FSBA modifies both alpha- and beta-subunits of F1 specifically and can be bound together with AXP at the same alpha-subunit.

Binding of 1 mole 5'-fluorosulfonylbenzoyladenosine (FSBA) per mol F1 induces about 50% inhibition of ATPase activity and 80% inhibition of ITPase activity. The binding of additional ligand results in a further inhibition of both activities. Maximally 5 mol/mol F1, causing complete inhibition of activity, can be bound. Using radioactive FSBA more label is found on alpha-subunits than on beta-subunits under the usual buffer conditions. The modified amino acids are alpha-Tyr300, alpha-Tyr244 and beta-Tyr368. Binding of FSBA, at least up to 3 mol/mol F1, does not result in loss of bound ADP, whether the starting enzyme contains 2, 3 or 4 bound nucleotides. Added adenine nucleotides compete with FSBA only for binding that results in modification of beta-subunits, shifting the alpha/beta ratio of bound label to higher values. It is concluded that the alpha-subunits contain two hydrophobic pockets for the binding of nucleoside moieties, with a different orientation relative to the P-loop. One pocket contains alpha-Tyr244 and alpha-Tyr300, the other beta-Tyr368. Since, however, in the binding of adenine nucleotide di- or triphosphates the P-loop is involved, only one of these ligands can bind per subunit. The previously not understood binding characteristics of several substrate analogues have now become interpretable on the assumption that also the structurally homologous beta-subunits contain 2 pockets where nucleoside moieties can bind. The kinetic effects of FSBA binding indicate that the first FSBA binds at the regulatory site that has a high affinity for ADP and pyrophosphate. Binding of pyrophosphate at this high-affinity regulatory site increases the Vmax of the enzyme, while binding at a second regulatory site, a low-affinity site, increases the rate of binding of FSBA with a factor of about 3. Binding of bicarbonate at this latter site is responsible for the disappearance of the apparent negative cooperativity of the ATPase activity.

Identification of an exchangeable non-catalytic site on mitochondrial F1-ATPase which is involved in the negative cooperativity of ATP hydrolysis.

Labeling of mitochondrial F1-ATPase with 8-azido-ATP or 8-azido-ADP under turnover conditions with Mg(2+)-ATP resulted in the identification of one exchangeable non-catalytic site whose occupation with a ligand does not influence the ATPase activity of F1 when measured at Vmax. With 8-azido-ADP two exchangeable non-catalytic sites could be labeled, but at one of them the bound ligand exchanges, at least partly, during the illumination under turnover conditions. After labeling an exchangeable non-catalytic site under turnover conditions with 8-azido-ATP or with 8-azido-ADP, F1-ATPase kept the ability to bind NAP3-2N3ADP at the slowly exchangeable noncatalytic site, thereby inhibiting the ATPase activity by 45%, as recently described (Edel et al. (1992) Biochim. Biophys. Acta 1101, 329-338). Covalent modification of the low-affinity non-catalytic site with 8-nitreno-AT(D)P increased the Km of ATP and abolished the negative cooperativity of ATP hydrolysis. This site can therefore be marked as a regulatory site, whose occupation with a nucleotide decreases the affinity of the catalytic sites for ATP.

Inhibition of mitochondrial F1-ATPase activity by binding of (2-azido-) ADP to a slowly exchangeable non-catalytic nucleotide binding site.

F1-ATPase was treated so that it contained three tightly bound nucleotides per molecule. One of these was bound at a catalytic site and was rapidly exchangeable, the two remaining nucleotides were nonexchangeable. Incubation of this preparation with ADP in the presence of Mg2+ results in 40-45% inhibition of the ATPase activity. With 2-azido-ADP instead of ADP, the ligand was covalently bound to F1 by illumination, in the presence or absence of turnover of the enzyme, and the site of binding was determined. In this way, one site could be identified, which induces the inhibition. The attachment of the covalently bound 2-nitreno-ADP is at Tyr-368 of a beta-subunit, characterized in the literature as a non-catalytic site. A second, non-catalytic site also binds 2-azido-ADP, but this binding is partially reversed by the addition of ATP and does not cause further inhibition of the ATPase activity. It is concluded that the slowly exchangeable non-catalytic site is the site of inhibition by ADP.

Characteristics of the non-exchangeable nucleotide binding sites of mitochondrial F1 revealed by dissociation and reconstitution with 2-azido-ATP.

The dissociation of mitochondrial F1-ATPase with 3 M LiCl at 0 degrees C, followed by reconstitution, has been analysed. FPLC over a gel filtration column in the dissociation buffer revealed the presence of two protein moieties, an alpha 3 gamma delta epsilon complex and single beta-subunits. When the dissociation and chromatography is performed at pH 6.2, the former protein moiety still contains some adenine nucleotides. Reconstitution of the dissociated complex is not possible any more after FPLC, probably due to the loss of residual adenine nucleotides. After a single column centrifugation step one nucleotide per F1 still remains bound. For reconstitution, additional ATP, or a suitable analog, is required. 2-Azido-ATP, but not 8-azido-ATP or ITP, can replace ATP during the reconstitution. F1, reconstituted in the presence of 2-azido-ATP, contains three tightly bound nucleotides, similar to freshly isolated F1, of which in this case one is an adenine nucleotide and two are azido-adenine nucleotides. One of the latter can be rapidly exchanged and is bound to a catalytic site. Covalent binding (at a beta-subunit) of the other tightly bound 2-azido-ATP by ultraviolet illumination does not result in inhibition of the enzyme. Digestion of F1 with trypsin, followed by HPLC, showed that the label is not bound to the fragment containing Tyr-368, nor to the fragment containing Tyr-345. This result was confirmed by CNBr digestion, followed by SDS-urea PAGE. We conclude that during dissociation of F1 one tightly bound nucleotide (ADP) remains bound at an alpha/beta interface site and that for reconstitution binding of ATP to a (non-catalytic) beta-site is required. The conformation of this site differs from that of the two catalytic beta-sites.

Bovine cytochrome c oxidases, purified from heart, skeletal muscle, liver and kidney, differ in the small subunits but show the same reaction kinetics with cytochrome c.

(1) Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate of purified cytochrome c oxidase preparations revealed that bovine kidney, skeletal muscle and heart contain different cytochrome c oxidase isoenzymes, which show differences in mobility of the subunits encoded by the nuclear genome. No differences in subunit pattern were observed between the oxidase preparations isolated from kidney and liver. (2) The kinetics of the steady-state reactions between bovine ferrocytochrome c and the four types of bovine cytochrome c oxidase preparation were compared under conditions of both high- and low-ionic strength. Also the pre-steady-state kinetics were studied. Only minor differences were observed in the electron-transfer activity of the isoenzymes. Thus, our experiments do not support the notion that the subunits encoded by the nuclear genome act as modulators conferring different activities to the isoenzymes of cytochrome c oxidase. (3) The cytochrome c oxidase preparation from bovine skeletal muscle was found to consist mainly of dimers, whereas the enzymes isolated from bovine kidney, liver and heart were monomeric.

The effect of detergents on bovine cytochrome c oxidase: a kinetic approach.

(1) Investigation of the relationship between the detergent concentration and steady-state and pre-steady-state kinetics of cytochrome c oxidase proved to be a valid approach in the study of protein-detergent interaction. (2) Laurylmaltoside, sodium cholate and Triton X-100 influenced the kinetics of cytochrome c oxidase cooperatively at detergent concentrations near their critical micelle concentration. This mode of interaction reflects disaggregation of the oxidase as a result of cooperative binding of the detergent. (3) Addition of increasing concentrations of Tween-80 to the aggregated enzyme caused a more gradual decrease in aggregation of the oxidase, which did not result in a change in activity of the enzyme. This suggests that aggregation of cytochrome c oxidase occurs in a highly regular manner in which no catalytic sites are shielded off. (4) Oxidase aggregates present at detergent concentrations below the critical micelle concentration of laurylmaltoside and Triton X-100 showed considerable activity. Their kinetics were equal to those of the oxidase in Tween-80, suggesting that the protein molecules are aligned in a similar way in all oligomers. Aggregates present in low concentrations of sodium cholate showed turnover rates that were twice as low as those observed with other aggregates. (5) Solubilisation of the oxidase by sodium cholate or Triton X-100 resulted in almost complete inhibition of enzymic activity, whereas the association rate of ferrocytochrome c was almost equal to that found for monomeric oxidase in laurylmaltoside. These results are in agreement with a mixed-type inhibition.