Effect of physico-chemical factors on anion-sensitive ATPase activity

Effects of temperature, pH and anions on the ATPase activity of submitochondrial particles of rat liver, rat heart, mouse liver, of red blood cell membranes, and of soluble enzyme of rat liver, mouse liver mitochondria were studied. The temperature relationships of membrane-bound and soluble ATPases have the breaks at 18-21 degrees C and 30-32 degrees C. These breaks were not shifted by sulfite, thiocyanate, methanol, glycerol and GTP. The pH changes from 6.0 to 8.5 produced no effect on the temperature relationships of ATPase activities but, strongly influenced the rate of ATPase reaction. The conformity between the obtained data and earlier proposed mechanism of anion control over anion-sensitive ATPase activity was discussed.     

The purified ATPase from chromaffin granule membranes is an anion-dependent proton pump

The proton-ATPase of chromaffin granules was purified so as to maintain its proton-pumping activity when reconstituted into phospholipid vesicles. The purification procedure involved solubilization with polyoxyethylene 9 lauryl ether, hydroxylapatite column, precipitation by ammonium sulfate, and glycerol gradient centrifugation. The protease inhibitor mixture used in previous studies inhibited the proton-pumping activity of the enzyme; therefore, the protein was stabilized by pepstatin A and leupeptin. The enzyme was purified at least 50-fold with respect to both ATPase and proton-pumping activity. The ATP-dependent proton uptake activity of the reconstituted enzyme was absolutely dependent on the presence of Cl- or Br- outside the vesicles, whereas sulfate, acetate, formate, nitrate, and thiocyanate were inhibitory. Sulfate inhibition seems to be due to competition with Cl- on the anion-binding site outside the vesicles, whereas nitrate and thiocyanate inhibited only from the internal side. As with the inhibition by N-ethylmaleimide, the proton-pumping activity was much more sensitive to nitrate than the ATPase activity. About 20 mM nitrate were sufficient for 90% inhibition of the proton-pumping activity while 100 mM inhibited only 50% of the ATPase activity both in situ and in the reconstituted enzyme. The possible regulatory effect of anions on the ATP-dependent proton uptake in secretory granules is discussed.     

Studies of soluble rat liver mitochondrial acid ATPases. I. Purification and catalytic properties of ATPase 1.

A method for isolation of a soluble ATPase from rat liver mitochondria after freeze thaw cycling is described. Two enzymatically active fractions were separated by DEAE-cellulose chromatography (ATPase 1 and ATPase 2). ATPase 1 has been purified 300 fold. ATPase 1 was homogenous as judged by polyacrylamide gel electrophoresis. The optimum pH of the enzyme was 5.8-6.0 and the optimum temperature was 45 degrees C. The enzyme follows Michaelis-Menten kinetics: Km (9 X 10(-4) M), Vmax (23,6 mumoles Pi released X min -1 X mg protein -1). The enzyme hydrolysed nucleoside triphosphates, but was inactive upon nucleoside di and monophosphates, glucose 6-phosphate, phosphoserine, pyrophosphate and glycerol 2-phosphate. In contrast to membrane bound ATPase, cations have no effect on the enzyme activity. Nucleoside di and mono phosphates and glycerol 2 phosphate inhibited competitively the enzyme. The enzyme was not affected by oligomycin, but was stimulated by lactate, 2-mercaptoethanol and dithiothreitol.     

Regulation of adenosine triphosphatase activity in mitochondria, chloroplasts and erythrocytes by anions, adenosine diphosphate and alcohols

The effects of sulfite, bicarbonate, thiocyanate, methanol, ethanol, glycerol, dimethy sulfoxide and ADP on the ATPase activity of the coupling factor from liver mitochondria (F1) and pea chloroplasts (CF1) and of the anion-sensitive ATPase from rat erythrocytes were investigated. Under steady-state conditions of ATP hydrolysis catalyzed by F1, CF1, and erythrocyte ATPase, three Km values for each of the enzymes, three activation constants for sulfite and three inhibition constants for thiocyanate were determined. The efficiency and direction of the effects of anions, alcohols and ADP strongly depend on temperature and substrate (Mg-ATP) concentration. The mechanisms of modification by anions and alcohols of the ATPase activities are discussed.     

Molecular polymorphism and mechanisms of activation and deactivation of the hydrolytic function of the coupling factor of oxidative phosphorylation.

The 13S coupling factor of oxidative phosphorylation from Alcaligenes faecalis has a latent adenosine triphosphatase (ATPase) function that can be activated by heating at 55 degrees C for 10 min at pH 8.5 in 50% glycerol. The specific activity increases from 0.1 to 20--30 mumol min-1 mg-1. Adenosine 5'-triphosphate (ATP) is not required for stabilization at 55 degreesC when glycerol is present. Activation involves displacement of the endogenous ATPase inhibitor subunit (epsilon subunit), and readdition of this subunit results in deactivation. In the deactivation process the ATPase inhibitor subunit can be replaced by other cationic proteins such as protamine, histones, or poly(lysine). Mg2+ and H+ also are effective deactivators. The fact that every positively charged substance tested deactivated the enzyme suggests that the inhibitor subunit is complexed with the enzyme at a site containing a surplus of negative charges. The activated enzyme is not labile, but it is salt labile, having a half-life of 2-3 min in 0.1 M KI at either 25 or 0 degrees C. The activated ATPase is also inhibited by aurovertin, 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole (NBD), and by the cross-linking agent dimethyl suberimidate. Evidence for polymorphism comes from finding that the properties of the unactivated enzyme (intrinsic ATPase) are different in many ways from the properties of activated ATPase. With respect to the coupling factor's ability to hydrolyze ATP, the data in this study suggest that there are at least four distinct functional allomorphs of this enzyme: (1) the latent enzyme, which has no kinetically measurable ATPase activity, (2) intrinsic ATPase, which is catalyzed by a small percentage of the molecular population that has been activated by some natural mechanism, (3) activated ATPase, which has properties different from those of intrinsic ATPase, and (4) aged activated ATPase, in which some of the properties (Km for substrate, sensitivity to deactivation by Mg2+ and H+) spontaneously change within 30 min.     

Proteins of bacterial membranes. Purification of soluble ATPase from Acholeplasma laidlawii

A purified preparation of ATPase (factor F1) from the Acholeplasma laidlawii was obtained. The purification procedure included extraction of the enzyme complex from the isolated membranes by ultrasonication, chromatography on DEAE-cellulose and gel filtration on Sepharose 6B. The specific activity of the ATPase was increased 30-fold as compared to the original activity. The Km value for ATP hydrolysis was 7,4 . 10(-4) M. ADP competitively inhibited the enzyme (Ki = 2,0 . 10(-4) M). Ouabain (2,5 . 10(-4) M) and dicyclohexylcarbodiimide (1,0 . 10(-4) M) did not inhibit the ATPase activity. The enzyme was activated by Mg2+, but was inhibited by a combination of Na+ and K+. The enzyme is cold-labile, but can be stabilized by storage in buffer solutions, containing methanol, glycerol or lecithin.     

Some properties of isolated mitochondrial ATPase from salmon heart

A soluble Mg-dependent ATPase, similar to the mitochondrial ATPase from beef heart, has been isolated from heart mitochondria of salmon (Salmo salar). The salmon heart ATPase has 5 subunits with molecular weights similar to the beef heart enzyme, but the Stoke's radius of the intact salmon enzyme is larger. The salmon heart ATPase is less temperature labile than the beef heart enzyme. The salmon heart ATPase is strongly inhibited by ADP, and the inhibition is highly temperature dependent. The ITPase activity is also inhibited by IDP (Ki = 180 micron). 2,4-Dinitrophenol in small concentrations stimulates the ITPase activity as well as the ATPase activity of the "washed" salmon heart enzyme. However, in an enzyme preparation which had been freed of most of the bound nucleotides by dialysis in the presence of glycerol (Roveri et al., 1980) the ITPase activity is not stimulated by 2,4-dinitrophenol.     

Effects of Organic Solvents on the Coupling Between ATP Hydrolysis and Sliding of Microtubules in Axonemes from Chlamydomonas Flagella

ABSTRACT. The effects of organic solvents on the ATPase activity and the sliding disintegration of axonemes from Chlamydomonas were investigated. The axonemal ATPase was markedly activated by methanol accompanying with marked inhibition of the sliding disintegration of axonemes. On the contrary, glycerol inhibited the ATPase activity without serious inhibition of the sliding disintegration. As far as the axonemes are not irreversibly denatured by extremely high concentration of solvents, the effects of solvents both on the ATPase and the ability of sliding are reversible. Therefore, the inhibition of sliding accompanied by the activation of ATPase is probably due to an inability to couple the hydrolysis of ATP to sliding between dynein and microtubule in the presence of methanol. The axonemal ATPase was less sensitive to vanadate inhibition after exposure to methanol. This indicates that methanol makes the dyneinADP.Pi complex unstable and increases product release. On the other hand, glycerol and ethylene glycol seem to stabilize the force generation responsible for the sliding through stabilizing the dynein.ADP.Pi complex.     

Purification and properties of the adenosine triphosphatase released from the liver mitochondrial membrane by chloroform

1. Soluble ATPase (adenosine triphosphatase) activity is released when rat liver submitochondrial particles are shaken with chloroform, provided that ATP or glycerol is present in the suspending medium. The extraction is very rapid and appears to be complete. 2. The ATPase of the chloroform extract is about 50% pure and can be readily purified to a specific activity of 60-70mumol/min per mg of protein by (NH(4))(2)SO(4) fractionation and column chromatography on Sephadex G-200. 3. The particulate and soluble ATPases have many similar properties, including their K(m) values for ATP, activation by various metal ions, hydrolytic activity with other nucleotides and stimulation by bicarbonate ions. 4. Unlike the particulate enzyme, the soluble enzyme is cold-labile and insensitive to oligomycin. 5. The molecular weight indicated by the mobility of the soluble ATPase on Sepharose 6B is 360000. 6. The soluble ATPase combines very readily with liver submitochondrial particles depleted of ATPase by salt extraction, and oligomycin-sensitivity is restored. Very little recombination of the enzyme occurs with chloroform-extracted particles. 7. The soluble enzyme contains orcinol-reactive material, suggesting that it may be a glycoprotein. The carbohydrate content was estimated to be 1-2% by weight. 8. It is concluded that the liver ATPase obtained by the chloroform extraction method of Beechey, Hubbard, Linnett, Mitchell & Munn [(1975) Biochem. J.148, 533-537] is similar to other preparations described previously and that this method is superior in simplicity and speed.     

The isolation of plasma membrane and characterisation of the plasma membrane ATPase from the yeast Candida albicans

Plasma membrane ghosts were isolated from Candida albicans ATCC 10261 yeast cells following stabilisation of spheroplasts with concanavalin A, osmotic lysis and Percoll density gradient centrifugation. Removal of extrinsic proteins with NaCl and methyl alpha-mannoside gave increased ATPase and chitin synthase specific activities in the resultant plasma membrane fraction. Sonication of this fraction yielded unilamellar plasma membrane vesicles which exhibited ATPase and chitin synthase specific activities of 4.5-fold and 3.0-fold, respectively, over those of the plasma membrane ghosts. ATPase activity in the membrane ghosts was optimal at pH 6.4, showed high substrate specificity (for Mg X ATP) and was inhibited 80% by sodium vanadate but less than 4% by oligomycin and azide. The effects of a range of other inhibitors were also characterised. Temperature effects of ATPase activity were marked, with a maximum at 35 degrees C. Breaks in the Arrhenius plot, at 12.2 degrees C and 28.9 degrees C, coincided with endothermic heat flow peaks detected by differential scanning calorimetry. ATPase was solubilised from the plasma membranes with Zwittergent in the presence of glycerol and phenylmethylsulphonyl fluoride and partially purified by glycerol density gradient centrifugation. The solubilised enzyme hydrolysed Mg X ATP at Vmax = 20 mumol X min-1 X mg-1 in the presence of phospholipids, with optimal activity at pH 6.0--6.5.     

Glutaraldehyde crosslinking analysis of the C12E8 solubilized H,K-ATPase

A soluble porcine H,K-ATPase preparation was obtained with the nonionic detergent, C12E8. ATP hydrolysis by the soluble H,K-ATPase was stimulated with respect to the native preparation at pH 6.1, while the K(+)-phosphatase activity was comparable to the native enzyme. The soluble enzyme demonstrated characteristic ligand-dependent effects on ATP hydrolysis, including ATP activation of K(+)-stimulated hydrolysis with a K0.5 of 28 +/- 4 microM ATP, and inhibition with an IC50 of 2.1 mM ATP. The activation and inhibition of ATP hydrolysis by K+ was also observed with a K0.5 for activation of 2.8 +/- 0.4 mM KCl at 2.0 mM ATP (pH 6.1) and inhibition with an IC50 of 135 mM KCl at 0.05 mM ATP. 2-Methyl-8-(phenylmethoxy)imidazo[1,2a]pyridine-3-acetonitrile (SCH 28080), a specific inhibitor of the native H,K-ATPase, competitively inhibited the K(+)-stimulated activity with a Ki of 0.035 microM. The soluble enzyme was stable with a t0.5 for ATPase activity of 6 h between 4 and 11 degrees C. The demonstration of these related ligand responses in the catalytic reactions of the soluble preparation indicates that it is an appropriate medium for investigation of the subunit associations of the functional H,K-ATPase. Subunit associations of the active soluble enzyme were assessed following treatment with the crosslinking reagent, glutaraldehyde. The distribution of crosslinked particles was independent of the soluble protein concentration in the crosslinking buffer within the protein range 0.3 to 2.0 mg/ml or the detergent to protein ratio varied from 1 to 15 (w/w). The crosslinked pattern was unaffected by the presence or absence of K during crosslinking or nucleotide concentration. These observations suggest that crosslinking occurs in associated subunits that do not undergo rapid associations dependent upon enzyme turnover. Phosphorylation of the soluble enzyme with 0.1 mM MgATP produced a phosphoprotein at 94 kDa. A phosphoprotein obtained after glutaraldehyde treatment exhibited identical electrophoretic mobility to the crosslinked particle identified by silver stain. Glutaraldehyde treatment of soluble protein fractions resolved on a linear 10-35% glycerol gradient revealed several smaller peptides partially resolved from the crosslinked pump particle, but no active fraction enriched in the monomeric H,K-ATPase. This data indicates that the functional porcine gastric H,K-ATPase is organized as a structural dimer.     

Involvement of the Plasma Membrane ATPase in the Osmoregulatory Mechanism of the Alga Dunaliella salina

The unicellular halotolerant alga Dunaliella salina recovers normally from a hypertonic shock even when suspended in NaCl and buffer only. Furthermore, addition of Cu²⁺, valinomycin and KCl, or permeable ions such as methyltriphenylphosphonium or thiocyanate, do not affect the recovery. However, treatment with two specific inhibitors of the plasma membrane adenosine triphosphatase (ATPase), diethylstilbestrol, or vanadate, fully inhibit the recovery. The inhibition is manifested by the inability of the cells to both synthesize glycerol and return to their original volume. The inhibitions are nonlethal, reversible and equally effective in the dark or the light. Since the plasma membrane ATPase is the only enzyme known to be inhibited by both diethylstilbestrol and vanadate, it is concluded that its activity is essential for the recovery of Dunaliella from a hypertonic shock. Mechanisms by which the plasma membrane ATPase may participate in the activation of glycerol production in the algae are discussed.     

Solubilization and some properties of the Mg2+-activated adenosine triphosphatase from Trypanosoma cruzi.

1. Grinding of epimastigotes of Trypanosoma cruzi with glass powder in a mortar yielded a Mg2+-activated adenosine triphosphatase (ATPase) preparation which was highly sensitive to oligomycin. 2. Chloroform treatment of the particles resulted in the solubilization of an ATPase which was (a) activated by MgCl2; (b) slightly inhibited by CaCl2; (c) activated by sulphite and bisulphite; (d) had an optimum pH of 7.6; and (e) had a Km for ATP of 2.1 mM (in the presence of 4 mM MgCl2). 3. The solubilized enzyme was insensitive to oligomycin and leucinostatin, which inhibited the membrane-bound ATPase, though inhibited by efrapeptin and quercetin. 4. The results indicate that the chloroform-extracted enzyme is a soluble F1-ATPase similar to those isolated from mammalian mitochondria.     

Calcium-dependent adenosine triphosphatase activity preservation in isolated sarcoplasmic reticulum.

ATPase activity in sarcoplasmic reticulum vesicles was measured before and after storage for several weeks and under a variety of conditions. Rapid freezing and storage at-80 degrees C provided optimum protection of enzyme activity. Sarcoplasmic reticulum preparations stored at 0 degrees C or frozen slowly and stored at-20 degrees C were not stable. At 0 degrees C sucrose, glycerol, and dithiothreitol had a stabilizing effect while NaCl, dimethylsulfoxide, and antioxidants afforded little or no protection.     

Effect of anions on the ATPase activity of submitochondrial particles

The effects of anions on the ATPase activity of submitochondrial particles from mouse liver cells were investigated. Thiocyanite decreased the ATP hydrolysis, acting as a competitive inhibitor with respect to sulfite. All the anions tested changed the ATPase activity noncompetitively towards Mg-ATP. The hydrolysis of CTP, GTP, ITP and UTP was insensitive to sulfite and thiocyanate. In the presence of Mn2+, Ca2+, Co2+, Zn2+ and Ba2+ an anion-dependent hydrolysis of ATP took place. It was assumed that the anions control the rate of the limiting step of the ATPase reaction, since sulfite and thiocyanate change the activation energy of ATP hydrolysis. The data obtained are discussed in terms of a previously proposed mechanism of the anions effect on the activity of mitochondrial ATPase.     

The identification and subcellular localization of thrombosthenin "M", the myosin-like component of pig platelets.

A protein has been studied which spontaneously precipitates from stored fractions of platelet soluble phase prepared by density gradient centrifugation. It is rich in a Ca2+ ATPase activity which displays an activity/pH profile resembling that of skeletal muscle myosin. Adjustment of freshly prepared soluble phase fractions to 0.6 M with respect to KCl and dilution 1 in 3 results in the precipitations of a protein fraction with essentially the same enzymatic properties as the spontaneously precipitable protein. These two similar proteins represent between 9 and 13% of the soluble phase total protein and each account for almost the whole of divalent cation activated ATPase activity of the soluble phases from which they were derived. The Mg2+ ATPase activity is only about twice purified with respect to the soluble phase enzyme activity, but the Ca2+ ATPase shows a 10-13-fold enrichment. Synthetic actomyosins can be prepared from the two proteins by addition of either platelet or skeletal muscle actin. These show significant increases in Mg2+ ATPase at the most favourable combination ratios. The ratio between the yield of soluble phase protein obtained by dilution precipitation and the lactate dehydrogenase activity of the soluble phase remains constant under a wide range of homogenization and sonication conditions applied to the original whole platelet suspensions. This confirms our earlier view that the soluble phase is a valid intracellular compartment for a considerable proportion of the platelet contractile protein and that in the complex the myosin-like component predominates.     

Reactivation of lipid-depleted Ca2+-ATPase by a nonionic detergent.

The Ca2+-ATPase of sarcoplasmic reticulum can be reversibly delipidated by precipitation with polyethyleneglycol in the presence of deoxycholate and glycerol to as low as 4 mol of phospholipid/mol of enzyme polypeptide and can then be reactivated to 90% of its original ATPase activity by the addition of phosphatidylcholine. Furthermore, the preparation exhibits nearly the same activity if the nonionic detergent dodecyl octaoxyethyleneglycol monoether is substituted for the added phospholipid. The delipidated ATPase is soluble in the detergent and retains activity for several days. This is the first report of the Ca2+-ATPase retaining high activity with less than about 30 mol of phospholipid bound per mol of polypeptide.     

Large-scale isolation of the Neurospora plasma membrane H+-ATPase

A method for the purification of relatively large quantities of the Neurospora crassa plasma membrane proton translocating ATPase is described. Cells of the cell wall-less sl strain of Neurospora grown under O2 to increase cell yields are treated with concanavalin A to stabilize the plasma membrane and homogenized in deoxycholate, and the resulting lysate is centrifuged at 13,500g. The pellet obtained consists almost solely of concanavalin A-stabilized plasma membrane sheets greatly enriched in the H+-ATPase. After removal of the bulk of the concanavalin A by treatment of the sheets with alpha-methylmannoside, the membranes are treated with lysolecithin, which preferentially extracts the H+-ATPase. Purification of the lysolecithin-solubilized ATPase by glycerol density gradient sedimentation yields approximately 50 mg of enzyme that is 91% free of other proteins as judged by quantitative densitometry of Coomassie blue-stained gels. The specific activity of the enzyme at this stage is about 33 mumol of P1 released/min/mg of protein at 30 degrees C. A second glycerol density gradient sedimentation step yields ATPase that is about 97% pure with a specific activity of about 35. For chemical studies or other investigations that do not require catalytically active ATPase, virtually pure enzyme can be prepared by exclusion chromatography of the sodium dodecyl sulfate-disaggregated, gradient-purified ATPase on Sephacryl S-300.     

Arginine 328 of the beta-subunit of the mitochondrial ATPase in yeast is essential for protein stability

The mitochondrial ATPase is rapidly inactivated by the arginine selective reagent phenylglyoxal. Recently, the purported major reacting residue has been reported for the chloroplast enzyme (Viale, A. M., and Vallejos, R. H. (1985) J. Biol. Chem. 260, 4958-4962) corresponding to Arg-328 in the beta-subunit of the yeast Saccharomyces cerevisiae mitochondrial ATPase, a highly conserved residue in the ATPase. This arginine residue was concluded to be in the active site of the ATPase and possibly involved in the binding of nucleotides. To test this hypothesis, site-directed mutagenesis of the yeast enzyme has been used to replace Arg-328 with alanine and lysine. The modified genes were transformed into a yeast strain, DMY111, which contained a null mutation in the gene coding for the beta-subunit of the ATPase. Both of the substitutions were functional in vivo as demonstrated by the ability of yeast transformants to grow on a nonfermentable carbon source. The water soluble F1-ATPase with Ala-328 and Lys-328 were extremely unstable, but could be stabilized with glycerol. The rate of enzymatic decay followed first order kinetics with half-lives of 1.1 and 4.0 min for the mutants with Ala-328 and Lys-328 in 10% and 5% glycerol, respectively, while the wild type enzyme was stable even in the absence of glycerol. Kinetic analysis of both ATPase and GTPase has been determined. The wild type enzyme had two observable apparent Km and Vmax values for ATPase which were 0.056 mM-1 and 67 units/min/mg and 0.140 mM-1 and 100 units/min/mg. The mutant enzyme containing Lys-328 showed similar kinetic values of 0.066 mM-1 and 23 units/min/mg and 0.300 mM-1 and 43 units/min/mg. The mutant enzyme containing Ala-328, however, only demonstrated a single site with values of 0.121 mM-1 and 45 units/min/mg. In contrast to ATPase activity, kinetic values for GTPase were nearly identical for the wild type and mutant enzymes. Opposite to predicted results, the mutant enzymes were more sensitive to the reagent phenylglyoxal. These results indicate that Arg-328 is important for protein stability, but not involved in catalysis.     

Membrane ATPase of Escherichia coli K 12 Selective solubilization of the enzyme and its stimulation by trypsin in the soluble and membrane-bound states

ATPase (EC 3.6.1.3) of Escherichia coli has been solubilized from two morphologically distinct membranes (vesicles and “ghosts”). Maximum ATPase release is attained with 3 mM EDTA in NH₄HCO₃, pH 9.0, and depends on protein concentration. After solubilization, the total enzyme activity is increased by 300% with respect to the membrane-bound enzyme. The released soluble ATPase accounts for more than 90% of this activity. Its specific activity is at least 10 times higher than the original value. Membrane treatment with buffers of various ionic strengths without EDTA and detergents is less selective. The molecular sieving properties (gel electrophoresis and Sephadex G-200 filtration) confirm the soluble nature of the preparation. A molecular weight close to 300 000 has been estimated for it.The membrane-bound ATPase is stimulated by trypsin by 70–100%. Most of the soluble ATPase maintains a trypsin activation of the same order. Exceptions are the preparations obtained at high protein dilution and extracted with sodium dodecyl sulphate and deoxycholate. The soluble ATPase is more labile than the membrane-bound enzyme. Its sensitivity to different temperatures depends upon protein concentration and pH during storage. Inactivation seems to result from dissociation and/or proteolysis.We suggest an ATPase link to the membrane through ionic divalent cation bridges. We also suggest that the enzyme possesses self-regulatory properties which would account for trypsin stimulation.