Protonation-dependent inactivation of Na,K-ATPase by hydrostatic pressure developed at high-speed centrifugation

Irreversible inactivation of membranous Na,K-ATPase by high-speed centrifugation in dilute aqueous solutions depends markedly on the protonation state of the protein. Pig kidney Na,K-ATPase is irreversibly inactivated at pH 5 but is fully protected at pH 7 and above. Shark rectal gland Na,K-ATPase is irreversibly inactivated at neutral or acidic pH and partially protected at an alkaline pH. The overall Na,K-ATPase activity and the K-dependent pNPPase activity were denatured in parallel. Cryoprotectants such as glycerol or sucrose at concentrations of 25-30% fully protect both enzymes against inactivation. The specific ligands NaCl and KCl protect the Na,K-ATPase activity partially and the pNPPase activity fully at concentrations of 0.2-0.3 M. Electron microscope analysis of the centrifuged Na,K-ATPase membranes revealed that the ultrastructure of the native membranes is preserved upon inactivation. It was also observed that the sarcoplasmic reticulum Ca-ATPase and hog gastric H, K-ATPase are susceptible to inactivation by high-speed centrifugation in a pH-dependent fashion. H,K-ATPase is protected at alkaline pH, whereas Ca-ATPase is protected only in the neutral pH range.     

Effects of anticonvulsive substances on Na,K-ATPase from the synaptic membranes of animal brain]

The distribution pattern of marker enzymes (Na, K-ATPase, acetylcholinesterase) in three fractions of synaptic membranes (SM) of rat brain were studied. The effects of three anticonvulsive agents on Na, K-ATPase from the total fraction of rat brain SM and purified membrane preparation from ox brain were estimated by different methods. Under optimal conditions (Na/K = 5) diphenylhydantoin (DPH) at a concentration of 0,1 mM activates Na, K-ATPase from the total SM fraction only in the absence of ouabain, whereas carbamazepine and pyrroxane taken at the same concentrations have no effect on Na, K-ATPase, irrespective of the type of the enzyme assay. DPH seems to compete with ouabain. Under non-optimal ionic conditions (Na/K = 250) all the anticonvulsive substances studied inhibit Na, K-ATPase of the total SM fraction. The mixture of hydrophobic agents (propylene glycol and ethanol) used to dissolve carbamazepine inhibits Na, K-ATPase from the total SM fraction only under non-optimal conditions. The inhibiting effect of the anticonvulsive substances under study on Na, K-ATPase from the purified membrane preparations is maximal at the concentration of 10(-6) M; at higher concentrations the effect is less pronounced.     

Characterization of membrane-bound adenosinetriphosphatase activity of sarcolemma-enriched fraction from vascular smooth muscle

Membrane-bound adenosinetriphosphatase (ATPase) activities of the sarcolemma-enriched fraction from bovine aorta were characterized. The membranes, isolated by a sucrose density gradient method, were enriched about 31-fold in sodium- and potassium-stimulated, magnesium-dependent ATPase (Na,K-ATPase) activity, and about 8-fold in 5'-nucleotidase activity compared to the homogenate, suggesting that the isolated membranes were substantially enriched with the sarcolemma. The membranes exhibited about 31, 33 and 42 mumol Pi/mg protein/h of Na,K-ATPase, magnesium-dependent ATPase and calcium-dependent ATPase activities, respectively, in the presence of 4 mmol/l ATP. The sarcolemma-enriched membranes required considerably high concentrations of well-known inhibitors for Na,K-ATPase such as vanadate (more than 1 mumol/l), lanthanum (more than 1 mmol/l) and calcium (10 mmol/l), to induce a significant inhibition in the Na,K-ATPase activity. Treatments of the membrane with physical disruptions and sodium dodecyl sulfate or deoxycholate reduced the total Na,K-ATPase activity, and did not expose fully the ouabain sensitivity of the Na,K-ATPase. These results indicate that there are marked differences in the properties of the ATPase between vascular smooth muscle sarcolemma and cardiac sarcolemma.     

Effect of catecholamines and metal chelating agents on the brain and brown adipose tissue Na,K-ATPase

Catecholamines stimulate Na,K-ATPase activity in the microsomal membranes of the brain and brown adipose tissue. This stimulation is apparent in the absence of soluble, cytosolic inhibitors and exhibits the same characteristics in both tissues: it occurs at high concentrations (10(-6)-10(-4) M) only; there is no difference in potency between isoprenaline, norepinephrine and epinephrine (EC50 = 1-2 X 10(-5) M); the D-stereoisomer of isoprenaline is equally as effective as the L-form; stimulation of Na,K-ATPase may also be achieved by the metal chelators EDTA, EGTA and desferal; the hydrophobic beta-blockers, propranolol and alprenolol, inhibit both the norepinephrine-stimulated and basal levels of enzyme activity at concentrations of 10(-5)-10(-3) M; phenoxybenzamine, an irreversible alpha-adrenergic blocker, inhibits basal Na,K-ATPase as well as norepinephrine-stimulated enzyme activity (EC50 = 2.5 X 10(-5) M). Because none of these observations can be related to the properties of the stereospecific adrenergic receptor (alpha or beta), it may be concluded that the catecholamine-Na,K-ATPase interaction is not mediated by the receptor. More probably, catecholamines may antagonize the Na,K-ATPase inhibition caused by some tightly membrane-bound metals (but not vanadium) via the ortho-catechol moiety of the catecholamine molecule. The stimulation of brown fat Na,K-ATPase by catecholamines does not have much relevance to the norepinephrine-stimulated thermogenesis in this tissue.     

Detergent inactivation of sodium- and potassium-activated adenosinetriphosphatase of the electric eel.

The stability of the sodium- and potassium-activated adenosinetriphosphatase (Na,K-ATPase) of the electric eel, Electrophorus electricus, was studied in five detergents in an effort to establish conditions for reconstitution of this membrane protein into defined phospholipids. The Na,K-ATPase activity of purified electric organ membranes as well as the ATPase is stable for at least 1 month of storage at 0 degrees C in the absence of detergents. At low concentrations of detergents, the enzyme is also stable for several days, but irreversible inactivation occurs rapidly as the detergent concentration is further increased. This inactivation begins at well-defined threshold concentrations for each detergent, and these concentrations generally occur in the order of the detergent critical micelle concentrations. Increasing the concentration of the electric organ membranes causes a linear increase in the inactivation threshold concentrations of Lubrol WX, deoxycholate, and cholate. The onset of inactivation evidently occurs when the mole fraction of detergent associated with the membrane lipids reaches a critical value in the narrow range of 0.2-0.4, in contrast to the large differences in the bulk concentrations of these detergents. The eel Na,K-ATPase is more sensitive to detergents than the sheep kidney enzyme.     

The Na/K-ATPase regulation by neurotransmitters in ontogeny

Activity of the Na/K-ATPase from rat brain synaptic membranes is inhibited by NA (noradrenaline). However, during fractionation of cytozole from nerve endings, two non-homogeneous peaks are found (SF(a), 60-100 kD and SF( i ),;10 kD), which influence the Na/K-ATPase activity, both directly and SF(a) NA-dependently. Joint action of NA and synaptic factors (SF(a) and SF(i)) on the Na/K-ATPase, represents a sum of four different processes: 1) NA, without synaptic factors, inhibits the Na/K-ATPase; 2) At low SF(a) concentrations NA-dependent Na/K-ATPase activatory mechanism is evident; 3) At high SF(a) concentrations NA-independent Na/K-ATPase is activated; 4) The low-molecular SF(i) protein inhibits the Na/K-ATPase. Regulation of the Na/K-ATPase activity by NA, SF(a) and SF( i), obtained in similar conditions from two weeks old and one year old rats, is different. In older rats SF(i) is characterized with strong Na/K-ATPase inhibition; in younger rats SF(i) does not change the Na/K-ATPase activity. The NA- and SF(i) -dependent inhibition and activation ratio is different in young and elder rats. In two week olds NA/SF(i) activatory mechanism is stronger, while in one year olds NA-dependent inhibition of the Na/K-ATPase is prevailing. These experimental data indicate that regulation of the Na/K-ATPase activity has an important role in synaptic transmission and that this process has noteworthy, albeit presently unknown, functional importance in integrative activity of the brain.     

Mechanism of brain Na,K-ATPase activation by adrenaline]

Norepinephrine stimulates Na, K-ATPase from rat brain homogenates at concentrations of 10(-4)--10(-5) and 10(-7)--10(-8) M. A low concentration maximum is observed after 48 hrs of incubation at -20 degrees C and is not changed by the addition of alpha-tocopherol, glycerol and MAO inhibitor ipraside. The maximum observed at the mediator concentration equal to 10(-4)--10(-5) M is eliminated after treatment with EGTA. At all concentrations of norepinephrine the enzyme stimulation is removed by the alpha-adrenoblocker phentolamine. The activated enzyme reveals lower sensitivity to Ca2+ induced inhibition. The role of Ca2+ and conformational state of the membranes in the realization of the remote effect on the adrenoreceptor-Na, K-ATPase system is discussed.     

Membrane regulation of brain Na,K-ATPase inhibition by calcium ions

In contrast to the purified enzyme. Na, K-ATPase from intact synaptic membranes is inhibited by Ca2+ according to a biphase pattern at Ca2+ concentrations of 10(-6) to 10(-3) M. The membrane damage after three washings with bidistilled water results in elimination of low cocentration phase. Recombination of the sediment and the supernatant restores the initial shape of the inhibition curve. Dithiothreitol greatly increases the inhibition by low Ca concentrations. This effect is absent in the purified enzyme preparation and is considerably reduced after the membrane damage. Recombination restores the dithiothreitol effect. It is suggested that the sensitivity of membrane Na,K-ATPase to low concentrations of Ca2+ is controlled by the components (most likely, peripheral proteins), which are loosely bound to the membrane, this process being dependent on the degree of the SH-group reduction.     

Changes in the membrane ATPase activity of erythrocytes and Candida guilliermondii under the action of roseofungin

Changes in the Mg-ATPase and Na, K-ATPase activity of the rat erythrocyte and Candida guilliermondii membranes under the effect of roseofungin were studied. The antibiotic was totally bound to the isolated plasmatic membranes of Candida guilliermondii, up to 3 micrograms of the antibiotic per 1 microgram of the yeast protein. The Mg-APTase activity of these membranes was slightly inhibited by the antibiotic. The activity of Na, K-ATPase was almost completely inhibited even at 0.04 mg of roseofungin per 1 mg of protein. Much higher concentrations of the antibiotic inhibited the Mg-ATPase and Na, K-ATPase activity of the erythrocyte membranes to a less extent.     

Analytical isolation of plasma membranes of intestinal epithelial cells: identification of Na, K-ATPase rich membranes and the distribution of enzyme activities.

A procedure was developed for the analytical isolation of brush border and basal lateral plasma membranes of intestinal epithelial cells. Brush border fragments were collected by low speed centrifugation, disrupted in hypertonic sorbitol, and subjected to density gradient centrifugation for separation of plasma membranes from nuclei and core material. Sucrase specific activity in the purified brush border plasma membranes was increased fortyfold with respect to the initial homogenate. Basal lateral membrane were harvested from the low speed supernatant and resolved from other subcellular components by equilibrium density gradient centrifugation. Recovery of Na, K-ATPase activity was 94%, and 61% of the recovered activity was present in a single symmetrical peak. The specific activity of Na, K-ATPase was increased twelvefold, and it was purified with respect to sucrase, succinic dehydrogenase, NADPH-cytochrome c reductase, nonspecific esterase, beta-glucuronidase, DNA, and RNA. The observed purification factors are comparable to results reported for other purification procedures, and the yield of Na, K-ATPase is greater by a factor of two than those reported for other procedures which produce no net increase in the Na, K-ATPase activity. Na, K-ATPase rich membranes are shown to originate from the basal lateral plasma membranes by the patterns of labeling that were produced when either isolated cells or everted gut sacs were incubated with the slowly permeating reagent 35S-p-(diazonium)-benzenesulfonic acid. In the former case subsequently purified Na, K-ATPase rich and sucrase rich membranes are labeled to the same extent, while in the latter there is a tenfold excess of label in the sucrase rich membranes. The plasma membrane fractions were in both cases more heavily labeled than intracellular protein. Alkaline phosphatase and calcium-stimulated ATPase were present at comparable levels on the two aspects of the epithelial cell plasma membrane, and 25% of the acid phosphatase activity was present on the basal lateral membrane, while it was absent from the brush border membrane. Less than 6% of the total Na, K-ATPase was present in brush border membranes.     

Interaction of FXYD10 (PLMS) with Na,K-ATPase from shark rectal glands. Close proximity of Cys74 of FXYD10 to Cys254 in the a domain of the alpha-subunit revealed by intermolecular thiol cross-linking

FXYD domain-containing proteins are tissue-specific regulators of the Na,K-ATPase that have been shown to have significant physiological implications. Information about the sites of interaction between some FXYD proteins and subunits of the Na,K-ATPase is beginning to emerge. We previously identified an FXYD protein in plasma membranes from shark rectal gland cells and demonstrated that this protein (FXYD10) modulates shark Na,K-ATPase activity. The present study was undertaken to identify the location of the C-terminal domain of FXYD10 on the alpha-subunit of Na,K-ATPase, using covalent cross-linking combined with proteolytic cleavage. Treatment of Na,K-ATPase-enriched membranes with the homobifunctional thiol cross-linker 1,4-bismaleimidyl-2,3-dihydroxybutane resulted in cross-linking of FXYD10 to the alpha-subunit. Cross-linking was not affected by preincubation with sodium or potassium but was significantly reduced after pre-incubation with the non-hydrolyzable ATP analog beta,gamma-methyleneadenosine 5'-triphosphate (AMP-PCP). A peptic assay was developed, in which pepsin treatment of Na,K-ATPase at low pH resulted in extensive cleavage of the alpha-subunit while FXYD10 was left intact. Proteolytic fragments of control and cross-linked preparations were isolated by immunoprecipitation and analyzed by gel electrophoresis. A proteolytic fragment containing FXYD10 cross-linked to a fragment from the alpha-subunit could be localized on SDS gels. Sequencing of this fragment showed the presence of FXYD10 as well as a fragment within the A domain of the alpha-subunit comprising 33 amino acids, including a single Cys residue, Cys254. Thus, regulation of Na,K-ATPase by FXYD10 occurs in part via cytoplasmic interaction of FXYD10 with the A domain of the shark alpha-subunit.     

Modulatory effect of two cardioglycosides on reconstituted Na+/K(+)-ATPase in proteoliposomes.

1. Na,K-ATPase was extracted from Cavia cobaya kidneys, solubilized with nonionic detergent C12E8 (octaethyleneglycol dodecyl monoether) in mixed lipid-detergent-protein micelles. The Na,K-ATPase specific activity was 30-35 IU/mg protein. 2. The enzyme was reconstituted in vesicles, made of phosphatidylethanolamine and cholesterol: an enhancement of +60% in specific activity was obtained. 3. Two different vesicle-types were carried out: open liposomes (partially organized membranes) and closed liposomes. 4. Proteoliposomes were employed for measuring the modulatory effect of two cardioglycosides: ouabain and digoxin. 5. Inhibition of the Na,K-ATPase activity revealed apparent Ki of 1.25 microM for ouabain and 0.25 microM for digoxin in open liposomes, and apparent Ki of 0.75 microM for ouabain and of 1.75 microM for digoxin in closed liposomes. 6. Maximum enhancement of enzymatic activity was found at concentrations of 5-0.5 nM for ouabain and 5-1 nM for digoxin in open liposomes, and 25-1 nM for both digoxin and ouabain in closed liposomes.     

Effect of thyroid hormone on the distribution and activity of Na, K-ATPase in ventricular myocardium

Employing detergent-free sucrose-density gradient fractionation method we isolated cholesterol-rich lighter membrane fractions containing ∼10% of protein, ∼30% of cholesterol in membranes of ventricular myocardium. Cholesterol-rich lighter membrane fractions contain >70% of Na, K-ATPase and caveolins 1 and 3 and <10% of β-actin. Treatment of hypothyroid rats with T₃ increased the relative abundance of both α1 and β1 Na, K-ATPase subunits in total membranes by 4- to 5-fold (with no change in caveolin-3), and resulted in 1.9-fold increase in enzyme activity. T₃-induced Na, K-ATPase subunits were preferentially distributed to the lighter fractions (#s 4, 5 and 6); and increased abundance of α1 and β1 were 34-70% and 43-68%, respectively. We conclude that the activity of Na, K-ATPase is not uniform in cardiac membranes, and while a significant amount of Na, K-ATPase is present in cardiac cholesterol-rich membrane fractions, the intrinsic activity is significantly less than the enzyme present in relatively cholesterol-poor membranes.     

The distribution of ATPase activities in purified transverse tubular membranes

Vesiculated fragments of transverse tubules (TT) and sarcoplasmic reticulum (SR) membranes were purified from heterogeneous microsomal membrane fractions of chicken breast muscle by a modification of an iterative calcium-oxalate loading technique. The distribution of ATPase activities were determined for the TT and SR and were compared to enriched fractions of sarcolemma (SL) membranes. The TT membranes were characterized by high rates of magnesium-stimulated ATPase (Mg-ATPase) and 5′-nucleotidase activities but were virtually devoid of calcium-stimulated, magnesium-dependent ATPase (Ca,Mg-ATPase) activity. Moderate levels of a latent sodium and potassium-stimulated ATPase (Na,K-ATPase) were observed for TT membranes when unmasked with valinomycin and monensin. In contrast to the behavior of TT membranes, highly purified SR membranes displayed an active Ca,Mg-ATPase but negligible Na,K-ATPase, Mg-ATPase, and 5′-nucleotidase activities. High levels of Na,K-ATPase and 5′-nucleotidase activities were observed for SL membranes; however, the SL displayed no appreciable Ca,Mg-ATPase and Mg-ATPase activities. The lack of significant Mg-ATPase activity in the SR and SL fractions suggested that the Mg-ATPase was uniquely associated with the TT membranes. The TT Mg-ATPase was further characterized by its pH and temperature dependences, and its sensitivity to pharmacologic agents. The Mg-ATPase of the TT was insensitive to inhibition by sodium azide and oligomycin in concentrations shown to exert maximum inhibition on the F₁ ATPase of submitochondrial particles. The Mg-ATPase was also resistant to the effects of ouabain and orthovanadate in concentrations which abolished the Na,K-ATPase and Ca,Mg-ATPase activities of the SL and SR, respectively. The Mg-ATPase displayed temperature and pH optima (25 °C, pH 7.3) which were distinguishable from the Ca,Mg-ATPase (45 °, pH 7.0) of highly purified SR fractions but which were very similar to the temperature and pH dependencies of the mixed microsomal fractions (MMF) from which the TT membranes were derived. Similarities in the pH and temperature dependencies of the TT and MMF Mg-ATPases plus the absence of appreciable Mg-ATPase activity in highly purified SR membranes suggests that the “basic” Mg-ATPase often seen in crude SR fractions may originate from TT membrane contamination. The resistance of the TT Mg-ATPase to inhibition by the pharmacologic agents tested plus its unique temperature and pH dependences indicate that this ATPase is distinguishable from other ATPases and may, therefore, be of value as a specific biochemical marker for TT membranes.     

Analytical isolation of plasma membranes of intestinal epithelial cells: Identification of Na,K-ATPase rich membranes and the distribution of enzyme activities

Summary A procedure was developed for the analytical isolation of brush border and basal lateral plasma membranes of intestinal epithelial cells. Brush border fragments were collected by low speed centrifugation, disrupted in hypertonic sorbitol, and subjected to density gradient centrifugation for separation of plasma membranes from nuclei and cole material. Sucrase specific activity in the purified brush border plasma membrane was increased fortyfold with respect to the initial homogenate. Basal lateral membrane were harvested from the low speed supernatant and resolved from other subcellular components by equilibrium density gradient centrifugation. Recovery of Na, K-ATPase activity was 94%, and 61% of the recovered activity was present in a single symmetrical peak. The specific activity of Na, K-ATPase was increased twelvefold, and it was purified with respect to sucrase, succinic dehydrogenase, NADPH-cytochromec reductase, nonspecific esterase, -glucoronidase, DNA, and RNA. The observed purification factors are comparable to results reported for other purification procedures, and the yield of Na, K-ATPase is greater by a factor of two than those reported for other procedures which produce no net increase in the Na, K-ATPase activity.Na, K-ATPase rich membranes are shown to originate from the basal lateral plasma membranes by the patterns of labeling that were produced when either isolated cells or everted gut sacs were incubated with the slowly permeating reagent³⁵S-p-(diazonium)-benzenesulfonic acid. In the former case subsequently purified Na, K-ATPase rich and sucrase rich membranes are labeled to the same extent, while in the latter there is a tenfold excess of label in the sucrase rich membranes. The plasma membrane fractions were in both cases more heavily labeled than intracellular protein.Alkaline phosphatase and calcium-stimulated ATPase were present at comparable levels on the two aspects of the epithelial cell plasma membrane, and 25% of the acid phosphatase activity was present on the basal lateral membrane, while it was absent from the brush border membrane. Less than 6% of the total Na, K-ATPase was present in brush border membranes.     

Effects of detergents on Na+ + K+-dependent ATPase activity in plasma-membrane fractions prepared from frog muscles. Studies of insulin action on Na+ and K+ transport.

The increase in Na+/K+ transport activity in skeletal muscles exposed to insulin was analysed. Plasma-membrane fractions were prepared from frog (Rana catesbeiana) skeletal muscles, and examination of the Na,K-ATPase (Na+ + K+-dependent ATPase) activity showed that it was insensitive to ouabain. In contrast, plasma-membrane fractions prepared from ouabain-pretreated muscles, by the same procedures, showed extremely low Na,K-ATPase activity. On adding saponin to the membrane suspension, the Na,K-ATPase activity increased, according to the detergent concentration. The maximum activity was about twice the control value, at 0.33 mg of saponin/mg of protein. Thus saponin makes vesicle membranes leaky, allowing ouabain in assay solutions to reach receptors on the inner surface of vesicles. Addition of insulin to saponin-treated membrane suspensions had no effect on the Na,K-ATPase activity, whereas the maximum activity of Na,K-ATPase in whole muscles was stimulated by exposure to insulin. The results show that the stimulation of Na+/K+ transport by insulin is not directly due to insulin binding to receptors on the cell surface, but rather support the view that the increase in the Na,K-ATPase induced by insulin requires an alteration of intracellular events.     

Identification of a phospholemman-like protein from shark rectal glands. Evidence for indirect regulation of Na,K-ATPase by protein kinase c via a novel member of the FXYDY family

The Na,K-ATPase provides the driving force for many ion transport processes through control of Na(+) and K(+) concentration gradients across the plasma membranes of animal cells. It is composed of two subunits, alpha and beta. In many tissues, predominantly in kidney, it is associated with a small ancillary component, the gamma-subunit that plays a modulatory role. A novel 15-kDa protein, sharing considerable homology to the gamma-subunit and to phospholemman (PLM) was identified in purified Na,K-ATPase preparations from rectal glands of the shark Squalus acanthias, but was absent in pig kidney preparations. This PLM-like protein from shark (PLMS) was found to be a substrate for both PKA and PKC. Antibodies to the Na, K-ATPase alpha-subunit coimmunoprecipitated PLMS. Purified PLMS also coimmunoprecipitated with the alpha-subunit of pig kidney Na, K-ATPase, indicating specific association with different alpha-isoforms. Finally, PLMS and the alpha-subunit were expressed in stoichiometric amounts in rectal gland membrane preparations. Incubation of membrane bound Na,K-ATPase with non-solubilizing concentrations of C(12)E(8) resulted in functional dissociation of PLMS from Na,K-ATPase and increased the hydrolytic activity. The same effects were observed after PKC phosphorylation of Na,K-ATPase membrane preparations. Thus, PLMS may function as a modulator of shark Na,K-ATPase in a way resembling the phospholamban regulation of the Ca-ATPase.     

Ouabain-sensitive H,K-ATPase functions as Na,K-ATPase in apical membranes of rat distal colon

Na,K-ATPase activity has been identified in the apical membrane of rat distal colon, whereas ouabain-sensitive and ouabain-insensitive H,K-ATPase activities are localized solely to apical membranes. This study was designed to determine whether apical membrane Na,K-ATPase represented contamination of basolateral membranes or an alternate mode of H,K-ATPase expression. An antibody directed against the H, K-ATPase alpha subunit (HKcalpha) inhibited apical Na,K-ATPase activity by 92% but did not alter basolateral membrane Na,K-ATPase activity. Two distinct H,K-ATPase isoforms exist; one of which, the ouabain-insensitive HKcalpha, has been cloned. Because dietary sodium depletion markedly increases ouabain-insensitive active potassium absorption and HKcalpha mRNA and protein expression, Na, K-ATPase and H,K-ATPase activities and protein expression were determined in apical membranes from control and sodium-depleted rats. Sodium depletion substantially increased ouabain-insensitive H, K-ATPase activity and HKcalpha protein expression by 109-250% but increased ouabain-sensitive Na,K-ATPase and H,K-ATPase activities by only 30% and 42%, respectively. These studies suggest that apical membrane Na,K-ATPase activity is an alternate mode of ouabain-sensitive H,K-ATPase and does not solely represent basolateral membrane contamination.     

Changes in the Na, K-ATPase of neuronal membranes in penicillin-induced epileptic foci in the cerebral cortex of the rat]

The relationship between electrophysiological changes and Na, K-ATPase activity of neuronal membranes in sodium penicillin-induced epileptic foci was studied. Na,K-ATPase activity is inhibited both in the primary focus and in homotopic contralateral area during latent period and in the stage of forming epileptic activity. In the stage of marked convulsive activity Na, K-ATPase is inhibited only in the primary focus. It is shown that penicillin at a concentration range of 2 x 10(-6)--2 x 10(-3) M does not influence Na,K-ATPase activity of crude synaptosomes of the rat brain cortex. It is suggested that Na,K-ATPase inactivation may serve as a pathogenetic factor in the development of convulsive process.     

Cation selectivity of gastric H,K-ATPase and Na,K-ATPase chimeras.

Chimeras of the catalytic subunits of the gastric H,K-ATPase and Na, K-ATPase were constructed and expressed in LLC-PK1 cells. The chimeras included the following: (i) a control, H85N (the first 85 residues comprising the cytoplasmic N terminus of Na,K-ATPase replaced by the analogous region of H,K-ATPase); (ii) H85N/H356-519N (the N-terminal half of the cytoplasmic M4-M5 loop also replaced); and (iii) H519N (the entire front half replaced). The latter two replacements confer a decrease in apparent affinity for extracellular K+. The 356-519 domain and, to a greater extent, the H519N replacement confer increased apparent selectivity for protons relative to Na+ at cytoplasmic sites as shown by the persistence of K+ influx when the proton concentration is increased and the Na+ concentration decreased. The pH and K+ dependence of ouabain-inhibitable ATPase of membranes derived from the transfected cells indicate that the H519N and, to a lesser extent, the H356-519N substitution decrease the effectiveness of K+ to compete for protons at putative cytoplasmic H+ activation sites. Notable pH-independent behavior of H85N/H356-519N at low Na+ suggests that as pH is decreased, Na+/K+ exchange is replaced largely by (Na+ + H+)/K+ exchange. With H519N, the pH and Na+ dependence of pump and ATPase activities suggest relatively active H+/K+ exchange even at neutral pH. Overall, this study provides evidence for important roles in cation selectivity for both the N-terminal half of the M4-M5 loop and the adjacent transmembrane helice(s).