H~＋－ATPase单位点水解过程中Fo构象的变化

利用Ｈ＾＋－ＡＴＰ酶复合中的Ｆｏ的色氨酸荧光,观察了复合体中Ｆ１结合ＡＴＰ或ＡＤＰ时,Ｆｏ的荧光猝灭常数的变化结果表明Ｆ１结合ＡＴＰ或ＡＤＰ时Ｆｏ可得到不同的猝来常数,也就是Ｆｏ会产生不同的构象变化。这些结果说明了Ｈ＾＋ＡＴＰ酶合ＡＴＰ合成的过程中Ｆ１与Ｆｏ之间存在着构象之间的通信与传递。     

H~＋－ATPase单位点水解过程中Fo构象的变化

利用Ｈ＋－ＡＴＰ酶复合体（也称ＡＴＰ合成酶）中的Ｆｏ的色氨酸荧光,观察了复合体中Ｆ１结合ＡＴＰ或ＡＤＰ（酶蛋白与底物分子比为１：１）时,Ｆｏ的荧光猝灭常数的变化（用竹红菌乙作为膜区蛋白荧光的猝灭剂）结果表明Ｆ１结合ＡＴＰ或ＡＤＰ时Ｆｏ可得到不同的猝灭常数（Ｋｓｖ）,也就是Ｆｏ会产生不同的构象变化。加入二价金属离子起动ＡＴＰ水解反应结束后：ＡＴＰ＋Ｈ２Ｏ→ＡＤＰ＋Ｐｉ,这时可以在Ｆｏ观察到与ＡＤＰ加Ｍｇ２＋时相同猝灭常数Ｋｓｖ;用荧光强度随时间进程变化的实验可观察到Ｆ１水解过程中导致Ｆｏ构象变化的动力学过程。这些结果说明了Ｈ＋－ＡＴＰ酶复合体ＡＴＰ合成的过程中Ｆ１与Ｆｏ之间存在着构象之间的通信与传递。     

Unisite and multisite catalysis in the ArsA ATPase

The ars operon of plasmid R773 encodes an As(III)/Sb(III) extrusion pump. The catalytic subunit, the ArsA ATPase, has two homologous halves, A1 and A2, each with a consensus nucleotide-binding sequence. ATP hydrolysis is slow in the absence of metalloid and is accelerated by metalloid binding. ArsA M446W has a single tryptophan adjacent to the A2 nucleotide-binding site. Tryptophan fluorescence increased upon addition of ATP, ADP, or a nonhydrolyzable ATP analogue. Mg(2+) and Sb(III) produced rapid quenching of fluorescence with ADP, no quenching with a nonhydrolyzable analogue, and slow quenching with ATP. The results suggest that slow quenching with ATP reflects hydrolysis of ATP to ADP in the A2 nucleotide-binding site. In an A2 nucleotide-binding site mutant, nucleotides had no effect. In contrast, in an A1 nucleotide-binding mutant, nucleotides still increased fluorescence, but there was no quenching with Mg(2+) and Sb(III). This suggests that the A2 site hydrolyzes ATP only when Sb(III) or As(III) is present and when the A1 nucleotide-binding domain is functional. These results support previous hypotheses in which only the A1 nucleotide-binding domain hydrolyzes ATP in the absence of activator (unisite catalysis), and both the A1 and A2 sites hydrolyze ATP when activated (multisite catalysis).     

Conformational dynamics of DnaB helicase upon DNA and nucleotide binding: analysis by intrinsic tryptophan fluorescence quenching

DnaB helicase of E. coli unwinds duplex DNA in the replication fork using the energy of ATP hydrolysis. We have analyzed structural and conformational changes in the DnaB protein in various nucleotides and DNA bound intermediate states by fluorescence quenching analysis of intrinsic fluorescence of native tryptophan (Trp) residues in DnaB. Fluorescence quenching analysis indicated that Trp48 in domain alpha is in a hydrophobic environment and resistant to fluorescence quenchers such as potassium iodide (KI). In domain beta, Trp294 was found to be in a partially hydrophobic environment, whereas Trp456 in domain gamma appeared to be in the least hydrophobic environment. Binding of oligonucleotides to DnaB helicase resulted in a significant attenuation of the fluorescence quenching profile, indicating a change in conformation. ATPgammaS or ATP binding appeared to lead to a conformation in which Trp residues had a higher degree of solvent exposure and fluorescence quenching. However, the most dramatic increase of Trp fluorescence quenching was observed with ADP binding with a possible conformational relaxation. Site-specific Trp --> Cys mutants of DnaB helicase demonstrated that conformational change upon ADP binding could be attributed exclusively to a conformational transition in the alpha domain leading to an increase in the solvent exposure of Trp48. However, formation of DnaB.ATPgammaS.DNA ternary complex led to a conformation with a fluorescence quenching profile similar to that observed with DnaB alone. The DnaB.ADP.DNA ternary complex produced a quenching curve similar to that of DnaB.ADP complex pointing to a change in conformation due to ATP hydrolysis. There are at least four identifiable structural/conformational states of DnaB helicase that are likely important in the helicase activity. The noncatalytic alpha domain in the N-terminus appeared to undergo the most significant conformational changes during nucleotide binding and hydrolysis. This is the first reported elucidation of the putative role of domain alpha, which is essential for DNA helicase action. We have correlated these results with partial structural models of alpha, beta, and gamma domains     

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.     

Tightly bound adenosine diphosphate, which inhibits the activity of mitochondrial F1-ATPase, is located at the catalytic site of the enzyme

The binding of one ADP molecule at the catalytic site of the nucleotide depleted F1-ATPase results in a decrease in the initial rate of ATP hydrolysis. The addition of an equimolar amount of ATP to the nucleotide depleted F1-ATPase leads to the same effect, but, in this case, inhibition is time dependent. The half-time of this process is about 30 s, and the inhibition is correlated with Pi dissociation from the F1-ATPase catalytic site (uni-site catalysis). The F1-ATPase-ADP complex formed under uni-site catalysis conditions can be reactivated in two ways: (i) slow ATP-dependent ADP release from the catalytic site (tau 1/2 20 s) or (ii) binding of Pi in addition to MgADP and the formation of the triple F1-ATPase-MgADP-Pi complex. GTP and GDP are also capable of binding to the catalytic site, however, without changes in the kinetic properties of the F1-ATPase. It is proposed that ATP-dependent dissociation of the F1-ATPase-GDP complex occurs more rapidly, than that of the F1-ATPase-ADP complex.     

Properties of ATP tightly bound to catalytic sites of chloroplast ATP synthase

Under steady state photophosphorylating conditions, each ATP synthase complex from spinach thylakoids contains, at a catalytic site, about one tightly bound ATP molecule that is rapidly labeled from medium 32Pi. The level of this bound [32P]ATP is markedly reduced upon de-energization of the spinach thylakoids. The reduction is biphasic, a rapid phase in which the [32P] ATP/synthase complex drops about 2-fold within 10 s, followed by a slow phase, kobs = 0.01/min. A decrease in the concentration of medium 32Pi to well below its apparent Km for photophosphorylation is required to decrease the amount of tightly bound ATP/synthase found just after de-energization and before the rapid phase of bound ATP disappearance. The [32P]ATP that remains bound after the rapid phase appears to be mostly at a catalytic site as demonstrated by a continued exchange of the oxygens of the bound ATP with water oxygens. This bound [32P]ATP does not exchange with medium Pi and is not removed by the presence of unlabeled ATP. The levels of tightly bound ADP and ATP arising from medium ADP were measured by a novel method based on use of [beta-32P]ADP. After photophosphorylation and within minutes after the rapid phase of bound ATP loss, the measured ratio of bound ADP to ATP was about 1.4 and the sum of bound ADP plus ATP was about 1/synthase. This ratio is smaller than that found about 1 h after de-energization. Hence, while ATP bound at catalytic sites disappears, bound ADP appears. The results suggest that during and after de-energization the bound ATP disappears from the catalytic site by hydrolysis to bound ADP and Pi with subsequent preferential release of Pi. These and related observations can be accommodated by the binding change mechanism for ATP synthase with participation of alternating catalytic sites and are consistent with a deactivated state arising from occupancy of one catalytic site on the synthase complex by an inhibitory ADP without presence of Pi.     

Interaction between aurovertin and adenine nucleotide binding sites on mitochondrial F1-ATPase and the isolated beta subunit

The effect of aurovertin on the binding parameters of ADP and ATP to native F1 from beef heart mitochondria in the presence of EDTA has been explored. Three exchangeable sites per F1 were titrated by ADP and ATP in the absence or presence of aurovertin. Curvilinear Scatchard plots for the binding of both ADP and ATP were obtained in the absence of aurovertin, indicating one high affinity site (Kd for ADP = 0.6-0.8 microM; Kd for ATP = 0.3-0.5 microM) and two lower affinity sites (Kd for ADP = 8-10 microM; Kd for ATP = 7-10 microM). With a saturating concentration of aurovertin capable of filling the three beta subunits of F1, the curvilinearity of the Scatchard plots was decreased for ATP binding and abolished for ADP binding, indicating homogeneity of ADP binding sites in the F1-aurovertin complex (Kd for ADP = 2 microM). When only the high affinity aurovertin site was occupied, maximal enhancement of the fluorescence of the F1-aurovertin complex was attained with 1 mol of ADP bound per mol of F1 and maximal quenching for 1 mol of ATP bound per mol of F1. When the F1-aurovertin complex was incubated with [3H]ADP followed by [14C]ATP, full fluorescence quenching was attained when ATP had displaced the previously bound ADP. In the case of the isolated beta subunit, both ADP and ATP enhanced the fluorescence of the beta subunit-aurovertin complex. The Kd values for ADP and ATP in the presence of EDTA were 0.6 mM and 3.7 mM, respectively; MgCl2 decreased the Kd values to 0.1 mM for both ADP and ATP. It is postulated that native F1 possesses three equivalent interacting nucleotide binding sites and exists in two conformations which are in equilibrium and recognize either ATP (T conformation) or ADP (D conformation). The negative interactions between the nucleotide binding sites of F1 are strongest in the D conformation. Upon addition of aurovertin, the site-site cooperativity between the beta subunits of F1 is decreased or even abolished.     

Movement of Cys-697 in myosin ATPase associated with ATP hydrolysis.

To detect movement of Cys-697 (SH2) in myosin subfragment-1 (S-1) associated with ATP hydrolysis, SH2 was labeled with the environmentally sensitive fluorescent analog of maleimide, 2-(4'-maleimidylanilino)naphthalene-6-sulfonic acid (MIANS). Complex formation of S-1 labeled at Cys-697 with MIANS (MIANS-S-1) with adenyl-5'-yl imidodiphosphate and ADP resulted in a significant decrease in the fluorescence intensity of approximately 40 and 30%, respectively. When ATP was added to MIANS-S-1, the fluorescence intensity decreased rapidly by approximately 40%, and this fluorescence level was maintained during the steady state of ATP hydrolysis. As the substrate was used up, the fluorescence intensity increased to approximately 70% of the original value. These results together with model experiments with MIANS-N-acetylcysteine indicate that in the presence of ATP, the MIANS fluorophore attached to SH2 is located in a less hydrophobic environment than is the fluorophore in the absence of ligand and that the hydrolysis of ATP enhances hydrophobicity around the fluorophore. Acrylamide fluorescence quenching studies of MIANS-S-1 confirmed these results, indicating that addition of ATP and ADP to MIANS-S-1 results in an increase in the Stern-Volmer quenching constant of the fluorophore by factors of approximately 3 and 2.5, respectively. The present observations suggest that binding of ATP causes a movement of SH2 toward the protein surface, whereas it goes back into the protein interior after ATP hydrolysis. The results also confirmed previous observations by a chemical cross-linking approach (Hiratsuka, T. (1987) Biochemistry 26, 3168-3173).     

Characterization of the substrate-induced conformational change of N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine-labeled sarcoplasmic reticulum Ca2(+)-ATPase by using different kinds of substrate

Cys-674 of the sarcoplasmic reticulum Ca2(+)-ATPase was labeled with N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine without a loss of the catalytic activity, and changes in the fluorescence intensity upon addition of seven kinds of substrate were followed by the stopped-flow method. The steady-state fluorescence intensity and anisotropy were also determined. When Ca2+ was present, the fluorescence intensity and anisotropy decreased greatly upon addition of any substrate used. The observed affinity for each substrate agreed with the previously observed affinity of the catalytic site. The fluorescence drop induced by the adenine nucleotides, ATP and adenosine 5'-(beta, gamma-methylene)triphosphate (a nonhydrolyzable ATP analog), was much faster than that induced by other substrates. The ATP-induced fluorescence drop preceded phosphoenzyme formation when the ATP concentration was high, but the fluorescence drop coincided with phosphoenzyme formation when it was slowed by reducing ATP concentrations. The fluorescence drop induced by ITP or acetyl phosphate was slow even at high concentrations of the substrate, and it coincided with phosphoenzyme formation. When Ca2+ was absent, the fluorescence intensity and anisotropy decreased only slightly upon addition of any substrate other than the adenine nucleotides. They decreased substantially upon addition of the adenine nucleotides, but the kinetics of this fluorescence drop were quite different from that of the fluorescence drop induced by any substrate in the presence of Ca2+. These results show that the conformational change, which makes the bound label less constrained, is induced by substrate binding to the catalytic site of the Ca2(+)-activated enzyme. This change precedes phosphoenzyme formation in the catalytic cycle and is greatly accelerated by the adenine moiety of the substrate.     

Detection of conformational changes in chloroplast coupling factor 1 by 8-anilino-1-naphthalene-sulphonate fluorescence changes

Chloroplast coupling factor 1 (CF1) contains a high-affinity binding site for 8-anilino-1-napthalene sulphonate (ANS,Kd = 5-6 microM). The binding of ANS to the enzyme is associated with a fluorescence enhancement and a blue-shift in the emission spectrum. ANS only slightly inhibits ATP hydrolysis by CF1. Adenine nucleotides and inorganic phosphate induce a fast ANS fluorescence quenching of about 50% which is due to a decrease in the affinity of the enzyme for ANS (Kd increases from 6 microM to 22 microM) and in the fluorescence quantum yield of the bound probe (by 33%) but not in the number of ANS sites (n = 1). Conversely, Mg and Ca ions induce a fluorescence enhancement of bound ANS. Inactivation of the enzyme enhances ANS fluorescence, eliminates the response to adenine nucleotides and inorganic phosphate but increases the response to divalent metals. The affinity of latent CF1 for ADP (Kd = 12 microM) is considerably higher than for ATP (Kd = 95 microM) in buffer containing EDTA. The Kd for inorganic phosphate is 140 microM. Mg increases the apparent affinity for ATP (Kd = 28 microM) but not for ADP or Pi. Binding of ATP to the tight-sites does not inhibit the ADP or Pi-induced fluorescence quenching but decreases the affinity for ADP (Kd = 34 microM) and for inorganic phosphate (Kd = 320 microM). These results suggest that the ADP and phosphate binding sites are different but not independent from the tight sites. Activation of a Mg-specific ATPase in CF1 by octyl glucoside decreases the affinity for ADP and inorganic phosphate by about threefold but increases the affinity for ATP. ATPase activation of CF1 also increases the Ki for ADP inhibition of ATP hydrolysis. ATPase activation also influences the ANS responses to Ca and Mg. Ca-ATPase activation increases the fluorescence enhancement and the apparent affinity for Ca whereas Mg-ATPase activation specifically increases the Mg-induced fluorescence enhancement. The fluorescence of CF1-bound ANS is enhanced by Dio-9 and quenched by phloridzin, quercetin, Nbf-Cl and FITC. Nbf-Cl and FITC completely inhibit the ADP-induced fluorescence quenching whereas Dio-9 inhibits the Mg-induced fluorescence enhancement. ANS does not relieve the quercetin or phloridzin inhibition of ATP hydrolysis indicating that these inhibitors do not compete with ANS for a common binding site. ANS may be used, therefore, as a sensitive probe to detect conformational changes in CF1 in response to activation or inactivation and to binding of substrates and of inhibitors.     

ATP hydrolysis-driven H+ translocation is stimulated by sulfate, a strong inhibitor of mitochondrial ATP synthesis

Sulfate is a partial inhibitor at low and a non-essential activator at high [ATP] of the ATPase activity of F(1). Therefore, a catalytically-competent ternary F(1) x ATP x sulfate complex can be formed. In addition, the ANS fluorescence enhancement driven by ATP hydrolysis in submitochondrial particles is also stimulated by sulfate, clearly showing that the ATP hydrolysis in its presence is coupled to H(+) translocation. However, sulfate is a strong linear inhibitor of the mitochondrial ATP synthesis. The inhibition was competitive (K (i) = 0.46 mM) with respect to Pi and mixed (K (i) = 0.60 and K'(i) = 5.6 mM) towards ADP. Since it is likely that sulfate exerts its effects by binding at the Pi binding subdomain of the catalytic site, we suggest that the catalytic site involved in the H(+) translocation driven by ATP hydrolysis has a more open conformation than the half-closed one (beta(HC)), which is an intermediate in ATP synthesis. Accordingly, ATP hydrolysis is not necessarily the exact reversal of ATP synthesis.     

Characterization of nucleotide binding sites on the membrane-bound chloroplast ATP synthase (coupling factor CF1)

Phosphorylation of ADP and nucleotide exchange by membrane-bound coupling factor CF₁ are very fast reactions in the light, so that a direct comparison of both reactions is difficult. By adding substrate ADP and phosphate to illuminated thylakoids together with the uncoupler FCCP, the phosphorylation time is limited and the amount of ATP formed can be reduced to less than 1 ATP per enzyme. Low concentrations of medium nucleotides during illumination increase the amount of ATP formed during uncoupling presumably by binding to the tight nucleotide binding site (further designated as ‘site A’) with an affinity of 1 to 7 μM for ADP and ATP. ATP formation itself shows half-saturation at about 30 μM. Loosely bound nucleotides are exchanged upon addition of nucleotides with uncoupler (Schumann, J. (1984) Biochim. Biophys. Acta 766, 334–342). Release depends binding of nucleotides to a second site. The affinity of this site for ADP (in the presence of phosphate) is about 30 μM. It is assumed that phosphorylation and induction of exchange both occur on the same site (site B). During ATP hydrolysis, an ATP molecule is bound to site A, while on another site, ATP is hydrolyzed rapidly. The affinity of ADP for the catalytic site (70 μM) is in the same range as the observed Michaelis constant of ADP during phosphorylation; it is assumed that site B is involved in ATP hydrolysis. Site A exhibits some catalytic activity; it might be that site A is involved in ATP formation in a dual-site mechanism. For ATP hydrolysis, however, direct determination of exchange rates showed that the exchange rate of ATP bound to site A is about 30-times lower than ATP hydrolysis under the same conditions.     

The fluorescence spectrum of the introduced tryptophans in the alpha 3(beta F155W)3gamma subcomplex of the F1-ATPase from the thermophilic Bacillus PS3 cannot be used to distinguish between the number of nucleoside di- and triphosphates bound to catalytic sites.

It has been reported that shifts in the fluorescence emission spectrum of the introduced tryptophans in the betaF155W mutant of Escherichia coli F(1) (bovine heart mitochondria F(1) residue number) can quantitatively distinguish between the number of catalytic sites occupied with ADP and ATP during steady-state ATP hydrolysis (Weber, J., Bowman, C., and Senior, A. E. (1996) J. Biol. Chem. 271, 18711--18718). In contrast, addition of MgADP, Mg-5'-adenylyl beta,gamma-imidophosphate (MgAMP-PNP), and MgATP in 1:1 ratios to the alpha(3)(betaF155W)(3)gamma subcomplex of thermophilic Bacillus PS3 F(1) (TF(1)) induced nearly identical blue shifts in the fluorescence emission maximum that was accompanied by quenching. Addition of 2 mm MgADP induced a slightly greater blue shift and a slight increase in intensity over those observed with 1:1 MgADP. However, addition of 2 mm MgAMP-PNP or MgATP induced a much greater blue shift and substantially enhanced fluorescence intensity over those observed in the presence of stoichiometric MgADP or MgAMP-PNP. It is clear from these results that the fluorescence spectrum of the introduced tryptophans in the betaF155W mutant of TF(1) does not respond in regular increments at any wavelength as catalytic sites are filled with nucleotides. The fluorescence spectrum observed after entrapping MgADP-fluoroaluminate complexes in two catalytic sites of the betaF155W subcomplex indicates that the fluorescence emission spectrum of the enzyme is maximally perturbed when nucleotides are bound to two catalytic sites. This finding is consistent with accumulating evidence suggesting that only two beta subunits in the alpha(3)beta(3)gamma subcomplex of TF(1) can simultaneously exist in the completely closed conformation.     

Reactions of a fluorescent ATP analog, 2'-(5-dimethyl-aminonaphthalene-1-sulfonyl) amino-2'-deoxyATP, with E. coli F1-ATPase and its subunits: the roles of the high affinity binding site in the alpha subunit and the low affinity binding site in the beta subunit

We performed kinetic studies on the reactions of a fluorescent ATP analog, 2'-(5-dimethyl-aminonaphthalene-1-sulfonyl) amino-2'-deoxyATP (DNS-ATP), with E. coli F1-ATPase (EF1) and its subunits, to clarify the role of each subunit in the ATPase reaction. The following results were obtained. 1. One mol of EF1, which contains nonexchangeable 2 mol ATP and 0.5 mol ADP, binds 3 mol of DNS-ATP. The apparent dissociation constant, in the presence of Mg2+, was 0.23 microM. Upon binding, the fluorescence intensity of DNS-ATP at 520 nm increased exponentially with t1/2 of 35 s, and reached 3.5 times the original fluorescence level. Following the fluorescence increase, DNS-ATP was hydrolyzed, and the fluorescence intensity maintained its enhanced level. 2. The addition of an excess of ATP over the EF1-DNS-nucleotide complex, in the presence of Mg2+, decreased the fluorescence intensity rapidly, indicating the acceleration of DNS-nucleotide release from EF1. ADP and GTP also decreased the fluorescence intensity. 3. DCCD markedly inhibited the accelerating effect of ATP on DNS-nucleotide release from EF1 and the EF1-DNS-ATPase or -ATPase activity in a steady state. On the other hand, DCCD only slightly inhibited the fluorescence increase of DNS-ATP, due to its binding to EF1, and the rate of single cleavage of 1 mol of DNS-ATP per mol of alpha subunit of EF1. 4. In the presence of Mg2+, 0.65-0.82 mol of DNS-ATP binds to 1 mol of the isolated alpha subunit of EF1 with an apparent dissociation constant of 0.06-0.07 microM. Upon binding, the fluorescence intensity of DNS-ATP at 520 nm increased 1.55 fold very rapidly (t1/2 less than 1 s). No hydrolysis of DNS-ATP was observed upon the addition of the isolated alpha subunit. The fluorescence intensity of DNS-ATP was unaffected by the addition of the isolated beta subunit. DNS-ATP was also unhydrolyzed by the isolated beta subunit. 5. EF1-ATPase was reconstituted from alpha, beta, and gamma subunits in the presence of Mg2+ and ATP. The kinetic properties of the fluorescence change of DNS-ATP in the reaction with the reconstituted EF1-ATPase were quite similar to those of native EF1. Most of our findings are consistent with a simple mechanism that the high affinity catalytic site and low affinity regulatory site exist in the alpha subunit and beta subunit, respectively. However, the findings mentioned in (4) suggest that the binding of the alpha and beta subunit, which is mediated by the gamma subunit, induces conformational change(s) in the ATP binding site located probably in the alpha subunit, and that the conformational change(s) is essential to exert the full hydrolyzing activity.     

Covalent modification of the catalytic sites of the H(+)-ATPase from chloroplasts, CF(0)F(1), with 2-azido-[alpha-(32)P]ADP: modification of the catalytic site 2 (loose) and the catalytic site 3 (open) impairs multi-site, but not uni-site catalysis of both ATP synthesis and ATP hydrolysis

The H(+)-ATPase from chloroplasts, CF(0)F(1), was isolated and purified. The enzyme contained one endogenous ADP at a catalytic site, and two endogenous ATP at non-catalytic sites. Incubation with 2-azido-[alpha-(32)P]AD(T)P leads to a tight binding of the azido-nucleotides. Free nucleotides were removed by three consecutive passages through centrifugation columns, and after UV-irradiation, the label was covalently bound. The labelled enzyme was digested by trypsin, the peptides were separated by ion exchange chromatography into nitreno-AMP, nitreno-ADP and nitreno-ATP labelled peptides, and these were then separated by reversed phase chromatography. Amino acid sequence analysis was used to identify the type of the nucleotide binding site. After incubation with 2-azido-[alpha-(32)P]ADP, the covalently bound label was found exclusively at beta-Tyr-362, i.e. binding occurs only to catalytic sites. Incubation conditions with 2-azido-[alpha-(32)P]ADP were varied, and conditions were found which allow selective binding of the label to different catalytic sites, either to catalytic site 2 or to catalytic site 3. For measurements of the degree of inhibition by covalent modification, CF(0)F(1) was reconstituted into phosphatidylcholine liposomes, and the membranes were energised by an acid-base transition in the presence of a K(+)/valinomycin diffusion potential. The rate of ATP synthesis was 120 s(-1), and the rate of ATP hydrolysis was 20 s(-1), both measured under multi-site conditions. Covalent modification of either catalytic site 2 or catalytic site 3 inhibited both ATP synthesis and ATP hydrolysis, the degree of inhibition being proportional to the degree of modification. Extrapolation to complete inhibition indicates that modification of one catalytic site, either site 2 or site 3, is sufficient to completely block multi-site ATP synthesis and ATP hydrolysis. The rate of ATP synthesis and the rate of ATP hydrolysis were measured as a function of the substrate concentration from multi-site to uni-site conditions with covalently modified CF(0)F(1) and with non-modified CF(0)F(1). The result was that uni-site ATP synthesis and ATP hydrolysis were not inhibited by covalent modification of either catalytic site 2 or site 3. The results indicate cooperative interactions between catalytic nucleotide binding sites during multi-site catalysis, whereas neither uni-site ATP synthesis nor uni-site ATP hydrolysis require interaction with other sites.     

Covalent modification of the catalytic sites of the H+-ATPase from chloroplasts and 2-nitreno-ADP. Modification of the catalytic site 1 (tight) and catalytic sites 1 and 2 together impairs both uni-site and multi-site catalysis of ATP synthesis and ATP hydrolysis

After isolation and purification, the H+-ATPase from chloroplasts, CF0F1, contains one endogenous ADP at a catalytic site, and two endogenous ATP at non-catalytic sites. Incubation with 2-azido-[alpha-32P]ADP leads to tight binding of azidonucleotides. Free nucleotides were removed by three consecutive passages through centrifugation columns, and upon UV-irradiation most of the label was covalently bound. The labelled enzyme was digested by trypsin, the peptides were separated by ion exchange chromatography into nitreno-AMP, nitreno-ADP and nitreno-ATP labelled peptides, and these were then separated by reversed phase chromatography. Amino acid sequence analysis was used to identify the type of the nucleotide binding site. After incubation with 2-azido-[alpha-32P]ADP, the covalently bound label was found exclusively at beta-Tyr-362. Incubation conditions with 2-azido-[alpha-32P]ADP were varied, and conditions were found which allow selective binding of the label to different catalytic sites, designated as 1, 2 and 3 in order of decreasing affinity for ADP, and either catalytic site 1 or catalytic sites 1 and 2 together were labelled. For measurements of the degree of inhibition by covalent modification, CF0F1 was reconstituted into phosphatidylcholine liposomes, and the membranes were energised by an acid-base transition in the presence of a K+/valinomycin diffusion potential. The rate of ATP synthesis was 50-80 s(-1), and the rate of ATP hydrolysis was 15 s(-1) measured under multi-site conditions. Covalent modification of either catalytic site 1 or catalytic sites 1 and 2 together inhibited ATP synthesis and ATP hydrolysis equally, the degree of inhibition being proportional to the degree of modification. Extrapolation to complete inhibition indicates that derivatisation of catalytic site 1 leads to complete inhibition when 1 mol 2-nitreno-ADP is bound per mol CF0F1. Derivatisation of catalytic sites 1 and 2 together extrapolates to complete inhibition when 2 mol 2-nitreno-ADP are bound per CF0F1. The rate of ATP synthesis and the rate of ATP hydrolysis were measured as a function of the substrate concentration from multi-site to uni-site conditions with derivatised CF0F1 and with non-derivatised CF0F1. ATP synthesis and ATP hydrolysis under uni-site and under multi-site condition were inhibited by covalent modification of either catalytic site 1 or catalytic sites 1 and 2 together. The results indicate that derivatisation of site 1 inhibits activation of the enzyme and that cooperative interactions occur at least between the catalytic sites 2 and 3.     

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.     

Location of lysine-beta 162 in mitochondrial F1-adenosinetriphosphatase

The quenching of the fluorescence of bovine heart F1-adenosinetriphosphatase labeled specifically at its essential Lys-beta 162 with 7-chloro-4-nitro-2,1,3-benzoxadiazole (N-NBD-F1) by 2',3'-O-(2,4,6-trinitrocyclohexadienylidene)adenosine 5'-triphosphate (TNP-ATP) has been studied. Analysis of the fluorescence data in the presence of 1 mM ATP shows that the dissociation constant of TNP-ATP from its first binding site in the covalently labeled enzyme is 250-fold lower than that of ATP, which it replaces in pH 7.0 buffer containing 25% glycerol, and that this binding causes a 54% quenching of the fluorescence of the N-NBD label due to energy transfer to the weakly fluorescent TNP-ATP molecule. Computation based on the observed quenching gives a distance of 25.6 +/- 0.4 A between the NBD label and the chromophore of the bound TNP-ATP molecule. Since the distance between the chromophore and the farthest O atom of the bound TNP-ATP is about 16 A, it seems quite likely that the epsilon-amino group of Lys-beta 162 is near the gamma-phosphate group of the TNP-ATP bound at the catalytic site. Similar measurements in the presence of 1 mM ADP show that the replacement of ADP at the catalytic site by TNP-ATP causes a 49% quenching of the fluorescence of the N-NBD label, which gives a distance of 26.5 +/- 0.4 A between the label and the chromophore of the bound TNP-ATP molecule.     

ATP synthase: what we know about ATP hydrolysis and what we do not know about ATP synthesis

In ATP synthase, X-ray structures, demonstration of ATP-driven gamma-subunit rotation, and tryptophan fluorescence techniques to determine catalytic site occupancy and nucleotide binding affinities have resulted in pronounced progress in understanding ATP hydrolysis, for which a mechanism is presented here. In contrast, ATP synthesis remains enigmatic. The molecular mechanism by which ADP is bound in presence of a high ATP/ADP concentration ratio is a fundamental unknown; similarly P(i) binding is not understood. Techniques to measure catalytic site occupancy and ligand binding affinity changes during net ATP synthesis are much needed. Relation of these parameters to gamma-rotation is a further goal. A speculative model for ATP synthesis is offered.