The ionic regulation of action potentials in the axon of a stretch receptor neuron of the stick insect (Carausius morosus)

Summary The ionic requirements for the action potentials recorded from the axon of the dorsal longitudinal stretch receptor inCarausius morosus have been studied using extracellular electrodes.In the intact preparation prolonged exposure to sodium-free, calcium-free, or magnesium-free salines produces no observable change in the amplitude of action potentials. Similarly, tetrodotoxin (1×10^–6 M) and cobaltous chloride (1×10^–2 M) are both ineffective in blocking the action potentials.In preparations in which the ionic barrier has been disrupted by removal of the nerve sheath the action potentials show sodium dependence. They are sustained in high sodium salines (150 mM) but are reversibly abolished in sodium-free salines. They are also reversibly abolished in 1×10^–6 M TTX, but unaffected by calcium-free or magnesium-free salines, or by cobaltous chloride (1×10^–2 M).It is concluded that the action currents in the axon of the stretch receptor are carried by sodium ions.     

Extrasynaptic action of vasopressin,oxytocin, and vasotocin neuropeptides on electrically operated ionic channels at the mollusk neuronal membrane

Techniques of intracellular dialysis and neuronal perfusion in the visceral ganglion ofLymnaea stagnalis used during voltage-clamping at the neuronal membrane helped to ascertain that a concentration of 1×10^–16–1×10^–6 M neuroactive peptides (vasopressin, oxytocin, and vasotocin) alter the amplitude of electrically-operated transmembrane ionic currents considerably without affecting the kinetics of current activation and inactivation and surface potential at the membrane. The experimental conditions applying made it possible to record incoming sodium and calcium currents separated from each other as well as outward delayed and transient potassium currents. It was found that electrically-operated cerebral currents could either increase or decline in amplitude under the effects of peptides applied at different concentrations to the membrane of the same unit. Receptors of the peptides investigated in this study are thought to be located within the structure of electrically-operated channels at the neuronal membrane.A. I. Gertsen Teaching Institute, Leningrad. Translated from Neirofiziologiya, Vol. 22, No. 4, pp. 526–533, July–August, 1990.     

Interaction between pentobarbital and GABA-activated ionic channels in rat cerebellar neurons

Using techniques of voltage clamping at the membrane, intracellular perfusion, and concentration clamping, GABA- and barbiturate-activated currents were investigated in single neurons isolated from the rat cerebellum. The dissociation constant for interaction between GABA and GABA receptors was measured at 3±0.8 × 10^–5 M. The presence of pentobarbital in the bathing solution exerts a potentiating effect on GABA-induced conductance in isolated neurons, shifting the dose-response curve for GABA towards lower concentration values without increasing peak chloride conductance. The concentrations at which GABA effects are potentiated range between 10^–6–10^–4 M. High concentrations of pentobarbital inhibit GABA-activated conductance; at concentrations in excess of 5 × 10^–4 M, it also brings about activation of chloride conductance, depressed by bicuculline and picrotoxin, in the absence of GABA. A short-term increase in membrane conductance is produced by rapid pentobarbital washout.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 22, No. 1, pp. 93–98, January–February, 1990.     

Argiopine,argiopinines, and pseudoargiopinines as glutamate receptor blockers in hippocampal neurons

A homologous set of low-molecular weight compounds selectively blocking ionic currents were purified from venom from the spiderArgiope lobata with a selective blocking action on ionic currents activated by applying glutamate and its agonist kainic acid (KA) to the membrane of neurons isolated from the rat hippocampus. Three groups of these compounds — argiopine, argiopinines, and pseudoargiopinines, produced voltage-dependent glutamate- and KA-activated ionic currents at concentrations of 10^–6-10^–4 M, interacting primarily with agonist-activated ionic channels without affecting K_d values of the agonist. The blocking action could be partially reversed by argiopine application but only slightly when argiopinines and pseudoargiopinines were used. Kinetics of toxin effects on Ka-activated ionic currents showed at least two exponential components with different time constants. Simple and reversed rate constants of interaction between toxins and ionic channels were estimated from the plot of the kinetics of ionic current blockade and recovery against toxin concentration. Argiopine, argiopinines, and pseudoargiopinines lend themselves to further research into glutamate receptors of the mammalian CNS employing electrophysiological and biochemical techniques.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev, M. M. Shemyakin Institute of Bioorganic Chemistry, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 21, No. 6, pp. 748–756, November–December, 1989.     

Depolarization of the neuronal membrane caused by Co-transport of taurine and sodium

C 1300 neuroblastoma cells were cultured and used to study the effect of sodium dependent taurine transport on the membrane potential. Measuring net accumulation of taurine and the depolarization caused by externally applied taurine, we found both processes become active at an external concentration of taurine of 1 mM or more. Net accumulation had K_m of 13 mM and a V_max of 126 nmol × mg of protein^–1×min^–1. The taurine induced depolarization of the neuroblastoma cell was parallelled by a 25 per cent decrease in its membrane impedance. The transport of taurine, the depolarization caused by taurine and the effect of taurine on the membrane impedance, all, had a similar dependence on the external sodium concentration. Our results on the depolarizing cotransport between taurine and sodium at the neuronal membrane, may illustrate an additional mechanism for the control of the electrical activity of neuronal cells.     

Inhibitory effects of GABA on synaptic excitation in isolated rat hippocampal slices

In research on -aminobutyric acid (GABA) used at different concentrations on the amplitude of EPSP within populations (PEPSP), as recorded from dentrites in isolated hippocampal slices, GABA induced a dose-dependent reversible reduction in PEPSP amplitude with no noticeable signs of desensitization. Highest sensitivity to GABA was shown by PEPSP in hippocampal zone CA1 (threshold concentration: 3×10^–5–2×10^–4 M; (concentration at which the effect equal to 1/2 of maximum occurs) IC₅₀: 5×10^–4–1×10^–3 M). The effects of GABA on PEPSP were not blocked by bicuculline, picrotoxin, or penicillin. Action of GABA on dendritic antidromic population spike (DAPS — postynaptic effects) were slightly diminished by these blockers. Baclofen inhibited PEPSP more powerfully than GABA (threshold concentration: 1×10^–6 M: IC₅₀: 3×10^–6 M), although it only produced a minor reduction in DAPS amplitude even at high concentrations. It is concluded that the inhibitory effect of GABA on PEPSP in hippocampal zone CA1 may be put down mainly to its presynaptic action mediated by GABA_B receptors on axonal terminals of Schaffer collaterals.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 22, No. 5, pp. 627–633, September–October, 1990.     

Quinidine blocking of sodium and potassium channels in myelinated nerve fibers

Experiments by the voltage clamp method showed that external application of quinidine (5 × 10^–5 M) to the Ranvier node membrane of the frog nerve fiber inhibitis both sodium and potassium currents. Blocking of the sodium current is considerably intensified by repetitive depolarization of the membrane (1–10 Hz); the rate of development of the block increases with an increase in stimulation frequency. After the end of stimulation the sodium current gradually returns to its initial level (with a time constant of the order of 30 sec at 12°C). Unlike repetitive depolarization with short (5 msec) stimuli, a prolonged shift (1 sec) of potential toward depolarization has no significant effect on quinidine blocking of the sodium current. Analysis of the current-voltage characteristic curves showed that quinidine blocks outward sodium current more strongly than inward. Batrachotoxin protects sodium channels against the blocking action of quinidine in a concentration of 10^–5 M. Inhibition of the outward potassium currents by quinidine is distinctly time-dependent in character: Initially the potassium current rises to a maximum, then falls steadily to a new stationary level. The results agree with the view that quinidine, applied externally, penetrates through the membrane in the basic form and blocks open sodium and potassium channels from within in the charged (protonated) form. The similarity in principle between the action of quinidine and local anesthetics on the sodium suggests that these compounds bind with the same receptor, located in the inner mouth of the sodium channel.A. V. Vishnevskii Institute of Surgery, Academy of Medical Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 14, No. 3, pp. 324–330, May–June, 1982.     

Interaction between sea anemone toxin BgTX8 and ionic channels of neurons isolated from mammals

The action of the toxin BgTX₈ separated from the sea actiniaBunodosoma granolifera on transient tetrodotoxin-sensitive sodium and outward potassium currents of units isolated from rat sensory ganglia was investigated using techniques of voltage clamping at the membrane and intracellular perfusion. It was found that BgTX₈ decelerates the inactivation kinetics but has little effect on activation kinetics of sodium current. At the same time, a 5–10% increase in the amplitude of inward current was often observed at holding potentials of about –100 to –120 mV at the membrane. The dissociation constant of the receptor-toxin equals 4×10^–6 M and is adequately described by Langmuir's isotherm. It was also established that intracellular perfusion of neurons with anemone toxin-containing solution leads to a reduction in the amplitude of sodium current and decelerates its inactivation process. Suppression of outward potassium current was also noted.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Institute of Brain Research, Academy of Sciences, Havana, Cuba. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 32–37, January–February, 1988.     

Action of thiamine on auditory evoked potentials in the guinea pig

A technique is proposed for quantifying the effects of physiologically active substances at the periphery of the auditory analyzer. It was found that applying 1×10^–11 to 1×10^–3 M thiamine to the membrane of guinea pig cochlear round window (fenestra rotunda) produces a rise in the amplitude and a reduction in the latency of the N₁ and N₂ components of auditory nerve action potentials, waves I and II of brainstem auditory evoked potentials occurring in response to an acoustic stimulus. It is suggested that this effect is produced by facilitated synaptic transmission at synapses between hair cells and spiral ganglia neurons under the action of thiamine penetrating into the cochlea.A. V. Palladin Institute of Biochemistry, Academy of Sciences of the Ukrainian SSR, Kiev. A. I. Kolomiichenko Research Institute of Otolaryngology, Ministry of Public Health of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 654–660, September–October, 1986.     

Blocking action of Nephila clavata spider toxin on ionic currents activated by glutamate and its agonists in isolated hippocampal neurons

The blocking action ofNephila clavata spider neurotoxin, or JSTX, on ionic currents activated by L-glutamate and its agonists when applied to the membrane of neurons isolated from the rat hippocampus was investigated using a concentration clamp technique. Crude JSTX venom was found to block L-glutamate-, quisqualate, and kainate-activated ionic currents induced by activating non-N-methyl-D-aspartate (non-NMDA) membrane receptors. Following the effects of JSTX, ionic currents activated by L-glutamate and its agonists declined to 34–36% of their initial value with no recovery during JSTX washout. An active fraction of JSTX at concentrations of 10^–4–10^–5 produced almost total but partially reversible blockade of ionic currents. The action of JSTX became less effective during depolarization. The concentration dependence of JSTX-induced blockade of kainate-activated ionic currents was investigated and the velocity constants of interaction between the toxin and glutamate receptors obtained. It is postulated that JSTX interacts with chemically-operated non-NMDA ionic channels, blocking their transition into a number of their possible open states.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 21, No. 2, pp. 152–160, March–April, 1989.     

Dynamics of chloride and potassium currents during the action potential in Chara studied with action potential clamp

TheCl^– and K⁺ currents underlying the action potential (AP) in the giant alga Chara were directly recorded with the action potential clamp method. An electrically triggered action potential was recorded and repetitively replayed as command voltage to the same cell under voltage clamp. The resulting clamp current was close to zero. Only the initial rectangular current used for stimulation was approximately reproduced by the clamp circuit. Inhibition of Cl^– channels with niflumic acid or ethacrynic acid and of K⁺ channels with Ba²⁺ evoked characteristic compensation currents because the amplifier had to add the selectively inhibited currents. Integration of the compensation currents revealed a mean flux through Cl^– and K⁺ channels of 3.3 10^–6 and 2.1 10^–6 mole M^–2 AP^–1 respectively. The dynamics of CI^– and K⁺ channel activation/inactivation were obtained by converting the relevant clamp currents to ionic permeabilities using the Goldman-Hodgkin-Katz current equation. During the AP the Cl^– permeability reaches a peak 370 ms, on average, after termination of the stimulating pulse. The following inactivation proceeds 3.6 times slower than the activation. The increase in K⁺ permeability lags behind the rise in Cl^– permeability, reaching a peak approximately 2 s after the latter.     

Effects of low concentrations of tetradotoxin on rat trigeminal ganglion neurons

Voltage clamping and intracellular perfusion methods were used to investigate ionic currents produced by depolarizing shifts of –120 mV from holding potential during experiments on neurons isolated from the trigeminial ganglion of one-month-old rats. It was found that tetradotoxin at low (external) concentrations of 10^–12–10¹⁰ M produced an increase in the amplitude and alternations in the kinetics of inward ionic currents. Similar effects were observed in 8 test cells out of 29. The extent to which the increase in the amplitude of inward ionic currents depended on concentration level could be described by Langmuir's isotherm, with a dissociation constant of the order of 5·10^–12 M. No such tetrodotoxin effects were observed when chloride ions were replaced by a non-penetrating anion in the intracellular solution. It is suggested that tetrodotoxin-sensitive channels exist in the neuronal membrane of the rat trigeminal ganglion, letting through chloride ions during depolarization of the membrane.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 6, pp. 723–729, November–December, 1986.     

Taurine- and FMRFamide-dependent modulation of receptor- and voltage-gated currents by cerebrolysine in molluscan neurons

The action of cerebrolysine, a biogenic stimulator, on the receptor- and voltage-gated ionic currents was studied in identifiedHelix pomatia neurons. Cerebrolysine reversibly suppressed the acetylcholine (ACh)- and glutamate (GLU)-induced chloride currents in some neurons (LP11, B4, E12) with a latency of 9±3 sec, while not affecting these currents in other neurons. The suppressing effect of cerebrolysine on the voltage-gated sodium and calcium currents was also selective. There were fast and slow phases, with latencies of 52±8 sec and 5±1 min, respectively, in the cerebrolysine effect on the voltage-gated sodium current. The effect of cerebrolysine on the sodium current during the fast suppression phase could be simulated with FMRFamide (10^–5 M), while those exerted on the ACh- and GLU-induced currents could be simulated with taurine (10^–6 M). The effects of cerebrolysine and the above substances were non-additive. These facts allow us to suggest that both taurine and FMRFamide (or its fragment) are involved in the mechanism of posttraumatic and postsurgical curative effects of cerebrolysine.Neirofiziologiya/Neurophysiology, Vol. 26, No. 3, pp. 190–196, May–June, 1994.     

Action of thiamine on different synapses

Thiamine at a concentration of 1×10^–14 to 1×10^–4 M facilitated neuromuscular transmission at the glutaminergic synapse of the crayfish adapter, manifesting as increased amplitude and quantal content of excitatory postsynaptic potentials and raised frequency of miniature excitatory postsynaptic potentials. Thiamine augmented spontaneous electrical activity and the amplitude of synaptic potentials in the longitudinal muscle of guinea pig taenia coli. It was found from studying the effects of thiamine on the membrane potential of rat brain synaptosomes that its presynaptic action is brought about by depolarization of the nerve terminal membrane. Interaction between thiamine and the nerve endings was described by a Hill coefficient of 0.22–0.30, indicating that it has several binding sites within the structure of the receptor concerned.A. V. Palladin Institute of Biochemistry, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 18, No. 5, pp. 621–629, September–October, 1986.     

Effects of quinine on calcium current in mollusk neurons

The effects of quinine on the peak amplitude and the decay of calcium currents (I_Ca) were investigated in nonidentified neurons isolated fromHelix pomatia. A concentration of 1×10^–5–5×10^–4 M quinine was found to produce a reversible dose-dependent deceleration in the decline of I_Ca ("lead" effect) and a reversible, slowly evolving dose-dependent reduction in I_Ca amplitude ("lag" effect). A reduction in amplitude down to half control level is observed at a quinine concentration of 6 ×10^–5 M, while the current-voltage relationship of I_Ca shifts by 5–10 mV towards negative potentials. Results show that quinine successfully blocks calcium channels inHelix pomatia neurons.Institute of Brain Research, All-Union Mental Health Research Center, Academy of Sciences of the USSR, Moscow. Translated from Neirofiziologiya, Vol. 19, No. 3, pp. 413–417, May–June, 1987.     

Effect of vanadate on brain protein phosphorylation

The effect of vanadate on the phosphorylation of synaptosomal membrane proteins prepared from rat cerebral cortex was studied. Vanadate concentrations of 10^–6, 10^–5, and 10^–4 M increased the endogenous phosphorylation activity by 25%, 37%, and 75%, respectively. Increasing the ATP concentration in the assay medium from 50 to 500 M did not influence the above effect. A commercial preparation of the purified protein kinase was stimulated 40% by 10^–3 M vanadate. Calcium-calmodulin dependent activity was stimulated only 20% by 10^–5 M vanadate. The effect was not enhanced by further increasing vanadate concentration. Addition of calcium ions (above 50 M) suppressed the vanadate effect, while an inhibition was observed at high Ca²⁺ concentration (2.5 mM). Below 50 M calcium ions stimulated phosphorylation activity in the absence of vanadate and did not affect the stimulatory action of vanadate. Cyclic AMP-dependent endogenous phosphorylation was also stimulated by vanadate. Activation by cAMP could not be observed at vanadate concentrations above 10^–6 M. Possible mechanisms of the vanadate effect are discussed.     

Ionic mechanisms underlying modulating effects of serotonin on acetylcholine-induced responses in Helix pomatia neurons

The ionic mechanisms underlying modulatory effects of serotonin on acetylcholine-response in identified and nonidentifiedHelix pomatia neurons were investigated using voltage-clamping techniques at the neuronal membrane. External application of 10^–5–10^–4 M serotonin to the membrane of neurons responding to application of acetylcholine depending on Na⁺ depolarization (D_Na response) reduced membrane conductivity during response to acetylcholine without changing reversal potential of acetylcholine-induced current. Acetylcholine (10^–6–10^–4 M) administration took place 1–3 min later. Neurons with response to acetylcholine application dependent on Cl⁺ depolarization (D_Cl response) or hyperpolarization (H_Cl response) behaved similarly. Analogous effects could be produced by external application of theophylline which, together with the latency and residual effect characteristic of serotonin action points to the participation of intracellular processes associated with the cellular cyclase system in the changes produced by serotonin in acetylcholineinduced response. Serotonin brought about a shift in reversal potential and an increase in the acetylcholine-induced current in those neurons where this response was associated with changed permeability at the membrane to certain types of ions. During two-stage acetylcholine-induced response of the D_Na-H_K type, serotonin inhibited the inward current stage. Mechanisms underlying modulatory serotonin action on acetylcholine-induced response in test neurons are discussed in the light of our findings.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 1, pp. 57–64, January–February, 1988.     

Acetylcholine activates a chloride channel as well as glutamate and GABA

Summary In conventional two microelectrode experiments, acetylcholine had qualitatively the same effect as GABA and glutamate on membrane potential and input resistance of muscle fibres of the opener and intrinsic stomach muscles of crayfish (Austropotamobius torrentium). In patch-clamp experiments, acetylcholine occasionally elicited single channel openings in cell-attached patches on these muscles. If outside-out patches were excised and the Cl^– concentration was high on both sides of the membrane, acetylcholine at concentrations of 1 nM regularly elicited single channel currents. The amplitude of single channel currents depended strongly on the intracellular concentration of Cl^–. The reversal potential of the channel, determined after replacing intracellular K⁺ with Cs⁺, corresponded to the Nernst potential for Cl^–. The voltage dependence and the reversal potential of single channel current amplitudes elicited by ACh, glutamate and GABA were identical. The distribution of life times of openings (>1 ms) elicited by ACh and glutamate could be fitted by a single exponential with a time constant of about 2.5 ms, corresponding to the mean open time. ACh and glutamate applied to the same outside-out patch showed cross-desensitization, and thus ACh and glutamate activate the same channels. An excitatory, cationic ACh-activated channel could not be identified. Permeabilities of the chloride channel were calculated according to the Goldman-Hodgkin-Katz equation at different membrane potentials. Negative single channel current amplitudes (inward currents) could be fitted with a permeability of ₂= 3.9×10^–14 cm³s^–1. For positive currents (outward) the channel had a permeability of ₁= 1.4× 10^–14 cm³s^–1. The permeability of the channel declined from 16×10^–14 cm³s^–1 to 2.3×10^–14 cm³s^–1 if the intracellular Cl^–-concentration was raised from 6 to 257 mM. The activation elicited by acetylcholine was inhibited by extracellular Ca⁺⁺. The mean current activated by ACh was reduced by a factor of 50 if the extracellular concentration of Ca⁺⁺ was raised from 0.1 mM to the physiological concentration of 13.5 mM.     

Ca binding to the human red cell membrane: Characterization of membrane preparations and binding sites

Summary Inside out and right side out vesicles were used to study the sidedness of Ca binding to the human red cell membrane. It was shown that these vesicles exhibited only a limited permeability to Ca, enabling the independent characterization of Ca binding to the extracellular and cytoplasmic membrane surfaces. Ca binding was studied in 10 mM Tris HCl at pH 7.4, 22±2°C and was shown to be complete in under 5 min. Scatchard plots were made from Ca binding data obtained at free Ca concentrations in the range of 10^–6 to 10^–3M. Under these conditions inside out vesicles exhibit two independent binding sites for Ca with association constants of 1×10⁵ and 6×10³ M^–1, and right side out vesicles exhibit three independent binding sites with association constants of 2×10⁵, 1.4×10⁴ and 3×10²M^–1. Upon the addition of 0.1M KCl a third, high affinity site was found on inside out vesicles with an association constant of 3×10⁵, (in 0.1 M KCl). Ca binding to inside out vesicles increased nearly linearly with pH in the, range of pH 4 to pH 11, while binding to right side out vesicles remained practically unchanged in the range of pH 7 to pH 9. Progressive increase of the ionic strength of the medium by the addition of K, Mg or Tris decreased Ca binding to inside out vesicles as did the addition of ATP. Comparison of a series of cation competitors for Ca binding sites on inside out vesicles at 0.003 mM Ca showed that La was the most effective competitor of all while Cd was the most effective divalent cation competitor of those tested. Our findings suggest that the effects of low concentrations of Ca at the inner surface of the red cell membrane are mediated primarily through Ca binding to site 1 (and, possibly site 2) of inside out vesicles of which there are approximately 1.6×10⁵ per equivalent cell.     

Chronic and endogenous regulation of insulin receptors by catecholamines in adipocytes from patients with a phaeochromocytoma

Insulin binding in adipocytes from patients with a phaeochromocytoma (PH) approached that of the controls (C) at low and higher concentrations of unlabeled insulin. The apparent receptor affinity was unchanged (ED50: PH 0.50×10^–9M and C0.60×10^–9M). Scatchard analysis of the binding data using the negative cooperative model revealed a 46% decrease in the total number of receptors together with no changes in both K^–e (PH 0.55×10⁹M^–1 and C 0.36×10⁹M^–1) and K^–f (PH 0.13×10⁹ M^–1 and C 0.07×10⁹ M^–1). According to the two site model, an altered proportion in the two classes of insulin binding sites was detected. This was accompanied by a catecholamine-desensitization of the adipocytes to the antilipolytic action of insulin. These events could represent a final situation of a chronic and endogeneous regulation by high levels of catecholamines of insulin receptors in human adipose tissue.