Cell potential and the sodium-potassium pump in vascular smooth muscle.

An electrogenic sodium-potassium pump appears to contribute materially to the steady-state potential and to certain of the transient potential responses of vascular smooth muscle. Since changes in cell potential in turn can lead to changes in contractile state, the pump is implicated in some of the constriction-dilation responses of blood vessels. The vasodilator action of potassium is explainable, for instance, through an effect on cell potential if (and only if) an electrogenic pump is assumed to be extruding sodium at a faster rate than it takes up potassium. This is supported by the observation that ouabain, an inhibitor of Na,K-ATPase activity, will eliminate or reverse the vascular effect of potassium. Furthermore, when the in vivo and in vitro effects on vascular smooth muscle of altered extracellular potassium concentration are compared to calculated cell potentials based on a model that includes an electrogenic pump, the experimental findings are shown to be logical and predictable.     

Characteristics of electrogenic sodium pumping in rat myometrium

Sodium-rich myometrium, obtained from the uteri of pregnant rats, rapidly hyperpolarized when 4.6–120 mM potassium was added to the bathing medium at 37°C. Hyperpolarization was due to sodium pumping since the process was markedly temperature dependent, was abolished by ouabain, and required both intracellular sodium and extracellular potassium. The observed membrane potential exceeded the calculated potassium equilibrium potential during hyperpolarization providing evidence that sodium pumping was electrogenic. Hyperpolarization was reduced in the presence of chloride. The rate of sodium pumping may influence potassium permeability since potassium apparently did not short-circuit the pump during hyperpolarization.     

The ascorbate-driven reduction of extracellular ascorbate free radical by the erythrocyte is an electrogenic process

Erythrocytes can reduce extracellular ascorbate free radicals by a plasma membrane redox system using intracellular ascorbate as an electron donor. In order to test whether the redox system has electrogenic properties, we studied the effect of ascorbate free radical reduction on the membrane potential of the cells using the fluorescent dye 3,3'-dipropylthiadicarbocyanine iodide. It was found that the erythrocyte membrane depolarized when ascorbate free radicals were reduced. Also, the activity of the redox system proved to be susceptible to changes in the membrane potential. Hyperpolarized cells could reduce ascorbate free radical at a higher rate than depolarized cells. These results show that the ascorbate-driven reduction of extracellular ascorbate free radicals is an electrogenic process, indicating that vectorial electron transport is involved in the reduction of extracellular ascorbate free radical.     

Potassium reaccumulation by isolated frog epidermis

The involvement of potassium in transepithelial sodium transport was tested by studying net potassium reuptake by potassium-depleted frog skin epidermis. Normal potassium content in half-strength Ringer's (0.244 μequiv/mg dry weight) fell 43% after 16 h in K-free medium at 5°C. Reaccumulation, against an electrochemical potential gradient, to 83% of the initial tissue potassium content occurred following incubation for 4 h at 22°C in K-containing medium. Sodium was required in the solution bathing the inside, but not the outside surface of the skin, for net potassium reaccumulation. Ouabain caused an additional potassium loss from potassium-depleted epidermis, but did not have the same effect on potassium-depleted isolatedcells. Procaine, lithium and caffeine completely inhibited, antidiuretic hormone and cyclic AMP may partially inhibit and amiloride had no effect on potassium reaccumulation. In many cases decreases in sodium and water content were found to occur even in the absence of net potassium reaccumulation. The results suggest (1) potassium is actively transported into the epidermis, (2) this transport is not rigidly coupled to sodium extrusion or water loss, (3) potassium uptake is not rigidly coupled to transepithelial sodium transport, or only a small fraction is involved, (4) potassium diffusion is restricted in the extracellular space.     

Mechanism of trace hyperpolarization of the action potential of snail giant neurons]

Depolarization current decreases and hyperpolarization current increases the amplitude of tracing hyperpolarization of the neuron action potential. Calcium-defficient solution supresses the tracing depolarization, and turns the rhythmical activity of the neuron into the flashlike one. An increase of outer concentration of potassium ions decreases the tracing depolarization. The latter is suppressed completely when the membrane behaves as a potassium electrode. The suppressing effect of the increase of potassium outer concentration on tracing hyperpolarization decreases with a decrease of calcium ions content in the medium. When an active release of sodium ions from the cell is inhibited with DNP and substitution of sodium ions by lithium ions the tracing hyperpolarization of the action potential is suppressed. The tracing hyperpolarization is also suppressed during the shunting of the electrogenic effect of potassium pump with the outcoming current of chlorine ions. It is suggested that the tracing hyperpolarization of the single action potential is due to the calcium-dependent fraction of electrogenic release of sodium ions from the cell.     

A theory for the membrane potential of living cells

We give an explicit formula for the membrane potential of cells in terms of the intracellular and extracellular ionic concentrations, and derive equations for the ionic currents that flow through channels, exchangers and electrogenic pumps. We demonstrate that the work done by the pumps equals the change in potential energy of the cell, plus the energy lost in downhill ionic fluxes through the channels and exchangers. The theory is illustrated in a simple model of spontaneously active cells in the cardiac pacemaker. The model predicts the experimentally observed intracellular ionic concentration of potassium, calcium and sodium. Likewise, the shapes of the simulated action potential and five membrane currents are in good agreement with experiment. We do not see any drift in the values of the concentrations in a long time simulation, and we obtain the same asymptotic values when starting from the full equilibrium situation with equal intracellular and extracellular ionic concentrations. Received: 9 December 1998 / Revised version: 30 August 1999 / Accepted: 15 October 1999     

An upper limit for the electrogenic Na-K pump contribution to maximum diastolic potential in feline cardiac Purkinje fibers in steady state

We have estimated an upper limit for the electrogenic contribution of the Na-K pump to diastolic transmembrane potential. We simultaneously monitored the maximum diastolic potential and the extracellular space potassium activity during exposure to a very high concentration of ouabain. Exposure to ouabain caused a depolarization of approximately 3 mV (n = 33 experiments) over 34 +/- 3 s (mean +/- standard error) prior to any change in extracellular K activity. In four experiments, we monitored intracellular sodium activity and observed it to rise with approximately the same temporal lag (delay = 26 +/- 7 s). We also measured relative membrane conductance in one series of experiments and observed it to decrease to 91 +/- 2% of its control value by the time extracellular space K began to rise. Following the initial increase in extracellular space K activity the subsequent membrane depolarization is shown to be accurately predicted solely from the measured increase in extracellular space K activity as calculated from the Goldman equation. Limitations of the method and possible interpretations of the data are discussed. We interpret this ouabain-induced depolarization that occurs prior to the rise in external K to be an upper limit to the Na-K pump's electrogenic contribution to steady-state membrane potential.     

Regulation of Ion Gradients across Myocardial Ischemic Border Zones: A Biophysical Modelling Analysis

The myocardial ischemic border zone is associated with the initiation and sustenance of arrhythmias. The profile of ionic concentrations across the border zone play a significant role in determining cellular electrophysiology and conductivity, yet their spatial-temporal evolution and regulation are not well understood. To investigate the changes in ion concentrations that regulate cellular electrophysiology, a mathematical model of ion movement in the intra and extracellular space in the presence of ionic, potential and material property heterogeneities was developed. The model simulates the spatial and temporal evolution of concentrations of potassium, sodium, chloride, calcium, hydrogen and bicarbonate ions and carbon dioxide across an ischemic border zone. Ischemia was simulated by sodium-potassium pump inhibition, potassium channel activation and respiratory and metabolic acidosis. The model predicted significant disparities in the width of the border zone for each ionic species, with intracellular sodium and extracellular potassium having discordant gradients, facilitating multiple gradients in cellular properties across the border zone. Extracellular potassium was found to have the largest border zone and this was attributed to the voltage dependence of the potassium channels. The model also predicted the efflux of from the ischemic region due to electrogenic drift and diffusion within the intra and extracellular space, respectively, which contributed to depletion in the ischemic region.     

The role of extracellular sodium in isosmotic intracellular regulation in the respiratory tree of Holothuria glaberrima

• 1.1. Respiratory trees of Holothuria glaberrima exposed to solutions in which sodium has been replaced by choline, Tris pH 6.1, Tris pH 8.0 or lithium show a net loss of intracellular water, potassium, sodium and chloride. Intracellular content of neutral orgainc osmotic effectors remains unmodified.
• 2.2. Extracellular lithium and Tris pH 8.0 decrease intracellular potassium concentration to half that in sodium, choline and Tris pH 6.1. Intracellular sodium concentration falls markedly while that of chloride falls moderately in sodium-free solutions. Sodium substitutes appear to enter the cells.
• 3.3. A model based on Donnan considerations accounts for the patterns of ion and water distribution.

     

Regulation of yeast H(+)-ATPase by protein kinases belonging to a family dedicated to activation of plasma membrane transporters

The regulation of electrical membrane potential is a fundamental property of living cells. This biophysical parameter determines nutrient uptake, intracellular potassium and turgor, uptake of toxic cations, and stress responses. In fungi and plants, an important determinant of membrane potential is the electrogenic proton-pumping ATPase, but the systems that modulate its activity remain largely unknown. We have characterized two genes from Saccharomyces cerevisiae, PTK2 and HRK1 (YOR267c), that encode protein kinases implicated in activation of the yeast plasma membrane H(+)-ATPase (Pma1) in response to glucose metabolism. These kinases mediate, directly or indirectly, an increase in affinity of Pma1 for ATP, which probably involves Ser-899 phosphorylation. Ptk2 has the strongest effect on Pma1, and ptk2 mutants exhibit a pleiotropic phenotype of tolerance to toxic cations, including sodium, lithium, manganese, tetramethylammonium, hygromycin B, and norspermidine. A plausible interpretation is that ptk2 mutants have a decreased membrane potential and that diverse cation transporters are voltage dependent. Accordingly, ptk2 mutants exhibited reduced uptake of lithium and methylammonium. Ptk2 and Hrk1 belong to a subgroup of yeast protein kinases dedicated to the regulation of plasma membrane transporters, which include Npr1 (regulator of Gap1 and Tat2 amino acid transporters) and Hal4 and Hal5 (regulators of Trk1 and Trk2 potassium transporters).     

Influence of Lithium Ions on the Transmembrane Potential and Cation Content of Cardiac Cells

The effect of lithium ions on cardiac cells was investigated by recording the changes in transmembrane potential and by following the movement of Li, Na, and K across the cell membrane. Isolated preparations of calf Purkinje fibers and cat ventricular muscles were used. Potentials were measured by intracellular microelectrodes; ion transport was estimated by flame photometric analysis and by using the radioactive isotopes of Na and K. It was shown (a) that Li ions can replace Na ions in the mechanism generating the cardiac action potential but that they also cause a marked depolarization and pronounced changes in action potential configuration; (b) that the resting permeability to Li ions is high and that these ions accumulate in the cell interior as if they were not actively pumped outwards. In Li-Tyrode [K]_i decreases markedly while the K permeability seems to be increased. In a kinetic study of net K and Na fluxes, the outward movement of each ion was found to be proportional to the second power of its intracellular concentration. The effect on the transmembrane potential is explained in terms of changes in ion movement and intracellular ion concentration.     

Spontaneous induction of superoxide release and degranulation of neutrophils in isotonic potassium medium: the role of intracellular calcium

When guinea pig peritoneal neutrophils were suspended in the isotonic medium of potassium, rubidium, and cesium ions at 37 degrees C, the cells released superoxide, while low activity was observed in the isotonic medium of sodium and lithium ions. The activity induced in the potassium medium was enhanced by potassium-ionophores, valinomycin, and gramicidin, and decreased by a potassium channel blocker, 4-aminopyridine. The superoxide-releasing activity was not affected by the presence or absence of extracellular calcium but was inhibited by an intracellular calcium antagonist-8-(N,N-diethylamino)-octyl-3,4,5-trimethoxybenzoate(TMB-8) with the half-inhibition concentration of 50 microM. The release of granular enzymes, lysozyme and beta-glucuronidase, was also induced in the isotonic potassium medium in the absence of extracellular calcium and inhibited by TMB-8. A remarkable elevation of the intracellular free calcium concentration in neutrophils, which was monitored by quin-2 fluorescence, was found when the cells were added to the potassium medium without calcium. The elevation was inhibited by the addition of TMB-8. These observations suggest that calcium mobilization from intracellular storage sites, not an influx of calcium from the extracellular medium, causes the release of superoxide and the granular enzymes in isotonic potassium medium.     

Sulfation of glycosaminoglycans depends on the catalytic activity of lithium-inhibited phosphatase BPNT2 in vitro

Golgi-resident bisphosphate nucleotidase 2 (BPNT2) is a member of a family of magnesium-dependent, lithium-inhibited phosphatases that share a three-dimensional structural motif that directly coordinates metal binding to effect phosphate hydrolysis. BPNT2 catalyzes the breakdown of 3′-phosphoadenosine-5′-phosphate, a by-product of glycosaminoglycan (GAG) sulfation. KO of BPNT2 in mice leads to skeletal abnormalities because of impaired GAG sulfation, especially chondroitin-4-sulfation, which is critical for proper extracellular matrix development. Mutations in BPNT2 have also been found to underlie a chondrodysplastic disorder in humans. The precise mechanism by which the loss of BPNT2 impairs sulfation remains unclear. Here, we used mouse embryonic fibroblasts (MEFs) to test the hypothesis that the catalytic activity of BPNT2 is required for GAG sulfation in vitro. We show that a catalytic-dead Bpnt2 construct (D108A) does not rescue impairments in intracellular or secreted sulfated GAGs, including decreased chondroitin-4-sulfate, present in Bpnt2-KO MEFs. We also demonstrate that missense mutations in Bpnt2 adjacent to the catalytic site, which are known to cause chondrodysplasia in humans, recapitulate defects in overall GAG sulfation and chondroitin-4-sulfation in MEF cultures. We further show that treatment of MEFs with lithium (a common psychotropic medication) inhibits GAG sulfation and that this effect depends on the presence of BPNT2. Taken together, this work demonstrates that the catalytic activity of an enzyme potently inhibited by lithium can modulate GAG sulfation and therefore extracellular matrix composition, revealing new insights into lithium pharmacology.     

An electrogenic pump in the xylem parenchyma of barley roots

Analysis of an electrogenic pump in the plasma membrane of xylem-parenchyma protoplasts from barley roots was performed using the patch-clamp technique in the whole-cell configuration. Particularly with regard to understanding xylem loading and unloading, the study of the electrogenic pump from this cell type is important; its functional confirmation was lacking to date. About one-half of the investigated protoplasts displayed current responses with reversal potentials between −80 and −200 mV. The application of fusicoccin, an H⁺-pump stimulator, caused an increase in currents recorded at a membrane potential of 0 mV and a shift of the reversal potential by about −50 mV. Treatment with dicylohexylcarbodiimid, an H⁺-pump inhibitor, resulted in the reduction of the current at 0 mV. The Ca²⁺-pump inhibitor, erythrosin B, showed no effect on current density at 0 mV and on the polarisation of the membrane potential. Enlarging the transmembrane pH gradient by raising the pH of the extracellular solution from 5.8 to 8.8 stimulated the currents. These are strong indications that the electrogenic pump was an H⁺-pump. Neither intracellular pH nor the intracellular Ca²⁺ concentration affected its activity. Simultaneous activity of the electrogenic pump and anion conductances could produce states in which protoplasts exhibited 'intermediate' reversal potentials. It was concluded that the electrogenic pump was not directly involved in the loading of KCl and KNO₃ into the xylem but, in combination with anion channel activities, contributed to the establishment of membrane potentials at which electroneutral salt transport and acid release can proceed.     

The effects of ionophores and metabolic inhibitors on methanogenesis and energy-related properties of Methanobacterium bryantii

The effects of numerous ionophores and inhibitors were tested on methane synthesis, intracellular ATP and potassium concentrations, and the proton motive force of the methanogenic archaebacterium Methanobacterium bryantii. M. bryantii had an internal pH near 6.8 (and hence little ΔpH during growth) with an electrical potential of ?127 mV in growth medium and ?105 mV in a pH 6.5 buffer. The study has identified agents which, in M. bryantii, can effectively cause a decline of intracellular ATP (gramicidin, acetylene) and potassium concentrations (gramicidin, nigericin), inhibit methane synthesis (acetylene, gramicidin, nigericin, triphenylmethylphosphonium bromide), eliminate the electrical potential (high extracellular potassium ion concentrations), and dissipate artificially imposed, inside alkaline, pH gradients (monensin, nigericin, carbonyl cyanide m-chlorophenylhydrazone). Carbonyl cyanide m-chlorophenylhydrazone was generally ineffective in media or buffers reduced with cysteine-sulfide but could be effective in cysteine-free solutions reduced with hydrogen sulfide.     

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.     

Potassium uptake by the dog erythrocyte

The inward transport of potassium by separated dog erythrocytes has been studied at concentrations of potassium in the medium from 2.9 to 25.0 m.eq./liter and at 38.0 and 33.0 degrees C. At the physiological concentration of external potassium (4.06 m.eq./liter medium), the inward potassium flux is 0.11 m.eq./liter cells hour and the glucose consumption is 2.0 mM/liter cells hour. The dependence of potassium influx on extracellular potassium concentration is given by the following equation, K influx (m.eq./liter cells hour) = 0.028 [K](amb.) - 0.003 in which [K](amb.) refers to the potassium concentration in the medium. In a single 93 hour experiment, 94 per cent of the intracellular potassium was exchanged at an apparently uniform rate. The average apparent activation energy for the process is 7,750 calories +/- 2,000 calories/mol and there is some indication that the apparent activation energy of inward K transport decreases with increasing external K concentration.     

Lithium and Valproate Protect Hippocampal Slices Against ATP-induced Cell Death

Lithium and valproate (VPA) are the most commonly prescribed mood-stabilizing drugs. Recently, several studies have reported their neuroprotective properties in several models of neural toxicity and, in some pathological conditions, large amounts of intracellular ATP can be released from damaged cells. In the present study, we investigate the potential neuroprotective effect of lithium and VPA against ATP-induced cell death in hippocampal slices of adult rats. Acute (in vitro) and chronic (in vivo) treatment at therapeutic doses with lithium or VPA significantly prevent the ATP-induced cell death. Lithium and VPA also exerted a synergic effect in the prevention of ATP-induced cell death. Moreover, hippocampal slices prepared from rats chronically treated with lithium or VPA presented a significant reduction in cell death in the presence of cytotoxic extracellular ATP. Although further investigations are necessary, our results show the neuroprotective effect of lithium and VPA against neuronal death induced by extracellular ATP, probably through a different pathway, and suggest novel uses of these drugs in neurogenerative diseases. L. C. Wilot and A. Bernardi equally contributed by this work.     

Identification of trkH,Encoding a Potassium Uptake Protein Required for Francisella tularensis Systemic Dissemination in Mice

Francisella tularensis is a highly infectious bacterium causing the zoonotic disease tularaemia. During its infectious cycle, F. tularensis is not only exposed to the intracellular environment of macrophages but also resides transiently in extracellular compartments, in particular during its systemic dissemination. The screening of a bank of F. tularensis LVS transposon insertion mutants on chemically defined medium (CDM) led us to identify a gene, designated trkH, encoding a homolog of the potassium uptake permease TrkH. Inactivation of trkH impaired bacterial growth in CDM. Normal growth of the mutant was only restored when CDM was supplemented with potassium at high concentration. Strikingly, although not required for intracellular survival in cell culture models, TrkH appeared to be essential for bacterial virulence in the mouse. In vivo kinetics of bacterial dissemination revealed a severe defect of multiplication of the trkH mutant in the blood of infected animals. The trkH mutant also showed impaired growth in blood ex vivo. Genome sequence analyses suggest that the Trk system constitutes the unique functional active potassium transporter in both tularensis and holarctica subspecies. Hence, the impaired survival of the trkH mutant in vivo is likely to be due to its inability to survive in the low potassium environment (1–5 mM range) of the blood. This work unravels thus the importance of potassium acquisition in the extracellular phase of the F. tularensis infectious cycle. More generally, potassium could constitute an important mineral nutrient involved in other diseases linked to systemic dissemination of bacterial pathogens.