Control of activity states of heart mitochondrial ATPase. Role of the proton-motive force and Ca2+

The ATPase complex of submitochondrial particles exhibits activity transitions that are controlled by the natural ATPase inhibitor (Gómez-Puyou, A., Tuena de Gómez-Puyou, M. and Ernster, L. (1979) Biochim. Biophys. Acta 547, 252–257). The ATPase of intact heart mitochondria also shows reversible activity transitions; the activation reaction is induced by the establishment of electrochemical gradients, whilst the inactivation reaction is driven by collapse of the gradient. In addition it has been observed that the influx of Ca²⁺ into the mitochondria induces a rapid inactivation of the ATPase; this could be due to the transient collapse of the membrane potential in addition to a favorable effect of Ca²⁺-ATP on the association of the ATPase inhibitor peptide to F₁-ATPase. This action of Ca²⁺ may explain why mitochondria utilize respiratory energy for the transport of Ca²⁺ in preference to phosphorylation. It is concluded that the mitochondrial ATPase inhibitor protein may exert a fundamental regulatory function in the utilization of electrochemical gradients.     

Isolation of the mitochondrial F1-F0 adenosine triphosphatase by Sepharose-hexylammonium chromatography: properties and reconstitution in liposomes

Lauryl dimethylamino oxide, a zwitterionic detergent, was employed to solubilize the H+ ATPase from beef heart mitochondria. A simple preparation procedure has been devised to obtain F1-F0 based on a method described to purify F1 ATPase (M. Tuena de Gómez-Puyou and A. Gómez-Puyou, 1977, Arch. Biochem. Biophys. 182, 82-86) which consists of the selective adsorption of F1 to Sepharose-hexylammonium beads. The preparation showed approximately 18 bands in sodium dodecyl sulfate-polyacrylamide gel electrophoresis; 5 correspond to F1 subunits and the rest probably to the stalk and hydrophobic sector F0. The binding of [14C]dicyclohexylcarbodiimide to a low-molecular-weight component of this preparation was demonstrated. The F1-F0 complex was reconstituted into phospholipid vesicles which displayed ATP-Pi exchange and ATP-dependent 9-aminoacridine fluorescence quenching, both sensitive to proton channel inhibitors.     

Mitochondrial creatine kinase activity prevents reactive oxygen species generation: antioxidant role of mitochondrial kinase-dependent ADP re-cycling activity

As recently demonstrated by our group (da-Silva, W. S., Gómez-Puyou, A., Gómez-Puyou, M. T., Moreno-Sanchez, R., De Felice, F. G., de Meis, L., Oliveira, M. F., and Galina, A. (2004) J. Biol. Chem. 279, 39846-39855) mitochondrial hexokinase activity (mt-HK) plays a preventive antioxidant role because of steady-state ADP re-cycling through the inner mitochondrial membrane in rat brain. In the present work we show that ADP re-cycling accomplished by the mitochondrial creatine kinase (mt-CK) regulates reactive oxygen species (ROS) generation, particularly in high glucose concentrations. Activation of mt-CK by creatine (Cr) and ATP or ADP, induced a state 3-like respiration in isolated brain mitochondria and prevention of H(2)O(2) production obeyed the steady-state kinetics of the enzyme to phosphorylate Cr. The extension of the preventive antioxidant role of mt-CK depended on the phosphocreatine (PCr)/Cr ratio. Rat liver mitochondria, which lack mt-CK activity, only reduced state 4-induced H(2)O(2) generation when 1 order of magnitude more exogenous CK activity was added to the medium. Simulation of hyperglycemic conditions, by the inclusion of glucose 6-phosphate in mitochondria performing 2-deoxyglucose phosphorylation via mt-HK, induced H(2)O(2) production in a Cr-sensitive manner. Simulation of hyperglycemia in embryonic rat brain cortical neurons increased both DeltaPsi(m) and ROS production and both parameters were decreased by the previous inclusion of Cr. Taken together, the results presented here indicate that mitochondrial kinase activity performed a key role as a preventive antioxidant against oxidative stress, reducing mitochondrial ROS generation through an ADP-recycling mechanism.     

Regulation of ATP hydrolysis in liver mitochondria from ground squirrel

The uncoupler-induced inactivation of H(+)-ATPase in liver mitochondria from ground squirrel has been studied. The dependence of this process on delta mu H+, pH and ATP indicates that it is caused by the protein inhibitor. This conclusion is also supported by the protective effect of Zn2+ and Cu2+. The inactivation can be induced by Ca2+ at low concentrations in the presence of phosphate. It is shown that the protein inhibitor inactivates ATPase almost completely under optimal conditions while its effect in mice or rat liver mitochondria does not exceed 30%. The potential efficiency of the inhibitor's action does not depend on either the season or the state of animals (hibernating or active). At the same time, the sensitivity of this system to Ca2+ is significantly lower in active (summer) animals.     

Mechanism of calcium potentiation of oxygen free radical injury to renal mitochondria. A model for post-ischemic and toxic mitochondrial damage

With a variety of forms of ischemic and toxic tissue injury, cellular accumulation of Ca2+ and generation of oxygen free radicals may have adverse effects upon cellular and, in particular, mitochondrial membranes. Damage to mitochondria, resulting in impaired ATP synthesis and diminished activity of cellular energy-dependent processes, could contribute to cell death. In order to model, in vitro, conditions present post-ischemia or during toxin exposure, the interactions between Ca2+ and oxygen free radicals on isolated renal mitochondria were characterized. The oxygen free radicals were generated by hypoxanthine and xanthine oxidase to simulate in vitro one of the sources of oxygen free radicals in the early post-ischemic period in vivo. With site I substrates, pyruvate and malate, Ca2+ pretreatment, followed by exposure to oxygen free radicals, resulted in an inhibition of electron transport chain function and complete uncoupling of oxidative phosphorylation. These effects were partially mitigated by dibucaine, a phospholipase A2 inhibitor. With the site II substrate, succinate, the electron transport chain defect was not manifest and respiration remained partially coupled. The electron transport chain defect produced by Ca2+ and oxygen free radicals was localized to NADH CoQ reductase. Calcium and oxygen free radicals reduced mitochondrial ATPase activity by 55% and adenine nucleotide translocase activity by 65%. By contrast oxygen free radicals alone reduced ATPase activity by 32% and had no deleterious effects on translocase activity. Dibucaine partially prevented the Ca2+-dependent reduction in ATPase activity and totally prevented the Ca2+-dependent translocase damage observed in the presence of oxygen free radicals. These findings indicate that calcium potentiates oxygen free radical injury to mitochondria. The Ca2+-induced potentiation of oxygen free radical injury likely is due in part to activation of phospholipase A2. This detrimental interaction associated with Ca2+ uptake by mitochondria and exposure of the mitochondria to oxygen free radicals may explain the enhanced cellular injury observed during post-ischemic reperfusion.     

Properties of epsilon-ATP hydrolysis by CF1-ATPase from pea chloroplasts

The ATPase activity of CF1 isolated from pea chloroplasts with epsilon-ATP, the fluorescent analog of ATP and ATP used as substrates, in the presence of Mg2+, Ca2+ and sodium sulfite (stimulator of the ATPase activity) was studied. The rate of epsilon-ATP hydrolysis in the presence of Mg2+ is nearly two times as low as that of ATP; an addition of sodium sulfite to the reaction mixture increases the reaction rate without changing the above ratio. The rate of Ca2+-dependent hydrolysis of epsilon-ATP is rather low as compared to that in the presence of Mg2+. epsilon-ADP is a competitive inhibitor of Mg2+-dependent ATPase reaction and inhibits this process in the presence of Ca2+, the inhibition being of a mixed type. Modification of CF1 by covalent binding of epsilon-ADP results in a 70-80% decrease of the Mg2+-dependent ATPase activity, the Ca2+-dependent ATPase activity is changed only insignificantly thereby. The differences in the activation of ATP and epsilon-ATP hydrolyses by Ca2+ and Mg2+ can be accounted for by the existence of two sites in the active center of CF1, which are specific for Mg2+ and Ca2+, respectively. It is concluded that the binding of epsilon-ADP occurs in the Mg2+-dependent ATPase site of the active center.     

Dimethylsulfoxide promotes K+-independent activity of pyruvate kinase and the acquisition of the active catalytic conformation.

Pyruvate kinase requires K+ for maximal activity; the enzyme exhibits 0.02% of maximal activity in its absence [Kayne, F. J. (1971) Arch. Biochem. Biophys. 143, 232-239]. However, pyruvate kinase entrapped in reverse micelles exhibits an important K+-independent activity [Ramírez-Silva, L., Tuena de Gómez-Puyou, M., & Gómez-Puyou, A. (1993) Biochemistry 32, 5332-5338]. It is possible that the amount of water, as well as interactions of the protein with the micelles, can account for this behavior. We therefore explored the solvent effects on the catalytic properties of muscle pyruvate kinase. The enzyme exhibited an activity of 19.4 micromol x min(-1) x mg(-1) in 40% dimethylsulfoxide, compared with 280 and 0.023 micromol x min(1) x mg(-1) observed with and without K+ in water, respectively. pH activity profiles and kinetic constants for the substrates of pyruvate kinase in dimethylsulfoxide without K+ were similar to those in 100% water with K+, and differed from those in water without K+. The spectral center of mass of the emission spectrum of pyruvate kinase in 100% water exhibited a blue shift of 3.5 nm in the presence of Mg(2+), phosphenolpyruvate, and K+, ligands that induce the active conformation of the enzyme. The spectral center of mass of the apoenzyme in 30-40% dimethylsulfoxide coincided with that of the enzyme-Mg(2+)-phosphenolpyruvate-K+ complex in 100% water. The water relaxation rate enhancement factor and binding of phosphenolpyruvate to the pyruvate kinase-Mn(2+)-(CH3)4N+ complex in 30-40% dimethylsulfoxide were similar to those of the pyruvate kinase-Mn(2+)-K+ complex in water. The aforementioned results indicate that when muscle pyruvate kinase is without K+, 30-40% dimethylsulfoxide induces its active conformation.     

Inhibition of oxidative phosphorylation by Ca2+ or Sr2+: a competition with Mg2+ for the formation of adenine nucleotide complexes

Intramitochondrial Sr2+, similar to Ca2+, inhibits oxidative phosphorylation in intact rat-liver mitochondria. Both Ca2+ and Sr2+ also inhibit the hydrolytic activity of the ATPase in submitochondrial particles. Half-maximal inhibition of ATPase activity was attained at a concentration of 2.5 mM Ca2+ or 5.0 mM Sr2+ when the concentration of Mg2+ in the medium was 1.0 mM. The inhibition of ATPase activity by both cations was strongly decreased by increasing the Mg2+ concentration in the reaction medium. In addition, kinetical data and the determination of the concentration of MgATP, the substrate of the ATPase, in the presence of different concentrations of Ca2+ or Sr2+ strongly indicate that these cations inhibit ATP hydrolysis by competing with Mg2+ for the formation of MgATP. On the basis of a good agreement between these results with submitochondrial particles and the results of titrations of oxidative phosphorylation with carboxyatractyloside or oligomycin in mitochondria loaded with Sr2+ it can be concluded that intramitochondrial Ca2+ or Sr2+ inhibits oxidative phosphorylation in intact mitochondria by decreasing the availability of adenine nucleotides to both the ADP/ATP carrier and the ATP synthase.     

Calcium transport mechanism in crayfish gastrolith epithelium correlated with the molting cycle. II. Cytochemical demonstration of Ca2+-ATPase and Mg2+-ATPase

Periodical changes in Ca2+-ATPase and Mg2+-ATPase activity were observed cytochemically in the crayfish gastrolith epithelium during the molting cycle in relation to the calcium transport mechanism. The ATPase activity was demonstrated by a new one-step lead citrate method. The reaction products were mainly restricted to the matrix of type II cell mitochondria. The Ca2+-ATPase activity was intensely observed in two calcium moving stages, the small gastrolith period which indicates the beginning of gastrolith formation, and the aftermolt , when the calcified gastrolith has been dissolved in the stomach and then reabsorbed from the stomach epithelium into the newly formed soft exoskeleton through the blood. Although the intensity of reaction products of Mg2+-ATPase varied in each stage, the enzymatic activity was observed throughout all molting stages. Reaction products were observed in all mitochondria, basement membranes, apical cytoplasmic membranes, and in some lysosomes. In conclusion, periodical changes in the two types of ATPase activity were seen in the mitochondria of gastrolith epithelium during the molting cycle, but Ca2+-ATPase activity seemed to be more prominently synchronized to the calcium movement in the gastrolith epithelium than Mg2+-ATPase activity. There results provide the strong evidence that Ca2+-ATPase may act strongly in the calcium transport system of crayfish molting.     

2,5-Di(tert-butyl)-1,4-benzohydroquinone--a novel inhibitor of liver microsomal Ca2+ sequestration

Treatment of rat liver microsomes with 2,5-di(tert-butyl)-1,4-benzohydroquinone caused a dose-related inhibition (Ki congruent to 1 microM) of ATP-dependent Ca2+ sequestration. This was paralleled by a similar impairment of the microsomal Ca2+-stimulated ATPase activity. In contrast, the hydroquinose failed to induce Ca2+ release from Ca2+-loaded liver mitochondria (supplied with ATP), and inhibited neither the mitochondrial F1F0-ATPase nor the Ca2+-stimulated ATPase activity of the hepatic plasma membrane fraction. The inhibition of microsomal Ca2+ sequestration was not associated with any apparent alteration of membrane permeability or loss of other microsomal enzyme activities or modification of microsomal protein thiols. These findings suggest that 2,5-di(tert-butyl)-1,4-benzohydroquinone is a potent and selective inhibitor of liver microsomal Ca2+ sequestration which may be a useful tool in studies of Ca2+ fluxes in intact cells and tissues.     

Characterization of rat heart plasma membrane Ca2+/Mg2+ ATPase

The Ca2+/Mg2+ ATPase of rat heart plasma membrane was activated by millimolar concentrations of Ca2+ or Mg2+; other divalent cations also activated the enzyme but to a lesser extent. Sodium azide at high concentrations inhibited the enzyme by about 20%; oligomycin at high concentrations also inhibited the enzyme slightly. Trifluoperazine at high concentrations was found inhibitory whereas trypsin treatment had no significant influence on the enzyme. The rate of ATP hydrolysis by the Ca2+/Mg2+ ATPase decayed exponentially; the first-order rate constants were 0.14-0.18 min-1 for Ca2+ ATPase activity and 0.15-0.30 min-1 for Mg2+ ATPase at 37 degrees C. The inactivation of the enzyme depended upon the presence of ATP or other high energy nucleotides but was not due to the accumulation of products of ATP hydrolysis. Furthermore, the inactivation of the enzyme was independent of temperature below 37 degrees C. Con A when added into the incubation medium before ATP blocked the ATP-dependent inactivation; this effect was prevented by alpha-methylmannoside. In the presence of low concentrations of detergent, the rate of ATP hydrolysis was reduced while the ATP-dependent inactivation was accelerated markedly. Both Con A and glutaraldehyde decreased the susceptibility of Ca2+/Mg2+ ATPase to the detergent. These results suggest that the Ca2+/Mg2+ ATPase is an intrinsic membrane protein which may be regulated by ATP.     

Calcium-binding ATPase inhibitor protein of bovine heart mitochondria. Role in ATP synthesis and effect of Ca2+

Submitochondrial particles (A particles) and phosphorylating electron-transport particles (ETPH) were prepared from bovine heart mitochondria. The A particles either were supplemented with or were depleted of the mitochondrial calcium-binding ATPase inhibitor protein (CaBI). The CaBI-depleted A particles still retained the Pullman-Monroy ATPase inhibitor protein (PMI), and the other particles all contained both CaBI and PMI. ATP synthase and ATPase activities of the particles were measured in similar reaction mixtures by luminescence of firefly luciferin-luciferase. Succinate was the respiratory substrate, and the adenylate kinase inhibitor P1, P5-di(adenosine-5') pentaphosphate was obligatory. The ATP synthase activity of CaBI-depleted A particles was 30-40% of that of the A and ETPH particles, and its ATPase activity was 7-8 times greater. Reconstitution of the CaBI-depleted A particles with CaBI restored the original ATP synthase and ATPase activities. ATP synthase activity rose about 1.7-fold when A particles were supplemented with additional CaBI and ATPase activity dropped to 9% of the original. Varying Ca2+ levels had little or no effect on the ATP synthase and ATPase activities of the CaBI-depleted A particles. In contrast, ATP synthase activity of the other particles was decreased by as much as 70% at the optimal Ca2+ concentration of 1 microM, and the ATPase activity of the A and EPTH particles rose concomitantly by 7-8-fold. The ATP synthase and ATPase activities of all the particles in microM Ca2+ became like those of the CaBI-depleted A particles. These changes were reversible; normal activities were restored as Ca2+ concentrations were raised above 1 microM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proton-translocating adenosinetriphosphatase in rough and smooth microsomes from rat liver

Rat liver smooth and rough microsomal membranes exhibit an ATP-dependent H+ transport which can be inhibited by sulfhydryl reagents and dicyclohexylcarbodiimide but is resistant to oligomycin. On the basis of inhibitor sensitivities and substrate specificities, this H+ pump was found to be different from that of mitochondria, lysosomes, gastric H+-K+-ATPase, and yeast plasma membrane H+-ATPase but to resemble that of endocytic vesicles and the H+ pump responsible for urinary acidification. The transport process is accelerated by valinomycin in the presence of potassium, suggesting that it is an electrogenic pump. The same fractions were enriched in an ATPase with inhibitor sensitivities similar to those of the transport activity. It is possible that the proton electrochemical gradients generated by this pump may play a role in the translocation of proteins and sugars, two of the major functions of these structures.     

Photoaffinity labeling of the (Ca+Mg)ATPase of skeletal and cardiac sarcoplasmic reticulum with [γ-32P]-8-azido-ATP

8-azido-ATP, when used in the 0.2–5 μM concentration range, fulfills the criteria for a specific photoaffinity label for the (Ca+Mg)ATPase of sarcoplasmic reticulum. It is a substrate for the enzyme. It is a mixed inhibitor of ATPase activity. When photolyzed at 0° it is an inhibitor of ATPase activity. The photoinduced binding of 8-azido-ATP to the (Ca+Mg)ATPase is promoted by Ca²⁺. The dependence of the labeling of the (Ca+Mg)ATPase on 8-azido-ATP, Ca²⁺ and Mg²⁺ concentrations strongly suggests that 2 classes of sites are labeled. When 10–60 μM 8-azido-ATP was used to label sarcoplasmic reticulum, proteins in addition to the (Ca+Mg)ATPase were labeled.     

The effect of the natural protein inhibitor on H+-ATPase hepatoma 22a mitochondria

The uncoupler-induced inactivation of H+-ATPase in hepatoma 22a and mouse liver mitochondria has been studied. The dependence of this process on delta microH, and pH and ATP was established. The inactivated ATPase could be reactivated at alkaline pH values in the absence of ATP. These data indicate that the inactivation is apparently caused by the natural protein inhibitor. ATP- and pH-dependent decrease of ATPase activity is also observed after Lubrol-WX disruption of mitochondria. It can be proposed that practically all ATPase molecules in hepatoma mitochondria are in a catalytically active complex with the protein inhibitor. At low delta microH this complex is inactivated via reversible pH-dependent and irreversible ATP-dependent rearrangements. The pH-dependent rearrangement of the isolated protein inhibitor from hepatoma mitochondria is also observed.     

Ultrastructural study of the Ca2+-dependent ATPase activity in rat adenohypophyseal cells

Ca-dependent ATPase activity in the rat anterior pituitary was demonstrated in 50-microns tissue slices of aldehyde-fixed tissue with the medium of Takano et al. (Cell Tissue Res. 243:91. 1986).--The outer surface of the plasma membrane of the parenchymal as well as the folliculo-stellate cells was lined with lead precipitate. The reaction deposit was particularly well localized in intercellular spaces both between two parenchymal cells, and between a parenchymal and a folliculo-stellate cell. A fine reaction deposit was also seen in the endoplasmic reticulum and Golgi apparatus of some parenchymal cells. Elimination of Ca2+ from the tissue and the substrate medium drastically reduced the amount of reaction product. If ATP was omitted or replaced by sodium beta-glycerophosphate, no reaction product was seen. Changing the Ca2+ concentration or addition of Mg2+ to the standard medium caused a decrease in reaction intensity. Substitution of Mg2+ for Ca2+ resulted, again in well-localized lead deposition which we attribute to the activity of another enzyme. We suggest that the activity we described in the membrane of glandular cells may correspond to the enzyme involved in the long-term regulation of intracellular Ca2+ level.     

A possible role of protein phosphorylation in the inactivation of a Ca2+-induced Ca2+ release channel from skeletal muscle sarcoplasmic reticulum

The Ca2+-induced Ca2+ release channel in the heavy fraction of the sarcoplasmic reticulum (SR) from rabbit skeletal muscle is inactivated during ATP-dependent Ca2+ uptake (Morii, H., Takisawa, H., & Yamamoto, T. (1985) J. Biol. Chem. 260, 11536-11541). AMP, one of the adenine nucleotides which activate the Ca2+ release, delayed the onset of the channel inactivation when added early during the course of the Ca2+ uptake. However, AMP could no longer activate the channel but accelerated the inactivation when added during the later phase of the Ca2+ uptake. In SR passively loaded with Ca2+, the Ca2+ channel which had been activated by AMP and Ca2+ was not spontaneously inactivated. Similarly, during GTP-dependent Ca2+ uptake, the channel activated by AMP was not inactivated. In addition acid phosphatase markedly delayed the onset of the inactivation during ATP-dependent Ca2+ uptake, without affecting Ca2+ ATPase activity or GTP-dependent Ca2+ uptake by heavy SR. The effect of the phosphatase was completely blocked by ruthenium red, a potent inhibitor of the channel. These results suggest that the channel is inactivated through an ATP-dependent process, presumably phosphorylation of proteins in the SR membrane. This was supported by the findings that the reactivation of the inactivated channel by added Ca2+ was markedly accelerated by the addition of acid phosphatase and that several proteins of heavy SR were phosphorylated during ATP-dependent Ca2+ uptake.     

The calcium-binding ATPase inhibitor protein from bovine heart mitochondria. Purification and properties

Two ATPase inhibitor proteins were isolated together from bovine heart mitochondria by a new procedure; each was purified further. The one inhibitor is a Ca2+-binding protein. It was found to contain 2 cysteine residues/mol as well as threonine and proline residues, all of which the other inhibitor (first isolated by Pullman and Monroy (Pullman, M.E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769] lacks. Its minimal molecular weight was 6390 with 62 amino acid residues/mol, and its isoelectric point was 4.6. Besides differences in size, composition, and response to Ca2+, the two inhibitor proteins also differed in response to sulfhydryl compounds, pH, KCl, and cardiolipin. Inhibition by the two inhibitor proteins was additive. Both cross-reacted with mitochondrial ATPase from rat skeletal muscle. Calmodulin, with or without Ca2+, had no effect on the activity of either inhibitor protein. Antibody to the Ca2+-binding inhibitor protein did not interact with the Pullman-Monroy inhibitor or have any effect on its activity. The antibody interacted with intact submitochondrial particles that contained both inhibitor proteins but not with particles from which only the Ca2+-binding inhibitor had been removed. Clearly, the two inhibitors are distinct immunologically as well as in other properties. The two types of inhibitor protein were also isolated from rat skeletal muscle mitochondria by the new procedure.     

Mg2+- or Ca2+-activated ATPase activities of plasma membranes isolated from vascular smooth muscle

Studies of ATP hydrolysis by various subcellular fractions isolated from rat mesenteric arteries and veins indicate that an apparent ATPase activity, which can be activated by Mg2+ or Ca2+, is primarily associated with the plasma membranes. Although both Mg2+-activated and Ca2+-activated ATPase activities under the optimal condition are substantially lower in venous than in arterial plasma membrane fraction, their dependence on the concentration of Mg2+ and Ca2+ are quite similar in arterial as well as venous plasma membrane fractions. No synergistic effect on ATP hydrolysis was observed in the presence of both Mg2+ and Ca2+. In addition, Mg2+-activated and Ca2+-activated ATPase activities show similar pH dependence, inhibition by deoxycholate, stability toward heat inactivation and substrate specificity. Furthermore, Mg2+-activated and Ca2+-activated ATPase activities were similarly reduced in vascular smooth muscles of spontaneously hypertensive rats. These results suggest that the activation of ATP hydrolysis by Mg2+ or Ca2+ may represent a single enzyme moiety in the plasma membrane of vascular smooth muscle. The possible involvement of such ATPase in the Ca2+ transport function of vascular smooth muscle is discussed.     

Properties and function of clostridial membrane ATPase.

ATPase (ATP phosphohydrolase, EC 3.6.1.3) was detected in the membrane fraction of the strict anaerobic bacterium, Clostridium pasteurianum. About 70% of the total activity was found in the particulate fraction. The enzyme was Mg2+ dependent; Co2+ and Mn2+ but not Ca2+ could replace Mg2+ to some extent; the activation by Mg2+ was slightly antagonized by Ca2+. Even in the presence of Mg2+, Na+ or K+ had no stimulatory effect. The ATPase reaction was effectively inhibited by one of its products, ADP, and only slightly by the other product, inorganic phosphate. Of the nucleoside triphosphates tested ATP was hydrolyzed with highest affinity ([S]0.5 v = 1.3 mM) and maximal activity (120 U/g). The ATPase activity could be nearly completely solubilized by treatment of the membranes with 2 M LiCl in the absence of Mg2+. Solubilization, however, led to instability of the enzyme. The clostridial solubilized and membrane-bound ATPase showed different properties similar to the "allotopic" properties of mitochondrial and other bacterial ATPases. The membrane-bound ATPase in contrast to the soluble ATPase was sensitive to the ATPase inhibitor dicyclohexylcarbodiimide (DCCD). DCCD, at 10(-4) M, led to 80% inhibition of the membrane-bound enzyme; oligomycin ouabain, or NaN3 had no effect. The membrane-bound ATPase could not be stimulated by trypsin pretreatment. Since none of the mono- or divalent cations had any truly stimulatory effect, and since a pH gradient (interior alkaline), which was sensitive to the ATPase inhibitor DCCD, was maintained during growth of C. pasteurianum, it was concluded that the function of the clostridial ATPase was the same as that of the rather similar mitochondrial enzyme, namely H+ translocation. A H+-translocating, ATP-consuming ATPase appears to be intrinsic equipment of all prolaryotic cells and as such to be phylogenetically very old; in the course of evolution the enzyme might have been developed to a H+-(re)translocating, ATP-forming ATPase as probably realized in aerobic bacteria, mitochondria and chloroplasts.