Kinetic properties of sodium transport pathways in the river lamprey Lampetra fluviatilis erythrocytes

To activate Na+/H+ exchange, intracellular pH (pHi) of erythrocytes of the river lamprey Lampetra fluviatilis were changed from 6 to 8 using nigericin. The Na+/H+ exchanger activity was estimated from the values of amiloride-sensitive components of Na+ (22Na) inflow or of H+ outflow from erythrocytes. Kinetic parameters of the carrier functioning were determined by using Hill equation. Dependence of Na+ and H+ transport on pHi value is described by hyperbolic function with the Hill coefficient value (n) close to 1. Maximal rate of ion transport was within the limits of 9-10 mmol/l cells/min, and the H+ concentration producing the exchanger 50% activation amounted to 0.6-1.0 microM. Stimulation of H+ outcome from acidified erythrocytes (pHi 5.9) with increase of H+ concentration in the incubation medium is described by Hill equation with n value of 1.6. Concentration of Na+: for the semimaximal stimulation of H+ outcome amounted to 19 mM. The obtained results indicate the presence in lamprey erythrocytes of only one binding site for H+ from the cytoplasm side and the presence of positive cooperativity in Na+ binding from the extracellular side of the Na+/H+ exchanger. Its efflux from cells in the Na+ -free medium did not change at a 10-fold increase of H+ concentration in the incubation medium. The presented data indicate differences of kinetic properties of the lamprey erythrocyte Na+/H+ exchanger and of this carrier isoforms in mammalian cells. In intact erythrocytes the dependence of the amiloride-sensitive Na+ inflow on its concentration in the medium is described by Hill equation with n 1.5. The Na+ concentration producing the 50% transport activation amounted to 39 mM and was essentially higher as compared with that in acidified erythrocytes. These data confirm the concept of the presence of two amiloride-sensitive pathways of Na+ transport in lamprey erythrocytes.     

The effect of an experimental neoplastic disease on the flux of sodium and potassium ions across red blood cells and on the lipid composition of their membranes.

The erythrocytes from Morris Hepatoma 5123 bearing rats took up Na+ and K+ ions from the incubation medium and released Na+ into the extracellular space at lower rates than did erythrocytes from intact control rats. The lipid composition of erythrocytes membranes from the tumor-bearing rats differed from that of membranes from unaffected rats, showing increased contents of phospholipid phosphorus and a decreased content of cholesterol, resulting in decreased cholesterol:phospholipid molar ratios.     

Amiloride-sensitive sodium transport in lamprey red blood cells: evidence for two distinct transport pathways

To determine Na+/H+ exchange in lamprey erythrocyte membranes, the cells were acidified to pH(i) 6.0 using the K+/H+ ionophore nigericin. Incubation of acidified erythrocytes in a NaCl medium at pH 8.0 caused a considerable rise in 22Na+ influx and H+ efflux during the first 1 min of exposure. In addition, exposure of acidified red cells to NaCl medium was associated with rapid elevation of intracellular Na+ content. The acid-induced changes in Na+ influx and H+ efflux were almost completely inhibited by amiloride and dimethylamiloride. In native lamprey erythrocytes, amiloride-sensitive Na+ influx progressively increased as the osmolality of incubation medium was increased by addition of 100, 200, or 300 mmol/l sucrose. Unexpectedly, the hypertonic stress induced a small, yet statistically significant decrease in intracellular Na+ content in these cells. The reduction in the cellular Na+ content increased with hypertonicity of the medium. The acid- and shrinkage-induced Na+ influxes were inhibited by both amiloride and 5-(N-ethyl-N-isopropyl)-amiloride (EIPA) in a dose-dependent manner. For both blockers, the half-maximal inhibitory values (IC50) were much greater for the shrinkage-induced (44 and 15 micromol/l for amiloride and EIPA, respectively) than for the acid-induced Na+ influx (5.1 and 3.3 micromol/l, respectively). The data obtained are the first demonstration of the presence of a Na+/H+ exchanger with high activity in acidified (pH(i) 6.0) lamprey red blood cells (on average, 512 +/- 56 mmol/l cells/h, n = 13). The amiloride-sensitive Na+ influxes produced by hypertonic cell shrinkage and acid load are likely to be mediated by distinct ion transporters in these cells.     

Effect of potassium depletion of Hep 2 cells on intracellular pH and on chloride uptake by anion antiport

The effect of K+ depletion of Hep 2 cells on ion fluxes, internal pH, cell volume, and membrane potential was studied. The cells were depleted of K+ by incubation in K+-free buffer with or without a preceding exposure to hypotonic medium. Efflux of K+ in cells not exposed to hypotonic medium was inhibited by furosemide or by incubation in Na+-free medium, indicating that in this case at least part of the K+ efflux occurs by Na+/K+/Cl- cotransport. After exposure to hypotonic medium, K+ efflux was not inhibited by furosemide, whereas it was partly inhibited by 4,4'-diisothiocyano-2,2'-stilbene-disulfonic acid (DIDS). Exposure to hypotonic medium induced acidification of the cytosol, apparently because of efflux of protons from intracellular acidic vesicles. When isotonicity was restored, a rebound alkalinization of the cytosol was induced, because of activation of the Na+/H+ antiporter. While hypotonic shock and a subsequent incubation in K+-free buffer rapidly depolarized the cells, depolarization occurred much more slowly when the K+ depletion was carried out by incubation in K+-free buffer alone. The cell volume was reduced in both cases. K+ depletion by either method strongly reduced the ability of the cells to accumulate 36Cl- by anion antiport, and K+-depleted cells were unable to increase the rate of 36Cl- uptake in response to alkalinization of the cytosol.     

Mechanism of the change in erythrocyte osmotic resistance in rats exposed to valinomycin: the features seen in spontaneous hypertension

Introduction of valinomycin into erythrocyte incubation medium increased the cell stability to water-induced hemolysis. In these conditions the erythrocytes of spontaneously hypertensive and normotensive (control) rats release 63.2 +/- 1.5% and 80.9 +/- 1.6%, respectively, of the total hemoglobin content. Valinomycin effect is completely abolished with K+ substitution for Na+ and is independent of extracellular Ca2+ concentration. Valinomycin had no effect on human erythrocyte osmotic stability. It has been shown that valinomycin-induced kinetics of Na+ and K+ redistribution was different in human and rat erythrocytes. The distinctions are thought to be related to specific anion transport mediated by the third band protein--the main component of membrane cytoskeleton.     

Ouabain-insensitive net sodium influx in erythrocytes of normotensive and essential hypertensive humans

The Na+ content of erythrocytes is elevated in people with essential hypertension. There is conflicting evidence about its cause. The present study was designed to investigate whether the increase in content is due to a defect in a ouabain-resistant Na+ flux. Net Na+ influx was determined from the increase in Na+ content of erythrocytes during incubation in the presence of ouabain. Na+ content of erythrocytes from 24 normotensive Caucasian subjects with no known family history of hypertension was 6.9 +/- 1.3 mmol per litre of cells. It was 7.9 +/- 2.0 mmol per litre of cells in 18 subjects with essential hypertension. The difference was less and not significant when the two non-Caucasian subjects of the hypertensive group were excluded. Net Na+ influx was 1.83 mmol/h per litre of cells in the normotensive group. In eight subjects it was measured on a second occasion after an interval of several months. The coefficient of a variation of the duplicate tests was 2.4%. Net Na+ influx was significantly higher in the hypertensive group, the value was 2.18 +/- 0.15 mmol/h per litre of cells. In 11 of these subjects, Na+ influx was measured on a second occasion. The coefficient of variation was 6.2%, significantly greater than in the control group. In some of these subjects Na+ influx was within the normal range on one of the two occasions. When the groups were compared with use of the mean values from the duplicate tests, net Na+ influx was elevated in 17 of the 18 hypertensive subjects. The findings are discussed with reference to previous work and in relation to the established facilitatory effects of an increased intracellular Na+ concentration on excitable cells that influence blood pressure.     

Human and dog erythrocytes: relationship between cellular ATP levels, ATP consumption and potassium concentrations.

The intracellular K+/Na+ ratio of various mammalian cell types are known to differ remarkably. Particularly noteworthy is the fact that erythrocytes of different mammalian species contain entirely different potassium and sodium concentrations. The human erythrocyte is an example of the supposedly "normal" high potassium cell, while the dog erythrocyte contains ten times more sodium than potassium ions (Table I). Furthermore, this difference is sustained despite the plasma sodium and potassium concentrations being almost identical in both species (high Na+ and low K+). In spite of these inorganic ion differences, both human and dog erythrocytes contain 33% dry material (mostly Hb) and 67% water. Conventional cell theory would couple cellular volume regulation with Na+ and K+ dependent ATPase activity which is believed to control intracellular Na+/K+ concentrations. Since the high Na+ and low K+ contents of dog erythrocytes are believed to be due to the lack of the postulated Na/K-ATPase enzyme, they must presumably have an alternative mechanism of volume regulation, otherwise current ideas of membrane ATPase activity coupled volume regulation need serious reconsideration. The object of our investigation was to explore the relationship between ATPase activity, ATP levels and the Na+/K+ concentrations in human and dog erythrocytes. Our results indicate that the intracellular ATP level in erythrocytes correspond with their K+, Na+ content. They are discussed in relation to conventional membrane transport theory and also to Ling's "association-induction hypothesis", the latter proving to be a more useful basis on which to interpret results.     

Transport ATPases in the erythrocytes of rats acclimatized to intermittent altitude hypoxia

The activity of Na+/K+- and Ca2+-ATPase and some allosteric properties of Na+/K+-ATPase were studied in whole erythrocytes and their membrane preparations (ghosts) from rats exposed to intermittent altitude hypoxia (10 and 24 exposures, 8 h/day in an altitude chamber, stepwise up to an altitude of 7,000 m). Ca2+-ATPase activity was increased both in whole erythrocytes and ghosts after the first phase of acclimatization (10 exposures). In a standard incubation medium (containing 3 mmol.l-1 MgCl2 ), Na+/K+-ATPase activity in the ghosts was also increased after the initial phase of acclimatization whereas in whole erythrocytes Na+/K+-ATPase was only decreased in the regression phase. At high MgCl2 concentrations (12 mmol.l-1) changes of Na+/K+-ATPase activity both in whole erythrocytes and in the ghosts followed similar time course with a pronounced increase in the first phase of acclimatization (10 exposures) followed by an abrupt drop (24 exposures) and then by a gradual normalization in the regression phase. Sensitivity of the enzyme to mounting MgCl2 concentrations was increased in the ghosts at the end of acclimatization and was decreased in whole erythrocytes during acclimatization and especially in the regression phase. It has been suggested that chronic altitude hypoxia leads to the alteration of cooperative interaction of the Na+/K+-ATPase subunits in the erythrocyte membrane and accumulation of some factor in the cells inhibiting this enzyme.     

Effect of extracellular volume expansion on erythrocyte sodium transport in rats.

The effects of extracellular volume expansion (EVE) on the major sodium transport systems and sodium and potassium contents in rat erythrocytes have been examined in the present study. Study has been performed in anesthetized Wistar rat weighing about 300 g. Acute extracellular volume expansion (EVE) was induced by a constant intravenous saline infusion (3% body wt, 3 hours). Rats anaesthetized and catheterized but not expanded were used as controls. Arterial blood samples from control and expanded rats were obtained at the same time, and assayed immediately. Intracellular sodium and potassium concentration and ouabain sensitive (Na(+)-K(+)-pump) and bumetanide sensitive (Na(+)-K(+)-cotransport system) outward Na+ fluxes in erythrocytes were measured. The effect of plasma on erythrocyte transport was also analyzed by measuring 86Rb uptake. Neither of two plasma cations (Na+ and K+) were modified by the EVE. Also intracellular Na+ and K+ levels remained unvariable. Total Na+ efflux was not modified by EVE, but pump-mediated Na+ efflux was smaller after than before EVE. The ouabain-inhibible Na+ efflux rate constant decreased after EVE (from 687 +/- 81 to 525 +/- 29 h-1 x 10(-3); P less than 0.05). Both Na(+)-K(+)cotransport-mediated Na+ efflux and passive permeability increased significantly after EVE. The incubation with plasma from saline-infused animals induced a significant decrease in Rb uptake rate constant, that was not observed after incubation with plasma from non-expanded rats.(ABSTRACT TRUNCATED AT 250 WORDS)     

Induction of amino acid transport activity in chick embryo fibroblasts by replacement of extracellular sodium chloride with disaccharide

The activity of amino acid transport System A in avian fibroblasts was increased following incubation of the cells in a medium in which most of the NaCl normally present had been isoosmotically replaced by sucrose. This increase was detectable after 2 h of incubation, reached a maximum at about 4 h, and remained constant thereafter. Transfer of treated cells back to a normal medium resulted in decay of the induced transport activity, with a half-life of less than 2 h. Kinetic analysis revealed that the increase in transport activity arose from an increase in Vmax, with little change in Km. This induction of System A activity did not occur if an inhibitor of either RNA or protein synthesis was present in the modified medium. The use of various different solutes as replacements for NaCl in the incubation medium showed that, although each replacement caused a decrease in both cellular Na+ content and protein synthesis, only disaccharides produced the increase in amino acid transport activity. In addition, estimates of cell volume indicated that, even under iso-osmotic conditions, incubation in the sucrose-containing medium caused initial cell shrinkage, followed by swelling. It is concluded that this induction of System A activity is associated with a volume regulatory process and that this process probably accounts for the parallel responses previously observed when cells were incubated in hyperosmolar media. Induction of amino acid transport activity by this process is distinct from adaptive regulation, caused by amino acid starvation; but the two processes are not strictly additive, and so appear to converge at some step.     

Kinetic characteristics of 22Na transport in human and rat erythrocytes during cytoplasm acidification and cell compression

Under normal conditions (pH0 = 7.4, pHi = 7.1-7.2) amiloride, a Na+/H+ exchange inhibitor, does not influence Na+ intake by human and rat erythrocytes. Acidification of the cytoplasm (pHi approximately 6.4) is accompanied by the acceleration of 22Na intake, which is decreased after addition of 1 mM amiloride (by 50 and 80%, respectively). The Ki value of amiloride for human and rat erythrocytes is 30 and 250 microM, respectively. In rat erythrocytes the dependence of the rate of the delta pH-induced incorporation of 22Na on Na+ concentration is described by a saturation curve (K0.5 for Na0+ is approximately 40 mM), whereas in human erythrocytes it obeys the diffusion kinetics. These results suggest that the Na+/H+ exchange takes place in rat erythrocytes, but is absent in human erythrocytes. In rat erythrocytes the Na+/H+ exchange can be induced by cell compression which can be caused either by decreasing the KCl content (after addition of valinomycin) or by increasing the osmolarity of the medium (in the presence of sucrose). The rate of Na+/H+ exchange induced by cell compression is increased by 60-70% after addition of protein kinases A and C activators. No effect of intracellular Ca2+ on the rate of the Na+/H+ exchange in rat erythrocytes is observed.     

Red-cell amino acid transport. Evidence for the presence of system ASC in mature human red blood cells.

The properties of Na+-dependent L-alanine transport in human erythrocytes were investigated using K+ as the Na+ substitute. Initial rates of Na+-dependent L-alanine uptake (0.2 mM extracellular amino acid) for erythrocytes from 22 donors ranged from 40 to 180 mumol/litre of cells per h at 37 degrees C. Amino acid uptake over the concentration range 0.1-8 mM was consistent with a single saturable component of Na+-dependent L-alanine transport. Apparent Km and Vmax. values at 37 and 5 degrees C measured in erythrocytes from the same donor were 0.27 and 0.085 mM respectively, and 270 and 8.5 mumol/litre of cells per h respectively. The transporter responsible for this uptake was identified as system ASC on the basis of cross-inhibition studies with a series of 42 amino acids and amino acid analogues. Apparent Ki values for glycine, L-alpha-amino-n-butyrate, L-serine and L-leucine as inhibitors of Na+-dependent L-alanine uptake at 37 degrees C were 4.2, 0.12, 0.16 and 0.70 mM respectively. Reticulocytes from a patient with inherited pyruvate kinase deficiency were found to have a 10-fold elevated activity of Na+-dependent L-alanine uptake compared with erythrocytes from normal donors. Separation of erythrocytes according to cell density (cell age) established that even the oldest mature erythrocytes retained significant Na+-dependent L-alanine transport activity. Amino acid transport was, however, a more sensitive indicator of cell age than acetylcholinesterase activity. Erythrocytes were found to accumulate L-alanine against its concentration gradient (distribution ratio approx. 1.5 after 4 h incubation), an effect that was abolished in Na+-free media. Na+-dependent L-alanine uptake was shown to be associated with L-alanine-dependent Na+ influx, the measured coupling ratio being 1:1.     

Activation of Na<Superscript>+</Superscript>/H<Superscript>+</Superscript> exchange by protein phosphatase inhibitors in red blood cells of the frog<Emphasis Type="Italic"> Rana ridibunda</Emphasis>

The present study was designed to evaluate the role of protein phosphatases in regulation of sodium transport in the marsh frog erythrocytes using 22Na as a tracer. For this purpose the cells were treated with several known inhibitors of protein phosphatases. In standard isotonic medium, exposure of the cells to 10 mmol l(-1) NaF, 20 nmol l(-1) calyculin A or 0.1 mmol l(-1) cantharidin resulted in a significant (1.7-fold) increase in unidirectional ouabain-insensitive Na+ influx. The Na+ influx in frog red cells was progressively activated as the medium osmolality was increased by addition of 100, 200 or 300 mmol l(-1) sucrose to standard isotonic medium. The stimulatory effect of protein phosphatase blockers on Na+ influx was much higher in hypertonic medium containing 100 or 200 mmol l(-1) sucrose than that in isotonic medium. Stimulation of Na+ transport enhanced with increasing concentrations of calyculin A, and half-maximal activation (EC50) was obtained at 16 nmol l(-1). However, Na+ influx induced by strong hypertonic treatment (+300 mmol l(-1) sucrose) was not altered further in the presence of protein phosphatase inhibitors. The changes in Na+ influx evoked by protein phosphatase inhibitors and hypertonic treatment were associated with a rise in the intracellular Na+, but not K+, content. Enhancement in Na+ influx after addition of protein phosphatase blockers to cell suspension in isotonic or hypertonic media was almost completely inhibited by Na+/H+ exchange inhibitors, amiloride and ethyl-isopropyl-amiloride. The basal Na+ influx in frog erythrocytes in isotonic medium was relatively low (1.7 mmol/l cells/h) and not affected by 1 mmol l(-1) amiloride. Thus, the data obtained clearly indicate that Na+/H+ exchanger in the marsh frog red blood cells is under tight regulatory control, in all likelihood via protein phosphatases of types PP-1 and PP-2A.     

Inhibition of the Na+/K+ cotransport system by cyclic AMP and intracellular Ca2+ in human red cells

Human erythrocytes are able to incorporate cyclic AMP (cAMP) in amounts larger than those required to saturate cAMP-dependent protein kinase. In contrast to previous observations in avian red blood cells in which cAMP stimulates the Na+/K+ cotransport system, we demonstrate that cAMP inhibits this system in human erythrocytes. The cotransport inhibition is enhanced by addition of phosphodiesterase inhibitor 1-methyl-3-isobutylxanthine to the incubation medium. The cAMP concentration giving half-maximal cotransport inhibition showed a wide variation among different individuals (from 0.1 to 5 mM external cAMP concentration). In contrast to cAMP, cyclic GMP showed little effect on the cotransport system. Ca2+ introduced into the cell interior was an inhibitor of the Na+/K+ cotransport system. These results suggest that in human cells in which endogeneous levels of cAMP and Ca2+ are modulated by hormones, the Na+/K+ cotransport system may be under hormonal regulation.     

Regulation of the number of Na+,K+-pump sites after mitogenic activation of lymphocytes

The early activation of Na+,K+-ATPase-mediated ion fluxes after concanavalin A (ConA) stimulation of pig lymphocytes is caused by an increase in intracellular Na+ concentration. A second mechanism of regulation of Na+,K+-ATPase activity becomes apparent between 3 and 5 h after mitogenic stimulation, but prior to onset of increase in cell volume; this consists of an increase (about 75%) in the number of ouabain-binding sites (from 35 X 10(3) +/- 12 X 10(3)/cell in resting to 60 X 10(3) +/- 27 X 10(3)/cell in activated lymphocytes). The increase in ouabain binding was attributed to an increase in the number of active Na+,K+-ATPase molecules, based on the following evidence: there was an increase in the Vmax of ouabain binding, without variation in the Km; the increase in ouabain binding was accompanied by a proportional increase in K+ influx, when the assay was performed in the presence of the Na+ ionophore monesin, which was used to eliminate the difference in intracellular Na+ concentration between resting and activated cells; there was proportionality between ouabain-inhibitable ATPase activity in permeabilized cells and the number of ouabain-binding sites in resting and activated lymphocytes. The ConA-induced increase in ouabain-binding sites was influenced neither by amiloride nor by incubation in low Na+ medium, under conditions which prevented both increase in intracellular Na+ concentration and K+ influx. Increase in intracellular Na+ concentration was ineffective in altering the number of active pump molecules in resting cells. During incubation with ConA, the presence of ouabain did not affect the increase in ouabain-binding sites; thus, regulation of the number of pump sites is independent of the regulation of their activity. The ConA-induced increase in number of ouabain-binding sites did not require protein synthesis; indeed, cycloheximide, anisomycin, and puromycin, under conditions in which they inhibited protein synthesis by by 95%, induced the increase to approximately the same extent as did ConA. This suggests the presence in resting lymphocytes of a rapidly turning over protein that either prevents the ATPase subunits from assembling or from integrating into the membrane.     

Mechanism of the stimulatory effect of a potassium-rich medium on the phosphorylation of glucose in isolated rat hepatocytes.

We have investigated the mechanism by which the replacement of a Na(+)-rich medium by a K(+)-rich medium causes an increase in the apparent affinity of glucokinase (hexokinase IV or D) for glucose in isolated hepatocytes [Bontemps, F., Hue, L. & Hers, H. G. (1978) Biochem. J. 174, 603-611]. The stimulatory effect of a K(+)-rich medium on the rate of glucose phosphorylation, as assessed by the release of tritium from [2-3H]glucose, was only partially additive with the effect of fructose, suggesting that it was also due to a decrease in the inhibition exerted on glucokinase by its regulatory protein. Measurements of metabolites indicated that the effect of the K(+)-rich medium was neither due to the formation of fructose 1-phosphate, nor to changes in the concentrations of fructose 6-phosphate or Pi, two other effectors of the regulatory protein. Replacement of Na+ by K+ in the medium resulted in a time-dependent and dose-dependent increase in cell volume that paralleled the changes in the rate of detritiation observed at 5 mM glucose. The water and chloride contents, estimated using radiolabelled compounds, were threefold and tenfold higher, respectively, in K+ cells than in Na+ cells, and the intracellular Cl- concentration about threefold higher (94 versus 29 meq/l). The effects of the K(+)-rich medium on cell volume, Cl- concentration and rate of detritiation were greatly reduced by including 80 mM trehalose or sucrose in the medium at the start of the incubation. Addition of trehalose to cells incubated for 45-50 min in the K(+)-rich medium caused an immediate decrease in cell volume whereas the rate of detritiation and the Cl- concentration underwent a transient increase followed by a decrease. Replacement of KCl by KBr, potassium acetate or potassium trichloroacetate in the K(+)-rich medium resulted in different relationships between cell volume and the rate of detritiation, in agreement with the differential effect of these salts on the activity of purified glucokinase assayed in the presence of regulatory protein. From these results we conclude that the increase in the activity of glucokinase induced by a KCl-rich medium is at least partly due to an increase in the concentration of Cl-, which relieves the inhibition exerted by the regulatory protein on purified glucokinase.     

Rainbow trout red cells in vitro

Washed rainbow trout erythrocytes incubated at 14 degrees C in Eagle's minimal essential medium and Cortland saline displayed sharp reductions in volume and water content, nucleoside triphosphate, K+ and Cl- concentrations. Mg2+ and, to a lesser extent, Na+ concentrations increased. Cellular to medium Cl- ratios were indicative of membrane hyperpolarization. Morphological irregularities were also observed. Oxygen consumption and hemoglobin system organization were not grossly affected. Supplementation with pyruvate stabilized nucleoside triphosphate concentrations for at least 24 hr, and reduced rates of volume and compositional change to some extent. Addition of norepinephrine at physiologically realistic levels led to stabilization of Cl- content and reductions in Mg2+ accumulation and water loss. Transient but modest increases in K+ and Ca2+ were coupled, under these circumstances, with some decrease in Na+ concentration. Factors which may contribute to the dysfunctional status of these cells in vitro are discussed.     

Protein kinase C activity in erythrocytes in primary hypertension: regulation of cell shape and cation transport

Protein kinase C activity in the lysate of erythrocytes of patients with essential hypertension (EH) and spontaneously hypertensive rats (SHR) was found to be increased by 1.6-2.0 times as compared with normotensive controls. Membrane cytoskeleton alterations observed in the erythrocytes of patients with EH and SHR were revealed in decreased average erythrocyte volume, increase of cup-shaped cell formation, and increase of basal phosphorylation of band 4.9 protein. In addition, the rate of Na(+)-H+ exchange in erythrocytes of EH patients and SHR was increased by 1.9-fold. In vitro treatment of erythrocytes of healthy donors and Wistar-Kyoto rats (WKY) with protein kinase C activator (12-O-tetradecanoylphorbol-13-acetate) leads to similar changes of cell shape, cell volume, band 4.9 protein phosphorylation and Na(+)-H+ exchange, as well as to an increase of diS-C3-(5) fluorescence. It may be assumed that alterations of these parameters revealed in primary hypertension are caused by increased activity of protein kinase C.     

Na+ Dependence of Tyrosine Transport Across the Synaptosomal Membrane Reflects Changes in the Morphology of Synaptosomes

The Na+ dependence of tyrosine uptake into rat brain synaptosomes and synaptosomal plasma membrane vesicles (SPMV) was examined in the present study. At low tyrosine concentrations, the isoosmotic substitution of Na+ by sucrose in the incubation medium led to an increase of tyrosine uptake in synaptosomes and to a decrease in SPMV. The removal of extracellular Ca2+ and Mg2+ and addition of isoosmotic sucrose completely prevented the augmented tyrosine uptake in Na+-free incubated synaptosomes. Morphological differences were found at the electron-microscopic level when synaptosomes were incubated in Na+-free and Na+-containing media. The internal volume measured for synaptosomes incubated in a Na+-free medium was almost half of that obtained in a Na+-containing medium, in good agreement with the observations made with the electron microscope. Also, the omission of Ca2+ and Mg2+ resulted in a specific swelling of only the synaptosomes incubated in Na+-free medium. When synaptosomes and SPMV were preloaded with several neutral amino acids, the tyrosine uptake rate was greatly increased, indicating fully operational exchange mechanisms for these amino acids. We propose that the enhancement of high-affinity synaptosomal tyrosine uptake observed in Na+-free medium is a consequence of a specific shrinkage of the synaptosomes and a parallel increase of the exchange rate with endogenous neutral amino acids.     

The Na+/K+/Cl- cotransport in C6 glioma cells. Properties and role in volume regulation

The role of the Na+/K+/Cl- cotransporter in the regulation of the volume of C6 astrocytoma cells was analyzed using isotopic fluxes and cell cytometry measurements of the cell volume. The system was inhibited by 'loop diuretics' with the following order of potency: benzmetanide greater than bumetanide greater than piretanide greater than furosemide. Under physiological conditions of osmolarity of the incubation media, equal rates of bumetanide-sensitive inward and outward K+ fluxes were observed. Blockade of the Na+/K+/Cl- cotransporter with bumetanide did not lead to a modification in the mean cell volume. When C6 cells were incubated in an hyperosmotic solution, a cell shrinkage was observed. It was accompanied by a twofold increase in the activity of the Na+/K+/Cl- cotransport, which then catalyzed the net influx of K+. In spite of this increased activity, no cell swelling could be measured. Incubation of the cells in an iso-osmotic medium deprived of either Na+, K+ or Cl- also produced cell shrinkage. Large activations (up to tenfold) of the Na+/K+/Cl- cotransport together with a cell swelling back to the normal volume were observed upon returning ion-deprived C6 cells to a physiological solution. This cell swelling was completely prevented in the presence of bumetanide. It is concluded that the Na+/K+/Cl- cotransport system is one of the transport systems involved in volume regulation of glial cells. The system can either be physiologically quiescent or active depending on the conditions used. A distinct volume regulating mechanism is the Na+/H+ exchange system.