The soluble adenosine triphosphatase of Thiobacillus ferrooxidans.

Adenosine triphosphatase (ATPase) from Thiobacillus ferrooxidans was purified 55-fold. Polyacrylamide gel electrophoresis of the most purified fraction showed only one major band; histochemical analysis showed that the ATPase activity was associated with this band. The pH optimum is 9-10. The enzyme hydrolyzed ATP stoichiometrically to ADP and inorganic phosphate, the Km for this substrate being 7.75 times 10-3 M. GTP and ITP are alternate substrates, the Km values for these being 6.71 times 10-3 M and 3.12 times 10-3 M, respectively. ADP is slightly hydrolyzed. Magnesium, manganese, and calcium can serve as cofactors; Km values for these are 2.0 times 10-3 M, 9.4 times 10-4 M, and 8.0 times 10-4 M, respectively. The enzyme activity was not activated by either sodium or potassium, but a combination of the two ions were inhibitory. Azide and p-hydroxymercuribenzoate strongly inhibited the enzyme activity, whereas cyanide, dinitrophenol, and N,N'-dicyclohexylcarbodiimide (DCCD) were without effect. The enzyme was cold labile at 0 degrees-C, but was more stable at 18-24 degrees-C.     

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.     

Inhibitor studies with adenohypophyseal granule membrane ATPase. Evidence for a membrane environment which modulates sensitivity to inhibitors

The limiting membranes of pituitary growth hormone and prolactin secretory granules contain a Mg2+-ATPase sensitive to anions. This enzyme is in many ways similar to mitochondrial ATPase. The enzyme was potently inhibited by oligomycin (Ki 6.5 X 10(-9) M), and was much more sensitive to the inhibitor than pituitary mitochondrial ATPase (Ki 2.7 X 10(-7) M). In contrast, the enzyme activity of intact secretory granules was only sparingly inhibited by oligomycin (maximal inhibition close to 30% at 5 X 10(-4) M). However, oligomycin (5 microM) did diminish to basal levels the enhanced granule ATPase activity observed in the presence of a stimulatory anion (25 mM sodium sulfite). Other compounds known to inhibit the proton translocating mitochondrial ATPase were also tested for their ability to inhibit the secretory granule ATPase. A similar pattern of limited inhibition in granules and greater sensitivity in isolated membranes was seen with the inhibitors N,N-dicyclohexylcarbodiimide and efrapeptin. In contrast, tri-n-butyltin chloride was a potent inhibitor of the ATPase of intact granules, and the susceptibility of the enzyme to inhibition by this compound was less after isolation of membranes. These observations suggest that pituitary secretory granule membrane ATPase may have a proton pumping function similar to that of the mitochondrial enzyme. In addition, the data imply that the inhibitor binding site(s) may be masked, inaccessible, or ineffective in intact granules, but exposed (or activated) in isolated membranes. The greater sensitivity of granule ATPase to tri-n-butyltin chloride, in contrast to the greater sensitivity of membrane ATPase to the other inhibitors, indicates that the tin compound may be effective at a membrane site(s) distinct from the others, or that the mechanism of inhibition is different.     

The alpha-2 isomer of the sodium pump is inhibited by calcium at physiological levels

The inhibition of the (Na,K)ATPase by calcium was investigated in plasma membrane preparations of rat axolemma, skeletal muscle and kidney outer medulla. Ouabain titration curves demonstrated that physiological calcium (0.08-5 microM) inhibited mainly the high affinity alpha 2 isomer. In axolemma all the (Na,K)ATPase had high ouabain affinity and calcium inhibited 40-50% of the activity with a Ki of 1.9 +/- 0.9 x 10(-7) M. In skeletal muscle high and low ouabain affinity components were present in equal amounts and calcium inhibited only the high affinity component with a Ki of 1.3 +/- 0.3 x 10(-7) M. Kidney enzyme had a low affinity for ouabain and showed very little sensitivity to calcium in the physiological range. It was demonstrated that high calcium levels inhibit the enzyme in a general sense, irrespective of the isomer, with a Ki of 6.5 +/- 6 x 10(-4) M for the kidney and 5.9 +/- 4 x 10(-4) M for the axolemma enzymes. In axolemma, enzyme activity was studied as a function of sodium concentration. Physiological calcium reduced Vmax while not significantly changing K 0.5 for sodium binding.     

Simultaneous bindings of ATPase inhibitor and 9K protein to F1F0-ATPase in the presence of 15K protein in yeast mitochondria

Yeast mitochondrial ATP synthase has three regulatory proteins, ATPase inhibitor, 9K protein, and 15K protein. The 9K protein binds directly to purified F1-ATPase, as does the ATPase inhibitor, but the 15K protein does not [Hashimoto, T. et al. (1987) J. Biochem. 102, 685-692]. In the present study, we found that 15K protein bound to purified F1F0-ATPase, forming an equimolar complex with the enzyme. The apparent dissociation constant was calculated to be 1.4 x 10(-5) M. The ATPase inhibitor and 9K protein also bound to F1F0-ATPase in the presence of ATP and Mg2+, and the dissociation constants of their bindings were about 3 X 10(-6) M. They bound to the enzyme competitively in the absence of 15K protein, but in its presence, they bound in equimolar amounts to the enzyme. The ATP-hydrolyzing activity of the enzyme-ligand complex was greatly influenced by the order of bindings of ATPase inhibitor and 9K protein: when the ATPase inhibitor was bound first, the activity of the enzyme was inhibited completely and was not restored by 9K protein, but when 9K protein was added first, the activity was inhibited only partially even after equimolar binding of the ATPase inhibitor to the enzyme. These observations strongly suggest that the 15K protein binds to the F0 part and functions to hold the ATPase inhibitor or 9K protein on the F1 subunit.     

Energy-transducing membrane-bound coupling factor-ATPase from Mycobacterium phlei. I. Purification, homogeneity, and properties.

The membrane-bound coupling factor from Mycobacterium phlei was solubilized from membrane vesicles by washing with low ionic strength buffer or 0.25 M sucrose. The solubilized enzyme exhibited coupling factor, latent ATPase, and succinate oxidation-stimulating activity. Purification by affinity chromatography using Sepharose coupled to ADP yielded a homogeneous preparation of latent ATPase which was purified about 200-fold with an 84% yield in a single step. Purified latent ATPase exhibited coupling factor activity but no succinate oxidation-stimulating activity. The molecular weight of latent ATPase was determined to be 250,000 +/- 10,000 by Sephadex G-200 chromatography. The ATPase was unmasked by trypsin treatment and activated by Mg2+ ion. However, trypsin treatment inactivated the coupling factor activity in the purified enzyme, indicating that the catalytic sites for ATPase and coupling activity are different. Unlike mitochondrial ATPase, latent ATPase from M. phlei was not cold-labile. Of the nucleoside triphosphates, UTP, ITP, and epsilon-ATP (1-N6-ethenoadenosine triphosphate) were hydrolyzed to a lesser extent compared to ATP. Kinetic data showed that ADP acted as a competitive inhibitor of latent ATPase activity with a Ki of 5 x 10(-3) M. Uncouplers of oxidative phosphorylation and respiratory inhibitors did not affect the latent ATPase activity, while sodium azide (0.1 mM) inhibited the latent ATPase activity.     

The role of SH-groups in the development sensitivity of ATPase in plasma membranes of plant cells to ions

The effects of the SH-groups binding agent p-chloromercurybenzoate (rho CMB) and the SH-containing compounds dithiothreitol (DTT), beta-mercaptoethanol (ME) and reduced glutathione (GSH) on activation by Mg2+ and K+ of ATPase in plasma membrane preparations from corn sprout root cells were studied. Rho CMB inhibited the ATPase activity, the degree of inhibition being directly dependent on the increase of the inhibitor concentration (from 10(-6) up to 10(-4) M); the inhibition was eliminated by the SH-containing agents (25 mM). DTT and ME added to the homogenization medium and ME added to the reaction mixture produced different effects on the ATPase activity of the membranes depending on the nature of the cations added. In the absence of the additives the ATPase activity was somewhat decreased, showing a sharp rise in the presence of Mg2+; an addition of K+ to a Mg2+-containing medium further increased the enzyme activity. GSH had no effect on the ATPase activation by the cations.     

Purification and characterization of a membrane-associated ATPase from Natronococcus occultus, a haloalkaliphilic archaeon

Isolated membranes of the extreme haloalkaliphilic archaeon Natronococcus occultus were able to hydrolyze ATP via an ATPase, which required the presence of Mg(2+), high concentrations of NaCl, and a pH value of 9. The native molecular mass of the purified ATPase was 130 kDa and was composed of 74- and 61-kDa subunits. Enzyme activity was specific for the hydrolysis of ATP with slight activity towards GTP, CTP, and ITP. The enzyme required NaCl for maximal activity but Na(2)SO(4) and (NH(4))(2)SO(4) could substitute. The enzyme showed no activity if Na(2)SO(3) or sodium citrate was substituted for NaCl. The ATPase from N. occultus was inhibited by NBD-Cl, NaN(3), and ouabain, and was sensitive to nitrate, vanadate, DCCD, and bafilomycin A(1). It was not inhibited by NEM in contrast to other previously characterized halophile ATPases. The ATPase had a K(M) of 0.5 mM and appeared to be non-competitively inhibited by NaN(3) with a K(I) of 3.1 mM.     

Reversible binding of Pi by beef heart mitochondrial adenosine triphosphatase.

Beef heart mitochondrial ATPase (F1) exhibited a single binding site for Pi. The interaction with Pi was reversible, partially dependent on the presence of divalent metal ions, and characterized by a dissociation constant at pH 7.5 of 80 micronM. A variety of substances known to influence oxidative phosphorylation or the activity of the soluble ATPase (F1) also influenced Pi binding by the enzyme. Thus aurovertin, an inhibitor of oxidative phosphorylation, which was bound tightly by F1 and inhibited ATPase activity, enhanced Pi binding via a 4-fold increase in the affinity of the enzyme for Pi (KD = 20 micronM) but did not alter binding stoichiometry. Anions such as SO4(2-), SO3(2-), chromate, and 2,4-dinitrophenolate, which stimulated ATPase activity of F1, also enhanced Pi binding. Inhibitors of ATPase activity such as nickel/bathophenanthroline and the protein ATPase inhibitor of Pullman and Monroy (Pullman, M. E., and Monroy, G. C. (1963) J. Biol. Chem. 238, 3762-3769) inhibited Pi binding. The adenine nucleotides ADP, ATP, and the ATP analog adenylyl imidodiphosphate as well as the Pi analog arsenate, also inhibited Pi binding. The observations suggest that the Pi binding site was located in or near an adenine nucleotide binding site on the molecule.     

Characterization of human erythrocyte cytoskeletal ATPase

Human erythrocyte cytoskeletal ATPase was extracted with 0.2 mM ATP (pH 8.0) from Triton X-100 treated ghosts. The ATPase fraction contained mainly spectrin, actin, and band 4.1. When the ATPase fraction was applied to a Sepharose 4B column, 90% of the ATPase activity was recovered in a spectrin, actin, and band 4.1 complex fraction and none was detected in the spectrin fraction. A specific activity of the complex ATPase was 60-120 nmol/(mg protein X h). No ATPase activity was detected in the presence of EDTA. The presence of magnesium in the incubation medium was essential for the ATPase activity. The activity was activated by KCl and was almost completely inhibited by 10(-5) M free calcium in the presence of 0.2 mM MgCl2. The Ki for Ca2+ was 7 X 10(-7) M. Phalloidin and DNase 1, which affect actin, inhibited this K,Mg-ATPase activity by 95%, but cytochalasin B did not inhibit it. N-Ethylmaleimide activated the ATPase 1.6-fold. The order of affinity for nucleotides was ATP greater than ITP greater than CTP, ADP, AMP-PNP, GTP. A specific ATPase activity of purified actin was 50 nmol/(mg X h). These results suggest that the cytoskeletal ATPase is actin ATPase and the actin ATPase is activated by spectrin and band 4.1.     

Affinity chromatography of H+-translocating adenosine triphosphatase isolated by chloroform extraction of Rhodospirillum rubrum chromatophores. Modification of binding affinity by divalent cations and activating anions.

1. ATPase isolated from Rhodospirillum rubrum by chloroform extraction and purified by gel filtration or affinity chromatography shows three bands (alpha, beta and gamma) upon electrophoresis in sodium dodecyl sulphate. 2. Ca2+-ATPase activity of the preparation is inhibited by aurovertin and efrapeptin but not by oligomycin. Activity may be inhibited by treatment with 4-chloro-7-nitrobenzofurazan and subsequently restored by dithiothreitol. 3. The enzyme fails to reconstitute photophosphorylation in chromatophores depleted of ATPase by sonic irradiation. 4. Most of the active protein from the crude chloroform extract binds to an affinity chromatography column bearing an immobilised ADP analogue but not to a column bearing immobilised pyrophosphate. 5. In the absence of divalent cations, a component with a very high specific activity for Ca2+-ATPase is eluted from the column by 1.6 mM ATP. This protein migrates asa single band on 5% polyacrylamide gel electrophoresis and only possesses three subunits. At 12 mM ATP an inactive protein is eluted which does not run on acid or alkali polyacrylamide gels and shows a complex subunit structure. 6. ATPase preparations prepared by acetone extraction or by sonic irradiation of chromatophores may also be purified 10-fold by affinity chromatography. 7. The inclusion of 5 mM MgCl2 or CaCl2 during affinity chromatography of chloroform ATPase increases the capacity of the column for the enzyme and demands a higher eluting concentration of ATP. 8. When the enzyme is more than 90% inhibited by efrapeptin or 4-chloro-7-nitrobenzofurazan, the binding characteristics of the enzyme are not affected. 9. 10 mM Na2SO3, which greatly stimulates the Ca2+- and Mg2+-dependent ATPase activity of the enzyme and increases Ki (ADP) for Ca2+-ATPase from 50 to 850 micron, prevents binding to the affinity column. Binding may be restored by the addition of divalent cations. 10. Na2SO3 increases the rate of ATP hydrolysis, ATP-driven H+ translocation and ATP-driven transhydrogenase in chromatophores. 11. It is proposed that anions such as sulphite convert the chromatophore ATPase into a form which is a more efficient energy transducer.     

K-252a, a novel microbial product, inhibits smooth muscle myosin light chain kinase

Effects of K-252a, (8R*, 9S*, 11S*)-(-)-9-hydroxy-9-methoxycarbonyl-8-methyl-2,3,9,10-tetrahydro-8, 11-epoxy-1H,8H,11H-2,7b,11a-triazadibenzo[a,g]cycloocta [cde]trinden-1-one, purified from the culture broth of Nocardiopsis sp., on the activity of myosin light chain kinase were investigated. 1) K-252a (1 x 10(-5) M) affected three characteristic properties of chicken gizzard myosin-B, natural actomyosin, to a similar degree: the Ca2+-dependent activity of ATPase, superprecipitation, and the phosphorylation of the myosin light chain. 2) K-252a inhibited the activities of the purified myosin light chain kinase and a Ca2+-independent form of the enzyme which was constructed by cross-linking of myosin light chain kinase and calmodulin using glutaraldehyde. The degrees of inhibition by 3 x 10(-6) M K-252a were 69 and 48% of the control activities with the purified enzyme and the cross-linked complex, respectively. Chlorpromazine (3 x 10(-4) M), a calmodulin antagonist, inhibited the native enzyme, but not the cross-linked one. These results suggested that K-252a inhibited myosin light chain kinase by direct interaction with the enzyme, whereas chlorpromazine suppressed the enzyme activation by interacting with calmodulin. 3) The inhibition by K-252a of the cross-linked kinase was affected by the concentration of ATP, a phosphate donor. The concentration causing 50% inhibition was two orders magnitude lower in the presence of 100 microM ATP than in the presence of 2 mM ATP. 4) Kinetic analyses using [gama-32P]ATP indicated that the inhibitory mode of K-252a was competitive with respect to ATP (Ki = 20 nM). These results suggest that K-252a interacts at the ATP-binding domain of myosin light chain kinase. The direct action of the compound on the enzyme would explain the multivarious inhibition of myosin ATPase, of superprecipitation, and of the contractile response of smooth muscle.     

Dicyclohexylcarbodiimide-sensitive ATPase in Halobacterium saccharovorum

Membranes from Halobacterium saccharovorum contained a cryptic ATPase which required Mg2+ or Mn2+ and was activated by Triton X-100. The optimal pH for ATP hydrolysis was 9-10. ATP or GTP were hydrolyzed at the same rate while ITP, CTP, and UTP were hydrolyzed at about half that rate. The products of ATP hydrolysis were ADP and phosphate. The ATPase required high concentrations (3.5 M) of NaCl for maximum activity. ADP was a competitive inhibitor of the activity, with an apparent Ki of 50 microM. Dicyclohexylcarbodiimide (DCCD) inhibited ATP hydrolysis. The inhibition was marginal at the optimum pH of the enzyme. When the ATPase was preincubated with DCCD at varying pH values, but assayed at the optimal pH for activity, DCCD inhibition was observed to increase with increasing acidity of the preincubation medium. DCCD inhibition was also dependent on time of preincubation, and protein and DCCD concentrations. When preincubated at pH 6.0 for 4 h at a protein:DCCD ratio of 40 (w/w), ATPase activity was inhibited 90%.     

Changes in surface ATPase of rat spermatozoa in transit from the caput to the cauda epididymidis.

Rat spermatozoa from the cauda epididymidis were found to have a lower activity of the surface ATPase than the spermatozoa from the caput region. The enzyme from spermatozoa of both regions had the same Michaelis constant (Km) for ATP of 5 X 10(-4) M. It was partly inhibited by ouabain and fluoride, but strongly inhibited by Cu2+, Zn2+,p-chloromercuribenzoate, 8-anilino-1-naphthalenesulphonate Triton X-100, Lubrol-PX, urea, guanidine hydrochloride, sodium dodecyl sulphate and glycerylphosphorylcholine. The enzyme of the spermatozoa from the cauda epididymidis was more sensitive to inhibition by ouabain and fluoride but less sensitive to inhibition by Cu2+ than that of the cells form the caput region. The Arrhenius plot of the temperature dependence of enzymatic activity varied for the cells from the caput and cauda epididymidis. The differences in the enzyme properties of spermatozoa from the two regions of the epididymis suggested that the decline in the activity during epididymal maturation may reflect changes in the lipids and sulphydryl groups of the sperm membrane.     

The effect of cationic surface-active agents on the Escherichia coli ATPase

The authors studied the effect of cationic surfactants (CS), such as alkyl(C8H17-C18H37)dimethylbenzylammonium (I), alkyl(C8H17-C16H33)benzyltrimethylammonium (II), alkyl(C8H17-C16H33)di-beta-hydroxyethylbenzylammonium (III) chlorides and chlorhydrate of glycine decyl ester (IV) on the ATPase activity of E. coli 1257 cell, spheroplasts, and isolated membranes. Changes in the ATPase activity of the E. coli cells and spheroplasts were found to depends on the concentration and the structure of the cationic surfactants. The removal of the cell wall increased the destroying effect of CS on the cytoplasmic membranes and enhanced the ATPase inhibition. The compounds with 16 and 18 carbon atom radical had the highest inhibitory effect. The action of cationic surfactants on the membrane is accompanied by changes in the protein and phospholipid composition and by significant solubilization of ATPase with pronounced inactivation of the enzyme. The kinetics of inhibition of E. coli membrane ATPase was studied to the presence of the homological series I and IV. The cationic surfactants under study inhibited the ATP hydrolysis catalysed by E. coli ATPase by a mixed type mechanism. Ki = 58.21.10(-4) M for IC10H21; 10.67.10(-4) M for IC12H25; 0.58.10(-4) M for IC16H33; 0.16.10(-4) M for IC18H37, and 5.93.10(-4) M for IV.     

Investigations on the mitochondria of the house fly,Musca domestica L. I. Adenosinetriphosphatases

1. The ATPase activity of insect mitochondria has been investigated. A comparison was made to determine the distribution and nature of such activity in other isolated fractions of the house fly, Musca domestica L. 2. The ATPase in insect mitochondria is specific in that orthophosphate can be cleaved only from ATP. The Michaelis-Menten constant K(8) = 2.78 x 10(-3)M and V(max.) = 76 micrograms P min.(-1) mg.(-1) dry weight. 3. Mg(++) and Mn(++) activate this enzymatic reaction in mitochondria, but Ca(++) does not. The extent of activation is 60 per cent with the optimal concentration 6 x 10(-4)M. Experiments with combinations of Mg(++) and Mn(++) show that either ion can replace the other and that the effects are additive, depending solely on the final concentration of the combination. Concentrations of Mg, Mn, or Ca ions higher than 6 x 10(-3)M inhibit the enzyme. 4. Fluoride does not inhibit the ATPase of insect mitochondria, whereas azide and chloromercuribenzoate do. The per cent inhibition depends on the concentration of inhibitor. 5. Finely dispersed mitochondrial particles have much greater ATPase activity than intact mitochondria. The possible relationship of this observation to latent ATPase is considered. 6. A magnesium-activated adenylate kinase is present in these mitochondria. The liberated orthophosphate, derived from ADP, is the result of the activity of adenylate kinase followed by the specific ATPase. 7. ATP can be dephosphorylated by enzymes found in the muscle fibrils, and in a "soluble" fraction, as well as in mitochondria. The fibrillar ATPase is Ca(++)-activated. The "soluble" fraction, however, like the mitochondria, is Mg(++)-activated. The "soluble" ATP dephosphorylation mechanism is distinguished from the mitochondrial ATPase in that it is inhibited by fluoride. 8. The "soluble" fraction also contains a magnesium-activated inorganic pyrophosphatase. Fluoride completely inhibits this enzymatic reaction. 9. The possible mechanism of ATP dephosphorylation in the "soluble" fraction is discussed.     

The alkaline adenosine triphosphatase activity of 30S dynein after modification of the SH groups. Possible involvement of some of the most reactive SH groups.

An apparent 'triphasic' alteration of 30S dynein ATPase activity was produced by treatment with various amounts of NEM when the modification and susequent ATPase assay were carried out at pH 7.4 and pH 10-10.2, respectively. The Mg-ATPase activity was markedly inhibited by modification of the most reactive SH groups with 10 microM NEM, although the same treatment had no significant effect on the activity when assayed at neutral pH. Increasing the NEM concentration to 0.3 mM largely restored the enzyme activity, but a further increase in NEM concentration inhibited the enzyme activity again. This unusual response of 30S dynein ATPase at pH 10-10.2 was accounted for by the results of Arrhenius plots of the enzyme activity at pH 10.1; the enzyme protein modified with not more than 10 microM NEM was not stable under the assay conditions (pH 10-10.2 at 25 degrees C), whereas modification with 0.3 mM NEM stabilized 30S dynein against the assay conditions. The possible significance of the 10 microM NEM-induced inhibition of the 30S dynein alkaline ATPase activity is discussed in connection with the participation of SH groups of 30S dynein in the enzyme activity.     

Effects of ethacrynic acid and furosemide on phosphorylation reactions of kidney mitochondria. Inhibition of the adenine nucleotide translocase.

Previous reports that ethacrynic acid and furosemide diminish mitochondrial P : O ratios and reduce (Na+ + K+)-ATPase activity suggested that these diuretics may inhibit mitochondrial phosphorylation reactions. This possibility was initially studied by determining the effects of ethacrynic acid and furosemide on [32P]ATP exchange activity of rat kidney mitochondria. Concentrations of both drugs at 10(-4) M or greater, significantly inhibited [32P]ATP exchange. To investigate the mechanism of this inhibition, the effects of ethacrynic acid and furosemide on the ATPase activity of intract mitochondria and sonicated submitochondrial particles were determined. Both diuretics inhibited ATPase activity of intact mitochondria at 10(-4) M. In contrast, ATPase of submitochondrial particles was significantly less susceptible to inhibition by the diuretics. These results suggested that ethacrynic acid anf furosemide inhibit adenine nucleotide transport across the mitochondrial membrane. This was directly tested by determining the effects of the diretics on the mitochondrial adenine nucleotide translocase. At 5-10(-4) M, both ethacrynic acid and furosemide significantly inhibited adenine nucleotide transport. These findings suggest that ethacrynic acid and furosemide may diminish renal tubular solute reabsorption by direct inhibition of adenine nucleotide transport across the mitochondrial inner membrane.     

Captopril inhibits ouabain-sensitive Na+/K+-ATPase

Captopril has been reported to inhibit ouabain-sensitive Na+/K+-ATPase activity in erythrocyte membrane fragments. We investigated the effect of captopril on two physiological measures of Na+/K+ pump activity: 22Na+ efflux from human erythrocytes and K+-induced relaxation of rat tail artery segments. Captopril inhibited 22Na+ efflux from erythrocytes in a concentration-dependent fashion, with 50% inhibition of total 22Na+ efflux at a concentration of 4.8 X 10(-3) M. The inhibition produced by captopril (5 X 10(-3) M) and ouabain (10(-4) M) was not greater than that produced by ouabain alone (65.3 vs. 66.9%, respectively), and captopril inhibited 50% of ouabain-sensitive 22Na+ efflux at a concentration of 2.0 X 10(-3) M. Inhibition by captopril of ouabain-sensitive 22Na efflux was not explained by changes in intracellular sodium concentration, inhibition of angiotensin-converting enzyme or a sulfhydryl effect. Utilizing rat tail arteries pre-contracted with norepinephrine (NE) or serotonin (5HT) in K+-free solutions, we demonstrated dose-related inhibition of K+-induced relaxation by captopril (10(-6) to 10(-4) M). Concentrations above 10(-4) M did not significantly inhibit K+-induced relaxation but did decrease contractile responses to NE, although not to 5HT. Inhibition of K+-induced relaxation by captopril was not affected by saralasin, teprotide or indomethacin. We conclude that captopril can inhibit membrane Na+/K+-ATPase in intact red blood cells and vascular smooth muscle cells. The mechanism of pump suppression is uncertain, but inhibition of ATPase should be considered when high concentrations of captopril are employed in physiological studies.     

Studies on rat liver argininosuccinate synthetase. Inhibition by various amino acids.

Inhibition studies of crystallized rat liver argininosuccinate synthetase [EC 6.3.4.5] are described. 1. L-Argininosuccinate, L-histidine, and L-tryptophan inhibited the enzyme activity at saturating amounts of the substrates. 2. L-Norvaline, L-argininosuccinate, L-arginine, L-isoleucine, and L-valine competitively inhibited the enzyme activity at a low concentration of L-citrulline, with Ki values of 1.3 x 10(4) M, 2.5 X 10(-4) M, 6.7 X 10(-4) M, 6.3 X 10(-4) M, and 6.0 x 10(-4) M, respectively. 3. L-Argininosuccinate and L-arginine competitively inhibited the enzyme activity at a low concentration of L-aspartate, with Ki values of 9.5 x 10(-4) M and 1.2 x 10(-3) M, respectively. 4. The modes of inhibition by L-histidine were mixed-noncompetitive, uncompetitive, and noncompetitive types with respect to L-citrulline, L-aspartate, and ATP, respectively. 5. When the enzyme was preincubated with L-citrulline, the enzyme activity was slightly increased in the presence of a low concentration of L-histidine in the assay mixture. 6. The conformation of the enzyme was markedly changed by the addition of L-histidine as judged from the CD spectrum. This change was partially reversed by incubation with L-citrulline.