Contrasting effects of the persistent Na+ current on neuronal excitability and spike timing

The persistent Na+ current, INaP, is known to amplify subthreshold oscillations and synaptic potentials, but its impact on action potential generation remains enigmatic. Using computational modeling, whole-cell recording, and dynamic clamp of CA1 hippocampal pyramidal cells in brain slices, we examined how INaP changes the transduction of excitatory current into action potentials. Model simulations predicted that INaP increases afterhyperpolarizations, and, although it increases excitability by reducing rheobase, INaP also reduces the gain in discharge frequency in response to depolarizing current (f/I gain). These predictions were experimentally confirmed by using dynamic clamp, thus circumventing the longstanding problem that INaP cannot be selectively blocked. Furthermore, we found that INaP increased firing regularity in response to sustained depolarization, although it decreased spike time precision in response to single evoked EPSPs. Finally, model simulations demonstrated that I(NaP) increased the relative refractory period and decreased interspike-interval variability under conditions resembling an active network in vivo.     

Interaction between the basolateral K+ and apical Na+ conductances in Necturus urinary bladder

Experimental modulation of the apical membrane Na+ conductance or basolateral membrane Na+-K+ pump activity has been shown to result in parallel changes in the basolateral K+ conductance in a number of epithelia. To determine whether modulation of the basolateral K+ conductance would result in parallel changes in apical Na+ conductance and basolateral pump activity, Necturus urinary bladders stripped of serosal muscle and connective tissue were impaled through their basolateral membranes with microelectrodes in experiments that allowed rapid serosal solution changes. Exposure of the basolateral membrane to the K+ channel blockers Ba2+ (0.5 mM/liter), Cs+ (10 mM/liter), or Rb+ (10 mM/liter) increased the basolateral resistance (Rb) by greater than 75% in each case. The increases in Rb were accompanied simultaneously by significant increases in apical resistance (Ra) of greater than 20% and decreases in transepithelial Na+ transport. The increases in Ra, measured as slope resistances, cannot be attributed to nonlinearity of the I-V relationship of the apical membrane, since the measured cell membrane potentials with the K+ channel blockers present were not significantly different from those resulting from increasing serosal K+, a maneuver that did not affect Ra. Thus, blocking the K+ conductance causes a reduction in net Na+ transport by reducing K+ exit from the cell and simultaneously reducing Na+ entry into the cell. Close correlations between the calculated short-circuit current and the apical and basolateral conductances were preserved after the basolateral K+ conductance pathways had been blocked. Thus, the interaction between the basolateral and apical conductances revealed by blocking the basolateral K+ channels is part of a network of feedback relationships that normally serves to maintain cellular homeostasis during changes in the rate of transepithelial Na+ transport.     

Intracellular Na+ and K+ activities and membrane conductances in the collecting tubule of Amphiuma

Membrane potentials and conductances, and intracellular ionic activities were studied in isolated perfused collecting tubules of K+-adapted Amphiuma. Intracellular Na+ (aNai) and K+ (aKi) activities were measured, using liquid ion-exchanger double-barreled microelectrodes. Apical and basolateral membrane conductances were estimated by cable analysis. The effects of inhibition of the apical conductance by amiloride (10(-5) M) and of inhibition of the basolateral Na-K pump by either a low K+ (0.1 mM) bath or by ouabain (10(-4) M) were studied. Under control conditions, aNai was 8.4 +/- 1.9 mM and aKi 56 +/- 3 mM. With luminal amiloride, aNai decreased to 2.2 +/- 0.4 mM and aKi increased to 66 +/- 3 mM. Ouabain produced an increase of aNai to 44 +/- 4 mM, and a decrease of aKi to 22 +/- 6, and similar changes were observed when the tubule was exposed to a low K+ bath solution. During pump inhibition, there was a progressive decrease of the K+-selective basolateral membrane conductance and of the Na+ permeability of the apical membrane. A similar inhibition of both membrane conductances was observed after pump inhibition by low K+ solution. Upon reintroduction of K+, a basolateral membrane hyperpolarization of -23 +/- 4 mV was observed, indicating an immediate reactivation of the electrogenic Na-K pump. However, the recovery of the membrane conductances occurred over a slower time course. These data imply that both membrane conductances are regulated according to the intracellular ionic composition, but that the basolateral K+ conductance is not directly linked to the pump activity.     

Determination of epithelial Na+ channel subunit stoichiometry from single-channel conductances

The epithelial Na(+) channel (ENaC) is a multimeric membrane protein consisting of three subunits, alpha, beta, and gamma. The total number of subunits per functional channel complex has been described variously to follow either a tetrameric arrangement of 2alpha:1beta:1gamma or a higher-ordered stoichiometry of 3alpha:3beta:3gamma. Therefore, while it is clear that all three ENaC subunits are required for full channel activity, the number of the subunits required remains controversial. We used a new approach, based on single-channel measurements in Xenopus oocytes to address this issue. Individual mutations that alter single-channel conductance were made in pore-lining residues of ENaC alpha, beta, or gamma subunits. Recordings from patches in oocytes expressing a single species, wild type or mutant, of alpha, beta, and gamma showed a well-defined current transition amplitude with a single Gaussian distribution. When cRNAs for all three wild-type subunits were mixed with an equimolar amount of a mutant alpha-subunit (either S589D or S592T), amplitudes corresponding to pure wild-type or mutant conductances could be observed in the same patch, along with a third intermediate amplitude most likely arising from channels with at least one wild-type and at least 1 mutant alpha-subunit. However, intermediate or hybrid conductances were not observed with coexpression of wild-type and mutant betaG529A or gammaG534E subunits. Our results support a tetrameric arrangement of ENaC subunits where 2alpha, 1beta, and 1gamma come together around central pore.     

Apical plasma membrane vesicles formed from organ donor colon demonstrate Na+ and H+ conductances and Na+/H+ exchange

Apical plasma membrane vesicles were prepared from human organ donor colon mucosal scrapings. These vesicles were enriched 10-fold in cysteine-sensitive alkaline phosphatase activity compared to starting homogenates, and showed minimal contamination of microsomal, mitochondrial or basolateral membranes. Transport studies using [22Na] uptake into proximal colonic vesicles demonstrated Na+ and H+ conductances, Na+/H+ exchange and amiloride inhibition of Na+ uptake. The isolation of these apical vesicles will permit detailed study of human colonic transport processes.     

Intracellular pH controls cell membrane Na+ and K+ conductances and transport in frog skin epithelium

We determined the effects of intracellular respiratory and metabolic acid or alkali loads, at constant or variable external pH, on the apical membrane Na+-specific conductance (ga) and basolateral membrane conductance (gb), principally due to K+, in the short-circuited isolated frog skin epithelium. Conductances were determined from the current-voltage relations of the amiloride-inhibitable cellular current pathway, and intracellular pH (pHi) was measured using double barreled H+-sensitive microelectrodes. The experimental set up permitted simultaneous recording of conductances and pHi from the same epithelial cell. We found that due to the asymmetric permeability properties of apical and basolateral cell membranes to HCO3- and NH+4, the direction of the variations in pHi was dependent on the side of addition of the acid or alkali load. Specifically, changing from control Ringer, gassed in air without HCO3- (pHo = 7.4), to one containing 25 mmol/liter HCO3- that was gassed in 5% CO2 (pHo = 7.4) on the apical side caused a rapid intracellular acidification whereas when this maneuver was performed from the basolateral side of the epithelium a slight intracellular alkalinization was produced. The addition of 15 mmol/liter NH4Cl to control Ringer on the apical side caused an immediate intracellular alkalinization that lasted up to 30 min; subsequent removal of NH4Cl resulted in a reversible fall in pHi, whereas basolateral addition of NH4Cl produced a prolonged intracellular acidosis. Using these maneouvres to change pHi we found that the transepithelial Na+ transport rate (Isc), and ga, and gb were increased by an intracellular alkalinization and decreased by an acid shift in pHi. These variations in Isc, ga, and gb with changing pHi occurred simultaneously, instantaneously, and in parallel even upon small perturbations of pHi (range, 7.1-7.4). Taken together these results indicate that pHi may act as an intrinsic regulator of epithelial ion transport.     

Cytoplasmic K+ effects on phosphoenzyme of Na,K-ATPase proteoliposomes and on the Na+-pump activity

Three phosphorylated reaction intermediates (EP) of Na,K-ATPase, and ADP-sensitive K+-insensitive EP (E1P), an ADP- and K+-sensitive EP (E*P), and a K+-sensitive ADP-insensitive EP (E2P), have been discovered at present. By using Na,K-ATPase proteoliposomes (PL) prepared from the electric eel enzyme, we found in this study that E*P existed even in the presence of K+ on both sides of the PL and that there was a sidedness difference in K+ sites between E*P and E2P. Cytoplasmic K+ (K+cyt) accelerated the conversion of E*P to E2P but did not dephosphorylate the E2P. Although the extracellular K+ accelerated the dephosphorylation of E2P, it did not interact with E*P directly. This K+cyt effect was also verified by the activation of Na+-pump in the Na+-K+ exchange mode. In the presence of K+cyt, both the ATP hydrolysis and Na+ uptake rates of the PL containing K+ inside vesicles increased sigmoidally with the concentrations of ATP and cytoplasmic Na+ (Na+cyt). However, in the absence of K+cyt, these Na+-pump reactions in PL containing K+ inside vesicles had only a hyperbolic curve. These results imply that the E*P to E2P conversion is one of the rate-limiting steps of the Na+-pump in the presence of a high concentration of ATP and that K+cyt may control this reaction step by enhancing the conversion rate of E*P to E2P.     

The regulation of selective and nonselective Na+ conductances in H441 human airway epithelial cells

Analysis of membrane currents recorded from hormone-deprived H441 cells showed that the membrane potential (V(m)) in single cells (approximately -80 mV) was unaffected by lowering [Na+]o or [Cl(-)]o, indicating that cellular Na+ and Cl(-) conductances (GNa and GCl, respectively) are negligible. Although insulin (20 nM, approximately 24 h) and dexamethasone (0.2 microM, approximately 24 h) both depolarized Vm by approximately 20 mV, the response to insulin reflected a rise in GCl mediated via phosphatidylinositol 3-kinase (PI3K) whereas dexamethasone acted by inducing a serum- and glucocorticoid-regulated kinase 1 (SGK1)-dependent rise in GNa. Although insulin stimulation/PI3K-P110 alpha expression did not directly increase GNa, these maneuvers augmented the dexamethasone-induced conductance. The glucocorticoid/SGK1-induced GNa in single cells discriminated poorly between Na+ and K+ (PNa/PK approximately 0.6), was insensitive to amiloride (1 mM), but was partially blocked by LaCl3 (La3+; 1 mM, approximately 80%), pimozide (0.1 mM, approximately 40%), and dichlorobenzamil (15 microM, approximately 15%). Cells growing as small groups, on the other hand, expressed an amiloride-sensitive (10 microM), selective GNa that displayed the same pattern of hormonal regulation as the nonselective conductance in single cells. These data therefore 1) confirm that H441 cells can express selective or nonselective GNa (14, 48), 2) show that these conductances are both induced by glucocorticoids/SGK1 and subject to PI3K-dependent regulation, and 3) establish that cell-cell contact is vitally important to the development of Na+ selectivity and amiloride sensitivity.     

Na,K-ATPase and the development of Na+ transport in rat distal colon

Summary Na, K-ATPase function was studied in order to evaluate the mechanism of increased colonic Na⁺ transport during early postnatal development. The maximum Na⁺-pumping activity that was represented by the equivalent short-circuit current after addition of nystatin (I _sc ^N ) did not change during postnatal life or after adrenalectomy performed in 16-day-old rats.I _sc ^N was entirely inhibited by ouabain; the inhibitory constant was 0.1mm in 10-day-old (young) and 0.4mm in 90-day-old (adult) rats. The affinity of the Na, K pump for Na⁺ was higher in young (11mm) than in adult animals (19mm). The Na, K-ATPase activity (measured after unmasking of latent activity by treatment with sodium dodecylsulfate) increased during development and was also not influenced by adrenalectomy of 16-day-old rats. The inhibitory constant for ouabain (K _I ) was not changed during development (0.1–0.3mm). Specific [³H]ouabain binding to isolated colonocytes increased during development (19 and 82 pmol/mg protein), the dissociation constant (K _D ) was 8 and 21 m in young and adult rats, respectively. The Na⁺ turnover rate per single Na, K pump, which was calculated fromI _sc ^N and estimated density of binding sites per cm² of tissue was 500 in adult and 6400 Na⁺/min·site in young rats. These data indicate that the very high Na⁺ transport during early postnatal life reflects an elevated turnover rate and increased affinity for Na⁺ of a single isoform of the Na, K pump. The development of Na⁺ extrusion across the basolateral membrane is not directly regulated by corticosteroids.     

Regulation of paracellular Na and Cl conductances by hydrostatic pressure

The effect of hydrostatic pressure on the paracellular ion conductance (Gp) composed of the Na⁺ conductance (G_Na) and the Cl⁻ conductance (G_Cl) has been Investigated. Gp, G_Na and G_Cl were time-dependently increased after applying an osmotic gradient generated by NaCl with basolateral hypotonicity. Hydrostatic pressure (1-4 cm H₂O) applied from the basolateral side enhanced the osmotic gradient-induced increase in Gp, G_Na and G_Cl in a magnitude-dependent manner, while the hydrostatic pressure applied from the apical side diminished the osmotic gradient-induced increase in Gp, G_Na and G_Cl. How the hydrostatic pressure influences Gp, G_Na and G_Cl under an isosmotic condition was also investigated. Gp, G_Na and G_Cl were stably constant under a condition with basolateral application of sucrose canceling the NaCl-generated osmotic gradient (an isotonic condition). Even under this stable condition, the basolaterally applied hydrostatic pressure drastically elevated Gp, G_Na and G_Cl, while apically applied hydrostatic pressure had little effect on Gp, G_Na or G_Cl. Taken together, these observations suggest that certain factors controlled by the basolateral osmolality and the basolaterally applied hydrostatic pressure mainly regulate the Gp, G_Na and G_Cl.     

Multiple conductances in the large K+ channel from Chara corallina shown by a transient analysis method.

The large conductance K+ channel in the tonoplast of Chara corallina has subconductance states (substates). We describe a method that detects substates by monitoring the time derivative of channel current. Substates near to the full conductance tend to have long durations and high probabilities, while those of smaller amplitude occur with less probability and short duration. The substate pattern is similar in cell-attached, inside-out and outside-out patches over a range of temperatures. The pattern changes at high Ca2+ concentration (10 mol m-3) on the cytoplasmic face of inside-out patches. One substate at approximately 50% of the full conductance is characterized by a high frequency of transitions from the full conductance level. This midstate conductance is not a constant proportion of the full conductance but changes as a function of membrane potential difference (p.d.) showing strong inward rectification. We suggest that the channel is a single pore that can change conformation and/or charge profile to give different conductances. The mean durations of the full conductance level and the midstate decrease as the membrane p.d. becomes more negative. Programs for analysis of channel kinetics based on an half-amplitude detection criterion are shown to be unsuitable for analysis of the K+ channel.     

Regulation of the paracellular Na+ and Cl- conductances by the NaCl-generated osmotic gradient in a manner dependent on the direction of osmotic gradients

In the present study, we investigated the effect of osmolality on the paracellular ion conductance (Gp) composed of the Na⁺ conductance (G_Na) and the Cl⁻ conductance (G_Cl). An osmotic gradient generated by NaCl with relatively apical hypertonicity (NaCl-absorption-direction) induced a large increase in the G_Na associated with a small increase in the G_Cl, whereas an osmotic gradient generated by NaCl with relatively basolateral hypertonicity (NaCl-secretion-direction) induced small increases in the G_Na and the G_Cl. These increases in the Gp caused by NaCl-generated osmotic gradients were diminished by the application of sucrose canceling the NaCl-generated osmotic gradient. The osmotic gradient generated by basolateral application of sucrose without any NaCl gradients had little effects on the Gp. However, this basolateral application of sucrose produced a precondition drastically quickening the time course of the action of the NaCl-generated osmotic gradient on the Gp. Further, we found that application of the basolateral hypotonicity generated by reduction of NaCl concentration shifted the localization of claudin-1 to the apical from the basolateral side. These results indicate that the osmotic gradient regulates the paracellular ion conductive pathway of tight junctions via a mechanism dependent on the direction of NaCl gradients associated with a shift of claudin-1 localization to the apical side in renal A6 epithelial cells.     

The sided action of Na+ on reconstituted shark Na+/K+-ATPase engaged in Na+-Na+ exchange accompanied by ATP hydrolysis. II. Transmembrane allosteric effects on Na+ affinity

The objective of the present investigation was to characterize the ATP-dependent Na+-Na+ exchange, with respect to cation sensitivity on the two aspects of the Na+/K+-pump protein. In order to accomplish this, we used Na+/K+-ATPase reconstituted with known orientation in the proteoliposomes. Activation by cytoplasmic Na+ shows cooperative interaction between three sites. The apparent intrinsic site constants displayed transmembrane dependence on the extracellular Na+ concentration. However, the apparent K0.5 for cytoplasmic Na+ is independent of the extracellular Na+ concentration. The activation by extracellular Na+ at a fixed cytoplasmic Na+ concentration is biphasic with a component which saturates at a concentration of about 1-2 mM extracellular Na+, a plateau phase up to 20 mM, and another component which tends to saturate at about 80 mM followed by a slight deactivation at higher concentrations of Na+. The apparent K0.5 value for extracellular Na+ is also found to be independent of the Na+ concentration on the opposite side of the membrane. The activation by extracellular Na+ can be explained by the negative cooperativity in the binding of extracellular Na+, but positive cooperativity in the rate of dephosphorylation of enzyme species with one and three sodium ions bound extracellularly. Na+ bound to E2-PNa has a transmembrane effect on the cooperativity between binding of cytoplasmic Na+, and E2-PNa2 does not dephosphorylate. K0.5/Vm for cytoplasmic as well as for extracellular Na+ decreases with an increase in the trans Na+ concentration in the non-saturating concentration range. The experiments indicate that at a step in the reaction simultaneous binding of extracellular and cytoplasmic Na+ occurs.     

Impairment of Na+/H+ exchange underlies inhibitory effects of Na+-free media on leukocyte function

Inhibition of activation has been reported when neutrophils are suspended in Na+-free media. We considered the possibility that impairment of cellular pH (pHi) regulation due to elimination of Na+/H+ exchange underlies this effect. In the absence of Na+, the phorbol ester-induced respiratory burst was partially inhibited and a concomitant cytoplasmic acidification recorded. Using nigericin/K+ to clamp pHi we demonstrated that the acidification accounts for the inhibition of O2 uptake. Moreover, in Na+-free media, relieving the acidification by means of ionophores restored maximal O2 consumption. It was concluded that Na+ is not directly involved in signal transduction during stimulation. Instead, omission of Na+ affects neutrophils activation indirectly, by impairing pHi regulation.     

The effects of external K+ and Na+ on the chemotaxis of rabbit peritoneal neutrophils.

Extracellular K+ enhances the chemotactic responsiveness and spontaneous movememt of rabbit peritoneal neutrophils but is not required for these functions. Other monovalent cations act the same; the rank order of their effectiveness is K+ = NH4 greater than Rb+ Cs+ greater than Li = Na. The K+ specific ionophore, valinomycin (10-7 M) inhances chemotaxis in the presence of K+ but not in its absence; another K+ specific ionophore, nigericin (10-7 M) inhibits chemotaxis in the absence of K+ but not in its presence. Ouabain (5 x 10-6 M) prevents the enhancing effects of K+ on chemotaxis. Removing the Na+ of the buffer and substituting it with K+, choline or glucose greatly enhances spontaneous motility but depresses chemotactic activity. One hypothesis suggested by the above results is that as a part of their action, chemotactic factors stimulate a net influx of K+ into the neutrophil; an alternative or additional hypothesis is that chemotactic factors stimulate a net efflux of Na+ from the neutrophil.     

The effects of several ligands on the potassium-vanadate interaction in the inhibition of the (Na+ + K+)-ATPase and the Na+, K+ pump

Inhibition by vanadate of the K+-dependent p-nitrophenylphosphatase activity catalyzed by the (Na+ + K+)-ATPase partially purified from pig kidney showed competitive behavior with the substrate, K+ and Mg2+ acted as cofactors in promoting that inhibition. Ligands which inhibited the K+-dependent p-nitrophenyl phosphate hydrolysis (Na+, nucleotide polyphosphates, inorganic phosphate) protected against inhibition by vanadate. The magnitude of that protection was proportional to the inhibition produced in the absence of vanadate. In the presence of only p-nitrophenyl phosphate and Mg2+, or when the protective ligands were tested alone, the activation of p-nitrophenyl phosphate hydrolysis by K+ followed a sigmoid curve in the presence as well in the absence of vanadate. However, the combination of 100 mM NaCl and 3 mM ATP resulted in a biphasic effect of K+ on the p-nitrophenyl phosphate hydrolysis in the presence of vanadate. After an initial rise at low K+ concentration, the p-nitrophenylphosphatase activity declined at high K+ concentrations; this decline became more pronounced as the vanadate concentration was increased. This biphasic response was not seen when a nonphosphorylating ATP analog was combined with Na+ (which favors the nucleotide binding) or with inorganic phosphate (a requirement for K+ - K+ exchange). Experiments with inside-out resealed vesicles from human red cells showed that in the absence of Na+ plus ATP, K+ promoted vanadate inhibition of p-nitrophenylphosphatase activity in a nonbiphasic manner, acting at cytoplasmic sites. On the other hand, in the presence of Na+ plus ATP, the biphasic response of p-nitrophenyl phosphate hydrolysis is due to K+ acting on extracellular sites. In vanadate-poisoned intact red blood cells, the biphasic response of the ouabain-sensitive Rb+ influx as a function of the external Rb+ concentration failed to develop when there was no Na+ in the extracellular media. In addition, in the absence of extracellular Na+, external Rb+ did not influence the magnitude of inhibition. The present findings indicate that external K+ favors vanadate inhibition by displacing Na+ from unspecified extracellular membrane sites.     

Contrasting effects of cPLA2 on epithelial Na+ transport

Activity of the epithelial Na+ channel (ENaC) is the limiting step for discretionary Na+ reabsorption in the cortical collecting duct. Xenopus laevis kidney A6 cells were used to investigate the effects of cytosolic phospholipase A2 (cPLA2) activity on Na+ transport. Application of aristolochic acid, a cPLA2 inhibitor, to the apical membrane of monolayers produced a decrease in apical [3H]arachidonic acid (AA) release and led to an approximate twofold increase in transepithelial Na+ current. Increased current was abolished by the nonmetabolized AA analog 5,8,11,14-eicosatetraynoic acid (ETYA), suggesting that AA, rather than one of its metabolic products, affected current. In single channel studies, ETYA produced a decrease in ENaC open probability. This suggests that cPLA2 is tonically active in A6 cells and that the end effect of liberated AA at the apical membrane is to reduce Na+ transport via actions on ENaC. In contrast, aristolochic acid applied basolaterally inhibited current, and the effect was not reversed by ETYA. Basolateral application of the cyclooxygenase inhibitor ibuprofen also inhibited current. Both effects were reversed by prostaglandin E2 (PGE2). This suggests that cPLA2 activity and free AA, which is metabolized to PGE2, are necessary to support transport. This study supports the fine-tuning of Na+ transport and reabsorption through the regulation of free AA and AA metabolism.     

Solvent effects on substrate and phosphate interactions with the (Na+ + K+)-ATPase

(Na+ + K+)-ATPase activity of a dog kidney enzyme preparation was markedly inhibited by 10-30% (v/v) dimethyl sulfoxide (Me2SO) and ethylene glycol (Et(OH)2); moreover, Me2SO produced a pattern of uncompetitive inhibition toward ATP. However, K+-nitrophenylphosphatase activity was stimulated by 10-20% Me2SO and Et(OH)2 but was inhibited by 30-50%. Me2SO decreased the Km for this substrate but had little effect on the Vmax below 30% (at which concentration Vmax was then reduced). Me2SO also reduced the Ki for Pi and acetyl phosphate as competitors toward nitrophenyl phosphate but increased the Ki for ATP, CTP and 2-O-methylfluorescein phosphate as competitors. Me2SO inhibited K+-acetylphosphatase activity, although it also reduced the Km for that substrate. Finally, Me2SO increased the rate of enzyme inactivation by fluoride and beryllium. These observations are interpreted in terms of the E1P to E2P transition of the reaction sequence being associated with an increased hydrophobicity of the active site, and of Me2SO mimicking such effects by decreasing water activity: (i) primarily to stabilize the covalent E2P intermediate, through differential solvation of reactants and products, and thereby inhibiting the (Na+ + K+)-ATPase reaction and acting as a dead-end inhibitor to produce the pattern of uncompetitive inhibition; inhibiting the K+-acetylphosphatase reaction that also passes through an E2P intermediate; but not inhibiting (at lower Me2SO concentrations) the K+-nitrophenylphosphatase reaction that does not pass through such an intermediate; and (ii) secondarily to favor partitioning of Pi and non-nucleotide phosphates into the hydrophobic active site, thereby decreasing the Km for nitrophenyl phosphate and acetyl phosphate, the Ki for Pi and acetyl phosphate in the K+-nitrophenylphosphatase reaction, accelerating inactivation by fluoride and beryllium acting as phosphate analogs, and, at higher concentrations, inhibiting the K+-nitrophenylphosphatase reaction by stabilizing the non-covalent E2.P intermediate of that reaction. In addition, Me2SO may decrease binding at the adenine pocket of the low-affinity substrate site, represented as an increased Ki for ATP, CTP and 3-O-methylfluorescein phosphate.     

Mechanisms of detergent effects on membrane-bound (Na+ + K+)-ATPase

Because the nonionic detergent octaethylene glycol dodecyl ether has been used extensively for studies on active solubilized preparations of (Na+ + K+)-ATPase, we tried to see if the detergent alters the properties of the membrane-bound enzyme prior to solubilization. Addition of the detergent, at concentrations below its critical micellar concentration, to reaction mixtures containing the highly purified membrane-bound enzyme reduced the K0.5 of ATP for (Na+ + K+)-dependent ATPase activity without affecting the maximal velocity or abolishing the negative cooperativity of the substrate-velocity curve. Under these conditions, however, the enzyme was not solubilized as evidenced by complete sedimentation of the membrane fragments containing the enzyme upon centrifugation at 100,000 X g for 30 min. Other nonsolubilizing effects of the detergent included an increase in K0.5 of K+, inhibition of Na+-dependent ATPase with no effect on K0.5 of ATP for this activity, and reductions in the spontaneous decomposition rates of the K+-sensitive phosphoenzyme obtained from ATP and the phosphoenzyme obtained from Pi. The nonsolubilizing effects of the detergent on the purified enzyme were obtained with no detectable lag, were readily reversible, and could be distinguished from its vesicle-opening effects on crude membrane preparations. Several other nonionic and ionic detergents had similar effects on the enzyme. The findings indicate (a) detergent binding to hydrophobic sites on extramembranous segments of enzyme subunits; (b) that occupation of these sites mimics the effects of ATP at a low-affinity regulatory site with no effect on high-affinity ATP binding to the catalytic site; and (c) that in studies on detergent-solubilized preparations, it is necessary to distinguish between the effects of solubilization per se and detergent effects at the regulatory site.