Does AMP participate in photosynthetic phosphorylation?

Osmotically disrupted chloroplasts catalyze a rapid, light and AMP and ATP dependent ³²P_i incorporation into ATP. Light does not stimulate [¹⁴C] AMP incorporation into ATP in this system. AMP in the presence of P_i inhibits electron flow in a manner analogous to ADP inhibition in the absence of P_i. The inhibition of AMP + P_i is reversed on addition of ADP.     

Isotopic probes of catalytic steps of myosin adenosine triphosphatase

A new approach to the direct estimation of the value of the off constant for dissociation of ATP from myosin subfragment 1 (S1) has been developed. From measurements of the extremely slow rate of release of [³²P]-ATP formed from ³²P_i by S1 catalysis and the amount of rapidly formed [³²P]-ATP tightly bound to S1, the value of the off constant is approximately 2.8 × 10⁻⁴ sec⁻¹ at pH 7.4. The concentration dependencies for P_i ⇌ H¹⁸ OH exchange and for ³²P_i incorporation into myosin-bound ATP give direct measurements of the dissociation constant of P_i from S1. Both approaches show that the enzyme has a very low affinity for P_i, with an apparent K_d of > 400 mM. Measurement of the average number of water oxygens incorporated into P_i released from ATP by S1-catalyzed hydrolysis in the presence of Mg²⁺ suggests that the hydrolytic step reverses an average of at least 5.5 times for each ATP cleaved. With the Ca²⁺-activated hydrolysis, less than one oxygen from water appears in each P_i released. This finding is indicative of a possible isotope effect in the attack of water on the terminal phosphoryl group of ATP.     

Energy-linked activities in reconstituted yeast adenosine triphosphatase proteoliposome. Adenosine triphosphate formation coupled with electron flow between ascorbate and ferricyanide.

(1) Conditions are described wherein the yeast oligomycin-sensitive adenosine triphosphatase (ATPase) complex can be reconstituted together with phospholipids to yield extremely high rates of ATP-³²P_j exchange. The vesicles so formed exhibit proton uptake upon addition of Mg²⁺-ATP and a relatively slow decay of the proton gradient. (2) The stimulation of ATP-³²P_i exchange by valinomycin + K⁺ reported previously (Ryrie, I. J. (1975) Arch. Biochem. Biophys. 168, 704–711) is apparently not simply due to a diffusion potential. The findings suggest that an electroimpelled, valinomycin-dependent migration of K⁺ may occur together with the electrogenic movements of protons during ATP hydrolysis and synthesis to establish optimal energized conditions for ATP-³²P_i exchange. (3) An artificial oxidative phosphorylation system in the reconstituted vesicles is described: [³²P]ATP formation from ADP and ³²P_i is shown to be linked with electron flow between external ascorbate and internal ferricyanide where a permeable proton carrier, such as phenazine methosulfate, is used to establish a proton gradient. That the yeast ATPase is capable of net ATP synthesis has also been demonstrated in a light-dependent reaction using ATPase proteoliposomes reconstituted together with bacteriorhodopsin.     

Properties of Bound Inorganic Phosphate on Bovine Mitochondrial F1F0-ATP Synthase

Beef-heart mitochondrial F₁F₀-ATP synthase contained six molecules of bound inorganic phosphate (P_i). This phosphate exchanged completely with exogenous ³²P_i when the enzyme was exposed to 30% (v/v) dimethyl sulfoxide (DMSO) and then returned to a DMSO-free buffer (Beharry and Bragg 2001). Only two molecules were replaced by ³²P_i when the enzyme was not pretreated with DMSO. These two molecules of ³²P_i were not displaced from the enzyme by the treatment with 1 mM ATP. Similarly, two molecules of bound ³²P_i remained on the DMSO-pretreated enzyme following addition of ATP, that is, four molecules of ³²P_i were displaced by ATP. The ATP-resistant ³²P_i was removed from the enzyme by pyrophosphate. It is proposed that these molecules of ³²P_i are bound at an unfilled adenine nucleotide-binding noncatalytic site on the enzyme. Brief exposure of the enzyme loaded with two molecules of ³²P_i to DMSO, followed by removal of the DMSO, resulted in the loss of the bound ³²P_i and in the formation of two molecules of bound ATP from exogenous ADP. A third catalytic site on the enzyme was occupied by ATP, which could undergo a P_i ATP exchange reaction with bound P_i The presence of two catalytic sites containing bound P_i is consistent with the X-ray crystallographic structure of F₁ (Bianchet, et al., 1998). Thus, five of the six molecules of bound P_i were accounted for. Three molecules of bound P_i were at catalytic sites and participated in ATP synthesis or P_i ATP exchange. Two other molecules of bound P_i were present at a noncatalytic adenine nucleotide-binding site. The location and role of the remaining molecule of bound P_i remains to be established. We were unable to demonstrate, using chemical modification of sulfhydryl groups by iodoacetic acid, any gross difference in the conformation of F₁F₀ in DMSO-containing compared with DMSO-free buffers.     

Actin polymerization and ATP hydrolysis

This paper surveys several aspects of the consequences of ATP hydrolysis associated with actin polymerization, and their physiological implications. ATP hydrolysis occurs on F-actin in two subsequent reactions, cleavage of ATP followed by the slower release of P_i. The latter reaction is linked to a conformation change of the actin subunit that causes a destabilization of the actin-actin interactions in the filament, i.e., a structural change of the filament. The nature of the nucleotide bound to terminal subunits therefore affects the dynamics of actin filaments. It is shown that this regulation is different at the two ends, terminal F-ADP-P_i subunits being present at steady state at the barbed end, while F-ADP-subunits are present at the pointed end. While cleavage of ATP on F-actin is irreversible, P_i release is reversible, which allows the regulation of filament dynamics by cellular P_i. The nature of the divalent metal ion — Ca²⁺ or Mg²⁺ — tightly bound to actin, in direct interaction with ATP, also affects the conformation of actin and the rate of ATP hydrolysis, therefore regulating actin dynamics. Finally, the rate of nucleotide exchange on G-actin is relatively slow, which allows the critical concentration to increase with the number of filaments in ATP, a property largely used by the cell via the action of severing proteins.     

The incorporation of 32P into spectrin aggregates following incubation of erythrocytes in 32P-labelled inorganic phosphate

³²P was incorporated into spectrin by incubation of fresh erythrocytes with ³²P_i and glucose. The dimer and tetramer aggregates revealed only covalently-bound incorporation of phosphorus, while a higher aggregate of spectrin revealed both covalent and non-covalent incorporation. The specific activity of the covalently-bound phosphorus in all oligomers was identical, suggesting that the state of association is independent of phosphorylation. The non-covalent incorporation was shown to be due to the association of ATP with this higher aggregate. The nucleotide appears not to be bound directly to spectrin but rather to component 5 (erythrocyte actin) which is also found to be associated with this highly aggregated spectrin structure.     

The incorporation of P into spectrin aggregates following incubation of erythrocytes in P-labelled inorganic phosphate

³²P was incorporated into spectrin by incubation of fresh erythrocytes with ³²P_i and glucose. The dimer and tetramer aggregates revealed only covalently-bound incorporation of phosphorus, while a higher aggregate of spectrin revealed both covalent and non-covalent incorporation. The specific activity of the covalently-bound phosphorus in all oligomers was identical, suggesting that the state of association is independent of phosphorylation. The non-covalent incorporation was shown to be due to the association of ATP with this higher aggregate. The nucleotide appears not to be bound directly to spectrin but rather to component 5 (erythrocyte actin) which is also found to be associated with this highly aggregated spectrin structure.     

Phosphate transport and its relationship to cation movements in Ehrlich Lettré ascites tumor cells.

In view of the importance of P_i in the control of cell metabolism, it was of interest to study the mechanism and regulation of P_i uptake by ascites tumor cells. For this purpose, the incorporation of ³²P_i into Ehrlich Lettré cells was compared when competitive anions and inhibitors which alter cation movements were present. Anions such as sulfanilate (35 mm) and succinate (30 mm) decrease ³²P_i uptake by ca. 35%, suggesting that transport is mediated by a protein similar to the 100,000 M_r anion carrier isolated from erythrocyte membranes. Furosemide, a diuretic which bears a structural analogy to sulfanilate inhibitors of anion transport, also decreases ³²P_i incorporation at concentrations as low as 2 × 10^?5m. This inhibitor blocks cation exchange in ascites tumor cells, and from the present data, it is suggested that a possible function of the furosemidesensitive cation exchange protein is to facilitate anion transport. Ouabain, known to inhibit (Na⁺ + K⁺)-ATPase and its dephosphorylation, stimulates the rate of incorporation of ³²P_i into cells and also raises the net inorganic phosphate level. The stimulation of ³²P_i incorporation is decreased by sulfanilate or succinate. In contrast to the effects of ouabain, addition of 10 mm K⁺, which is known to stimulate (Na⁺ + K⁺)-ATPase and its dephosphorylation, decreases ³²P_i incorporation. These observations suggest that anion transport and energy-dependent Na⁺ and K⁺ movements may be closely coupled to the intact cell.     

Purification and reconstitution of the 32Pi-ATP exchange activity of bovine chromaffin granule membrane

Ghosts derived from bovine chromaffin granules have a ³²P_i-ATP exchange activity which is associated with the H⁺ pump of that membrane. This activity was low when compared to bacteria, chloroplasts or submitochondrial particles, but had similar properties (K_m for ATP and P_i, ATP/Mg²⁺ ratio, pH profile, inhibition by dicyclohexylcarbodiimide and tributyltin) to the ATPase from above membranes. The ³²P_i-ATP exchange activity was solubilized by cholate/octylglucoside mixtures. The soluble extract was lipid depleted by ammonium sulfate fractionation and partially purified by sucrose gradient centrifugation. The purified preparation was reconstituted with phospholipids by freeze-thawing. The reconstituted vesicles had a ³²P_i-ATP exchange sensitive to dicyclohexylcarbodiimide and trybutyltin and an ATPase with a sensitivity to the inhibitors which varied with the reconstitution conditions. The α- and β-subunits of F₁-ATPase were major components of the preparation.     

A rapid method for the measurement of [γ-32P]ATP specific radioactivity in tissue extracts and its application to the study of 32Pi uptake in perfused rat heart

(i) A new, rapid method for the measurement of [γ-³²P]ATP specific radioactivity in tissue extracts in the presence of other ³²P-containing compounds is described. The deproteinized extract is incubated with phosphorylase b and phosphorylase kinase, and the incorporation of ³²P into protein from [γ-³²P]ATP is measured by precipitation on filter paper in trichloroacetic acid. No separation of ATP or other treatment of the extracts is required for the assay. (ii) ³²P_i uptake in perfused rat heart was found to be a relatively slow process, with a K_m of 0.084 mm, whereas equilibration between intracellular ³²P_i and [γ-³²P]ATP occurred rapidly.     

Reversal of the calcium pump in human red cells

Summary Human red cells containing low ATP and high P_i concentrations were suspended in media with and without 2mm Ca²⁺, and the incorporation of (³²P)P_i into ATP was measured. There was some incorporation whatever the medium, but in every experiment there was an extra incorporation when the cells were in the Ca²⁺-containing medium. This extra incorporation was abolished by the ionophore A23187, which collapses the Ca²⁺ concentration gradient across the membranes, or by LaCl₃, which blocks the Ca²⁺ pump. Starved and phosphate-loaded cells also show an uptake of Ca²⁺ which is not apparent in fresh cells. Results are consistent with the idea that Ca²⁺-dependent incorporation of P_i into ATP is catalyzed by the Ca²⁺ pump using energy derived from the Ca²⁺ concentration gradient.     

The phosphorylation of intramitochondrial AMP: A suggestion for the compartmentation of endogenous Pi pool

1. The mitochondrial level of AMP gradually diminishes during incubation of mitochondria with glutamate but does not with succinate. This decline of AMP, associated with stoichiometric increase in ADP and/or ATP, is accelerated by the addition of electron acceptors or 2,4-dinitrophenol, while arsenite, arsenate and rotenone are inhibitory. These results are in agreement with the view that AMP is phosphorylated to ADP in the inner space of rat liver mitochondria via succinyl-CoA synthetase (succinate: CoA ligase (GDP), EC 6.2.1.4) and GTP:AMP phosphotransferase dependent on the oxidation of 2-oxoglutarate, which is promoted by the transfer of electron from NADH to the respiratory chain.2. Studies of the periodical changes of chemical quantities of adenine nucleotides as well as of their labelling with ³²P_i reveals the following characteristics concerning mitochondrial phosphorylation. (i) In contrast to the mass action ratio of ATP to ADP, the ratio of ADP to AMP is not affected by the intramitochondrial concentration of P_i. (ii) ³²P_i, externally added, is incorporated into ADP much more slowly than into γ-phosphate of ATP. (iii) Conversely, ATP loses its radioactivity from γ-phosphate position more rapidly than [³²P]ADP when ³²P-labelled mitochondria are incubated with non-radioactive P_i.3. In order to elucidate the above characteristic properties of phosphorylation, a hypothetical scheme is proposed which postulates the two separate compartments in the intramitochondrial pool of P_i; one readily communicates with external P_i and is utilized for the phosphorylation of ADP in oxidative phosphorylation, while the other less readily communicates with external P_i and serves as the precursor of ADP via succinyl-CoA synthetase and GTP:AMP phosphotransferase.     

Yeast nicotinic acid phosphoribosyltransferase. Studies of reaction paths, phosphoenzyme, and Mg2+ effects.

Initial velocity and ATP-ADP isotope exchange kinetic data on yeast nicotinate phosphoribosyltransferase indicate a sequential steady-state mechanism m which ATP adds first, followed by a random order of addition of the substrates PP-ribose-P and nicotinic acid. Reaction flux through the alternative ping-pong pathway, evidenced first by ATP-ADP isotope exchange in the absence of nicotinic acid and PP-ribose-P substrates, is reduced by low concentrations of either, or both, of these substrates. Both Mg²⁺-complexed and -free PP-ribose-P are enzymatically active. Phosphorylated enzyme, prepared with [γ-³²P]ATP and separated by gel chromatography, retains ³²P_i until incubated with both substrates, PP-ribose-P and nicotinic acid, which completely discharge the ³²P_i.     

A simple modification to an enzymic method for the preparation of[γ-32P]ATP free of salt and buffer

An existing enzymic method for preparing [γ-³²P]ATP from 32P_i has been modified toyield [γ-³²P]ATP free of salt and buffer. ³²P is incorporated into the γ-position of ATP by isotopic exchange in the presence of glyceraldehyde 3-phosphate dehydrogenase and 3-phosphoglycerate kinase. Unreacted ³²P_i is separated from [γ-³²P]ATP by column chromatography on Dowex 1 bicarbonate. [γ-³²P]ATP is eluted with 2 m triethylammonium bicarbonate, which is then completely removed by freeze-drying.     

The reversal of the myosin and actomyosin ATPase reactions and the free energy of ATP binding to myosin

Evidence is presented that both myosin and actomyosin in presence of Mg²⁺ and KCl catalyze an incorporation of ³²P_i into ATP. The rate with actomyosin is about $\text{1}\text{500}$ the rate of ATP hydrolysis; the rate with myosin is less than $\text{1}\text{100}$ of that with actomyosin. With myosin, but not with actomyosin, an apparent initial “burst” of ³²P_i incorporation into ATP is observed. Actin binding thus promotes ATP dissociation. The data with myosin allow estimation of both the amount of enzyme-bound [³²P]-ATP present and the rate constant, k_?1, for dissociation of the myosin· ATP. From these results and other data a ?ΔG^o for ATP binding to myosin of 12–13 kcal/mole may be estimated, with a much lower ?ΔG^o for hydrolysis of enzyme-bound ATP. Protein conformational change accompanying ATP binding appears to be the principal means of capture of energy from the overall reaction of ATP cleavage.     

A 31P-NMR study of the cross-membrane pH gradient induced by ATP hydrolysis in mitochondria

³¹P-NMR has been used to study the increase of ΔpH in mitochondria by externally added ATP. Freshly prepared mitochondria was treated with N-ethylmaleimide to inhibit the exchange between internal and external P_i. Upon addition of ATP, phosphocreatine (30 mM) and creatine kinase to a NMR sample of mitochondria suspension (approx. 120 mg protein/ml) at 0°C, an increase of ΔpH by approx. 0.5 pH unit was observed. However the increased ΔpH could not be maintained, but slowly decayed along with the increase of external ADP/ATP ratio. Further addition of valinomycin to the suspension induced a larger ΔpH (approx. 1) which was maintained by the increased rate of internal ATP hydrolysis as seen in the growth of the internal P_i peak intensity in NMR spectra and the concomitant decrease of the external phosphocreatine peak. The external P_i and ATP peaks stayed virtually constant. When carboxyatractyloside was added to inhibit the ATP/ADP translocase, the internal P_i increase was stopped and the ΔpH decayed. These observations in conjunction with those made earlier in respiring mitochondria clearly show the reversible nature of the ATPase function in which the internal ATP hydrolysis is associated with outward pumping of protons.     

Studies on photophosphorylation utilizing methylene diphosphonate analogs of ADP and ATP

Spinach chloroplasts were able to photophosphorylate the ADP analog α,β-methylene adenosine 5′-diphosphate (AOPCP). Phosphorylation of AOPCP was catalyzed by chloroplasts that were washed or dialyzed to remove free endogenous nucleotides. In the presence of glucose, hexokinase, AOPCP and ³²P_i, the ³²P label was incorporated into α,β-methylene adenosine 5′-triphosphate (AOPCPOP).In contrast to photophosphorylation of AOPCP, the ATP analog AOPCPOP was a poor substrate for the ATP-P_i exchange reaction and its hydrolysis was neither stimulated by light and dithiothreitol nor inhibited by Dio-9.Photophosphorylation of AOPCP was inhibited by the α,β- and β,γ-substituted methylene analogs of ATP, while phosphorylation of ADP was unaffected by them. The ATP-P_i exchange was also unaffected by both ATP analogs, while the weak AOPCPOP-P_i exchange was inhibited by the β,γ-methylene analog of ATP.Direct interaction of methylene analogs with the chloroplast coupling factor ATPase was indicated by the enzymatic hydrolysis of AOPCPOP on polyacrylamide gels.     

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.     

Exchange between inorganic phosphate and adenosine triphosphate in (Na+,K+)-ATPase

(Na⁺,K⁺)-ATPase is able to catalyze a continuous ATP?P_i exchange in the presence of Na⁺ and in the absence of a transmembrane ionic gradient. At pH 7.6 the Na⁺ concentration required for half-maximal activity is 85 mM and at pH 5.1 it is 340 mM. In the presence of optimal Na⁺ concentration, the rate of exchange is maximal at pH 6.0 and varies with ADP and P_i concentration in the assay medium. ATP?P_i exchange is inhibited by K⁺ and by ouabain.     

Relationships of inosine triphosphate and bicarbonate effects on F1 ATPase to the binding change mechanism

Two interesting previously reported properties of mitochondrial F₁ ATPase have been confirmed and have been examined by¹⁸O exchange measurements to assess if they are consistent with sequential participation of catalytic sites during ATP hydrolysis. These are the ability of HCO ₃ ^– to increase reaction rate with apparent loss of cooperative interaction between subunits and the ability of ITP to accelerate the hydrolysis of a low concentration of ATP. The effect of HCO ₃ ^– was tested at concentrations of ATP lower than previous measurements. The activation disappeared when ATP was reduced to 0.1 µM. The HCO ₃ ^– activation at higher ATP concentrations did not change the extent of reversal of the cleavage of tightly bound ATP at the catalytic site, as measured by the average number of water oxygens incorporated with each P_i formed when 5 or 10 µM ATP is hydrolyzed. The data are consistent with sequential site participation with HCO ₃ ^– acceleration of ADP departure after a binding change that stops¹⁸O exchange and loosens ADP binding.When ITP concentration was lowered during net ITP hydrolysis by F₁ ATPase an increase in water oxygen incorporation into P_i formed is observed, as noted previously for ATP hydrolysis. The acceleration of the cleavage of a constant low concentration of [-¹⁸O]ATP by concomitant hydrolysis of increasing concentrations of ITP was accompanied by a decrease in water oxygen incorporation with each P_i formed from the ATP. These results add to evidence for the binding change mechanism for F₁ ATPase with sequential participation of catalytic sites.