Sodium fluxes in internally dialyzed squid axons

In the squid axon Na+/Ca2+ exchanger the state of the Ca i-regulatory site influences the affinities of the intra- and extracellular transport sites for Na+ and Ca2+

In squid axons, intracellular Mg2+ reduces the activity of the Na+/Ca2+ exchanger by competing with Ca2+ i for its regulatory site. The state of the Ca i-regulatory site (active-inactive) also alters the apparent affinity of intra- and extracellular transport sites. Conditions that hinder the binding of Ca2+ i (low pH i, low [Ca2+]i, high [Mg2+]i) diminish the apparent affinity of intracellular transport sites, in particular for Na i due to its synergism with H+ inhibition, but less noticeably for Ca2+ i because of its antagonism towards (Ha i + Na+ i) and Mg2+ i inhibitions. These are kinetic effects unrelated to the true affinity of the sites. With the Ca i-regulatory site saturated, the intracellular transporting sites are insensitive to [H+]i and to ATP. Likewise, the state of the Ca i-regulatory site (activated or inactivated) influences the affinity of the extracellular Ca o and Na o-transport sites (trans effects). In this case, the effects are opposite to those predicted by any of the transport schemes proposed for the Na+/Ca2+exchanger; i.e. its mechanism remains unexplained. In addition to their intrinsic importance for a full understanding of the properties of the Na+/Ca2+ exchanger, these findings show a new way by which the state of the Ca i-regulatory site may determine net movements of Ca2+ through this system.

Sodium/calcium exchanger: influence of metabolic regulation on ion carrier interactions

The Na(+)/Ca(2+) exchanger's family of membrane transporters is widely distributed in cells and tissues of the animal kingdom and constitutes one of the most important mechanisms for extruding Ca(2+) from the cell. Two basic properties characterize them. 1) Their activity is not predicted by thermodynamic parameters of classical electrogenic countertransporters (dependence on ionic gradients and membrane potential), but is markedly regulated by transported (Na(+) and Ca(2+)) and nontransported ionic species (protons and other monovalent cations). These modulations take place at specific sites in the exchanger protein located at extra-, intra-, and transmembrane protein domains. 2) Exchange activity is also regulated by the metabolic state of the cell. The mammalian and invertebrate preparations share MgATP in that role; the squid has an additional compound, phosphoarginine. This review emphasizes the interrelationships between ionic and metabolic modulations of Na(+)/Ca(2+) exchange, focusing mainly in two preparations where most of the studies have been carried out: the mammalian heart and the squid giant axon. A surprising fact that emerges when comparing the MgATP-related pathways in these two systems is that although they are different (phosphatidylinositol bisphosphate in the cardiac and a soluble cytosolic regulatory protein in the squid), their final target effects are essentially similar: Na(+)-Ca(2+)-H(+) interactions with the exchanger. A model integrating both ionic and metabolic interactions in the regulation of the exchanger is discussed in detail as well as its relevance in cellular Ca(i)(2+) homeostasis.

Effects of intracellular signals on Na+/K(+)-ATPase pump activity in the frog skin epithelium

The effects of intracellular signals (pHi, Na+i, Ca2+i, and the electrical membrane potential), on Na+ transport mediated by the Na+/K+ pump were investigated in the isolated Rana esculenta frog skin. In particular we focussed on pHi sensitivity since protons act as an intrinsic regulator of transepithelial Na+ transport (JNa) by a simultaneous control of the apical membrane Na+ conductance (gNa) and the basolateral membrane K+ conductance (gK). pHi changes which modify JNa, gNa and gK, do not affect the Na+ transport mediated by the pump as shown by kinetic and electrophysiological studies. In addition, no changes were observed in the number of 3H-ouabain binding sites in acid-loaded epithelia. Our attempts to modify cellular Ca2+ (by using Ca(2+)-free/EGTA Ringer solution or A23187 addition) also failed to produce any significant effects in the Na+ pump turnover rate or the number of 3H-ouabain binding sites. The Na+ pump current was found to be sensitive to the basolateral membrane potential, saturating for very positive (cell) potentials and a reversal potential of -160 mV was calculated from I-V relationships of the pump. Changes in Na+i considerably affected the Na+ pump rate. A saturating relationship was found between pump rate and Nai+ with maximal activation at Nai+ greater than 40 mmol/l; a high dependence of the pump rate and of the number of 3H-ouabain binding sites was observed in the physiological range of Nai+. We conclude that protons (in the physiological pH range) which act directly and simultaneously on the passive transport pathways (gNa and gK), have no direct effect on the Na+/K+ pump rate. After an acid load, the inhibition of JNa is primarily due to the reduction of gNa. This results in a reduction of Nai and the pump turnover rate then becomes dependent on other pathways of Na+ entry such as the basolateral membrane Na+/H+ exchanger.

Metabolic signaling between photoreceptors and glial cells in the retina of the drone (Apis mellifera)

Experimental evidence showing metabolic interaction and signaling between photoreceptors-neurons and glial cells of the honeybee drone retina is presented. In this tissue [3H]2-deoxyglucose ([3H]2DG) in the dark and during repetitive light stimulation is phosphorylated to [3H]2-deoxyglucose-6P ([3H]2DG-6P) almost exclusively in the glial cells. Hence, stimulus-induced changes in the rate of formation of [3H]2DG-6P occurs predominantly in the glial cells. Repetitive stimulation of the photoreceptors with light flashes induced about a 47% rise in the rate of formation of [3H]2DG-6P in the glial cells and this effect is probably due to the activation of hexokinase. The potent inhibitor of glycolysis iodoacetic acid (IAA), inhibited this phosphorylation by about 75%. Probably this was largely due to an about 70% decrease of adenosine triphosphate (ATP). Exposure of the retina to IAA suppressed the transient rise in oxygen consumption (delta QO2) in the photoreceptors and subsequently the light-induced receptor potential. This indicates that the supply of a glycolytic substrate by glial cells to the photoreceptors is greatly reduced by IAA. Anoxia, by rapidly suppressing QO2, abolished the receptor potential of the photoreceptors and caused a rapid drop of about 50% in the ATP content of the retina. At the same time the formation of [3H]2DG-6P was inhibited by about 30%. This indicates that respiring photoreceptors send a metabolic signal to glial cells which is suppressed by anoxia.

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.

Pump current and Na+/K+ coupling ratio of Na+/K+-ATPase in reconstituted lipid vesicles

A method is described for studying the coupling ratio of the Na+/K+ pump, i.e., the ratio of pump-mediated fluxes of Na+ and K+, in a reconstituted system. The method is based on the comparison of the pump-generated current with the rate of K+ transport. Na+/K+-ATPase from kidney is incorporated into the membrane of artificial lipid vesicles; ATPase molecules with outward-oriented ATP-binding site are activated by addition of ATP to the medium. Using oxonol VI as a potential-sensitive dye for measuring transmembrane voltage, the pump current is determined from the change of voltage with time t. In a second set of experiments, the membrane is made selectively K+-permeable by addition of valinomycin, so that the membrane voltage U is equal to the Nernst potential of K+. Under this condition, dU/dt reflects the change of intravesicular K+ concentration and thus the flux of K+. Values of the Na+/K+ coupling ratio determined in this way are close to 1.5 in the experimental range (10-75 mM) of extravesicular (cytoplasmic) Na+ concentrations.

Contribution of the Na+/K+-pump to the membrane potential

The inward movement of sodium ions and the outward movement of potassium ions are passive and the reverse movements against the electrochemical gradients require the activity of a metabolism-driven Na+/K+-pump. The activity of the Na+/K+-pump influences the membrane potential directly and indirectly. Thus, the maintenance of a normal electrical function requires that the Na+/K+-pump maintain normal ionic concentrations within the cell. The activity of the Na+/K+-pump also influences the membrane potential directly by generating an outward sodium current that is larger when the Na+/K+-pump activity is greater. The activity of the Na+/K+-pump is regulated by several factors including the intracellular sodium concentration and the neuromediators norepinephrine and acetylcholine. The inhibition of the Na+/K+-pump can lead indirectly to the development of inward currents that may cause repetitive activity. Therefore, the Na+/K+-pump modifies the membrane potential in different ways both under normal and abnormal conditions and influences in an essential way many cardiac functions, including automaticity, conduction and contraction. Key words. Active transport of ions; cardiac tissues; electroneutral and electrogenic Na+/K/-pump; control of Na+/K+-pump; normal and abnormal electrical events.

Stimulation-induced changes in the intracellular sodium activity of the crayfish stretch receptor

Changes in intracellular Na+ activity (aiNa) caused by mechanical stimulation in the slowly adapting stretch receptor of the crayfish were examined using Na+-selective microelectrodes. A series of brief stretches (each giving rise to a brief receptor potential and a single action potential) induced a reversible increase in aiNa which was proportional to the stimulation frequency in the range examined, 0-9.5 Hz. At 9.5 Hz, aiNa increased by 4-5 mM from the resting value of 7-10 mM. Tetrodotoxin (TTX) reduced, but did not abolish the stimulation-dependent increase in aiNa indicating the involvement of a Na+-influx pathway in addition to the potential-dependent, TTX-sensitive sodium channels of the neuronal plasma membrane. A likely candidate for this TTX-resistant pathway are the cationic transducer channels of the dendrites.

Effects of the ATP, ADP and inorganic phosphate on the transport rate of the Na+,K+-pump

(Na+ + K+)-ATPase from kidney outer medulla was incorporated into artificial dioleoylphosphatidylcholine vesicles. In the reconstituted system the pump can be activated by adding ATP to the external medium. ATP-driven potassium extrusion by the Na+,K+-pump was studied using a voltage-sensitive dye in the presence of valinomycin. ADP strongly reduced the turnover rate of the pump with a concentration for half-maximal inhibition of cD,1/2 = 0.1 mM. cD,1/2 was found to be virtually independent of ATP concentration, indicating that the inhibition is non-competitive with respect to ATP. The non-competitive inhibition by ADP can be explained on the basis of the Post-Albers reaction cycle of the Na+,K+-pump, assuming that the main action of ADP is the reversal of the phosphorylation step. A similar 'product inhibition' was observed with inorganic phosphate, but at much higher concentrations (cP,1/2 = 14 mM).

Cell sodium activity and sodium pump function in frog skin

Cell Na activity, acNa, was measured in the short-circuited frog skin by simultaneous cell punctures from the apical surface with open-tip and Na-selective microelectrodes. Skins were bathed on the serosal surface with NaCl Ringer and, to reduce paracellular conductance, with NaNO3, Ringer on the apical surface. Under control conditions acNa averaged 8 +/- 2 mM (n = 9, SD). Apical addition of amiloride (20 microM) or Na replacement reduced acNa to 3 mM in 6-15 min. Sequential decreases in apical [Na] induced parallel reductions in acNa and cell current, Ic. On restoring Na after several minutes of exposure to apical Na-free solution Ic rose rapidly (approximately less than 30 sec) to a stable value while acNa increased exponentially, with a time constant of 1.8 +/- 0.7 min (n = 8). Analysis of the time course of acNa indicates that the pump Na flux is linearly related to acNa in the range 2-12 mM. These results indicate that acNa plays an important role in relating apical Na entry to basolateral active Na flux.

Effects of altering the ATP/ADP ratio on pump-mediated Na/K and Na/Na exchanges in resealed human red blood cell ghosts

Resealed human red blood cell ghosts were prepared to contain a range of ADP concentrations at fixed ATP concentrations and vice versa. ATP/ADP ratios ranging from approximately 0.2 to 50 were set and maintained (for up to 45 min) in this system. ATP and ADP concentrations were controlled by the addition of either a phosphoarginine- or phosphocreatine-based regenerating system. Ouabain-sensitive unidirectional Na efflux was determined in the presence and absence of 15 mM external K as a function of the nucleotide composition. Na/K exchange was found to increase to saturation with ATP (K 1/2 approximately equal to 250 microM), whereas Na/Na exchange (measured in K-free solutions) was a saturating function of ADP (K 1/2 approximately equal to 350 microM). The elevation of ATP from approximately 100 to 1,800 microM did not appreciably affect Na/Na exchange. In the presence of external Na and a saturating concentration of external K, increasing the ADP concentration at constant ATP was found to decrease ouabain-sensitive Na/K exchange. The decreased Na/K exchange that still remained when the ADP/ATP ratio was high was stimulated by removal of external Na. Assuming that under normal substrate conditions the reaction cycle of the Na/K pump is rate-limited by the conformational change associated with the release of occluded K [E2 X (K) X ATP----E1 X ATP + K], increasing ADP inhibits the rate of these transformations by competition with ATP for the E2(K) form. A less likely alternative is that inhibition is due to competition with ATP at the high-affinity site (E1). The acceleration of the Na/K pump that occurs upon removing external Na at high levels of ADP evidently results from a shift in the forward direction of the transformation of the intermediates involved with the release of occluded Na from E1P X (Na). Thus, the nucleotide composition and the Na gradient can modulate the rate at which the Na/K pump operates.

The facilitating effect of gangliosides on the electrogenic (Na+/K+) pump and on the resistance of the membrane potential to hypoxia in neuromuscular preparation

The effects have been investigated of a mixture of gangliosides from beef brain cortex (GM1, GD1a, GD1b and GT1) either added to the bathing medium or injected intraperitoneally on muscle fibres and nerve terminals in mouse diaphragm. The electrogenic (Na+/K+) pump activity of muscle fibres enriched with sodium was increased by 38% after 2-h pretreatment with gangliosides (5 X 10(-8) mol X 1(-1]. Muscles from animals treated with gangliosides did not show the substantial depolarization of the resting membrane potential (RMP) in K+-free solution (6 h) shown by control muscles. Further, treatment with gangliosides slowed the changes in muscle fibre RMP and frequency of the miniature end-plate potentials in oxygen deprived muscles.

Acetyl phosphate can act as a substrate for Na+ transport by (Na+ + K+)-ATPase

Experiments using liposomes with (Na+ + K+)-ATPase incorporated showed that in the presence of extravesicular Mg2+, acetyl phosphate was able to stimulate Na+ uptake when the liposomes contained Na+ or choline and were K+-free; this acetyl phosphate-dependent Na+ transport was similar to the ATP-dependent transport observed with 0.003 mM or 3 mM ATP. When the intravesicular solution contained K+, there was an ATP-dependent Na+ uptake which was large with 3 mM ATP and small (about the size seen in K+-free liposomes) with 0.003 mM ATP; in this case, although acetyl phosphate produced a slight activation of Na+ transport, the effect was not statistically significant. All ATP and acetyl phosphate-stimulated Na+ transport disappeared in the absence of extravesicular Mg2+ or in the presence of ouabain in the intravesicular solution. These results are consistent with the hypothesis that, at the concentration used, acetyl phosphate can replace ATP in the catalytic but not in the regulatory site of the (Na+ + K+)-ATPase and active Na+ transport system. This suggests that as far as the early stages of the pump cycle are concerned the role of ATP is simply to phosphorylate.

Active sodium transport and fluid secretion in the gall-bladder epithelium of Necturus

Intracellular Na, K and Cl activities (acNa, acK and acCl) and membrane potentials were measured in Necturus gall-bladder epithelium using double-barrelled ion-sensitive micro-electrodes. Mucosal membrane potential was about -55 mV and the mean control activities were acNa = 14.7 mM, acK = 91.6 mM and acCl = 20.3 mM. Replacing mucosal Na by K caused a fall in acNa that followed an exponential time course. The rate of change in acNa was linearly related to acNa above a certain value (congruent to 3 mM). acK and acCl both increased in K Ringer solution. From the change in all three ions the cell was estimated to swell at an initial rate of 0.13% s-1. From the initial rate of change in acNa, a net cell efflux of Na of 405 pmol cm-2 s-1 was calculated. Replacement of Na by Tris or choline led to a similar result. The transepithelial Na transport rate was for this group of animals 346 pmol cm-2 s-1. Ouabain (10(-3) M) produced an increase in acNa and acCl, whereas acK decreased. The cells were estimated to swell at an initial rate of 0.06% s-1. The initial Na influx after Na-pump inhibition was calculated to be 162 pmol cm-2 s-1. The parallel measure of the transepithelial rate of transport of Na gave a value of 189 pmol cm-2 s-1. Ouabain inhibited the decrease in acNa after replacement of Na by K by about 80%. A fast depolarization, ranging from 2 to 7 mV, occurred after the perfusion with ouabain. Em then slowly decreased from about 53 to 32 mV in 1 h. It is concluded that (a) the major fraction of the transepithelial transport of Na is transcellular and mediated by the Na pump, (b) the pumping rate is linearly dependent on internal Na within a certain range and (c) the Na pump is electrogenic under normal circumstances.

Effects of p-nitrophenylphosphate on Ca2+ transport in inside-out vesicles from human red-cell membranes

Ca2+-ATPase activity and Ca2+ uptake in inside-out vesicles from human red cell membranes are changed in parallel by p-nitrophenylphosphate. This indicates that, unlike the Ca2+ pump of sarcoplasmic reticulum, the Ca2+ pump of the red cell membrane does not utilize p-nitrophenylphosphate hydrolysis to drive Ca2+ transport.

Intracellular ion control in lobster stretch receptor neurone

The control of intracellular ion concentrations by means of passive and active transmembrane ion transports was investigated in the lobster stretch neurone using electrophysiological and pharmacological techniques in combination with recording with ion-sensitive microelectrodes. In resting conditions [Na+]i, [K+]i, and [Cl-]i were, in both slowly and rapidly adapting cells, found to be in the order of 20, 155, and 50 mM, respectively. In the slowly adapting cell impulse firing at stationary frequencies of 7-10 Hz caused an increase in [Na+]i and a decrease in [K+]i of 20-30 mM; [Cl-]i was only little affected, the rise in [Na+]i led to an enhanced Na-K pump activity noticeable as an increase in pump current production. In stationary conditions the quotient between pump current and Na+ influx increments was about 0.3, which is compatible with 3:2 Na-K pumping ratio in the present preparation. From measurements of the pump current activation during stationary firing at maximum tolerable frequencies an estimate was made of the cell's maximum pump current production. The measurements were used in the formulation of a mathematical model of the intracellular ion control in which expressions of active and passive transmembrane ion transports are incorporated into the continuity equation for the ion fluxes involved.

Numerical analysis of the method of internal dialysis of giant axons

This paper presents a numerical analysis of the method of internal dialysis used for studies of membrane transport in giant axons. Account is taken of the complete geometry, end effects, and finite dialyzate flow rates. Both influx and efflux experimental conditions are considered. Results place quantitative limits on system performance that are sufficiently general for use in experimental design. The completeness of solute equilibration and the uniformity of solute concentration at the axon membrane are assessed, as well as the sensitivity to dialysis solution flow rate. The effects of undialyzed axon ends on the equilibration rate and on the uniformity of concentration are determined, and the contribution of undialyzed ends to influx measurements is evaluated. Equilibration times are correlated with physical properties of axoplasm and dialysis tubing, and with dialysis solution flow rate. Numerical results confirm the general qualitative assessments of the method that are based on years of successful application.

Electrical and biochemical properties of an enzyme model of the sodium pump

The electrochemical properties of a widely accepted six-step reaction scheme for the Na+, K+-ATPase have been studied by computer simulation. Rate coefficients were chosen to fit the nonvectorial biochemical data for the isolated enzyme and a current-voltage (I-V) relation consistent with physiological observations was obtained with voltage dependence restricted to one (but not both) of the two translocational steps. The vectorial properties resulting from these choices were consistent with physiological activation of the electrogenic sodium pump by intracellular and extracellular sodium (Na+) and potassium (K+) ions. The model exhibited K+/K+ exchange but little Na+/Na+ exchange unless the energy available from the splitting of adenosine triphosphate (ATP) was reduced, mimicking the behavior seen in squid giant axon. The vectorial ionic activation curves were voltage dependent, resulting in large shifts in apparent Km's with depolarization. At potentials more negative than the equilibrium or reversal potential transport was greatly diminished unless the free energy of ATP splitting was reduced. While the pump reversal potential is at least 100 mV hyperpolarized relative to the resting potential of most cells, the voltage-dependent distribution of intermediate forms of the enzyme allows the possibility of considerable slope conductance of the pump I-V relation in the physiological range of membrane potentials. Some of the vectorial properties of an electrogenic sodium pump appear to be inescapable consequences of the nonvectorial properties of the isolated enzyme. Future application of this approach should allow rigorous quantitative testing of interpretative ideas concerning the mechanism and stoichiometry of the sodium pump.

In squid axons intracellular Mg2+ is essential for ATP-dependent Na+ efflux in the absence and presence of strophanthidin

The effect on Na+ efflux of removal of intracellular Mg2+ was studied in squid giant axons dialyzed without internal Ca2+. In the absence of Mg2i+, ATP was unable to stimulate any efflux of Na+ above the baseline of about 1 pmol . cm-2 . s-1. This behavior was observed in otherwise normal axons and in axons poisoned with 50 microM strophanthidin in the sea water. Reinstatement of 4 mM MgCl2 in excess to ATP in the dialysis solution brought about the usual response of Na+ efflux to ATP, external K+ and strophanthidin. The present experiments show that, regardless of the mechanism for the ATP-dependent Na+ efflux in strophanthidin-poisoned axons, this type of flux shares with the active Na+ extrusion the need for the simultaneous presence of intracellular ATP and Mg2+.

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.

Transport of electrolytes in muscle

The muscle fiber stands alongside the red blood cell and the giant axon as one of the three classical cell types that have had major application in investigating ion transport processes in cell membranes. Of these three cell types, the muscle fiber was the first to provide definite evidence for a sodium pump. The ability of the sodium pump to produce an electrical potential difference across the cell membrane was also first demonstrated in muscle fibers. This important property of the sodium pump is now known to have physiological significance in many other types of cells. In this review, electrolyte transport investigations in skeletal muscle are traced from their inception to the current state of the field. Applications of major research techniques are discussed and key results are summarized. An overview of electrolyte transport in muscle, this article emphasizes relationships between the muscle fiber membrane potential and ionic transport processes.

Active and passive Na+ fluxes across the basolateral membrane of rabbit urinary bladder

The apical membrane of rabbit urinary bladder can be functionally removed by application of nystatin at high concentration if the mucosal surface of the tissue is bathed in a saline which mimics intracellular ion concentrations. Under these conditions, the tissue is as far as the movement of univalent ions no more than a sheet of basolateral membrane with some tight junctional membrane in parallel. In this manner the Na+ concentration at the inner surface of the basolateral membrane can be varied by altering the concentration in the mucosal bulk solution. When this was done both mucosal-to-serosal 22Na flux and net change in basolateral current were measured. The flux and the current could be further divided into the components of each that were either blocked by ouabain or insensitive to ouabain. Ouabain-insensitive mucosal-to-serosal Na+ flux was a linear function of mucosal Na+ concentration. Ouabain-sensitive Na+ flux and ouabain-sensitive, Na+-induced current both display a saturating relationship which cannot be accounted for by the presence of unstirred layers. If the interaction of Na+ with the basolateral transport process is assumed to involve the interaction of some number of Na+ ions, n, with a maximal flux, MMAX, then the data can be fit by assuming 3.2 equivalent sites for interaction and a value for MMAX of 287.8 pM cm-2 sec-1 with an intracellular Na concentration of 2.0 mM Na+ at half-maximal saturation. By comparing these values with the ouabain-sensitive, Na+-induced current, we calculate a Na+ to K+ coupling ratio of 1.40 +/- 0.07 for the transport process.

Comparative effects of external monovalent cations on sodium pump activity and ouabain inhibition rates in squid giant axon

1. A number of external monovalent cations were compared with regard to their effects on Na pump rate and the rate of ouabain inhibition of the pump in squid giant axon. 2. External ions which stimulate active Na efflux (K, Rb, and Cs) were found to decrease the rate at which low concentrations of ouabain inhibit the pump, and those ions which inhibit the pump externally (Na and Li) to increase the rate of inhibition. 3. In Na- and Li-containing solutions, pump rate appeared to be the major factor in determining the rate of ouabain inhibition regardless of whether K, Cs, or Rb was used to stimulate active Na efflux. 4. When choline was substituted for external Na, ouabain inhibition rates were more than twice as rapid when Cs was used as the pump-stimulating cation than when K was activating the pump to a similar level. 5. These results suggest that external monovalent cations modulate ouabain inhibition in squid axon at two classes of sites: pump activation sites, and also separate regulatory sites, whose occupation can significantly increase the rate of ouabain inhibition independent of pump turnover rate.

Na+, K+-dependent adenosine triphosphate phosphohydrolase. Two types of kinetics

Kinetic analysis of hydrolytic activity of (Na+, K+)-ATPase purified from duck salt glands shows that several substrates are hydrolysed in different manners. UTP, GTP and ITP are hydrolysed in accordance with usual Michaelis kinetics with the single Km value and with no cooperatively (Hill coefficient, nH = 1), while CTP is hydrolysed, like ATP, in accordance with non-Michaelis kinetics with two Km values. Hydrolysis of the last two substrates in the range of the second Km is characterised by positive cooperativity with nH greater than 1.

The effects of alterations in the external sodium concentration on human leucocyte sodium and potassium transport in vitro

Human leucocytes incubated in tissue culture fluid of low-sodium concentration (2 mM; iso-osmolarity maintained with choline chloride) reached a new equilibrium within 1 hour and lost approximately 25% of intracellular potassium and 70% of intracellular sodium. The rate constant for ouabain-sensitive sodium efflux fell by more than 50% and the ouabain-insensitive rate constant increased nearly threefold in the low-sodium medium. Total sodium efflux fell in proportion to internal sodium whereas ouabain-insensitive sodium efflux remained unchanged. A reduction in external sodium from 140 to 2 mM was associated with a 75% fall in sodium influx. In the low-sodium medium ouabain-sensitive potassium influx exceeded ouabain-sensitive sodium efflux and no ouabain-sensitive potassium efflux could be demonstrated. Ouabain-insensitive potassium influx and that portion of potassium efflux which is dependent on external potassium fell in parallel in low-sodium cells, suggesting reduced activity of a ouabain-insensitive K:K exchange system.

Intracellular sodium ion activity and sodium transport in rabbit urinary bladder

1. Intracellular potentials and the intracellular activities of Na+ and K+ were examined using conventional and ion-selective micro-electrodes. 2. In animals on a normal diet, the intracellular Na+ activity was 8.6 +/- 2.9 mM (mean +/- S.D.) with a mean short-circuit current of 2.8 +/- 0.9 microA/cm2. 3. In animals on a low-Na+ diet, the intracellular Na+ activity was 18.5 +/- 9.9 mM with a short-circuit current of 4.5 +/- 1.3 microA/cm2 (mean +/- S.D.). 4. There was a correlation between short-circuit current and intracellular Na+ activity which could be fitted by a saturating hyperbolic relationship. 5. Treatment of the issue with ouabain and amiloride produced an increase and a decrease, respectively, in the intracellular Na+ activity. 6. Treatment with aldosterone produced a large increase in short-circuit current with a substantial increase in intracellular Na+ activity. 7. Intracellular Na+ activity does not seem to affect apical membrane permeability directly.

An ATP-dependent sodium-sodium exchange in strophanthidin poisoned dialysed squid giant axons

1. Dialysed giant axons from the squid have been used to study some of the properties of the Na+ fluxes when the Na+ pump is fully inhibited by strophanthidin. 2. In axons which had been depleted of ATP, strophanthidin had no effect on Na+ efflux. Similar negative results were obtained in axons dialysed with and without internal or external K+, and with or without 100 microM-internal Ca2+. 3. In the presence of 60 mM-internal Na+, 440 mM-external Na+ and strophanthidin, the fluxes of Na+ had the following characteristics. (i) ATP stimulated an efflux and an influx of Na+ of similar magnitude. The K1/2 for ATP, measured from its effect on Na+ efflux, was about 200 microM. (ii) The non-hydrolysable ATP analogue adenylyl(beta, gamma-methylene)-diphosphonate (AMP-PCP), at 2 mM concentration, either alone or in combination with 2 mM-internal phosphate, failed to stimulate any efflux of Na+. (iii) The ATP-dependent Na+ efflux was not affected by removal of internal or external K+, or external Mg2+ or Ca2+, and was not dependent on internal Ca2+. (iv) within the resolution of the method, all the ATP-dependent Na+ influx required internal Na+, and all the ATP-dependent Na+ efflux required external Na+. From the magnitude of the unidirectional Na+ fluxes the stoichiometry seemed to be a 1 to 1 Na+--Na+ exchange. 4. The ATP-internal Na+-dependent influx of Na+ in the presence of strophanthidin was not affected by 1 mM-vandate in the dialysis solution, a concentration which fully inhibits the Na+ efflux through the Na+ pump that is activated by external K+. 5. In the presence of external Na+, the external K+ sites of the Na+ pump are completely saturated with 100 mM-external K+. In unpoisoned axons incubated with 100 mM-external K+, replacement of external Na+ with Tris+ produced no change in the efflux of Na+. However, in axons poisoned with 50 microM-strophanthidin, replacement of external Na+ with Tris+ resulted in a reversible inhibition of Na+ efflux. This could suggest that strophanthidin poisoning might induce Na+ (cations?) fluxes which are not present in normal conditions.

The effects of ATP on the interactions between monovalent cations and the sodium pump in dialysed squid axons

1. The efflux of Na in dialysed axons of the squid has been used to monitor the sidedness of the interactions of the Na pump with Na(+) ions, K(+) ions and ATP. The axons were under conditions such that most of the Na efflux went through the Na pump by means of a complete cycle of ATP hydrolysis.2. With 310 mm-K(i) (+), 70 mm-Na(i) (+) and 10 mm-K(+) artificial sea water (ASW) more than 97% of the Na efflux was abolished by removal of ATP. The efflux of Na was stimulated by ATP with a K((1/2)) of about 200 mum. This is similar to the K((1/2)) of 150 mum found for the ATP dependence of a ouabain-sensitive Na,K-ATPase activity in membrane fragments isolated from squid optical nerves.3. A 100-fold reduction in the ATP concentration (from 3-5 mm to 30-50 mum) increased the apparent affinity of the Na pump for K(o) (+) about 8-fold. In addition, the maximal rate of K(o) (+)-stimulated Na efflux was reduced by a similar factor. Analogous results were seen in axons dialysed with 310 mm-K(i) (+) or without K(i) (+).4. The relative effectiveness of external monovalent cations as activators of the Na efflux was a function of the ATP concentration inside the axon. With 3-5 mm-ATP the order of effectiveness was K(+) > NH(4) (+) > Rb(+). With 30-50 mum-ATP the sequence was NH(4) (+) >> K(+) >> Rb(+). These results were not affected by the removal of K(i) (+).5. When the ATP concentration was 3 mm and the Na(i) (+) concentration 70 mm, the removal of K(i) (+) produced a slight and reversible increase in the total efflux of Na (15%) and no change in the ATP-dependent Na efflux. When the ATP concentration was reduced to 30-50 mum, or the Na(i) (+) concentration lowered to 5-10 mm, the removal of K(i) (+) reversibly increased the total and the ATP-dependent efflux of Na. The largest increase in Na efflux was seen when both ATP and Na(i) (+) were simultaneously reduced. The ATP-dependent extra Na efflux resulting from the exclusion of K(i) (+) was abolished by 10(-4)m-ouabain in the sea waters.6. The increase in the ATP-dependent Na efflux observed in axons dialysed with 0 K(i) (+) + 10 mm-K(+) ASW was not seen in axons perfused with 310 mm-K(i) (+) + 450 mm-K(+) ASW. However, both experimental conditions gave rise to a similar (and small) ATP-independent and ouabain-insensitive efflux of Na. This indicates that the effects on the Na pump of removing K(i) (+) are not due to the simultaneous membrane depolarization. In addition, it suggests that K(i) (+) has an inhibitory effect on the Na pump, and that that effect is antagonized by Na(i) (+) and ATP.7. The present results are consistent with the idea that the same conformation of the Na pump (and Na,K-ATPase) can be reached by interaction with external K(+) after phosphorylation and with internal K(+) before rephosphorylation. This enzyme conformation produces an enzyme-K complex from which K(+) ions are not easily released unless high concentrations of ATP are present. This also stresses a non-phosphorylating regulatory role of ATP.

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.

Vanadate inhibits uncoupled Ca efflux but not Na--Ca exchange in squid axons

Nerve cells can maintain a very low intracellular calcium concentration ([Ca2+]i) against large Ca2+ electrochemical gradients (see ref. 1 for review). The properties of the calcium efflux from these cells depend on [Ca2+]i (ref. 2), and within the physiological range, most Ca efflux depends on ATP (which stimulates with high affinity) and is insensitive to Na1, Na0 and Ca0 (uncoupled Ca efflux). When the [Ca2+]i is well above the physiological range, Ca efflux becomes only partially dependent on ATP (acting now with low affinity), is inhibited by Nai and is stimulated by Na0 and Ca0 (Na--Ca exchange). Orthovanadate, a powerful inhibitor of the (Na+ + K+)ATPase and the Na pump, also inhibits the Ca-stimulated ATPase activity, which is the enzymatic basis for the uncoupled Ca pump, in human red cells. The experiments reported here show that in squid axons the ATP-dependent uncoupled Ca efflux can be fully and reversibly inhibited by vanadate, whereas concentrations of vanadate 10 times higher have no effect on the Na--Ca exchange. This is another indication that the uncoupled Ca efflux represents an ATP-driven Ca pump, and supports the suggestion that the uncoupled Ca efflux and Na--Ca exchange are mediated by different mechanisms.

Sodium and potassium fluxes across the dialyzed giant axon of Myxicola

Resting and stimulated fluxes of sodium and potassium across the giant axon of the marine annelid, Myxicola infundibulum, have been characterized using the technique of internal dialysis. In most respects the ion movements were found to be similar to those in squid axons. Sodium efflux and potassium influx were found to be active, cardiac glycoside-sensitive fluxes, with a variable coupling ratio. However, when [ATP]i was lowered to less than 20 microM by treatment with cyanide and continuous dialysis, or to less than 2 microM by dialysis with glucose following injection of hexokinase, Na efflux and K influx were unaltered. The maintained fluxes were not accounted for by an increased passive permeability of the axolemma, although 30-60% of the Na efflux appeared to be due to Na-Na exchange. An altered form of Na pump operation at low [ATP]i is a more likely explanation than an alternate energy source, or an ATP source proximate to the axolemma. The transient response of 22Na efflux to a change in [22Na]i was found to be much slower than in squid, tau = 360 sec. The efflux delay could only be accounted for by an extra-axonal diffusion barrier, which is probably the basement membrane surrounding the ventral nerve cord.

Calcium movement in nerve fibres

Given the existence of a difference in electrical potential between the interior of a nerve cell and the media surrounding it, where the cytoplasm is some 70 mV negative (Hodgkin, 1958), it must be expected that any positively charged ion to which the cell membrane is permeable is more concentrated in the cell interior. For monovalent cations such as Na and divalent cations such as Ca and Mg this is not the case in the majority of the cells such as the squid giant axon. In other words, nerve cells maintain a lower intracellular concentration of these ions, as compared with their concentration in the extracellular fluid. For Mg, Ca and Na ions, this lower internal concentration must, in the steady state, be effected by some membrane based mechanism which consumes energy.

Sidedness of the ATP-Na+-K+ interactions with the Na+ pump in squid axons

Using dialysed squid axons we have been able to control internal and external ionic compositions under conditions in which most of the Na+ efflux goes through the Na+ pump. We found that (i) internal K+ had a strong inhibitory effect on Na+ efflux; this effect was antagonized by ATP, with low affinity, and by internal Na+, (ii) a reduction in ATP levels from 3 mM to 50 microM greatly increased the apparent affinity for external K+, but reduced its effectiveness compared with other monovalent cations, as an activator of Na+ efflux, and (iii) the relative effectiveness of different K+ congeners as external activator of the Na+ efflux, though affected by the ATP concentration, was not affected by the Na+/K+ ratio inside the cells. These results are consistent with the idea that the same conformation of the (Na+ + K+)-ATPase can be reached by interaction with external K+ after phosphorylation and with internal K+ before rephosphorylation. They also stress a nonphosphorylating regulatory role of ATP.

Chloride and sodium influx: a coupled uptake mechanism in the squid giant axon

The squid giant axon was internally dialyzed while the unidirectional fluxes of either Cl or Na were measured. The effects of varying the internal or external concentration of either Na or Cl were studied. Chloride influx was directly proportional to the external Na concentration whereas Cl efflux was unaffected by changes of the external Na concentration between 0 and 425 mM. Neither Cl influx nor efflux were affected by changes of internal Na concentration over the range of 8-158 mM. After ouabain and TTX treatment a portion of the remaining Na influx was directly dependent on the extracellular Cl concentration. Furthermore, when the internal Cl concentration was increased from 0 to 150 mM, the influxes of Cl and Na were decreased by 14 and 11 pmol/cm2.s, respectively. The influx of both ions could be substantially reduced when the axon was depleted of ATP. The influxes of both ions were inhibited by furosemide but unaffected by ouabain. It is concluded that the squid axolemma has an ATP-dependent coupled Na-Cl co-transport uptake mechanism.