMPPNP was induced by aurovertin. The uncA F1-ATPases had low but real steady-state rates of ATP hydrolysis, which were inhibited by aurovertin but relatively insensitive to inhibition by AMPPNP, efrapeptin, and sodium azide. Non-steady-state ( unisite ) ATP hydrolysis rates catalyzed at low substrate concentrations by uncA F1-ATPases were similar to normal.(ABSTRACT TRUNCATED AT 250 WORDS)     

The native mitochondrial F1-inhibitor protein complex carries out uni- and multisite ATP hydrolysis

The rate of ATP hydrolysis under multi- and unisite conditions was determined in the native F1-inhibitor protein complex of bovine heart mitochondria (Adolfsen, R., MacClung, J.A., and Moudrianakis, E.N. (1975) Biochemistry 14, 1727-1735). Aurovertin was used to distinguish between hydrolytic activity catalyzed by the F1-ATPase or the F1-inhibitor protein (F1.I) complex. We found that incubation of aurovertin with the F1.I complex, prior to the addition of substrate, results in a stimulation of the hydrolytic activity from 1 to 8-10 mumol min-1 mg-1. The addition of aurovertin to a F1.I complex simultaneously with ATP results in a 30% inhibition with respect to the untreated F1.I. In contrast, if the F1.I complex is activated up to a hydrolytic activity of 80 mumol min-1 mg-1, aurovertin inhibits the enzyme in a manner similar to that described for F1-ATPase devoid of the inhibitor protein. The native F1.I complex catalyzes the hydrolysis of ATP under conditions for single catalytic site, liberating 0.16-0.18 mol of Pi/mol of enzyme. Preincubation with aurovertin before the addition of substrate had no effect under these conditions. On the other hand, if the F1.I ATPase was allowed to hydrolyze ATP at a single catalytic site, catalysis was inhibited by 98% by aurovertin. In F1-ATPase, the hydrolysis of [gamma-32P]ATP bound to the first catalytic site is promoted by the addition of excess ATP, in the presence or absence of aurovertin. Under conditions for single site catalysis, hydrolysis of [gamma-32P]ATP in the F1.I complex was not promoted by excess ATP. We conclude that the endogenous inhibitor protein regulates catalysis by promoting the entrapment of adenine nucleotides at the high affinity catalytic site, thus hindering cooperative ATP hydrolysis.     

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.     

Does the γ subunit move to an abortive position for ATP hydrolysis when the F1·ADP·Mg complex isomerizes to the inactive F1*·ADP·Mg complex?

F₁-ATPases transiently entrap inhibitory MgADP in a catalytic site during turnover when noncatalytic sites are not saturated with ATP. An initial burst of ATP hydrolysis rapidly decelerates to a slow intermediate rate that gradually accelerates to a final steady-state rate. Transition from the intermediate to the final rate is caused by slow binding of ATP to noncatalytic sites which promotes dissociation of inhibitory MgADP from the affected catalytic site. Evidence from several laboratories suggests that the γ subunit rotates with respect to α/β subunit pairs of F₁-ATPases during ATP hydrolysis. The α₃β₃ and α₃β₃δ subcomplexes of the TF₁-ATPase do not entrap inhibitory MgADP in a catalytic site during turnover, suggesting involvement of the γ subunit in the entrapment process. From these observations, it is proposed that the γ subunit moves into an abortive position for ATP hydrolysis when inhibitory MgADP is entrapped in a catalytic site during ATP hydrolysis.     

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.     

Nitrogenase of Klebsiella pneumoniae. Kinetic studies on the Fe protein involving reduction by sodium dithionite, the binding of MgADP and a conformation change that alters the reactivity of the 4Fe-4S centre.

The kinetics of reduction of indigocarmine-dye-oxidized Fe protein of nitrogenase from Klebsiella pneumoniae (Kp2ox) by sodium dithionite in the presence and absence of MgADP were studied by stopped-flow spectrophotometry at 23 degrees C and at pH 7.4. Highly co-operative binding of 2MgADP (composite K greater than 4 X 10(10) M-2) to Kp2ox induced a rapid conformation change which caused the redox-active 4Fe-4S centre to be reduced by SO2-.(formed by the predissociation of dithionite ion) with k = 3 X 10(6) M-1.s-1. This rate constant is at least 30 times lower than that for the reduction of free Kp2ox (k greater than 10(8) M-1.s-1). Two mechanisms have been considered and limits obtained for the rate constants for MgADP binding/dissociation and a protein conformation change. Both mechanisms give rate constants (e.g. MgADP binding 3 X 10(5) less than k less than 3 X 10(6) M-1.s-1 and protein conformation change 6 X 10(2) less than k less than 6 X 10(3) s-1) that are similar to those reported for creatine kinase (EC 2.7.3.2). The kinetics also show that in the catalytic cycle of nitrogenase with sodium dithionite as reductant replacement of 2MgADP by 2MgATP occurs on reduced and not oxidized Kp2. Although the Kp2ox was reduced stoichiometrically by SO2-. and bound two equivalents of MgADP with complete conversion into the less-reactive conformation, it was only 45% active with respect to its ability to effect MgATP-dependent electron transfer to the MoFe protein.     

Effect of denaturants on multisite and unisite ATP hydrolysis by bovine heart submitochondrial particles with and without inhibitor protein

The effect of guanidinium hydrochloride (GdnHCl) on multisite and unisite ATPase activity by F0F1 of submitochondrial particles from bovine hearts was studied. In particles without control by the inhibitor protein, 50 mM GdnHCl inhibited multisite hydrolysis by about 85%; full inhibition required around 500 mM. In the range of 500-650 mM, GdnHCl enhanced the rate of unisite catalysis by promoting product release; it also increased the rate of hydrolysis of ATP bound to the catalytic site without GdnHCl. GdnHCl diminished the affinity of the enzyme for aurovertin. The effects of GdnHCl were irreversible. The results suggest that disruption of intersubunit contacts in F0F1 abolishes multisite hydrolysis and stimulates of unisite hydrolysis. Particles under control by the inhibitor protein were insensitive to concentrations of GdnHCl that induce the aforementioned alterations of F0F1 free of inhibitor protein, indicating that the protein stabilizes the global structure of particulate F1.     

The binding mechanism of the yeast F1-ATPase inhibitory peptide: role of catalytic intermediates and enzyme turnover

The mechanism of inhibition of yeast mitochondrial F(1)-ATPase by its natural regulatory peptide, IF1, was investigated by correlating the rate of inhibition by IF1 with the nucleotide occupancy of the catalytic sites. Nucleotide occupancy of the catalytic sites was probed by fluorescence quenching of a tryptophan, which was engineered in the catalytic site (beta-Y345W). Fluorescence quenching of a beta-Trp(345) indicates that the binding of MgADP to F(1) can be described as 3 binding sites with dissociation constants of K(d)(1) = 10 +/- 2 nm, K(d2) = 0.22 +/- 0.03 microm, and K(d3) = 16.3 +/- 0.2 microm. In addition, the ATPase activity of the beta-Trp(345) enzyme followed simple Michaelis-Menten kinetics with a corresponding K(m) of 55 microm. Values for the K(d) for MgATP were estimated and indicate that the K(m) (55 microm) for ATP hydrolysis corresponds to filling the third catalytic site on F(1). IF1 binds very slowly to F(1)-ATPase depleted of nucleotides and under unisite conditions. The rate of inhibition by IF1 increased with increasing concentration of MgATP to about 50 mum, but decreased thereafter. The rate of inhibition was half-maximal at 5 microm MgATP, which is 10-fold lower than the K(m) for ATPase. The variations of the rate of IF1 binding are related to changes in the conformation of the IF1 binding site during the catalytic reaction cycle of ATP hydrolysis. A model is proposed that suggests that IF1 binds rapidly, but loosely to F(1) with two or three catalytic sites filled, and is then locked in the enzyme during catalytic hydrolysis of ATP.     

Adenine nucleotide binding at a noncatalytic site of mitochondrial F1-ATPase accelerates a Mg(2+)- and ADP-dependent inactivation during ATP hydrolysis.

The evidence is presented that the ADP- and Mg(2+)-dependent inactivation of MF1-ATPase during MgATP hydrolysis requires binding of ATP at two binding sites: one is catalytic and the second is noncatalytic. Binding of the noncatalytic ATP increases the rate of the inactive complex formation in the course of ATP hydrolysis. The rate of the enzyme inactivation during ATP hydrolysis depends on the medium Mg2+ concentration. High Mg2+ inhibits the steady-state activity of MF1-ATPase by increasing the rate of formation of inactive enzyme-ADP-Mg2+ complex, thereby shifting the equilibrium between active and inactive enzyme forms. The Mg2+ needed for MF1-ATPase inactivation binds from the medium independent from the MgATP binding at either catalytic or noncatalytic sites. The inhibitory ADP molecule arises at the MF1-ATPase catalytic site as a result of MgATP hydrolysis. Exposure of the native MF1-ATPase with bound ADP at a catalytic site to 1 mM Mg2+ prior to assay inactivates the enzymes with kinact 24 min-1. The maximal inactivation rate during ATP hydrolysis at saturating MgATP and Mg2+ does not exceed 10 min-1. The results show that the rate-limiting step of the MF1-ATPase inactivation during ATP hydrolysis with excess Mg2+ precedes binding of Mg2+ and likely is the rate of formation of enzyme with ADP bound at the catalytic site without bound P(i). This complex binds Mg2+ resulting in inactive MF1-ATPase.(ABSTRACT TRUNCATED AT 250 WORDS)     

Relaxation from rigor of skinned trabeculae of the guinea pig induced by laser photolysis of caged ATP.

The kinetics of ATP-induced rigor cross-bridge detachment were studied by initiating relaxation in chemically skinned trabeculae of the guinea pig heart using photolytic release of ATP in the absence of calcium ions (pCa > 8). The time course of the fall in tension exhibited either an initial plateau phase of variable duration with little change in tension or a rise in tension, followed by a decrease to relaxed levels. The in-phase component of tissue stiffness initially decreased. The rate then slowed near the end of the tension plateau, indicating transient cross-bridge rebinding, before falling to relaxed levels. Estimates of the apparent second-order rate constant for ATP-induced detachment of rigor cross-bridges based on the half-time for relaxation or on the half-time to the convergence of tension records to a common time course were similar at 3 x 10(3) M-1 s-1. Because the characteristics of the mechanical transients observed during relaxation from rigor were markedly similar to those reported from studies of rabbit psoas fibers in the presence of MgADP (Dantzig, J. A., M. G. Hibberd, D. R. Trentham, and Y. E. Goldman. 1991. Cross-bridge kinetics in the presence of MgADP investigated by photolysis of caged ATP in rabbit psoas muscle fibres. J. Physiol. 432:639-680), direct measurements of MgADP using [3H]ATP in cardiac tissue in rigor were made. Results indicated that during rigor, nearly 18% of the cross-bridges in skinned trabeculae had [3H]MgADP bound. Incubation of the tissue during rigor with apyrase, an enzyme with both ADPase and ATPase activity, reduced the level of [3H]MgADP to that measured following a 2-min chase in a solution containing 5 mM unlabeled MgATP. Apyrase incubation also significantly reduced the tension and stiffness transients, so that both time courses became monotonic and could be fit with a simple model for cross-bridge detachment. The apparent second-order rate constant for ATP-induced rigor cross-bridge detachment measured in the apyrase treated tissue at 4 x 10(4) M-1 s-1 was faster than that measured in untreated tissue. Nevertheless, this rate was still over an order of magnitude slower than the analogous rate measured in previous studies of isolated cardiac actomyosin-S1. These results are consistent with the hypothesis that the presence of MgADP bound cross-bridges suppresses the inhibition normally imposed by the thin filament regulatory system in the absence of calcium ions and allows cross-bridge rebinding and force production during relaxation from rigor.     

Characterization of the nucleotide tight-binding sites of the isolated mitochondrial F1-ATPase

The properties of the nucleotides tightly bound with mitochondrial F1-ATPase were examined. One of three bound nucleotide molecules is localized at the site with Kd approximately 10(-7) M and released with koff approximately 0.1 s-1. The second nucleotide molecule is bound with the enzyme with Kd approximately 10(-8) M and koff for its dissociation is 3 X 10(-4) s-1. The third is never released even in the presence of 1 mM ATP or ADP. The last two nucleotides are believed to be bound at the noncatalytic sites of F1-ATPase. Pyrophosphate promotes liberation of two releasable nucleotide molecules, decreasing the affinity of the enzyme to AD(T)P. From the results obtained it follows that the only suitable criterion for localization of the nucleotide at the F1-ATPase catalytic site is the high rate (koff greater than or equal to 0.1 s-1) of its spontaneous release.     

The (alpha F(357)C)(3)(beta R(372)C)(3)gamma subcomplex of the F(1)-ATPase from the thermophilic Bacillus PS3 has altered ATPase activity after cross-linking alpha and beta subunits at noncatalytic site interfaces

In crystal structures of bovine MF(1), the side chains of alpha F(357) and beta R(372) are near the adenines of nucleotides bound to noncatalytic sites. To determine if during catalysis these side chains must pass through the different arrangements in which they are present in crystal structures, the catalytic properties of the (alpha F(357)C)(3)(beta R(372)C)(3)gamma subcomplex of the TF(1)-ATPase were characterized before and after cross-linking the introduced cysteines with CuCl(2). The unmodified mutant enzyme hydrolyzes MgATP at 50% the rate exhibited by wild type. Detailed comparison of the catalytic properties of the double mutant enzyme before and after cross-linking with those of the wild-type subcomplex revealed the following. Before cross-linking, the (alpha F(357)C)(3)(beta R(372)C)(3)gamma subcomplex has less tendency than wild type to release inhibitory MgADP entrapped in a catalytic site during turnover when MgATP binds to noncatalytic sites. Following cross-linking, ATPase activity is reduced 5-fold, and inhibitory MgADP entrapped in a catalytic site during turnover does not release under conditions wherein binding of ATP to noncatalytic sites of the wild-type enzyme promotes release of MgADP from the affected catalytic site. When assayed in the presence of lauryldimethylamine oxide, which prevents turnover-dependent entrapment of inhibitory MgADP in a catalytic site, ATPase activity of the cross-linked form is 47% that of the unmodified mutant enzyme. These results suggest that, during catalysis, the side chains of alpha F(357) and beta R(372) do not pass through the extremely different relative positions in which they exist at the three noncatalytic site interfaces in crystal structures.