Furosemide-sensitive Na+-K+ cotransport and cellular metabolism in human erythrocytes

Metabolic depletion of human red cells with 2-deoxy-D-glucose in the presence of EGTA decreased ATP to about 4% of the initial value and increased total ouabain- and furosemide-resistant Na+ and K+ effluxes by 20% and 100%, respectively, and furosemide-sensitive Na+ and K+ effluxes by 100% and 60%, respectively. When ATP was restored, all the components of Na+ and K+ fluxes measured returned to baseline levels suggesting a metabolic dependence.     

Furosemide-sensitive Na and K fluxes in human red cells. Net uphill Na extrusion and equilibrium properties

This paper reports experiments designed to find the concentrations of internal and external Na and K at which inward and outward furosemide-sensitive (FS) Na and K fluxes are equal, so that there is no net FS movement of Na and K. The red cell cation content was modified by using the ionophore nystatin, varying cell Na (Nai) from 0 to 34 mM (K substitution, high-K cells) and cell K (Ki) from 0 to 30 mM (Na substitution, high-Na cells). All incubation media contained NaCl (Nao = 130 or 120 nM), and KCl (Ko = 0-30 mM). In high-K cells, incubated in the absence of Ko, there was net extrusion of Na through the FS pathway. The net FS Na extrusion increased when Nai was increased. Low concentrations of Ko (0-6 mM) slightly stimulated, whereas higher concentrations of Ko inhibited, FS Na efflux. Increasing Ko stimulated the FS Na influx (K0.5 = 4 mM). Under conditions similar to those that occur in vivo (Nai = 10, Ki = 130, Nao = 130, Ko = 4 mM, Cli/Clo = 0.7), net extrusion of Na occurs through the FS pathway (180-250 mumol/liter cell X h). The concentration of Ko at which the FS Na influx and efflux and the FS K influx and efflux become equal increased when Nai increased in high-K cells and when Ki was increased in high-Na cells. The net FS Na and K fluxes both approached zero at similar internal and external Na and K concentrations. In high-K cells, under conditions when net Na and K fluxes were near zero, the ratio of FS Na to FS K unidirectional flux was found to be 2:3. In high-K cells, the empirical expression (Nai/Nao)2(Ki/Ko)3 remained at constant value (apparent equilibrium constant, Kappeq +/- SEM = 22 +/- 2) for each set of internal and external cation concentrations at which there was no net Na flux. These results indicate that in the physiological region of concentrations of internal and external Na, K, and Cl, the stoichiometry of the FS Na and K fluxes is 2 Na:3 K. In high-Na cells under conditions when net FS Na and K fluxes were near zero, the ratio of FS Na to FS K unidirectional fluxes was 3:2 (1).(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Furosemide-sensitive K+ (Rb+) transport in human erythrocytes: Modes of operation,dependence on extracellular and intracellular Na+, kinetics,pH dependency and the effect of cell volume and N-ethylmaleimide

Summary The effect of extracellular and intracellular Na⁺ (Na _o ⁺ , Na _i ⁺ ) on ouabain-resistant, furosemide-sensitive (FS) Rb⁺ transport was studied in human erythrocytes under varying experimental conditions. The results obtained are consistent with the view that a (1 Na⁺+1 K⁺+2 Cl^–) cotransport system operates in two different modes: modei) promoting bidirectional 11 (Na⁺–K⁺) cotransport, and modeii) a Na _o ⁺ -independent 11 K _o ⁺ /K _i ⁺ exchange requiring Na _i ⁺ which, however, is not extruded. The activities of the two modes of operation vary strictly in parallel to each other among erythrocytes of different donors and in cell fractions of individual donors separated according to density. Rb⁺ uptake through Rb _o ⁺ /K _i ⁺ exchange contributes about 25% to total Rb⁺ uptake in 145mm NaCl media containing 5mm RbCl at normal Na _i ⁺ (pH 7.4). Na⁺–K⁺ cotransport into the cells occurs largely additive to K⁺/K⁺ exchange. Inward Na⁺–Rb⁺ cotransport exhibits a substrate inhibition at high Rb _o ⁺ . With increasing pH, the maximum rate of cotransport is accelerated at the expense of K⁺/K⁺ exchange (apparent pK close to pH 7.4). The apparentK _m ^Rb _o ⁺ of Na⁺–K⁺ cotransport is low (2mm) and almost independent of pH, and high for K⁺/K⁺ exchange (10 to 15mm), the affinity increasing with pH. The two modes are discussed in terms of a partial reaction scheme of (1 Na⁺+1 K⁺+2 Cl^–) cotransport with ordered binding and debinding, exhibiting a glide symmetry (first on outside = first off inside) as proposed by McManus for duck erythrocytes (McManus, T.J., 1987,Fed. Proc., in press). N-ethylmaleimide (NEM) chemically induces a Cl^–-dependent K⁺ transport pathway that is independent of both Na _o ⁺ and Na _i ⁺ . This pathway differs in many properties from the basal, Na _o ⁺ -independent K⁺/K⁺ exchange active in untreated human erythrocytes at normal cell volume. Cell swelling accelerates a Na _o ⁺ -independent FS K⁺ transport pathway which most probably is not identical to basal K⁺/K⁺ exchange. K _o ⁺ o ⁺

o ⁺ o ²⁺ reduce furosemide-resistant Rb⁺ inward leakage relative to choline _o ⁺ .     

Na+ and K+ transport in excised soybean roots

Uptake, accumulation and xylem transport of K⁺ and Na⁺ in excised roots of soybean were investigated by use of a perfusion technique. This technique permitted independent quantification of, on the one hand, entry of ions into the roots and their transport through the cortex to the xylem vessels, and on the other hand reabsorption from the xylem vessels to the neighbouring cells and the external medium. Data are consistent with a low degree of selective uptake of K⁺ over Na⁺. However, Na⁺ depletion of the xylem stream by reabsorption limits, although weakly, its translocation to the shoots. Na⁺ reabsorbed is for a great part reexcreted into the external medium. The low efficiency of these processes is discussed in relation to the Na⁺ sensitivity of soybean.     

An ionometric study of Na+ and K+ fluxes across the nystatin-modified human erythrocyte membrane]

The application of ion-selective electrodes is discussed for the kinetic determination of K+ and Na+ concentrations in the system, containing human red blood cells modified by nystatin. A series of mixed solutions was worked out, according to which the Na(+)-glass and the K(+)-thick membrane valinomycin electrodes were calibrated. The human erythrocytes were washed for 3 times with the basic solution (in mol per liter: 0.141 NaCl, 0.004 KCl, 0.002 CaCl2, 0.003 MgCl2, 0.01 glucose), and then were resuspended in it. The suspension was kept in a shaking bath at 37 degrees C. The modification of the cell membranes was performed by the introduction of different amounts of the antibiotic nystatin into the probe. Under these conditions the concentration of Na+ decreased, while K+ concentration increased. The values of concentration were registered ionometrically. In an hour and a half the stationary lines were obtained. Being based on the values of the stationary cation concentrations and the final concentrations, registered after the complete lysis of erythrocytes promoted by saponin, the ratio of cation fluxes across the modified membrane to the flux across the nonmodified membrane was calculated in accordance with the Hodgkin-Katz equation.     

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

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

Na+ and K+ transport in Nitrosomonas europaea and Nitrobacter agilis

Potassium-depleted cells of Nitrosomonas europaea and Nitrobacter agilis were prepared by diethanolamine treatment and contained less than 5 mM intracellular K⁺. The addition of K⁺ to K⁺-depleted cells of N. europaea and N. agilis resulted in a depolarization of membrane potential (ΔΨ) by about 5 and 10 mV, respectively. This depolarization was, however, compensated by an equivalent increase in transmembrane pH gradient (ΔpH), so that the total proton-motive force (Δp) remained constant, indicating that K⁺ transport was electrogenic in both bacteria. Using ²²Na⁺-loaded cells, it is shown that both bacteria lack a respiration-dependent Na⁺ pump; however, antiporters for Na⁺/H⁺, K⁺/Na⁺ and K⁺/H⁺ were detected. Of these, at least the K⁺/Na⁺ antiporter required an electrochemical gradient for its operation. It is also shown that the unprotonated form of NH₄⁺ is transported into these bacteria by a simple diffusion mechanism.     

Cationomycin and monensin partition between serum proteins and erythrocyte membrane: consequences for Na+ and K+ transport and antimalarial activities

The ionophore properties of cationomycin and monensin were studied on human erythrocytes by measuring Na+ influx by 23Na NMR and concomitant K+ efflux by potentiometry in the presence of increasing amounts of serum. Both ion currents (Na+ or K+) decreased linearly with the reciprocal of serum amount. The serum effects on ion currents were stronger with cationomycin than with monensin. Assuming this decreased transport activity was due to drug binding to serum proteins, a partition coefficient between the protein and the membrane phase was determined for each ionophore by using a novel model. This partition coefficient is about 30 times higher for cationomycin than for monensin; the same result was obtained with purified human serum albumin, indicating that albumin may be the major ionophore binding protein of serum. In parallel, we also measured IC50 for 50% in vitro growth inhibition of Plasmodium falciparum, the agent of malaria. In the presence of increasing serum concentrations, the antimalarial activity was decreased for both ionophores. Serum effect was less severe for monensin than for cationomycin, in agreement with the weaker interaction of monensin with proteins as shown from the partition coefficient values. A correlation was established between the ion transport currents (sodium and potassium) and the IC50 measured on P. falciparum in the presence of the various concentrations of serum. The relative value of the ion transport currents (expressed as percentage of control in absence of serum) can be indicative of the ionophore unbound fraction in the medium.     

Electrogenic ion transport by Na+,K+-ATPase

Experimental data on the ion electrogenic transport by Na+,K+-ATPase available in the literature are analyzed. Special attention is paid to the measurements of unsteady-state electric currents initiated by alternating voltage or rapid introduction of the substrate. In the final part, a physical model of the Na+,K+-ATPase functioning is discussed. According to this model, active transport is carried out by opening and closing of the access channels used for the sodium and potassium exchange between solutions on either side of the membrane. The model explains most of the experimental data, although some details (the channel size, rates of individual transport steps) need further refinement.     

Effect of glycosphingolipids on erythrocyte Na+,K+-ATPase activity

The total fractions of gangliosides and cerebrosides isolated from the tissue of human brain were studied for their effect on the Na+, K+-ATPase activity of native erythrocytes and their membranes. It is shown that gangliosides depending on time of their preincubation with the enzyme preparation and concentration produce both the activating and inhibiting action and cerebrosides--only the inhibiting one. Gangliosides inhibit the transport ATPase activity noncompetitively with respect to ATP and Na+ and competitively--to K+, cerebrosides inhibit it noncompetitively with respect to all ATPase activators.