ATP regeneration by thermostable ATP synthase

We investigated the possibility of using thermostable ATP synthase (TF(0)F(1)) for a new ATP regeneration method. TF(0)F(1) was purified from a thermophilic bacterium, PS3, and reconstituted into liposomes. ATP synthesis experiments showed that TF(0)F(1) liposomes could synthesize ATP in micromole concentrations by acid-base change. The acid-base change was repeated six times over an 11-day period with no detectable loss of activity at the reaction temperature (45 degrees C). Given these encouraging results, we conceptualized and modeled a system to synthesize ATP using ATP synthase with energy supplied by acid-base change. In this system, liposomes containing ATP synthase are immobilized on small glass spheres that facilitate separation of buffers from the liposomes after the acid-base change. Compared to an alternate system that uses membranes to separate the buffers from the liposomes, the glass spheres reduce inefficient mixing of acidic and basic buffers during the acid-base change. To increase the ATP synthesis yield, this system uses electrodialysis to regenerate a potassium gradient after the acid-base change. It also employs water-splitting electrodialysis to regenerate KOH and HCl required to adjust the pH of acidic and basic buffers. All reagents are recycled, so electrical energy is the only required input.     

ATP Synthase: The machine that makes ATP

The recently determined crystal structure of the F₁ part of mitochondrial ATP synthase provides new insights into the workings of one of the most remarkable and complex biochemical machines.     

C-Terminal mutations in the chloroplast ATP synthase gamma subunit impair ATP synthesis and stimulate ATP hydrolysis

Two highly conserved amino acid residues, an arginine and a glutamine, located near the C-terminal end of the gamma subunit, form a "catch" by hydrogen bonding with residues in an anionic loop on one of the three catalytic beta subunits of the bovine mitochondrial F1-ATPase [Abrahams, J. P., Leslie, A. G., Lutter, R., and Walker, J. E. (1994) Nature 370, 621-628]. The catch is considered to play a critical role in the binding change mechanism whereby binding of ATP to one catalytic site releases the catch and induces a partial rotation of the gamma subunit. This role is supported by the observation that mutation of the equivalent arginine and glutamine residues in the Escherichia coli F1 gamma subunit drastically reduced all ATP-dependent catalytic activities of the enzyme [Greene, M. D., and Frasch, W. D. (2003) J. Biol. Chem. 278, 5194-5198]. In this study, we show that simultaneous substitution of the equivalent residues in the chloroplast F1 gamma subunit, arginine 304 and glutamine 305, with alanine decreased the level of proton-coupled ATP synthesis by more than 80%. Both the Mg2+-dependent and Ca2+-dependent ATP hydrolysis activities increased by more than 3-fold as a result of these mutations; however, the sulfite-stimulated activity decreased by more than 60%. The Mg2+-dependent, but not the Ca2+-dependent, ATPase activity of the double mutant was insensitive to inhibition by the phytotoxic inhibitor tentoxin, indicating selective loss of catalytic cooperativity in the presence of Mg2+ ions. The results indicate that the catch residues are required for efficient proton coupling and for activation of multisite catalysis when MgATP is the substrate. The catch is not, however, required for CaATP-driven multisite catalysis or, therefore, for rotation of the gamma subunit.     

Synthesis and hydrolysis of ATP by the mitochondrial ATP synthase

A brief summary of the factors that control synthesis and hydrolysis of ATP by the mitochondrial H+-ATP synthase is made. Particular emphasis is placed on the role of the natural ATPase inhibitor protein. It is clear from the existing data obtained with a number of agents that there is no correlation between variations of the rate of ATP hydrolysis and ATP synthesis as driven by respiration. The mechanism by which each condition differentially affects the two activities is not entirely known. For the case of the natural ATPase inhibitor protein, it appears that the protein controls the kinetics of the enzyme. This control seems essential for achieving maximal accumulation of ATP during electron transport in systems that contain relatively high concentrations of ATP.     

STIMULATION OF BRAIN ACETYL-CoA HYDROLASE BY ATP AND ATP ANALOGUES

The effects of ATP and ATP analogues on the brain acetyl-CoA hydrolase (EC 3.1.2.1) were studied. The enzyme was stimulated reversibly by ATP-Mg²⁺ the presence of Mg²⁺ being absolutely required for the stimulation. The stimulatory effect of ATP was highly specific since adenine nucleotides other than ATP had no stimulatory effects and nucleoside triphosphates other than ATP stimulated the enzyme much less than ATP in the following order: ATP > ITP CTP, UTP GTP. A phosphate modified analogue of ATP, AMP-PNP had a similar stimulatory effect to that of ATP. Other ATP analogues such as AMP-PCP and AMPCPP showed less stimulatory effect than ATP. The order of the stimulatory effects of these ATP analogues was: ATP > AMP-PNP > AMP-PCP > AMPCPP. The concentrations needed for half-maximal stimulation of ATP, AMP-PNP and AMP-PCP were approx 0.11 mm , 0.22 mm, and 0.22 mm , respectively. Double reciprocal plots demonstrated that ATP as well as AMP-PNP produced a significant decrease in the apparent K_m, value for acetyl-CoA and an increase in V_max indicating that these nucleotides increased the affinity for acetyl-CoA through binding at a site other than the catalytic site. The data described above suggest that the rate of hydrolysis of acetyl-CoA may be regulated by the concentration of ATP in the micro-environment of the enzyme.     

How ATP inhibits the open K(ATP) channel

ATP-sensitive potassium (K(ATP)) channels are composed of four pore-forming Kir6.2 subunits and four regulatory SUR1 subunits. Binding of ATP to Kir6.2 leads to inhibition of channel activity. Because there are four subunits and thus four ATP-binding sites, four binding events are possible. ATP binds to both the open and closed states of the channel and produces a decrease in the mean open time, a reduction in the mean burst duration, and an increase in the frequency and duration of the interburst closed states. Here, we investigate the mechanism of interaction of ATP with the open state of the channel by analyzing the single-channel kinetics of concatenated Kir6.2 tetramers containing from zero to four mutated Kir6.2 subunits that possess an impaired ATP-binding site. We show that the ATP-dependent decrease in the mean burst duration is well described by a Monod-Wyman-Changeux model in which channel closing is produced by all four subunits acting in a single concerted step. The data are inconsistent with a Hodgkin-Huxley model (four independent steps) or a dimer model (two independent dimers). When the channel is open, ATP binds to a single ATP-binding site with a dissociation constant of 300 microM.     

Non-mitochondrial ATP transport

Exchange of organelle ATP with cytosolic ADP through the ADP/ATP carrier is a well-characterized feature of mitochondrial metabolism. Obligate intracellular bacteria, such as Rickettsia prowazekii, and higher-plant plastids possess another type of adenylate transporter, which exchanges bacterial or plastidic ADP for ATP from the eukaryotic (host cell) cytoplasm. The bacterial and plastidic transporters are similar but do not share significant sequence similarities with the mitochondrial carrier. Recent molecular and biochemical studies are providing deeper insight into the functional and evolutionary relationships between the bacterial and the plant transport proteins.     

Studies on ATP

The experiments described in this paper serve as a contribution to the solution of the discrepancies which exist in the assay of ATP:thiamine diphosphate phosphotransferase activity (EC 2.7.4.15), presently in use as a tool for the diagnosis of Leigh's disease (SNE, subacute necrotizing encephalomyelopathy). The results obtained with this phosphotransferase assay can, in part, be explained by the presence of thiamine triphosphate (ThTP) in the preparation of thiamine diphosphate (ThDP) used as a substrate, by the inhibition by ATP of the ThTP phosphohydrolase activity, present in fractions of rat brain homogenates, and by the stimulation by ThDP of the ATPase activity. When [2-¹⁴C-thiazole]thiamine was used for the synthesis of [¹⁴C]ThTP in fractions of rat brain, it was found that after chromatographic separation of thiamine and its phosphates,¹⁴C radio-activity could be demonstrated in the ThTP fractions, even in the absence of an enzyme source. Probably a complex is formed between [¹⁴C]thiamine and a phosphate ester which behaves chromatographically as ThTP. It is concluded that the assay system for the measurement of ThTP synthesis in its present form is, in our hands, not suitable for diagnostic purposes.     

ATP synthase in slow- and fast-growing mycobacteria is active in ATP synthesis and blocked in ATP hydrolysis direction

ATP synthase is a validated drug target for the treatment of tuberculosis, and ATP synthase inhibitors are promising candidate drugs for the treatment of infections caused by other slow-growing mycobacteria, such as Mycobacterium leprae and Mycobacterium ulcerans. ATP synthase is an essential enzyme in the energy metabolism of Mycobacterium tuberculosis; however, no biochemical data are available to characterize the role of ATP synthase in slow-growing mycobacterial strains. Here, we show that inverted membrane vesicles from the slow-growing model strain Mycobacterium bovis BCG are active in ATP synthesis, but ATP synthase displays no detectable ATP hydrolysis activity and does not set up a proton-motive force (PMF) using ATP as a substrate. Treatment with methanol as well as PMF activation unmasked the ATP hydrolysis activity, indicating that the intrinsic subunit ? and inhibitory ADP are responsible for the suppression of hydrolytic activity. These results suggest that the enzyme is needed for the synthesis of ATP, not for the maintenance of the PMF. For the development of new antimycobacterial drugs acting on ATP synthase, screening for ATP synthesis inhibitors, but not for ATP hydrolysis blockers, can be regarded as a promising strategy.     

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.     

Hypothesis for Coupling Energy Transduction with ATP Synthesis or ATP Hydrolysis

A mechanistic hypothesis for coupling and energy transduction has been developed. It is suggested that membrane-bound ATPases play an intermediate high energy role.