Relationship of tightly bound ADP and ATP to control and catalysis by chloroplast ATP synthase

Whether the tightly bound ADP that can cause a pronounced inhibition of ATP hydrolysis by the chloroplast ATP synthase and F1 ATPase (CF1) is bound at catalytic sites or at noncatalytic regulatory sites or both has been uncertain. We have used photolabeling by 2-azido-ATP and 2-azido-ADP to ascertain the location, with Mg2+ activation, of tightly bound ADP (a) that inhibits the hydrolysis of ATP by chloroplast ATP synthase, (b) that can result in an inhibited form of CF1 that slowly regains activity during ATP hydrolysis, and (c) that arises when low concentrations of ADP markedly inhibit the hydrolysis of GTP by CF1. The data show that in all instances the inhibition is associated with ADP binding without inorganic phosphate (Pi) at catalytic sites. After photophosphorylation of ADP or 2-azido-ADP with [32P]Pi, similar amounts of the corresponding triphosphates are present on washed thylakoid membranes. Trials with appropriately labeled substrates show that a small portion of the tightly bound 2-azido-ATP gives rise to covalent labeling with an ATP moiety at noncatalytic sites but that most of the bound 2-azido-ATP gives rise to covalent labeling by an ADP moiety at a catalytic site. We also report the occurrence of a 1-2-min delay in the onset of the Mg2+-induced inhibition after addition of CF1 to solutions containing Mg2+ and ATP, and that this delay is not associated with the filling of noncatalytic sites. A rapid burst of Pi formation is followed by a much lower, constant steady-state rate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Source of rapidly labeled ATP tightly to non-catalytic sites on the chloroplast ATP synthetase

Bound [32P]ATP is found on deenergized, washed chloroplast thylakoids which were illuminated in the presence of ADP and [32P]Pi. Tight binding of [32P]ATP occurred both during and after energization. Different classes of bound [32P]ATP were distinguished on the basis of their rates of formation, susceptibility to hexokinase and displacement by unlabeled ATP. 1. The rates of formation and discharge of the rapidly labeled tightly bound ATP class were much lower than that of ATP formation. The level of this bound ATP saturates at lower concentrations of substrates than does the rate of phosphorylation. Unlabeled ATP, present in the reaction medium, displaces the rapidly labeled tightly bound ATP without affecting the rate of phosphorylation. 2. We therefore conclude that the rapidly labeled bound ATP class does not fulfill the requirements expected for a catalytic intermediate and that the nucleotide tight binding site(s) on the ATP synthetase differ from the catalytic site(s) for ATP formation. 3. Since the rapidly labeled tightly bound [32P]ATP is not abolished by high concentrations of hexokinase, but is nevertheless displaced by exogenous ATP, we propose that tight binding of ATP to non-catalytic sites occurs via a free species of newly synthesized ATP which diffuses slowly to the medium from a space accessible to ATP but not to hexokinase.     

Catalytic and regulatory effects of light intensity on chloroplast ATP synthase

The incorporation of water oxygens into ATP made by photophosphorylation is known to be increased markedly when either Pi or ADP concentration is lowered. The present studies show a similar increase in oxygen exchange when light intensity is lowered even with ample ADP and Pi present. The number of reversals of bound ATP formation prior to release increases about 1 to about 27 in the presence of dithiothreitol and to 5 in its absence. The equilibrium of the bound reactants still favors ATP at low light intensity, as shown by measurement of the amount of bound ATP rapidly labeled from [32P]Pi during steady-state photophosphorylation. Changes observed in the interconversion rate in the absence of added thiol are likely involved in the regulation of the dark ATPase activity in the chloroplast. The interconversion rate of bound ATP to bound ADP and Pi in the presence of thiol is about the same at low and high light intensities. This rate of bound ATP formation is not sufficient, however, to account for the maximum rate of photophosphorylation. Thus, when adequate protonmotive force is present, the rate of conversion of bound ADP and Pi to bound ATP, and possibly that of bound ATP to bound ADP and Pi, must be increased, with proton translocation being completed only when bound ATP is present to be released. These observations are consistent with the predictions of the binding change mechanism with sequential participation of catalytic sites and are accommodated by a simplified general scheme for the binding change mechanism that is presented here.(ABSTRACT TRUNCATED AT 250 WORDS)     

Bound adenosine 5'-triphosphate formation, bound adenosine 5'-diphosphate and inorganic phosphate retention, and inorganic phosphate oxygen exchange by chloroplast adenosinetriphosphatase in the presence of Ca2+ or Mg2+

When the heat-activated chloroplast F1 ATPase hydrolyzes [3H, gamma-32P]ATP, followed by the removal of medium ATP, ADP, and Pi, the enzyme has labeled ATP, ADP, and Pi bound to it in about equal amounts. The total of the bound [3H]ADP and [3H]ATP approaches 1 mol/mol of enzyme. Over a 30-min period, most of the bound [32P]Pi falls off, and the bound [3H]ATP is converted to bound [3H]ADP. Enzyme with such remaining tightly bound ADP will form bound ATP from relatively high concentrations of medium Pi with either Mg2+ or Ca2+ present. The tightly bound ADP is thus at a site that retains a catalytic capacity for slow single-site ATP hydrolysis (or synthesis) and is likely the site that participates in cooperative rapid net ATP hydrolysis. During hydrolysis of 50 microM [3H]ATP in the presence of either Mg2+ or Ca2+, the enzyme has a steady-state level of about one bound [3H]ADP per mole of enzyme. Because bound [3H]ATP is also present, the [3H]ADP is regarded as being present on two cooperating catalytic sites. The formation and levels of bound ATP, ADP, and Pi show that reversal of bound ATP hydrolysis can occur with either Ca2+ or Mg2+ present. They do not reveal why no phosphate oxygen exchange accompanies cleavage of low ATP concentrations with Ca2+ in contrast to Mg2+ with the heat-activated enzyme. Phosphate oxygen exchange does occur with either Mg2+ or Ca2+ present when low ATP concentrations are hydrolyzed with the octyl glucoside activated ATPase. Ligand binding properties of Ca2+ at the catalytic site rather than lack of reversible cleavage of bound ATP may underlie lack of oxygen exchange under some conditions.     

Rates of various reactions catalyzed by ATP synthase as related to the mechanism of ATP synthesis.

The forward and reverse rates of the overall reaction catalyzed by the ATP synthase in intact rat heart mitochondria, as measured with 32P, were compared with the rates of two partial steps, as measured with 18O. Such rates have been measured previously, but their relationship to one another has not been determined, nor have the partial reactions been measured in intact mitochondria. The partial steps measured were the rate of medium Pi formation from bound ATP (in state 4 this also equals the rate of medium Pi into bound ATP) and the rate of formation of bound ATP from bound Pi within the catalytic site. The rates of both partial reactions can be measured by 31P NMR analysis of the 18O distribution in Pi and ATP released from the enzyme during incubation of intact mitochondria with highly labeled [18O]Pi. Data were obtained in state 3 and 4 conditions with variation in substrate concentrations, temperature, and mitochondrial membrane electrical potential gradient (delta psi m). Although neither binding nor release of ATP is necessary for phosphate/H2O exchange, in state 4 the rate of incorporation of at least one water oxygen atom into phosphate is approximately twice the rate of the overall reaction rate under a variety of conditions. This can be explained if the release of Pi or ATP at one catalytic site does not occur, unless ATP or Pi is bound at another catalytic site. Such coupling provides strong support for the previously proposed alternating site mechanism. In state 3 slow reversal of ATP synthesis occurs within the mitochondrial matrix and can be detected as incorporation of water oxygen atoms into medium Pi even though medium [32P]ATP does not give rise to 32Pi in state 3. These data can be explained by lack of translocation of ATP from the medium to the mitochondrial matrix. The rate of bound ATP formation from bound Pi at catalytic sites was over twice the rate of the overall reaction in both states 4 and 3. The rate of reaction at the catalytic site is considerably less sensitive to the decrease in membrane potential and the concentration of medium ADP than is the rate of medium ATP formation. This supports the view that the active catalytic site is occluded and proceeds at a rapid rate which is relatively independent of delta psi m and of media substrates.     

Demonstration and quantitation of catalytic and noncatalytic bound ATP in submitochondrial particles during oxidative phosphorylation.

Techniques are described for studying the labeling of ADP and ATP bound to the ATP synthase complex of beef heart submitochondrial particles catalyzing oxidative phosphorylation. These suffice for measurements of bound nucleotides during the time required for a single turnover, during steady state net ATP synthesis, or under quasiequilibrium conditions of ATP formation and hydrolysis. Results show that the "tightly bound" ATP associated with isolated submitochondrial particles does not become labeled by medium [32P]Pi rapidly enough to qualify as an intermediate in ATP synthesis. In contrast to chloroplast preparations, little or no bound [32P]Pi committed to ATP formation is present on particles during steady state synthesis. Also, highly active particles synthesizing ATP from [32P]Pi and filtered after EDTA addition have no detectable bound [32P]ATP even though several ATPs have been made per synthase complex. However, under quasiequilibrium conditions membrane-bound ADP and ATP are present whose labeling characteristics qualify them as intermediates in ATP synthesis. In addition, a hexokinase-accessibility approach shows the presence of a steady level of bound ATP. Lack of detection of bound intermediates under other conditions is regarded as reflecting the ready reversibility of oxidative phosphorylation, with consequent facile cleavage of bound ATP and release of bound Pi.     

Localization of the high-affinity binding site for ATP on the membrane-bound chloroplast ATP synthase

The photoaffinity analog 2-azido-ADP has been used to investigate the high-affinity binding site(s) for ATP on the chloroplast thylakoid membrane. Photophosphorylation of 2-azido-ADP results in the rapid formation of 2-azido-ATP, which remains tightly bound to the membranes after extensive washing. The kinetic parameters of the tight binding of ATP and of 2-azido-ATP are similar (apparent Km = 1-2 microM; maximum extent = 0.2-0.4 nmol/mg of chlorophyll). Ultraviolet irradiation of washed thylakoid membranes containing tightly bound 2-azido-[gamma-32P]ATP induces covalent incorporation of the label exclusively into the beta subunit of the chloroplast coupling factor one. Previous results have shown that the tight binding site for ADP is also located on the beta subunit of the ATP synthase (Czarnecki, J. J., Abbott, M. S., and Selman, B. R. (1983) Eur. J. Biochem. 136, 19-24). To further characterize the tight binding sites for ADP and ATP, the membrane-bound coupling factor has been covalently modified with either tightly bound 2-azido-[gamma-32P]ATP or tightly bound 2-azido-[beta-32P]ADP. The photolabeled beta subunits have been isolated and subjected to partial proteolytic digestion and SDS-gel electrophoresis. The results of these experiments demonstrate that the tight binding sites for ADP and ATP are located on identical portions of beta subunit polypeptide.     

Nucleotide-free kinesin hydrolyzes ATP with burst kinetics

Bovine brain kinesin binds ADP tightly and contains a stoichiometric amount of ADP at its active site when isolated in the presence of free Mg2+ (Hackney, D. D. (1988) Proc. Natl. Acad. Sci. U.S.A. 85, 6314-6318). EDTA in excess of Mg2+ weakens ADP binding and nucleotide-free kinesin can be prepared by gel filtration with excess EDTA. On addition of ATP, this nucleotide-free enzyme catalyzes the rapid hydrolysis of a stoichiometric amount of ATP in a burst phase followed by much slower continued ATP hydrolysis limited by the release of ADP from the active site. This burst reaction is evident both by formation of [32P]Pi from [gamma-32P]ATP and by formation of [alpha-32P]ADP from [alpha-32P]ATP. At 1.1 nM kinesin active sites, the observed rate of the burst phase increases linearly with ATP over the 1-20 nM range yielding a bimolecular rate of net ATP binding and hydrolysis of 2.5 microM-1 s-1. The intercept at zero ATP is 0.008 s-1 which equals the ADP release rate at 0.008-0.009 s-1. This predicts a Km for ATP of approximately 3.5 nM and measurements of the dependence on ATP concentration of the steady state rate and amount of bound ADP are consistent with a Km of this magnitude.     

A study on the exchange of tightly bound nucleotides on the membrane-associated chloroplast ATP synthase complex

Light-induced exchange of tightly bound ADP on the membrane-associated chloroplast coupling factor 1 (CF₁) was concluded to be a two-step mechanism involving a loose enzyme-ADP complex (Strotmann, H., Bickel-Sandkötter, S. and Shoshan, V. (1979) FEBS Lett. 101, 316–320). Rapid binding of [¹⁴C]ADP to the coupling factor after deenergization of thylakoids which were illuminated in the presence of [¹⁴C]ADP was suggested to reflect the conversion of loosely bound to tightly bound ADP. Experimental data of the present paper support the assumption of an intermediate enzyme form with loosely bound ADP: (a) the amplitude of the rapid binding phase is independent on the concentration of uncoupler added in the light; (b) the amplitude is virtually unaffected by dilution of the medium [¹⁴]CADP concentration; (c) high concentrations of unlabeled ADP are required to reduce the rapid binding phase while binding of medium [¹⁴C]ADP is inhibited by unlabeled ADP in the micromolar range. These results exclude the possibility that the rapid initial formation of tightly bound [¹⁴C]ADP on deenergization might be caused by an energized nucleotide-free enzyme form which is able to pick up [¹⁴C]ADP from the medium at a higher rate than the deenergized nucleotide-free form. At saturating [¹⁴C]ADP concentrations in the light, the amount of the loose enzyme-ADP complex is about 35%, while 65% of the coupling factors contain a tightly bound ADP. Dissociation of the loose complex is slow in the absence of medium nucleotides but accelerated if ADP is present, suggesting that ADP binding to another site of the enzyme promotes release of the former ADP molecule. The significance of the loosely bound nucleotide in the catalytic mechanism is discussed.     

Uni-site ATP synthesis in thylakoids

Uni-site ATP synthesis was measured with thylakoids. The membrane-bound ATP-synthase, CF0F1, was brought into the active, reduced state by illumination in the presence of thioredoxin, dithiothreitol and phosphate. This enzyme contains two tightly bound ATP per CF0F1. ATP was released from the enzyme when ADP was added in substoichiometric amounts during illumination. Experiments with [14C]ADP indicated that after binding the same nucleotide was phosphorylated and released as [14C]ATP, i.e. only one site is involved in ATP-synthesis ('uni-site ATP-synthesis'). The two tightly bound ATP are not involved in the catalytic turnover. The rate constant for ADP binding was (4 +/- 2) x 10(6) M-1s-1. Compared to deenergized conditions the rate constant for ADP binding and that for ATP-release were drastically increased, i.e. membrane energization increased the rate constants for the ATP-synthesis direction.     

The role of tightly bound ADP on chloroplast ATPase

Isolated chloroplast coupling factor 1 ATPase is known to retain about 1 mol of tightly bound ADP/mol of enzyme. Some experimental results have given evidence that the bound ADP is at catalytic sites, but this view has not been supported by observations of a slow replacement of the bound ADP when CaATP or MgATP is added. The experiments reported in this paper show why a slow replacement of ADP bound at a catalytic site can occur. When coupling factor 1, labeled with tightly bound [3H]ADP, is exposed to Mg2+ or Ca2+ prior to the addition of MgATP or CaATP, a pronounced lag in the onset of ATP hydrolysis is observed, and only slow replacement of the [3H]ADP occurs. Mg2+ or Ca2+ can induce inhibition very rapidly, as if an inhibited form of the enzyme results whenever the enzyme with tightly bound ADP encounters Mg2+ or Ca2+ prior to ATP. The inhibited form can be slowly reactivated by incubation with EDTA, although some irreversible loss in activity is encountered. In contrast, when MgATP or CaATP is added to enzyme depleted of Mg2+ and Ca2+ by incubation with EDTA, a rapid onset of ATP hydrolysis occurs and most of the tightly bound [3H]ADP is released within a few seconds, as expected for binding at a catalytic site. The Mg2+-induced inhibition of both the ATPase activity and the lack of replacement of tightly bound [3H] ADP can be largely prevented by incubation with Pi under conditions favoring Pi addition to the site containing the tightly bound ADP. Our and other results can be explained if enzyme catalysis is greatly hindered when MgADP or CaADP without accompanying Pi is tightly bound at one of the three catalytic sites on the enzyme in a high affinity conformation.     

Characteristics of the formation of enzyme-bound ATP from medium inorganic phosphate by mitochondrial F1 adenosinetriphosphatase in the presence of dimethyl sulfoxide

Addition of dimethyl sulfoxide promotes the formation of enzyme-bound ATP from medium Pi by mitochondrial F1 adenosinetriphosphatase that has tightly bound ADP present. Measurements are reported of medium Pi in equilibrium H18OH exchange and of the dependence of formation of enzyme-bound ATP on Pi concentration. Attainment of an apparent equilibrium between medium Pi and bound ATP requires longer than 30 min, even though the rates of Pi binding and release after apparent equilibrium is reached would suffice for a faster approach to equilibrium. Slow protein conformational changes or other unknown modulating factors may be responsible for the slow rate of bound ATP formation. After apparent equilibrium is reached, each Pi that binds to the enzyme reversibly forms ATP about 50 times before being released to the medium. The rate of interconversion of bound ATP to bound ADP and Pi is much slower than that in the absence of dimethyl sulfoxide as measured with sufficiently low ATP concentrations so that single-site catalysis is favored. Although the interconversion rate is slowed, the equilibrium constant for bound ATP formation from bound ADP and Pi is not far from unity. Dimethyl sulfoxide favors the formation of enzyme-bound ATP by promoting the competent binding of Pi to enzyme with ADP bound at a catalytic site rather than by promoting formation of bound ATP from bound ADP and Pi.     

Significant quantities of endogenous GDP and ADP are present on catalytic sites of the F1-ATPase isolated from M. lysodeikticus in the absence of added nucleotides.

The F1-ATPase from Micrococcus lysodeikticus is isolated in the absence of exogenous nucleotides. After removing loosely bound nucleotides from the isolated enzyme by gel permeation chromatography, analysis for tightly bound nucleotides revealed in 14 experiments 0.4 +/- 0.1 mol ADP, 0.5 +/- 0.2 mol GDP, and 0.8 +/- 0.2 mol ATP per mol of F1. Incubation of the isolated enzyme with Mg2+ or Ca2+ did not alter the endogenous nucleotide composition of the enzyme, indicating that endogenous ATP is not bound to a catalytic site. Incubation of the enzyme with P(i) decreased the amount of tightly bound ADP and GDP but did not effect the ATP content. Hydrolysis of MgATP in the presence of sulfite raised the tightly bound ADP and lowered tightly bound GDP on the enzyme. In the reciprocal experiment, hydrolysis of MgGTP in the presence of sulfite raised tightly bound GDP and lowered tightly bound ADP. Turnover did not affect the content of tightly bound ATP on the enzyme. These results suggest that endogenous ADP and GDP are bound to exchangeable catalytic sites, whereas endogenous ATP is bound to noncatalytic sites which do not exchange. The presence of endogenous GDP on catalytic sites of isolated F1 suggests that the F0F1-ATP synthase of M. lysodeikticus might synthesize both GTP and ATP under physiological conditions. In support of this hypothesis, we have found that plasma membrane vesicles derived from M. lysodeikticus synthesize [32P]GTP from [32P]P(i) using malate as electron donor for oxidative phosphorylation.     

Binding of adenine nucleotides to the F1-inhibitor protein complex of bovine heart submitochondrial particles.

The binding of ATP radiolabeled in the adenine ring or in the gamma- or alpha-phosphate to F1-ATPase in complex with the endogenous inhibitor protein was measured in bovine heart submitochondrial particles by filtration in Sephadex centrifuge columns or by Millipore filtration techniques. These particles had 0.44 +/- 0.05 nmol of F1 mg-1 as determined by the method of Ferguson et al. [(1976) Biochem. J. 153, 347]. By incubation of the particles with 50 microM ATP, and low magnesium concentrations (less than 0.1 microM MgATP), it was possible to observe that 3.5 mol of [gamma-32P]ATP was tightly bound per mole of F1 before the completion of one catalytic cycle. With [gamma-32P]ITP, only one tight binding site was detected. Half-maximal binding of adenine nucleotides took place with about 10 microM. All the bound radioactive nucleotides were released from the enzyme after a chase with cold ATP or ADP; 1.5 sites exchanged with a rate constant of 2.8 s-1 and 2 with a rate constant of 0.45 s-1. Only one of the tightly bound adenine nucleotides was released by 1 mM ITP; the rate constant was 3.2 s-1. It was also observed that two of the bound [gamma-32P]ATP were slowly hydrolyzed after removal of medium ATP; when the same experiment was repeated with [alpha-32P]ATP, all the label remained bound to F1, suggesting that ADP remained bound after completion of ATP hydrolysis. Particles in which the natural ATPase inhibitor protein had been released bound tightly only one adenine nucleotide per enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Energy-linked binding of Pi is required for continuous steady-state proton-translocating ATP hydrolysis catalyzed by F0.F1 ATP synthase

The presence of medium Pi (half-maximal concentration of 20 microM at pH 8.0) was found to be required for the prevention of the rapid decline in the rate of proton-motive force (pmf)-induced ATP hydrolysis by Fo.F1 ATP synthase in coupled vesicles derived from Paracoccus denitrificans. The initial rate of the reaction was independent of Pi. The apparent affinity of Pi for its "ATPase-protecting" site was strongly decreased with partial uncoupling of the vesicles. Pi did not reactivate ATPase when added after complete time-dependent deactivation during the enzyme turnover. Arsenate and sulfate, which was shown to compete with Pi when Fo.F1 catalyzed oxidative phosphorylation, substituted for Pi as the protectors of ATPase against the turnover-dependent deactivation. Under conditions where the enzyme turnover was not permitted (no ATP was present), Pi was not required for the pmf-induced activation of ATPase, whereas the presence of medium Pi (or sulfate) delayed the spontaneous deactivation of the enzyme which was induced by the membrane de-energization. The data are interpreted to suggest that coupled and uncoupled ATP hydrolysis catalyzed by Fo.F1 ATP synthases proceeds via different intermediates. Pi dissociates after ADP if the coupling membrane is energized (no E.ADP intermediate exists). Pi dissociates before ADP during uncoupled ATP hydrolysis, leaving the E.ADP intermediate which is transformed into the inactive ADP(Mg2+)-inhibited form of the enzyme (latent ATPase).     

Two types of kinetic regulation of the activated ATPase in the chloroplast photophosphorylation system

The inhibition by light of chloroplast coupling factor ATPase is not due simply to competing photophosphorylation. This inhibition is only partially relieved by either an arsenate-pool trap for released phosphate, or a pyruvate kinase/phosphoenolpyruvate trap for ADP. Moreover, the amount of product return that does occur in the absence of trapping systems, ascertained by incorporation of 32Pi or [2-3H]ADP back into ATP during the hydrolysis reaction, is insufficient to account for the observed activity decrease. In intermediate pi:H2O oxygen exchange studies, the number of water oxygens incorporated into each molecule of Pi produced does not vary with light intensity during the ATPase assay. This indicates that the light-induced change in ATPase activity is not due to an alteration of rat constants involved in the forward and reverse partitioning of the E.ADP.Pi complex. In contrast, ammonium chloride, an uncoupler of photophosphorylation which stimulates membrane-bound coupling factor ATPase when added after light activation, causes a shift in the pattern of intermediate Pi:H2O oxygen exchange toward a lower number of water oxygens incorporated per Pi formed. The effect of NH4+ consistent with ATPase activity stimulation caused by enhanced partitioning forward of the E.products complex. These observations suggest the operation of two mechanisms of regulation of ATP ase activity during chloroplast de-energization. However, a direct effect of NH4+ on the coupling factor itself, independent of the membrane energization effect, cannot be ruled out by the present studies. Additional oxygen exchange experiments lead to the conclusion that the binding of ATP at a site catalyzing extensive ATP:H2O back exchange in the native chloroplast system ( Wimmer, M. J., and Rose, I. A. (1977) J. Biol. Chem. 252, 6769-6775) is different from the binding of ATP for net hydrolysis in the system activated for ATPase.     

Localization of the tight ADP-binding site on the membrane-bound chloroplast coupling factor one

The photoaffinity analog 2-azido-ADP (2-azidoadenosine 5'-diphosphate) was used as a probe of the spinach chloroplast ATP synthase. The analog acted as a substrate for photophosphorylation. Several observations suggested that 2-azido-ADP and ADP bound to the same class of tight nucleotide binding sites: (a) 2-azido-ADP competitively inhibited ADP tight binding (Ki = 1.4 microM); (b) the concentration giving 50% maximum binding, K0.5 for analog tight binding (1 microM) was similar to that observed for ADP (2 microM); (c) nucleotide tight binding required prior membrane energization and was completely reversed by re-energization; (d) the tight binding of 2-azido-[beta-32P]ADP was completely prevented by ADP; (e) the analog inhibited the light-triggered ATPase activity at micromolar concentrations. Ultraviolet irradiation of washed thylakoid membranes containing tightly bound 2-azido-[beta-32P]ADP resulted in the covalent incorporation of the label into the membranes. Denaturing polyacrylamide gel electrophoresis of the labeled membranes demonstrated that the beta subunit of the coupling factor one complex was the only polypeptide in the thylakoid membranes which was labeled. These results identify the beta subunit of the coupling factor as the location of the tightly bound ADP on the thylakoid membranes.     

Energy-dependent changes in the ATP/ADP ratio at the tight nucleotide binding site of chloroplast ATP synthase

Using DTT-modulated thylakoid membranes we studied tight nucleotide binding and ATP content in bound nucleotides and in the reaction mixture during [¹⁴C] ADP photophosphorylation. The increasing light intensity caused an increase in the rate of [¹⁴C] ADP incorporation and a decrease in the steady-state level of tightly bound nucleotides. Within the light intensity range from 11 to 710 w m^–2, ATP content in bound nucleotides was larger than that in nucleotides of the reaction mixture; the most prominent difference was observed at low degrees of ADP phosphorylation. The increasing light intensity was accompanied by a significant increase of the relative ATP content in tightly bound nucleotides. The ratio between substrates and products formed at the tight nucleotide binding site during photophosphorylation was suggested to depend on the light-induced proton gradient across the thylakoid membrane.Abbreviations AdN adenine nucleotide - Chl chlorophyll - DTT dithiothreitol - FCCP carbonylcianide p-trifluoromethoxyphenilhydrazone - P_i inorganic orthophosphate - PMS phenazine methosulfate - TLC thin-layer chromatography - Tricine N-[tris(hydroxymethyl)methyl] glycine     

Inhibition of photophosphorylation by ATP and the role of magnesium in photophosphorylation.

ATP and pyrophosphate at high concentration (greater than 1 mM) inhibited photophosphorylation of isolated spinach chloroplasts in the normal salt medium and did not cause stimulation of electron transport. The inhibition of photophosphorylation by ATP or pyrophosphate was shown to be abolished by the addition of excess MgCl2, ADP and phosphate. It has been demonstrated that the rates of photophosphorylation in the absence and presence of ATP or pyrophosphate are determined similarly by the concentrations of magnesium-ADP (Mg - ADP-) and magnesiumphosphate (Mg - Pi) complexes. It is highly probable that Mg - ADP- and Mg - Pi, but not free ADP and free phosphate, are the active form of the substrates of photophosphorylation. This is in support of the view that ATP inhibits photophosphorylation by decreasing the concentration of Mg2+ which is available for the formation of the complex with ADP and phosphate.     

Characterization of nucleotide binding sites of the isolated H(+)-ATPase from spinach chloroplasts, CF(0)F(1)

Soluble purified CF(0)F(1) from chloroplasts was either oxidized or reduced and then incubated with [alpha-(32)P]ATP in the presence or in the absence of Mg(2+). Depending on the conditions of incubation, the enzyme showed different tight-nucleotide binding sites. In the presence of EDTA, two sites bind [alpha-(32)P]ATP from the reaction medium at different rates. Both sites promote ATP hydrolysis, since equimolar amounts of [alpha-(32)P]ATP and [alpha-(32)P]ADP are bound to the enzyme. In the presence of Mg(2+), only one site appears during the first hour of incubation, with characteristics similar to those described in the absence of Mg(2+). However, after this time a third site appears also permitting binding of ATP from the reaction medium, but in this case the bound ATP is not hydrolyzed. Covalent derivatization by 2-azido-[alpha-(32)P]ATP was used to distinguish between catalytic and noncatalytic sites. In the presence of Mg(2+), there are at least three distinct nucleotide binding sites that bind nucleotide tightly from the reaction medium: two of them are catalytic and one is noncatalytic.