The Effects of Various Ions on Resting and Spike Potentials of Barnacle Muscle Fibers

Effects of monovalent cations and some anions on the electrical properties of the barnacle muscle fiber membrane were studied when the intra- or extracellular concentrations of those ions were altered by longitudinal intra-cellular injection. The resting potential of the normal fiber decreases linearly with increase of logarithm of [K⁺]_out and the decrement for a tenfold increase in [K⁺]_out is 58 mv when the product, [K⁺]_out ·[Cl^-]_out, is kept constant. It also decreases with decreasing [K⁺]_in but is always less than expected theoretically. The deviation becomes larger as [K⁺]_in increases and the resting potential finally starts to decrease with increasing [K⁺]_in for [K⁺]_in > 250 mM. When the internal K⁺ concentration is decreased the overshoot of the spike potential increases and the time course of the spike potential becomes more prolonged. In substituting for the internal K⁺, Na⁺ and sucrose affect the resting and spike potentials similarly. Some organic cations (guanidine, choline, tris, and TMA) behave like sucrose while some other organic cations (TEA, TPA, and TBA) have a specific effect and prolong the spike potential if they are applied intracellularly or extracellularly. In all cases the active membrane potential increases linearly with the logarithm of [Ca⁺⁺]_out/[K⁺]_in and the increment is about 29 mv for tenfold increase in this ratio. The fiber membrane is permeable to Cl^- and other smaller anions (Br^- and I^-) but not to acetate^- and larger anions (citrate^-, sulfate^-, and methanesulfonate^-).     

Electrical properties of Paramecium caudatum: all-or-none electrogenesis

Summary Specimens of Paramecium immersed in solutions of CaCl₂ show graded electrogenesis in response to imposed transmembrane current. However, when BaCl₂ in a final concentration of 0.25 mM is added to a 1 mM CaCl₂ solution, an outward current pulse of 10^-10 amp or greater elicits an all-or-none transient reversal in membrane potential having a duration of about 40 msec. An increase of [Ba⁺⁺] results in (a) lower resting potential, (b) positive shift in critical firing level, (c) increased overshoot of the action potential, (d) decreased hyperpolarizing afterpotential, and (e) increased duration of the action potential (a.p.). If [Ca⁺⁺] is increased along with [Ba⁺⁺] so as to keep the ratio [Ba⁺⁺]/[Ca⁺⁺] constant, the same results are obtained except that the duration of the a. p. remains unaltered. Thus, effects a-d appear to be related to [Ba⁺⁺] and not to [Ca⁺⁺] or [Cl^-]. The degree of overshoot in 1 mM Ca is linearly related to log [Ba⁺⁺] with a slope of approximately 22 mv. With the ratio [Ba⁺⁺]/[Ca⁺⁺] constant, the slope closely approaches the ideal value of 29 mv. The evidence indicates that prolongation of the action potential is due to a delayed onset of Ba inactivation, and that this in turn is a function of surface-bound Ba. Other features of the action potential are absolute refractoriness during its rising and plateau phases, relative refractoriness lasting several seconds, and repetitive firing in response to steady current depolarization. The response is unaffected by TTX and TEA. Mn prolongs the action potential. Sr has an action similar to Ba, whereas the addition of K, Na, Rb, or Mg to the basic calcium medium is unaccompanied by all-or-none electrogenesis.On leave of absence from the Zoological Institute, Faculty of Science, University of Tokyo.Support came from National Science Foundation grant GB-5752x, U.S.P.H.S. grant NB-03664, and in part from Office of Naval Research grant Nonr 4785(00) administered by the Marine Biological Laboratory, Woods Hole.     

Graded and All-or-None Electrogenesis in Arthropod Muscle : I. The effects of alkali-earth cations on the neuromuscular system of Romalea microptera

Graded electrically excited responsiveness of Romalea muscle fibers is converted to all-or-none activity by Ba⁺⁺, Sr⁺⁺, or Ca⁺⁺, the two former being much the more effective in this action. The change occurs with as little as 7 to 10 per cent of Na⁺ substituted by Ba⁺⁺. The spikes now produced have overshoots and may be extremely prolonged, lasting many seconds. During the spike the membrane resistance is lower than in the resting fiber, but the resting resistance and time constant are considerably increased by the alkali-earth ions. The excitability is also increased, spikes arising neurogenically from spontaneous repetitive discharges in the axon as well as myogenically from spontaneous activity in the muscle fibers. Repetitive responses frequently occur on intracellular stimulation with a brief pulse. The data indicate that the alkali-earth ions exert a complex of effects on the different action components of electrically excitable membrane. They may be described in terms of the ionic theory as follows: The resting K⁺ conductance is diminished. The sodium inactivation process is also diminished, and sodium activation may be increased. Together these changes can act to convert graded responsiveness to the all-or-none variety. The alkali-earth ions can also to some degree carry inward positive charge during activity, since spikes are produced when Na⁺ is fully replaced with the divalent ions.     

Graded and All-or-None Electrogenesis in Arthropod Muscle : II. The effects of alkali-earth and onium ions on lobster muscle fibers

Conversion of graded responsiveness of lobster muscle fibers to all-or-none activity by alkali-earth and tetraethylammonium (TEA) ions appears to be due to a combination of effects. The membrane is hyperpolarized, its resistance is increased, and its sensitivity to external K⁺ is diminished, all effects which indicate diminished K⁺ conductance. While the spikes are prolonged, the conductance is higher throughout the response than it is in the resting membrane. Repetitive activity becomes prominent. These effects indicate maintained high conductance for an ion which causes depolarization. This is normally Na⁺, since its presence in low concentrations potentiates the effects of Ba⁺⁺, but the alkali-earth ions and TEA can also carry inward charge. Ba⁺⁺, Sr⁺⁺, and TEA appear to be more effective than is Ca⁺⁺ in its normal role, which is probably to depress K⁺ conductance and Na inactivation. Thus, conversion of graded to all-or-none responsiveness appears to occur because of the relative increase of depolarizing inward ion flux and decrease of repolarizing outward flux.     

Membrane Currents Carried by Ca, Sr, and Ba in Barnacle Muscle Fiber During Voltage Clamp

Membrane currents associated with voltage clamp of the giant muscle fibers of a barnacle, Balanus nubilus, were analyzed in terms of currents of the Ca and K channels. Although the activation of the K channel occurs more slowly than that of the Ca channel, both currents show a significant temporal overlap. The currents carried by Ca⁺⁺, Sr⁺⁺, or Ba⁺⁺ through the Ca channel were compared under the conditions at which this overlap was the least. When only one divalent cation is present in the solution, Ba⁺⁺ carries more current than Ca⁺⁺ or Sr⁺⁺ and the sequence of the current is Ba > Sr ≈ Ca. When the external solution contains a relatively high concentration of Co⁺⁺, which is a blocking agent for the Ca channel, inversion of the sequence occurs, to Ca > Sr > Ba. This is due to the fact that the blocking effect differs depending on which ion carries current through the Ca channel. The Ba current is most sensitive and the Ca current is least affected. Ba suppresses the current of the K channel, independently of its current-carrying function through the Ca channel.     

Effects of the Intracellular Ca Ion Concentration upon the Excitability of the Muscle Fiber Membrane of a Barnacle

The membrane excitability and contraction were examined in single barnacle muscle fibers with different internal Ca⁺⁺ concentrations by using buffer solutions made up with EGTA and Ca-gluconate in various proportions. During the passage of dc currents the membrane shows all-or-none spike potentials for internal Ca⁺⁺ concentrations below about 8 x 10^-8 M, oscillatory potential changes in the range between 8 x 10^-8 to 5 x 10^-7 M, but neither oscillatory nor spike potentials were seen for concentrations above 5 x 10^-7 M. All-or-none spike potentials were suppressed when the internal Mg⁺⁺ concentration exceeded 5 mM. The suppression threshold of the internal Ca⁺⁺ concentration for the Sr spike is much higher than that for the Ca spike. The threshold concentration of internal Ca⁺⁺ for contraction was about 8 x 10^-7 M.     

The ionic requirements for the initiation of action potentials in insect muscle fibers

Electrical properties of locust leg muscle fibers were studied by means of intracellular electrodes. In most fibers, a depolarizing current pulse initiated a local response. A delayed decrease in membrane resistance appeared with more than about 10 mv depolarization. In some fibers a regenerative response also was found. Membrane constants were measured, applying the short cable model. The value of the space constant λ was 1.6 mm and the calculated value of R_m was about 1750 ohm cm². Action potentials could be elicited when the bathing fluid contained more than 2–5 mM Ba or Sr. Similar responses were seen with 2 mM Ca in the presence of tetraethylammonium (TEA). The overshoot of these action potentials increased with increasing [Ca⁺⁺]_o, [Sr⁺⁺]_o, or [Ba⁺⁺]_o, the increment for a 10-fold increase being about 29 mv for Ca and Sr and between 40 and 50 mv for Ba. These action potentials were inhibited by Mn ions but were not affected by tetrodotoxin or procaine. In solutions containing Ba or Sr, action potentials generated were suppressed by addition of Ca. The removal of Na ions did not change the configuration of the action potential. The results suggest that an increase in permeability to Ca, Ba, or Sr ions makes a major contribution to the initiation of action potentials in this tissue.     

An electrogenic sodium pump in Limulus ventral photoreceptor cells

A hyperpolarization can be recorded intracellularly following either a single bright light stimulus or the intracellular injection of Na⁺. This after-hyperpolarization is abolished by bathing in 5 x 10^-6 M strophanthidin or removal of extracellular K⁺. Both treatments also lead to a small, rapid depolarization of the dark-adapted cell. When either treatment is prolonged, light responses can still be elicited, although with repetitive stimuli the responses are slowly and progressively diminished in size. The rate of diminution is greater for higher values of [Ca⁺⁺]_out; with [Ca⁺⁺]_out = 0.1 mM, there is almost no progressive diminution of repetitive responses produced by either K⁺-free seawater or strophanthidin. We propose that an electrogenic Na⁺ pump contributes directly to dark-adapted membrane voltage and also generates the after-hyperpolarizations, but does not directly generate the receptor potential. Inhibition of this pump leads to intracellular accumulation of sodium ions, which in turn leads to an increase in intracellular Ca⁺⁺ (provided there is sufficient extracellular Ca⁺⁺). This increase in intracellular calcium probably accounts for the progressive decrease in the size of the receptor potential seen when the pump is inhibited.     

Bioelectric effects of ions microinjected into the giant axon of Loligo

1. A technique is described for recording the bioelectric activity of the squid giant axon during and following alteration of the internal axonal composition with respect to ions or other substances. 2. Experimental evidence indicates that the technique as described is capable of measuring changes in local bioelectric activity with an accuracy of 10 to 15 per cent or higher. 3. Alterations of the internal K⁺ or Cl^- concentrations do not cause the change in resting potential expected on the basis of a Donnan mechanism. 4. The general effect of microinjection of K⁺ Rb⁺, Na⁺, Li⁺, Ba⁺⁺, Ca⁺⁺, Mg⁺⁺, or Sr⁺⁺ is to cause decrease in spike amplitude, followed by propagation block. 5. The resting potential decreases when the amplitude of the spike becomes low and block is incipient. 6. The decrease in resting potential and spike amplitude may be confined to the immediate vicinity of the injection. 7. At block, the resting potential decreases up to 50 per cent, but injection of small quantities of divalent cations may cause much larger localized depolarization. 8. The blocking effectiveness of K⁺, Na⁺, and Ca⁺⁺ expressed as reciprocals of the relative amounts needed to cause block is approximately 1:5:100. Rb⁺ has the same low effectiveness as does K⁺. Li⁺ resembles Na⁺. Ba⁺⁺ and Mg⁺⁺ are approximately as effective as Ca⁺⁺. 9. Microinjection of Na⁺ may cause marked prolongation of the spike at the injection site as well as decrease in its amplitude. 10. The anions used (Cl^-, HCO₃^-, NO₃^-, SO₄^-, aspartate, and glutamate) do not seem to exert specific effects. 11. A tentative explanation is offered for the insensitivity of the resting potential to changes in the axonal ionic composition. 12. New data are presented on the range of variation, in a large sample, of the magnitude of the resting potential and spike amplitude.     

The role of calcium in excitation-contraction coupling of lobster muscle

Potassium contractures were induced in lobster muscle bundles under conditions which produced varying KCl fluxes into the fibers. The presence or absence of chloride fluxes during depolarization by high concentrations of potassium, had no effect on the tensions developed. The curve relating tension to the membrane potential had a typical sigmoid shape with an apparent "threshold" for tension at -60 mv. Soaking the muscles in low (0.1 mM) calcium salines for 30 min completely eliminated the potassium contractures but the caffeine contractures were only slightly reduced under these conditions. The potassium contracture could be completely restored in less than 2 min by return of the calcium ions to the saline. Evidence is presented for independent, superficial, and deep calcium sites; the superficial sites appear to be involved in the coupling mechanisms associated with potassium contractures. These sites are highly selective for Ca⁺⁺, and attempts to substitute either Cd⁺⁺, Co⁺⁺, Mg⁺⁺, Ba⁺⁺, or Sr⁺⁺ for Ca⁺⁺ were unsuccessful. However, K⁺ appeared to compete with Ca⁺⁺ for these sites, and the evoked tension could be reduced by prestimulation of the muscle fibers with high K⁺ salines. The results of studies on the influx of ⁴⁵Ca during potassium contractures were compatible with the view of muscle activation by the entry of extracellular calcium.     

Membrane permeability changes in amphibian eggs at ovulation

Electropotential differences between the cytoplasm and external medium have been compared in the mature R. pipiens occyte and the ovulated unfertilized egg as a function of [Na]_o, [K]_o, [Ca]_o and [Cl]_o. In solutions containing 1.0 mM Ca⁺⁺ the oocyte behaved as though it were predominantly permeable to K⁺ and Cl^?, i.e., like a KCl electrode. However, the steady potential decreased with decreasing [Ca]_o and in 5 × 10^?4 mM [Ca]_o the oocyte membrane behaved like a NaCl electrode. Studies on the steady potential as a function of [Na]_o, [K]_o and [Cl]_o in 1.0 mM Ca⁺⁺ or Ca-free solutions suggest that Ca⁺⁺ controls the passive permeability of the oocyte membrane to Na⁺ and Cl^?. In the ovulated unfertilized egg the K⁺ selectivity of the cell membrane disappeared and the system behaved like a NaCl electrode. No effect of external Ca⁺⁺ or K⁺ concentration changes on the steady potential was observed. These results indicate that the ion permeability properties of the ovulated egg are similar to that of the ovarian oocyte in Ca-deficient medium, and suggests that the mechanism of ovulation may involve the removal of Ca⁺⁺ regulation of ion permeability of the egg cell membrane.     

Calcium dependent action potentials in skeletal muscle fibres of a beetle larva, Xylotrupes dichotomus

The ionic requirement for generating action potentials in ventral longitudinal muscle fibers dissected from beetle larvae was examined by conventional electrophysiological techniques. Muscle fibers that generated only graded responses in physiological saline were able to generate an all-or-none action potential when the potassium permeability of the membrane was inhibited by tetraethylammonium⁺ added to the saline. The peak of the action potential thus elicited was intimately related to the external Ca⁺⁺ concentration. The action potential was blocked by Co⁺⁺ which is known as a competitive inhibitor of Ca-spikes. Neither tetrodotoxin (3 μM) nor a Na-free condition effectively blocked the generation of the action potential. Mg⁺⁺ induced a shift in the peak of the action potential; this was, however, due to the stabilizing action of Mg⁺⁺ but not due to the penetration of Mg⁺⁺ through the muscle membrane. No action potential was elicited in the muscle fiber when immersed in a Ca-free, EGTA saline even when a high concentration of either Mg⁺⁺, Na⁺, or tetraethylammonium⁺ was present. The action potential of the larval muscle fiber was thus concluded to be a Ca-spike, through the channel of which Na⁺ or Mg⁺⁺ did not penetrate.     

Surface density of calcium ions and calcium spikes in the barnacle muscle fiber membrane

The effects of various divalent cations in the external solution upon the Ca spike of the barnacle muscle fiber membrane were studied using intracellular recording and polarizing techniques. Analysis of the maximum rate of rise of the spike potential indicates that different species of divalent cations bind the same membrane sites competitively with different dissociation constants. The overshoot of the spike potential is determined by the density of Ca (Sr) ions in the membrane sites while the threshold membrane potential for spike initiation depends on the total density of divalent cations. The order of binding among different divalent and trivalent cations is the following: La+++, UO2++ > Zn++, Co++, Fe++ > Mn++ > Ni++ > Ca++ > Mg++, Sr++.     

Electrical and Mechanical Responses in Deep Abdominal Extensor Muscles of Crayfish and Lobster

Electrical and mechanical studies have been made of the deep abdominal extensor muscles, medial (DEAM) and lateral (DEAL), of crayfish and lobster. The medial muscle responds to direct (intracellular) and indirect stimulation with a transient membrane depolarization which exhibits the properties of a propagated non-decremental action potential but does not overshoot the zero level. The amplitude is about 30 mv in crayfish and 50 mv in lobster. It is followed by a fast all-or-none twitch whose duration at 20°C is 30 to 50 msec. and whose developed tension is 500 gm/cm² or about half the tetanic value. Membrane potential is K⁺-dependent and immersion in high K⁺ induces a brief transient tension rise as in other twitch-type muscles. The action potential and twitch are normal even if all external Na⁺ is replaced with sucrose but vary with external Ca⁺⁺, the action potential increasing 8 to 10 mv for a twofold increase in Ca⁺⁺. The lateral muscle (DEAL) is much slower and responds to intracellular stimulation only with an electrotonic or a local response. Mechanical responses and relaxation speeds are slow with minimal duration of contraction of 0.5 to 2 seconds. Immersion in high K solutions induces large maintained tensions. Sarcomere length in the fast DEAM is uniform and about 2 µ at rest, but in the DEAL speed is less and sarcomere length is greater averaging about 4.5 µ but with a mixed population of fibers.     

Theoretical description of the calcium channel in rat spinal ganglion neurons

The surface charge density (σ′₀) and the binding constant of Ca⁺⁺ with charged groups on the outer surface of the membrane (K_Ca) were calculated from experimentally determined values of the shift of the current-voltage characteristic curves of calcium currents in the membrane of rat spinal ganglion neurons: σ′₀ = 0.15 ± 0.05 e/nm² and K_Ca = 70 ± 10 liters/mole. Using a three-barrier model the energy profile of the calcium channel of the membrane of these neurons was calculated for Ca⁺⁺, Ba⁺⁺, Cd⁺⁺, Mn⁺⁺, Co⁺⁺, and verapamil. The calcium current was shown to be determined mainly by the depth of the potential hole corresponding to the outer binding site of the calcium channel. It is concluded from the results that the outer binding site of the calcium channel contains only one carboxyl group.     

The effects of intracellular iontophoretic injection of calcium and sodium ions on the light response of Limulus ventral photoreceptors

During intracellular iontophoretic injection of Ca⁺⁺ into Limulus ventral photoreceptor cells, there is a progressive diminution of the light response. Following Ca⁺⁺ injection, the size of the light response slowly recovers. Similarly, there is a progressive diminution of the light response during intracellular injection of Na⁺ and recovery after the injection is stopped. The rate of diminution during Na⁺ injection is greater for higher [Ca⁺⁺]_out. In solutions which contain 0.1 mM Ca⁺⁺, there is nearly no progressive decrease in the size of the light response during Na⁺ injection. Intracellular injections of Li⁺ or K⁺ do not progressively decrease the size of the light response. We propose that an increase in [Na⁺]_in leads to an increase in [Ca⁺⁺]_in and that an increase in [Ca⁺⁺]_in by any means leads to a reduction in responsiveness to light.     

Muscle Contraction during Hyperpolarizing Currents in the Crab

Isolated muscle fibers from the motor legs of the crab Trichodactilus dilocarcinus were submitted to strong hyperpolarizing currents of varied intensities which produced tension during the current pulse. Threshold for tension was obtained with intensities of about 0.2 x 10^–5 A, changing E_m to ca. –150 mV (starting from a resting potential ofca. –80 mV). At the closure of the anodic square pulse, a second phase of tension usually appeared superimposed upon the one obtained during hyperpolarization. The first phase of tension increased with the increase of Ca⁺⁺ concentration in the bath. Sr⁺⁺ produced the same type of mechanical output as Ca⁺⁺. When added to the normal Ca⁺⁺ concentration, Ba⁺⁺ and Mn⁺⁺ in low concentrations (up to 21.5 mM) also increased the tension of this phase, but at higher concentrations they blocked both phases while Mg⁺⁺ did not alter the tension. Of all the divalent cations employed, only Sr⁺⁺ is capable of developing tension as a substitute for Ca⁺⁺ in the external media. Procaine administered in a dosage (5 x 10^–3 W/V)which would suppress the contracture due to caffeine (10 mM), did not modify the tension developed during the hyperpolarization. The preceding data indicate that the Ca⁺⁺ required for tension during hyperpolarization comes from sites which would differ from those usually postulated for tension due to depolarization in the muscle fibers of other crustaceans (American crayfish). Furthermore, the external source of Ca⁺⁺ appears to be one mainly implicated in the induction of tension due to inward current pulses.     

Barium modifies the concentration dependence of active potassium transport by insect midgut

Summary The rate of active K⁺ transport by the isolated lepidopteran midgut shows a rectangular hyperbolic relation to [K⁺] over the range 20 to 70mm K⁺ in the absence of any divalent cation. Addition of Ba⁺⁺ to the hemolymph (K⁺ uptake) side introduces a linear component to the concentration dependence, such that active K^– transport is decreased at [K⁺] of 55mm or less, but increased transiently at higher [K⁺]. As [Ba⁺⁺] is increased over the range 2 to 8mm the linear component increases and the saturating component decreases; in 8mm Ba⁺⁺ the concentration dependence is dominated by the linear component. The effect of Ba⁺⁺ cannot easily be accounted for by simple competition with K⁺ for basal membrane uptake sites. Similar effects might be exercised by other alkali earth cations, since the concentration dependence of active K⁺ transport possesses a substantial linear component in solutions containing 5mm Ca⁺⁺ and 5mm Mg⁺⁺ (the alkali earth metal concentrations of standard lepidopteran saline).     

Triple helix formation and disulphide bonding during the biosynthesis of glomerular basement membrane collagen.

White erythrocyte membranes, or ghosts, were monoconcave discocytes when incubated in 50mM N-tris (hydroxymethyl) methyl-2-aminoethane sulfonic acid titrated to pH 7.4 with triethanolamine. If 3mM MgCl₂ was included in the incubation medium, the ghosts were predominantly echinocytes. The echinocytic form could also be induced by Co⁺⁺, Ni⁺⁺, Li⁺, Na⁺, K⁺, $\text{NH}{}_4{}^{\mathrm{+}}$ and tetramethylammonium ion, all as chloride salts. The concentration of cation necessary for 50% of the ghosts to be echinocytes was correlated with the hydrated charge density of the cation with the most highly charged cations being the most effective. The cations Ca⁺⁺, Sr⁺⁺, Ba⁺⁺ and La⁺⁺⁺, (also as chloride salts) did not induce the normal echinocytic form, but at high levels induced a few misshapen forms with some resemblance to echinocytes. Instead Ca⁺⁺, Sr⁺⁺, Ba⁺⁺ and La⁺⁺⁺ suppressed the formation of echinocytes in the presence of Mg⁺⁺ and other ions. This suggests the presence of a specific Ca⁺⁺ binding site important to shape control in the erythrocyte membrane.     

Cationic inhibition of Ca current and Ca-dependent ciliary responses in Paramecium

The Paramecium cell membrane was voltage-clamped under K current suppression conditions. Ciliary beating was registered using high-speed video microscopy. Depolarizing step pulses activated a transient inward current and induced reversed ciliary beating. Very strong positive steps inhibited ciliary reversal during the pulse suggesting inhibition of the Ca influx. We call the potential, which is sufficiently positive to induce transition from reversed to normal ciliary beating, the transition potential. The transition potential rose with increasing external Ca²⁺ showing saturation beyond 1 mM Ca²⁺. Addition of Mg²⁺, Ba²⁺ or K⁺ to the 1 mM Ca²⁺ bathing solution depressed the transition potential in a concentration-dependent manner. The depolarization-activated inward Ca current increased with rising external Ca concentration, and addition of either Mg²⁺, Ba²⁺ or K²⁺ diminished the inward Ca current. The diverging results of Ca²⁺-dependent positive shifts, and Mg²⁺-(Ba²⁺-, K⁺-) dependent negative shifts in transition potential are compared with shifts of V_Imax. It is concluded that external cations bind competitively — in addition to membrane surface charges — to affinity sites of Ca channel, where they specifically modulate permeation of calcium.