The influence of chloride on the ouabain-sensitive membrane potential and conductance of crayfish giant axons

Effect of extracellular potassium on ouabain-sensitive consumption of high-energy phosphate by crayfish giant axons: a study of the energy requirement for transport in the steady state

Crayfish axons exposed to a high or low extracellular K+ concentration ([K+]o) maintain intracellular Na+ and K+ concentrations constant, for up to 3 h, by adjusting both the Na+/K+ transport "coupling ratio" and turnover rate in compensation for changes in ion fluxes due to altered electrochemical gradients. These findings give rise to the prediction that the steady-state consumption of high-energy phosphate (approximately P) [ATP and phospho-L-arginine (Arg-P)] is inversely proportional to the [K+]o, i.e., directly proportional to the product of membrane conductance and magnitude of the transmembrane electrochemical gradients for Na+ and K+. This investigation was designed to test this hypothesis. The [K+]o did not influence total approximately P consumption (Q approximately P) of the axon. For a [K+]o between 0.5 and 21.6 mM, Q approximately P averaged 52.8 +/- 4.7%/h (n = 44) of the initial [ATP] + [Arg-P]. Unlike total Q approximately P, the ouabain-sensitive portion of Q approximately P was markedly influenced by [K+]o. In 0.5 mM K+o, ouabain poisoning reduced Q approximately P to 8%/h, a result indicating that 85% of the total Q approximately P was ouabain sensitive. For 1.35 mM K+o, the ouabain-sensitive portion was 66%; at 5.4 mM K+o, 45%; and at 13.5 mM K+o, 41%. There was a small but significant increase in the ouabain-sensitive Q approximately P at 21.6 mM K+o, compared with Q approximately P at 5.4 mM K+o. The pattern of effect of [K+]o on Q approximately P was similar to its effect on the electrical power content of the Na+ and K+ electrochemical gradients. In contrast to the generally accepted Na+ flux (JNa)/approximately P stoichiometry of 3, an actual ratio of JNa/approximately P stoichiometry of approximately 33:1 was calculated for the experiments reported here, a result suggesting that cells in a zero-membrane current steady state utilize efficient energy conservation mechanisms that may not operate under non-steady-state conditions.

High potassium selective permeability and extracellular ion regulation in the glial perineurium (blood-brain barrier) of the crayfish

Selective ion permeability, ion transport properties, and electrical resistance of the perineurial barrier, as they relate to interstitial ion regulation, where studied and characterized electrophysiologically in ion substitution experiments. In high external [K+] a transient spike-like voltage was generated across the perineurial barrier which fell over 1-2 min to a slowly decaying voltage. The glial perineurium had at least a 10 times greater permeability to K+ than Cl-, and was effectively impermeant to Na+. The potential, in high external [K+], was determined by the K+ and Cl- gradients and their relative permeabilities across the sheath. For other cations the selectivity sequence of the perineurial barrier, as determined from electrophysiological measurements, was K+ greater than or equal to Rb+ much greater than NH4+ greater than Cs+ greater than Li+ greater than Na+ corresponding most closely to the Eisenman sequence IV. The perineurium had a resistance of 260 +/- 23 omega cm2 in crayfish physiological solution. In high [K+]0 the resistance fell by over half during the transient spike potential and then recovered towards resting levels as the voltage decayed. In the intact nerve cord interstitial [K+] rose to only 10-20 mM during a 2-min exposure to 100 mM K0+. K influx and efflux were related to the change in barrier permeability and an increased selectivity to K+ which, in these studies, was determined primarily by its electrochemical gradient across the perineurial barrier. The results suggest that the crayfish perineurium is a leaky epithelium capable of a high degree of ion regulation. Trans-perineurial barrier potential and conductance in high external [K+] are primarily functions of passive processes of the perineurial glial cell membranes and of the paracellular conductance channels driven by the electrochemical gradient for the K+. Accordingly, the mass transport of [K+] showed the same quantitative relationship in both directions.

Studies of axon-glial cell interactions and periaxonal K+ homeostasis--III. The effect of anisosmotic media and potassium on the relationship between the resistance in series with the axon membrane and glial cell volume

The effect of anisosmotic physiological solutions and [K+]o on the resistance in series with the axon membrane were studied in medial giant axons of the crayfish, Procambarus clarkii, to determine if changes in series resistance are correlated with changes in glial cell volume and volume regulatory responses. Series resistance was estimated from computer analysed voltage waveforms generated by constant current and space clamp techniques using piggy-back axial wire current passing and glass pipette recording electrodes. Axons subjected to anisosmotic physiological solution in the range of 23 to 175% of isosmolar solution demonstrated that the series resistance of axons changes in a manner similar to that expected for a volume change in isolated cells. In hyperosmotic solution the series resistance changes biphasically, initially decreasing followed by a recovery of the series resistance, similar to the regulatory volume increase described for glial cells in culture. The increase in series resistance following the initial decrease is inhibited by bumetanide (0.1 mM). Ouabain (1 mM), an inhibitor of the volume decreasing Na-K pump, causes the series resistance to increase significantly above that seen for the no-drug control. Bumetanide, an inhibitor of the volume increasing Na-K-Cl cotransporter, inhibits the volume regulatory response to anisosmotic media. Treating the axon with three times normal external [K+] causes the series resistance to decrease approximately 15% while five times normal [K+] leads to a 15% increase in series resistance. Both ouabain and d-tubocurare (10(-p8) M) prevent the three-fold [K+]-induced decrease in series resistance while carbachol (10(-7) M) and bumetanide have little effect. On the other hand, ouabain enhances the five-fold [K+]-induced increase in series resistance while carbachol and bumetanide cause the five-fold [K+] response to be in a decreasing direction. d-Tubocurare has little effect on the five-fold [K+]-induced increase in series resistance. The study demonstrates that under the conditions of these experiments changes in series resistance are a reflection of changes in cell volume modulated by ouabain- and bumetanide-sensitive K+ uptake mechanisms. The effects of carbachol and d-tubocurare on the series resistance suggest that their effects are modulated through their actions on the glial cell membrane potential and the electrochemical gradient for K+, which in turn controls the amount of K+ that appears in the periaxonal space.(ABSTRACT TRUNCATED AT 400 WORDS)

Studies of axon-glial cell interactions and periaxonal K- homeostasis--I. The influence of Na+, K+, Cl- and cholinergic agents on the membrane potential of the adaxonal glia of the crayfish medial giant axon

The ionic basis for the low (-40 mV) resting membrane potential of glial cells surrounding the giant axons of the crayfish and their hyperpolarization by cholinergic agents (to -55 mV) was studied using standard electrophysiological techniques, ionic substitutions and pharmacological agents. The resting membrane potential of the glial cell was depolarized by increasing [K+]o, but the response was not Nernstian. Na+ depletion caused a small depolarization of the glial resting membrane potential, whereas Cl- depletion resulted in a hyperpolarization comparable to that seen with carbachol at various [K+]o. Both furosemide (1 mM) and bumetanide (0.1 mM) produced an 8-10 mV hyperpolarization as compared to 15-17 mV seen with Cl- depletion or carbachol. Carbachol has no further effect on the potential following furosemide treatment or Cl- depletion. After carbachol administration or Cl- depletion the resting membrane potential of the glial cell responded to [K+]o in a more Nernstian manner. The data indicate that the low resting membrane potential of glial cells is due to a combination of a low [K+]i and an outwardly-directed (depolarizing) Cl- electrochemical gradient. Carbachol acts to decrease Cl- conductance, resulting in the hyperpolarization of the glial cell membrane and a decrease in the outwardly-directed K+ electrochemical gradient by approximately two-thirds. We hypothesize that this mechanism for modulation of the glial cell membrane potential and the K+ electrochemical gradient serves to enhance the uptake of K+ by the glial cell transport system.

Inhibition of Na+, K+-ATPase activity by delta-aminolevulinic acid

delta-Aminolaevulinic acid (ALA) has been shown to be toxic to cultured neurons and glia at concentrations as low as 10 microM. In an attempt to elucidate the mechanism of toxicity, the effects of ALA on membrane ATPase activity were investigated. Exposure of neuron cultures to 1 mM ALA for 7 days caused a substantial decrease in both Na+, K+-ATPase and Mg2+-ATPase activities. At lower concentrations, ALA affected only the Na+, K+-component. ALA appeared to act directly, inhibiting Na+, K+-ATPase activity in rat brain cortex membrane preparations at 10 microM. Although this effect was slight, it may well represent the mechanism of action of ALA, since ouabain, a potent inhibitor of Na+, K+-ATPase activity, proved to be more toxic to cultured neurons than ALA. Furthermore, cardiac glycoside overdosage causes neurological disturbances which are very similar to those observed in the acute attack of porphyria.

Depression of axonal excitability by valproate is antagonized by phenytoin

Standard electrophysiologic techniques were employed to determine the effects of the two anticonvulsants, valproic acid (VPA) and phenytoin (DPH), on the membrane excitability properties of the crayfish giant axon. VPA, 4 mM, produces a depolarization of the membrane that is associated with a decrease in the resting membrane conductance (gM). VPA also attenuates the increase in gNa and gK that are responsible for the depolarization and repolarization of the action potential; it decreases the magnitude, rate of depolarization and repolarization, and conduction velocity of the propagated action potential while increasing its duration. DPH has some effects on membrane properties that are qualitatively similar to those of VPA; 0.11 mM DPH also decreases gM, gNa, and gK. Unlike VPA, DPH does not have a significant effect on magnitude of either the resting or action potential. Pretreatment of axons with DPH reduces the effect of VPA on the magnitude, rate of depolarization and repolarization, and duration of the action potential while completely preventing the effects of VPA on resting potential, conduction velocity, and membrane conductance. These experiments and others on the effects of K(+) depolarization on membrane properties demonstrate that part, but not all, of the influence of VPA on the membrane is secondary to its depolarizing effect. The results reported here on a membrane model suggest at least part of the cellular basis for the anticonvulsant properties of VPA and DPH, alone and in combination.

Effects of inhibition and stimulation of Na+-K+ active transport on the resting membrane input conductance of the guinea-pig ventricle

The effects of inhibition by ouabain and stimulation by high frequency drive of the sarcolemmal Na+-K+ active transport system on the resting input conductance (gi) of guinea-pig ventricular muscles were determined. Although both pump inhibition and stimulation were associated with changes in electrophysiological properties of the muscles, neither had a significant effect on gi.

Effects of chloride on the electrical and mechanical properties of guinea pig ventricle

The purpose of this study was to investigate the influence of chloride on the electrical and mechanical properties of the guinea pig ventricular myocardium. Bathing media were made chloride free by substituting the relatively impermeant anion gluconate, isethionate, or sulfate. Removal of chloride increased contractility and decreased the duration of the action potential. Additional experiments explored the influence of chloride free media on electrogenic calcium influx estimated from the magnitude of the action potential in cells partially depolarized by potassium (the slow response). In the absence of chloride, transient increases occurred in the magnitude of the slow response while the positive inotropic effect was maintained. These experiments suggest that the effects of chloride free media are mediated secondarily by an enhanced calcium influx.

Effect of external potassium on the coupled sodium: potassium transport ratio of axons

1. Resting membrane potential and the current-voltage relation were measured in crayfish giant axons bathed in various potassium solutions with and without ouabain. 2. Ouabain caused a depolarization of the membrane at each [K]o used but did not affect membrane resistance. 3. The ouabain-sensitive transport current was least (3 microamperemeter/cm2) in 0 mM [K]o and greatest (7 microamperemeter/cm2) in 16.2 and 21.6 mM [K]o. 4. The assumption was made an some indirect evidence presented that axons equilibrated in various potassium solutions maintain constant internal sodium and potassium concentrations for up to 3 h. 5. On the basis of this assumption, the apparent ratio of coupled Na : K transport was calculated. It was found to be least (-1.3/1) in 0 mM [K]o and to approach infinity in 16.2 and 21.6 mM [K]o. 6. The data indicate that the apparent variability of the Na : K exchange ratio likely represents an intrinsic property of the exchange mechanism and is less likely to be explained by a fixed-ratio coupled Na : K transport operating in parallel with electro-neutral Na : Na or K : K exchange.

Contribution of sodium pump to resting potential of squid giant axon

The effect of the cardiotonic aglycone, strophanthidin, on sodium and potassium efflux, membrane potential, membrane conductance, potassium permeability, and the shape of the action potential of the giant axon of the squid, Loligo pealei, was examined. Strophanthidin depolarized the membrane to an extent determined by the intracellular sodium concentration, except in axons pretreated with cyanide, in which the effect is abolished. Cyanide itself hyperpolarized the axon membrane. Axons treated with strophanthidin appear to be better potassium electrodes, but this observation is fully accounted for by the stimulating effect of [K]o on an electrogenic sodium pump. The increase in potassium efflux produced by strophanthidin is also well accounted for by the observed membrane depolarization and the known dependence of potassium permeability on membrane potential (e-fold increase in efflux per 6.4 mV depolarization). Strophanthidin has no demonstrable effect on membrane conductance apart from that due to the observed depolarization. These findings support the view that cardiotonic steroids, at least in nerve, are specific inhibitors of the sodium pump, devoid of effects on permeability that might interfere with the study of electrogenic pumping. The alteration in the shape of the action potential after exposure to strophanthidin (deepening of the "underswing") suggests that the strophanthidin-induced membrane depolarization results from the inhibition of a true electrogenic pump, and not from ion redistributions in the vicinity of the membrane.

The influence of cardioactive steroids, metabolic inhibitors, temperature and sodium on membrane conductance and potential of crayfish giant axons

1. The resting membrane potential and the current-voltage relation were measured in crayfish giant axons before and after treatment with cardioactive steroids, metabolic inhibitors, extracellular sodium depletion and low temperature. 2. The membrane resistance of axons treated with cardioactive steroids, metabolic inhibitors, and low extracellular sodium was reduced by 30-53% depending on the treatment. Low temperature also caused a decrease in the membrane resistance of the axon but the decrease was limited to potentials around the resting membrane potential. The temperature response of sodium depleted or ouabain treated axons was an increase in resistance at all points along the current-voltage relation. 3. All inhibitors and low temperature caused a depolarization of the membrane potential. Ouabain and strophanthidin were the most effective, reducing the membrane potential by an average of 9.6 mV in 10-20 min. Low sodium did not cause a depolarization but consistently reduced the membrane resistance by an average of 30%. 4. The data suggest that there is an interaction between the activity of the ouabain-sensitive transport system and resting membrane resistance in the crayfish axon.