Properties of GABA-induced transmembrane currents in isolated neurons of the rat spinal ganglia

Using techniques of voltage-clamp in the whole-cell configuration and fast local superfusion, we studied the properties of transmembrane ion currents evoked in freshly isolated neurons of the spinal ganglia of rats by application of γ-aminobutyric acid, GABA, in different concentrations. Increases in the GABA concentration and application time resulted in modification of the amplitude and kinetic parameters of the currents. The dependence between the current amplitude and GABA concentration could be adequately described by the Hill equation. The current rise could be fitted by a sum of two exponential curves with different time constants; the time constant of the second exponent changed with an increase in the GABA concentration, while the first exponent was not sensitive to these changes. The current decay also should be fitted by two exponents. The time constant of the first exponent did not change with increases in the GABA concentration or duration of its application; at the same time the second exponent noticeably depended on the time of GABA application. Our experiments demonstrated that the density of GABA-activated ion channels in the membranes of the studied spinal ganglion cells is relatively high; this finding allows us to suppose possible involvement of these channels in regulation of the transmembrane conductivity in these cells.     

Effects of vasopressin on the somatic membrane of spinal ganglia neurons

Intracellular recording from the soma of 68 sensory neurons was performed during experiments on perfused cerebrospinal ganglia (CSG) isolated from 22- to 36-day-old rats. Application of vasopressin (VP) to the CSG produced a response in 59 cells (or 87.76%). Depolarization was noted in 67.8% of those responding, two-stage response in 16.95%, and hyperpolarization in 15.25%. All responses were dose-dependent and reversible. Membrane resistance (R_m) following depolarization declined but increased following hyperpolarization. Application of VP produced a lengthening of action potentials (AP) and a decline both in AP amplitude and after-hyperpolarization. A correlation was revealed between the biophysical properties of CSG neurons and the pattern of their response to VP. Neurons with a slow velocity of axonal conductance, protracted AP, and high R_m (small cells) had the lowest sensitivity threshold to VP at a concentration of 1·10^–11 M and responded with prolonged high-amplitude depolarizing potentials. Cells with a high velocity of axonal conductance, short-lasting AP, and low R_m responded to VP at a concentration of 1·10^–8 M, although response was occasionally lacking even at a concentration of 1·10^–6 M. Depolarization was more short-lived in these neurons and characterized by lower amplitude; cases of hyperpolarization were sometimes observed. Findings from our study would indicate that VP exerts an effect on the soma or primary sensory neurons, acting preferentially on small CSG cells.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 6, pp. 801–808, November–December, 1988.     

Mutual modulating effects of serotonin and dopamine on neurons of rat spinal ganglia

It was established in experiments on isolated rat spinal ganglia that the introduction of dopoamine (0.01–1.0 µM) into a superfusate potentiates the depolarizing responses of the neurons evoked by the action of serotonin, which is delivered from a micropipette under pressure, while the addition of serotonin in the same concentrations potentiates the depolarizing responses of the neurons evoked by the action of dopamine. The mutual potentiation of the effects of dopamine and serotonin depends on the concentration of the monoamines and is eliminated by blockers of the D₁- (but not D₂-dopamine) and type 2 serotonin (but not IA) receptors. The mutual potentiation of the effects of monoamines is of a postsynaptic nature and is associated with a change in the intracellular concentration of second messengers (Ca²⁺ and cAMP).A. M. Gor'kii Donetsk Medical Institute, Ministry of Health of the Ukrainian SSR. Translated from Neirofiziologiya, Vol. 23, No. 2, pp. 168–173, March–April, 1991.     

Two different tetrodotoxin-separable inward sodium currents in the membrane of isolated cardiomyocytes

Isolated ventricular myocytes of 3 to 5 weeks old rats were studied under conditions of intracellular perfusion and voltage clamp. The existence of two inward sodium currents with different TTX-sensitivities and different properties was shown. The fast sodium current was more sensitive to TTX (Kd about 8 X 10(-8) mol/l). The block of the slow sodium current by TTX was less specific (Kd about 7 X 10(-6) mol/l). There was an about four fold difference in the inactivation time constants between these currents. The maximum on the I-V curve of the slow sodium current was shifted along the voltage axis by about 15 mV in the positive direction as compared with that of the fast sodium current. A slow current carried by calcium ions was observed in sodium-free solution. The kinetics and TTX-sensitivity of this current were similar to those of the slow sodium current. The amplitude of this current was 15 to 20 times lower as compared with the slow sodium current observed in Na-containing solution with 10(-6) mol/l TTX (a concentration which completely blocked the fast sodium current). It is suggested that the slow voltage-gated TTX-sensitive channels described are not highly selective and pass both sodium and calcium ions.     

Action of neurotoxin from the sea anemoneHomostichanthus duerdemi on inward sodium current in mammalian neurons

The action of purified toxin from the sea anemoneHomostichanthus duerdemi (HTX-1) on the inward sodium current was studied in experiments on isolated neurons from rat spinal ganglia and neuroblastoma cells of clone N-18F1, by an intracellular perfusion and voltage clamp method. HTX-1 was found to delay inactivation of the tetrodotoxin-(TTX-)sensitive inward sodium current and to make it incomplete, but virtually without affecting its activation. The relationship between the fraction of sodium channels modified by the toxin and the HTX-1 concentration is described by a Langmuir isotherm with association constant of (1.1 ± 0.1)·10^–7 M (holding potential –100 mV). Under the influence of the toxin the peak inward sodium current was increased by about 80%. Binding of HTX-1 with TTX-sensitive sodium channels is distinguished by strong potential-dependence: at a holding membrane potential of 0 mV the binding constant was an order of magnitude less than at a potential of –100 mV. In the case of brief action of HTX-1 on the nerve cell membrane (under 5 min) the effect of the toxin was completely reversible, but if the time of action of HTX-1 exceeded 30 min, subsequent washing with normal solution for 90 min did not abolish the effect completely.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Pacific Institute of Bioorganic Chemistry, Far Eastern Scientific Center, Academy of Sciences of the USSR, Vladivostok. Translated from Neirofiziologiya, Vol. 14, No. 4, pp. 402–409, July–August, 1982.     

Single calcium channels in neurons of rat spinal ganglia

Using a refined patch clamp technique, a study was made of single calcium channels of spinal ganglia neurons on a cell-attached membrane site in newborn rats; these convey the basic (high threshold) component of calcium current. Findings show that currents carried by calcium ions at a concentration of 60 mM in the recording pipet changes from 0.58±0.05 to 0.43±0.05 pA with a change in potential of 20 mV. This corresponds to a channel conductance of 7±0.5 pS. The distribution of open time was monoexponential with a time constant of about 0.75 msec, independent of membrane potential. Distribution of closed time approached a biexponential time course. The fast component (0.8 msec) was voltage-dependent, while the slow component decreased from 22 to 4 msec when depolarization increased by 20 mV. Using experimentally obtained time parameters which describe single calcium channel function, and assuming a three-tier model of the channel, the numerical values of the constants of transition rates between individual states were determined.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 17, No. 5, pp. 673–682, September–October, 1985.     

Gating currents of sodium channels in neurons of the rat trigeminal ganglia

Using a voltage-clamp technique and intracellular dialysis, gating currents of sodium channels were first recorded and studied in neurons of the rat trigeminal ganglia. The rising phase of gating currents lasted 30 to 70 µsec; these currents decayed in a monoexponential manner with a time constant equal to that for activation of the sodium current. Voltage dependences for the gating charge and sodium conductance were also nearly identical. Analysis of the activation of sodium conductance demonstrated that the power n of the activation variable in the equation used changed from more than 6 to 3 at test potentials of –30 mV and 0 mV, respectively. It is hypothesized that, with a change in the test potential within this voltage range, the cooperativity of activation undergoes a twofold decrease. In the presence of 2 mM caffeine or theophylline in the external solution, curves of the voltage dependence of the gating charge and sodium conductance shifted toward more negative values of the test potential, by 5.4 ± 0.7 mV, the maximum gating charge increased by 8.4 ± 3.2%, and the slope factor for both curves decreased by 9.2 ± 3.4%. Since the above effects were identical for both xanthines and developed under conditions of constant intracellular dialysis, i.e., under conditions where the effect of a change in the intracellular calcium concentration was ruled out, the most probable reason for these effects is a direct action of the tested agents on sodium ion channels, which facilitates the movement of gating charges.Neirofiziologiya/Neurophysiology, Vol. 36, Nos. 5/6, pp. 370–376, September–December, 2004.This revised version was published online in April 2005 with a corrected cover date and copyright year.     

Characteristics of the second inward current in cells isolated from rat ventricular muscle

The second inward current (Isi) in single cells isolated from ventricular muscle of adult rat hearts was measured in response to step depolarizations under voltage-clamp conditions. The major ion carrying this current was Ca, and Isi was reduced or abolished by Mn, Ni, Cd, nifedipine, nimodipine and D600. Sr and B could substitute for Ca as charge carriers, and reduced the rate of apparent inactivation of Isi. These effects of Sr and Ba, together with the relation between the steady level of apparent inactivation and membrane potential in Ca containing solution, were taken as evidence that inactivation was at least in part dependent on internal Ca. The reduction of external Na to 11% of normal caused a reduction in peak Isi when Ca was present in the external solution, but did not reduce Isi when Ca was replaced by Sr. It therefore seems unlikely that Na is a major charge carrier for Isi under the conditions of our experiments. The time-to-peak and rate of apparent inactivation of Isi were faster than in previous studies that used multicellular preparations. Both the kinetics and peak amplitude of Isi were markedly dependent on temperature (Q10 close to 3). Contraction of the cells, which was monitored optically, was initiated within 3 ms of the peak Isi, reached a maximum level after approximately 40-50 ms, and was about 100 ms in duration.     

Histochemical study of isolated neurons in culture from chick embryo spinal ganglia

Summary Dissociated chick embryo spinal ganglia neurons, cultivated without direct contact with glial cells maintain some enzymatic activities, for example: carboxylic esterases, succinic-dehydrogenase (SDH), glutamic-dehydrogenase (GDH), monoamine oxidase (MAO), lactico-dehydrogenase (LDH) and alcoholic-dehydrogenase (ADH) for several days periods.Nerve growth factor (NGF) prolongs the maintenance of the mitochondrial enzymes, carboxylic esterases, LDH and ADH in cultures of isolated neurons. Extract of embryonic spinal cord gives almost similar results as NGF.With the technical assistance of Miss E. Darcel.This work is part of the Doctorat ès-Sciences thesis.     

Potential-dependent membrane sodium pump current in snail giant neurons

The effect of the membrane potential on the pump current evoked by iontophoretic injection of sodium into the neuron and the effect of the intracellular sodium ion concentration on the potential dependence of the pump current were investigated by the voltage clamp method in isolated and semi-isolated neurons ofHelix pomatia andHelix italiana. The pump current was shown to change its direction in the presence of marked hyperpolarization of the membrane (by more than −80 to −120 mV). An increase in the intracellular sodium ion concentration following injection of excess ions into the neuron increases the potential dependence of the pump current. A possible connection between passive potassium permeability and the activity of the enzymic transport mechanism for the elimination of sodium from the cell is postulated.     

The effects of sodium pump activity on the slow inward current in sheep cardiac Purkinje fibres

The effects of Na pump activity on the slow inward current, Isi, magnitude and twitch tension were investigated in sheep cardiac Purkinje fibres. A two-microelectrode voltage-clamp method was used, tension being measured simultaneously. Na pump activity was lowered either by reducing the extracellular K concentration, [K]O, or by applying the cardiotonic steroid strophanthidin. Reduction of [K]O from 4 to 0 mM leads to time-dependent increases in Isi magnitude and twitch tension. The increases of Isi and tension could be reversed by adding Tl, Rb, Cs or NH4 ions to the K-free superfusate. The actions of these ions are attributed to the known ability of these cations to activate the external site of the Na pump. This conclusion is supported by the observation that such activator cations do not reverse the increases in Isi and tension produced by strophanthidin. We conclude that the effects of low [K]O on Isi are mediated by Na pump inhibition. Similarly the Na pump inhibition produced by strophanthidin increases Isi and tension, although, in this case, other mechanisms may also contribute. Measurements of the activity of the electrogenic Na pump show that elevated intracellular Na ion concentration secondary to Na pump inhibition and not the instantaneous Na pump turnover rate mediates the increase in Isi magnitude.     

Effects of allapinin on sodium currents in isolated neurons of the trigeminal ganglia and cardiomyocytes of rats

Block of sodium currents by allapinin (diterpene alkaloid with strong antiarrhythmic properties) was investigated in isolated, voltage clamped rat trigeminal neurons and cultured neonatal rat single ventricular myocytes. Allapinin produces a decrease in sodium current amplitude without any changes in voltage dependent properties. Possible differences between the mechanisms of antiarrhythmic effect of diterpene alkaloids and classic antiarrhythmic agents have been analysed.     

Gaba-activated conductance of neurons isolated from rat cerebellum and sensory ganglia

Currents activated by gamma-aminobutyric acid (GABA) were recorded in single Purkinje cells isolated from the rat cerebellum and trigeminal ganglia. All neurons tested were GABA-sensitive. Reversal potential of GABA-activated current matched equilibrium potential for chloride ions as determined by Nernst's equation. The dose-response curve was described by Langmuir's isotherm with a dissociation constant (K_d) of 1.4·10^–4 M. Nembutal did not just increase the amplitude of GABA-activated current but also activated matching ionic conductance in the absence of GABA. Ionic currents activated by GABA were reversibly blocked by bicuculline methiodide and isocoryne.A. A. Bogomolets Institute of Physiology, Academy of Sciences of the Ukrainian SSR, Kiev. Translated from Neirofiziologiya, Vol. 20, No. 5, pp. 645–652, September–October, 1988.     

Pharmacological properties of the potassium-activated inward current in pyramidal hippocampal neurons

Elevation of the external potassium concentration induced a two-phase inward current in freshly isolated pyramidal hippocampal neurons. This current was voltage-dependent and demonstrated strong inward rectification. The current consisted of a leakage current and a time-dependent current (τ=40–50 msec at 21°C); the latter was designated asI _ΔK. As was shown earlier, K⁺ is a major charge carrier in the development of slow potassium-activated current. The pharmacological properties ofI _ΔK were studied using a patch-clamp technique.I _ΔK was completely blocked by external 10 mM TEA or 5 mM Ba²⁺ (IC₅₀=480±90mM) and exhibited low sensitivity to extracellular Cs⁺ (2 mM). This current was not affected by 1 mM 4-aminopyridine and was insensitive to a muscarinic agonist, carbachol (50 μM), and to 1 mM extracellular Cd²⁺. Elevation of external Ca²⁺ from 2.5 mM to 10 mM did not changeI _ΔK. Our data indicate that the pharmacological properties ofI _ΔK differ from those of other voltage-gated potassium currents, but more specific blockers must be used to make this evidence conclusive.     

Enhancement of inward current by serotonin in neurons of Aplysia

In RB cells of Aplysia, serotonin, in the presence of TEA, 4AP and Ba, elicits a voltage-dependent inward current. In Ba-TEA-4AP seawater, RB cells showed a negative slope region (NSR) in their current-voltage (I-V) relationship when measured at the end of 2-s commands from a holding potential of -60 mV. Addition of serotonin to the bathing solution enhanced the NSR. When holding potential was lowered to -10 mV, the NSR as well as the effects of serotonin were greatly reduced. Addition of 20 mM cobalt to the bathing solution blocked both the NSR and the inward current produced by serotonin. Changes in potassium concentration produced no consistent shift in voltage sensitivity nor change in amplitude of the current elicited by serotonin. Intracellular injection of cesium sufficient to broaden action potentials did not block the enhancement of NSR by serotonin. These results support the conclusion that in RB cells, serotonin produces a voltage-dependent current carried by calcium ions.