Intracellular sodium activity and the sodium pump in snail neurones

Acid influx into snail neurones caused by reversal of the normal pHi-regulating system

Intracellular pH (pHi), and Na+ and Cl- activities were measured with ion-sensitive micro-electrodes in Helix aspersa neurones, and the effects of reducing external pH (pHo) were investigated. When pHo was changed from 7.5 to 6.5 keeping CO2 constant, there was a slow fall in pHi, a rise in internal Cl and a fall in internal Na. These ionic changes are opposite to those caused by normal operation of the pHi-regulating system. These effects of external acidification were inhibited by the application of SITS (4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonic acid) or by the removal of external Cl. Raising intracellular Na activity by inhibiting the Na pump increased the rate of fall of pHi in acid solutions. In acid solutions the average rate of acid uptake attributable to reversed pHi-regulation was about three times the rate of loss of internal Na, and about twice the rate of Cl uptake. We conclude that these intracellular ion changes in acid solutions were largely due to a reversal of the pHi-regulating mechanism, so that it carried acid into, rather than out of, the cell interior.

Activation of feline acetylcholine synthesis in the absence of release: dependence on sodium, calcium and the sodium pump

Following a 15 min inhibition of the Na pump in the cat superior cervical ganglion by perfusion with K-free Locke solution, a 10 min recovery period in normal Locke produced a 51% increase in acetylcholine stores. The increase in acetylcholine stores occurred without increase in acetylcholine release. Thus this procedure of pump inhibition followed by recovery selectively activates acetylcholine synthesis. The increase in acetylcholine stores occurred entirely during the 10 min recovery period in which the Na pump was re-activated. This increase represents a rate of synthesis of acetylcholine of 5.1% of stores per minute, which equals the maximum rate that can be achieved during high-frequency preganglionic nerve stimulation. The increase in stores was not affected by substituting isethionate for all but 8 mM-Cl in the perfusion fluids. The increase in stores was prevented by reducing the Na concentration of the K-free Locke to 25 mM. The increase in stores was only 17% when Ca was omitted from the K-free Locke. Omission of Ca from the perfusion fluid in the recovery period as well as in the period of pump inhibition prevented any increase in stores. It is concluded that the selective activation of acetylcholine synthesis following the pause in Na pumping was a direct result of an increase in Na pump rate and an increase in internal Ca in the nerve terminals. It is proposed that similar changes in Na pump rate and internal Ca produced by repetitive nerve impulse activity likewise activate acetylcholine synthesis independently of release of transmitter or depletion of stores.

Stimulation of a sodium influx by cAMP in Helix neurons

Brief pressure injections of aqueous solutions of cAMP in identified neurons of Helix pomatia caused depolarizations which lasted for tens of seconds. In voltage-clamped neurons an inward current of similar duration was induced which saturated at 10 microA/cm2 cell surface. In the range of negative membrane potentials with little voltage-dependent activation, this current was not accompanied by a change in membrane conductance. The inward current was not produced by injection of ATP, ADP, adenosine, inosine or cGMP. cAMP derivatives produced longer-lasting effects. Prolongation of the inward current was also observed after inhibition of the phosphodiesterase by IBMX. Drugs which block active transport had no effect on the response to cAMP injection. The inward current depended on extracellular sodium, and was maximal when all other mono- and divalent cations were replaced by Na+. The cAMP-induced current was accompanied by a transient increase in [Na+]i, but there was no change in [Cl-]i. Li+ could largely substitute for Na+; Ca2+ was less effective. Addition of Mg2+ or Ca2+ to solutions containing a high Na+-concentration inhibited the response. Internal acidification with HCl reversibly enhanced the inward current. These data indicate that the depolarizing effect of cAMP can be accounted for by an inward movement of Na-ions, and that the effect is augmented by H+-ions.

Intracellular Na+ and Ca2+ in leech Retzius neurones during inhibition of the Na+-K+ pump

The intracellular Na activity, aNai, and the intracellular Ca activity, aCai, were measured with double-barrelled neutral carrier Na+- and Ca2+-sensitive microelectrodes in Retzius neurones in the central nervous system of the leech Hirudo medicinalis. The aNai was measured to be 8.0 mM (corrected for Ca interference), which corresponds to a cytoplasmic Na+ concentration of 10.7 mM, assuming a Na activity coefficient of 0.75. The calculated Na+ equilibrium potential was 59 mV, giving a total Na+ electrochemical gradient of approximately 102 mV. The aCai was found to range between 1 and 5 X 10(-7) M, from which a Ca2+ equilibrium potential near + 120 mV was estimated. When the Na+-K+ pump was inhibited by lowering the external K+ concentration or by adding the glycoside ouabain (5 X 10(-4) M), the aNai reversibly increased severalfold. When aNai increased to high levels following complete pump inhibition, the aCai increased above 10(-6) M, and the membrane input resistance decreased. After removal of ouabain, aNai, aCai and the membrane resistance recovered within 30 min after a delay of 20-40 min. Our results suggest that a large increase of aNai produces a rise in aCai, possibly by means of a Na+-Ca2+ exchange across the cell membrane. The elevation of the aCai may be responsible for the decrease in membrane resistance, and may also be related to the uncoupling of the paired Retzius neurones observed in the presence of Na+-K+ pump inhibitors.

Dual mechanism of ouabain action on noradrenaline output from guinea-pig vas deferens

Isolated guinea-pig vas deferens was used to test the effects of varying the concentration of extracellular Na+, Ca2+ and Mg2+ and the influence of tetanic transmural stimulation and of tetrodotoxin on the ouabain-induced increase in noradrenaline output. The total amount of noradrenaline released by ouabain increased with increasing concentration of either Na+ (from 35 to 143 mM) or Ca2+ (from 0.3 to 2.5 mM). The rise in the ouabain-induced increase of noradrenaline output was retarded by increasing the concentration of either Ca2+ from 0.3 to 5 mM or Mg2+ from 1.2 to 20 mM. Tetanic transmural stimulation facilitated the occurrence of ouabain-induced noradrenaline output, while tetrodotoxin (5 X 10(-7) g/ml) greatly inhibited it. These results suggest that ouabain causes an increase in noradrenaline output through at least two different mechanisms, a tetrodotoxin-sensitive action potential and Na+-dependent Ca2+ influx resulting from the inhibition of the Na+-K+ pump.

Linear range of Na+ pump in sciatic nerve of frog

The Na+-activated utilization of O2 by frog sciatic nerve is a linear function of the internal concentration of Na+ in preparations deprived of external Ca2+. It is assumed that this component of O2 uptake is a measure of the active extrusion of Na+ by the Na+ pump because it is suppressed by ouabain. However, no tendency toward saturation, expected in an enzymatic process with a high affinity for Na+, was evident. Similar linearity has been reported in other neuronal preparations in experiments measuring 22Na+ efflux directly. The slope of the linear relation between Na+-activated O2 uptake and the concentration of internal Na+ is independent of the external concentration of Na+, but it decreases when the external concentration of K+ is changed from 10 to 4.8 mM.

The effect of cAMP on the cell membrane potential and intracellular ion activities in proximal tubule of Rana esculenta

Experiments were performed in proximal tubule of the isolated perfused frog kidney to evaluate peritubular cell membrane potentials (PDpt), and the intracellular ion activities of sodium (Nai+), chloride (Cli-) and potassium (Ki+) under control conditions and following peritubular application of dibutyryl-cyclic AMP (cAMP, 2 X 10(-4) mol X 1(-1)). Conventional and ion-sensitive microelectrodes were applied to record continuously cAMP-induced changes of these parameters in individual proximal tubule cells. Within a few minutes a significant hyperpolarisation of PDpt (delta = 2.0 +/- 0.2 mV) occurs simultaneously with a decrease of Nai+ (delta = 2.5 +/- 0.5 mmol X 1(-1)). Ki+ increases (delta = 3.6 +/- 0.9 mmol X 1(-1)) and Cli- decreases (0.4 +/- 0.07 mmol X 1(-1)) slightly, but significantly. With both ions the alterations of the chemical gradient is significantly smaller than the potential shift. PDte is not significantly altered by cAMP. The cAMP-induced hyperpolarisation of PDpt can be observed in presence and absence of luminal glucose. However, omission of Na+ from the luminal perfusate abolishes the hyperpolarising effect of cAMP on PDpt. The results suggest that cAMP reduces sodium entry from the lumen into the cell, thus hyperpolarising the cell membrane and decreasing Nai+. Persistence of sensitivity of PDpt to cAMP after omission of glucose indicates that other Na+ coupled transport processes and/or passive Na+ conductance are affected by cAMP. the changes of Ki+ and Cli- are secondary, following the change of PDpt.

Effects of ATP on Na+ transport and membrane potential in inside-out renal basolateral vesicles

We have studied Na+ transport in inside-out basolateral membrane vesicles isolated from rabbit kidney cortex. The addition of ATP in the presence of Mg2+ to the outside of K+-loaded vesicles induced a rapid influx of Na+ against its chemical gradient. Whereas intravesicular K+ was required, extravesicular K+ was inhibitory. ATP-dependent Na+ uptake was inhibited by intravesicular, but not extravesicular ouabain, while extravesicular vanadate was inhibitory. Evaluation of changes in membrane potential using the lipophilic cation triphenylmethylphosphonium (TPMP+) demonstrated hyperpolarization of the membrane voltage after MgATP addition. Changing membrane potential from zero to -40 mV had no effect on ATP-dependent Na+ transport. The potential produced MgATP was inhibited by valinomycin and by protoinophores, but not by vanadate or ouabain. By contrast, the hyperpolarization that occurred in mitochondria after MgATP addition was inhibited by 75% by vanadate. We conclude that the properties of the renal basolateral sodium pump are qualitatively similar to those found in red cell and nerve and that these membranes probably also contain an electrogenic proton pump.

Effect of luminal potassium on cellular sodium activity in the early distal tubule of Amphiuma kidney

From previous studies it is known that a furosemide-sensitive sodium chloride cotransport system is operative in the luminal cell membrane of the early distal amphibian tubule. Since inhibition of sodium chloride cotransport prevents potassium reabsorption in this nephron segment, experiments were carried out to evaluate further the possible relationship between sodium chloride and potassium transport by studying the changes of cellular sodium activity following luminal deletion of potassium ions. Sodium-sensitive liquid ion exchange microelectrodes and conventional microelectrodes were employed to determine the transepithelial potential (PDte), the peritubular cell membrane potential (PDpt) and the intracellular sodium activity (Nai+) in the presence and absence of luminal potassium. The ratio of the luminal cell membrane resistance over the peritubular cell membrane resistance (Rlu/Rpt) was also estimated. When potassium ions are omitted from the luminal perfusate, PDpt hyperpolarizes by some 20 mV, PDte approaches zero and Nai+ decreases by about 40%. Rlu/Rpt is more than doubled in the presence of a potassium-free perfusate. Both potential and resistance changes are fully reversible. Similar results were obtained in experiments in which Barium ions (1 mmol/1 BaCl2) were present during the luminal potassium substitution. Our results indicate that absence of potassium inhibits luminal sodium chloride entry; as a result of continued peritubular sodium extrusion cellular sodium activity falls. The increase of Rlu/Rpt following perfusion with a potassium-free perfusate is interpreted as a decrease of a significant electrodiffusive potassium conductance in the luminal cell membrane.

Effects of maintained illumination upon [K+]0 in the subretinal space of the isolated retina of the toad

Illumination of the vertebrate retina evokes a transient decrease in extracellular potassium concentration, [K+]0, in the subretinal space. During maintained illumination, [K+]0 recovers toward its dark-adapted level. The mechanisms most likely to contribute to this recovery process were examined by using K+-selective microelectrodes to measure [K+]0 in the isolated retina of the toad. Bufo marinus. Although both diffusion of K+ and changes in the rod membrane voltage contribute to the recovery of [K+]0 during maintained illumination, other factors are likely to be involved as well. It is suggested that this recovery process could be due in part to inhibition of the Na+/K+ pump in the rod photo-receptors during maintained illumination.

Post-tetanic depolarization in sympathetic neurones of the guinea-pig

1. Repetitive intracellular stimulation at a frequency of 5-30 Hz for 1-10 s evoked in neurones of the isolated inferior mesenteric and superior cervical ganglia of the guinea-pig three types of post-spike membrane potential changes: (i) hyperpolarization, (ii) hyperpolarization followed by a slow depolarization, and (iii) a second hyperpolarization following the initial two responses.2. The initial post-spike hyperpolarization had a mean duration of 2.0 s and was often associated with a fall in membrane resistance; it could be elicited in every sympathetic neurone studied. This response was termed the post-tetanic hyperpolarization (PTH).3. The slow depolarization which could be induced only in a portion of neurones had a mean amplitude and duration of 2.2 mV and 27.5 s, respectively; it was termed the post-tetanic depolarization (PTD).4. PTD was associated with a fall in membrane resistance, augmented by membrane hyperpolarization, and reduced by depolarization; its mean extrapolated equilibrium potential was -38 mV.5. PTD was not blocked by nicotinic and muscarinic antagonists, or alpha-and beta-adrenergic receptor antagonists, whereas it was suppressed by adrenaline, noradrenaline, Co(2+) and a low Ca(2+) solution.6. The amplitude of the single spike after-hyperpolarization in normal Krebs solution as well as in high K(+) solution was increased during PTD; furthermore, conditioning hyperpolarization to the level of E(K) increased the amplitude of PTD in normal Krebs as well as in high K(+) solution.7. PTD with similar amplitude, time course and membrane characteristics could be evoked in a portion of neurones of the rabbit superior cervical ganglia; however, PTD was not detected in neurones of the rat superior cervical ganglia.8. Decentralization of the guinea-pig and rabbit superior cervical ganglia for 14 d did not alter the number of neurones in which PTD could be elicited, its amplitude, or its time course.9. Our results suggest that a chemical substance(s) is responsible for the generation of PTD; it may be released from the soma and/or dendrites and acts in an auto-receptive manner on the cells in question. The nature and origin of the second hyperpolarization remain to be clarified.

Block of inward rectification by intracellular H+ in immature oocytes of the starfish Mediaster aequalis

Intracellular pH was recorded in immature starfish oocytes using pH-sensitive microelectrodes, and inwardly rectifying potassium currents were measured under voltage clamp. When the intracellular pH was lowered using acetate-buffered artificial sea water from the normal value of 7.09 to 5.9, inward rectification was completely blocked. The relationship between inward rectification and internal pH between 7.09 and 5.9 could be fit by a titration curve for the binding of three H ions to a site with a pK of 6.26 to block the channel. The H+ block showed no voltage dependence, and the activation kinetics of the inwardly rectifying currents were not affected by the changes in internal pH.

The effects of rubidium ions and membrane potentials on the intracellular sodium activity of sheep Purkinje fibres

1. Intracellular Na activity, aiNa, was measured in voltage-clamped sheep cardiac Purkinke fibres. 2. Increasing [Rb]0 from 0 to 4 mM in K-free solutions (at a fixed membrane potential) decreased aiNa. Further increases of [Rb]0 (up to 20 mM) had little or no effect. 3. Following exposure to Rb-free, K-free solution, the addition of a test concentration of Rb produced an exponential decrease of aiNa. The rate constant of decay of aiNa increased with increasing [Rb]0 over the measured range (0-20 mM). 4. The accompanying electrogenic Na pump current transient decayed with the same rate constant as aiNa over the range of [Rb]0 examined. During this decay the electrogenic Na pump current was a linear function of aiNa. Increasing [Rb]0 increased the steepness of the dependence of the electrogenic current on aiNa. 5. A constant fraction of the net Na efflux was electrogenic. This fraction was not affected by varying [Rb]0 over the range 0-20 mM. 6. Using a simple model, it is shown that the dependence of steady-state aiNa on [Rb]0 is half-saturated by less than 1 mM-[Rb]0. The rate constant of decay of aiNa and the slope of the relationship between electrogenic Na pump current and aiNa are, however, better fitted with a lower affinity for Rb (K0.5 = 4 mM-[Rb]0). 7. Depolarizing the membrane potential with the voltage clamp decreased aiNa; hyperpolarization increased it. These effects persisted in the presence of 10(-5) M-strophanthidin. An effect of membrane potential on the net passive Na influx can account for the observations. 8. The effects of membrane potential on the net passive Na influx were examined by measuring the maximum rate of rise of aiNa at different holding potentials after inhibiting the Na-K pump in a K-free, Rb-free solution. Depolarization decreased the Na influx. 9. Using the constant field equation, the net passive Na influx was used to estimate the apparent Na permeability coefficient, PNa. This was between 0.8 x 10(-8) and 1.5 x 10(-8) cm sec-1.

The ionic mechanism of intracellular pH regulation in crayfish neurones

1. Intracellular pH (pHi) regulation in crayfish neurones was studied using pH-, Na+-, and Cl- sensitive micro-electrodes. Neuronal pH regulation has previously been studied only in molluscs. 2. The average resting pHi of crayfish neurones was 7.12 +/- 0.09, which is 1 pH unit more alkaline than that predicted were H+ ions distributed in equilibrium with the membrane potential. 3. When the cytoplasm was acidified (by NH4Cl loading, CO2 application, or HCl injection), pHi recovered towards its resting value. 4. Removal of Na+ from the external solution inhibited pHi recovery from an acid load by more than 90%. pHi recovery resumed immediately when external Na+ was reintroduced. 5. The resting intracellular Na+ concentration ([Na+]i) of crayfish neurones was 15-25 mM. During pHi recovery from an acid load, [Na+]i increased by 10-50 mM. 6. Reducing the external HCO3(-) concentration from 5 mM to 0 mM slowed pHi recovery by an average of about 45%. This slowing was appreciable even in cells in which Na+ removal almost totally blocked pHi recovery. 7. The resting intracellular Cl- concentration ([Cl-]i) was 30-40 mM, indicating that these cells actively accumulate Cl-. During pHi recovery from an acid load, [Cl-]i decreased by 3-5 mM. 8. In the presence of the anion exchange inhibitor SITS (4-acetamide-4'-isothiocyanostilbene-2,2'-disulphonic acid), pHi recovery was slowed to the rate which was normally seen in HCO3(-)-free Ringer solution. SITS abolished the dependence of pHi recovery on the external HCO3(-) concentration. 9. It is concluded that pHi regulation in crayfish neurones involves two separate mechanisms: a Na+-dependent, HCO3(-)-independent acid extrusion process, and a Cl---HCO3(-) exchange which is probably also Na+-dependent.

An analysis of histamine-induced inhibitory response in molluscan neurons

Mechanisms of the histamine-induced inhibitory response (the H2-response) in neurons of the marine mollusc Onchidium, were further investigated following the preceding paper. The H2-response in normal saline was blocked by ouabain, but the response recovered after a short exposure to Na-free solution containing ouabain. The recovery was only transient in the continuous presence of ouabain. When external Na was reduced to about 1/8 normal concentration (60 mM), the H2-response became sensitive to removal of external Ca, but insensitive to ouabain. The suppressing effect of Ca removal and the recovery by Ca readmission appeared very slowly. However, in about 1/3 normal Na concentration (150 mM) the H2-response was suppressed by removal of the Ca, only in the presence of ouabain. The Na-gradient may be regulated by the ouabain-insensitive transportk, such as a Na-Ca exchange in addition to the ouabain-sensitive Na-pump. The Na-Ca exchange probably dominates over the ouabain-sensitive Na-pump only when passive Na-influx is reduced in a low external Na concentration. The H2-response was markedly inhibited by DNP (5 X 10(-4)M) and cyanide (2 X 10(-3)M), while the hyperpolarization produced by glutamate, which was accompanied by a large reduction of membrane resistance, was not affected by these metabolic inhibitors. Over a wide range of external Na concentrations, the membrane potential was lower in presence than in the absence of external Ca. This may be explained by the hypothesis that there is an electrogenic Na-Ca exchange in which Ca-influx is coupled with Na-efflux. According to a similar hypothesis, the H2-response is produced by the transport system in which Ca-efflux is coupled with Na-influx and the system is controlled by the transmembrane Na gradient.

Interactions of cell volume, membrane potential, and membrane transport parameters

Equations have been written and solved that describe for animal cells the relationships among membrane transport, cell volume, membrane potential, and distribution of permeant solute. The essential system consists of n + 2 equations, where n is the number of permeant solute species. The n of the equations are the n transport equations for the permeant species, one for each species. The other two equations are statements of 1) the condition for bulk electroneutrality inside the cell and 2) the condition for isotonicity between the interior and exterior of the cell. Numerical solutions have been obtained in both the steady-state and time-varying cases for transport equations that are physically and phenomenologically reasonable. In addition to numerical solutions analytic expressions are presented that show the ranges of membrane parameters essential for volume regulation; for values of membrane parameters beyond explicitly defined bounds, the equations do not have real, positive solutions for cell volume.

Appearance of calcium action potentials in crayfish slow muscle fibres under conditions of low intracellular pH

1. The intracellular pH (pHi) of crayfish slow flexor muscle fibres was measured using recessed-tip pH micro-electrodes. To study the electrophysiological effects of intracellular acidification, pHi was lowered to values between the normal 7 . 2 and 6 . 3 by removal of external NH4Cl after a 20--30 min exposure. 2. During intracellular acidification, the fibres became capable of generating all-or-none Ca action potentials, rather than the normal small graded responses; no change in resting potential or input resistance accompanied this change in excitability. 3. All-or-none spikes appeared at pHi = 6 . 4--6 . 5. The spikes disappeared when pHi was increased again following the addition of 10 mM-bicarbonate to the external solution. CO2-saturated saline, which decreased pHi to 6 . 4, also caused the appearance of all-or-none action potentials. 4. The appearance of action potentials was correlated with a decrease in delayed rectification as pHi fell, as indicated by the response to depolarizing current pulses and by constant-current I--V plots in solutions in which all Ca ions had been replaced by Co. 5. External tetraethylammonium (TEA), at concentrations which reproduced the pHi = 6 . 4 effects on the I--V relation, also caused the appearance of all-or-none action potentials. 6. It is concluded that low pHi in these fibres partially blocks (or causes a depolarizing shift in the voltage dependence of) the voltage-sensitive outward K current which normally shunts the inward Ca current and prevents the generation of action potentials.

Correlation between changes in membrane potential and intracellular sodium activity during K activated response in sheep Purkinje fibres

Following superfusion with a K free medium sheep Purkinje fibres show a strong correlation between changes in membrane potential and the intracellular Na activity in K containing solution. This correlation persists after changes in the internal Na or extracellular K activity and following substitution of Rb for external K.

Electrophysiological and pharmacological properties of glial cells associated with the medial giant axon of the crayfish with implications four neuron-glial cell interactions

Schwann-like glial cells surrounding the medial giant axon of the crayfish (Procambarus clarkii) were impaled with glass microelectrodes to study their responses to cholinomimetics, cholinergic receptor blockers and ouabain. Axon electrical properties were simultaneously monitored. Glial cells have a low membrane potential compared to the axon; -42 mV and -85 mV, respectively. Acetylcholine, carbachol and nicotine hyperpolarized the glial cells but did not affect the axon steady-state or active membrane potentials. The action of the cholinergics was completely blocked by d-tubocurarine and alpha-bungarotoxin. Ouabain hyperpolarized the glial cell but depolarized the axon. Tubocurarine blocked the ouabain hyperpolarization but not the delayed depolarization of the glia cell or the axon. It is concluded that ouabain causes the release of acetylcholine from the glial cell-axon preparation, inducing the glial hyperpolarization. Studies of the axon-glial cell interaction suggest that a function of the glial cell is to actively modulate the periaxonal potassium concentration on a signal from the axon. Periaxonal potassium can strongly affect axon membrane potential through electrogenic Na transport, modifying axon signalling properties.

Sodium influx rate and ouabain-sensitive rubidium uptake in isolated guinea pig atria

1. Ouabain-sensitive 86Rb+ uptake by tissue preparations has been used as an estimate of Na+ pump activity. This uptake, however, may be a measure of the Na+ influx rate, rather than capacity of the Na+ pump, since intracellular Na+ concentration is a determinant of the active Na+/Rb+ exchange reaction under certain conditions. This aspect was examined by studying the effect of altered Na+ influx rate on ouabain-sensitive 86Rb+ uptake in atrial preparations of guinea pig hearts. 2. Electrical stimulation markedly enhanced ouabain-sensitive 86Rb+ uptake without affecting nonspecific, ouabain-insensitive uptake. Paired-pulse stimulation studies indicate that the stimulation-induced enhancement of 86Rb+ uptake is due to membrane depolarizations, and hence related to the rate of Na+ influx. 3. Alterations in the extracellular Ca2+ concentration failed to affect the 86Rb+ uptake indicating that the force of contraction does not influence 86Rb+ uptake. 4. Reduced Na+ influx by low extracellular Na+ concentration decreased 86Rb+ uptake, and an increased Na+ influx by a Na+-specific ionophore, monensin, enhanced 86Rb+ uptake in quiescent atria. 5. Grayanotoxins, agents that increase transmembrane Na+ influx, and high concentrations of monensin appear to have inhibitory effects on ouabain-sensitive 86Rb+ uptake in electrically stimulated and in quiescent atria. 6. Electrical stimulation or monensin enhanced ouabain binding to (Na+ + K+)-ATPase and also increased the potency of ouabain to inhibit 86Rb+ uptake indicating that the intracellular Na+ available to the Na+ pump is increased under these conditions. 7. The ouabain-sensitive 86Rb+ uptake in electrically stimulated atria was less sensitive to alterations in the extracellular Na+ concentration, temperature and monensin than that in quiescent atria. 8. These results indicate that the rate of Na+ influx is the primary determinant of ouabain-sensitive 86Rb+ uptake in isolated atria. Electrical stimulation most effectively increases the Na+ available to the Na+ pump system. The ouabain-sensitive 86Rb+ uptake by atrial preparations under electrical stimulation at a relatively high frequency seems to represent the maximal capacity of the Na+ pump in this tissue.

Mechanism of monensin-induced hyperpolarization of neuroblastoma-glioma hybrid NG108-15

Addition of the ionophore monensin to mouse neuroblastoma-rat glioma hybrid NG108-15 cells leads to a 20 to 30-mV increase in the electrical potential across the plasma membrane as shown by direct intracellular recording techniques and by distribution studies with the lipophilic cation [3H]-tetraphenylphosphonium+ (TPP+) [Lichtshtein, D., Kaback, H.R. & Blume, A.J. (1979) Proc. Natl. Acad. Sci. USA 76, 650-654]. The effect is not observed with cells suspended in high K+ medium, is dependent upon the presence of Na+ externally, and the concentration of monensin that induces half-maximal stimulation of TPP+ accumulation is approximately 1 microM. The ionophore also causes rapid influx of Na+, a transient increase in intracellular pH, and a decrease in extracellular pH, all of which are consistent with the known ability of monensin to catalyze the transmembrane exchange of H+ for Na+. Although ouabain has no immediate effect on the membrane potential, the cardiac glycoside completely blocks the increase in TPP+ accumulation observed in the presence of monensin. Thus, the hyperpolarizing effect of monensin is mediated apparently by an increase in intracellular Na+ that acts to stimulate the electrogenic activity of the Na+,K+-ATPase. Because monensin stimulates TPP+ accumulation in a number of other cultured cell lines in addition to NG108-15, the techniques described may be of general use for studying the Na+,K+ pump and its regulation in situ.

Electrogenic sodium extrusion in cardiac Purkinje fibers

Thin canine cardiac Purkinje fibers in a fast flow chamber were exposed to K-free fluid for 15 s to 6 min to initiate "sodium loading," then returned to K-containing fluid to stimulate the sodium pump. The electrophysiological effects of enhanced pump activity may result from extracellular K depletion caused by enhanced cellular uptake of K or from an increase in the current generated as a result of unequal pumped movements of Na and K, or from both. The effects of pump stimulation were therefore studied under three conditions in which lowering the external K concentration ([K]0) causes changes opposite to those expected from an increase in pump current. First, the resting potential of Purkinje fibers may have either a "high" value of a "low" (less negative) value: at the low level of potential, experimental reduction of [K]0 causes depolarization, whereas an increase in pump current should cause hyperpolarization. Second, in regularly stimulated Purkinje fibers, lowering [K]0 prolongs the action potential, whereas an increase in outward pump current should shorten it. Finally, lowering [K]0 enhances spontaneous "pacemaker" activity in Purkinje fibers, whereas an increase in outward pump current should reduce or abolish spontaneous activity. Under all three conditions, we find that the effects of temporary stimulation of the sodium pump are those expected from a transient increase in outward pump current, not those expected from K depletion.

Use of a lipophilic cation for determination of membrane potential in neuroblastoma-glioma hybrid cell suspensions

Neuroblastoma-glioma hybrid cells (NG108-15) in suspension accumulate the permeant lipophilic cation [(3)H]tetraphenylphosphonium (TPP(+)) against a concentration gradient. The steady-state level of TPP(+) accumulation is about twice as great in physiological media of low K(+) concentration (i.e., 5 mM K(+)/135 mM Na(+)) than in a medium of high K(+) concentration (i.e., 121 mM K(+)/13.5 mM Na(+)). The latter manipulation depolarizes the NG108-15 plasma membrane and indicates that the resting membrane potential (DeltaPsi) is due primarily to a K(+) diffusion gradient (K(in) (+) --> K(out) (+)). TPP(+) accumulation is time and temperature dependent, achieving a steady state in 15-20 min at 37 degrees C, and is a linear function of cell number and TPP(+) concentration (i.e., the concentration gradient is constant). The difference in TPP(+) accumulation in low and high K(+) media under various conditions has been used to calculate mean (+/-SD) DeltaPsi values of -56 +/- 3, -63 +/- 4, and -66 +/- 5 mV at 26, 33, and 37 degrees C, respectively. Importantly, these values are virtually identical to those obtained by direct electrophysiological measurements made under the same conditions. TPP(+) accumulation is abolished by the protonophore carbonylcyanide-m-chlorophenylhydrazone, whereas the neurotoxic alkaloid veratridine diminishes uptake to the same level as that observed in high K(+) media. In addition, the effect of veratridine is dependent upon the presence of external Na(+) and is blocked by tetrodotoxin. The steady-state level of TPP(+) accumulation is enhanced by monensin, indicating that this ionophore induces hyperpolarization under appropriate conditions. Finally, ouabain has essentially no effect on the steady-state level of TPP(+) accumulation in short-term experiments, suggesting that Na(+),K(+)-ATPase activity makes little contribution to the resting potential in these cells. Because many of these observations are corroborated by intracellular recording techniques, it is concluded that TPP(+) distribution measurements can provide a biochemical method for determining membrane potentials in populations of cultured neuronal cells.

The measurement of intracellular sodium activities in the bullfrog by means of double-barreled sodium liquid ion-exchanger microelectrodes

A double-barreled Na+-selective microelectrode was constructed with monensin as a liquid ion exchanger. The HCl-treated monensin was dissolved in a solvent (Corning 477317) at 10% (weight/weight). Internal reference solution of its ionic barrel was mixture of 0.49 M NaCl and 0.01 M KCl, the pH being adjusted to 3 with 0.1 M citrate-HCl buffer, whereas that of the PD barrel was 0.5 M KCl. Average slope and selectivity ratio (Na+/K+) tested on 10 different microelectrodes were -57.5 +/- 1.87 mV/P(Na) (SEM) and 6.7 +/- 0.44, respectively. The electrical resistance was an order of 10(10) ohm and the response time was less than 10 sec. Using this microelectrode, a free flow micropuncture experiment was carried out in the bullfrog kidney and the intracellular Na+ activity as well as the membrane PD was determined on the proximal tubular cell. Average value (+/- SEM, n = 15) for the intracellular Na+ and K+ was 20.7 +/- 1.56 mEq/L and 61.2 +/- 1.16 mEq/L, respectively, and -68.7 +/- 0.88 mV for the peritubular membrane PD. There was a significant negative correlation between Na+ and K+ activities within the cell, i.e., the lower the ionic activity of cellular Na+ was, the higher the cellular K+, and vice versa, the sum of these two being kept nearly constant. The above finding may be somehow related to the isosmosis in the reabsorptive process across the proximal tubular epithelium.

The intracellular sodium activity of cardiac Purkinje fibres during inhibition and re-activation of the Na-K pump

1. The intracellular Na activity, aiNa, of sheep heart Purkinje fibres was continuously monitored using Na+-sensitive glass micro-electrodes. The effects of removal and restoration of external K, and of application and removal of various cardioactive steroids, were investigated. 2. The aiNa increased in K-free solutions and rapidly recovered on addition of external K. The rate of this recovery depended on both the external K concentration, [K]o, and the aiNa. The rate of aiNa recovery was found to be half maximally activated at a [K]o of about 10 mM. If corrections are applied to allow for changes in the net passive Na influx at various [K]o, then this value is increased to approximately 12.5 mM. 3. At a given [K]o, there appeared to be a linear relationship between the rate of aiNa recovery and the level to which aiNa had increased in K-free solution (over the range of aiNa from 7.5 to 31 mM). 4. Addition of the cardioactive steroids strophanthidin, acetylstrophanthidin, actodigin (AY 22,241) or dihydro-ouabain produced rapid changes of aiNa. At low concentrations, these compounds sometimes produced a small decrease in aiNa, while at concentrations above 10(-7) M they produced a dose-dependent increase. 5. The effects on aiNa of both low and high concentrations of all these cardioactive steroids were readily reversible within 120 min. The time course of the aiNa recovery mainly depended on the concentration of the cardioactive steroid applied, and on the level to which aiNa had increased. 6. Upon addition of a cardioactive steroid (above 10(-7) M, aiNa at first increased almost linearly with time. The rates of such an increase were measured during this period at various cardioactive steroid concentrations and used to produce dose-response curves. The concentrations that produced a half-maximum rate of aiNa increase were near to 10(-6) M for strophanthidin and acetylstrophanthidin, but near to 10(-5) M for actodigin and dihydro-ouabain. 7. The mean maximum rate of aiNa increase produced by the addition of a high cardioactive steroid concentration was 0.49 +/- 0.17 mM/min (+/-S.D., n = 21). This would indicate a net passive Na influx into the cells of approximately 2.8 p-mole/cm2sec. 8. This maximum rate of aiNa increase could be achieved by the addition of 10(-5) M-strophanthidin or acetylstrophanthidin, but 10(-4) to 10(-3) M-actodigin or dihydro-ouabain was required to produce a similar rate of increase. 9. The addition of these high cardioactive steroid concentrations produced an initially rapid increase of aiNa. After 15-30 min this aiNa increase slowed considerably. The aiNa appeared to reach a 'plateau' within 2-4 hr at levels much below those predicted for a Na electrochemical equilibrium across the cell membrane.

Physiological and morphological evidence for coupling in mouse salivary gland acinar cells

Three experimental techniques were employed to examine coupling between acinar cells of the mouse salivary gland. Passage of DC current pulses via intracellular microelectrodes between neighboring cells showed that small ions could be directly passed from one cell to another. Intracellular iontophoresis of the dye Lucifer Yellow CH into a single cell indicated that small molecules could spread by means of intercellular cytoplasmic bridges througout an acinus and, occasionally, into cells of adjacent acini. Freeze-fracture replicas of acinar cell membranes indicated the presence of gap junctions which were correlated with both electrical and dye coupling experiments. Suggestions are made for the function of direct intercellular exchange in salivary secretory cells. The role of electrical coupling in coordination of the activity of different secretory cell types is discussed as one possible function.

Blockage of depolarization-induced mitogenesis in CNS neurons by 5-fluoro-2'-deoxyuridine

Experiments designed to provide further evidence, at the basic metabolic level, that true mitogenesis and mitotic activity are being induced in CNS neurons in response to sustained ionic depolarization were conducted. The ability of 5-fluoro-2'-deoxyuridine (FUdR), a well-studied inhibitor of normal mitogenesis in naturally proliferating cells, to block induction of DNA synthesis (and subsequent nuclear division) in culture-matured neurons depolarized with ouabain was ascertained, as well as the ability of exogenously supplied thymidine to permit effective bypass of such blockage. Observations of the sequence of intracellular morphological changes induced by ouabain were also made, along with a determination of the alterations in this sequence introduced by FUdR. The results indicate that ouabain mediated depolarization rapidly induces and/or activates the key mitogenic enzyme thymidylate synthetase in the mitotically quiescent neurons, along with all other mitogenesis-specific enzymes required for DNA synthesis and nuclear division. A probable mechanism by which such mitogenic induction may proceed is elaborated. The early morphological changes observed correlate well with the early time-sequence of mitogenic metabolic events, while development of the later changes appears to be dependent upon the progress of mitogenesis activity. The results support the possibility that CNS neurons of adult origin may also be induced to initiate normal mitogenesis by appropriately imposed depolarization treatments.

Effects of pH, Ca, ADH, and theophylline on kinetics of Na entry in frog skin

The short circuit current as a function of Na concentration in both solutions was found to obey Michaelis-Menten kinetics under a variety of experimental conditions. Values of maximal transport rate (Im) and half-maximal Na concentrations (Kt) were determined from these experiments. Three type of results were obtained: 1) Im and Kt both decreased by approximately the same fraction when the pH of both solutions was reduced by increasing PCO2, 2) Im decreased and Kt increased when the external pH was decreased, and 3) Im increased with ADH and theophylline, decreased with external Ca, and Kt remained unchanged. Various criteria were utilized to determine that these were properties of the entry barrier for Na into the "transport pool." The results are explained in terms of a model that separates three different types of actions on the entry barrier: 1) competition of Na with other ions in the external solution for entry, 2) modulation of the number of sites available for Na translocation by changing the cytoplasmic pH, and 3) alterations in the rate of Na translocation caused by changes in the Na permeability or the electrochemical gradient across the entry barrier.

Comparison of the mechanisms controlling intracellular pH and sodium in snail neurones

Ion-sensitive microelectrodes were used to record intracellular pH, Na+ and Cl- in snail neurones. NaCl or HCl was injected iontophoretically to compare the Na pump with the pHi regulating system. The Na pump was inhibited by ouabain, carbonyl cyanide m-chlorophenyl hydrazone and increasing the membrane potential, whereas the pHi regulating system was relatively unaffected. Activation of the Na pump had no effect on pHi whereas activation of the pHi recovery process increased internal Na+. Activation of the pHi recovery process by CO2 application increased internal Na+ and also decreased internal Cl-. The results show that there is no direct connexion between the Na pump and the pHi recovery process, and that the pHi recovery process is electroneutral, and appears not to require metabolic energy. The results also confirm that the pHi recovery process involves the influx of Na+ ions and the efflux of Cl- ions.

The effects of external cations and ouabain on the intracellular sodium activity of sheep heart Purkinje fibres

1. The intracellular Na activity of sheep heart Purkinje fibres has been measured using recessed-tip Na(+)-sensitive glass micro-electrodes.2. The internal Na activity was 7.2 +/- 2.0 mM (mean +/- S.D., n = 32) at the normal external Na concentration, [Na](o), in these experiments of 140 mM (equivalent to an external Na activity of 105 mM). The equilibrium potential for Na across the fibre membrane was therefore approximately + 70 mV.3. When the [K](o) was altered the internal Na activity changed, reaching a new level within about 20 min. Increasing the [K](o) from 4 to 25 mM decreased the internal Na by approximately 30%, while decreasing the [K](o) from 4 to 1 mM increased internal Na by 20%.4. The removal of external K produced an easily reversible increase in the internal Na with an initial rate equivalent to a concentration change of 0.24 +/- 0.07 m-mole/min (mean +/- S.D., n = 8).5. Ouabain produced increases in the internal Na activity that were only very slowly reversible. The threshold concentration for producing an increase was approximately 10(-7)M.6. When [Na](o) was reduced the internal Na activity fell rapidly with a single exponential time course (time constant 3.3 +/- 0.8 min, mean +/- S.D., n = 16) to a new, relatively stable level. The recovery of internal Na on return to the normal [Na](o) did not have a simple time course. It was normally complete within 10-30 min.7. The relationship of the stabilized level of the internal Na activity to the [Na](o) was approximately linear over the range 140-14 mM-[Na](o). When [Na](o) was reduced from 140 to 14 mM the internal Na activity fell by 72 +/- 5% (mean +/- S.D., n = 21).8. When the [Na](o) was reduced, the decrease in the internal Na activity was partially inhibited by Mn or by removal external Ca.9. When the [Ca](o) was altered over the range 0.2-16 mM the internal Na activity was reduced by approximately 50% for a tenfold increase in the [Ca](o).10. The relationship between internal Na and contractility is discussed.

Rate-dependent changes in extracellular potassium in the rabbit atrium

We measured levels of potassium ion in the extracellular space of isolated superfused rabbit atria continuously with double-barreled microelectrodes of which on barrel was a K+ liquid ion-exchanger microelectrode and the other a potential-sensing micropipette. Increases in heart rate resulted in transient increases in extracellular potassium ([K+]0). When the quiescent atrium was stimulated the maximal increase was 0.4 mM at rates of 60/min, 0.7 mM at 90/min, 0.9 mM at 120/min, 1.3 mM at 200/min, and 1.8 mM at 300/min. The increase was not sustained during continued stimulation but declined toward prestimulation levels. When the stimulus was terminated the extracellular potassium activity decreased below bathing solution values by 0.2 mM after 60/min, 0.5 mM after 90/min, 0.7 mM ater 120/min, 0.9 mM after 200/min, and 1.0 mM after 300/min and subsequently returned to a value equal to that of the bathing solution. The magnitude of the decline in extracellular potassium activity during prolonged stimulation was markedly decreased when the bathing solution contained either zero potassium, ouabain, LiCl, or a decreased Po2 such that an elevation in [K+]0 persisted during stimulation. Moreover, the reduction in [K+]0 that followed the cessation of stimulation also was inhibited. These results support a role of the Na-K pump in maintaining extracellular potassium activity during changes in cardiac rate.

The effect of calcium injection on the intracellular sodium and pH of snail neurones

1. Ion-sensitive glass micro-electrodes were used to measure the intracellular pH (pHi) and the intracellular sodium ion concentration, [Na+]i, in identified Helix aspersa neurones. 2. The injection of small volumes of 0-1 McaCl2, which increased the membrane potential by 10-15 mV for 1-2 min, had little or no effect on [Na+]i. Increases of up to 1 mM in [Na+]i could be reversibly induced by larger injections. 3. Calcium injection caused an immediate decrease in pHi, which appeared to be directly proportional to the amount of calcium injected. Injections causing hyperpolarizations of 10-20 mV which recovered in 2-5 min caused pHi decreases of 0-04-0-15 units. After each of these injections both pHi and the membrane potential recovered exponentially but with different time constants. 4. The injection of calcium at a low rate could decrease pHi without affecting the membrane potential. 5. Neither membrane potential nor pHi were affected by the injection of small volumes of 0-1 M-MgCl2, Injection of CoCl2 produced a large transient decrease in pHi but no significant change in membrane potential. 6. Exposure of the cell to saline equilibrated with 2-5% CO2 greatly reduced the pHi decrease caused by calcium injection but had only small effects on the membrane potential response. 7. It is concluded that most of the injected calcium is exchanged for protons inside the cell.

The effect of lowering external sodium on the intracellular sodium activity of crab muscle fibres

1. Intracellular Na activity, aiNa, was continuously measured in crab (Carcinus maenas) muscle fibres using a recessed-tip Na+ -sensitive glass micro-electrode. Experiments could last up to several hours. AiNa remained stable during prolonged experiments. The mean resting aiNa was 8-4 +/- 0-02 mM (S.E. of mean for eighty-nine fibres) and the mean resting membrane potential was 65-3 mV +/- 0-3 (S.E. of mean for eighty-nine fibres). 2. Reducing [Na]o to 1/10 normal (maintaining ionic strength with equivalent amounts of either Li or Tris) caused a large and rapid fall of aiNa. There appeared to be two components of the effect, a fast and slow. The initial fast rate of decrease was about 3-5 m-mole/min decreasing to half this value in about 1 min. The rate of decrease of aiNa was not linearly related to aiNa. The size of the fast change of aiNa was related to the magnitude of the Na gradient across the membrane. 3. High concentrations (2 x 10-4m) of ouabain caused a very slow rise of aiNa by 1 or 2 mn/hr. This was equivalent to a net Na influx of between 1 and 10 p-mole/cmi. sec, depending on whether or not a correction was applied to account for the increased surface area of the fibre caused by the invaginating cleft system. 4. The response to low Nso was virtually insensitive to the removal of Ko or to prolonged reatment with high concentrations of ouabain (2 x 10-4 m; 100 min) and so could not readily be attributed to active Na/K pumping. 5. The response of aiNa to low Nao was reversibly inhibited by high concencentrations of Mn (50 mm) and by low concentrations of La (3-1 mm). La itself stimulated a rapid fall of aiNa in normal Nao.