Effect of ouabain and metabolic inhibitors on the Na and K movements and nucleotide contents of L cells

Alterations of Na+/K+-ATPase function in caveolin-1 knockout cardiac fibroblasts

Recent studies have demonstrated that the Na(+)/K(+)-ATPase is not only an ion pump, but also a membrane receptor that confers the ligand-like effects of cardiotonic steroids (CTS) such as ouabain on protein kinases and cell growth. Because CTS have been implicated in cardiac fibrosis, this study examined the role of caveolae in the regulation of Na(+)/K(+)-ATPase function and CTS signaling in cardiac fibroblasts. In cardiac fibroblasts prepared from wild-type and caveolin-1 knockout [Cav-1(-/-)] mice, we found that the absence of caveolin-1 did not affect total cellular amount or surface expression of Na(+)/K(+)-ATPase alpha1 subunit. However, it did increase ouabain-sensitive (86)Rb(+) uptake. While knockout of caveolin-1 increased basal activities of Src and ERK1/2, it abolished the activation of these kinases induced by ouabain but not angiotensin II. Finally, ouabain stimulated collagen synthesis and cell proliferation in wild type but not Cav-1(-/-) cardiac fibroblasts. Thus, we conclude that caveolae are important for regulating both pumping and signal transducing functions of Na(+)/K(+)-ATPase. While depletion of caveolae increases the pumping function of Na(+)/K(+)-ATPase, it suppresses CTS-induced signal transduction, growth, and collagen production in cardiac fibroblasts.

Different patterns of cell volume regulation in hyposmotic media between attached and suspended HeLa cells

Both attached and suspended HeLa cells swelled in a medium of a hypotonic osmolality of 235 mosmol/kg H2O. When the osmolality was further decreased to 166 mosmol/kg H2O, attached cells instantly swelled and then rapidly lost water and K+, followed by slow gains of them. Suspended cells instantly swelled and then K+ loss and regulatory volume decrease (RVD) occurred. Neither 0.1 mM ouabain nor 10 mM TEA changed the water loss of attached cells, whereas ouabain inhibited RVD of suspended cells. Quinine (1 mM) inhibited water losses from both cells and comparison of the losses implies stronger activation of K+ channel in attached cells than in suspended cells. Omission of medium Ca2+ or addition of 10 mM BaCl2 inhibited RVD in part. These results suggest that hyposmotic stress induces net water loss from attached cells, associated with K+ release through the Ca(2+)-dependent K+ channel. Suspended cells osmotically swell, followed by RVD with K+ and Na+ releases through the K+ channel and Na(+)-pump, respectively. The different patterns of volume changes may relate to the difference of activity or time of activation of the K+ channel between both cells.

Membrane potential of rat calvaria bone cells: dependence on temperature

The membrane potentials of bone cells derived from calvaria of new born rats was shown to be strongly dependent on temperature. When we lowered the temperature from 36 degrees C to 26 degrees C, cells with spontaneous resting membrane potentials (MP) of -80 to -50 mV depolarized (mean amplitude 8 mV; n = 33), and the membrane resistance increased by approximately 80% (n = 20). The temperature response depended on the actual MP, the reversal potential being in the range of -80 to -90 mV. With the application of ouabain (0.1-1 mmol/liter; n = 12), cells depolarized. Simultaneously, the reversal potential of the temperature response was shifted towards more positive values and approached the actual MP level of the cells. Consequently, the depolarization amplitudes induced by lowering temperature were reduced at spontaneous MP levels. The rise of the membrane resistance during cooling was unaffected. When the extracellular chloride concentration was reduced from 133 to 9 mmol/liter, temperature-dependent depolarizations persisted at spontaneous MP values (n = 5). The findings indicate that the marked effects of temperature changes on the MP of bone-derived cells are mainly determined by changes of the potassium conductance.

Ionic dependence of the extracellular ATP-induced permeabilization of transformed mouse fibroblasts: role of plasma membrane activities that regulate cell volume

Extracellular ATP rendered the plasma membrane of transformed mouse fibroblasts permeable to normally impermeant molecules. This permeability change was prevented by increasing the ionic strength of the isotonic medium with NaCl. Conversely, the cells exhibited increased sensitivity to ATP when the NaCl concentration was decreased below isotonicity, when the KCl concentration was increased above 5 mM while maintaining isotonicity, and when the pH of the medium was raised above 7.0. These conditions as well as the addition of ATP itself caused cell swelling. However, the effect of ATP was independent of cell volume and dependent upon the ionic strength and not the osmolarity of the medium since 1) addition of sucrose to isotonic medium did not prevent permeabilization although media made hypertonic with either sucrose or NaCl caused a decrease in cell volume; and 2) addition of sucrose or NaCl to hypotonic media caused a decrease in cell volume, but only NaCl addition decreased the response to ATP. Conditions that have been shown to inhibit plasma membrane proteins that play a reciprocal role in cell volume regulation had reciprocal effects on the permeabilization process, even though the effect of ATP was independent of cell volume. For example, inhibition of the Na+,K+-ATPase by ouabain increased sensitivity of cells to ATP while conditions which inhibit Na+,K+,Cl- -cotransporter activity, such as treatment of the cells with the diuretics furosemide or bumetanide or replacement of sodium chloride in the medium with sodium nitrate or thiocyanate, inhibited permeabilization. The furosemide concentration that inhibited permeabilization was greater than the concentration that inhibited Na+,K+,Cl- -cotransporter-mediated 86Rb+ (K+) uptake, suggesting that the effect of furosemide on the permeabilization process may not be specific for the Na+,K+,Cl- -cotransporter.

The influence of virus transformation and cell population density on some membrane properties of mouse fibroblasts in culture

The influence of cell population density and simian virus 40 transformation on the activity of the Na-K pump was studied in mouse fibroblasts cultured in medium supplemented with fetal bovine serum. The activity of the Na-K pump was determined from K+ influx, ethacrynate-sensitive K+ influx, (Na+ + K+)-ATPase assay, and the determinations of intracellular potassium and sodium ion concentrations in these cells. The activity of the Na-K pump was found to decrease in density-inhibited cultures of normal fibroblasts (designated as 3T3 cells), while in the virus-transformed cells (SV3T3) the activity remained fairly constant at all cell population densities.

Kinetic mechanism of Na+, K+, Cl--cotransport as studied by Rb+ influx into HeLa cells: effects of extracellular monovalent ions

Ouabain-insensitive, furosemide-sensitive Rb+ influx (JRb) into HeLa cells was examined as functions of the extracellular Rb+, Na+ and Cl- concentrations. Rate equations and kinetic parameters, including the apparent maximum JRb, the apparent values of Km for the three ions and the apparent Ki for K+, were derived. Results suggested that one unit molecule of this transport system has one Na+, one K+ and two Cl- sites with different affinities, one of the Cl- sites related with binding of Na+, and the other with binding of K+(Rb+). A 1:1 stoichiometry was demonstrated between ouabain-insensitive, furosemide-sensitive influxes of 22Na+ and Rb+, and a 1:2 stoichiometry between those of Rb+ and 36Cl-. The influx of either one of these ions was inhibited in the absence of any one of the other two ions. Monovalent anions such as nitrate, acetate, thiocyanate and lactate as substitutes for Cl- inhibited ouabain-insensitive Rb+ influx, whereas sulfamate and probably also gluconate did not inhibit JRb. From the present results, a general model and a specialized cotransport model were proposed: In HeLa cells, one Na+ and one Cl- bind concurrently to their sites and then one K+(Rb+) and another Cl- bind concurrently. After completion of ion bindings Na+, K+(Rb+) and Cl- in a ratio of 1:1:2 show synchronous transmembrane movements.

Membrane voltage, resistance, and channel switching in isolated mouse fibroblasts (L cells): a patch-electrode analysis

The whole-cell patch-electrode technique of Fenwick, Marty & Neher (1982) has been applied to single suspension-cultured mouse fibroblasts. Seals in the range of 10-50 G omega were obtained without special cleaning of the cell membranes. Rupture of the membrane patch inside the electrode was accompanied by a shift of measured potential into the range -10 to -25 mV, but in most cases with little change in the recorded resistance. The latter fact implied that the absolute resistance of the cell membrane must be in the same range as the seal resistance and the recorded potential is a poor measure of actual cell membrane potential. Steady-state current-voltage curves (range -160 mV to +80 mV) were generated before and after rupture of the membrane patch, and the difference between these gave (zero-current) membrane potentials of -50 to -75 mV, which represents a leak-corrected estimate of the true cell-membrane potential. The associated slope conductivity of the cell membrane was 5-15 microS/cm2 (assumed smooth-sphere geometry, cells 13-15 microns in diameter) and was K+-dominated. With 0.1 mM (or more) free Ca2+ filling the patch electrode, membrane potentials in the range -60 to -85 mV were observed following patch rupture, with associated slope conductivities of 200-400 microS/cm2, also K+-dominated. Similar voltages and conductivities were observed at the peak of pulse-induced 'hyperpolarizing activation' (Nelson, Peacock, & Minna, 1972), and the two phenomena probably reflect the behaviour of Ca2+-activated K+ channels. Both the pulse-induced conductance and the Ca2+-activated conductance spontaneously decayed, the latter over periods of 5-15 min following patch rupture. Sr2+, Ba2+, and Co2+ could also activate the putative K+ channels, but only Sr2+ really mimicked Ca2+. Co2+ and Ba2+ activated with a delay of several minutes following patch rupture, and deactivated quickly with a small decrease of conductance and a large decrease of membrane potential. Evidently, Co2+ and Ba2+ affect channel specificity as well as channel opening and closing kinetics.

Potassium-chloride cotransport in cultured chick heart cells

The polystrand preparation of cultured chick heart cells has a unidirectional transmembrane Cl- efflux that is twice K+ efflux. However, Cl- conductance of this heart cell membrane is low [regardless of extracellular K+ (K+o)], suggesting the existence of electroneutral Cl--dependent transport mechanisms. Furosemide (10(-3) M) decreases the 36Cl tracer efflux rate constant from a control value of 0.67 to 0.33 min-1. Extracellular Na+--free solution, which depletes intracellular Na+ within 1 min, has no significant effect on 36Cl efflux. K+o-free solution plus 4,4'-diisothiocyanostilbene-2,2'-disulfonic acid (DIDS; 10(-4) M) promotes the loss of Cl- against the Cl- electrochemical gradient; Cl- loss is furosemide sensitive in a dose-dependent manner. Incubating polystrands in 133 mM K+o, normal extracellular Cl- (Cl-o) solution causes net K+ and Cl- uptake in a 1:1 stoichiometry as well as a furosemide-sensitive volume increase; 130 mM extracellular choline or Li+ cannot mimic this high-K+o-induced volume increase. Removal of Cl-o from 133 mM K+o solution prevents K+ uptake and causes a Cl- loss as well as a furosemide-sensitive volume decrease. Adjusting Cl-o concentrations in high-K+o solution plus DIDS, so that the Cl- chemical gradient equally opposes the K+ chemical gradient, prevents high-K+o-induced volume changes. These data suggest that the cardiac cell membrane contains a furosemide-sensitive K+-Cl- cotransport mechanism.

Kinetic parameters and mechanism of active cation transport in HeLa cells as studied by Rb+ influx

On incubation of HeLa cells in chilled isotonic medium, intracellular Na+ (Nac+) increased and K+ (Kc+) decreased with time, reaching steady levels after 3 h. The steady levels varied in parallel with the extracellular cation concentrations ([Na+]e, [K+]e). The cell volumes and the protein and water contents, respectively, of cells kept for 3 h in chilled media of various [Na+]e and [K+]e were not significantly different. Ouabain-sensitive Rb+ influx took place at the initial rate for a certain period which depended on [Na+]c at the beginning of the assays. The existence of two external K+ loading sites per Na+/K+-pump was demonstrated. The affinities of the sites for Rb+ as a congener of K+ were almost the same. Na+e inhibited ouabain-sensitive Rb+ influx competitively, whereas K+ was not inhibitory. Kinetic parameters were determined: the K 1/2 for Rbe+ in the absence of Na+e was 0.16 mM and th Ki for Na+e was 36.8 mM; the K 1/2 for Na+c was 19.5 mM and the Ki for K+c seemed to be extremely large. The rate equation of the ouabain-sensitive Rb+ influx suggests that Na+ and K+ are exchanged alternately through the pump by a binary mechanism.

Membrane potentials, electrolyte contents, cell pH, and some enzyme activities of fibroblasts

The resting membrane potential of the cultured fibroblasts derived from rabbit subcutaneous tissues was -10.2 +/- 0.20 mV (n = 390). This potential was affected by the potassium concentration in the culture medium, but not by other chemical or hormonal preparations, such as dibutyryladenosine 3',5'-cyclic monophosphate (0.5 to 5.0 mmol/l), sodium fluoride (10(-5) to 10(-4) M), hydrocortisone (10(-7) to 10(-6) M), parathyroid extract (0.5 to 1.0 U/ml), or thyrotrophin (5 to 10 mU/ml). The Na+, K+, and Cl- concentrations of the cultured fibroblasts were 35.4, 85.7, and 22.6 mmol/l cell water, respectively. The water and protein contents of these cells were 82.1 and 9.18 g/100-g cells, respectively. The intracellular pH of fibroblasts as determined by [14C] dimethyloxazolidine-2, 4-dione, and 3H2O ranged between 6.9 and 7.1 when the pH of the culture medium was maintained at 7.4. The activities of Na+, K+-, HCO3(-)-, and Ca++, Mg++-ATPases in these cultured cells were 19.0 +/- 2.1, 13.6 +/- 2.1, and 6.6 +/- 1.2 nmol pi/mg protein per minute, respectively, and the carbonic anhydrase activity was 0.054 U/mg protein. Calculations based on the values for the membrane potential and the electrolyte concentrations observed in this study indicate that Na+, K+, Cl-, and H+ are not distributed according to their electrochemical gradients across the cell membrane. Na+, Cl-, and H+ are actively transported out of the cells and K+ into the cells.

Rapid changes in bidirectional K+ fluxes preceding DMSO-induced granulocytic differentiation of HL-60 human leukemic cells

When grown in medium containing 5 mM potassium and 140 mM sodium, HL-60, a human promyelocytic cell line, maintained a steady-state intracellular K+ concentration of 145 mmol/L cells and a steady-state intracellular Na+ concentration of 30 mmol/L cells. Nearly 90% of the unidirectional 42K+ influx could be inhibited by the cardiac glycoside ouabain with a Ki of 5 X 10(-8) M. This ouabain-sensitive component of influx rose as a saturating function of the extracellular K+ concentration with a K1/2 of 0.85 mM. The component of 42K+ influx resistant to ouabain inhibition was a linear function of the extracellular K+ concentration and was insensitive to inhibition by the diuretic furosemide. Unidirectional K+ efflux followed first order kinetics with a half-time of 55 min. Addition of 1.5% dimethyl sulfoxide (DMSO) to a culture of HL-60 cells allowed two population doublings followed by the cessation of growth without an impairment of cell viability. Beginning 2 to 3 days after DMSO addition, the cells underwent a dramatic reduction in volume (from 925 microns 3 to 500 microns 3) and began to take on the morphological features of mature granulocytes. Throughout this process of differentiation there was no change in the intracellular sodium or potassium concentration. However, immediately following the addition of DMSO to a culture of cells, there began an immediate, coordinated reduction in bidirectional K+ flux. The initial rate of the ouabain-sensitive component of K+ influx fell with a half-time of 11 h to a final rate, at 6 days induction, equal to one ninth that of the uninduced control, and over the same period, the rate constant for K+ efflux fell with a half-time of 14 h to a final value one fourth that of the uninduced control. The rapidity with which these flux changes occur raises the possibility that they play some role in the control of subsequent events in the process of differentiation.

Cellular responses to external ATP which precede an increase in nucleotide permeability in transformed cells

Transformed mouse fibroblasts, such as 3T6, exhibit an increase in plasma membrane permeability to nucleotides and other normally impermeant molecules when incubated with external ATP in an alkaline medium low in divalent cations. Increased nucleotide permeability, induced by external ATP, occurs after a 3- to 5-min lag period. Prior to this event, there is a dramatic Na+ influx and K+ efflux, a significant reduction in the levels of intracellular ATP and organic phosphates, and a reduction in the plasma membrane potential. Accordingly, we postulate that these cellular responses to external ATP play a role in the efflux of nucleotides. Ouabain, a specific inhibitor of the plasma membrane (Na+,K+)-ATPase, acts together with low concentrations of external ATP to increase nucleotide permeability in 3T6 cells. This effect occurs at concentrations of ouabain and ATP which alone do not increase nucleotide permeability. In addition, ouabain and low concentrations of ATP alone have little effect on the level of intracellular ATP. This is in contrast to energy inhibitors and uncouplers which appear to enhance nucleotide permeability by lowering the intracellular ATP concentration. Ouabain alone causes a threefold increase in intracellular Na+ levels and a similar reduction in intracellular K+ levels under our experimental conditions, supporting the idea that ion fluxes are involved in the mechanism of permeabilization.

ATP content in isolated mammalian nerve cells assayed by a modified luciferin-luciferase method

ATP content in a nerve cell isolated from dorsal root ganglia of adult guinea-pigs by collagenase was measured by a newly developed technique modified from the conventional luciferin-luciferase methods. A small volume (4 microliters) of the nerve cell suspension, which contained 10-300 nerve cells (3-100 X 10(-4) microliters of cellular volume) under view of an inverted, phase-contrast microscope, was heat-treated for about 1 s by flame of an alcohol lamp. This heat-treated cell suspension was then reacted with a luciferin-luciferase solution. Light flux from the bioluminescence thus elicited gave an ATP content in single nerve cell, 27 pg (mean) +/- 10 pg (S.D.). ATP concentration in a nerve cell was calculated as 1.7 mM (mean) +/- 0.6 mM. The ATP content in a nerve cell was reduced when the nerve cells were exposed to KCN (5 microM) or dinitrophenol (20 microM), respectively.

Low-frequency voltage noise in a mammalian bone cell clone

Measurements were made of plasma membrane voltage noise in cells of a bone cell clone. The measurements were made under conditions intended to approximate in vivo conditions more closely than in previous electrical measurements on small mammalian cells. Mononucleate cells of normal size, imbedded in a collagen matrix, were used. The electrical state of the cell membrane under normal conditions was characterized by low-frequency random fluctuations (noise) of high magnitude. Hyperpolarizing spikes were observed in some cells. Power spectrum analysis revealed that the random fluctuations were actually a sum of incoherent spike patterns, with spikes of the same time width as those seen in the clearly spiking patterns. This analysis, combined with similar measurements in a high [K+], low [Na+] medium, showed that the fluctuation/spiking phenomenon resulted from modulation of K+ and Na+ transport by a control process at a level higher than that of the individual channels. This process persisted when the membrane potential was depolarized. These results indicate that the membrane potential is not part of the feedback loop producing the fluctuation/spiking phenomenon.

Cation exchange and glycoside binding in cultured rat heart cells

The Na/K-exchange characteristics, ouabain-binding kinetics, and Na pump turnover rates of synchronously contracting monolayers of neonatal rat myocardial cells were studied. The cells exchange Na rapidly (T1/2 = 35 s) with a mean Na flux of approximately 25 (pmol/cm2)/s. The half time (T1/2) of K exchange is much longer (12 min); the mean K flux is 13 (pmol/cm2)/s. Active Na/K transport, as measured by K influx, is relatively ouabain sensitive, and 10(-6) M ouabain produces half-maximal inhibition. Ouabain (10(-2)M) inhibits 60% of the Na efflux and 75% of the K influx. The cells bind [3H]ouabain rapidly (T1/2 = 8 min), but release it very slowly (T1/2 = 11 h), and both the amount bound and the rate of binding were inversely proportional to extracellular K. Specific [3H]ouabain binding demonstrates saturation reaching a maximum of 1.6 x 10(6) molecules per cell at 2 x 10(-7) M [3H]ouabain. From cell surface area and ouabain-sensitive flux measurements, the Na pump density was calculated at 720/micrometer2 with an individual pump turnover rate of 50/s. Thus the studies indicate that despite their neonatal origin, the behavior of the Na pump in these cells is very similar to that in other mammalian tissues.

Genetic alterations in potassium transport in L cells

Starting with mutagenized cultures of the mouse fibroblastic cell line LM(TK-), we have selected mutant clones by their ability to grow at 0.2 micrometer K+, a concentration unable to support the growth of the parent cell. The mutants fall into two classes on the basis of their potassium transport properties. Both classes maintain a high intracellular K+ concentration when growing in low-potassium medium, and both are unaltered in the ouabain-sensitive Na/K pump. One class shows an increased activity of a ouabain-resistant, furosemide-sensitive K+ transport system; the other class shows a decreased activity of a specific component of K+ efflux.

Inorganic phosphate in Ehrlich ascites tumor cells and its distribution across the cell membrane

A regulatory function of the cell membrane in controlling the cytoplasmic level of Pi has been proposed, and in Ehrlich ascites tumor cells an active influx of primary phosphate has been reported in the literature. In the present study, Ehrlich cells were incubated at 1.5--50 mM extracellular Pi at pH 7.4 (Pi mainly secondary phosphate) and at pH 6.0 (mainly primary phosphate), and the measured cell Pi was compared with the value expected from a passive distribution of Pi. At a low extracellular Pi concentration the cell Pi was 3--6 mumol/g or even more. It is suggested that a major part of this cell Pi can be accounted for by enzymic release of Pi during the sampling procedure. If this interpretation is correct, the present results show that both ionic species of Pi are in electrochemical equilibrium across the cell membrane at steady state. Moreover, in vivo the concentration of free Pi in the cytosol will presumably be maintained at a steady-state level of about 0.4 mM, one order of magnitude below the directly measured values. This implies that the ratio [ATP]/[ADP][Pi] which is important in the regulation of energy metabolism, is higher than reported in the literature.

An altered response of virally transformed 3T3 cells to ouabain

The effect of ouabain on K+ transport was examined in 3T3 and virally transformed 3T3 cells. A 10 min exposure to ouabain (10(-3) M) produced approximately 40% inhibition of the unidirectional K+ influx in all cell lines. In 3T3 cells the response was not significantly altered by up to 70 min exposure to the drug. In contrast, the continued exposure of transformed cells to ouabain produced a time-dependent increase in the K+ influx. This increased influx was shown to be accompanied by an increase in the K+ efflux. The results suggest that, in transformed cells, ouabain produces both an inhibition of Na+-K+ exchange and a stimulation of K+-K+ exchange. The latter was shown to be more readily reversible than the former.

Oscillation of membrane potential in L cells: III K + current-voltage curves

Cultured L cells were found previously to have an oscillating membrane potential. Current-voltage (I--V) curves were measured during these oscillations. Two I--V curves were recorded, one at the maximum and one at the minimum of oscillations. Each curve is nonlinear, and when they are subtracted from one another, the result gives the I--V curve for the K+ current producing oscillations. This Ik--V curve is zero for -85 to -90 mV and saturates for positive and high negative membrane potentials. When the external K+ is increased the I--V curve is shifted and its zero current potential is reduced. The K+ zero current potential follows a Nernst relation when plotted against the external K+ concentration. The Ik--V curves all have a similar shape at different K+ concentrations, showing a saturation on each side of the zero current potential. The results can be explained satisfactorily in term of a carrier model for K+ ions.

Diffusion rates of cell surface antigens of mouse-human heterokaryons. I. Analysis of the population

The rate of appearance, in a newly formed heterokaryon population, of cells bearing completely intermixed mouse and human surface antigens may be used to estimate diffusion constants for antigens on individual cells. From this estimate, it appears that the surface antigens in most cells do not diffuse at the rate expected, but rather move more slowly, by a factor of ten or more, than expected from either measured or calculated diffusion constants for proteins freely mobile in the plane of a lipid membrane. Differences in diffusion rates between cells are not due to effects of Sendai virus, or of trypsin. Restrictions on diffusion are apparently not due to cytochalasin B- or Colcemid-sensitive elements.

Oscillations of membrane potential in L cells. I. Basic characteristics

The membrane potentials and resistances of L cells were measured using a standard electrophysiological technique. The values obtained in physiological media were around--15 mV and 37Momega, respectively. Almost all the large nondividing L cells (giant L cells) showed spontaneous oscillations of the membrane potential between around -15 and -40 mV. Application of an appropriate electrical or mechanical stimulus was also capable of eliciting responses but such were usually induced only once. The total membrane conductance increased significantly and in parallel with such a hyperpolarizing response. Cooling of the cells and application of metabolic inhibitors to the cells completely blocked the spontaneous oscillation despite the fact that the electrically induced hyperpolarizing response remained. Intracellular K+, Na+ and Cl- concentrations were measured by means of a flame photometer and a chloridometer, and the equilibrium potential for each ion was estimated.

Effect of verapamil and of extracellular Ca and Na on contraction frequency of cultured heart cells

Monolayer cultures of myocardial cells were prepared by trypsin dispersion of neonatal rat ventricles. The cells were cultured for 4-5 days by which time a synchronously contracting monolayer of some 1.0 x 10(6) cells per 6-cm diam petri dish had formed. The contraction frequency and Na influx of the cells were unaffected by tetrodotoxin (2 x 10(-5) mg/ml) but both were markedly reduced by the addition of verapamil (10(-9) M to 10(-5) M). The effect of verapamil on both parameters occurred very rapidly. Although unresponsive to change in [Ca]0 between 0.3 mM and 3.0 mM, the contraction frequency of the cells declined rapidly as the [Ca]0 was reduced below 0.3 mM. On the other hand the beating rate of the cells was linearly related to [Na]0 below 40 mM the cells ceased to contract. It is therefore apparent that both [Ca]0 and [Na]0 contribute to the maintenance of the contraction frequency of cultured myocardial cells, but the latter is by far the more important. There also appeared to be, under all conditions, a close relationship between verapamilsensitive Na influx and contraction frequency. For the greater part this relationship was linear although at higher Na influx values it appeared to show evidence of saturation.

Effect of quinidine and temperature on sodium uptake and contraction frequency of cultured rat myocardial cells

The effects of quinidine and temperature on Na influx and contraction frequency of synchronously contracting rat myocardial cells in monolayer cultures were studied. Quinidine (10(-6) M to 10(-1) M) produced a prompt reduction in Na influx, maximum after 30 seconds of exposure, and dose-dependent along a sigmoid log dose-response curve. At 37 degrees C, Na influx (mumol/10(11) cells per sec) decreased from 30.19 to 24.70 (P less than 0.001) and 10.49 (P less than 0.001) on exposure to quinidine, 10(-6) and 10(-2) M, respectively. Simultaneously the contraction frequency decreased from a control of 120/min to 105/min and 48/min with 10(-6) M and 5 X 10(-4) M quinidine. At higher concentrations spontaneous contractions ceased. The effects on Na influx and contraction were reversible by washing the cells free of the drug (30 seconds). A temperature-dependent decrease in the Na influx between 37 degrees C and 22 degrees C also induced a decrease in contraction frequency. Between 25 degrees C and 35 degrees C the Q10 values for Na influx and contraction frequency were 2.41 and 2.44 respectively. Under all conditions tested there was a constant linear relationship (r = 0.98) between Na influx and contraction frequency for all values of Na influx greater than 11.82 mumol/10(11) cells per sec. Na influx and contraction frequency were insensitive to tetrodotoxin (10(-5) g/ml) but very sensitive to verapamil and to changes in extracellular Na. Quinidine affected only the verapamil-sensitive Na influx. The results indicate a close relationship between verapamil-sensitive inward Na movement and automaticity in these cells and demonstrate that the quinidine-induced changes in automaticity are closely linked to the effect on Na influx.

The ionic basis of the membrane potential in a rat glial cell line

Intracellular ionic concentrations, membrane potential and Na+ and K+ flux were measured in a clonal rat glial cell line, C6. Intracellular concentrations of C6 cells were: (mmole/liter cell water) K+ 145 +/- 4 S.D., Na+ 18 +/- 4 S.D., Cl- 14 +/- 1 S.D. Cells maintained a steady state level of K+ over the duration of the experiments. This was substantiated by the close agreement between absolute values for K+ influx and efflux measured with 42K. When cells were depleted of internal Na+, K+ influx was significantly reduced suggesting that a portion of inward K+ movement is linked to Na+ extrusion. Efflux of Na+, calculated from the half-time of exchange from cells preloaded with 22Na, was higher than passive Na+ influx determined by blocking Na+ extrusion with ouabain. Since cell Na+ concentration remained relatively constant, part of the Na+ efflux may be due to exchange diffusion. The average membrane potential of C6 cells uas -36 mV. The potential showed a 31 mV slope for a 10-fold change in external K+ so that it is determined predominantly by the ratio of external/internal K+. The potential however, consistent with the relatively large passive Na+ influx, was influenced by Na+. Replacing all but 20 mM external Na+ with choline hyperpolarized the membrane by 13 mV. The ratio of PNa/PK of 0.11 suggests that Na+ is outwardly transported to maintain the steady-state concentrations observed. Since these responses are similar to those in non-tumor glia, it suggests that the C6 cell line may provide a useful model for studying ionic regulation in glial cells.

Regulation of cellular growth by sodium pump activity

Cellular growth has been found to be directly related to the amount of sodium pumping activity in mouse lymphoblasts (L5178-Y) cultured in varying concentrations of the cardiac glycoside, ouabain. No short-term adaptation (within one generation) occured; i.e., neither growth rate nor (Na+ + K+)-ATPase activity increased in cells cultured for 1-2 days in ouabain. Growth inhibition commenced after two hours, occurring concomitantly with decreased 3H-leucine incorporation into protein. The time course of this inhibition of protein synthesis, measured by leucine incorporation was similar to, but slightly slower than the time course or the dissipation of the sodium gradient. On the other hand, 3H-thymidine incorporation is unaffected by ouabain treatment over the same period. The uptake of 3H-alanine, a neutral amino acid thought to be transported via a Na+-dependent carri-r, was depressed concurrently with the sodium gradient dissipation. It is suggested, therefore, that ouabain inhibition of cellular growth results primarily from the dissipation of the sodium gradient leading to decreased Na+-dependent transport of amino acids (e.g., alanine) and, therefore, decreased protein synthesis, as observed by leucine incorporation. A sensitive and rapid method for determining ouabain inhibition of cell volume regulation is also described, which may prove potentially useful for assaying Na pump activity.

Ionic fluxes in isolated epithelial cells of the abdominal skin of the frog Leptodactylus ocellatus

Unidirectional ion fluxes are measured in cells isolated by a trypsination-dissection method from the epithelium of the frog Leptodactylus ocellatus. Potassium seems to be contained in a single cellular compartment. The influx of potassium is 0.0068 mumole min-1 mg-1 of dry weight and is carried by a ouabain-sensitive pump. Sodium seems to be contained in two cellular compartments, one of which does not exchange its Na within the experimental period. The possibility that these compartments reflect the existence of different types of cells is not discarded. 49% of the rate constant for the Na efflux is ouabain-sensitive and 23% is ethacrynic-sensitive. Under control conditions the permeability to potassium (PK), sodium (PNa) and chloride (PC1) are 7.6 X 10(-5), 2.6 X 10(-5) and 2.8 X 10(-5) liters/min mg, respectively. The value of PNa is much higher than predicted by current electrical models of the epithelium. The discrepancy might offer some insight into the nature of the "inner facing barrier" of the skin.

The early effects of ouabain on potassium metabolism and rate of proliferation of mouse lymphoblasts

Murine lymphoblasts grown in suspension culture in the presence of ouabain showed a dose dependent and sequential decrease in 86Rb+ (K+ analogue) influx, cellular potassium content, and growth rate. An increase in eosin staining and a decrease in cell number was observed after two hours in the presence of 1 mM ouabain; 1 muM ouabain was without effect on any of the parameters measured. Ouabain inhibition was rapidly and completely reversible at concentrations that were not cytotoxic.

Adaptation of potassium metabolism and restoration of mitosis during prolonged treatment of mouse lymphoblasts with ouabain

The effects of ouabain on the growth of murine lymphoblasts in vitro have been studied. Exposure of cells to ouabain (0.1 mM) initially inhibited 86Rb+ uptake rate, reduced the intracellular potassium concentration, and decreased population growth rates. Continued exposure to the same ouabain concentration resulted in an increase of 86Rb+ uptake rate, intracellular potassium content and population growth rates to control values (adaptation). When treated cells were resuspended in medium free of ouabain after 12 to 15 hours of ouabain treatment, 86Rb+ uptake rates and intracellular potassium levels exceeded those of untreated cells. Adaptation was inhibited by cycloheximide (3 mug/ml) and by actinomycin D (0.05 mug/ml). Kinetic analysis of transport suggested that while the total capacity of the Na/, K+ transport system increased, the affinity for both the cation (86Rb+) and ouabain decreased.

Evidence for the genetic control of the sodium pump density in HeLa cells

1. HeLa cells were grown in normal and altered growth solutions; the ion contents, volumes, K sensitive ouabain binding, the Na-K-ATPase and the Na and K transport measured.2. Cells grown in 1 x 10(-4)M ethacrynate or low-K media for 24 hr have a raised [Na](i), a decreased [K](i), and an increased ouabain binding. Those grown in low-K also have an increased Na-K-ATPase activity.3. When cells are put into low-K solutions the [Na](i) initially rises to a high value, and then starts to fall some 8 hours later as the ouabain binding increases, suggesting that these additional sites represent working Na pumps. Flux measurements on low-K cells provide some support for this view.4. Experiments in which sorbitol replaced [Na](o) showed that the increased ouabain binding and Na-K-ATPase was related to the increase in [Na](i) rather than the decrease in [K](i) and was not due to a non-specific effect of [K](o) change.5. The protein synthesis inhibitors cycloheximide and puromycin stopped the effect of ethacrynate and low-K solutions on increased ouabain binding. They also decreased the ouabain binding and K influx in normal cells over 24 hr. Cycloheximide had similar effects on Na-K-ATPase in low-K treated and normal cells. These results suggest that protein synthesis is required for the appearance of more ouabain sensitive sites in the cell membrane, both in response to ethacrynate and low-K treatment and for normal replacement during the cell's life.6. The RNA synthesis inhibitors actinomycin D (AMD) and cordycepin had complex effects on ouabain binding in fresh and ethacrynate treated cells. These inhibitors increased the ouabain binding but decreased the K influx. This discrepancy was due to the appearance of ouabain binding sites with different characteristics from normal sites. A limited investigation of this phenomenon was carried out. Probably AMD stops the normal replacement of sites in the membrane.7. These results are consistent with the hypothesis that HeLa cells have a system for controlling the number of Na pumps in their membranes. This system responds to the level of [Na](i) within the cell and involves protein synthesis. It is not clear to what extent the nucleus is normally involved in this process.

Transmission on an active electrical response between fibroblasts (L cells) in cell culture

An active electrical response, the hyperpolarizing activation or H.A. response, is characteristic of L cells (a continuous line of fibroblasts) and is transmitted in a decremental manner between contiguous cells. Direct electrical coupling between pairs of L cells occurs occasionally, but transmission of the active electrical response is not dependent on such electrical connections. Some L cells are sensitive to acetylcholine but the transmitted response is not dependent on a cholinergic mechanism. 5-Iodosalicylate blocks the active electrical response. The response can be elicited readily by mechanical stimuli, and thus can serve both as a mechanical and chemical receptor mechanism and as a means of communication between cells.

Ionic transport and membrane potential of rat liver cells in normal and low-chloride solutions

1. The ouabain-sensitive component of Na efflux and K influx amount to 58 and 72% respectively. Taking into account also (a) the diffusional passive fluxes of Na (5%) and K (13%), as estimated by Ussing's equation and (b) the ouabain-insensitive Na-Na exchange (28%), 85% (K) and 90% (Na) of the measured total fluxes can be accounted for.2. Na efflux is diminished when K is partially or totally removed from the medium. This effect is reversible, indicating probably activation of the Na pump by external K.3. The coupling ratio of Na and K ouabain-sensitive fluxes is equal to 1.58, suggesting that three Na ions are removed from and two K ions are carried into the cell in one cycle of the pump. Hence, in liver cell membranes, the Na pump must be electrogenic.4. A tenfold decrease in [Cl](o) by substitution with an impermeant anion results in a membrane hyperpolarization and a decrease in [Cl](i). Cl loss from the liver is compensated by an equivalent loss of intracellular K to preserve electroneutrality.5. The measurement of passive fluxes indicates that Cl removal from the perfusing solutions increases P(K) but does not alter P(Na).6. Addition of ouabain brings about a depolarization which is three times greater in low-Cl solutions (21.9 mV) than in normal-Cl solutions (6.8 mV).7. It is concluded that hyperpolarization which develops when Cl ions are removed can be accounted for entirely by (a) the increase in P(K), (b) the increase of the contribution of the electrogenic pump to membrane potential.

Ion levels and membrane potential in chick heart tissue and cultured cells

Intracellular concentrations of sodium and potassium as well as resting potentials and overshoots have been determined in heart tissue from chick embryos aged 2-18 days. Intracellular potassium declined from 167 mM at day 2 to 117-119 mM at days 14-18. Intracellular sodium remained nearly constant at 30-35 mM during the same period. The mean resting potential increased from -61.8 mV at day 3 to about -80 mV at days 14-18. The mean overshoot during the same period increased from 12 to 30 mV. P(Na)/P(K) calculated from the ion data and resting potentials declined from 0.08 at day 3 to 0.01 at days 14-18. Thus, the development of embryonic chick heart during days 2-14 is characterized by a declining intracellular potassium concentration and an increasing resting potential and overshoot. Heart cells from 7- to 8-day embryos, cultured either in monolayer or reassociated into aggregates, were compared with intact tissue of the same age. The intracellular concentrations of sodium and potassium were similar in the three preparations and cultured cells responded to incubation in low potassium medium or treatment with ouabain in a manner similar to that of intact tissue. Resting potentials and overshoots were also similar in the three preparations.

Uptake of ( 3 H)ouabain and Na pump turnover rates in cells cultured in ouabain

1. The binding of [(3)H]ouabain to fresh Girardi and Hela cells and to those cultured in low concentrations of ouabain for 24 hr has been measured.2. Fresh cells bind 1.6-2.2 x 10(6) molecules of ouabain(*) per cell from K-free Krebs, but less than 0.3 x 10(6) molecules from 15 mM-[K](o) Krebs. The ouabain(*) binds with a t((1/2)) of about 8 min from K-free 2 x 10(-7)M ouabain(*) and is released with a t((1/2)) of about 20 hr. Cells in a poor condition probably exchange ouabain more quickly.3. Cells incubated in ouabain(*) for 24 hr bind ouabain in amounts dependent on the [ouabain] and the external [K]. At the highest [ouabain] used the total amount bound exceeds that bound by fresh cells. Lowering [K](o) in the medium increases the maximum ouabain which is bound.4. Cells incubated in ouabain(*) for 24 hr bind an additional amount of ouabain when exposed to 2 x 10(-7)M ouabain(*) in K-free Krebs.5. There is a close relationship between the% of the total ouabain bound in 24 hr and the% inhibition of the Na efflux suggesting that this ouabain is bound to the Na pumps.6. Radiochromatography of the counts recovered from the cells showed that it migrated to the same place as the applied [(3)H]ouabain. The wash-off rate of ouabain bound to cells during incubation is similar to that from fresh cells, both tests suggesting that the ouabain exists in the same state in the cells.7. The number of Na ions extruded per pump is constant at about 60 sec(-1) in fresh cells and those pre-incubated in ouabain.8. The total ouabain bound by the cells is closely related to the [Na](i) in cells pre-incubated in ouabain but is unaffected by it in fresh cells where [Na](i) is raised acutely.9. These results are compatible with the hypothesis that partial blocking of Na pumps leads to the production of more pumping sites by the cell.

Effect of prolonged ouabain treatment of Na, K, Cl and Ca concentration and fluxes in cultured human cells

1. Girardi and Hela cells (derived from human heart and cervix respectively) were grown as monolayer cultures in B.M.E. (Eagles basal medium) containing concentrations of ouabain up to 5 x 10(-8)M for periods ranging up to 5 days. The cell sizes, numbers, Na, K, Cl, and Ca concentrations and fluxes were then measured.2. Twenty-four hours incubation in ouabain concentrations equal to or less than 5 x 10(-8)M caused a rise in [Na](i) and an almost equal fall in [K](i) to new steady levels. The concentrations so reached were linearly related to the ouabain concentrations, such that in 5 x 10(-8)M ouabain [Na](i) rose to 124 m-mole/l. intracellular water and [K](i) fell to 55 m-mole/l. i.c. water in Girardi cells. In Hela cells the changes were smaller at any particular ouabain concentration. These levels were maintained constant for at least 5 days.3. In cells in the logarithmic phase of growth, raising [Na](i) and lowering [K](i) by ouabain caused a slowing of growth rate proportional to the ouabain concentration used. In cells in the stationary phase there was no change in the cell numbers over 24 hr. The volume of the cells was not directly affected by the treatment.4. Reducing [K](o) from the normal value of 5.4 to 2.5 mM increased the effect of any ouabain concentration, whereas increasing [K](o) to 7.5 decreased the effect of ouabain.5. Reduction of [K](o) to 2.5 mM had no effect on the [K](i) or [Na](i) but halved the cell numbers, probably by a reduction in the growth rate. The mechanism of this effect is obscure.6. In Girardi cells raising [Na](i) and lowering [K](i) by prolonged treatment increases the total Na fluxes and decreases the total K fluxes but keeps the total Na + K flux constant. High-Na, low-K cells had a reduced Na:K exchange compared to fresh cells and also had a Na:K pumped ratio nearer 4:1 than the 3:2 normally found.7. These cells also show ouabain-sensitive and ouabain-insensitive Na:Na exchanges. In high-Na, low-K cells the ouabain sensitive Na:Na exchange is the same as in fresh cells. The effect of treatment on the ouabain insensitive Na:Na exchanges has not been elucidated.8. The Cl content and fluxes are not altered by prolonged ouabain treatment. From this it is inferred that the membrane potential in high-Na, low-K cells is the same as in normal cells.9. High-Na, low-K cells have the same calcium content and fluxes as fresh cells. From this it is concluded that there is no Na:Ca coupling in these cells.

An active electrical response in fibroblasts

L cells have a resting potential of about -16 mv (internal negative) at 37 degrees C in Dulbecco's modified Eagle's medium containing 10% fetal calf serum and a potassium concentration of 5.4 mM. Membrane resistivity is about 20,000 ohmcm(2) when the surface filopodia described by others are taken into account. Mechanical and electrical stimuli can evoke an active response from mouse L cells, cells of the 3T3 line, and normal fibroblasts which we have termed hyperpolarizing activation or the H.A. response. This consists of a prolonged (3-5 sec) increase in the membrane permeability by a factor of 2-10 with a parallel increase in membrane potential to about -50 mv. The reversal potential for the H.A. response is -80 mv. The resting cells are depolarized to about -12 mv when the external medium contains 27 mM potassium, and the potential reached at the peak of the H.A. response is about -30 mv. The reversal potential for the H.A. response is about -40 mv in 27 mM external potassium. This effect of potassium ions on the reversal potential of the H.A. response leads us to conclude that the response represents an increase in membrane permeability, predominantly to potassium, by at least a factor of five. This increase must be greater than 20-fold if previous measurements of the ratio of potassium permeability to chloride permeability in L cells are valid for the preparation used in the present study.

Effect of Na, metabolic inhibitors and ATP on Ca movements in L cells

1. The Ca movements in normal and ;ghost' L cells have been examined; all measurements were made using (45)Ca.2. Normal cells have a Ca concentration of about 1 m-mole/l. of cell volume, and exchange Ca in a complex way but with great rapidity; the time taken for the initial Ca(*) content to fall to half was less than 2 min.3. Poisoning normal cells with DNP 10(-3)M + IAA 10(-4)M causes a marked reduction in the Ca efflux, no change in Ca influx and an increase in total Ca.4. Variation in internal or external Na concentration does not alter the Ca fluxes or concentrations. Application of cyanide or ouabain and alteration of external K concentration had no effect on the Ca fluxes.5. The sulphydryl reagents, ethacrynic acid and N-ethylmaleimide (NEM), have a rapid and marked effect on reducing the Ca efflux.6. L cell ghosts previously poisoned with DNP+IAA have a low Ca efflux. When ATP or CTP is incorporated into such cells the Ca efflux becomes normal.7. An extra amount of phosphate is produced by L cell ghosts when pumping Ca. This is equivalent to the splitting of 1.8 moles of ATP per mole of Ca pumped.8. It is concluded that L cells have a Ca pump driven by ATP, and that Na has no effect on Ca movements in these cells.

The membrane potential and permeabilities of the L cell membrane to Na, K and chloride

1. The chloride content and fluxes, and the membrane potential of L cells have been measured.2. L cells contain chloride, 70 m-mole/l. intracellular water and have a flux of 5.5 p-mole/cm(2) sec.3. The membrane potential is -15 mV.K-free Krebs causes an increase in E(m) and replacing chloride with sulphate causes a temporary reduction in E(m).4. These values for E(m) and chloride, and previously obtained values for Na and K fluxes and contents were used to calculate the permeabilities of the various ions using the Goldman constant field theory. This gave permeabilities of 6.3, 4.2 and 51 x 10(-9) cm/sec for K, Na and chloride respectively, a ratio of 1:0.67:8.10.5. It is concluded that these cells have a low membrane potential because the P(K) is some 100 times lower than in skeletal muscle, therefore leading to a P(K) of the same order as P(Na).