Lithium transport pathways in human red blood cells

In human red cells, Li is extruded against its own concentration gradient if the external medium contains Na as a dominant cation. This uphill net Li extrusion occurs in the presence of external Na but not K, Rb, Cs, choline, Mg, or Ca, is ouabain-insensitive, inhibited by phloretin, and does not require the presence of cellular ATP. Li influx into human red cells has a ouabain-sensitive and a ouabain-insensitive but phloretin-sensitive component. Ouabain-sensitive Li influx is competitively inhibited by external K and Na and probably involves the site on which the Na-K pump normally transports K into red cells. Ouabain does not inhibit Li efflux from red cells containing Li concentrations below 10 mM in the presence of high internal Na or K, whereas a ouabain-sensitive Li efflux can be measured in cells loaded to contain 140 mM Li in the presence of little or no internal Na or K. Ouabain-insensitive Li efflux is stimulated by external Na and not by K, Rb, Cs, choline, Mg, or Ca ions. Na-dependent Li efflux does not require the presence of cellular ATP and is inhibited by phloretin, furosemide, quinine, and quinidine. Experiments carried out in cells loaded in the presence of nystatin to contain either only K or only Na show that the ouabain-insensitive, phloretin-inhibited Li movements into or out of human red cells are stimulated by Na on the trans side and inhibited by Na on the cis side of the red cell membrane. The characteristics of the Na-dependent unidirectional Li fluxes and uphill Li extrusion are similar, suggesting that they are mediated by the same Na-Li countertransport system.     

Ca2+-activated Na+ fluxes in human red cells. Amiloride sensitivity

The effect of Ca2+ on the ouabain- and bumetanide-resistant Na+ fluxes in intact red cells was studied at relatively constant internal Ca2+, membrane potential, and cell volume. The red cell calcium concentration was modified using the ionophore A23187. In fresh red cells, the Na+ influx and efflux (1.2 +/- 0.13 and 0.26 +/- 0.07 mmol/liter cells x h, respectively) were not affected by amiloride (1 mM). When external Ca2+ was raised from 0 to 150 microM, in the presence of A23187, both the Na+ influx and efflux were stimulated (about 3.5-fold). The Ca2+-activated Na+ efflux and influx had an apparent Km for activation by Ca2+o of about 25 microM. The Ca2+-dependent Na+ transport was inhibited 30-60% by amiloride (ID50 = 17.3 +/- 8 microM). Amiloride, however, had no effect on the Ca2+-dependent K+ influx. The amiloride-sensitive (AS) transport pathway was a linear function of the Na+o concentration in the range from 0 to 75 mM. The Ca2+i activation seems to depend on the metabolic integrity of red cells. 1) It does not take place in ATP-depleted red cells; 2) ATP-repletion of ATP-depleted red cells fully restored AS Na influx; and 3) ATP-enrichment (ATP-red cells) enhanced the AS Na influx by about 100%. The Ca2+-activated AS Na+ influx was not affected by either DIDS or trifluoperazine. The present results indicate that in human erythrocytes an increase in internal Ca2+ activates on otherwise silent AS Na+-transport system, which is dependent on the metabolic integrity of the red cells.     

Kinetics of the sodium pump in red cells of different temperature sensitivity

Ouabain-sensitive K influx into ground squirrel and guinea pig red cells was measured at 5 and 37 degrees C as a function of external K and internal Na. In both species the external K affinity increases on cooling, being three- and fivefold higher in guinea pig and ground squirrel, respectively, at 5 than at 37 degrees C. Internal Na affinity also increased on cooling, by about the same extent. The effect of internal Na on ouabain-sensitive K influx in guinea pig cells fits a cubic Michaelis-Menten-type equation, but in ground squirrel cells this was true only at high [Na]i. There was still significant ouabain-sensitive K influx at low [Na]i. Ouabain-binding experiments indicated around 800 sites/cell for guinea pig and Columbian ground squirrel erythrocytes, and 280 sites/cell for thirteen-lined ground squirrel cells. There was no significant difference in ouabain bound per cell at 37 and 5 degrees C. Calculated turnover numbers for Columbian and thirteen-lined ground squirrel and guinea pig red cell sodium pumps at 37 degrees C were about equal, being 77-100 and 100-129 s-1, respectively. At 5 degrees C red cells from ground squirrels performed significantly better, the turnover numbers being 1.0-2.3 s-1 compared with 0.42-0.47 s-1 for erythrocytes of guinea pig. The results do not accord with a hypothesis that cold-sensitive Na pumps are blocked in one predominant form.     

Voltage-dependent stimulation of Na+/K(+)-pump current by external cations: selectivity of different K+ congeners.

Currents generated by the endogenous Na+/K+ pump in the oocytes of Xenopus laevis were determined under voltage-clamp as currents activated by different K+ congeners. The voltage dependence of the pump current reflects voltage-dependent steps in the reaction cycle. The decrease of K(+)-activated pump current at positive potentials has been attributed to voltage-dependent stimulation by the external K+ (Rakowski, Vasilets, LaTona and Schwarz (1991) J. Membr. Biol. 121, 177-187). In Na(+)-free solution, activation of the pump by external cations seems to be the dominating voltage-dependent and rate-determining step in the reaction cycle. Under these conditions, the voltage dependence of apparent Km values for pump activation can be analyzed. The dependence suggests voltage-dependent binding of extracellular cations assuming that an effective charge of about 0.4 of an elementary charge is moved in the electrical field during a step associated with the cation binding. The apparent Km values at 0 mV differ for various cations that stimulate pump activity. The values are in mM: 0.10 for Tl+, 0.63 for K+, 0.71 for Rb+, 9.3 for NH4+, and 12.9 for Cs+. The corresponding apparent affinities follow the same sequence as the cation permeability of the K(+)-selective delayed rectifier channel of nerve cells. The results are compatible with the interpretation that the cations have to pass an ion-selective access channel to reach their binding sites in the pump molecule.     

Active sodium and potassium transport in high potassium and low potassium sheep red cells

The kinetic characteristics of the ouabain-sensitive (Na + K) transport system (pump) of high potassium (HK) and low potassium (LK) sheep red cells have been investigated. In sodium medium, the curve relating pump rate to external K is sigmoid with half maximal stimulation (K_1/2) occurring at 3 mM for both cell types, the maximum pump rate in HK cells being about four times that in LK cells. In sodium-free media, both HK and LK pumps are adequately described by the Michaelis-Menten equation, but the K_1/2 for HK cells is 0.6 ± 0.1 mM K, while that for LK is 0.2 ± 0.05 mM K. When the internal Na and K content of the cells was varied by the PCMBS method, it was found that the pump rate of HK cells showed a gradual increase from zero at very low internal Na to a maximum when internal K was reduced to nearly zero (100% Na). In LK cells, on the other hand, no pump activity was detected if Na constituted less than 70% of the total (Na + K) in the cell. Increasing Na from 70 to nearly 100% of the internal cation composition, however, resulted in an exponential increase in pump rate in these cells to about ⅙ the maximum rate observed in HK cells. While changes in internal composition altered the pump rate at saturating concentrations of external K, it had no effect on the apparent affinity of the pumps for external K. These results lead us to conclude that the individual pump sites in the HK and LK sheep red cell membranes must be different. Moreover, we believe that these data contribute significantly to defining the types of mechanism which can account for the kinetic characteristics of (Na + K) transport in sheep red cells and perhaps in other systems.     

A kinetic analysis of Na-Li countertransport in human red blood cells

We examined the kinetic properties of the interactions between inner and outer cation sites of the Na-Li countertransport system in human red blood cells. Li-stimulated Na efflux [V(Na)] was measured as a function of external Li [(Li)o] and internal Na [(Na)i] contents. At each (Li)o, a Hanes plot of (Na)i/V(Na) vs. (Na)i allowed us to calculate the apparent dissociation constant for internal Na (KiNa) and the maximal rate of Na efflux [Vmax(Na)]. In erythrocytes from 10 different subjects, the Vmax(Na)/KiNa ratios were independent of the external Li concentrations. In other experiments, Na-stimulated Li efflux [V(Li)] was measured as a function of external Na and internal Li contents. In three subjects studied, the Vmax(Li)/KiLi ratios were independent of the external Na concentrations. The data strongly suggest that the countertransport mechanism is consecutive ("ping-pong").     

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

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

Sidedness of (sodium, potassium)-adenosine triphosphate of inside-out red cell membrane vesicles. Interactions with potassium.

Inside-out membrane vesicles of human red cells, prepared according to the method of Steck et al. (1970) Science 168, 255-257) have sufficiently low cation permeability to allow the examination of the side-specific interactions of ligands with the asymmetric sodium pump complex. In accordance with the known properties of the pump in intact cells the following results were observed: (a) ATP-dependent sodium influx and (b) maximal (sodium, potassium)-ATPase with K+ present inside the vesicles with larger than or equal to 20 micronM ATP. With much lower [ATP], K+ inhibited sodium-activated ATPase. K+ was inhibitory at either surface. Inhibition was different on the two sides since cytoplasmic (extravesicular) Na+ counteracted inhibition by cytoplasmic (extravesicular) K+ but not inhibition by K+ at the plasma or external membrane surface, i.e. intravesicular K+. A decrease in the steady state level of the phosphenzyme intermediate of sodium-activated ATPase was caused also by K+ at either surface. The effect of cytoplasmic K+ is compatible with its competitive inhibition of activation of phosphorylation of the enzyme by cytoplasmic Na+. At 37 degrees, the inhibitory effect of external K+ is due to interaction with the phosphoenzyme to form a stable complex of K+ with the dephosphenzyme resulting in a decreased overall reaction rate but increased turnover of the phosphoenzyme (E-P + K leads to EK + Pi). At 0 degree, external K+ inhibits by interacting with the unphosphorylated enzyme to form an occluded enzyme-K complex. This results in a decreased overall rate but relatively small change in apparent turnover of the phosphoenzyme. At 0 degree, but not at 37 degrees, external Na+ counteracted the inhibitory effects of external K+.     

Palytoxin induces an increase in the cation conductance of red cells

Palytoxin (PTX), isolated from the marine soft coral Palythoa tuberculosa, increases the cation conductance of human red cell membranes. In the presence of 10(-10) M PTX and 10(-5) M DIDS, the membrane potential approximates the equilibrium potential for Na+ or K+ rather than Cl-. Even in the absence of DIDS, the Na+ and K+ conductances were greater than the Cl- conductance. The selectivity of the PTX-induced cation conductance is K+ greater than Rb+ greater than Cs+ greater than Na+ greater than Li+ much greater than choline+ greater than TEA+ much greater than Mg2+. Measurements of K+ efflux revealed two apparent sites for activation by PTX, one with a Kal of 0.05 nM and a maximum flux, nu max1, of 1.4 mol/liter of cells per h and another with a Ka2 of 98 nM and a nu max2 of 24 mol/liter of cells per h. These effects of PTX are completely blocked by external ouabain (300 microM) and prevented by internal vanadate (100 microM). When the PTX channels are open, the Na,K pumps do not catalyze ATP hydrolysis. Upon thorough washout of cells exposed to about five molecules of PTX/pump, the Na,K pump of these cells operates normally. Blockage of the positively charged NH2 terminus of PTX with a p-bromobenzoyl group reduces the potency of the compound to induce Na and K fluxes by at least a factor of 100, and to compete with the binding of [3H]ouabain by at least a factor of 10. These data are consistent with the conclusion that PTX binds reversibly to the Na,K pumps in the red cell membrane and opens a (10-pS) channel equally permeable to Na and K at or near each pump site.     

Interaction of external alkali metal ions with the Na-K pump of human erythrocytes: a comparison of their effects on activation of the pump and on the rate of ouabain binding

The effects of external alkali metal ions on the rate of ouabain binding and on the rate of the Na-K pump were examined in human red blood cells. In Na-containing solutions, K, Cs, and Li decreased the rate of ouabain binding. For K and Cs, the kinetics of this effect were similar to those for their activation of the pump. In Na-free (choline- substituted) solutions the rate of ouabain binding was decreased by K whereas it was promoted by Cs and Li. External Na increased the rate of ouabain binding whether or not external K was present, and the kinetics of this effect were not the same as those for inhibition of the pump by Na. These findings are interpreted to mean that not only do the cations affect ouabain binding at the external loading sites on the pump from which ions are translocated inward, but that there are additional sites on the external aspect of the pump at which cations can promote ouabain binding, and that these sites can be occupied by Li, Na, and Cs. It is postulated that these latter sites are those from which Na is discharged after outward translocation by the pump.     

Modulation of erythrocyte Na transport pathway(s) by excess Na intake

Different Na transport pathways were studied in the erythrocytes of 10 normotensive subjects who received 240 meq/day of Na in excess of their usual diet. In most of these subjects the maximal rate (Vmax) of the Na,K pump and the Na,K-cotransport system was markedly decreased on the first day of the diet. In some of these subjects, excess Na intake induced an increase in the apparent affinity for internal Na for the Na,K pump and the Na,K-cotransport system. The decrease in the Na,K pump fluxes was not concomitant to that of the co-transport system and not accompanied with an increase in blood pressure or cation concentration in the plasma. Interestingly, the apparent affinity for internal Li of the Li-Na exchange was markedly increased without alteration of the Vmax. The passive permeability for Na and the cellular Na content were not altered by excess Na intake. Ouabain and bumetanide at low concentrations respectively induced an increase in the apparent affinity for internal Na of the Na,K pump and the Na,K- cotransport system. These results are similar to those observed after excess Na intake. These later agree with the hypothesis that Na homeostasis regulates some endogenous factors with ouabain-like and furosemide-like properties that might contribute to the regulation of cellular Na handling.     

Evidence for tryptophan residues in the cation transport path of the Na(+),K(+)-ATPase

A family of aryl isothiouronium derivatives was designed as probes for cation binding sites of Na(+),K(+)-ATPase. Previous work showed that 1-bromo-2,4,6-tris(methylisothiouronium)benzene (Br-TITU) acts as a competitive blocker of Na(+) or K(+) occlusion. In addition to a high-affinity cytoplasmic site (K(D) < 1 microM), a low-affinity site (K(D) approximately 10 microM) was detected, presumably extracellular. Here we describe properties of Br-TITU as a blocker at the extracellular surface. In human red blood cells Br-TITU inhibits ouabain-sensitive Na(+) transport (K(D) approximately 30 microM) in a manner antagonistic with respect to extracellular Na(+). In addition, Br-TITU impairs K(+)-stimulated dephosphorylation and Rb(+) occlusion from phosphorylated enzyme of renal Na(+),K(+)-ATPase, consistent with binding to an extracellular site. Incubation of renal Na(+),K(+)-ATPase with Br-TITU at pH 9 irreversibly inactivates Na(+),K(+)-ATPase activity and Rb(+) occlusion. Rb(+) or Na(+) ions protect. Preincubation of Br-TITU with red cells in a K(+)-free medium at pH 9 irreversibly inactivates ouabain-sensitive (22)Na(+) efflux, showing that inactivation occurs at an extracellular site. K(+), Cs(+), and Li(+) ions protect against this effect, but the apparent affinity for K(+), Cs(+), or Li(+) is similar (K(D) approximately 5 mM) despite their different affinities for external activation of the Na(+) pump. Br-TITU quenches tryptophan fluorescence of renal Na(+),K(+)-ATPase or of digested "19 kDa membranes". After incubation at pH 9 irreversible loss of tryptophan fluorescence is observed and Rb(+) or Na(+) ions protect. The Br-TITU appears to interact strongly with tryptophan residue(s) within the lipid or at the extracellular membrane-water interface and interfere with cation occlusion and Na(+),K(+)-ATPase activity.     

Large diameter of palytoxin-induced Na/K pump channels and modulation of palytoxin interaction by Na/K pump ligands

Palytoxin binds to Na/K pumps to generate nonselective cation channels whose pore likely comprises at least part of the pump's ion translocation pathway. We systematically analyzed palytoxin's interactions with native human Na/K pumps in outside-out patches from HEK293 cells over a broad range of ionic and nucleotide conditions, and with or without cardiotonic steroids. With 5 mM internal (pipette) [MgATP], palytoxin activated the conductance with an apparent affinity that was highest for Na(+)-containing (K(+)-free) external and internal solutions, lowest for K(+)-containing (Na(+)-free) external and internal solutions, and intermediate for the mixed external Na(+)/internal K(+), and external K(+)/internal Na(+) conditions; with Na(+) solutions and MgATP, the mean dwell time of palytoxin on the Na/K pump was about one day. With Na(+) solutions, the apparent affinity for palytoxin action was low after equilibration of patches with nucleotide-free pipette solution. That apparent affinity was increased in two phases as the equilibrating [MgATP] was raised over the submicromolar, and submillimolar, ranges, but was increased by pipette MgAMPPNP in a single phase, over the submillimolar range; the apparent affinity at saturating [MgAMPPNP] remained approximately 30-fold lower than at saturating [MgATP]. After palytoxin washout, the conductance decay that reflects palytoxin unbinding was accelerated by cardiotonic steroid. When Na/K pumps were preincubated with cardiotonic steroid, subsequent activation of palytoxin-induced conductance was greatly slowed, even after washout of the cardiotonic steroid, but activation could still be accelerated by increasing palytoxin concentration. These results indicate that palytoxin and a cardiotonic steroid can simultaneously occupy the same Na/K pump, each destabilizing the other. The palytoxin-induced channels were permeable to several large organic cations, including N-methyl-d-glucamine(+), suggesting that the narrowest section of the pore must be approximately 7.5 A wide. Enhanced understanding of palytoxin action now allows its use for examining the structures and mechanisms of the gates that occlude/deocclude transported ions during the normal Na/K pump cycle.     

Passive potassium transport in LK sheep red cells. Effects of anti-L antibody and intracellular potassium

The passive K influx in low K(LK) red blood cells of sheep saturates with increasing external K concentration, indicating that this mode of transport is mediated by membrane-associated sites. The passive K influx, iMLK, is inhibited by external Na. Isoimmune anti-L serum, known to stimulate active K transport in LK sheep red cells, inhibits iMLK about twofold. iMLK is affected by changes in intracellular K concentration, [K]i, in a complex fashion: increasing [K]i from near zero stimulates iMLK, while further increases in [K]i, above 3 mmol/liter cells, inhibit iMLK. The passive K influx is not mediated by K-K exchange diffusion. The effects of anti-L antibody and [K]i on passive cation transport are specific for K: neither factor affects passive Na transport. The common characteristics of passive and active K influx suggest that iMLK is mediated by inactive Na-K pump sites, and that the inability to translocate Na characterizes the inactive pumps. Anti-L antibody stimulates the K pump in reticulocytes of LK sheep. However, anti-L has no effect on iMLK in these cells, apparently because reticulocytes do not have the inactive pump sites which, in mature LK cells, are a consequence of the process of maturation of circulating LK cells. The results also indicate that anti-L alters the maximum velocity of both active and passive K fluxes by converting pumps sites from a form mediating passive K influx to an actively transporting form.     

Characterization of a novel variant of amino acid transport system asc in erythrocytes from Przewalski's horse (Equus przewalskii).

In thoroughbred horses, red blood cell amino acid transport activity is Na(+)-independent and controlled by three codominant genetic alleles (h, l, s), coding for high-affinity system asc1 (L-alanine apparent Km for influx at 37 degrees C congruent to 0.35 mM), low-affinity system asc2 (L-alanine Km congruent to 14 mM), and transport deficiency, respectively. The present study investigated amino acid transport mechanisms in red cells from four wild species: Przewalski's horse (Equus przewalskii), Hartmann's zebra (Zebra hartmannae), Grevy's zebra (Zebra grevyi), and onager (Equus hemonius). Red blood cell samples from different Przewalski's horses exhibited uniformly high rates of L-alanine uptake, mediated by a high-affinity asc1-type transport system. Mean apparent Km and Vmax values (+/- SE) for L-alanine influx at 37 degrees C in red cells from 10 individual animals were 0.373 +/- 0.068 mM and 2.27 +/- 0.11 mmol (L cells.h), respectively. As in thoroughbreds, the Przewalski's horse transporter interacted with dibasic as well as neutral amino acids. However, the Przewalski asc1 isoform transported L-lysine with a substantially (6.4-fold) higher apparent affinity than its thoroughbred counterpart (Km for influx 1.4 mM at 37 degrees C) and was also less prone to trans-stimulation effects. The novel high apparent affinity of the Przewalski's horse transporter for L-lysine provides additional key evidence of functional and possible structural similarities between asc and the classical Na(+)-dependent system ASC and between these systems and the Na(+)-independent dibasic amino acid transport system y+. Unlike Przewalski's horse, zebra red cells were polymorphic with respect to L-alanine transport activity, showing high-affinity or low-affinity saturable mechanisms of L-alanine uptake. Onager red cells transported this amino acid with intermediate affinity (apparent Km for influx 3.0 mM at 37 degrees C). Radiation inactivation analysis was used to estimate the target size of system asc in red cells from Przewalski's horse. The transporter's in situ apparent molecular weight was 158,000 +/- 2500 (SE).     

(Na,K)-ATPase-mediated cation pumping in cultured rat hepatocytes. Rapid modulation by alanine and taurocholate transport and characterization of its relationship to intracellular sodium concentration

(Na,K)-ATPase is thought to maintain the transmembrane electrochemical sodium gradient which powers secondary active sodium-coupled transport of a variety of solutes including amino acids and bile acids. However, little is known regarding the effect of sodium-coupled solute transport on intracellular sodium concentration ( [Na]ic) and on (Na,K)-ATPase-mediated cation pumping in the intact cell. In order to address this question, we have measured 22Na uptake rate, steady state 22Na content, and ouabain-suppressible 86Rb uptake rate in primary cultures of adult rat hepatocytes under a variety of conditions. Compared with control conditions (sodium uptake rate = 6.00 +/- 0.40 nmol X min-1 X mg-1; [Na]ic = 11.96 +/- 0.54 mM; cation pumping = 2.53 +/- 0.18 nmol X min-1 X mg-1), cation pumping was increased by taurocholate (less than or equal to 158%), alanine (less than or equal to 246%), monensin (less than or equal to 400%), and cold exposure (less than or equal to 525%), and this increase was accompanied by increases in Na uptake and [Na]ic. In contrast, preincubation in low sodium medium decreased all three variables. These changes in cation pumping were blocked in the absence of extracellular sodium and were not accompanied by changes in ouabain-suppressible ATP hydrolysis measured in cell homogenate. An overall plot of cation pumping versus [Na]ic yielded a sigmoid-shaped curve. Values for KNa (17.8 +/- 1.4 mM) and Vmax (8.98 +/- 0.62 nmol X min-1 X mg-1) for cation pumping were estimated assuming three sodium sites per pump unit. These findings indicate that: 1) uptake of alanine and taurocholate is associated with a rapid increase in (Na,K)-ATPase cation pumping; 2) this increase probably results from an increase in pumping per pump unit rather than an increase in the total number of pump units, and it appears to be mediated via an increase in sodium influx and [Na]ic; 3) [Na]ic under control conditions is close to the apparent KNa of cation pumping, implying that substrate availability may be the mechanism whereby sodium uptake is tightly linked to (Na,K)-ATPase cation pumping in intact hepatocytes.     

Cation Activation of the Basolateral Sodium-Potassium Pump in Turtle Colon

The current generated by electrogenic sodium-potassium exchange at the basolateral membrane of the turtle colon can be measured directly in tissues that have been treated with serosal barium (to block the basolateral potassium conductance) and mucosal amphotericin B (to reduce the cation selectivity of the apical membrane). We studied the activation of this pump current by mucosal sodium and serosal potassium, rubidium, cesium, and ammonium. The kinetics of sodium activation were consistent with binding to three independent sites on the cytoplasmic side of the pump. The pump was not activated by cellular lithium ions. The kinetics of serosal cation activation were consistent with binding to two independent sites with the selectivity Rb > K > Cs > NH₄. The properties and kinetics of the basolateral Na/K pump in the turtle colon are at least qualitatively similar to those ofthe well-characterized Na/K-ATPase of the human red blood cell .     

Cation-induced asymmetry of choline flux across presynaptic plasma membranes.

Highly cholinergic synaptosomes from the optic lobes of Sepia officinalis retain their ability to concentrate K+ and extrude Na+ sensitive but is not obligatorily coupled to choline metabolism, or an energy supply as shown by the action of metabolic and ion pump inhibitors. The influx and efflux and/or steady-state distributions of choline in the presence of Na+, Li+, Rb+, Cs+ and mannitol were studied. The influx studies at different cis-choline concentrations revealed two systems for choline influx with different monovalent cation sensitivity and suggested a 1 : 1 interaction of choline with both mechanisms. Choline efflux was stimulated by trans-choline. Calculations of the internal/external concentration ratio expected if choline transport were coupled to the Na+ gradient gave a maximal value of about 10(2). A secondary active transport of choline, where Na+ is the driver solute provides an explanation for the cation sensitivity of the mechanism as well as for the method of coupling of choline transport to the varying demands of the nervous system for acetylcholine.     

Membrane transport of potassium ions in erythrocytes of the American black bear, Ursus americanus

1. Membrane transport of K ions was investigated in red blood cells of bears by methods of measurement of unidirectional isotopic fluxes. 2. Unlike red cells of dogs, red cells of bears exhibited a significant, though small, component of ouabain-sensitive K influx. 3. Ouabain-insensitive K influx, as in other carnivore cells, was activated by swelling and inhibited by shrinkage. Swelling-induced K influx was dependent upon presence of chloride ions but was not inhibited by furosemide or bumetanide. 4. Ouabain-sensitive K influx was largest with ATP and with high concentration of Na in the cell, but it persisted in the absence of cytoplasmic Na or ATP. It was also resistant to the drug, harmaline, at a concentration that in other cells fully inhibits ouabain-sensitive K influx. 5. It was concluded that under such adverse conditions ouabain-sensitive K influx represents another mode of the Na/K pump not fully described elsewhere. 6. Also, as in low K red cells of sheep and goat, apparent absence of Na/K pump activity in carnivore red cells may represent suppression rather than elimination of activity. 7. Ouabain-insensitive K influx showed a seasonal pattern with minima occurring in early winter, earlier than for the minimum observed in Na influx. 8. Ouabain-sensitive K influx tended to be lower in the hibernation season of the bear, but the seasonal pattern was not consistent.     

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.