Furosemide-sensitive K+ channel in glioma cells but not neuroblastoma cells in culture

A furosemide-sensitive, ouabain-insensitive [⁸⁶Rb⁺] uptake is described in glioma cells in culture which is dependent upon external Na⁺, K⁺, and Cl^? concentrations. This transport activity was also inhibited by bumetanide at 100-fold lower concentrations than furosemide. Furosemide-sensitive swelling of glioma cells is demonstrated and this activity is dependent upon external Na⁺ and K⁺ in a manner similar to [⁸⁶Rb⁺] uptake. This transport activity was not detected in neuroblastoma cells and the possible relevance of these findings to extracellular K⁺ buffering by glia is discussed.     

Specific drug sensitive transport pathways for chloride and potassium ions in steady-state ehrlich mouse ascites tumor cells

A major aim of this investigation was to determine whether, in steady-state ascites cells, Cl^? transport can be partitioned into a furosemide-sensitive cotransport with K⁺ and a separate 4,4′-isothiocyanostilbene-2,2′-disulfonic acid (DIDS) sensitive self-exchange. Both Cl^? and K⁺ fluxes were studied. The furosemide- and Cl^? sensitive K⁺ fluxes were equivalent, both in normal ionic media and when the external K⁺ concentration, [K⁺]_o, was varied from 4 to 30 mM. The stoichiometry of the furosemide-sensitive Cl^? and K⁺ fluxes was 2 Cl^?: 1 K⁺ at 0.1 and 0.5 mM drug levels but increased to 3 Cl^? : 1 K⁺ at 1.0 mM furosemide. DIDS at 0.1 mM had no effect on the K⁺ exchange rate but inhibited Cl^? exchange by $\text{39\% ± 2}$ (S.E.). The effects of DIDS and 0.5 mM furosemide on Cl^? transport were additive but 1.0 mM furosemide and DIDS had overlapping inhibitory actions. Thus furosemide acts on components of K⁺ and Cl^? transport which are linked to each other, but the drug also inhibits an additional DIDS-sensitive Cl^? pathway, when present at higher concentrations. The dependence of the furosemide-sensitive K⁺ and Cl^? transport on [K⁺]_o was also studied; both fluxes fell as the [K⁺]_o increased. The latter results recall those in an earlier study by Hempling (Hempling, H.G. (1962) J. Cell. Comp. Physiol. 60, 181–198).     

Electrically silent cotransport of Na+, K+ and Cl− in ehrlich cells

A cotransport system for Na⁺, K⁺ and Cl^? in Ehrlich cells is described. It is insensitive towards ouabain but specifically inhibited by furosemide and other ‘high ceiling’ diuretics at concentrations which do not affect other pathways of the ions concerned. As the furosemide-sensitive fluxes of these ions are not affected by changes in membrane potential, and as their complete inhibition by furosemide does not appreciably alter the membrane potential, they appear to be electrically silent. Application of the pulse-response methods in terms of irreversible thermodynamics reveals tight coupling between the furosemide-sensitive flows of Na⁺, K⁺ and Cl^? ($\text{q}$ close to unity for all three combinations) at a stoichiometry of 1 : 1 : 2. The site for each of the ions appears to be rather specific: K⁺ can be replaced by Rb⁺ but not by other cations tested whereas Cl^? can be poorly replaced by Br^? but not by NO₃^?, in contradistinction to the Cl^?-OH^? exchange system. The cotransport system appears to function in cell volume regulation as it tends to make the cell swell, thus counteracting the shrinking effect of the ouabain-sensitive (Na⁺, K⁺) pump.The experiments presented could not clarify whether the cotransport process is a primary or secondary active one; while incongruence between transport and conjugated driving force seems to indicate primary active transport, it is very unlikely that hydrolysis of ATP supplies energy for the transport process, since there is no stimulation of ATP turnover observable under operation of the cotransport system.     

Sidium-dependent ion cotransport in steady-state Ehrlich ascites tumor cells

Summary The Ehrlich tumor cell possesses and anion-cation cotransport system which operates as a bidirectional exchanger during the physiological steady state. This cotransport system, like that associated with the volume regulatory mechanism (i.e. coupled net uptake of Cl^–+Na⁺ and/or K⁺) is Cl^–-selective and furosemide-sensitive, suggesting the same mechanism operating in two different modes. Since Na⁺ has an important function in the volume regulatory response, its role in steady-state cotransport was investigated. In the absence of Na⁺, ouabain-insensitive K⁺ and DIDS-insensitive Cl^– transport (KCl cotransport) are low and equivalent to that found in 150mm Na⁺ medium containing furosemide. Increasing the [Na⁺] results in parallel increases in K⁺ and Cl^– transport. The maximum rate of each (18 to 20 meq/(kg dry wt)·min) is reached at about 20mm Na⁺ and is maintained up to 55mm. Thus, over the range 1 to 55mm Na⁺ the stoichiometry of KCl cotransport is 11. In contrast to K⁺ and Cl^–, furosemide-sensitive Na⁺ transport is undetectable until the [Na⁺] exceeds 50mm. From 50 to 150mm Na⁺, it progressively rises to 7 meq/(kg dry wt)·min, while K⁺ and Cl^– transport decrease to 9 and 16 meq/(kg dry wt)·min, respectively. Thus, at 150mm Na⁺ the stoichiometric relationship between Cl^–, Na⁺ and K⁺ is 211. These results are consistent with the proposal that the Cl^–-dependent cation cotransport system when operating during the steady state mediates the exchange of KCl for KCl or NaCl for NaCl; the relative proportion of each determined by the extracellular [Na⁺].     

Cl− transport in apical plasma membrane vesicles isolated from bovine tracheal epithelium

The Cl^? transport properties of the luminal border of bovine tracheal epithelium have been investigated using a highly purified preparation of apical plasma membrane vesicles. Transport of Cl^? into an intravesicular space was demonstrated by (1) a linear inverse correlation between Cl^? uptake and medium osmolarity and (2) complete release of accumulated Cl^? by treatment with detergent. The rate of Cl^? uptake was highly temperature-sensitive and was enhanced by exchange diffusion, providing evidence for a carrier-mediated transport mechanism. Transport of Cl^? was not affected by the ‘loop’ diuretic bumetanide or by the stilbene-derivative anion-exchange inhibitors SITS (4-acetamido-4′-isothiocyanostilbene-2,2′-disulfonic acid) and DIDS (4,4′-diisothiocyanostilbene-2,2′-disulfonic acid). In the presence of the impermeant cation, tetramethylammonium (TMA⁺), uptake of Cl^? was minimal; transport was stimulated equally by the substitution of either K⁺ or Na⁺ for TMA⁺. Valinomycin in the presence of K⁺ enhanced further Cl^? uptake, while amiloride reduced Na⁺-stimulated Cl^? uptake towards the minimal level observed with TMA⁺. These results suggest the following conclusions: (1) the tracheal vesicle membrane has a finite permeability to both Na⁺ and K⁺; (2) the membrane permeability to the medium counterion determines the rate of Cl^? uptake; (3) Cl^? transport is not specifically coupled with either Na⁺ or K⁺; and, finally (4) Cl^? crosses the tracheal luminal membrane via an electrogenic transport mechanism.     

Na+ transport processes in isolated guinea pig nasal gland acinar cells

In the dispersed acinar cells of the submucosal nasal gland in the guinea pig, intracellular Na⁺ concentration ([Na⁺]i) was measured with a microfluorimetric imaging method and the cytosolic indicator dye, sodium-binding benzofuran isophthalate, under HCO₃^?-free conditions. In the unstimulated condition, the [Na⁺]i was averaged to 12.8 ± 5.2 mM. Addition of 100 μM ouabain or removal of external K⁺ caused an increase in [Na⁺]i. Replacement of external Cl^? with NO₃^? or addition of 0.5 mM furosemide reversibly decreased the [Na⁺]i. The recovery process from the reduced [Na⁺]i was inhibited by removal of either K⁺ or Cl^? in the bath solution. These findings indicate the presence of a continuous influx of Na⁺ coupled with K⁺ and Cl^? movement. Application of acetylcholine (ACh, 1 μM) caused an increase in [Na⁺]i by about 15–20 mM, which was completely inhibited by addition of 10 μM atropine. Increased cytosolic Na⁺ induced by ACh was extruded by the Na⁺-K⁺ pump. Removal of external Cl^? and addition of 50 μM dimethylamiloride inhibited ACh-induced increase in [Na⁺]i by about 66% and 19%, respectively. In both unstimulated and stimulated state, Na⁺-K⁺ pump, Na-K-Cl cotransport, and Na⁺-H⁺ exchange play a critical role in maintaining intracellular electrolyte environment and in controlling a continuous secretion of nasal fluids. © 1995 Wiley-Liss, Inc.     

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.     

The ionic relations of Porphyra purpurea(Roth) C.Ag. (Rhodophyta, Bangiales)

Abstract Radioisotope equilibration techniques have been used to determine the intracellular concentration of K⁺, Na⁺ and Cl_?, together with the unidirectional ion fluxes across the plasmalemma of Porphyra purpurea. Influx and efflux of ⁴²K⁺, ²⁴Na⁺ and ³⁶C1^? are biphasic, the rapid, initial uptake and loss of tracer from individual thalli being attributable to desorption from extracellular regions. Cellular fluxes are slower and monophasic, cells discriminating in favour of K⁺ and Cl^? and against Na⁺. A comparison between the equilibrium potential of individual ion species and the measured membrane potential demonstrates that there is an active component of K⁺ and Cl^? influx and Na⁺ efflux. ‘Active’ uptake and ‘passive’ loss of K⁺ and Cl^? are reduced when plants are kept in darkness, suggesting that a fraction of the transport of K⁺ and Cl^? may be due to ‘exchange diffusion’ (K⁺/K⁺ and Cl^?/Cl^?antiport).     

Occurrence of passive furosemide-sensitive transmembrane potassium transport in cultured cells

Furosemide ($\text{1 · 10}{}^{\mathrm{?4}}\text{M}$) inhibits a proportion of the total passive (ouabain-insensitive) K⁺ influx into primary chick heart cell cultures (85%), BC₃H1 cells (75%), MDCK cells (40%) and HeLa cells (57%). This action of furosemide upon K⁺ influx is independent of ($\text{Na}{}^{\mathrm{+}}\text{+}\text{K}{}^{\mathrm{+}}\text{)-}\text{pump}$ inhibition since the furosemide-sensitive component of the K⁺ influx is identical in the presence and absence of ouabain ($\text{1 · 10}{}^{\mathrm{?3}}\text{M}$). For HeLa cells the passive, furosemide-sensitive component of K⁺ influx is markedly dependent upon the external K⁺, Na⁺ and Cl^? content. Acetate, iodide and nitrate are ineffective as substitutes for Cl^?, whereas Br^? is partially effective. Partial Cl^? replacement by NO₃^? gave an apparent affinity of 100 mM [Cl]. Na⁺ replacement by choline⁺ abolishes the furosemide-sensitive component, whereas Li⁺ replacement reduces this component by 48%. Partial Na⁺ replacement by choline⁺ gives an apparent affinity of 25 mM [Na⁺]. Variation in the external K⁺ content gives an affinity for the furosemide-sensitive component of approx. 1.0 mM. Furosemide inhibition of the passive K⁺ inflúx is of high affinity, half-maximal inhibition being observed at $\text{5 · 10}{}^{\mathrm{?6}}\text{M}$ furosemide. Piretanide ($\text{1 · 10}{}^{\mathrm{?4}}\text{M}$) and phloretin ($\text{1 · 10}{}^{\mathrm{?4}}\text{M}$) inhibit the same component of passive K⁺ influx as furosemide; ethacrynic acid and amiloride ($\text{both}\text{1 · 10}{}^{\mathrm{?4}}\text{M}$) partially so. The stilbene, SITS ($\text{1 · 10}{}^{\mathrm{?6}}\text{M}$), was ineffective as an inhibitor of the furosemide-sensitive component.     

Kinetics of chloride transport in the cyanobacterium Synechococcus R-2 (Anacystis nidulans, S. leopoliensis) PCC 7942

The kinetics of the light-driven Cl^? uptake pump of Synechococcus R-2 (PCC 7942) were investigated. The kinetics of Cl^? uptake were measured in BG-11 medium (pH_o, 7·5; [K⁺]_o, 0·35 mol m^?3; [Na⁺]_o, 18 mol m^?3; [Cl^?]_o, 0·508 mol m^?3) or modified media based on the above. Net³⁶Cl^? fluxes (?Cl^?_o,i) followed Michaelis-Menten kinetics and were stimulated by Na⁺ [18 mol m^?3 Na⁺ BG-11 ?Cl^?_max= 3·29±0·60 (49) nmol m^?2 s^?1 versus Na⁺-free BG-11 ?Cl^?_max= 1·02±0·13 (54) nmol m^?2 s^?1] but the Km was not significantly different in the presence or absence of Na⁺ at pH_o 10; the Km was lower, but not affected by the presence or absence of Na⁺ [Km = 22·3±3·54 (20) mmol m^?3]. Na⁺ is a non-competitive activator of net ?Cl^?_o,i. High [K⁺]_o (18 mol m^?3) did not stimulate net ?Cl^?_o,i or change the Km in Na⁺-free medium. High [K⁺]_o (18 mol m^?3) added to Na⁺ BG-11 medium decreased net ?Cl^?_o,i [18 mol m^?3K⁺ BG-11; ?Cl^?_max= 2·50±0·32 (20) nmol m^?2 s^?1 versus BG-11 medium; ?Cl^?_max= 3·35±0·56 (20) nmol m^?2 s^?1] but did not affect the Km 55·8±8·100 (40) mmol m^?3]. Na⁺-stimulation of net ?Cl^?_o,i followed Michaelis-Menten kinetics up to 2–5 mol m^?3 [Na⁺]_o but higher concentrations were inhibitory. The Km for Na⁺-stimulation of net ?Cl^?_o,i [K_1/2(Na⁺)] was different at 47 mmol m^?3 [Cl^?]_o (K_1/2[Na⁺] = 123±27 (37) mmol m^?3]. Li⁺ was only about one-third as effective as Na⁺ in stimulating Cl^? uptake but the activation constant was similar [K_1/2(Li⁺) = 88±46 (16) mmol m^?3]. Br^? was a competitive inhibitor of Cl^? uptake. The inhibition constant (Ki) was not significantly different in the presence and absence of Na⁺. The overall Ki was 297±23 (45) mmol m^?3. The discrimination ratio of Cl^? over Br^? (δCl^?/δBr^?) was 6·38±0·92 (df = 147). Synechococcus has a single Na⁺-stimulated Cl^? pump because the Km of the Cl^? transporter and its discrimination between Cl^? and Br^? are not significantly different in the presence and absence of Na⁺. The Cl^? pump is probably driven by ATP.     

Ouabain-resistant Na+, K+ transport system in mouse NIH 3T3 cells

Summary It is shown that the ouabain-resistant (OR) furosemide-sensitive K⁺(Rb⁺) transport system performs a net efflux of K⁺ in growing mouse 3T3 cells. This conclusion is based on the finding that under the same assay conditions the furosemidesensitive K⁺(Rb⁺) efflux was found to be two- to threefold higher than the ouabain-resistant furosemide-sensitive K⁺(Rb⁺) influx. The oubain-resistant furosemide-sensitive influxes of both²²Na and⁸⁶Rb appear to be Cl^– dependent, and the data are consistent with coupled unidirectional furosemide-sensitive influxes of Na⁺, K⁺ and Cl^– with a ratio of 1 1 2. However, the net efflux of K⁺ performed by this transport system cannot be coupled to a ouabain-resistant net efflux of Na⁺ since the unidirectional ouabain-resistant efflux of Na⁺ was found to be negligible under physiological conditions. This latter conclusion was based on the fact that practically all the Na⁺ efflux appears to be ouabainsensitive and sufficient to balance the Na⁺ influx under such steady-state conditions. Therefore, it is suggested that the ouabain-resistant furosemide-sensitive transport system in growing cells performs a facilitated diffusion of K⁺ and Na⁺, driven by their respective concentration gradients: a net K⁺ efflux and a net Na⁺ influx.     

KCl loss and cell shrinkage in the ehrlich ascites tumor cell induced by hypotonic media, 2-deoxyglucose and propranolol

Ehrlich ascites tumor cells lose KCl and shrink after swelling in hypotonic media and in response to the addition of 2-deoxyglucose, propranolol, or the Ca²⁺ ionophore, A23187, plus Ca²⁺ in isotonic media. All of these treatments activate cell shrinkage via a pathway with the following characteristics: (1) the KCl loss responsible for cell shrinkage does not alter the membrane potential; (2) NO₃^? does not substitute for Cl^?; (3) the net KCl movements are not inhibited by quinine or DIDS; and (4) early in this study furosemide was effective in inhibiting cell shrinkage but this sensitivity was subsequently lost. This evidence suggests that the KCl loss in these cells occurs via a cotransport mechanism. In addition, hypotonic media and the other agents used here stimulate a Cl^? -Cl^? exchange, a net loss of K⁺ and a net gain of Na⁺ which are not responsible for cell shrinkage. The Ehrlich cell also appears to have a Ca²⁺-activated, quinine-sensitive K⁺ conductive pathway but this pathway is not part of the mechanism by which these cells regulate their volume following swelling or shrink in isotonic media in response to 2-deoxyglucose or propranolol. Shrinkage by the loss of K⁺ through the Ca²⁺ stimulated pathway appears to be limited by Cl^? conductive movements; for when NO₃^?, an anion demonstrated here to have a higher conductive movement than Cl^?, is substituted for Cl^?, the cells will shrink when the Ca²⁺-stimulated K⁺ pathway is activated.     

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.     

Fluxes and compartmentation of K+, Na+ and Cl−, and action of auxins in suspension-cultured Petroselinum cells

Transport of ⁸⁶Rb⁺/K⁺, ²²Na⁺, ³⁶Cl^?, and [³H]indole acetic acid (IAA) has been studied on suspension-cultured cells of the parsley, Petroselinum crispum (Mill) Nym. By compartmental analysis two intracellular compartments of K⁺, Na⁺, and Cl^? have been identified and ascribed to the cytoplasm and vacuole; half-times of exchange were around 200 s and 5 h, respectively. According to the Ussing-Teorell flux equation, active transport is required for the influx into the cytoplasm at the plasmalemma (K⁺, Cl^?) and the tonoplast (K⁺, Na⁺, Cl^?). The plasmalemma permeability pattern, P_K:P_Na:P_Cl=1.00:0.24:0.38, features an increased chloride permeability compared with cells from higher plant tissues. IAA uptake showed an exponential timecourse, was half-maximal after 10 min, and a linear function of the IAA concentration from 10^?9 to 10^?5 M. IAA and 2,4-dichlorophenoxy acetic acid reduce the apparent influx of K⁺, Na⁺, Cl^? during the initial 30 min after addition and subsequently accelerate both in- and efflux of these ions. We discuss that auxins could affect the ion fluxes in a complex way, e.g. by protonophorous activity and by control of the hypothetical proton pump.     

cAMP activates Cl−/HCO3− exchange for regulation of intracellular pH in renal epithelial cells

The role of cAMP in regulation of intracellular pH in the confluent LLC-PK₁ cells was investigated. DibutyrylcAMP and forskolin induce intracellular acidification. This acidification is inhibited by DIDS and ethacrynic acid, inhibitors of Na⁺-independent Cl^?/HCO₃^? exchange, and by removal of extracellular Cl^?. In addition, Bt₂ cAMP causes Cl^? entry into LLC-PK₁ cells. These results suggest that cAMP activates Cl^? transport, namely Na⁺-independent Cl^?/HCO₃^? exchange, which participates in pH_i regulation.     

The effect of harmaline on unidirectional potassium fluxes and ouabain binding in renal cell cultures

Harmaline inhibits K⁺ influx into primary cell cultures of ground squirrel kidneys to a greater extent than either ouabain or furosemide. A concentration of 200 μM harmaline was required to inhibit half of the total K⁺ influx; this effect was also seen at low temperature (5°C), and in another species (hamster). Although kinetic analysis of K⁺ influx indicates that harmaline does not compete with extracellular K⁺, harmaline did reduce the binding of [³H]ouabain to the cells. K⁺ efflux was also reduced. Therefore, harmaline may inhibit the furosemide-sensitive Na⁺/K⁺ cotransport system as well as the ouabain-sensitive Na⁺/K⁺ pump.     

Thiol-Dependent passive K/Cl transport in sheep red cells: IV. Furosemide inhibition as a function of external Rb+, Na+, and Cl−

Summary The effect of the loop diuretic furosemide (4-chloro-N-furfuryl-5-sulfamoyl-anthranilic acid) on the thiol-dependent, ouabain-insensitive K(Rb)/Cl transport in low K⁺ sheep red cells was studied at various concentrations of extracellular Rb⁺, Na⁺ and Cl^–. In Rb⁺-free NaCl media, 2×10^–3 m furosemide inhibited only one-half of thiol-dependent K⁺ efflux. In the presence of 23mm RbCl, however, the concentration of furosemide to produce 50% K⁺ efflux inhibition (IC₅₀) was 5×10^–5 m. In Rb⁺ containing NaCl media, the inhibitory effect of 10^–3 m furosemide was equal to that caused by NO ₃ ^– replacement of Cl^– in the medium. The apparent synergistic action of furosemide and external Rb⁺ on K⁺ efflux was also seen in the ouabain-insensitive Rb⁺ influx. A preliminary kinetic analysis suggests that furosemide binding alters both maximal K⁺(Rb⁺) transport and apparent external Rb⁺ affinity. In the presence of external Rb⁺, Na⁺ (as compared to choline) exerted a small but significant augmentation of the furosemide inhibition of K⁺(Rb⁺) fluxes. There was no effect of Cl^– on the IC₅₀ value of furosemide. As there is no evidence for coupled Na⁺K⁺ cotransport in low K⁺ sheep red cells, furosemide may modify thiol-dependent K⁺(Rb⁺/Cl flux or Rb⁺ (and to a slight degree Na⁺) modulate the effect of furosemide.     

Measurement and stoichiometry of bumetanide-sensitive (2Na∶1K∶3Cl) cotransport in ferret red cells

Summary The bumetanide-sensitive uptake of Na⁺, K^–(Rb^–) and Cl^– has been measured at 21°C in ferrent red cells treated with (SITS+DIDS) to minimize anion flux via capnophorin (Band 3). During the time course of the influx experiments tracer uptake was a first-order rate process. At normal levels of external Na⁺ (150mm) the bumetanide-sensitive uptake of K⁺ was dependent on Cl^– and represented almost all of the K⁺ uptake, the residual flux demonstrating linear concentration dependence. The uptake of Na⁺ and Cl^– was only partially inhibited by bumetanide indicating that pathways other than (Na+K+Cl) cotransport participate in these fluxes. The diuretic-sensitive uptake of Na⁺ or Cl^– was, however, abolished by the removal of K⁺ or the complementary ion indicating that bumetanide-sensitive fluxes of Na⁺, K⁺ and Cl^– are closely coupled. At very low levels of [Na] _o (<5mm) K⁺ influx demonstrated complex kinetics, and there was evidence of the unmasking of a bumetanide-sensitive Na⁺-independent K⁺ transport pathway. The stoichiometry of bumetanide-sensitive tracer uptake was 2Na1K3Cl both in cells suspended in a low and a high K⁺-containing medium. The bumetanide-sensitive flux was markedly reduced by ATP depletion. We conclude that a bumetanide-sensitive cotransport of (2Na1K3Cl) occurs as an electroneutral complex across the ferret red cell membrane.     

Sodium Transport in Capillaries Isolated from Rat Brain

Abstract: Brain capillary endothelial cells form a bloodbrain barrier (BBB) that appears to play a role in fluid and ion homeostasis in brain. One important transport system that may be involved in this regulatory function is the Na⁺,K⁺-ATPase that was previously demonstrated to be present in isolated brain capillaries. The goal of the present study was to identify additional Na⁺ transport systems in brain capillaries that might contribute to BBB function. Microvessels were isolated from rat brains and ²²Na ⁺ uptake by and efflux from the cells were studied. Total ²²Na ⁺ uptake was increased and the rate of ²²Na ⁺ efflux was decreased by ouabain, confirming the presence of Na⁺,K⁺-ATPase in capillary cells. After inhibition of Na⁺,K⁺-ATPase activity, another saturable Na ⁺ transport mechanism became apparent. Capillary uptake of ²²Na ⁺ was stimulated by an elevated concentration of Na ⁺or H⁺ inside the cells and inhibited by extracellular Na⁺, H⁺, Li⁺, and NH₄⁺. Amiloride inhibited ²²Na ⁺ uptake with a K_i between 10^?5 and 10^?6M but there was no effect of 1 mM furosemide on ²²Na⁺ uptake by the isolated microvessels. These results indicate the presence in brain capillaries of a transport system capable of mediating Na ⁺/ Na ⁺ and Na ⁺/H ⁺ exchange. As a similar transport system does not appear to be present on the luminal membrane of the brain capillary endothelial cell, it is proposed that Na ⁺/H ⁺ exchange occurs primarily across the antiluminal membrane.