Role of the furosemide-sensitive Na+/K+ transport system in determining the steady-state Na+ and K+ content and volume of human erythrocytesin vitro andin vivo

Summary To study the physiological role of the bidirectionally operating, furosemide-sensitive Na⁺/K⁺ transport system of human erythrocytes, the effect of furosemide on red cell cation and hemoglobin content was determined in cells incubated for 24 hr with ouabain in 145mm NaCl media containing 0 to 10mm K⁺ or Rb⁺. In pure Na⁺ media, furosemide accelerated cell Na⁺ gain and retarded cellular K⁺ loss. External K⁺ (5mm) had an effect similar to furosemide and markedly reduced the action of the drug on cellular cation content. External Rb⁺ accelerated the Na⁺ gain like K⁺, but did not affect the K⁺ retention induced by furosemide. The data are interpreted to indicate that the furosemide-sensitive Na⁺/K⁺ transport system of human erythrocytes mediates an equimolar extrusion of Na⁺ and K⁺ in Na⁺ media (Na⁺/K⁺ cotransport), a 1:1 K⁺/K⁺ (K⁺/Rb⁺) and Na⁺/Na⁺ exchange progressively appearing upon increasing external K⁺ (Rb⁺) concentrations to 5mm. The effect of furosemide (or external K⁺/Rb⁺) on cation contents was associated with a prevention of the cell shrinkage seen in pure Na⁺ media, or with a cell swelling, indicating that the furosemide-sensitive Na⁺/K⁺ transport system is involved in the control of cell volume of human erythrocytes. The action of furosemide on cellular volume and cation content tended to disappear at 5mm external K⁺ or Rb⁺. Thein vivo red cell K⁺ content was negatively correlated to the rate of furosemide-sensitive K⁺ (Rb⁺) uptake, and a positive correlation was seen between mean cellular hemoglobin content and furosemide-sensitive transport activity. The transport system possibly functions as a K⁺ and waterextruding mechanism under physiological conditiosin vivo. The red cell Na⁺ content showed no correlation to the activity of the furosemide-sensitive transport system.     

A study on Na+-coupled oxidative phosphorylation: ATP formation supported by artificially imposed ΔpNa and ΔpK inVibrio alginolyticus cells

Addition of Na⁺ to the K⁺-loadedVibrio alginolyticus cells, creating a 250-fold Na⁺ gradient, is shown to induce a transient increase in the intracellular ATP concentration, which is abolished by the Na⁺/H⁺ antiporter, monensin. The pNa-supported ATP synthesis requires an additional driving force supplied by endogenous respiration or, alternatively, by a K⁺ gradient (high [K⁺] inside). In the former case, ATP formation is resistant to the protonophorous uncoupler. Dicyclohexylcarbodiimide and diethylstilbestrol, but not vanadate, completely inhibit Na⁺ pulse-induced ATP formation. The data agree with the assumption that Na⁺-ATP-synthase is involved in oxidative phosphorylation inV. alginolyticus. Interrelation of H⁺ and Na⁺ cycles in bacteria is discussed.Abbreviations and electrochemical gradients of H⁺ and Na⁺, respectively - transmembrane electric potential difference - pH, pNa, and pK concentration gradients of H⁺, Na⁺, and K⁺, respectively - CCCP carbonyl cyanidem-chlorophenylhydrazone - DCCD N,N-dicyclohexylcarbodiimide - DES diesthylstilbestrol - HQNO 2-heptyl-4-hydroxyquinolineN-oxide - Tricine N[2-hydroxy-1,1-bis(hydroxymethyl)ethyl]glycine     

Apical sodium entry in split frog skin: Current-voltage relationship

Summary Apical Na⁺ entry into frog skin epithelium is widely presumed to be electrodiffusive in nature, as for other tight epithelia. However, in contrast to rabbit descending colon andNecturus urinary bladder, the constant field equation has been reported to fit the apical sodium current (N _Na)-membrane potential (^mc) relationship over only a narrow range of apical membrane potentials or to be inapplicable altogether. We have re-examined this issue by impaling split frog skins across the basolateral membrane and examining the current-voltage relationships at extremely early endpoints in time after initiating pulses of constant transepithelial voltage. In this study, the rapid transient responses in ^mc were completed within 0.5 to 3.5 msec. Using endpoints to 1 to 25 msec, the Goldman equation provided excellent fits of the data over large ranges in apical potential of 300 to 420 mV, from approximately –200 to about +145 mV (cell relative to mucosa). Split skins were also studied when superfused with high serosal K⁺ in order to determine whether theI _Na-^mc relationship could be generated purely by transepithelial measurements. Under these conditions, the basolateral membrane potential was found to be –10±3 mV (cell relative to serosa, mean±se), the basolateral fractional resistance was greater than zero, and the transepithelial current was markedly and reversibly reduced. For these reasons, use of high serosal K⁺ is considered inadvisable for determining theI _Na-^mc relationship, at least in those tissues (such as frog skin) where more direct measurements are technically feasible. Analysis of theI _Na-^mc relationships under baseline conditions provided estimates of intracellular Na⁺ concentration and of apical Na⁺ permeability of 9 to 14mm and of 3 × 10^–7 cm · sec^–1, respectively, in reasonable agreement with estimates obtained by different techniques.     

K+ transport in ‘Tight’ epithelial monolayers of MDCK cells

Summary Bidirectional transepithelial K⁺ flux measurements across high-resistance epithelial monolayers of MDCK cells grown upon millipore filters show no significant net K⁺ flux.Measurements of influx and efflux across the basal-lateral and apical cell membranes demonstrate that the apical membranes are effectively impermeable to K⁺.K⁺ influx across the basal-lateral cell membranes consists of an ouabain-sensitive component, an ouabain-insensitive component, an ouabain-insensitive but furosemide-sensitive component, and an ouabain-and furosemide-insensitive component.The action of furosemide upon K⁺ influx is independent of (Na⁺–K⁺)-pump inhibition. The furosemide-sensitive component is markedly dependent upon the medium K⁺, Na⁺ and Cl^– content. Acetate and nitrate are ineffective substitutes for Cl^–, whereas Br^– is partially effective. Partial Cl^– replacement by NO₃ gives a roughly linear increase in the furosemide-sensitive component. Na⁺ replacement by choline abolishes the furosemide-sensitive component, whereas Li⁺ is a partially effective replacement. Partial Na⁺ replacement with choline gives an apparent affinity of 7mm Na, whereas variation of the external K⁺ content gives an affinity of the furosemide-sensitive component of 1.0mm.Furosemide inhibition is of high affinity (K _1/2=3 m). Piretanide, ethacrynic acid, and phloretin inhibit the same component of passive K⁺ influx as furosemide; amiloride, 4,-aminopyridine, and 2,4,6-triaminopyrimidine partially so. SITS was ineffective.Externally applied furosemide and Cl^– replacement by NO ₃ ^– inhibit K⁺ efflux across the basal-lateral membranes indicating that the furosemide-sensitive component consists primarily of KK exchange.     

Stimulation of human cheek cell Na+/H+ antiporter activity by saliva and salivary electrolytes: amplification by nigericin

Proton-dependent, ethylisopropylamiloride (EIPA)-sensitive Na⁺ uptake (Na⁺/H⁺ antiporter) studies were performed to examine if saliva, and ionophores which alter cellular electrolyte balance, could influence the activity of the cheek cell Na⁺/H⁺ antiporter. Using the standard conditions of 1 mmol/1 Na⁺, and a 65:1 (inside:outside) proton gradient in the assay, the uniport ionophores valinomycin (K⁺) and gramicidin (Na⁺) increased EIPA-sensitive Na⁺ uptake by 177% (p < 0.01) and 227% (p < 0.01), respectively. The dual antiporter ionophore nigericin (K⁺-H⁺) increased EIPA-sensitive Na⁺ uptake by 654% (p < 0.01), with maximal Na⁺ uptake achieved by 1 min and at an ionophore concentration of 50 mol/l, with an EC ₅₀ value 6.4 mol/l. Preincubation of cheek cells with saliva or the low molecular weight (MW) components of saliva (saliva activating factors, SAF) for 2 h at 37°C, also significantly stimulated EIPA-sensitive Na⁺ uptake. This stimulation could be mimicked by pre-incubation with 25 mmol/l KCl or K⁺-phosphate buffer. Pre-incubating cheek cells with SAF and the inclusion of 20 mol/1 nigericin in the assay, produced maximum EIPA-sensitive Na⁺ uptake. After pre-incubation with water, 25 mmol/1 K⁺-phosphate or SAF, with nigericin in all assays, the initial rate of proton-gradient dependent, EIPA-sensitive Na⁺ uptake was saturable with respect to external Na⁺ with K_m values of 0.9, 1.7, and 1.8 mmol/l, and V _max values of 13.4, 25.8, and 31.1 nmol/mg protein/30 sec, respectively. With 20 mol/1 nigericin in the assay, Na⁺ uptake was inhibited by either increasing the [K⁺]_o in the assay, with an ID ₅₀ of 3 mmol/l. These results indicate that nigericin can facilitate K⁺ _i exchange for H⁺ _o and the attending re-acidification of the cheek cell amplifies IINa+ uptake via the Na⁺/H⁺ antiporter. The degree of stimulation of proton-dependent, EIPA-sensitive Na⁺ uptake is therefore dependent, in part, on the intracellular K⁺ _i.     

Effect of Extracellular pH on Presteady-State and Steady-State Current Mediated bythe Na<Superscript>+</Superscript>/K<Superscript>+</Superscript> Pump

A ouabain sensitive inward current occurs in Xenopus oocytes in Na⁺ and K⁺ -free solutions. Several laboratories have investigated the properties of this current and suggested that acidic extracellular pH (pH_o) produces a conducting pathway through the Na⁺/K⁺ pump that is permeable to H⁺ and blocked by [Na⁺]_o. An alternative suggestion is that the current is mediated by an electrogenic H⁺-ATPase. Here we investigate the effect of pH_o and [Na⁺]_o on both transient and steady-state ouabain-sensitive current. At alkaline or neutral pH_o the relaxation rate of pre-steady-state current is an exponential function of voltage. Its U-shaped voltage dependence becomes apparent at acidic pH_o, as predicted by a model in which protonation of the Na⁺/K⁺ pump reduces the energy barrier between the internal solution and the Na⁺ occluded state. The model also predicts that acidic pH_o increases steady-state current leak through the pump. The apparent pK of the titratable group(s) is 6, suggesting that histidine is involved in induction of the conductance pathway. ²²Na efflux experiments in squid giant axon and current measurements in oocytes at acidic pH_o suggest that both Na⁺ and H⁺ are permeant. The acid-induced inward current is reduced by high [Na⁺]_o, consistent with block by Na⁺. A least squares analysis predicts that H⁺ is four orders of magnitude more permeant than Na⁺, and that block occurs when 3 Na⁺ ions occupy a low affinity binding site (K _0.5=130±30 mM) with a dielectric coefficient of 0.23±0.03. These data support the conclusion that the ouabain-sensitive conducting pathway is a result of passive leak of both Na⁺ and H⁺ through the Na⁺/K⁺ pump.     

Sodium-transport NADH-quinone reductase of a marineVibrio alginolyticus

The respiratory chain of a marine bacterium,Vibrio alginolyticus, required Na⁺ for maximum activity, and the site of Na⁺-dependent activation was localized on the NADH-quinone reductase segment. The Na⁺-dependent NADH-quinone reductase extruded Na⁺ as a direct result of redox reaction. It was composed of three subunits, , , and , with apparentMr of 52, 46, and 32 KDa, respectively. The reduction of ubiquinone-1 to ubiquinol proceeded via ubisemiquinone radicals. The former reaction was catalyzed by the FAD-containing subunit. This reaction showed no specific requirement for Na⁺. For the formation of ubiquinol, the presence of the subunit and the FMN-containing subunit was essential. The latter reaction specifically required Na⁺ for activity and was strongly inhibited by 2-n-heptyl-4-hydroxyquinolineN-oxide. It was assigned to the coupling site for Na⁺ transport. The mode of energy coupling of redox-driven Na⁺ pump was compared with those of decarboxylase- and ATP-driven Na⁺ pumps found in other bacteria.     

The sodium concentration of the lateral intercellular spaces of MDCK cells: A microspectrofluorimetric study

MDCK cell monolayers grown on glass coverslips were used to examine the Na⁺ concentration in individual lateral intercellular spaces (LIS) by video fluorescence microscopy. The LIS was filled with the Na⁺-sensitive fluorescent dye SBFO by incubation of the monolayers for 75–90 min with 250 m of the membrane impermeant form of the dye. After dye loading, the monolayers were perfused at 37°C with solutions buffered with HEPES or bicarbonate/CO₂ containing 142 mm Na⁺. Ratios of the fluorescence images after sequential excitation with 340 nm and 380 nm light were performed and in situ calibration of LIS Na⁺ was accomplished after blocking the Na⁺ pump with 5 × 10^–4 m ouabain. Measurements of Na⁺ along the basolateral-to-apical axis of the LIS at 1.0 or 1.5 m intervals did not reveal a Na⁺ gradient when the perfusate was either HEPES or bicarbonate/CO₂ solutions. In bicarbonate solutions, the mean Na⁺ concentration (mm) was 157.2 ± 2.3, 15 mm higher than the bath Na⁺ concentration. In HEPES solutions, however, the Na⁺ concentration was not different from the bath concentration (142.7 ± 3.1 mm). The time course of Na⁺ changes in LIS was investigated by rapidly switching the perfusate from 142 to 80 mm Na⁺ and measuring the Na⁺ changes at one focal plane.We would like to thank P.H. Tran and C. Gibson for their technical and computational assistance as well as Dr. B.-E. Persson (University of Uppsala, Sweden) for his contribution in the early phases of the study.     

Significance of the β-Subunit in the Biogenesis of Na+/K+-ATPase

This review summarizes our experiments on the significance of the -subunit in the functional expression of Na⁺/K⁺-ATPase. The -subunit acts like a receptor for the -subunit in the biogenesis of Na⁺/K⁺-ATPase and facilitates the correct folding of the -subunit in the membrane. The -subunit synthesized in the absence of the -subunit is subjected to rapid degradation in the endoplasmic reticulum. Several assembly sites are assigned in the sequence of the -subunit from the cytoplasmic NH₂-terminal domain to the extracellular COOH-terminus: the NH₂-terminal region of the extracellular domain, the conservative proline in the third disulfide loop, the hydrophobic amino acid residues near the COOH-terminus and the cysteine residues forming the second and the third disulfide bridges. Upon assembly, the -subunit confers a resistance to trypsin on the -subunit. The conformations induced in the -subunit of Na⁺/K⁺-ATPase by Na⁺/K⁺- and H⁺/K⁺-ATPase -subunits are somehow different from each other and are named the NK-type and KH-type, respectively. The extracellular domain of the -subunit is involved in the folding of the -subunit leading to trypsin-resistant conformations. The sequences from Cys150 to the COOH-terminus of the Na⁺/K⁺-ATPase -subunit and from Ile89 to the COOH–terminus of the H⁺/K⁺-ATPase -subunit are necessary to form trypsin-resistant conformations of the NK- and HK-type. respectively. The first disulfide loop of the extracellular domain of the -subunits is critical in the expression of functional Na⁺/K⁺-ATPase.     

Na+ and K+ fluxes stimulated by Na+-coupled glucose transport: Evidence for a Ba2+-insensitive K+ efflux pathway in rabbit proximal tubules

Summary Addition of glucose or the nonmetabolizable analogue -methyl-d-glucoside to rabbit proximal tubules suspended in a glucoseand alanine-free buffer caused a sustained increase in intracellular Na⁺ content (+43±7 nmol · (mg protein)^–1) and a concomitant but larger decrease in K⁺ content (–72±11 nmol· (mg protein)^–1). A component of the net K⁺ efflux was Ba²⁺ insensitive, and was inhibited by high (1mm) but not low (10 m) concentrations of the diuretics, furosemide and bumetanide. The increase in intracellular Na⁺ content is consistent with the view that the increased rates of Na⁺ and water transport seen in the proximal tubule in the presence of glucose can be attributed (at least in part) to a stimulation of basolateral pump activity by an increased [Na⁺] _i .     

Electrogenic properties of the cloned Na+/glucose cotransporter: II. A transport model under nonrapid equilibrium conditions

Summary The results of the accompanying electrophysiological study of the cloned Na⁺/glucose cotransporter from small intestine (Parent, L., Supplisson, S., Loo, D.D.F., Wright, E.M. (1992) J. Membrane Biol. 125:49–62) were evaluated in terms of a kinetic model. The steady-state and presteady-state cotransporter properties are described by a 6-state ordered kinetic model (mirror symmetry) with a Na⁺:MDG stoichiometry of 2. Carrier translocation in the membrane as well as Na⁺ and sugar binding and dissociation are treated as a function of their individual rate constants. Empty carrier translocation and Na⁺ binding/ dissociation are the only steps considered to be voltage dependent. Currents were associated with the translocation of the negatively charged carrier in the membrane. Negative membrane potential facilitates sugar transport. One numerical solution was found for the 14 rate constants that account quantitatively for our experiment observations: i.e., (i) sigmoidal shape of the sugar-specific current-voltage curves (absence of outward currents and inward current saturation at high negative potentials), (ii) Na⁺ and voltage dependence of K _0.5 ^sugar and i _max ^sugar , (iii) sugar and voltage dependence of K _0.5 ^Na and i _max ^Na , (iv) presteady-state currents and their dependence on external Na⁺, MDG and membrane potential, and (v) and carrier Na⁺ leak current. We conclude that the main voltage effect is on carrier translocation. Na⁺ ions that migrate from the extracellular medium to their binding sites sense 25 to 35% of the transmembrane voltage, whereas charges associated with the carrier translocation experiences 60 to 75% of the membrane electrical field. Internal Na⁺ ion binding is not voltage dependent. In our nonrapid equilibrium model, the rate-limiting step for sugar transport is a function of the membrane potential, [Na]₀ and [MDG]₀. At 0 mV and at saturating [Na]₀ and [MDG]₀, the rate-limiting step for sugar transport is the empty carrier translocation (5 sec^–1). As the membrane potential is made more negative, the empty carrier translocation gets faster and the internal Na⁺ dissociation becomes increasingly rate limiting. However, as [Na]₀ is decreased to less than 10 mm, the rate-limiting step is the external Na⁺ ions binding in the 0 to –150 mV potential range. At 0 mV, the external Na⁺ dissociation constant KNa is 80 mm and decreases to 24 mm at –150 mV. The external sugar dissociation constant KNaS is estimated to be 200 m and voltage independent. Finally, the internal leak pathway (CNa₂ translocation) is insignificant. While we cannot rule out a more complex kinetic model, the electrical properties of the cloned Na⁺/glucose cotransporter are found to be adequately described by this 6-state kinetic model.We are grateful to Drs. A. Berteloot, S. Ciani, and J.-Y. Lapointe for stimulating discussions and thank our colleagues for comments. L.P. was recipient of a post-doctoral fellowship from the Medical Research Council of Canada. This work was supported by a grant from the U.S. Public Health Service DK 19567.     

An Amiloride-sensitive Na+ conductance in the basolateral membrane of toad urinary bladder

Summary Exposing the apical membrane of toad urinary bladder to the ionophore nystatin lowers its resistance to less than 100 cm². The basolateral membrane can then be studied by means of transepithelial measurements. If the mucosal solution contains more than 5mm Na⁺, and serosal Na⁺ is substituted by K⁺, Cs⁺, or N-methyl-d-glucamine, the basolateral membrane expresses what appears to be a large Na⁺ conductance, passing strong currents out of the cell. This pathway is insensitive to ouabain or vanadate and does not require serosal or mucosal Ca²⁺. In Cl-free SO ₄ ^2– Ringer's solution it is the major conductive pathway in the basolateral membrane even though the serosal side has 60mm K⁺. This pathway can be blocked by serosal amiloride (K _i=13.1 m) or serosal Na⁺ ions (K _i 10 to 20mm). It also conducts Li⁺ and shows a voltage-dependent relaxation with characteristic rates of 10 to 20 rad sec^–1 at 0 mV.     

Amiloride-sensitive Na+ transport in human red cells: Evidence for a Na/H exchange system

Summary The role of transmembrane pH gradients on the ouabain, bumetanide and phloretin-resistant Na⁺ transport was studied in human red cells. Proton equilibration through the Jacobs-Stewart cycle was inhibited by the use of DIDS (125 m) and methazolamide (400 m). Red cells with different internal pH (pH _i =6.4, 7.0 and 7.8) were prepared and Na⁺ influx was measured at different external pH (pH _o =6.0, 7.0, 8.0). Na⁺ influx into acid-loaded cells (pH _i =6.4) markedly increased when pH _o was raised from 6.0 to 8.0. Amiloride, a well-known inhibitor of Na⁺/H⁺ exchange systems blocked about 60% of the H⁺-induced Na⁺ entry, while showing small inhibitory effects in the absence of pH gradients. When pH₀ was kept at 8.0, the amiloride-sensitive Na⁺ entry was abolished as pH _i was increased from 6.4 to 7.8. Moreover, measurements of H⁺ efflux into lightly buffered media indicated that the imposition of an inward Na⁺ gradient stimulated a net H⁺ efflux which was sensitive to the amiloride analog 5-N-methyl-N-butyl-amiloride. Furthermore, in the absence of a chemical gradient for Na⁺ (Na _i ⁺ =Na ₀ ⁺ =15mm,Em=+6.7 mV), an outward H⁺ gradient (pH _i =6.4, pH₀=8.0) promoted a net amiloride-sensitive Na⁺ uptake which was abolished at an external pH of 6.0. These findings are consistent with the presence of an amiloride-sensitive Na⁺/H⁺ exchange system in human red cells.     

Regulation of the Na+/K+-ATPase by insulin: Why and how?

The sodium-potassium ATPase (Na⁺/K⁺-ATPase or Na⁺/K⁺-pump) is an enzyme present at the surface of all eukaryotic cells, which actively extrudes Na⁺ from cells in exchange for K⁺ at a ratio of 3:2, respectively. Its activity also provides the driving force for secondary active transport of solutes such as amino acids, phosphate, vitamins and, in epithelial cells, glucose. The enzyme consists of two subunits ( and ) each expressed in several isoforms. Many hormones regulate Na⁺/K⁺ -ATPase activity and in this review we will focus on the effects of insulin. The possible mechanisms whereby insulin controls Na⁺/K⁺-ATPase activity are discussed. These are tissue- and isoform-specific, and include reversible covalent modification of catalytic subunits, activation by a rise in intracellular Na⁺ concentration, altered Na⁺ sensitivity and changes in subunit gene or protein expression. Given the recent escalation in knowledge of insulin-stimulated signal transduction systems, it is pertinent to ask which intracellular signalling pathways are utilized by insulin in controlling Na⁺/K⁺-ATPase activity. Evidence for and against a role for the phosphatidylinositol-3-kinase and mitogen activated protein kinase arms of the insulin-stimulated intracellular signalling networks is suggested. Finally, the clinical relevance of Na⁺/K⁺-ATPase control by insulin in diabetes and related disorders is addressed.     

Ouabain resistance of the epithelial cell line (Ma104) is not due to lack of affinity of its pumps for the drug

Na⁺, K⁺-pumps of most eukaryotic animal cells bind ouabain with high affinity, stop pumping, and consequently loose K⁺, detach from each other and from the substrate, and die. Lack of affinity for the drug results in ouabain resistance. In this work, we report that Ma104 cells (epithelial from Rhesus monkey kidney) have a novel form of ouabain-resistance: they bind the drug with high affinity (Km about 4×10^–8 m), they loose their K⁺ and stop proliferating but, in spite of these, up to 100% of the cells remain attached in 1.0 m ouabain, and 53% in 1.0 mm. When 4 days later ouabain is removed from the culture medium, cells regain K⁺ and resume proliferation. Strophanthidin, a drug that attaches less firmly than ouabain, produces a similar phenomenon, but allows a considerably faster recovery. This reversal may be associated to the fact that, while in ouabain-sensitive MDCK cells Na⁺, K⁺-ATPases blocked by the drug are retrieved from the plasma membrane, those in Ma104 cells remain at the cell-cell border, as if they were cell-cell attaching molecules. Cycloheximide (10 g/ml) and chloroquine (10 m) impair this recovery, suggesting that it also depends on the synthesis and insertion of a crucial protein component, that may be different from the pump itself. Therefore ouabain resistance of Ma104 cells is not due to a lack of affinity for the drug, but to a failure of its Na⁺, K⁺-ATPases to detach from the plasma membrane in spite of being blocked by ouabain.We wish to thank Dr. E. Rodríguez-Boulán for the generous supply of Ma104 cells, as well as acknowledge the generous economic support of the National Research Council (CONACYT) of Mexico. Confocal experiments were performed in the Confocal Microscopy Unit of the Physiology Department, CINVESTAV.     

Kinetic properties of the ATP-dependent Ca2+ pump and the Na+/Ca2+ exchange system in basolateral membranes from rat kidney cortex

Summary Basolateral plasma membranes from rat kidney cortex have been purified 40-fold by a combination of differential centrifugation, centrifugation in a discontinuous sucrose gradient followed by centrifugation in 8% percoll. The ratio of leaky membrane vesicles (L) versus right-side-out (RO) and inside-out (IO) resealed vesicles appeared to be LROIO=431. High-affinity Ca²⁺-ATPase, ATP-dependent Ca²⁺ transport and Na⁺/Ca²⁺ exchange have been studied with special emphasis on the relative transport capacities of the two Ca²⁺ transport systems. The kinetic parameters of Ca²⁺-ATPase activity in digitonin-treated membranes are:K _m =0.11 m Ca²⁺ andV _max=81±4 nmol P_i/min·mg protein at 37°C. ATP-dependent Ca²⁺ transport amounts to 4.3±0.2 and 7.4±0.3 nmol Ca²⁺/min·mg protein at 25 and 37°C, respectively, with an affinity for Ca²⁺ of 0.13 and 0.07 m at 25 and 37°C. After correction for the percentage of IO-resealed vesicles involved in ATP-dependent Ca²⁺ transport, a stoichiometry of 0.7 mol Ca²⁺ transported per mol ATP is found for the Ca²⁺-ATPase. In the presence of 75mm Na⁺ in the incubation medium ATP-dependent Ca²⁺ uptake is inhibited 22%. When Na⁺ is present at 5mm an extra Ca²⁺ accumulation is observed which amounts to 15% of the ATP-dependent Ca²⁺ transport rate. This extra Ca²⁺ accumulation induced by low Na⁺ is fully inhibited by preincubation of the vesicles with 1mm ouabain, which indicates that (Na⁺–K⁺)-ATPase generates a Na⁺ gradient favorable for Ca²⁺ accumulation via the Na⁺/Ca²⁺ exchanger. In the absence of ATP, a Na⁺ gradient-dependent Ca²⁺ uptake is measured which rate amounts to 5% of the ATP-dependent Ca²⁺ transport capacity. The Na⁺ gradient-dependent Ca²⁺ uptake is abolished by the ionophore monensin but not influenced by the presence of valinomycin. The affinity of the Na⁺/Ca²⁺ exchange system for Ca²⁺ is between 0.1 and 0.2 m Ca²⁺, in the presence as well as in the absence of ATP. This affinity is surprisingly close to the affinity measured for the ATP-dependent Ca²⁺ pump. Based on these observations it is concluded that in isolated basolateral membranes from rat kidney cortex the Ca²⁺-ATPase system exceeds the capacity of the Na⁺/Ca²⁺ exchanger four- to fivefold and it is therefore unlikely that the latter system plays a primary role in the Ca²⁺ homeostasis of rat kidney cortex cells.     

Na+/Ca2+ countertransport in plasma membrane of rat pancreatic acinar cells

Summary The presence of a coupled Na⁺/Ca²⁺ exchange system has been demonstrated in plasma membrane vesicles from rat pancreatic acinar cells. Na⁺/Ca²⁺ exchange was investigated by measuring⁴⁵Ca²⁺ uptake and⁴⁵Ca²⁺ efflux in the presence of sodium gradients and at different electrical potential differences across the membrane (=) in the presence of sodium. Plasma membranes were prepared by a MgCl₂ precipitation method and characterized by marker enzyme distribution. When compared to the total homogenate, the typical marker for the plasma membrane, (Na⁺+K⁺)-ATPase was enriched by 23-fold. Markers for the endoplasmic reticulum, such as RNA and NADPH cytochromec reductase, as well as for mitochondria, the cytochromec oxidase, were reduced by twofold, threefold and 10-fold, respectively. For the Na⁺/Ca²⁺ countertransport system, the Ca²⁺ uptake after 1 min of incubation was half-maximal at 0.62 mol/liter Ca²⁺ and at 20 mmol/liter Na⁺ concentration and maximal at 10 mol/liter Ca²⁺ and 150 mmol/liter Na⁺ concentration, respecitively. When Na⁺ was replaced by Li⁺, maximal Ca²⁺ uptake was 75% as compared to that in the presence of Na⁺. Amiloride (10^–3 mol/liter) at 200 mmol/liter Na⁺ did not inhibit Na⁺/Ca²⁺ countertransport, whereas at low Na⁺ concentration (25 mmol/liter) amiloride exhibited dose-dependent inhibition to be 62% at 10^–2 mol/liter. CFCCP (10^–5 mol/liter) did not influence Na⁺/Ca²⁺ countertransport. Monensin inhibited dose dependently; at a concentration of 5×10^–6 mol/liter inhibition was 80%. A SCN^– or K⁺ diffusion potential (=), being positive at the vesicle inside, stimulated calcium uptake in the presence of sodium suggesting that Na⁺/Ca²⁺ countertransport operates electrogenically, i.e. with a stoichiometry higher than 2 Na⁺ for 1 Ca²⁺. In the absence of Na⁺, did not promote Ca²⁺ uptake. We conclude that in addition to ATP-dependent Ca²⁺ outward transport as characterized previously (E. Bayerdörffer, L. Eckhardt, W. Haase & 1. Schulz, 1985,J. Membrane Biol. 84:45–60) the Na⁺/Ca²⁺ countertransport system, as characterized in this study, represents a second transport system for the extrusion of calcium from the cell. Furthermore, the high affinity for calcium suggests that this system might participate in the regulation of the cytosolic free Ca²⁺ level.     

Amiloride blockable sodium fluxes in toad bladder membrane vesicles

Summary Recently we reported a simple manual assay for the measurements of isotope fluxes through channels in heterogenous vesicle populations (Garty et al.,J. Biol. Chem. 258:13094–13099 (1983)). The present paper describes the application of this method to the assessment of amiloride blockable fluxes in toad bladder microsomes. When²²Na⁺ uptake was monitored in the presence of an opposing Na⁺ gradient, a relatively large and transient amiloride-sensitive flux was observed. Such an amiloride-blockable flux could also be induced by a KCl+valinomycin diffusion potential. The effects of the intra- and extravesicular ionic composition on the rate of²²Na⁺ uptake were examined. It was shown that the amiloride-blockable fluxes occur in particles permeable to Na⁺ and Li⁺ but relatively impermeable to K⁺, Tris⁺ and Cl^–. Analysis of the amiloride dose-response relations revealed a complex non Michaelis-Menten behavior. The data could be accounted for by assuming either a strong negative cooperativity in the amiloride-membrane interaction, or two amiloride-sensitive Na⁺ conducting pathways withK _i values of 0.06 and 6.4 m. Both pathways appear to be electrogenic and therefore the possibility of an electroneutral amiloride-blockable Na/H exchange was excluded. Calcium ions could block the amiloride-sensitive flux from the inner but not from the outer phase of the membrane. It is suggested that although a substantial part of the²²Na⁺ flux is inhibited only by a relatively high concentration of amiloride, this uptake represents transport through the apical Na-specific channels. The data also define the optimal experimental conditions for the study of amiloride-sensitive fluxes in toad bladder microsomes.     

Na+-dependent medium-affinity uptake of L-glutamate in the insect epidermis

It is proposed that the activity of an epidermal cotransport system for Na⁺ and dicarboxylic amino acids accounts for the small amounts of L-glutamate and L-aspartate in the otherwise amino-acid-rich blood plasma of insects. This Na⁺-dependent transport system is responsible for more than 95% of the uptake of these amino acids into the larval epidermis of the beetle Tenebrio molitor. Kinetic analysis of uptake showed that the Na⁺-dependent co-transporter has medium affinity for L-glutamate and L-aspartate. The K _m for L-glutamate uptake was 146 mol·l^-1, and the maximum velocity of uptake (V _max) was 12.1 pmol·mm^-2 of epidermal sheet per minute. The corresponding values for L-aspartate were 191 mol·l^-1 and 8.4 pmol·mm^-2·min^-1. The Na⁺/L-glutamate co-transporter has a stoichiometry of at least two Na⁺ ions for each L-glutamate-ion transported (n=217). The co-transporter has an affinity for Na⁺ equivalent to a K _m of 21 mmol · l^-1 Na⁺. Na⁺ is the only external ion apparently required to drive L-glutamate uptake. Li⁺ substitutes weakly for Na⁺. Removal of external K⁺ or addition of ouabain decreases uptake slowly over 1 h, suggesting that these treatments dissipate the Na⁺/K⁺ gradient by inhibiting epidermal Na⁺/K⁺ ATPase. Several structural analogues of L-glutamate inhibit the medium-affinity uptake of L-glutamate. The order of potency with which these competitive inhibitors block glutamate uptake is L-cysteatethreo-3-hydroxy-Dl-aspartate > D-aspartateL-aspartate> L-cysteine sulphinate > L-homocysteateD-glutamate. L-trans-Pyrrolidine-2,4-dicarboxylate, a potent inhibitor of L-glutamate uptake in mammalian synaptosomes, is a relatively weak blocker of epidermal uptake. The epidermis takes up substantially more L-glutamate by this Na⁺-dependent system than tissues such as skeletal muscle and ventral nerve cord. The epidermis may be a main site regulating blood L-glutamate levels in insects with high blood [Na⁺]. Because L-glutamate and L-aspartate stimulate skeletal muscle in insects, a likely role for epidermal L-glutamate/L-aspartate transporter is to keep the level of these excitatory amino acids in the blood below the postsynaptic activation thresholds.Abbreviation ac acetate - Ch choline - CNS central nervous system - cpm counts per minute - CDTA trans-1,2-diaminocyclohexane-N,N,N,N-tetraacetic acids - HPLC high performance liquid chromatography - K _m Michaelis constant - n _app apparent number - NMG N-methyl-D-glucamine - Pipes Piperazine-N,N-bis-[2-ethanesulfonic acid] - SD standard deviation - TEA tetraethyl-ammonium - V velocity of uptake - V _max maximum velocity of uptake     

Evaluation of ion gradient-dependent H+ transport systems in isolated enterocytes from the chick

Summary The experiments reported here evaluate the capability of isolated intestinal epithelial cells to accomplish net H⁺ transport in response to imposed ion gradients. In most cases, the membrane potential was kept constant by means of a K⁺ plus valinomycin voltage clamp in order to prevent electrical coupling of ion fluxes. Net H⁺ flux across the cellular membrane was examined at pH 6.0 (the physiological lumenal pH) and at pH 7.4 using methylamine distribution or recordings of changes in media pH. Results from both techniques suggest that the cells have an Na⁺/H⁺ exchange system in the plasma membrane that is capable of rapid and sustained changes in intracellular pH in response to an imposed Na⁺ gradient. The kinetics of the Na⁺/H⁺ exchange reaction at pH 6.0 [K _t for Na⁺=57mm,V _max=42 mmol H⁺/liter 3OMG (3-O-methylglucose) space/min] are dramatically different from those at pH 7.4 (K _t for Na⁺=15mm,V _max=1.7 mmol H⁺/liter 3OMG space/min). Experiments involving imposed K⁺ gradients suggest that these cells have negligible K⁺/H⁺ exchange capability. They exhibit limited but measurable H⁺ conductance. Anion exchange for base equivalents was not detected in experiments performed in media nominally free of bicarbonate.