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

Cation regulation by the terrestrial isopod Armadillidium vulgare (Crustacea: Isopoda: Oniscidea) during dehydration in air

Many terrestrial arthropods display tight osmotic and ionic regulation of the hemolymph during dehydration. In this study, we sought to quantify the level of regulation of the major hemolymph cations in the terrestrial isopod Armadillidium vulgare (Isopoda, Oniscidea). Inulin space measurements showed that the hemolymph comprises 52 ± 2.2% of the hydrated water content but contributes 71 ± 9.8% of water losses during desiccation. Hemolymph concentrations of Na+, K+ and Ca²+ were measured in variably dehydrated animals using ion-selective microelectrodes and compared with predicted concentrations assuming no regulation. Na+ and Ca²+ are quite tightly regulated, showing respective concentration increases of 20.8% and 7.1% following a 50% reduction in hemolymph volume, but K+ showed no measurable regulation. The excreted cation fraction during desiccation is negligible. Sites of ion sequestration were examined by injecting ²²Na and ⁴⁵Ca into the hemolymph of hydrated animals and assaying tissue-specific activities following dehydration. Na+ is apparently sequestered non-specifically by an unknown mechanism. Ca²+ accumulates in the dorsal somatic tissues, possibly in the calcium pool of the cuticle. How A. vulgare avoids significant disruptions of E(m) and neuromuscular function in the absence of K+ regulation, and how it sequesters Na+, both pose intriguing challenges for future work.

Dynamic and static calcium gradients inside large snail (Helix aspersa) neurones detected with calcium-sensitive microelectrodes

We have used quartz Ca²⁺-sensitive microelectrodes (CASMs) in large voltage-clamped snail neurones to investigate the inward spread of Ca²⁺ after a brief depolarisation. Both steady state and [Ca²⁺]_i transients changed with depth of penetration. When the CASM tip was within 20 μm of the far side of the cell the [Ca²⁺]_i transient time to peak was 4.4 ± 0.5 s, rising to 14.7 ± 0.7 s at a distance of 80 μm. We estimate that the Ca²⁺ transients travelled centripetally at an average speed of 6 μm² s⁻¹ and decreased in size by half over a distance of about 45 μm. Cyclopiazonic acid had little effect on the size and time to peak of Ca²⁺ transients but slowed their recovery significantly. This suggests that the endoplasmic reticulum curtails rather than reinforces the transients. Injecting the calcium buffer BAPTA made the Ca²⁺ transients more uniform in size and increased their times to peak and rates of recovery near the membrane. We have developed a computational model for the transients, which includes diffusion, uptake and Ca²⁺ extrusion. Good fits were obtained with a rather large apparent diffusion coefficient of about 90 ± 20 μm² s⁻¹.This may assist fast recovery by extrusion.

Ultrastructural and mechanical properties of electrically inexcitable skeletal muscle fibers of the crustacean Atya lanipes

Examination of the ultrastructure and mechanical activation of the ventro-abdominal flexor muscle of the freshwater crustacean Atya lanipes shows that the fibers are of the long sarcomere, tonic type. The fibers possess an ample and well-organized internal membrane system, with extensive regions of T/SR dyad contacts near the ends of the A bands. An orbit of 10-12 thin filaments surrounds each thick filament. The lanthanum tracer method reveals a highly regular organization of the T-system, Z-tubules, and multiple internal clefts. Tension generation responds to extracellular potassium in a concentration dependent manner and is very slow. Mechanical activation is strictly dependent on extracellular Ca2+, even though these muscle fibers do not generate Ca2+ currents when depolarized. Tension development responds to caffeine and is also dependent on extracellular Na+, suggesting that Ca2+ release from the SR and Ca2+ influx via the Na/Ca exchanger intervene in mechanical activation.

Intracellular Na+, K+ and Cl- activity in tonic and phasic muscle fibers of the crab Eriphia

(1) Intracellular activities of K+, Na+ and Cl- were measured with ion-sensitive microelectrodes in four different types of muscle fibers in the closer muscle of the crab Eriphia. (2) The membrane resting potentials of the tonic fibers were 9-15 mV more positive than those of phasic muscle fibers. This was due to higher permeability of the membranes of tonic fibers for Na+. (3) The intracellular Na+-activity of tonic fibers was 35-40% higher than that of phasic fibers. Also intracellular Cl- -activity was about 15-33% higher in tonic fibers. (4) No significant differences in K+ -activities were found between physiologically different muscle fiber types. The K+ -equilibrium potentials were always more negative than the resting potentials. In muscle fibers with inhibitory innervation, Cl- -equilibrium potentials were close to (phasic fibers) or slightly more negative (tonic fibers) than resting potentials.

Light-induced oxygen consumption in Limulus ventral photoreceptors does not result from a rise in the intracellular sodium concentration

Illumination of Limulus ventral photoreceptors leads to an increase in the intracellular concentration of sodium, [Na+]i, and to an increase in the consumption of O2 (delta QO2). After a 1-s light flash, it takes approximately 480 s for [Na+]i to return to within 10% of its preillumination level, whereas delta QO2 takes approximately 90 s. Thus, the delta QO2 is complete long before [Na+]i has returned to its resting level. Pressure injection of Na+ into the cell in order to elevate [Na+]i to the same levels as attained by illumination causes a rise in [Na+]i that returns to baseline with the same time course as the light-induced rise in [Na+]i. However, the injection of Na+ does not lead to an increase of the consumption of O2. We conclude that activation of the Na pump by a rise in [Na+]i is not a factor involved in the light-induced activation of O2 consumption in these cells.

Strophanthidin and force regulation by intracellular sodium activity in cardiac Purkinje fibers

The role of intracellular sodium activity (aiNa) in the inotropy of a low concentration of strophanthidin (5 X 10(-8 M) was studied in sheep cardiac Purkinje fibers by recording contractile force, aiNa and transmembrane potentials under conditions that vary aiNa. High [Na]O, strophanthidin and tetrodotoxin (TTX) changed force and aiNa in a closely related manner: on logarithmic coordinates, the data were well fitted by a single line obtained through the regression equation F = b (aiNa)s where b represents the intercept and s the slope of the relation. With low strophanthidin, force increases as a linear function of (aiNa) approximately 5 and with high [Na]O as a linear function of (aiNa) approximately 6. However, the combined administration of high [Na]O and strophanthidin results in a potentiated inotropic effect as force becomes a linear function of (aiNa) approximately 14. This potentiation and its abolition by TTX suggests that factors other than aiNa powerfully modify the inotropy of a low strophanthidin concentration.

Investigation of factors affecting the intracellular sodium activity in the smooth muscle of guinea-pig ureter

1. The intracellular Na+ activity (aNai) of the smooth muscle cells from guinea-pig ureter has been measured using double-barrelled Na+-sensitive micro-electrodes. aiNa in modified Krebs solution at 35 degrees C was of a mean 7.4 +/- 2.9 mM (n = 32, S.D. of an observation), equivalent to a Na+ equilibrium potential (ENa) of +66.7 mV. Membrane potential (Em) was of a mean -50.8 +/- 4.6 mV. 2. Inhibition of the Na+ pump by application of ouabain or removal of external K+ (K+o) resulted in a restricted rise of aNai. The rate of rise was faster in the presence of ouabain (10(-4) M) but the stabilized aNai was not significantly different from that observed after the prolonged absence of K+o. The mean aiNa recorded after prolonged Na+ pump inhibition was 20.6 +/- 5.5 mM (n = 28), equivalent to an ENa of +39.6 mV. Neither removal of K+o after aNai had stabilized in the presence of ouabain nor application of ouabain after aNai had stabilized in K+-free solution caused a rise in aiNa, suggesting that the Na+ pump was fully inhibited by either procedure. 3. Reduction of Na+o resulted in a rapid fall in aiNa against the electrochemical gradient, both before and after Na+ pump inhibition. At each level of Na+o, aNai stabilized such that ENa remained approximately constant in either condition. Readdition of Na+o resulted in a rapid recovery of aNai. 4. Elevation of Ca2+o (at constant Na+o) caused a fall in aNai of much the same time course as that observed on reduction of Na+o, both before and after Na+ pump inhibition. The extent of the fall was dependent upon the initial aNai. Reduction of Ca2+o resulted in a rise in aNai. 5. Elevation of the external divalent cation concentration with Mn2+ or, to a lesser extent, Mg2+ reduced aiNa in the presence of a functional Na+ pump. But after prolonged exposure to ouabain or K+-free solution, elevation of Mg2+o had no effect on aiNa while application of Mn2+o caused a slow rise. These results suggest that Ca2+o affects aiNa in two ways. One is mimicked by Mg2+ and Mn2+ and is probably due to alteration of the Na+ leak. The other is a specific effect, revealed by Na+ pump inhibition. 6. It is concluded that aiNa can be maintained far from equilibrium in the absence of a functional Na+ pump. Several lines of evidence are discussed which indicate the participation of Na+-Ca2+ exchange in Na+ extrusion in this condition.

Excitatory effect of amino acids on identified neuron R14 of Aplysia. I. Glycine-induced depolarization and its ionic mechanism

The ionic mechanism of the membrane effect of glycine on identified neuron R14 of Aplysia was investigated with conventional intracellular recording and voltage-clamp techniques. Both localized and bath applications of glycine markedly depolarize R14. Bath-applied glycine induced an inward current that gradually reached a maximum and remained at that level until glycine was washed out. Displacement of the holding potential from -46 to -121 mV increased the inward current. The extrapolated reversal potential was +38.6 mV. Reduction of [Na+]o reversibly decreased the inward current. Alterations of [K+]O, [Cl-]O, and [Ca2+]O, as well as bath-applied ouabain and sodium cyanide, did not affect the inward current. These results suggest that glycine can induce an Na+ current and that the glycine-induced inward current does not reflect an active uptake by an Na+-coupled transport system of glycine into the neuron.

The effect of leakage on micro-electrode measurements of intracellular sodium activity in crab muscle fibres

The effect of lowering extracellular Na (Nao) on the intracellular Na activity has been measured in single muscle fibres from the crab Carcinus maenas using Na+-sensitive glass micro-electrodes. Measurements have been made with recessed-tip micro-electrodes inserted radially into intact fibres, and with axial electrodes in cannulated fibres. Reducing Nao to one-tenth normal caused local contractions in intact fibres. The apparent steady-state internal Na (Nai) and the fall in Nai when Nao was reduced were found to vary considerably not only between different fibres but also when measured with different electrodes in the same fibre. The steady-state Nai, and the extent and rate of its decrease when Nao was reduced, could be reduced by pushing the Na+-sensitive electrode deeper into the fibre. Cannulated fibres generally had higher internal Na activities than intact fibres, but at comparable levels of Nai the rate of fall recorded from cannulated fibres when Nao was reduced was much slower than with intact fibres. In both intact and cannulated fibres the decrease in Nai was reduced by ouabain. The level of Nai recorded in cannulated fibres was sensitive to depolarization. Depolarizations from -50 to -30 mV resulted in a rise in Nai while further depolarization to 0 mV resulted in a fall in Nai. We conclude that both our results and those of Vaughan-Jones (1977) on undissected fibres are contaminated by leakage into the fibre round the micro-electrode. The true internal Na activity is probably much lower than previously reported.

Sodium/calcium exchange in mammalian ventricular muscle: a study with sodium-sensitive micro-electrodes

A method for mounting and rapidly perfusing small ventricular trabeculae (diameter around 250 micron) from either ferret or guinea-pig is described. Tension, membrane potential (Em) and intracellular Na activity (aiNa) were measured. aiNa was measured using Na-sensitive micro-electrodes. At room temperature (22-26 degrees C), [Na]o 155 mmol/l and [Ca]o 5.4 mmol/l, aiNa was 10.9 mmol/l +/- S.D. 4.2 mmol/l (n = 148). When [Na]o was reduced from 155 to 1.5 mmol/l contractures developed. These were about twitch height in guinea-pig but less than the twitch height in ferret. Associated with the development of the contracture there was a decrease in aiNa. The aiNa halved within 30 s. The decrease in aiNa was not influenced by changing pHo from 7.4 to 9.5, K-free solution or strophanthidin 50 mumol/l and was not passive since, even when the [Na]o was 1.5 mmol/l, the driving force for Na ions remained inward. The aiNa decreased if [Ca]o was increased and [Na]o decreased or vice versa. On the basis of these findings it is concluded that the decrease in aiNa is mainly due to Na/Ca exchange. Despite the large decrease in aiNa the [Ca]i, as monitored by tension changes, hardly increased. Since Ca uptake does occur in Na-free conditions in heart muscle it is proposed that the mitochondria take up Ca ions and so prevent an excessive rise in cytoplasmic Ca. Strophanthidin increased both aiNa and the withdrawal contracture, but collected results from a number of experiments showed no clear correlation between the initial aiNa and contracture amplitude. Strophanthidin may, therefore, have actions additional to increasing aiNa.

Contractions induced by sodium withdrawal in crab (Callinectes danae) muscle fibres

A study was made of the effects of Na removal on the resting tension of single muscle fibres of the crab Callinectes danae. Reduction of [Na]o (replacement with Li, Tris or choline) below a threshold value, typical for each fibre, induced spontaneous, local contractions randomly dispersed along the fibres; this was followed by propagated contractile waves and tension oscillations. Sustained contractures were occasionally seen at threshold [Na]o and were consistently observed when [Na]o was further reduced. The Na withdrawal contractions depended on [Ca]o and were abolished in Ca-free media; they were restored within seconds after the addition of Ca (3-12 mM) or Sr (15-25 mM), but not Ba (10-100 mM), to the media. Caffeine (0.2-1.0 mM) facilitated, whereas La (2-5 mM), procaine (1 mM) or lidocaine (10 mM) inhibited the Na-withdrawal contractions. It is concluded that increased Ca influx across the sarcolemma and release of stored Ca from the sarcoplasmic reticulum are involved in the contractions induced by Na-deficient solutions in crab fibres.

Effect of 50% external sodium in solutions of normal and twice normal tonicity on internal sodium activity in frog skeletal muscle

Neutral carrier based sodium-selective microelectrodes were used to monitor intracellular sodium activity in single frog skeletal muscle fibres during exposure to 50% external sodium solutions at normal and twice normal tonicity. Intracellular sodium activity in normal Ringer was 12.3 +/- 0.7 mM and was increased to 34.4 +/- 1.3 mM in hypertonic solution. Exposure to normotonic or hypertonic solutions containing only 50% sodium (NaCl) replaced by sucrose to maintain tonicity) did not affect the intracellular sodium activity during at least 20 min. Thus, in frog skeletal muscle, external sodium appears not to play a major role in regulating internal sodium, e.g. through ion exchange mechanisms as postulated for other excitable tissues.

The dependence of sodium pumping and tension on intracellular sodium activity in voltage-clamped sheep Purkinje fibres

1. Intracellular Na activity (aiNa) was measured in sheep cardiac Purkinje fibres using a recessed-tip Na+-sensitive micro-electrode. The membrane potentials was controlled with a two-micro-electrode voltage clamp. Tension was measured simultaneously. 2. Removing external K produced a rise of aiNa and both twitch and tonic tension. On adding 4-10 mM-[Rb]0 to reactivate the Na-K pump aiNa and tension declined. An electrogenic Na pump current transient accompanied the fall of aiNa. 3. The half-time of decay of the electrogenic Na pump current transient was similar to that of aiNa, (mean tNa0.5/tI0.5 = 0.97 +/- 0.03 (S.E.M.; n = 28)). Following the re-activation of the Na-K pump, the electrogenic Na pump current transient was linearly related to aiNa. 4. The duration of exposure to K-free, Rb-free solutions was varied to change the level of aiNa. On subsequently re-activating the Na-K pump with 10 mM-[Rb]0, the ratio of the charge extruded to the total change of aiNa was constant. It is concluded that the fraction of Na extruded electrogenically is unaffected by changes of aiNa. About 26% of the total Na extrusion appeared as charge transfer. 5. The relationship between tonic tension and aiNa was usually different during Na-K pump inhibition in a K-free, Rb-free solution compared with the relationship during Na-K pump re-activation. In general, a given aiNa was associated with a greater level of tonic tension during Na-K pump inhibition compared with that during pump re-activation. A similar hysteresis was often seen between twitch tension and aiNa.

The effects of chloride substitution on intracellular pH in crab muscle

1. Intracellular pH (pHi) was measured in crab muscle fibres using pH-sensitive micro-electrodes. The mean stable pHi was 7.19 +/- 00.2 (S.E. of mean) and the corresponding mean membrane potential was -64.6 +/- 0.4 mV (S.E. of mean) at an external pH of 7.5. 2. The effects on pHi of replacing 20% (100 mM) of the external NaCl by the Na salts of various anions were examined. The anions of weak acid (pK'a greater than 4.5) caused large internal acidifications. The anions of strong acids (pK'a less than 2.6) caused little or no change in pHi. The anions of acids with an intermediate pK'a had varied effects on pHi. In particular salicylate (pK'a = 2.97) was found to cause a large fall in pHi. 3. Increasing the external pH reduced the effects of the anions of weak acids on pHi. It is argued that these effects are the result of the entry and subsequent dissociation of undissociated acid molecules. 4. The results with propionate were quantified by comparing them with the effects of 5% CO2 and were found to be smaller than expected. It is suggested that this is the result of substantial membrane permeability to the propionate anion.

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.

Sodium-calcium exchange in regulation of cardiac contractility. Evidence for an electrogenic, voltage-dependent mechanism

The origin and regulatory mechanisms of tonic tension (Ca current-independent component of contractility) were investigated in frog atrial muscle under voltage-clamp conditions. Tonic tension was elicited by depolarizing pulses of 160 mV (Em = +90 mV, i.e., close to E ca) and 400--600 ms long. An application of Na-free (LiCl) or Ca-free Ringer's solutions resulted in a fast (less than 120 s), almost complete abolition of tonic tension. When [Na]o was reduced (with LiCl or sucrose as the substitutes), the peak tonic tension increased transiently and then decreased below the control level. The transient changes in tonic tension were prevented by using low-Na, low-Ca solutions where the ratios [Ca]0/[Na]40 to [Ca]o/[Na]4o were kept constant (1.1 X 10(-8) mM-3 to 8.7 X 10(-13) mM-5). Na-free (LiCl) solution elicited contractures accompanied by a membrane hyperpolarization or by an outward current even when the Na-K pump was inhibited. 15 mM MnCl2 (or 3 mM LaCl3) inhibited the development of the Na-free contracture and the related part of hyperpolarization or the outward current. In conclusion, our results indicate that tonic tension is regulated by a Na-Ca exchange mechanism. Furthermore, they suggest that this exchange could be electrogenic (exchanging three or more Na ions for one Ca ion) and thus voltage dependent. The possible contribution of an electrogenic Na-Ca exchange in the maintenance of cardiac membrane potential is discussed.

The depolarizing afterpotential of crab muscle fibres. A sodium-dependent process mediated by intracellular calcium

1. A study was made of the depolarizing afterpotential (d.a.p.) which follows the initial graded electrogenesis of crab muscle fibres. 2. Increasing the strength, duration or amplitude of the stimulating current pulses enhanced both the d.a.p. and the local contractions. 3. Arsenazo III was injected intracellularly and changes in light absorbance by the dye were used to monitor the increase in free sarcoplasmic Ca concentration during excitation-contraction (E-C) coupling. The onset of the absorbance changes occurred during the depolarizing phase of the initial electrogenesis and the maximum value coincided with the peak of the d.a.p. An exponential decay of the absorbance signal occurred during the repolarizing phase of the d.a.p. 4. Ionophoretic injection of EGTA into the sarcoplasm did not affect the initial electrogenesis but did reduce changes in dye absorbance, blocked tension development and abolished the d.a.p. 5. Caffeine (0.1--0.4 mM) markedly enhanced both the d.a.p. and the local contractions, but had no effect on the initial electrogenesis. 6. Replacement of extracellular Na ions with Li, Tris or choline abolished the d.a.p. The initial electrogenesis was enhanced in the choline-containing medium, but was not affected by Li or Tris. The rate of relaxation of the local contractions and the rate of decay of the light absorbance changes were slowed in Na-free saline. 7. Tetrodotoxin (10(-5) g/ml.) had no effect on either the membrane responses or tension development. 8. For initial graded responses of comparable peak amplitude a threefold reduction of [Ca-a1o shortened the d.a.p., but had little effect onits peak amplitude. A fivefold increase in [Ca]o reduced both the amplitude and duration of the d.a.p. 9. Changes in [Mg]o had little effect on the d.a.p., but both Mn (4--10 mM) and La (0.1 mM) blocked the initial electrogenesis and the d.a.p. 10. It is concluded that distinct ionic mechanisms give rise to the initial electrogenesis and the d.a.p. While the former is due to activation of Ca conductance, the d.a.p. is a Na-dependent phenomenon that is tetrodotoxin-insensitive, and mediated by the rise of intracellular Ca concentration during E--C coupling.

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.