Tightly bound nucleotides of the energy-transducing ATPase of chloroplasts and their role in photophosphorylation.

1. Like other energy-transducing membranes, chloroplast membranes bear a coupling ATPase with especially tight binding sites for adenine nucleotides. Membranes washed several times still contain 2.5 nmol ATP and 1.3 nmol ADP bound per mg chlorophyll, which is equivalent to 1.9 ATP and 1.0 ADP per coupling ATPase. 2. In de-energized membranes, these nucleotides exchange to only a limited extent with added nucleotides. In membranes illuminated in the presence of pyocyanine, however, complete exchange of the bound nucleotides occurs rapidly, irrespective of whether ATP or ADP is present in the medium. 3. Pi can exchange into these nucleotided at both the beta and gamma positions when the membranes are energized in the presence of Mg-2+. Equilibrium with the beta and gamma groups of th ebound nucleotides is, however, not complete. 4. The inhibitors and uncouplers Dio-9, S13 and EDTA have different effects on the exchange of nucleotides, the exchange of inorganic phosphate and photophosphorylation. 5. The bound ATP level on the membrane is stable to a wide variety of conditions. The ADP level, however, drops to near zero under conditions of maximal activation of the emmbrane ATPase.     

Tightly bound nucleotides of the energy-transducing ATPase, and their role in oxidative phosphorylation. I. The Paracoccus denitrificans system.

1. The coupling ATPase of Paracoccus denitrificans can be removed from the membrane by washing coupled membrane fragments at low salt concentrations. 2. This ATPase resembles coupling ATPases of mitochondria, chloroplasts and other bacteria. It is a negatively charged protein of molecular weight about 300,000. An inhibitor protein in bound tightly to the ATPase in vivo, and can be destroyed by trypsin treatment. 3. ATP and ADP are found tightly bound to the coupling ATPase of P. denitrificans, both in its membrane-bound and isolated state. The ATP/ADP ratio on the enzyme is greater than one. 4. Under de-energised condtions, the bound nucleotides are not available to the suspending medium. When the membrane is energised however, the bound nucleotides can exchange with added nucleotides and incorporate 32Pi. 32Ppi is incorporated into the beta and gamma positions of the bound nucleotides, but beta-labelling probably does not occur on the coupling ATPase. 5. Uncouplers inhibit the exchange of the free nucleotides or 32Pi into the bound nucleotides, while venturicidin (an energy transfer inhibitor) and aurovertin stimulate the exchange. 6. The response of the bound nucleotides to energisation is consistent with their being involved directly in the mechanism of oxidative phosphorylation.     

Tightly bound nucleotides of the energy-transducing ATPase,and their role in oxidative phosphorylation. II. The beef heart mitochondrial system

1. Beef heart mitochondrial ATPase, in both the membrane-bound and isolated form, contains tightly bound ATP and ADP. Each mol of ATPase contains about 2.2 mol ATP and 1.3 mol ADP.2. In the absence of ATPase activity, these nucleotides exchange only slowly with nucleotides in solution. The exchange rate is increased during coupled ATPase activity, but not when the ATPase is uncoupled.3. Oligomycin and dicyclohexylcarbodiimide inhibit exchange of the bound nucleotides, as does the ATPase inhibitor protein, although in each case some residual exchange occurs. Aurovertin, although inhibiting phosphorylation, does not inhibit the exchange. This is discussed in terms of the reversibility of these inhibitors.4. The stimulation of exchange seen during coupled ATPase activity requires energisation of the ATPase molecule. Using the exchange reaction as a probe of energisation, it is deduced that energy can be transferred between different ATPase molecules.5. It is proposed that coupled ATPase activity and phosphorylation in submitochondrial particles involve the tight nucleotide binding sites and the (weak) ATPase site, while uncoupled ATPase activity involves only the weak site.     

Tightly bound nucleotides of the energy-transducing ATPase,and their role in oxidative phosphorylation. I. The Paracoccus denitrificans system

1. The coupling ATPase of Paracoccus denitrificans can be removed from the membrane by washing coupled membrane fragments at low salt concentrations.2. This ATPase resembles coupling ATPases of mitochondria, chloroplasts and other bacteria. It is a negatively charged protein of molecular weight about 300 000. An inhibitor protein is bound tightly to the ATPase in vivo, and can be destroyed by trypsin treatment.3. ATP and ADP are found tightly bound to the coupling ATPase of P. denitrificans, both in its membrane-bound and isolated state. The ATP/ADP ratio on the enzyme is greater than one.4. Under de-energised conditions, the bound nucleotides are not available to the suspending medium. When the membrane is energised however, the bound nucleotides can exchange with added nucleotides and incorporate ³²P_i. ³²P_i is incorporated into the β and γ positions of the bound nucleotides, but β-labelling probably does not occur on the coupling ATPase.5. Uncouplers inhibit the exchange of the free nucleotides or ³²P_i into the bound nucleotides, while venturicidin (an energy transfer inhibitor) and aurovertin stimulate the exchange.6. The response of the bound nucleotides to energisation is consistent with their being involved directly in the mechanism of oxidative phosphorylation.     

Tightly bound nucleotides of the energy-transducing ATPase, and their role in oxidative phosphorylation. II. The beef heart mitochondrial system.

1. Beef heart mitochondrial ATPase, in both the membrane-bound and isolated form, contains tightly bound ATP and ADP. Each mol of ATPase contains about 2.2 mol ATP and 1.3 mol ADP. 2. In the absence of ATPase activity, these nucleotides exchange only slowly with nucleotides in solution. The exchange rate is increased during coupled ATPase activity, but not when the ATPase is uncoupled. 3. Oligomycin and dicyclohexylcarbodiimide inhibit exchange of the bound nucleotides, as does the ATPase inhibitor protein, although in each case some residual exchange occurs. Aurovertin, although inhibiting phosphorylation, does not inhibit the exchange. This is discussed in terms of the reversibility of these inhibitors. 4. The stimulation of exchange seen during coupled ATPase activity requires energisation of the ATPase molecule. Using the exchange reaction as a probe of energisation, it is deduced that energy can be transferred between different ATPase molecules. 5. It is proposed that coupled ATPase activity and phosphorylation in submitochondrial particles involve the tight nucleotide binding sites and the (weak) ATPase site, while uncoupled ATPase activity involves only the weak site.     

Flash-induced photophosphorylation in chloroplasts with activated ATPase

Chloroplasts which were rapidly isolated from illuminated leaves showed activity of ATP hydrolysis at a level much higher than that of the dark control. Under the high-intensity illumination or under repetitive flash excitation, the activated chloroplasts synthesized more ATP than those with a low ATP hydrolysis activity. formed under repetitive flashes was smaller in the activated chloroplasts than in the inactive chloroplasts. The inhibition of ATP yield per flash by valinomycin or nigericin in the presence of K⁺ was stronger in the inactive chloroplasts than in the activated chloroplast. ATP synthesis in the activated chloroplasts seems to have a lower threshold.     

Evaluation by steady-state enzyme kinetics of the role of tightly bound nucleotides during photophosphorylation

The ATP synthetase of chloroplast membranes binds ADP and ATP with high affinity, and the binding becomes quasi-irreversible under certain conditions. One explanation of the function of these nucleotides is that they are transiently tightly bound during ATP synthesis as part of the catalytic process, and that the release of tightly bound ATP from one catalytic site is promoted when ADP and P(i) bind to a second catalytic site on the enzyme. Alternatively, it is possible that the tightly bound nucleotides are not catalytic, but instead have some regulatory function. We developed steady-state rate equations for both these models for photophosphorylation and tested them with experiments where two alternative substrates, ADP and GDP, were phosphorylated simultaneously. It was impossible to fit the results to the equations that assumed a catalytic role for tightly bound nucleotides, whether we assumed that both ADP and GDP, or only ADP, are phosphorylated by a mechanism involving substrate-induced release of product from another catalytic site. On the other hand, the equations derived from the regulatory-site model that we tested were able to fit all the results relatively well and in an internally consistent manner. We therefore conclude that the tightly bound nucleotides most likely do not derive from catalytic intermediates of ATP synthesis, but that substrate (and possibly also product) probably bind both to catalytic sites and to noncatalytic sites. The latter may modulate the transition of the ATP-synthesizing enzyme complex between its active and inactive states.     

In vivo and in vitro incorporation of endogenous nucleotides by the energy-transducing ATPase of Streptococcus faecalis

The soluble ATPase isolated from Streptococcus faecalis membranes containing tightly bound endogenous nucleotides do not exchange in the presence of ATP and Mg+2 added during the purification of the enzyme. In this paper the stoichiometry of endogenous nucleotides in the soluble ATPase obtained from (a) growing cells, (b) nongrowing glycolyzing cells, and (c) isolated cell membranes has been defined. The time course of incorporation was also studied in nongrowing, glycolyzing cells and isolated cell membranes. In all cases, 1-2 mol of nucleotide was bound per mol of enzyme. Maximal incorporation required approximately 1 h at 38 degrees C. Incorporation of cytoplasmic nucleotide into the enzyme occurred by a process of slow exchange for bound nucleotide. N,N'-dicyclohexylcarbodiimide, which inhibits the membrane-bound ATPase and prevents generation of the protonmotive force, had no effect on incorporation of endogenous nucleotides in glycolyzing cells. Treatment of glycolyzing cells with gramicidin D plus K+, which dissipates the protonmotive force but has no effect on ATPase activity, did not inhibit incorporation of nucleotide. These results support the view that the slow exchange-incorporation of endogenous nucleotide(s) is independent of ATP hydrolysis and a protonmotive force. An in vitro system for the study of nucleotide binding at endogenous sites is described.     

Influence of adenine nucleotides on the inhibition of photophosphorylation in spinach chloroplasts by N-ethylmaleimide.

The incubation of spinach chloroplasts with 1 mM N-ethylmaleimide in light for 60 to 90 s results in a partial, irreversible inhibition of photophosphorylation. The inhibition was not overcome at infinite light intensity or at infinite concentrations of the phosphorylation substrates. Although the inhibition diminished with decreasing concentrations of adenosine diphosphate in the assay of phosphorylation, the inhibition of guanosine diphosphate phosphorylation was independent of the concentration of this nucleotide. Although adenosine di- or triphosphate (10 to 30 muM) alone partially prevented the development of the N-ethylmaleimide inhibition of phosphorylation, these nucleotides were more effective when either 1 mM inorganic phosphate or arsenate was also present. The light-dependent incorporation of N-ethylmaleimide into chloroplast-bound coupling factor 1 was affected by adenosine triphosphate and inorganic phosphate in a manner similar to the onset of N-ethylmaleimide inhibition. Since guanosine diphosphate did not protect phosphorylation from N-ethylmaleimide inhibition but is phosphorylated at rapid rates, it is apparent that coupling factor 1 in chloroplasts has multiple nucleotide recognition sites.     

Tightly bound nucleotides affect phosphate binding to mitochondrial F1-ATPase

The interaction of inorganic phosphate with native and nucleotide-depleted F1-ATPase was studied. F1-ATPase depleted of tightly bound nucleotides loses the ability to bind inorganic phosphate. The addition of ATP, ADP, GTP and GDP but not AMP, restores the phosphate binding. The nucleotides affecting the phosphate binding to F1-ATPase are located at the catalytic (exchangeable) site of the enzyme. The phosphate is thought to bind to the same catalytic site where the nucleotide is already bound. It is thought that ADP is the first substrate to bind to F1-ATPase in the ATP synthesis reaction.     

Tightly bound 2-azido-adenine nucleotides at catalytic and noncatalytic sites of the rat liver F1 ATPase label adjacent tryptic peptides of the beta subunit

UV irradiation of rat liver F1 ATPase, previously exposed to Mg2+ and [beta, gamma-32P]-2-azido-ATP and separated from medium nucleotides, covalently modifies two tyrosine residues in adjacent tryptic peptides of the beta subunit. This results from the occupancy by 2-azido-ATP or 2-azido-ADP of two distinct types of nucleotide binding sites, the catalytic and noncatalytic sites. The two modified peptides are identical to the ones modified by 2-azido-adenine nucleotides in the beef heart F1 ATPase. Both catalytic and noncatalytic sites are labeled when the ATPase is exposed to [beta-32P]-2-azido-ADP in the presence or the absence of 5'-adenylyimidodiphosphate (AMP-PNP), showing that two distinct types of ADP binding sites are present on the liver enzyme. Similar incorporation of 2-azido-adenine nucleotides is obtained when membrane-bound rat liver F1 ATPase is incubated with Mg2+ and [beta, gamma-32P]-2-azido-ATP.     

Nigericin-induced stimulation of photophosphorylation in chloroplasts

Amines have been shown recently to stimulate at low concentrations the steady-state rate of photophosphorylation by unbroken chloroplasts (Giersch, C. (1982) Z. Naturforsch. 37c, 242–250). In the present contribution it is demonstrated that not only amines but also the carboxylic ionophores nigericin and monensin at concentrations of 10 and 150 nM, respectively, stimulate the phosphorylation rate. The $\text{ATP}\text{2}\text{e}$ ratio is not decreased upon the addition of nigericin at concentrations that stimulate phosphorylation. Nigericin-induced stimulation is observed only in the presence of sufficient external potassium, indicating that the observed stimulation is unlikely to be a side-effect of the uncoupler but is related to H⁺-K⁺ exchange. The proton permeability of the thylakoid membrane is increased and the proton gradient decreased by amounts of nigericin that stimulate phosphorylation. The membrane potential is not affected in the steady state, indicating that the proton-motive force is slightly reduced upon addition of the ionophore. Data on the proton-motive force were related to maximum values of the phosphorylation potential, which was 45 000–50 000 M^?1 in the absence and 30 000–35 000 M^?1 in the presence of 10 nM nigericin. The observation that the $\text{ATP}\text{2}\text{e}$ ratio is not decreased in the presence of uncoupler-induced proton leakage is suggested to indicate that the thylakoid lumen does not represent a homogeneous phase of constant proton electrochemical potential. The results presented here are in agreement with the chemiosmotic concept as far as energetic aspects are concerned but seem to be at variance with the postulated free mobility of protons inside the thylakoids. A tentative model of uncoupler-induced stimulation of phosphorylation is presented.     

AMP photophosphorylation and binding by chloroplasts

Stoichiometric amounts of chloroplast thylakoids photophosphorylate free AMP to tightly bound ADP. Free ADP is a poor competitor for this AMP photoreaction, which saturates below 16 micronAMP. The inhibitor, diadenosine pentaphosphate, abolishes AMP photophosphorylation, and inhibits dark ADP binding. Taken together, these data imply that this photoreaction involves the high affinity nucleotide binding site(s) of chloroplast coupling factor CF1, and that little mixing with free nucleotides occurs.