Effects of external cesium and rubidium on outward potassium currents in squid axons

We have studied the effects of external cesium and rubidium on potassium conductance of voltage clamped squid axons over a broad range of concentrations of these ions relative to the external potassium concentration. Our primary novel finding concerning cesium is that relatively large concentrations of this ion are able to block a small, but statistically significant fraction of outward potassium current for potentials less than approximately 50 mV positive to reversal potential. This effect is relieved at more positive potentials. We have also found that external rubidium blocks outward current with a qualitatively similar voltage dependence. This effect is more readily apparent than the cesium blockade, occurring even for concentrations less than that of external potassium. Rubidium also has a blocking effect on inward current, which is relieved for potentials more than 20-40 mV negative to reversal, thereby allowing both potassium and rubidium ions to cross the membrane. We have described these results with a single-file diffusion model of ion permeation through potassium channels. The model analysis suggests that both rubidium and cesium ions exert their blocking effects at the innermost site of a two-site channel, and that rubidium competes with potassium ions for entry into the channel more effectively than does cesium under comparable conditions.     

THE SELECTIVE ABSORPTION OF POTASSIUM BY ANIMAL CELLS : II. THE CAUSE OF POTASSIUM SELECTION AS INDICATED BY THE ABSORPTION OF RUBIDIUM AND CESIUM.

1. Frog muscles perfused with Ringer solution in which potassium chloride has been replaced by an equivalent amount of rubidium or cesium chloride take up rubidium or cesium and incorporate them into the tissue substance in such form as to be retained during a subsequent perfusion with potassium-free Ringer solution, provided the muscles contract during the first perfusion. Retention of rubidium or cesium by a resting muscle does not occur. 2. Rats on synthetic diets, adequate in all respects except that potassium was replaced by an equivalent amount of rubidium or cesium, died after a period varying from 10 to 17 days with characteristic symptoms including tetanic spasms. Muscle, heart, liver, kidney, spleen, and lung tissues were then found to contain significant amounts of rubidium or cesium. The concentration of these metals in the muscle amounted, in some cases, as shown by a spectroscopic estimation, to about half the concentration of potassium normally found in mammallian muscle. 3. The results are regarded as tending to confirm the theory that the peculiarities in the physiological effects of potassium, including the facility with which it is "selected" by living cells in preference to sodium, are related to the electronic structure of the potassium ion as compared with that of similar ions. The possible relationship of the comparative migration velocity, a function of the electronic structure, to physiological effects is suggested.     

Cation exchange binding of rubidium and cesium by rat liver cell microsomes

The rubidium and cesium binding characteristics of rat liver cell microsomes were studied by an equilibration, centrifugation and washing procedure. Concentration dependence experiments, in which microsomes were equilibrated in media containing 0 to 400 mM rubidium or cesium chloride at pH 6.9, yielded saturation type adsorption isotherms similar to those previously reported for sodium and potassium. Mass law analysis of the data yielded apparent dissociation constants of 21 × 10^?3 eq/liter and 19 × 10^?3 eq/liter for rubidium and cesium binding, respectively. The results indicate that cesium is bound slightly more strongly than rubidium, and that both these cations may be bound more strongly than sodium or potassium. The maximum binding capacity at pH 6.9 was approximately 1.3 meq rubidium or cesium/g nitrogen. Sodium, potassium, magnesium and calcium generally associated with the isolated microsomes decreased concomitantly with increasing bound rubidium or cesium, demonstrating the ion exchange nature of the binding. Results of pH-dependence experiments showed that following equilibration of the microsomes in media containing approximately 96 mM rubidium or cesium at various pH values, bound rubidium or cesium was essentially zero at pH less than five, increased sharply between pH 5 and 7, and tended to level off at higher pH. The present results further characterize the cation binding properties of the microsomal material.     

The Potassium Flux Ratio in Skeletal Muscle As a Test for Independent Ion Movement

The flux ratio of potassium ions was measured on frog sartorius muscle under conditions in which a substantial net potassium loss occurs. Muscle fiber membrane potentials were measured under identical conditions. The observed flux ratios were compared with values calculated from a theoretical relation derived on the assumptions that the unidirectional fluxes are both passive and occur independently. The results favor the conclusion that the potassium fluxes across skeletal muscle membrane occur along passive electrochemical gradients and obey the independence principle.     

Effect of Various Ions, pH, and Osmotic Pressure on Oxidation of Elemental Sulfur by Thiobacillus thiooxidans

The oxidation of elemental sulfur by Thiobacillus thiooxidans was studied at pH 2.3, 4.5, and 7.0 in the presence of different concentrations of various anions (sulfate, phosphate, chloride, nitrate, and fluoride) and cations (potassium, sodium, lithium, rubidium, and cesium). The results agree with the expected response of this acidophilic bacterium to charge neutralization of colloids by ions, pH-dependent membrane permeability of ions, and osmotic pressure.     

Effect of various ions, pH, and osmotic pressure on oxidation of elemental sulfur by Thiobacillus thiooxidans.

The oxidation of elemental sulfur by Thiobacillus thiooxidans was studied at pH 2.3, 4.5, and 7.0 in the presence of different concentrations of various anions (sulfate, phosphate, chloride, nitrate, and fluoride) and cations (potassium, sodium, lithium, rubidium, and cesium). The results agree with the expected response of this acidophilic bacterium to charge neutralization of colloids by ions, pH-dependent membrane permeability of ions, and osmotic pressure.     

CALCULATIONS OF BIOELECTRIC POTENTIALS : VI. SOME EFFECTS OF GUAIACOL ON NITELLA

Values have been calculated for apparent mobilities and partition coefficients in the outer non-aqueous layer of the protoplasm of Nitella. Among the alkali metals (with the exception of cesium) the order of mobilities resembles that in water and the partition coefficients (except for cesium) follow the rule of Shedlovsky and Uhlig, according to which the partition coefficient increases with the ionic radius. Taking the mobility of the chloride ion as unity, we obtain the following: lithium 2.04, sodium 2.33, potassium 8.76, rubidium 8.76, cesium 1.72, ammonium 4.05, ½ magnesium 20.7, and ½ calcium 7.52. After exposure to guaiacol these values become: lithium 5.83, sodium 7.30, potassium 8.76, rubidium 8,76, cesium 3.38, ammonium 4.91, ½ magnesium 20.7, and ½ calcium 14.46. The partition coefficients of the chlorides are as follows, when that of potassium chloride is taken as unity: lithium 0.0133, sodium 0.0263, rubidium 1.0, cesium 0.0152, ammonium 0.0182, magnesium 0.0017, and calcium 0.02. These are raised by guaiacol to the following: lithium 0.149, sodium 0.426, rubidium 1.0, cesium 0.82, ammonium 0.935, magnesium 0.0263, and calcium 0.323 (that of potassium is not changed). The effect of guaiacol on the mobilities of the sodium and potassium ions resembles that seen in Halicystis but differs from that found in Valonia where guaiacol increases the mobility of the sodium ion but decreases that of the potassium ion.     

Some Cation Interactions in Muscle

It has been possible to treat potassium, rubidium, and cesium ion entry into frog sartorius muscle by the use of a model which assumes a limited number of sites at the cell surface. The ion concentration in an outer surface layer is regarded as the main factor determining the rate of inward movement. It is supposed that the concentration of ions in the external solution is effective in promoting inward movement only to an extent determined by the fraction of sites occupied. Equations are derived from the model which fit the inward flux versus applied concentration curves experimentally determined for the three ions. The ions were found to compete for the postulated sites in various bi-ionic mixtures, the competition being satisfactorily described by equations derived from the model. The constants assigned to each ion remain invariant and independent of gradients in electrochemical potential. The order of decreasing exchange rate found is K > Rb > Cs. The order of decreasing site affinity found is Rb > K > Cs which is the same order as that observed for the ion selectivity deduced from analytical measurements of cation preference after equilibration in various equimolal mixtures (Lubin and Schneider (21)). The manner in which such a model might affect the application of a theory which assumes electrical driving forces as well is discussed.     

Untersuchung der im Vergleich zur Kalium-Anreicherung bevorzugten Anreicherung von Cäsium 137 im Säugetierorganismus

Zusammenfassung Es werden Untersuchungen zur Kalium-, Rubidium- und Cäsium- Anreicherung am perfundierten Meerschweinchenherzen durchgeführt. Unter Verwendung der Radionuklide⁴²K,⁸⁶Rb und¹³⁷Cs werden mit Hilfe einer Meßeinrichtung Alkaliionenflüsse zwischen Perfusionslösung und Herzmuskelzelle bestimmt. Es wird die Mehrdeutigkeit der Versuchsergebnisse diskutiert und einexperimentum crucis vorgeschlagen, das entscheiden soll, ob das Ruhepotential als Diffusionsoder als Grenzflächenpotential angesehen werden muß. Im Hinblick auf die unterschiedliche Kalium- und Cäsium-137-Anreicherung im Säugetierorganismus zeigen die Versuche, daß sich Cäsium gegenüber der Muskelzelle qualitativ wie Kalium verhält und daß Cäsium im Herzmuskel nicht bevorzugt angereichert wird.

---

On the preferred accumulation of cesium 137 in mammalian organism in comparison with the accumulation of potassiumI. Accumulation of potassium, rubidium and cesium in the perfused guinea-pig heart

Summary Experiments concerning the accumulation of potassium, rubidium and cesium in the perfused guinea-pig heart were performed. Using the radionuclides⁴²K,⁸⁶Rb,¹³⁷Cs and a scintillation counter, the alkali ion fluxes between the perfusion solution and the heart muscle cells are evaluated. The ambiguity of the results is discussed and anexperimentum crucis is proposed which shall decide wether the resting potential has the character of a diffusion or of a phase-boundary potential. As to the different accumulations of potassium and cesium in mammalian organism, our experiments demonstrate that the transport mechanism into the cell is similar for potassium and cesium and that cesium is not accumulated at a higher degree than potassium in the heart muscle cell.

     

A comparative study of the membrane permeability properties of amphibian and cephalopod mollusc lenses

Summary The potassium permeability characteristics of the lens membranes of the amphibianRana pipiens and the cephalopodSepiola atlantica were compared by electrophysiological techniques. Both membrane systems are much more permeable to potassium than sodium and inSepiola, the membranes behave as a pure selective potassium electrode near the normal resting potential. The amphibian lens electrical conductance behaves as an outward rectifier, the properties of which can be altered in the presence of external caesium and rubidium. The effects observed were interpreted in terms of blocking of conductance by the alkali metals.The resting conductance ofSepiola lens membranes is much greater than that of the frog and it is not voltage-sensitive. When the external potassium is reduced, however, the conductance decreases and the underlying non-linear properties are revealed. Additions of rubidium, caesium and barium to the external medium further reduce the conductance and the rectifying properties are enhanced. Again these effects are interpreted in terms of a blocking of potassium conductance by these ions.The different potassium permeability properties of the two systems are discussed in terms of the role of potassium in the regulation of lens internal osmolarity.     

Transmembrane effects in the sodium pump system. I. The effect of external potassium and rubidium on the dependence of sodium efflux on sodium concentration in the frog muscle

The dependence of sodium efflux on intracellular sodium content with various potassium and rubidium concentration in the external medium has been studied on frog sartorious muscle. In potassium-sodium-free magnesium medium ouabain-sensitive sodium efflux was shown to be proportional to internal sodium concentration. In the presence of external ribidium (0.5--5.0 mM) the efflux concentration relations are non-linear, being closely described by assuming that 3 Na+ are transported per pump cycle. In sodium loaded muscles the efflux concentration curve was found to be dependent on the external rubidium concentration, becoming linear instead of S-shaped with the decrease in internal rubidium concentration from 5.0--2.5 to 1.0--0.5 mM. The apparent affinity constant for the internal sodium pump site increased with increasing the external rubidium (potassium) concentration. The data obtained may contribute to the kinetic evaluation of the type of Na-K pump mechanism, being more consistent with simultaneous model of pump operation.     

Sodium channel selectivity. Dependence on internal permeant ion concentration

The selectivity of sodium channels in squid axon membranes was investigated with widely varying concentrations of internal ions. The selectivity ratio, PNa/PK, determined from reversal potentials decreases from 12.8 to 5.7 to 3.5 as the concentration of internal potassium is reduced from 530 to 180 to 50 mM, respectively. The internal KF perfusion medium can be diluted by tetramethylammonium (TMA), Tris, or sucrose solutions with the same decrease in PNa/PK. The changes in the selectivity ratio depend upon internal permeant ion concentration rather than ionic strength, membrane potential, or chloride permeability. Lowering the internal concentration of cesium, rubidium, guanidnium, or ammonium also reduces PNa/Pion. The selective sequence of the sodium channel is: Na greater than guanidinium greater than ammonium greater than K greater than Rb greater than Cs.     

Rubidium reduces potassium permeability and fluid secretion in Malpighian tubules of Locusta migratoria, L

The basal membrane potential (V(b)) of Locusta Malpighian tubule cells in control saline results from its relatively high permeability to potassium. In the presence of 1 mM barium added to the control saline V(b) hyperpolarized from a mean resting potential of -72.1 mV to -90.1 mV. On substituting rubidium for potassium in the control saline, V(b) also hyperpolarized to a value of -91.4 mV. Rubidium was also similarly effective in hyperpolarizing the basal membrane even in the presence of control concentrations of potassium in the bathing medium. Substitution of rubidium for potassium also effected a approximately 50% reduction in the rate of fluid secretion. The action of inhibitors on V(b) in the presence of rubidium showed that V(b) under these conditions probably originated from the bafilomycin-sensitive electrogenic potential generated across the apical membrane by a V-type ATPase. The responses of V(b) to potassium, barium and rubidium and their inhibition of fluid secretion suggest the presence of a substantial rubidium-blockable potassium conductance located on the basal membrane of Locusta Malpighian tubule cells.     

Long duration responses in squid giant axons injected with 134cesium sulfate solutions

Giant axons from the squid were injected with 1.5 M cesium sulfate solutions containing the radioactive isotopes 42K and 134Cs. These axons, when stimulated, gave characteristic long duration action potentials lasting between 5 and 45 msec. The effluxes of 42K and 134Cs were measured both under resting conditions and during periods of repetitive stimulation. During the lengthened responses there were considerable increases in potassium efflux but only small increases in cesium efflux. The selectivity of the delayed rectification process was about 9 times greater for potassium ions than for cesium ions. The data suggest that internal cesium ions inhibit the outward potassium movement occurring during an action potential. The extra potassium effluxes taking place during excitation appear to be reduced in the presence of cesium ions to values between 7 and 22% of those expected in the absence of cesium inhibition.     

The Suppression of the Late After-Potential in Rubidium-Containing Frog Muscle Fibers

The late after-potential that follows trains of impulses in frog muscle fibers is virtually absent when most of the intracellular potassium is replaced by rubidium and the muscle is immersed in rubidium-containing Ringer's fluid. Its amplitude is also reduced in freshly dissected, potassium-containing muscle fibers that are immersed directly in Rb-Ringer's fluid. These findings are discussed in terms of the model for muscle membrane of Adrian and Freygang (1962 a, b) and in relation to the report of Adrian (1964) that Rb-containing muscle fibers do not exhibit the variations in potassium permeability as a function of membrane potential that are found in fibers with normal intracellular potassium concentration immersed in Ringer's fluid.     

Transmembrane effects in the sodium pump system. II. The ratio of the sodium efflux to the sodium concentration in frog muscle in media with various sodium substitutes

The dependence of sodium efflux on the internal sodium concentration on sodium-free magnesium, Tris, coline and lithium media was investigated on frog striated muscle. In all the sodium-substituted media, the efflux concentration curve was found to be dependent on the external rubidium concentration, being S-shaped at the saturating external rubidium (potassium) concentration and becoming close to linear at the low external rubidium concentration (0.5-1.0 microM). The maximal sodium efflux at saturating levels of internal sodium concentrations remains unchanged with various sodium substitutes in the medium, whereas the affinity constant of internal sodium sites is dependent on the external cations.     

D2O as a modifier of ionic specificity of Na, K-ATPase

Effect of heavy water D2O on the rate of hydrolysis of ATP and pNPP by Na,K-ATPase was studied. Heavy water of high concentration inhibits the rate of ATPase reaction in all the studied ratios of the ions Na/K at constant ionic strength 150 mM. Activation of the enzyme was observed in the solution with low concentration of heavy water (less than 5%). The value of isotope effects depended on the ratio between sodium and potassium ion concentrations in the medium. At low temperature no activation of the enzyme with heavy water in low concentration was observed. Substitution of usual water for the heavy one was accompanied by a decrease of apparent constants of enzyme activation with sodium and potassium ions. During pNPP hydrolysis with Na,K-ATPase an increase of reaction rate in the medium with heavy water was observed. Substitution of potassium ions by cesium resulted in an increase of isotope effects during ATP and pNPP hydrolysis. Analysis of isotope effects in terms of the molecular model of sodium pump proposed permits a conclusion that the isotope effects of heavy water are explained by its influence as a solvent, the binding centres of potassium and sodium ions are localized in different regions of the enzyme differing in physico-chemical properties. The structure of sodium centres is controlled by hydrogen bonds, and of potassium ones--by hydrophobic interactions; the transport of ions by the enzyme is accompanied by dehydration of ions.     

Identification of novel KCNQ4 openers by a high-throughput fluorescence-based thallium flux assay

To develop a real-time thallium flux assay for high-throughput screening (HTS) of human KCNQ4 (Kv7.4) potassium channel openers, we used CHO-K1 cells stably expressing human KCNQ4 channel protein and a thallium-sensitive dye based on the permeability of thallium through potassium channels. The electrophysiological and pharmacological properties of the cell line expressing the KCNQ4 protein were found to be in agreement with that reported elsewhere. The EC₅₀ values of the positive control compound (retigabine) determined by the thallium and ⁸⁶rubidium flux assays were comparable to and consistent with those documented in the literature. Signal-to-background (S/B) ratio and Z factor of the thallium influx assay system were assessed to be 8.82 and 0.63, respectively. In a large-scale screening of 98,960 synthetic and natural compounds using the thallium influx assay, 76 compounds displayed consistent KCNQ4 activation, and of these 6 compounds demonstrated EC₅₀ values of less than 20 μmol/L and 2 demonstrated EC₅₀ values of less than 1 μmol/L. Taken together, the fluorescence-based thallium flux assay is a highly efficient, automatable, and robust tool to screen potential KCNQ4 openers. This approach may also be expanded to identify and evaluate potential modulators of other potassium channels.     

Potassium transport system of Rhodopseudomonas capsulata

Rhodopseudomonas capsulata required potassium (or rubidium or cesium as analogs of potassium) for growth. These cations were actively accumulated by the cells by a process following Michaelis-Menten saturation kinetics. The monovalent cation transport system had Km's of 0.2 mM K+, 0.5 mM Rb+, and 2.6 mM Cs+. The rates of uptake of substrates by the potassium transport system varied with the age of the culture, although the affinity constant for the substrates remained constant. The maximal velocity of uptake of K+ was lower in aerobically grown cells than in photosynthetically grown cells, although the Km's for K+ and for Rb+ were about the same.     

Model of active transport of ions in cardiac cell

A model of the active transport of ions in a cardiac muscle cell, which takes into account the active transport of Na⁺, K⁺, Ca²⁺, Mg²⁺, HCO₃⁻ and Cl⁻ ions, has been constructed. The model allows independent calculations of the resting potential at the biomembrane and concentrations of basic ions (sodium, potassium, chlorine, magnesium and calcium) in a cell. For the analysis of transport processes in cardiac cell hierarchical algorithm “one ion-one transport system” was offered. The dependence of the resting potential on concentrations of the ions outside a cell has been established. It was shown, that ions of calcium and magnesium, despite their rather small concentration, play an essential role in maintenance of resting potential in cardiac cell. The calculated internal concentrations of ions are in good agreement with the corresponding experimental values.