Further studies on the partial double Donnan. Is isosmotic KCl solution isotonic with cells of respiratory trees of the holothurian Isostichopus badionotus Selenka?

As potassium, chloride and water traverse cell membranes, the cells of stenohaline marine invertebrates should swell if exposed to sea water mixed with an isosmotic KCl solution as they do when exposed to sea water diluted with water. To test this hypothesis respiratory tree fragments of the holothurian Isostichopus badionotus were exposed to five isosmotic media prepared by mixing artificial sodium sea water with isosmotic (611 mmol/l) KCl solution to obtain 100, 83, 71, 60 and 50% sea water, with and without 2 mmol/l ouabain. For comparison, respiratory tree fragments were incubated in sea water diluted to the same concentrations with distilled water, with and without ouabain. Cell water contents and potassium and sodium concentrations were unaffected by KCl-dilution or ouabain in isosmotic KCl-sea water mixtures. In tissues exposed to H(2)O-diluted sea water, cell water increased osmometrically and potassium, sodium and chloride concentrations decreased with dilution; ouabain caused a decrease in potasium and an increase in sodium but no effect on chloride concentrations. The isotonicity of the isosmotic KCl solution cannot be adscribed to impermeability of the cell membrane to KCl as both ions easily traverse the cell membrane. Rather, operationally immobilized extracellular sodium ions, which electrostatically hold back anions and consequently water, together with the lack of a cellward electrochemical gradient for potassium, resulting from membrane depolarization caused by high external potassium concentration, would explain the isotonicity of isosmotic KCl solution. The high external potassium concentration also antagonizes the inhibitory effect of ouabain on the Na(+)/K(+) ATPase responsible for sodium and potassium active transport.     

AMP deaminase from the gill of Salmo gairdnerii Richardson: effects of anions, cations and buffers

The AMP deaminase isoenzymes from trout gill were activated by sodium and potassium, sodium being the most efficient. The optimal concentration for activation was 30-50 mM. The enzyme was sensitive to ionic strength, and imidazole was an inhibitor at concentrations higher than 25 mM. A possible regulation of gill AMP deaminase by intracellular imidazole buffers is discussed. AMP deaminase activity was tested in the presence of physiological concentrations of sodium and potassium. When the concentration of one of these cations was varied around its physiological concentration, the enzyme activity was relatively stable, indicating that the intracellular AMP deaminase activity would be insensitive to changes in the concentrations of monovalent cations. The effects of the sodium salts of different inorganic and organic anions were tested. Except chloride and gluconate, all were inhibitors of gill AMP deaminase.     

Oxygen consumptions and potassium contents of slices of rat renal cortex.

An oxygen electrode respirometer for determining the oxygen consumption of slices of mammalian renal cortex is described and assessed. Though rat renal cortical slices incubated in potassium-free medium for one hour lost 102 +/- 14 mmol of potassium/kg dry weight, there was only a small, nonsignificant fall in oxygen consumption. In contrast the oxygen consumption of slices incubated in potassium-free medium with 10 mmol.1-1 ouabain was markedly reduced (by 32 +/- 6%), while such slices lost 180 +/- 15 mmol of potassium/kg dry weight. These disproportionate effects on potassium loss and inhibition of oxygen consumption suggest that in renal cortical slices the loss of potassium in low potassium medium is not primarily due to inhibition of the conventional sodium pump.     

Cellular lithium and transepithelial transport across toad urinary bladder

Summary Toad urinary bladders were exposed on either their mucosal or serosal surfaces, or on both surfaces, to medium in which sodium was replaced completely by lithium. With mucosal lithium Ringer's, serosal sodium Ringer's, short-circuit current (SCC) declined by about 50 percent over the first 60 min and was then maintained over a further 180 min. Cellular lithium content was comparable to the sodium transport pool. With lithium Ringer's serosa, SCC was abolished over 60 to 120 min whether the mucosal cation was sodium or lithium. Measurements of cellular ionic composition revealed that the epithelial cells gained lithium from both the mucosal and serosal media. With lithium Ringer's mucosa and serosa, cells lost potassium and gained lithium and a little chloride and water, but these changes in cellular ions could not account for the current flow across the tissue under these conditions, which must, therefore, have been carried by a transepithelial movement of lithium itself. The inhibition by serosal lithium of SCC was overcome by exposure of the mucosal surface of the bladders to amphotericin B. Thus it reflected, predominantly, an inhibition of lithium entry to the cells across the apical membrane. It is suggested that this inhibition is a consequence of cellular lithium accumulation.     

Osmolytes responsible for volume reduction under isosmotic or hypoosmotic conditions in Barnacle muscle cells.

In numerous animal cells, experimental manipulations that increase the intracellular free Ca2+ concentration induce cell volume reduction. This may occur under isosmotic conditions, e.g. when external Ca2+ (Ca(o)) is replaced by Mg2+ (42) or during exposure to hypoosmotic conditions (i.e. regulatory volume decrease, RVD) in the presence of Ca(o). We determined the osmolytes responsible for volume reduction under isosmotic and hypoosmotic conditions in barnacle muscle cells. Organic osmolytes (i.e. free amino acids and methylamines) and inorganic ions accounted for approximately 78% and 22% of the intracellular isosmotic activity, respectively. Isosmotic Ca(o) removal induced a net loss of KCI (with a ratio of 1K:1Cl) and free amino acids (FAA, mainly glycine and taurine). During RVD. the same ions (but in a proportion of 2K:1Cl) and FAA were lost. Since RVD was accompanied by extracellular alkalinization, the 2K:1Cl loss may be explained by the presence of a K+/H+ exchanger (or K+-OH- co-transporter) or Cl-/OH- exchanger. The lack of RVD in the absence of Ca(o) cannot be attributed to the loss of intracellular osmolytes during isosmotic Ca(o) removal because addition of Ca(o) during cell swelling promoted RVD.     

Evidence for chloride dependent potassium and water transport induced by hyposmotic stress in erythrocytes of the marine teleost,Opsanus tau

Summary Red blood cells of the marine teleost,Opsanus tau (oyster toadfish), were characterized as to their normal hemoglobin, ion and water contents. Cells were exposed to ouabain containing, hyposmotic salt solutions (osmolarity reduced to 2/3 of normal) in which the cation or anion composition was varied. It was found that the initial cell volume expansion due to water influx was independent of the anion present. However, a secondary volume reduction was dependent on the presence of chloride or bromide anions. During volume reduction, cellular potassium and chloride ion contents fell by about equal amounts. Potassium loss was commensurate to the total amount of potassium ions detected extracellularly about 1.5h after the initial osmotic shock. No major changes were seen in the cellular sodium ion contents. When chloride ions within the cells and in the suspending medium were replaced by nitrate, iodide or thiocyanate, the cells failed to return to volumes close to those of isosmotically suspended controls, and the cellular potassium content also remained constant. In hypotonic potassium chloride the cells failed to extrude potassium chloride and water, and hence retained their expanded volume. Neither potassium loss nor volume decrease occurred in cells swollen in hypotonic sodium chloride media containing furosemide or 4,4 diisothiocyano-2,2-stilbene-disulfonic acid (DIDS). These two compounds are known inhibitors of monovalent cation cotransport and anion self exchange, respectively, in mammalian red cells. Hence toadfish red cells respond to osmotic swelling primarily by activation of an ouabain-insensitive, chloride dependent potassium transport system which is sensitive to inhibition by furosemide and DIDS.     

Ouabain-insensitive salt and water movements in duck red cells. II. The role of chloride in the volume response

This paper describes the effect of external chloride on the typical swelling response induced in duck red cells by hypertonicity or norepinephrine. Lowering chloride inhibits swelling and produces concomitant changes in net movements of sodium and potassium in ouabain-treated cells, which resemble the effect of lowering external sodium or potassium. Inhibition is the same whether chloride is replaced with gluconate or with an osmotic equivalent of sucrose. Since changes in external chloride also cause predictable changes in cell chloride, pH, and water, these variables were systematically investigated by varying external pH along with chloride. Lowering pH to 6.60 does not abolish the response if external chloride levels are normal, although the cells are initially swollen due to the increased acidity. Cells deliberately preswollen in hypotonic solutions with appropriate ionic composition can also respond to norepinephrine by further swelling. These results rule out initial values of cell water, chloride, and pH as significant variables affecting the response. Initial values of the chloride equilibrium potential do have marked effect on the direction and rate of net water movement. If chloride is lowered by replacement with the permeant anion, acetate, E(Cl) is unchanged and a normal response to norepinephrine, which is inhibited by furosemide, is observed. Increasing internal sodium by the nystatin technique also inhibits the response. A theory is developed which depicts that the cotransport carrier proposed in the previous paper (W.F. Schmidt and T.J. McManus. 1977b. J. Gen. Physiol. 70:81-97) moves in response to the net electrochemical potential difference driving sodium and potassium across the membrane. Predictions of this theory fit the data for both cations and anions.     

A voltage-gated chloride conductance in rat cultured astrocytes

Large voltage-dependent outward currents are recorded with the whole-cell patch-clamp technique from rat cultured astrocytes under conditions where an outward movement of potassium ions is excluded (either by blockage of the potassium channels pharmacologically or by replacement of the internal potassium by the impermeant large organic cation N-methyl-(+)-glucamine). The current, which is activated at potentials more positive than -40 to -50 mV, is normally carried by an inward movement of chloride ions. Its reversal potential is the same as the chloride equilibrium potential. With depolarization to +60 mV (for 225 ms) little or no inactivation of the current occurs: with depolarizations to +90 to +110 mV a time-dependent decay is seen. The current, which is often not marked immediately after formation of the whole-cell clamp, generally increases over a period of a few minutes to a maximum (after which it usually declines), as if some as yet unknown intracellular factor keeping the channels closed were being washed away from the membrane. The time course of this phenomenon is not affected by changing of the internal free calcium concentration (from 10(-8)M to 10(-6)M) or by an intracellular mixture of cyclic AMP (1 mM), ATP (4 mM) and Mg+ (2 mM). The conductance is slightly increased when the chloride of the bathing medium is replaced by bromide; is much reduced on replacement by methylsulphate, sulphate, isethionate, or acetate; and is virtually abolished on replacement by the large anion gluconate. The outward current is inhibited by the disulphonate stilbenes DIDS and SITS; this blocking action was initially partly reversible, although never completely so. It is suggested that the chloride conductance plays a role in the spatial buffering of potassium by astrocytes.     

Electrolyte balance in gastrointestinal disease

Even small losses of gastrointestinal secretions when combined with reduced intake of electrolytes may seriously disturb electrolyte balance. Knowledge of the ionic composition of secretions lost is essential in planning therapy. Loss of gastric contents usually results in excessive loss of chloride; in achlorhydria this is not the case. Loss of sodium and potassium may be large in either case and is often underestimated. Small bowel obstruction results in a more balanced loss of electrolyte which may not affect acidbase balance greatly. In diarrhea loss of base predominates, and may result in a large potassium deficit. Steatorrhea due to nontropical sprue results in large fecal losses of sodium, potassium and chloride, in addition to the large calcium and phosphorus loss. In chronic peptic ulcer excessive ingestion of milk and absorbable alkalies may result in hypercalcemia, azotemia and alkalosis, without hypercalciuria. Since renal function is usually adequate in the milder gastrointestinal disturbances, electrolyte and fluid replacement should be started early, and can be guided by generally available laboratory tests, the carbon dioxide combining power and serum chloride levels, provided the predominate ionic loss is known and potassium deficiency remedied. If this is done, development of serious fluid and electrolyte deficits can usually be prevented.     

Effect of intravesicular monovalent cations on the steady state of the phosphoenzyme of adenosine triphosphatase dependent on sodium and potassium ions in inside-out plasma-membrane vesicles.

Phosphorylation of the ATPase dependent on Na+ and K+ is promoted through the synergistic action of cations on both sides of the membrane. This phenomenon has been observed in plasma membrane vesicles isolated from sheep-kidney outer medulla which accept ATP from the outside surface (inside-out) and which are tight for sodium ions. In these inside-out vesicles phosphorylating capacity is low even in the presence of 100 mM extravesicular sodium chloride as is turnover of the enzyme. The level of the phosphoenzyme and the transient release of inorganic phosphate from the phosphoenzyme increases several-fold when sodium chloride is allowed to equilibrate over the membrane, 25 mM intravesicular NaCl is necessary to obtain the half-maximum level of the phosphoenzyme. This result shows that intravesicular (= extracellular) low affinity sites are involved in the phosphorylation. Intravesicular potassium ions modify the activating action of Na+ on the phosphorylation by increasing the steady state of the phosphoenzyme at low intravesicular sodium ion concentrations. This suggests that Na+ and K+ compete with each other for the intravesicular cation-binding site.     

Cation Dependence of Hypotaurine Uptake in Mouse Brain Slices

Abstract: Mouse brain slices take up hypotaurine (2-aminoethanesulphinic acid) from medium by means of two concentrative low- and high-affinity transport systems. [³⁵S]Hypotaurine uptake by the slices was significantly reduced in the absence of external potassium, calcium, or magnesium ions. An excess of potassium ions also inhibited hypotaurine uptake by one-half. Uptake was almost completely abolished on removal of sodium ions. The K _m constants for both low- and high-affinity transport components increased in a low-sodium medium, suggesting that sodium ions are required when hypotaurine is attached to its possible carrier sites in plasma membranes. Sodium ions also mimicked allosteric effectors of hypotaurine transport, showing positive cooperativity. More than two sodium ions may be involved in the transport of one hypotaurine molecule across the cell membrane. The calculated activation energies of transport were fairly similar in normal and sodium-deficient media and thus sodium ions may not participate in the activation mechanisms of the transport. With respect to cation dependence, hypotaurine transport in brain slices exhibits features characteristic of neurotransmitter amino acids.     

Regulatory changes in the K+, Cl- and water contents of HeLa cells incubated in an isosmotic high K(+)-medium

HeLa cells had their normal medium replaced by an isosmotic medium containing 80 mM K+, 70 mM Na+ and 100 microM ouabain. The cellular contents of K+ first increased and then decreased to the original values, that is, the cells showed a regulatory decrease (RVD) in size. The initial increase was not inhibited by various agents except by substitution of medium Cl- with gluconate. In contrast, the regulatory decrease was inhibited strongly by addition of either 1 mM quinine, 10 microM BAPTA-AM without medium Ca2+, or 0.5 mM DIDS, and partly by either 1 mM EGTA without medium Ca2+, 10 microM trifluoperazine, or substitution of medium Cl- with NO3-. Addition of DIDS to the NO3(-)-substituted medium further suppressed the K+ loss but the effect was incomplete. Intracellular Ca2+ showed a transient increase after the medium replacement. These results suggest that the initial increase in cell K+ is a phenomenon related to osmotic water movement toward Donnan equilibrium, whereas the regulatory K+ decrease is caused by K+ efflux through Ca(2+)-dependent K+ channels. The K+ decrease induced a decrease in cellular water, i.e., RVD. The K+ efflux may be more selectively associated with Cl- efflux through DIDS-sensitive channels than the efflux of other anions.     

Sodium-chloride transport in the medullary thick ascending limb of henle's loop: Evidence for a sodium-chloride cotransport system in plasma membrane vesicles

Sodium transport mechanisms were investigated in plasma membrane vesicles prepared from the medullary thick ascending limb of Henle's loop (TALH) of rabbit kidney. The uptake of 22Na into the plasma membrane vesicles was investigated by a rapid filtration technique. Sodium uptake was greatest in the presence of chloride; it was reduced when chloride was replaced by nitrate, gluconate or sulfate. The stimulation of sodium uptake by chloride was seen in the presence of a chloride gradient directed into the vesicle and when the vesicles were equilibrated with NaCl, KCl plus valinomycin so that no chemical or electrical gradients existed across the vesicle (tracer exchange experiments). Furosemide decreased sodium uptake into the vesicles in a dose-dependent manner only in the presence of chloride, with a Ki of around 5 X 10(-6) M. Amiloride, at 2 mM, had no effect on the chloride-dependent sodium uptake. Similarly, potassium removal had no effect on the chloride-dependent sodium uptake and furosemide was an effective inhibitor of sodium uptake in a potassium-free medium. The results show the presence of a furosemide-sensitive sodium-chloride cotransport system in the plasma membranes of the medullary TALH. There is no evidence for a Na+/H+ exchange mechanism or a Na+ -K+ -Cl- cotransport system. The sodium-chloride cotransport system would effect the uphill transport of chloride against its electrochemical potential gradient at the luminal membrane of the cell.     

Water and ion balance in the tissues of the dehydrated cockroach, Periplaneta americana

Cockroaches dehydrated for 8 days lost nearly 50% of their haemolymph volume and approx 25% of their tissue water. Haemolymph osmolality and sodium, potassium, and chloride concentrations in the haemolymph and tissue water were all regulated within narrow limits. It is confirmed that sodium and potassium ions are sequestered within the fat body during periods of dehydration. The increase in sodium and potassium ions in the fat body is shown to arise from ionic regulation of haemolymph and other tissues. During periods of rehydration, sodium and potassium concentrations decrease in the fat body and haemolymph volume and ionic concentrations return to near original levels. A small proportion of the surplus haemolymph chloride ions is shown to be associated with the cuticle during times of water deprivation.     

Use of low temperature and high K+ incubation media for in vitro tissue preparation for X-ray microanalysis

Incubation of tissue slices in physiological buffers gives rise to significant changes in the intracellular ion concentrations, which may disturb subsequent X-ray microanalysis. In the present study it was attempted to design incubation conditions that retain the in vivo conditions better. The following variables were investigated: (1) exchange of Na⁺ in the incubation medium for K⁺, and exchange of Cl^–for the less permeable gluconate anion; (2) incubation at 4°C rather than at 37°C; and (3) addition of dextran to the incubation medium. Brief exposure (a few seconds) of liver slices to a buffer causes changes in the intracellular Na, Cl and K concentrations, depending on the ionic composition of the buffer. Incubation in a normal physiological (high NaCl) buffer at 37°C results in a further increase of Na and Cl and a further decrease in K in liver cells. The changes reach a maximum at 30 min and the concentrations then remain stable throughout a 2-h incubation. Incubation in sodium gluconate medium or addition of dextran to the physiological buffer somewhat reduces the changes in the intracellular ion composition (compared to the standard physiological incubation medium). Incubation in potassium gluconate medium results in a decrease in cellular Na and an increase in K. Quantitative morphological studies show that tissue oedema is observed to the same extent in hepatocytes incubated in sodium gluconate, potassium gluconate and physiological buffer containing 10% dextran. However, these buffers cause significantly less cell oedema than the physiological (high NaCl) buffer. Incubation of liver, cerebral cortex or submandibular gland slices in physiological (high NaCl) solutions at 4°C for 4 h caused a more extensive increase in Na⁺ and decrease in K⁺ than incubation at 37°C for 2 h. This suggests inhibition of the Na⁺, K⁺-ATPase under these conditions. As compared to incubation at 37°C for 2 h, tissues incubated in potassium gluconate buffer at 4°C for 4 h have a cellular K concentration closer to the in situ value. Cholinergic stimulation of tissue slices from cerebral cortex and submandibular gland at room temperature for 1 min shows the best physiological response in tissue slices preincubated at 4°C for 4 h in high KCl, potassium gluconate and high NaCl, in this order. The response can, however, only be seen, when cholinergic stimulation is carried out in a standard physiological buffer with a high NaCl concentration. It is concluded that in vitro storage of tissue for X-ray microanalysis is best carried out at 4°C in a solution with a high K⁺ concentration.     

gamma-Aminobutyric acid transport in reconstituted preparations from rat brain: coupled sodium and chloride fluxes

Transport of gamma-aminobutyric acid (GABA) is electrogenic and completely depends on the presence of both sodium and chloride ions. These ions appear to be cotransported with gamma-aminobutyric acid through its transporter [reviewed in Kanner, B. I. (1983) Biochim. Biophys. Acta 726, 293-316]. Using proteoliposomes into which a partially purified gamma-aminobutyric acid transporter preparation was reconstituted, we have been able--for the first time--to provide direct evidence for sodium- and chloride-coupled gamma-aminobutyric acid transport. This has been done by measuring the fluxes of 22Na+, 36Cl-, and [3H]GABA. These fluxes have the following characteristics: There are components of the net fluxes of sodium and chloride that are gamma-aminobutyric acid dependent. The sodium flux is chloride dependent; i.e., when Cl- is replaced by inorganic phosphate or by SO4(2-), gamma-aminobutyric acid dependent sodium fluxes are abolished. The chloride flux is sodium dependent; i.e., when Na+ is replaced by Tris+ or by Li+, gamma-aminobutyric acid dependent chloride fluxes are abolished. Thus, the gamma-aminobutyric acid dependent sodium and chloride fluxes appear to be catalyzed by the transporter. Using these fluxes we have attempted to determine the stoichiometry of the process. We measured the initial rate of sodium-dependent gamma-aminobutyric acid fluxes and that of gamma-aminobutyric acid dependent sodium fluxes. This yields the stoichiometry between sodium and gamma-aminobutyric acid (2.58 +/- 0.99). Similarly, we measured the stoichiometry between chloride and gamma-aminobutyric acid, which is found to be 1.27 +/- 0.12.(ABSTRACT TRUNCATED AT 250 WORDS)     

UPTAKE AND RELEASE OF D- AND L-ASPARTATE BY RAT BRAIN SLICES

D-Aspartate is accumulated by slices of adult rat cortex by a high affinity uptake which is abolished if the sodium ions in the incubation medium are replaced by choline. A small uptake of D-aspartate takes place if the sodium ions are replaced by lithium ions. It appears likely that D-aspartate shares the same transport system with L-aspartate, and that the uptake of D-aspartate is into the same osmotically-sensitive particles as those which accumulate L-aspartate. D-Aspartate is released from cerebral cortex slices by raised potassium concentrations, provided calcium is present in the perfusing buffer. Both D- and L-aspartate produce gross hyperactivity when injected intraperitoneally into immature rats. Radioactive D-aspartate may be very useful in examining the neurotransmitter role of the naturally- occurring L-aspartate e.g. in studies of the autoradiographic localization of high affinity L-aspartate accumulation, its main advantage being that, unlike L-aspartate, D-aspartate does not undergo rapid metabolism.     

Haemolymph plasma composition of the Essig''s lupine aphid, Macrosiphum albifrons Essig (homoptera: aphididae)

Haemolymph from the Essig's Lupine aphid, Macrosiphum albifrons (Essig), was analyzed for pH, osmolality, and concentrations of magnesium, calcium, potassium, sodium, chloride, phosphate and citrate. The concentration of inorganic ions and citrate was relatively low forming only 14% of the osmotic potential of the plasma (476 mOsm). The composition of the plasma resembled more the composition of phytophagous Endopterygota than Exopterygota.     

Voltage-gated cation and anion channels in mammalian Schwann cells and astrocytes

This article reviews some recent studies on the voltage-gated ion channels in the plasmalemma of the satellite cells of the peripheral and central nervous systems. Following the finding that rabbit Schwann cells exhibit a large binding capacity for saxitoxin (Ritchie and Rang, 1983) electrophysiological studies have shown that these cells not only express plasmalemmal voltage-gated sodium channels but also voltage-gated potassium channels (Chiu, Shrager and Ritchie, 1984; Shrager, Chiu and Ritchie, 1985). Whole-cell recording with the patch-clamp method reveals that the properties of these two kinds of channel are quite similar to those of the corresponding channels in the nodal axolemma, except that the peak current-voltage relation of the sodium channels is shifted about 30 mV in the depolarizing direction. Similar voltage-gated sodium and potassium channels exist in rat cultured astrocytes (Bevan et al., 1985). Furthermore, the outward current on depolarization in astrocytes has a component other than that carried in the potassium channels. About 75% of the total outward current is blocked by external TEA or internal caesium; and it is presumed to be a potassium current. The remainder, however, is insensitive to these potassium channel blocking agents; but it is abolished by exposure to the two stilbene sulphonates, DIDS and SITS (Gray and Ritchie, 1986). This remaining current persists in the presence of the large organic cation N-methyl-(+)-glucamine in the patch pipette. It is, however, reduced when the chloride of the external medium is replaced by methyl-sulphate, sulphate, or isethionate; and it is abolished when the external anion is gluconate (M.W., 190). The TEA-insensitive component of outward current in astrocytes thus seem to involve an influx of chloride ions through a voltage-gated channel whose diameter is such that anions larger than gluconate cannot pass. The current in the channels is neglible at potentials more negative than about -40 mV.     

IONS AND THE TRANSPORT OF GAMMA-AMINOBUTYRIC ACID BY SYNAPTOSOMES

Abstract— The initial rate of uptake of [2,3-³H]gamma-aminobutyric acid by rat brain synaptosomes was studied under incubation conditions in which GABA metabolism was minimal. The presence of both sodium and potassium in the incubation medium was essential for sustained uptake. Uptake proceeded for a short period of time in the absence of potassium and then ceased. No uptake was observed when sodium chloride was completely replaced with sucrose or choline chloride. The sodium-dependence curve for GABA uptake was markedly sigmoid. The sigmoid character of the curve was not attributable to a lag phase in uptake at low sodium concentrations. Calcium strongly stimulated the initial rate of uptake at low sodium concentrations but had little effect at sodium concentrations above 100 m m and was not able to support uptake in the absence of sodium. The sigmoid character of thesodium-dependence curve was completely eliminated by 20 m m calcium ion. Magnesium and phosphate had little effect on the initial rate of GABA uptake.