Effects of arginine binding reagents on ATPase and ATP-Pi exchange activities of mitochondrial ATP synthetase complex (complex V)

ATP synthase and the actions of inhibitors utilized to study its roles in human health, disease, and other scientific areas

ATP synthase, a double-motor enzyme, plays various roles in the cell, participating not only in ATP synthesis but in ATP hydrolysis-dependent processes and in the regulation of a proton gradient across some membrane-dependent systems. Recent studies of ATP synthase as a potential molecular target for the treatment of some human diseases have displayed promising results, and this enzyme is now emerging as an attractive molecular target for the development of new therapies for a variety of diseases. Significantly, ATP synthase, because of its complex structure, is inhibited by a number of different inhibitors and provides diverse possibilities in the development of new ATP synthase-directed agents. In this review, we classify over 250 natural and synthetic inhibitors of ATP synthase reported to date and present their inhibitory sites and their known or proposed modes of action. The rich source of ATP synthase inhibitors and their known or purported sites of action presented in this review should provide valuable insights into their applications as potential scaffolds for new therapeutics for human and animal diseases as well as for the discovery of new pesticides and herbicides to help protect the world's food supply. Finally, as ATP synthase is now known to consist of two unique nanomotors involved in making ATP from ADP and P(i), the information provided in this review may greatly assist those investigators entering the emerging field of nanotechnology.

Mitochondrial ATPase

Considerable progress has been made in recent years in our understanding of the phosphorylating apparatus in mitochondria, chloroplasts, and bacteria. It has become clear that the structure and the function of the ATP synthesizing apparatus in these widely divergent organisms is similar if not virtually identical. The subunit composition of F1, its molecular architecture, the location and function of substrate binding sites, as well as putative control sites, understanding of the component parts of the oligomycin-sensitive ATPase complex, and the role of these components in the function of the complex all are under active investigation in many laboratories. The developing information and the new insights provided have begun to permit experimental approaches, at the molecular level, to the mode of action of the ATPase in electron-transport-coupled ATP synthesis.

Role of energy in oxidative phosphorylation

This article reviews the current status of information regarding the role of energy in the process of oxidative phosphorylation by mitochondria. The available data suggest that in submitochondrial particles (SMP) energy is utilized for the binding of ADP and Pi and for the release of ATP bound at the catalytic sites of F1-ATPase. The process of ATP synthesis on the surface of F1 from F1-bound ADP and Pi appears to be associated with negligible free energy change. The rate of energy production by the respiratory chain modulates the kinetics of ATP synthesis between a low Km (for ADP and Pi)-low Vmax mode and a high Km-high Vmax mode. The Km extremes for ADP are 2-3 microM and 120-150 microM, and Vmax for ATP synthesis at high rates of energy production by bovine-heart SMP is about 440 S-1 (mole F1)-1 at 30 degrees C, which corresponds to 11 mumol ATP (min.mg of protein)-1. The interaction of dicyclohexylcarbodiimide (DCCD) or oligomycin at the proteolipid (subunit c) of the membrane sector (F0) of the ATP synthase complex alters the mode of ATP binding at the catalytic sites of F1, probably to one of lower affinity. It has been suggested that protonic energy might be conveyed to the catalytic sites of F1 in an analogous manner, i.e., via conformation changes in the ATP synthase complex initiated by proton-induced alterations in the structure of the DCCD-binding proteolipid. Finally, the relationship between the steady-state membrane potential (delta psi) and the rates of electron transfer and ATP synthesis has been discussed. It has been shown, in agreement with the delocalized chemiosmotic mechanism, that under appropriate conditions delta psi is exquisitely sensitive to changes in the rates of energy production and consumption.

Inactivation of the mitochondrial ATPase inhibitor protein by chemical modification with diethylpyrocarbonate

Modification of histidine residue(s) by diethylpyrocarbonate treatment of submitochondrial particles obtained by sonication results in inhibition of ATPase activity and stimulation of oligomycin-sensitive H+ conduction. The inhibition of the ATPase (EC 3.6.1.3) activity persisted in F1 isolated from diethylpyrocarbonate-treated submitochondrial particles, which exhibited the absorbance spectrum of modified histidine. Thus the inhibition of the ATPase activity results from histidine modification in F1 subunits. Removal of the natural inhibitor protein from submitochondrial particles resulted in stimulation of proton conduction. After removal of F1 inhibitor protein from the particles the stimulatory effect exerted by diethylpyrocarbonate treatment on proton conduction was lost. Reconstitution experiments showed that purified F1 inhibitor protein lost, after histidine modification, its capacity to inhibit the ATPase activity and proton conduction. These observations show that the stimulation of proton conduction by the ATPase complex effected by diethylpyrocarbonate treatment results from histidine modification in F1 inhibitor protein.

Thiols in oxidative phosphorylation: thiols in the F0 of ATP synthase essential for ATPase activity

It was shown previously that the ATP synthase complex of bovine heart mitochondria contains an essential set of thiols or dithiols in its membrane sector (F0), whose modification by various reagents results in uncoupling [Yagi, T., and Hatefi, Y. (1984) Biochemistry 23, 2449-2455]. The sensitivity to modifiers was increased by membrane energization, and the uncoupling was reversed by membrane-permeable thiol compounds when modifiers other than alkylating agents were used to uncouple. The present paper demonstrates that there exists in the F0 of bovine ATP synthase another set of essential thiols, whose modification results in reversible inhibition of ATPase activity. These thiols are most susceptible to modification by mercurials (p-chloromercuribenzoate greater than p-chloromercuribenzene sulfonate) and do not appear to be modified by N-ethylmaleimide. The reversible modification of these thiols by mercurials protects the ATP synthase against irreversible inhibition in F0 by N,N-dicyclohexylcarbodiimide. The possible location of these two sets of thiols in the F0 of bovine ATP synthase is discussed.

Hypothesis--a chemical mechanism for the biosynthesis of ATP involving ion-exchange reactions

Dissociation constants for Mg . ATP were determined by displacing ATP from Dowex-1 resin with magnesium. These constants were then used to analyze the kinetics of yeast mitochondrial ATPase, in terms of the concentrations of free magnesium and free ATP, at a series of pH values. Both Mg . ATP and hydroxide ions were found to compete with the binding of ATP to the enzyme. These results were interpreted, in terms of an ion-exchange model, to mean that the synthesis of ATP may require the utilization of both magnesium and hydroxide ions for the dissociation of ATP from the enzyme as Mg . ATP. The concentrations of Mg and hydroxide required to compete with ATP were both found to be about three orders of magnitude greater than those required to form products, indicating that magnesium and hydroxide ions can contribute about 8 kcal of energy when ATP is synthesized.

Phenylglyoxal inactivation of the mitochondrial adenosine triphosphatase from Trypanosoma cruzi

The reaction of Trypanosoma cruzi Mg2+-stimulated adenosine triphosphatase (ATPase, coupling factor 1, or F1) with phenylglyoxal, a dicarbonylic compound, resulted in a rapid loss of its enzymatic activity. The inactivation showed pseudo-first-order kinetics with both membrane-bound and soluble F1-ATPase, the rate of the enzyme inactivation being faster in bicarbonate buffer (pH 7.9) than in borate buffer (pH 8.0). The log (pseudo-first-order rate constant) vs. log(phenylglyoxal concentration) plots obtained with the membrane-bound and soluble F1-ATPase in bicarbonate buffer, and also with F1 in borate buffer, had slopes of near 1.0 while the plot for the membrane-bound ATPase in borate buffer had a slope of 1.6. Second-order rate constants (in mM-1 X min-1) were 55 (for both ATPase preparations in bicarbonate buffer) and 34 (for the membrane-bound ATPase in borate buffer). When the reaction was performed in the presence of ATP, the rate of inactivation was significantly decreased. It is concluded that, as in the mammalian F1-ATPase, arginyl residues play an essential role in T. cruzi mitochondrial ATPase, probably at the hydrolytic site.

Functional groups at the catalytic site of BF1 adenosinetriphosphatase from Escherichia coli

The rates of inactivation of BF1 adenosinetriphosphatase (BF1-ATPase) from Escherichia coli by 7-chloro-4-nitro-2,1,3-benzoxadiazole, 1-fluoro-2,4-dinitrobenzene, 2,4,6-trinitrobenzenesulfonate, phenylglyoxal, and N,N'-dicyclohexylcarbodiimide have been measured in the presence and absence of various concentrations of inorganic phosphate, ADP, ATP, or magnesium ion. Dissociation equilibrium constants and rate constants for the labeling reactions have been deduced from a quantitative treatment of the kinetic data. The results suggest that the essential Tyr, Lys, Arg, and Glu or Asp residues are probably located at the catalytic site of BF1-ATPase and that in addition to steric interference, the effect of charge interaction should also be considered in interpreting the kinetic data on the protection of BF1-ATPase by substrate molecules against inactivation by the above labeling reagents. Examination of the relative values of the rate constants for the labeling reactions in the presence and absence of inorganic phosphate, ADP, ATP, or magnesium ion, respectively, and the effect of NBD label on the rates of labeling of the essential guanidinium, amino, and carboxyl groups suggest that the arrangement of these four functional groups at the catalytic site of BF1 may be similar to that previously proposed for MF1-ATPase from bovine heart; namely, the essential amino group and the unusually reactive phenol group are probably located near the bound inorganic phosphate or the gamma-phosphate group of the bound ATP, the essential guanidinium group is probably located nearer to the alpha- or beta-phosphate group than to the gamma-phosphate group of the bound ATP or the bound inorganic phosphate, and the essential carboxylate group is probably complexed with a magnesium ion which it shares with the bound inorganic phosphate.

Mitochondrial adenosinetriphosphatase inhibitor protein: reversible interaction with complex V (ATP synthetase complex)

Mitochondrial ATPase inhibitor protein (IF1) reacts reversibly with complex V and inhibits up to 90% of its ATPase activity. Both the rate and extent of inhibition are pH and temperature dependent and increase as the pH is lowered from pH 8 tp 6.7 (the lowest pH examined) or as the temperature is increased from 4 to 36 degrees C. Nucleotide triphosphates plus Mg2+ ions are required for inhibition of complex V ATPase activity by IF1. In the presence of Mg2+ ions, the effectiveness order of nucleotides is ATP greater than ITP greater than GTP greater than UTP. Highly purified complex V, which requires added phospholipids for expressing ATPase and ATP-Pi exchange activities, cannot be inhibited by IF1 plust ATP-Mg2+ unless phospholipids are also added. This indicates that the active state of the enzyme is necessary for the IF1 effect to be manifested, because F1-ATPase, which does not contain nor require phospholipids for catalyzing ATP hydrolysis, can be inhibited by IF1 plus ATP-Mg2+ in the absence of added phospholipids. The IF1-inhibited complex V, but not IF1-inhibited F1-ATPase, can be reactivated by incubation at pH greater than 7.0 in the absence of ATP-Mg2+. The reactivation rate is pH dependent and is influenced by temperature and enzyme concentration. Complex V preparations contain small and variable amounts of IF1. This endogenous IF1 behaves the same as added IF1 with respect to conditions described above for inhibition and reactivation and can result in 25-50% inhibition in different complex V preparations. However, complex V lacking endogenous IF1 can be reconstituted from F0, F1, oligomycin sensitivity conferring protein, and phospholipids. Inhibition of this reconstituted preparation in the presence of ATP-Mg2+ depends entirely on addition of IF1. In general, the ATP-Pi exchange activity of complex V is more sensitive to the chemical inhibitors of F1-AtPase tha its ATPase activity. This is not so, however, for IF1. Under conditions that IF1 caused approximately 75% inhibition of ATPase activity of complex V, no more than 10% of the ATP-Pi exchange activity was inhibited.

Inactivation of crystalline tobacco ribulosebisphosphate carboxylase by modification of arginine residues with 2,3-butanedione and phenylglyoxal

Crystalline tobacco ribulosebisphosphate carboxylase (3-phospho-D-glycerate carboxylase (dimerizing), EC 4.1.1.39) is rapidly and completely inactivated by 2,3-butanedione in borate buffer or phenylglyoxal, reagents which are highly specific for the modification of arginine residues. Inactivation by phenylglyoxal is enhanced in Bicine buffer and partially reversible, whereas inactivation by butanedione is markedly enhanced in borate buffer, irreversible in the presence of borate and partially reversed upon complete removal of borate and excess reagent. When the modification reaction is performed in the presence of various ligands, only the substrate ribulosebisphosphate and the diphosphorylated competitive inhibitor sedoheptulosebisphosphate protect against inactivation. Loss of carboxylase activity is directly proportional to incorporation of [14C]phenylglyoxal until about 15% of the initial activity remains. Extrapolation to zero activity suggests that inactivation by [14C]phenylglyoxal correlates with the modification of three arginine residues per 69 000 dalton protomer. Complete protection by ribulosebisphosphate or sedoheptulosebisphosphate correlates with the shielding of 1-2 (1.27 +/- 0.25) essential arginyl groups per protomer, which are located within the 55 000 dalton catalytic subunits of the protein. Similarly, amino acid analyses of acid hydrolysates of the butanedione- or phenyl-glyoxal-inactivated and substrate-protected enzymes suggest that complete protection by ribulosebisphosphate correlated with the shielding of 1.9-2.4 arginine residues per protomer. However, modification of the control and substrate-protected enzymes are these arginine-selective alpha-dicarbonyls does not alter modulation by anionic effectors.