Three catalytic sites in mitochondrial ATPase

Kinetic data obtained after determining the hydrolytic activity of ATPase from rat liver in preparations where the enzyme had been purified, or in mitochondria, strongly suggest the existence of three different catalytic sites with different affinity for the substrate. The results obtained when measuring the ATPase activity at different substrate concentrations, and in the presence of the inhibitors KOCN or KSCN, or of the activators dinitrophenol and bicarbonate, show that the binding of these compounds to a regulatory site or sites affects in a different degree the hydrolytic activity of each catalytic site.     

Effects of fluorescamine labeling on mitochondrial ATPase activity.

Fluorescamine labeling of rat liver mitochondria enhances the ATPase activity. It reached maximum stimulation when mitochondria were treated with 30–34 nmol fluorescamine per mg of mitochondrial protein. This stimulation is inhibited by N,N′-dicyclohexylcarbodiimide. The maximum stimulation caused by labeling is the same as that obtained from uncoupler with optimum concentration. The chemiosmotic potential (Δμ_H⁺) decreases as the labeling increased. However, Δμ_H⁺ is not abolished completely even when ATPase activity reaches a maximum. The results suggest that primary amino groups may be involved in controlling mitochondrial ATPase activity.     

Uncoupler-reversible inhibition of mitochondrial ATPase by metal chelates of bathophenanthroline. I. General features

(1) Certain metal chelates of 4,7-diphenyl-1,10-phenanthroline (bathophenanthroline, BPh) are potent inhibitors of soluble mitochondrial F₁-ATPase. (2) The BPh-metal chelate inhibition of soluble mitochondrial F₁-ATPase is relieved by uncouplers of oxidative phosphorylation. (3) The uncouplers appear to interact directly with the inhibitory chelates, forming stoichiometric adducts. (4) A complex between F₁ and bPh₃Fe²⁺, containing 3 mol BPh₃Fe²⁺/mol F₁, has been isolated. The enzymically inactive F₁-BPh₃Fe²⁺ complex binds uncouplers, yielding an enzymically active F₁-BPh₃Fe²⁺-uncoupler complex.     

Temperature dependence of mitochondrial oligomycin-sensitive proton transport ATPase

The temperature dependence of the oligomycin-sensitive ATPase (complex V) kinetic parameters has been investigated in enzyme preparations of different phospholipid composition. In submitochondrial particles, isolated complex V, and complex V reconstituted in dimirystoyl lecithin vesicles, the Arrhenius plots show discontinuities in the range 18–28°C, while no discontinuity is detected with dioleoyl lecithin recombinant. Van't Hoff plots ofK _m also show breaks in the same temperature interval, with the exception of the dioleoylenzyme vesicles, whereK _m is unchanged. Thermodynamic analysis of the ATPase reaction shows that DMPC-complex V has rather larger values of activation enthalpy and activation entropy below the transition temperature (24°C) than those of the other preparations, while all enzyme preparations show similar free energies of activation (14.3–18.5 kcal/mol). The results indicate that temperature and lipid composition influence to a different extent both kinetic and thermodynamic parameters of ATP hydrolysis catalyzed by the mitochondrial ATPase.     

A temperature-dependent structural change of mitochondrial ATPase

The temperature dependence of the intrinsic tryptophan fluorescence in either bovine heart submitochondrial particles or oligomycin-sensitive ATPase isolated therefrom shows a discontinuity at near 25°C, which coincides with the temperature where a break in the Arrhenius plot of ATPase activity is found. Addition of n-butanol to submitochondrial particles induces a decrease of tryptophan fluorescence in the whole temperature range. The discontinuity is interpreted as a temperature-dependent structural change and related to a viscosity-induced phase separation of the intrinsic mitochondrial proteins.     

Uncoupler-reversible inhibition of mitochondrial ATPase by metal chelates of bathophenanthroline. II. comparison with other inhibitors

(1) Trisbathophenanthroline-Fe²⁺(BPh₃Fe²⁺) alters the hyperbolic relationship between concentration of ATP and reaction velocity of F₁-ATPase to sigmoidal, with a simultaneous decrease in maximal velocity. (2) BPh₃Fe²⁺ binds to the β-subunit of F₁ and competes with the binding of aurovertin. The reversal of this effect by uncouplers in enhanced by ADP and diminished by ATP. BPh₃Fe²⁺ also changes the hyperbolic concentration dependence of aurovertin binding to sigmoidal. (3) BPh₃Fe²⁺ stabilizes F₁ against cold inactivation and cold dissociation in an uncoupler-reversible manner. (4) BPh₃Fe²⁺ efficiently protects F₁ against the light-induced inactivation occurring in the presence of Rose Bengal, and the effect is reversed by uncouplers. (5) The results are discussed in relation to the reaction mechanism of F₁-ATPase and other enzymes catalyzing the reversible hydrolysis of pyrophosphate bonds.     

Inhibition of mitochondrial ATPase by 2,4,3',5'-tetrahydroxystilbene.

2,4,3',5'-tetrahydroxystilbene (THS) wa s found to inhibit rat liver mitochondrial adenosine triphosphatase (ATPase) activity induced by various concentrations of 2,4-dinitrophenol (DNP). The I50 was found to be 17 nmoles/mg mitochondrial protein. The maximum inhibitory effects of oligomycin and atractyloside on the DNP-activated mitochondrial ATPase activity can be enhanced by adding THS. The atractyloside-insensitive ATPase activity of Lubrol-treated rat liver mitochondria was also inhibited by low concentration of THS. The tetramethoxyderivative of THS was much less effective than the parent compound in depressing the ATPase activity of both intact and Lubrol-treated mitochondria. These observations suggest that the phenolic groups are essential for the mitochondrial actions of THS, and this compound most probably acts by a mechanism different from oligomycin on the mitochondrial ATPase complex.     

Sulphydryl groups in photosynthetic energy conservation. IV. Inhibition of the ATPase of chloroplast coupling factor 1 by sulphydryl reagents

1. o-Iodosobenzoate and 2,2′-dithio bis-(5-nitropyridine) inhibited by about fifty per cent the ATPase activity of heat-activated chloroplast coupling factor 1 only when present during the heating but were without effect when added before or after the activation. Reversion of this inhibition was only obtained by a second heat treatment with 10 mM dithioerythritol.2. The inhibition of the Ca²⁺-ATPase of coupling factor 1 by o-iodosobenzoate or 2,2′-dithio bis-(5-nitropyridine) was not additive with similar inhibitions obtained with the alkylating reagents iodoacetamide and N-ethylmaleimide.3. The heat-activated ATPase of o-iodosobenzoate-treated coupling factor 1 had a higher K_m for ATP, without modification of V. The modified enzyme was desensitized against the allosteric inhibitor ADP.     

Inhibition of muscle actomyosin ATPase activity by mitochondrial ATPase inhibitor.

Ascites hepatoma cell line AH-130 was tested for the ability to transport various amino acids and glutathione before and after γ-glutamyl transpeptidase of the cells was affinity-labeled and inactivated by 6-diazo-5-oxo-L-norleucine, a glutamine analog. The rate of uptake of alanine, glycine, leucine and glutamine by the cells remained unchanged after γ-glutamyl transpeptidase was inactivated by this affinity label. This indicated that γ-glutamyl transpeptidase of the cell was not involved in the transport process of these amino acids tested. The uptake of glutathione was also tested before and after affinity labeling the enzyme. The total amount of the radioactivity incorporated into the cells was not significantly affected by the enzyme inactivation. However, the relative amount of incorporated intact glutathione was found to be slightly but significantly increased after membraneous γ-glutamyl transpeptidase was inactivated by the affinity label, while that of component amino acid, glycine, was found to decrease. This indicated that glutathione was taken up by the cell in its intact form as well as in degraded forms into its component amino acids, and γ-glutamyl transpeptidase in the ascites tumor cell AH-130 seemed to be involved in the metabolic process via the latter system.     

Oligomycin-resistant mitochondrial ATPase from mouse fibroblasts.

Fourteen oligomycin-resistant LM(TK-) clones were isolated following the mutagenesis of minicells. In the absence of oligomycin, the mutants grew with population doubling times similar to that of the wild type (1 day). In 3 or 5 microgram oligomycin/ml the doubling times of the mutants were 1.2-2.5 days. Both stable and unstable classes were represented among the oligomycin-resistant mutants. Mitochondrial ATPase activities of the mutants were 1.3-1130 times more resistant to oligomycin than the wild type. The mitochondrial ATPase of OLI 14 was found to be bound firmly to the mitochondrial membrane, showed no alteration in the pH optimum compared to wild-type, and exhibited increased resistance to DCCD and venturicidin. These results are consistent with the conclusion that oligomycin resistance in these mutants results from altered mitochondrial ATPase.     

Specificity of nucleotide binding and coupled reactions utilising the mitochondrial ATPase

1. 1. Tightly bound ATP and ADP, found on the isolated mitochondrial ATPase, exchange only slowly at pH 8, but the exchange is increased as the pH is reduced. At pH 5.5, more than 60% of the bound nucleotide exchanges within 2.5 min.

2. 2. Preincubation of the isolated ATPase with ADP leads to about 50% inhibition of ATP hydrolysis when the enzyme is subsequently assayed in the absence of free ADP. This effect, which is reversed by preincubation with ATP, is absent on the membrane-bound ATPase. This inhibition seems to involve the replacement of tightly bound ATP by ADP.

3. 3. Using these two findings, the binding specificity of the tight nucleotide binding sites was determined. iso-Guanosine, 2′-deoxyadenosine and formycin nucleotides displaced ATP from the tight binding sites, while all other nucleotides tested did not. The specificities of the tight sites of the isolated and membrane-bound ATPase were similar, and higher than that of the hydrolytic site.

4. 4. The nucleotide specificities of ‘coupled processes’ nucleoside triphosphate-driven reversal of electron transfer, nucleoside triphosphate-³²P_i exchange and phosphorylation were higher than that of the hydrolytic site of the ATPase and similar to that of the tight nucleotide binding sites.

5. 5. The different nucleotide specificities of uncoupled ATP hydrolysis and coupled processes can be explained even if both processes involve a single common site on the ATPase molecule. This model requires that energy can be ‘coupled’ only when it is released/utilised in the nucleotide binding steps of the mechanism.

6. 6. Adenosine β,γ-imidotriphosphate (AMP-PNP) is not a simple reversible inhibitor of the ATPase, since incubation requires preincubation and is not reversed when the compound is diluted out, or by addition of ATP. This compound inhibits the isolated and membrane-bound ATPase equally well. Its guanosine analogue does not act in this way.

7. 7. In submitochondrial particles, ADP inhibited uncoupled hydrolysis of ATP much more effectively than coupled hydrolysis, the latter being measured both directly (from ATP hydrolysis in the absence of uncoupler) or indirectly, by monitoring ATP-driven reduction of NAD⁺ by succinate.

8. 8. The effects of ADP and AMP-PNP were interpreted as providing evidence for two of the intermediates in the proposed scheme for coupled triphosphate hydrolysis.

Influence of aurovertin on mitochondrial ATPase activity.

Investigations have been made of the kinetic effects of the antibiotic aurovertin on the ATPase and ITPase activity of isolated rat liver mitochondrial ATPase. Unusual patterns of inhibition, decreasing slope, and increasing y-intercept values of double reciprocal plots, were observed with Mg-ATP as the substrate under various conditions. Under specified conditions, aurovertin stimulated hydrolysis of MgATP. The inhibition of MgITP hydrolysis was uncompetitive. Aurovertin eliminated the HCO3-minus stimulation of MgATP hydrolysis. The implications of these findings for the mechanism of mitochondrial ATPase are briefly discussed.     

Functional role of soluble mitochondrial ATPase subunits.

A preparation of soluble mitochondrial ATPase (coupling factor F1) containing no gamma and delta minor subunits has been isolated. The minor-subunits-deficient F1 was found to be competent in ATP hydrolysis. However, it did not demonstrate a "coupling" effect in EDTA-submitochondrial particles. A portion of the ATPase activity of EDTA particles, stimulated by the minor-subunits-deficient F1, was insensitive to oligomycin. ATPase activity of Na+-particles was changed only slightly by this F1. It is suggested that gamma and delta subunits are necessary to form specific contacts between the F1 molecule and components of the mitochrondrial membrane.     

Inhibition of mitochondrial ATPase by Hg++ ions.

1. Maximum heart mitochondrial ATPase activity is displayed in the presence of an ATP/Mg++ ratio of 0.6--1.2. Under these conditions, mercury ions inhibit ATPase activity of both the mitochondria and the isolated enzyme. In both cases, inhibition occurs within concentration limits of 1--1.5X10(-4) M. 2. The inhibitory effect of free Hg++ ions can be abolished by converting them to a complex with ethylenediaminetetraacetic acid [EDTA]. 3. The inhibitory effect of Hg++ ions on mitochondrial ATPase can be attributed to their nonspecific action on functional groups of the active centre or to breakdown of the quaternary structure of the protein molecule of the enzyme.