Studies on the microsomal sodium-plus-potassium ion-stimulated adenosine triphosphatase system in rat ventral prostate

A Mg(2+)+Na(+)+K(+)-stimulated adenosine triphosphatase (ATPase) preparation was isolated from rat ventral prostate by flotation of microsomal membranes in high-density sucrose solutions. The reaction medium for optimum Na(+)+K(+)-stimulated ATPase activity was found to be: Na(+), 115mm; K(+), 7-10mm; Mg(2+), 3mm; ATP, 3mm; tris buffer, pH7.4 at 38 degrees , 20mm. The average DeltaP(i) (Mg(2+)+Na(+)+K(+) minus Mg(2+)+Na(+)) was 9mumoles/mg. of protein/hr., representing a 30% increase over the Mg(2+)+Na(+)-stimulated ATPase activity. At high concentrations, K(+) was inhibitory to the enzyme activity. Half-maximal inhibition of Na(+)+K(+)-stimulated ATPase activity was elicited by ouabain at 0.1mm. The preparation exhibited phosphatase activity towards ribonucleoside triphosphates other than ATP. However, stimulation of P(i) release by Na(+)+K(+) was observed only with ATP as substrate. The apparent K(m) for ATP for Na(+)+K(+)-stimulated activity was about 0.3x10(-3)m. Ca(2+) inhibited only the Na(+)+K(+)-stimulated ATPase activity. Mg(2+) could be replaced by Ca(2+) but then no Na(+)+K(+) stimulation of ATPase activity was noticed. The addition of testosterone or dihydrotestosterone (17beta-hydroxy-5alpha-androstan-3-one) in vitro at 0.1-10mum under a variety of experimental conditions did not significantly increase the Na(+)+K(+)-stimulated ATPase activity. The enzyme preparations from prostates of orchidectomized rats, however, exhibited a drastic decrease in the specific activity of Na(+)+K(+)-stimulated ATPase; these changes were prevented in the orchidectomized rats by injection of testosterone propionate.     

The cerebral sodium-plus-potassium ion-stimulated adenosine triphosphatase of bovine brain and its microsomal matrix

1. Adenosine triphosphatase activities of dispersions prepared from bovine cerebral cortex that had been frozen, were greater than those of dispersions prepared from fresh tissue. The subcellular distribution of components of the dispersion was not altered by freezing the tissue and a microsomal fraction enriched in Na(+)+K(+)-stimulated adenosine triphosphatase activity was prepared. 2. The bovine cerebral microsomes were further treated with a 2m-sodium iodide reagent to obtain a particulate preparation with minimal Na(+)+K(+)-independent adenosine triphosphatase activity. Na(+)+K(+)-stimulated activity was increased by the sodium iodide treatment and this preparation was shown to be enriched in lipid constituents. 3. Density-gradient centrifugation of the sodium iodide treated preparation gave three main subfractions each containing approximately equal amounts of phospholipid and protein. Further exposure of the sodium iodide-treated preparation to the 2m-sodium iodide reagent altered the distribution of protein and phospholipid among the fractions obtained by density-gradient centrifugation. Dissociation of phospholipids from protein in the sodium iodide-treated preparation was brought about also by high concentrations of arginine. Concentrated solutions of arginine and sodium thiocyanate brought about dissociation of phospholipids from protein of the microsomal preparation. 4. Many amino acids were found to inhibit Na(+)+K(+)-stimulated adenosine triphosphatase activity when present in high concentrations. The inhibition was complex but resulted, in part at least, from diminished affinity for ATP and Na(+) in the presence of the amino acids. 5. A non-ionic detergent, Lubrol W, solubilized up to 40% of the enzyme activity of the sodium iodide-treated preparation together with 30% of the protein and phospholipid in the preparation. Protein was released from the sodium iodide-treated preparation by pancreatic elastase but Na(+)+K(+)-stimulated adenosine triphosphatase activity of the residue was diminished. Ultrasonic treatment of the sodium iodide-treated preparation failed to release a significant proportion of Na(+)+K(+)-stimulated adenosine triphosphatase activity into a form not deposited by ultracentrifugation.     

The role of bound potassium ions in the hydrolysis of low concentrations of adenosine triphosphate by preparations of membrane fragments from ox brain cerebral cortex

1. The intrinsic Na(+), K(+), Mg(2+) and Ca(2+) contents of a preparation of membrane fragments from ox brain were determined by emission flame photometry. 2. Centrifugal washing of the preparation with imidazole-buffered EDTA solutions decreased the bound Na(+) from 90+/-20 to 24+/-12, the bound K(+) from 27+/-3 to 7+/-2, the bound Mg(2+) from 20+/-2 to 3+/-1 and the bound calcium from 8+/-1 to <1nmol/mg of protein. 3. The activities of the Na(+)+K(+)+Mg(2+)-stimulated adenosine triphosphatase and the Na(+)-dependent reaction forming bound phosphate were compared in the unwashed and washed preparations at an ATP concentration of 2.5mum (ATP/protein ratio 12.5pmol/mug). 4. The Na(+)-dependent hydrolysis of ATP as well as the plateau concentration of bound phosphate and the rate of dephosphorylation were decreased in the washed preparation. The time-course of formation and decline of bound phosphate was fully restored by the addition of 2.5mum-magnesium chloride and 2mum-potassium chloride. Addition of 2.5mum-magnesium chloride alone fully restored the plateau concentration of bound phosphate, but the rate of dephosphorylation was only slightly increased. Na(+)-dependent ATP hydrolysis was partly restored with 2.5mum-magnesium chloride; addition of K(+) in the range 2-10mum-potassium chloride then further restored hydrolysis but not to the control rate. 5. Pretreatment of the washed preparation at 0 degrees C with 0.5nmol of K(+)/mg of protein so that the final added K(+) in the reaction mixture was 0.1mum restored the Na(+)-dependent hydrolysis of ATP and the time-course of the reaction forming bound phosphate. 6. The binding of [(42)K]potassium chloride by the washed membrane preparation was examined. Binding in a solution containing 10nmol of K(+)/mg of protein was linear over a period of 20min and was inhibited by Na(+). Half-maximal inhibition of (42)K(+)-binding required a 100-fold excess of sodium chloride. 7. It was concluded (a) that a significant fraction of the apparent Na(+)-dependent hydrolysis of ATP observed in the unwashed preparation is due to activation by bound K(+) and Mg(2+) of the Na(+)+K(+)+Mg(2+)-stimulated adenosine triphosphatase system and (b) that the enzyme system is able to bind K(+) from a solution of 0.5mum-potassium chloride.     

Chemical modification of a cerebral sodium-plus-potassium ion-stimulated adenosine triphosphatase preparation

1. A particulate Na(+)+K(+)-stimulated adenosine triphosphatase preparation obtained by treatment of bovine cerebral microsomes with a sodium iodide reagent has been further treated with acid anhydrides likely to convert amino groups into acidic derivatives. 2. The extent of acylation of amino groups was determined by reaction of the remaining amino groups with 2,4,6-trinitrobenzenesulphonic acid. The unmodified preparation contains about 1.2 muequiv. of amino groups/mg of protein of which only about 0.5 muequiv. are accounted for by protein amino groups. Kinetics of the trinitrobenzenesulphonic acid reaction with the unmodified preparation are complex and are altered by ATP or ouabain. 3. The compounds examined cause loss of Na(+)+K(+)-stimulated adenosine triphosphatase activity when relatively few amino groups are modified but ATP was found to afford partial protection against inactivation by methylmaleic anhydride. Na(+)+K(+)-stimulated adenosine triphosphatase activity is partly restored to the dimethylmaleylated preparation by hydrolysis of the dimethylmaleyl-amide bonds but not if more than about 20% of the amino groups have been acylated. 4. Supernatants obtained by high-speed centrifugation of the dimethylmaleylated preparation contained up to 45% of the total protein with less than 10% of the total phospholipid. Methylmaleyl and benzenetricarboxylyl derivatives of the enzyme preparation behaved similarly but tetrafluorosuccinylated material was almost entirely deposited by centrifugation.     

Calcium ion-dependent p-nitrophenyl phosphate phosphatase activity and calcium ion-dependent adenosine triphosphatase activity from human erythrocyte membranes

In the presence of ATP and of Mg(2+), human erythrocyte membranes show a phosphatase activity towards p-nitrophenyl phosphate which is activated by low concentrations of Ca(2+). The effect of Ca(2+) is strongly enhanced if either K(+) or Na(+) is also present. Activation of the p-nitrophenyl phosphate phosphatase by Ca(2+) reaches a half-maximum at about 8mum-Ca(2+) and is apparent only when the ion has access to the inner surface of the cell membrane. Ca(2+)-dependent phosphatase activity can only be observed if ATP is at the inner surface of the cell membrane, and the presence of ATP seems to be absolutely necessary, since either its removal or its replacement by other nucleoside triphosphates abolishes the activating effect of Ca(2+). The properties of the (ATP+Ca(2+))-dependent phosphatase are very similar to those of the Ca(2+)-dependent ATPase (adenosine triphosphatase), also present in erythrocyte membranes, which probably is involved in Ca(2+) transport in erythrocytes. The similarities suggest that both activities may be properties of the same molecular system. This view is further supported by the fact that p-nitrophenyl phosphate inhibits to a similar extent Ca(2+)-dependent ATPase activity and ATP-dependent Ca(2+) extrusion from erythrocytes.     

Properties of the sarcolemmal calcium ion-stimulated adenosine triphosphatase of hamster skeletal muscle

1. A sarcolemmal fraction was isolated from hamster hind-leg skeletal muscles by successive treatment with lithium bromide and potassium chloride. The membranous fraction was observed to contain a highly active Ca(2+)-stimulated ATPase (adenosine triphosphatase), a Mg(2+)-stimulated ATPase, and an Na(+)+K(+)-stimulated Mg(2+)-dependent ouabain-sensitive ATPase. 2. The Ca(2+)-stimulated ATPase activity was pH-dependent, the optimum being pH7.6. 3. Optimum activation of this enzyme was obtained with 3-4mm-Ca(2+) when 4mm-ATP was present as a substrate, and was not influenced by Na(+), K(+) or ouabain, whereas 2,4-dinitrophenol, sodium azide, oligomycin, sodium fluoride and ethanedioxybis(ethylamine)tetra-acetate were inhibitory. 4. The Ca(2+)-stimulated ATPase was markedly inhibited by thiol-blocking reagents, and cysteine was able to reverse this inhibition. 5. Various bivalent cations stimulated ATP hydrolysis by the sarcolemmal fraction in the following decreasing order of potency: Mg(2+), Ca(2+), Mn(2+), Co(2+), Sr(2+), Ba(2+), Zn(2+), Cu(2+).     

Comparison of some minor activities accompanying a preparation of sodium-plus-potassium ion-stimulated adenosine triphosphatase from pig brain

1. An ATPase (adenosine triphosphatase) preparation obtained from pig brain microsomes by treatment with sodium iodide showed four apparently different ouabain-sensitive activities under various conditions. They were (a) ouabain-sensitive Mg(2+)-stimulated ATPase, (b) K(+)-stimulated ATPase, (c) (Na(+),K(+))-stimulated ATPase and (d) Na(+)-stimulated ATPase activities. 2. These activities showed the same substrate specificity, ATP being preferentially hydrolysed and CTP slightly. AMP was not hydrolysed. 3. These activities were inhibited by low concentration of ouabain. The concentration producing 50% inhibition was 0.1mum for ouabain-sensitive Mg(2+)-stimulated ATPase, 0.2mum for K(+)-stimulated ATPase, 0.1mum for (Na(+),K(+))-stimulated ATPase and 0.003mum for Na(+)-stimulated ATPase activity. 4. The ouabain-sensitive ATPase activities were inactivated by N-ethylmaleimide but the insensitive ATPase activity was not. 5. The three ouabain-sensitive ATPase activities were inhibited about 50% by 1mm-Ca(2+), whereas the ouabain-sensitive Mg(2+)-stimulated ATPase activity was activated by the same concentration of Ca(2+). The preparation was treated with ultrasonics at 20kcyc./sec. The 2min. ultrasonic treatment inactivated the ATPase activities by 50%. 7. The temperature coefficient Q(10) was 6.6 for K(+)-stimulated ATPase activity, 3.7 for (Na(+),K(+))-stimulated ATPase and 2.6 for Na(+)-stimulated ATPase. 8. Organic solvents inactivated the ATPase activities, to which treatment the K(+)-stimulated ATPase was the most resistant. 9. The phosphorylation of the enzyme preparation became less dependent on Na(+) with decreasing pH. This Na(+)-independent phosphorylation at low pH was sensitive to K(+) and hydroxylamine as well as the Na(+)-dependent phosphorylation at neutral pH.     

Distribution of sodium-plus-potassium-stimulated adenosine-triphosphatase activity in isolated nerve-ending particles

1. A rapid method for the isolation of nerve-ending particles from brain is described. This involved the centrifugation of the large-granule fraction over a discontinuous density gradient consisting of 3% (w/v) and 13% (w/v) Ficoll dissolved in 0.32m-sucrose. The results of the biochemical as well as morphological identification of nerve-ending particles are given. 2. Approx. 20% of the (Na(+)+K(+))-stimulated adenosine-triphosphatase activity originally present in the cerebral grey-matter suspension was recovered in the fraction consisting principally of large nerve-ending particles (approx. 1mu in diameter). The activity of the adenosine triphosphatase/mg. of protein in the nerve-ending fraction approximated to that in the small-granule fraction after the treatment with glycol ether diamine-tetra-acetic acid. The conclusion was drawn that the synaptic structure, supposedly the limiting membrane of the nerve-ending particle, is one of the feasible sites of localization of the (Na(+)+K(+))-stimulated adenosine-triphosphatase activity in cerebral tissues. Adenosine triphosphatase in purified cerebral mitochondria was not stimulated by Na(+). 3. No qualitative differences were found between the (Na(+)+K(+))-stimulated adenosine-triphosphatase activities exhibited by the nerve-ending particles and by the cerebral small-granule fraction with respect to pH-dependence, cation requirements and susceptibility to ouabain.     

Separation of adenosine diphosphate-adenosine triphosphate–exchange activity from the cerebral microsomal sodium-plus-potassium ion-stimulated adenosine triphosphatase

1. A microsomal fraction from ox cerebral cortex catalysed [(14)C]ADP-ATP exchange at a speed similar to that at which it liberated P(i) from ATP in the presence of Na(+), K(+) and Mg(2+). 2. Repeated washing the fraction with MgATP solutions solubilized most of the exchange activity and left the adenosine triphosphatase insoluble and little changed in activity. The exchange activity was accompanied by negligible adenosine-triphosphatase activity and was enriched by precipitation at chosen pH and by DEAE-Sephadex. At no stage was its activity affected by Na(+), K(+) or ouabain. 3. The washed microsomal fraction was exposed to a variety of reagents; a sodium iodide-cysteine treatment increased both adenosine-triphosphatase and exchange activities, as also did a synthetic zeolite. Preparations were obtained with exchange activities less than 3% of their Na(+)-plus-K(+)-stimulated adenosine-triphosphatase activity. Some contribution to the residual exchange activity was made by an adenylate kinase. 4. Thus over 95% of the microsomal ADP-ATP-exchange activity does not take part in the Na(+)-plus-K(+)-stimulated adenosine-triphosphatase reaction. Participation of some of the residual 3% of the ADP-ATP-exchange activity has not been excluded, but there appears no firm evidence for its participation in the adenosine triphosphatase; the bearing of this conclusion on mechanisms proposed for the Na(+)-plus-K(+)-stimulated adenosine triphosphatase is indicated.     

The adenosine diphosphate–adenosine triphosphate-exchange reaction of cerebral microsomes and its relation to the sodium ion-stimulated adenosine-triphosphatase reaction

Microsomes from guinea-pig cerebral cortex contain a system capable of exchanging ADP with ATP at rates of about 20mumoles/mg. of protein/hr. The ADP-ATP-exchange reaction requires Mg(2+) for activity. The reaction is not stimulated by Na(+) or K(+) and is not inhibited by ouabain, in contrast with the Na(+)-plus-K(+)-stimulated adenosine triphosphatase. The pH optimum also differs from that of the adenosine triphosphatase. The ADP-ATP-exchange reaction is stimulated two- to three-fold by non-ionic, anionic and cationic detergents, even when these agents are inhibiting the adenosine-triphosphatase reaction. This reaction may represent a component of the Na(+)-plus-K(+)-stimulated adenosine-triphosphatase reaction but is more likely to be due to other enzyme systems present in microsomal subfractions.     

The phosphatidylinositol kinase of rat brain

1. The presence of a phosphatidylinositol kinase in homogenates of adult rat brain was shown by using labelled ATP or labelled phosphatidylinositol. 2. The kinase was activated by Mg(2+) or Mn(2+) and inhibited by Ca(2+), Cu(2+), K(+), Na(+) and F(-). 3. The detergents sodium deoxycholate, Cutscum and Triton X-100 markedly stimulated the reaction; sodium taurocholate, Tween-20 and cetyltrimethyl-ammonium bromide were less effective. 4. The activity of the enzyme was dependent on SH groups. 5. The subcellular distribution of the kinase in brain resembled that of Na(+)-plus-K(+)-stimulated adenosine triphosphatase and 5'-nucleotidase.     

The nature and properties of the inducible sodium-plus-potassium ion-dependent adenosine triphosphatase in the gills of eels (Anguilla anguilla) adapted to fresh water and sea water

1. Gill tissue from eels adapted to fresh water or to sea water was disrupted in 0.32m-sucrose containing 0.1% (w/v) sodium deoxycholate and the subcellular distribution of (Na(+)+K(+))-dependent adenosine triphosphatase was determined. 2. About 70% of the recovered enzyme was in a fraction sedimenting between 225000g(av.)-min and 6000000g(av.)-min; the specific activities of enzymes from tissues of freshwater and seawater eels were 16 and 51 mumol of phosphate/h per mg of protein respectively. 3. The enzymes from gills of freshwater and seawater eels were indistinguishable on the basis of a number of parameters. These included phosphorylation by [gamma-(32)P]ATP, the binding of [(3)H]ouabain, the extent to which bound [(3)H]ouabain was displaced by increasing concentrations of KCl and pH optima. 4. Electrophoresis on polyacrylamide gels in sodium dodecyl sulphate showed that enzyme preparations from both sources had an identical number of protein components. 5. The higher specific activity of (Na(+)+K(+))-dependent adenosine triphosphatase from tissue of seawater eels was accompanied by increased amounts of two protein components. One of these proteins retained (32)P after treatment of the enzyme with [gamma-(32)P]ATP and had mol.wt. 97000; the other component was a glycoprotein with mol.wt. approx. 46000. 6. The results are discussed in terms of the nature of the transepithelial NaCl pumps in the gills of freshwater and seawater fish.     

The reversible delipidation of a solubilized sodium-plus-potassium ion-dependent adenosine triphosphatase from the salt gland of the spiny dogfish.

A microsomal fraction rich in Na+, K+-ATPase (sodium-plus-potassium ion-dependent adenosine triphosphatase) and the corresponding K+-dependent p-nitrophenyl phosphatase from the rectal salt gland of the spiny dogfish was solubilized by treatment with deoxycholate at high ionic strength. On gel filtration through Sepharose 6B, the ATPase apoenzyme could be separated, in apparently soluble form, from the tissue-fraction phospholipids and was almost free of enzymic activity (2% of the p-nitrophenyl phosphatase activity and 0.2% of the ATPase activity being recovered). On mixing the apoenzyme with an activator consisting of cooked ox brain, a large proportion of the original enzymic activity was obtained. Specific activities of the re-activated enzyme were somewhat higher than in the material before gel filtration: values of 1300-1450 mumol and 250-290 mumol/h per mg of protein were obtained for the hydrolysis of ATP and of p-nitrophenyl phosphate respectively. The activity was inhibitible by ouabain.     

K+-independent active transport of Na+ by the (Na+ and K+)-stimulated adenosine triphosphatase

The (Na+ and K+)-stimulated adenosine triphosphatase (Na+,K+)-ATPase) from canine kidney reconstituted into phospholipid vesicles showed an ATP-dependent, ouabain-inhibited uptake of 22Na+ in the absence of added K+. This transport occurred against a Na+ concentration gradient, was not affected by increasing the K+ concentration to 10 microM (four times the endogenous level), and could not be explained in terms of Na+in in equilibrium Na+out exchange. K+-independent transport occurred with a stoichiometry of 0.5 mol of Na+ per mol of ATP hydrolyzed as compared with 2.9 mol of Na+ per mol of ATP for K+-dependent transport.     

Cytochemistry of Phosphatases in Myxococcus xanthus

An Mg(2+)-dependent and a K(+)-stimulated adenosine triphosphatase were localized by cytochemistry at or near both surfaces of the cytoplasmic membrane of Myxococcus xanthus. An alkaline and an acid phosphatase resided at the external surface of the membrane or in the periplasm. All enzymes could be extracted from partially fixed cells with Mg(2+)-deficient buffers. Suboptimal external phosphate elicited dissociation of adenosine triphosphatase from the membrane but not that of the unspecific phosphatases. The dissociated enzymes migrated into the cytoplasm where they were associated mainly with cytoplasmic aggregates.     

Characterization and partial isolation of ouabain-insensitive Na(+) -ATPase in MDCK I cells

We show that MDCK I cells express, besides the classical (Na(+)+K(+))ATPase, a Na(+)-stimulated ATPase activity with the following characteristics: (1) K(0.5) for Na(+) 7.5+/-1.5 mM and V(max) 23.12+/-1.1 nmol Pi/mg per min; (2) insensitive to 1 mM ouabain and 30 mM KCl; and (3) inhibited by furosemide and vanadate (IC(50) 42.1+/-8.0 and 4.3+/-0.3 microM, respectively). This enzyme forms a Na(+)-stimulated, furosemide- and hydroxylamine-sensitive ATP-driven acylphosphate phosphorylated intermediate with molecular weight of 100 kDa. Immunoprecipitation of the (Na(+)+K(+))ATPase with monoclonal anti-alpha(1) antibody reduced its activity in the supernatant by 90%; the Na(+)-ATPase activity was completely maintained. In addition, the formation of the Na(+)-stimulated, furosemide- and hydroxylamine-sensitive ATP-driven acylphosphate intermediate occurred at the same magnitude as that observed before immunoprecipitation. These data suggest that Na(+)-ATPase and (Na(+)+K(+))ATPase activities are independent, with Na(+)-ATPase belonging to a different enzyme entity.     

Fractionation of liver plasma membranes prepared by zonal centrifugation

1. Plasma membranes were isolated from crude nuclear sediments from mouse and rat liver by a rate-dependent centrifugation through a sucrose density gradient contained in the ;A' type zonal rotor. 2. The membranes were further purified by isopycnic centrifugation, and characterized enzymically, chemically and morphologically. 3. When the plasma-membrane fraction of sucrose density 1.17g/cm(3) was dispersed in a tight-fitting homogenizer, two subfractions of densities 1.12 and 1.18 were obtained by isopycnic centrifugation. 4. The light subfraction contained 5'-nucleotidase, nucleoside diphosphatase, leucine naphthylamidase and Mg(2+)-stimulated adenosine triphosphatase activities at higher specific activities than unfractionated membranes. The heavy subfraction was deficient in the above enzymes but contained higher Na(+)+K(+)-stimulated adenosine triphosphatase activity. 5. The light subfraction contained twice as much phospholipid and cholesterol, and three times as much N-acetylneuraminic acid relative to unit protein weight as the heavy subfraction. Polyacrylamide-gel electrophoresis indicated differences in protein composition. 6. Electron microscopy showed the light subfraction to be vesicular. The heavy subfraction contained membrane strips with junctional complexes in addition to vesicles.     

Stabilization of Na+, K+-adenosine triphosphatase by dimethyl sulfoxide under inactivation by urea]

Hydrophobic agents, e.g. methanol, ethanol, isopropanol, acetone and dioxane were shown to induce irreversible inactivation of Na+, K+-adenosine triphosphatase beginning with their concentrations of 20 to 35%, whereas dimethyl sulphoxide exerted similar effect only at concentration of 50% and higher. Urea also irreversibly inactivated Na+, K+-adenosine triphosphatase, beginning with a concentration of about 20%. It was found that, dimethyl sulphoxide contrary to the other hydrophobic agents studied, protected Na+, K+-adenosine triphosphatase against the inactivating (denaturing) action of urea. The highest stabilizing effect of dimethyl sulphoxide was displayed at concentrations from 20 to 30%.     

Potassium ion-stimulated and sodium ion-dependent adenosine diphosphate–adenosine triphosphate exchange activity in a kidney microsomal fraction

1. K(+) did not affect the Mg(2+)-dependent transphosphorylation but markedly increased the Na(+)-stimulated ADP-ATP exchange rate mediated by a microsomal fraction from guinea-pig kidney. 2. Rb(+), Cs(+), NH(4) (+) and Li(+) were equally effective in stimulating the Na(+)-dependent ADP-ATP exchange activity. 3. Treatment of the microsomal fraction with N-ethylmaleimide or increased concentrations of Mg(2+) prevented stimulation of the Na(+)-dependent exchange reaction by K(+). 4. Ouabain (2.5mum) inhibited ATP hydrolysis by 33% but did not decrease the K(+)-stimulated Na(+)-dependent ADP-ATP exchange rate. 5. A possible mechanism for stimulation of exchange activity by K(+) is discussed.     

The influence of external sodium ions on the sodium pump in erythrocytes

1. A study has been made of the interaction between Na(+) and K(+) on the adenosine triphosphatase activity of erythrocyte ;ghosts', and on the K(+) influx and Na(+) efflux of intact erythrocytes. The adenosine triphosphatase activity and the ion movements were greater at a low external K(+) concentration in the absence of Na(+) than they were in the presence of 150mm-Na(+). The inhibition by external Na(+) of K(+) influx had an inhibitory constant of 5-10mm. 2. Activation by K(+) of kidney microsomal adenosine triphosphatase was retarded by Na(+), and activation by Na(+) was retarded by K(+). Fragmented erythrocyte membranes behaved similarly. 3. These observations suggest that there is competition between Na(+) and K(+) at the K(+)-sensitive site of the membrane.