Action of alkyl cations and the natural ATPase inhibitor from mitochondria on soluble mitochondrial ATPase

The effect of the natural ATPase inhibitor and octylguanidine on the ATPase activity of soluble oligomycin-insensitive mitochondrial F₁ were compared. Both compounds induced a maximal inhibition of 60–80% in various preparations of F₁ studied. The inhibition was of the uncompetitive type with respect to MgATP, and the action of the compounds was partially additive. The data suggest that octylguanidine reproduces the action of the natural ATPase inhibitor. Alkylammonium salts also affect the ATPase activity in a similar form. F₁ bound to Sepharose-hexylammonium is largely inactive, whilst free hexylammonium at higher concentrations induces only a partial inhibition of the activity. This suggests that the degree of immobilization of F₁ is related to the magnitude of inhibition of ATPase activity induced by alkyl cations. The binding of F₁ to Sepharose-hexylammonium is prevented by high concentrations of Na⁺ or K⁺.     

Increased content of natural ATPase inhibitor in tumor mitochondria

The ATPase activity of Zajdela hepatoma and Yoshida sarcoma submitochondrial particles was several times lower than the enzyme activity in rat heart and rat liver submitochondrial particles. The content of F1-ATPase in the tumor mitochondria was found not to be very different from that in mitochondria of rat liver. Immunochemical determination of the amount of the natural ATPase inhibitor revealed that the tumor mitochondria contain 2-3-times more ATPase inhibitor than control mitochondria. It is concluded that the low ATPase activity of the tumor mitochondria results from the inhibition of the enzyme activity by the natural ATPase inhibitor.     

ATPase inhibitor from yeast mitochondria. Purification and properties.

1. Mitochondria from Candida utilis CBS 1516 and Sacchromyces cerevisiae JB 65 possess an ATPase-inhibitor activity. The inhibitor activity depends on the growth conditions of the yeast cells. It is markedly decreased when the cells are grown in the presence of a high concentration of glucose, which suggests that glucose represses the synthesis of the ATPase inhibitor or of a protein required for the insertion of the inhibitor into the inner mitochondrial membrane. 2. The ATPase inhibitor has been isolated from D. utilis mitochondria and purified to homogeneity. The minimal molecular weight calculated from amino acid composition is close to 7500. Dtermination of the molecular weight by sokium dodecylsulfate-polyacrylamide gel electrophoresis gives a value close to 6000. 3. The ATPas inhibitor of C. utilis mitochondria differs from the beef heart ATPase inhibitor by a number of properties. It has a lower molecular weight (6000-7500 vs 10500), a different amino acid composition, and a more acidic isoelectric point 5, 6 vs 7, 6). In spite of these differences, the C. utilis inhibitor cross-reacts with the ATPase of beef heart submitochondrial inhibitor-depleted particles. 4. The interaction of the C. utilis inhibitor with the ATPase of inhibitor-depleted particles requires the addition of Mg-2+-ATP or ATP in the incubation medium. 5. 14-C labelling of the C.utilis inhibitor has been achieved by growing C. utilis in a medium supplemented with [14-C]leucine. It has been found by titration experiments that the C. utilis 14-C-labelled inhibitor binds to the homologous submitochondrial inhibitor-depleted particles with a KD of about 10- minus 7 M. The number of binding sites is of the order of 0.1 nmol/mg protein.     

Purification and properties of ATPase inhibitor from rat liver mitochondria.

(1) The ATPase inhibitior protein has been isolated from rat liver mitochondria in purified form. The molecular weight determined by sodium dodecyl sulfate gel electrophoresis is approximately 9500, and the isoelectric point is 8.9. (2) The protein inhibits both the soluble ATPase and the particle-bound ATPase from rat liver mitochondria. It also inhibits ATPase activities of soluble F1, and inhibitor-depleted submitochondrial particles derived from bovine heart mitochondria. (3) On particle-bound ATPase the inhibitor has its maximal effect if incubated in the presence of Mg2+. ATP at slightly acidic pH. (4) The inhibitor has a minimal effect on Pi-ATP exchange activity in sonicated submitochondrial particles. However, unexpectedly the inhibitor greatly stimules Pi-ATP exchange activity in whole mitochondria while the low ATPase activity of the mitochondria is not affected. The possible mechanism of action of the inhibitor on intact mitochondria is offered.     

Partial characterization of a soluble ATPase from pea cotyledon mitochondria.

A partially purified soluble ATPase (ATP phosphohydrolase, EC 3.6.1.3) from pea cotyledon mitochondria was characterized. Inhibition patterns with azide, NaF, and cold, and a stimulation by 2,4-dinitrophenol were typical of F1-ATPases from mammalian mitochondria. The enzyme hydrolysed GTP, ITP, and ATP, but not CTP, UTP, ADP, or IDP. ATPase and ITPase activities were strongly inhibited by ADP and to a lesser extent by IDP. Distinctive properties of the pea mitochondrial enzyme were activation by high concentrations of CaCl2 and stimulation by NaCl.     

Regulation of the synthesis and hydrolysis of ATP by mitochondrial ATPase. Role of the natural ATPase inhibitor protein

The action of the natural ATPase inhibitor protein of Pullman and Monroy (Pullman, M. E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769) on the mechanisms of energy conservation of heart mitochondria has been explored. The synthesis and hydrolysis of ATP and the Pi-ATP exchange reaction were studied in submitochondrial particles that possess the ATPase-inhibitor protein complex in two distinguishable states. In addition to their different rates of hydrolysis, the two states of the complex have been identified from their different accessibility to antibodies directed against the inhibitor protein, and from the different action of antibodies and trypsin on the ATPase activity of the two types of particles studied. The steady state rates of hydrolysis and of the Pi-ATP exchange reaction of the particles are determined by the state in which the ATPase-inhibitor complex exists. Apparently by modifying the rate of one of the steps involved in the catalytic reaction of the ATPase, the inhibitor protein determines the extent to which the enzyme is able to catalyze ATP hydrolysis and the Pi-ATP exchange reaction. This action of the inhibitor protein also reflects the rate at which the particles carry out oxidative phosphorylation.     

Specific fragmentation of natural inhibitor of mitochondrial ATPase by thrombin

The ability of cholestanol (5α-cholestan-3β-ol) to support growth of two independently derived sterol auxotrophs, FY3 and GL7, has been examined. Growth on this stanol was precluded unless minute quantities of sterol were also available. Contaminating sterol in most cholestanol preparations or excess sterol in the inoculum used in growth studies could provide the required sterol in quantities capable of sustaining growth through an entire culture cycle. Evidence is presented for multiple functions of sterols in $\text{Saccharomyces}\text{cerevisiae}$.     

Cell-free synthesis of mitochondrial ATPase inhibitor precursor and its transport into yeast mitochondria

ATPase inhibitor protein, which blocks mitochondrial ATPase activity by forming an enzyme-inhibitor complex, was found to be synthesized as a larger precursor in a cell-free translation system directed by yeast mRNA. Other protein factors, which stabilize latent ATPase by binding to the enzyme-inhibitor complex, were also found to be formed as larger precursors. The precursor of ATPase inhibitor protein was transported into isolated yeast mitochondria and was cleaved to the mature peptide in the mitochondria. Impaired mitochondria lacking phosphorylation activity could not convert the precursor to the mature form. Neither antimycin A nor oligomycin alone exhibited a marked effect on the transport-processing of the precursor by intact mitochondria. However, when antimycin A was added with oligomycin, the transport-processing was markedly inhibited. The processing was also strongly inhibited by an uncoupler, carbonylcyanide p-trifluoro-methoxyphenyl hydrazone. The inhibition by the uncoupler was not relieved by ATP added externally. It is concluded that the transport-processing of precursor proteins requires intact mitochondria with a potential difference across the inner membrane.     

Inhibition of soluble yeast mitochondria ATPase by ethidium-bromide.

Surface galactosyl residues of alive embryonal carcinoma cells were tritium-labeled by the galactose oxidase NaB(3H)4 method. The labeled glycopeptides isolated from Pronase digests of the cells, were found to be similar to those prepared from endogeneously labeled embryonal carcinoma cells. They consisted mostly of high molecular weight material, and contained receptors for peanut agglutinin. It is concluded that at least a fraction of the high molecular weight glycopeptides characteristic of early embryonic cells, is displayed on the cell suface.     

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.     

Purification and properties of ATPase inhibitor from rat liver mitochondria

(1) The ATPase inhibitor protein has been isolated from rat liver mitochondria in purified form. The molecular weight determined by sodium dodecyl sulfate gel electrophoresis is approximately 9500, and the isoelectric point is 8.9.

(2) The protein inhibits both the soluble ATPase and the particle-bound ATPase from rat liver mitochondria. It also inhibits ATPase activities of soluble F₁, and inhibitor-depleted submitochondrial particles derived from bovine heart mitochondria.

(3) On particle-bound ATPase the inhibitor has its maximal effect if incubated in the presence of Mg²⁺. ATP at slightly acidic pH.

(4) The inhibitor has a minimal effect on P_i-ATP exchange activity in sonicated submitochondrial particles. However, unexpectedly the inhibitor greatly stimulates P_i-ATP exchange activity in whole mitochondria while the low ATPase activity of the mitochondria is not affected. The possible mechanism of action of the inhibitor on intact mitochondria is offered.