Effects of Ruthenium ions on the sensory terminal discharges of the frog muscle spindle

The presence of a mixed Na+-Ca2+ spike along the sensory terminal of the frog muscle spindle was verified. When the terminal was perfused with Ringer's solution containing 0.1-0.5 mM ruthenium red (RuR), the amplitude and duration of the spike were increased, occurring as a prolonged or a long-lasting depolarization of up to 20-30 s duration following individual afferent spikes evoked spontaneously or antidromically by electrical stimulation. In an isotonic TEA solution, the amplitude and duration of the afferent spikes were increased; however, no prolonged depolarization occurred. Adding 0.2 mM RuR to the TEA solution produced the prolonged and long-lasting depolarization. All responses disappeared in the presence of 3 microM TTX or Na+-free Ringer's solution. An impedance decrease along the terminal was observed during the prolonged or long-lasting depolarization. The prolonged depolarization was blocked by the addition of Ca2+-blockers; the afferent spikes remained. In preparations preincubated with 0.1 mM RuR, increasing CaCl2 in Ringer's solution from 0.2 mM, resulted in shortening of the duration of individual spikes with prolonged depolarization and in increase in the maximum rate of rise (MRR) of the spikes. Preincubation with higher concentrations of RuR produced higher sensitivities in the modifications of the duration and MRR to the change in [Ca2+]O. The responses were retained by adding RuR or RuCl3 to Ca2+-free Ringer's solution containing 0.1-5 mM EGTA, although all responses disappeared in Ca2+-free EGTA Ringer's solution. It is concluded that the RuR-induced prolonged response is produced by an influx of Na+.     

Different Types of Potassium Outward Current in Relay Neurons Acutely Isolated from the Rat Lateral Geniculate Nucleus

Different classes of potassium (K+) outward current activated by depolarization were characterized in relay neurons acutely isolated from the rat lateral geniculate nucleus (LGN), using the whole-cell version of the patch-clamp technique. A fast-transient current (IA), activated at around - 70 mV, declined rapidly with a voltage-dependent time constant (tau=6 ms at + 45 mV), was 50% steady-state inactivated at - 70 mV, and rapidly recovered from inactivation with a monoexponential time course (tau=21 ms). IA was blocked by 4-aminopyridine (4-AP, 2 - 8 mM) and was relatively insensitive to tetraethylammonium (TEA, 2 - 10 mM). After elimination of IA by a conditioning prepulse (30 ms to - 50 mV), a slow-transient K+ current could be studied in isolation, and was separated into three components, IKm, IKs and a calcium (Ca2+)-dependent current, IK[Ca]. The slow-transient current was not consistently affected by 4-AP (up to 8 mM), while TEA (2 - 10 mM) predominantly blocked IKs and IK[Ca]. The component IKm persisted in a solution containing TEA and 4-AP, activated at around - 55 mV, declined monoexponentially during maintained depolarization (tau=98 ms at + 45 mV), was 50% inactivated at - 39 mV, and recovered with tau=128 ms from inactivation. IKs activated at a similar threshold, but declined much slower with tau=2662 ms at + 45 mV. Steady-state inactivation of IKs was half-maximal at - 49 mV, and recovery from inactivation occurred relatively fast with tau=116 ms. From these data and additional current-clamp recordings it is concluded that the K+ currents, due to their wide range of kinetics and dependence on membrane voltage or internal Ca2+ concentration, are capable of cooperatively controlling the firing threshold and of shaping the different states of electrophysiological behaviour in LGN relay cells.     

The effects of QX314 on thalamic neurons

The effects of QX314 were studied in cat thalamic neurons recorded in vivo. Besides blocking Na+ spike electrogenesis, QX314 transformed spindle oscillations into a single long-lasting period of hyperpolarization that terminated with a rebound Ca2+ spike. Large sustained injections of the drug resulted in the occurrence of numerous fast prepotentials that had the characteristics of attenuated dendritic Ca2+ spikes. These effects are interpreted as resulting from the blockage by QX314 of a persistent Na+ current and a delayed rectifier K+ current which currents have already been disclosed in thalamic neurons recorded in vitro.     

The Na-K pump in neuropile glial cells of the medicinal leech

The membrane potential of neuropile glial (NG) cells in the central nervous system of the medicinal leech and the K+ concentration in extracellular spaces (ECS) of the neuropile were measured under various experimental conditions to determine properties of a glial Na+-K+ pump. The ganglia were exposed to K+-free saline thereby loading the NG cells with intracellular Na+. Their membranes hyperpolarized transiently when the K+-free solution was replaced by a bathing medium with normal (= 4 mM) K+ concentration. The hyperpolarization increased in amplitude with time of exposure to K+ -free solution and could be abolished by ouabain or by replacing Na+ with Li+. The transient membrane hyperpolarization could not be attributed to K+ depletion in the ECS of the neuropile or to changes in membrane input conductance. In a (bathing) medium containing 5 X 10(-4) M ouabain, the K+ concentration in the ECS increased transiently, and the NG cell membrane depolarized rapidly. This short-term depolarization (duration 2-3 min) was followed by a second long-term depolarization (duration 15 min) of the NG cell membrane, which reached a steady-state 20 min after ouabain application. In a bathing medium with elevated external K+ concentrations, the amplitude of the membrane depolarization was enhanced by ouabain. This depolarizing ouabain effect was a result of K+ accumulation in the ECS. We conclude that the Na+-K+ pump does not contribute directly to the resting membrane potential of NG cells and is not directly involved in K+ homeostasis at the cellular level.     

The neuropeptide egg-laying hormone modulates multiple ionic currents in single target neurons of the abdominal ganglion of Aplysia

The bag cell neurons of the abdominal ganglion of Aplysia are a useful system for the study of peptidergic neurotransmission. A 20 min burst of impulse activity in the bag cells induces or augments repetitive firing in LB and LC neurons in the abdominal ganglion for up to several hours. Previous experiments have indicated that this effect is mediated by the putative bag cell transmitter egg-laying hormone (ELH). Using voltage-clamp analysis we found that bag cell bursts (BCBs) evoke long-lasting changes in membrane current in these neurons that are mimicked by the application of ELH. The combined ELH-evoked current is inward at all membrane potentials between -110 and -10 mV and consists of 3 separable currents persisting for 30-120 min. They include (1) a depolarizing current that is activated at membrane potentials above -40 mV. This current, termed ISI, is blocked by prolonged exposure to 10 mM Ni2+/0 mM Ca2+ and is not abolished by 0 mM Na+ or 100 mM TEA+/0 mM Na+ in the bathing medium. It is therefore a Ca2+-sensitive current and does not involve Na+ as a charge carrier. (2) There is a hyperpolarizing current that is activated at membrane potentials below approximately -70 mV. This current, termed IR, is blocked by external Rb+ (5 mM) and Cs+ (10 mM) and has a chord-conductance that shifts with the external [K+] according to the Nernst potential for potassium. It is therefore an inwardly rectifying K+ current. (3) There is a small, steady depolarizing current, termed Ix. This current is the only one that remains after prolonged exposure to 10 mM Ni2+/0 mM Ca2+-containing bathing medium. It is Na+ dependent and is associated with a small increase in membrane conductance that is largely independent of membrane voltage. All 3 currents are slow to inactivate; they appear to sum algebraically to produce the net BCB- or ELH-evoked current.     

Veratridine delays apoptotic neuronal death induced by NGF deprivation through a Na+-dependent mechanism in cultured rat sympathetic neurons

Superior-cervical ganglion (SCG) cells dissociated from newborn rats depend on nerve growth factor (NGF) for survival. Membrane depolarization with elevated K+ is known to prevent neuronal death following NGF deprivation and/or to promote survival via a Ca2+-dependent mechanism. Here we have exploited the possibility of whether or not a Na+-dependent pathway for neuronal survival is present in these cells. Veratridine (ec50=40 nM), a voltage-dependent Na+ channel activator, significantly delayed the onset of apoptotic cell death in NGF-deprived SCG neurons that had been cultured for 7 days in the presence of NGF. This effect was blocked completely by Na+ channel blockers including tetrodotoxin (TTX, 1 μM), benzamil (25 μM) and flunarizine (1 μM), but was not attenuated by nimodipine (1 μM), an L-type Ca²⁺ channel blocker. The saving effect of veratridine on cultured neurons was observed even in low Ca²⁺ media (0–1.0 mM), but was completely abolished in a low Na⁺ medium (38 mM). Sodium-binding benzofuran isophthalate was employed as a fluorescent probe for monitoring the level of cytoplasmic free Na⁺, which revealed a sustained increase in its level (12.9 mM, 307% of that of control) in response to veratridine (0.75 μM). The TTX or flunarizine completely blocked veratridine-induced Na⁺ influx in these cultured neurons. Moreover, no appreciable increase in intracellular Ca²⁺ was detected under these conditions. Though Na⁺ channels were effectual in SCG neurons which were freshly isolated from newborn rats, the Na⁺-dependent saving effect of veratridine was not observed in these young neurons. These lines of evidence suggest that the death-suppressing effect of veratridine on cultured SCG neurons depends on the Na⁺ influx via voltage-dependent Na⁺ channels, and suggests the presence of Na⁺-dependent regulatory mechanism(s) in neuronal survival.     

Reversal of the static component of spindle potential by imposed depolarizing current in the frog muscle spindle

The static component of the spindle potential provoked during stretch of isolated muscle spindles of the frog was reversed during the application of depolarizing currents ranging from 0.2 to 5 nA in normal Ringer solution and also in Na+-free Ringer solution. In the same range of current intensities, spontaneous rhythmic hyperpolarizations due to [Ca2+]i-activated GK, an attenuation of membrane impedance, and an anomalous decrease in amplitude of the afferent spikes were observed. All 4 phenomena were abolished by K+ channel blockers (10 mM CsCl, 1-2 mM 4-aminopyridine (4-AP), or 20 mM tetraethylammonium chloride (TEA], Ca2+ channel blockers (5-10 mM CoCl2, MnCl2, 1-2 mM CdCl2 or 0.5 mM verapamil) or 0.1 mM quinine. The amplitude of the static component of the spindle potential was markedly increased at threshold concentration of the K+ channel blockers (5 mM CsCl, 0.1-0.5 mM 4-AP or 5-10 mM TEA), but the component disappeared at that of the Ca2+ channel blockers. The rhythmic hyperpolarizations are associated with the spindle potential, except for its dynamic component, which often triggers a hyperpolarizing deflection. We suggest that both the static component of the spindle potential and rhythmic hyperpolarizations are due to GK(Ca) in the intracapsular axon, either along the terminal or at the branching nodes, or both; and that the receptor potential contributes to, but is not the same as, the spindle potential.     

Effects of inhibitors of Na,K-ATPase on the membrane potentials and neurotransmitter efflux in rat brain slices

The potassium potential EK, of rat brain slices was estimated by determining the uptake of 86Rb+. The ERb was the same for slices prepared from five rostral brain regions, the average value being 66.4 mV. The ERb values in the presence of 20 microM ouabain were only slightly lower than the resting values; increasing concentrations of ouabain above 20 microM resulted in a graded depolarization in all five brain regions. High concentrations (1 mM) of two other inhibitors of Na+,K+-ATPase, dihydro-ouabain and strophanthidin, produced no more depolarization than did 20 microM ouabain. Competitive binding studies indicated that the differential effects were due to the relative binding to brain slices. Erythrosin B, an inhibitor of Na+,K+-ATPase, had no measurable effect on ERb. Intermediate concentrations of the Na+/H+ ionophore monensin slightly hyperpolarized striatal slices, whereas the same monensin concentrations plus 20 microM ouabain, 1 mM strophanthidin or 70 microM erythrosin B resulted in marked depolarization. Measurement of the membrane potential via uptake of methyltriphenylphosphonium cation indicated that ERb was indeed a valid estimation of the membrane potential. EK was measured directly by monitoring 42K+ uptake in striatal slices and was found to be essentially identical to ERb. Uptake of 22Na+ was consistent with the values for ERb or EK. Several conditions that resulted in little or no measurable depolarization of striatal slices did induce efflux of exogenously loaded GABA and dopamine; these conditions included 20 microM ouabain, 1 mM dihydro-ouabain or strophanthidin, and 70 microM erythrosin B. Neurotransmitter efflux in the absence of general cell depolarization was not accompanied by altered rates of respiration or decreased ATP levels.     

Simultaneous action of MK-801 (dizclopine) on dopamine, glutamate, aspartate and GABA release from striatum isolated nerve endings

The simultaneous effect of MK-801 on the baseline- and depolarization (20 microM veratridine or 30 mM high K+)-evoked release of endogenous dopamine, glutamate (Glu), aspartate (Asp), and GABA is investigated in the same preparation of rat striatum isolated nerve endings. MK-801, in the microM range, selectively increases the baseline and high K+ depolarization-evoked release of dopamine, without causing any effect on the baseline or on the high K+-evoked release of Glu, Asp and GABA. In addition to this selective action on dopamine release, MK-801 inhibits the veratridine depolarization-evoked release of all the neurotransmitters tested, including dopamine. In SBFI and fura-2 preloaded striatal synaptosomes, MK-801 inhibits the elevation of internal Na+ (Na(i)) and the elevation of internal Ca2+ (Ca(i)) induced by veratridine depolarization. The elevation of Ca(i) induced by high K+ depolarization is unchanged by MK-801. This study reveals two separate MK-801 actions. (1) The voltage-independent action, which increases dopamine release selectively, and might contribute to the effects of MK-801 on motor coordination. (2) The voltage-dependent action, which inhibits all the veratridine-evoked responses including the evoked release of the excitatory amino acids (which are particularly concentrated in striatum nerve endings), and might contribute to the anticonvulsant and neuroprotective effects of MK-801.     

The spindle potential in the frog muscle spindle does not require external Na

Spindle potential recorded from the sensory nerve terminal of isolated frog muscle spindles disappeared within 20-30 min after the spindle receptor was perfused with Na+-free (Li, Tris or choline) Ringer's solution, whereas the amplitude of spindle potential was not attenuated for periods up to 60 min when the spindles were perfused in a Na+-free Ringer's solution containing both 10 mM TEA and 0.1 mM 4-aminopyridine after being washed with a normal Ringer's solution containing both the K+-channel blockers. It is concluded that the time-dependent decrease in the amplitude of spindle potential during the application of Na+-free solution is not ascribable to a decrease in the inward current carried by Na+, but is due to an increase in an outward current carried by K+.     

Electrical properties of facial motoneurons in brainstem slices from guinea pig

Electrical properties of guinea pig facial motoneurons (FMNs) were studied in a brainstem slice preparation. FMNs were identified histologically and by antidromic activation. They displayed time-varying responses and inward rectification during both subthreshold depolarization and hyperpolarization. The depolarizing rectification was caused by a persistent Na+ current (INaP); the Cs+-sensitive hyperpolarizing response had a different mechanism. Hyperpolarizing prepulses caused a 4-aminopyridine-sensitive delay of spike initiation. An evoked spike was followed by a fast- and a medium-duration hyperpolarization (the fAHP and mAHP, respectively). Blockade of Ca2+ influx abolished the mAHP without affecting spike duration, whereas spikes were prolonged and the fAHP was abolished by TEA or 4-AP. Adequate depolarization evoked tonic repetitive firing characterized by a steep F-I slope and fast adaptation. Abolition of the mAHP was associated with reduced fast adaptation and increased F-I slope, whereas the mAHP was enhanced and firing rate was slowed after TEA application. Three outward ionic currents were identified during voltage clamp: a rapidly inactivating current, a slowly inactivating current and a slow persistent Ca2+-mediated current (IK(Ca]. We conclude that spike repolarization and the fAHP are governed mainly by fast voltage-dependent currents, whereas progressive activation of IK(Ca) causes fast adaptation and, together with INaP, regulates firing rate.     

Ionic currents on type-I cells of the rabbit carotid body measured by voltage-clamp experiments and the effect of hypoxia

Type-I cells (from rabbit embryos) in primary culture were studied in voltage-clamp experiments using the whole cell arrangement of the patch-clamp technique. With a pipette solution containing 130 mM K⁺ and 3 mM Mg-ATP, large outward currents were obtained positive to a threshold of about −30 mV by clamping cells from −50 mV to different test pulses (−80 to 50 mV). Negative to −30 mV, the slope conductance was low (outward rectification). The outward currents were blocked by external Cs⁺ (5 mM) and partially blocked by TEA (5 mM) and Co²⁺ (1 mM). The initial part of the outward currents during depolarizing voltage pulses exhibited a transient Ca²⁺ inward component partially superimposed to a Ca²⁺-dependent outward current. Inward currents were further characterized by replacing K⁺ with Cs⁺ in the intra- and extracellular solution in order to minimize the outward component and by using 1.8 mM Ca²⁺ or 10.8 mM Ba²⁺ as charge carrier. Slow-inactivating inward currents were recorded at test potentials ranging from −50 to 40 mV (holding potential −80 mV). The maximal amplitude, measured at 10 mV in the U-shaped I–V curve, amounted to 247 ± 103pA(n = 3). This inward current was insensitive to 3 μM TTX, but blocked by 1 mM Co²⁺ and partially reduced by 10 μM D600 and 3 μM PN 200-110. In contrast to outward currents, the inward currents exhibited a ‘run-down’ within about 10 min. Lowering the pO₂ from the control of 150 Torr (air-gassed medium) to 28 Torr had no apparent effect on inward currents, but depressed reversibly outward currents by 28%. In conclusion, it is suggested that type-I cells possess voltage-activated K⁺ and Ca²⁺ channels which might be essential for chemoreception in the carotid body.     

Synchronization of rat hippocampal neurons in the absence of excitatory amino acid-mediated transmission

Extracellular and intracellular recordings and measurements of extracellular K⁺ concentration ([K⁺]_o) were performed in the adult rat hippocampus in an in vitro slice preparation. Excitatory amino acid receptor antagonists, as well as the K⁺-channel blockers 4-aminopyridine (4AP, 50 μM) and/or tetraethylammonium (TEA, 5 mM), were added to the bath. Synchronous, negative-going field potentials were recorded in the CA3 stratum radiatum during application of 4AP and excitatory amino acid receptor antagonists. Each of these events was associated with an intracellular long-lasting depolarization and a concomitant rise in [K⁺]_o that attained peak values of 4.3 + 0.1 mM (mean ± S.E.M., n = 6 slices) and lasted 29 ± 3 s. These field potentials were still recorded in CA3 stratum radiatum after addition of TEA. Under these conditions, prolonged field potentials (40.2 ± 4.5 s, n = 18) characterized by a prominent positive component; discharge of population spikes also occurred. [K⁺]_o, increases associated with these prolonged field-potential discharges had a considerable variability in magnitude (peak value = 3.8–14.1 mM, 6.1 ± 0.7 mM, n = 5) and duration (14–210 s; 48 ± 13 s, n = 5). In 8% of the cases spreading depression-like episodes were observed. [K⁺]_o increases during spreading depression-like episodes attained peak values of 11–27 mM (22.8 ± 0.2 mM, n = 2) and had a duration of 160–396 s (244 ± 29 s, n = 2). All types of synchronous activity were abolished by the GABAA receptor antagonist bicuculline methiodide (t0 μM) ( n= 11). A similar effect was obtained by applying Ca²⁺-free/high-Mg²⁺ medium ( n = 5). Simultaneous field-potential recordings in CA3, CAI, dentate area and subiculum demonstrated that negative-going potentials and prolonged field-potential discharges occurred in all areas in a synchronous fashion. Spreading depression-like episodes were more frequently recorded in the CAI than in the CA3 area and were not seen in the subiculum or dentate area. These experiments indicate that a glutamatergic-independent, synchronous GABA-mediated potential which is elicited by 4AP in the adult rat hippocampus continues to occur in the presence of TEA. In addition, concomitant application of these K⁺-channel blockers induces a novel type of prolonged field-potential discharge as well as spreading depression-like episodes. Since all synchronous potentials (including spreading depression-like episodes) were abolished by bicuculline methiodide, we conclude that their occurrence is presumably dependent upon the post-synaptic activation of GABA_A receptors located on neuronal and glial elements. As excitatory synaptic transmission was nominally blocked under our experimental conditions, we also propose that rises in [K⁺]_o and consequent redistribution processes are per se sufficient to make all types of synchronous activity propagate.     

Expression and kinetic properties of Na(+) currents in rat cardiac dorsal root ganglion neurons

The expression and properties of voltage-gated Na(+) currents in cardiac dorsal root ganglion (DRG) neurons were assessed in this study. Cardiac DRG neurons were labelled by injecting the Fast Blue fluorescent tracer into the pericardium. Recordings were performed from 138 cells. Voltage-dependent Na(+) currents were found in 115 neurons. There were 109 neurons in which both tetrodotoxin-sensitive (TTX-S, blocked by 1 microM of TTX) and tetrodotoxin-resistant (TTX-R, insensitive to 1 microM of TTX) Na(+) currents were present. Five cells expressed TTX-R current only and one cell only the TTX-S current. The kinetic properties of Na(+) currents and action potential waveform parameters were measured in neurons with cell membrane capacitance ranging from 15 to 75 pF. The densities of TTX-R (110.0 pA/pF) and TTX-S (126.1 pA/pF) currents were not significantly different. Current threshold was significantly higher for TTX-R (-34 mV) than for TTX-S (-40.4 mV) currents. V(1/2) of activation for TTX-S current (-19.6 mV) was significantly more negative than for TTX-R current (-9.2 mV), but k factors did not differ significantly. V(1/2) and the k constant for inactivation for TTX-S currents were -35.6 and -5.7 mV, respectively. These values were significantly lower than those recorded for TTX-R current for which V(1/2) and k were -62.3 and -7.7 mV, respectively. The action potential threshold was lower, the 10-90% rise time and potential width were shorter before than after the application of TTX. Based on this we drew the conclusion that action potential recorded before adding tetrodotoxin was mainly TTX-S current dependent, while the action potential recorded after the application of toxin was TTX-R current dependent. We also found 23 cells with mean membrane capacitance ranging from 12 to 35 pF (the smallest labelled DRG cells found in this study) that did not express the Na(+) current. The function of these cells is unclear. We conclude that the overwhelming majority of cardiac dorsal root ganglion neurons in which voltage-dependent Na(+) currents were present, exhibited both TTX-S and TTX-R Na(+) currents with remarkably similar expression and kinetic properties.     

Voltage clamp analysis of intact stomatogastric neurons

Two-electrode voltage clamp of intact, identified pyloric neurons of the spiny lobster stomatogastric ganglion reveals two major outward currents. A rapidly inactivating, tetraethylammonium- (TEA) insensitive, 4-aminopyridine- (4AP) sensitive, outward current resembles IA of molluscan neurons; it activates rapidly on depolarizations above rest (e.g. -45 mV), delaying both the axonal-sodium and the neuropil-calcium spikes which escape voltage-clamp control. We infer that A-current is distributed both in a space clamped region (on or near the soma) and in a non-space clamped region with access to the generators for sodium and calcium spikes. A calcium-dependent outward current, IO(Ca), activates rapidly at clamp steps above -25 mV and inactivates at depolarizing holding voltages. Increasing depolarization results in an increase in both IO(Ca) and firing rate but a reduction in the amplitude of the sodium spike current. Blockage of IO(Ca) with Cd2+ causes little change in spike firing pattern. These observations are consistent with IO(Ca) being activated primarily in the soma and nearby regions which are under good control with a soma voltage clamp (and distant from the Na(+)-spike trigger zone). While the lack of space clamp limits resolution of charging transients and tail currents, the identification of the major current subgroups can still be readily accomplished, and inferences about the location and function of currents can be made which would not be possible if the cells were space clamped or truncated.     

Changes in ionic conductances induced by cAMP in Helix neurons

Adenosine 3',5'-cyclic monophosphate (cAMP) was injected by a fast and quantitative pressure injection method into voltage-clamped identified Helix neurons. The intracellular elevation of cAMP caused an inward current which was not accompanied by a significant change in membrane conductance in a negative potential range with little activation of voltage-dependent membrane conductances. Near resting potential Na+ ions were the main carrier of the cAMP-induced inward current as measured with ion-selective microelectrodes. TTX did not affect the Na+ influx. K+ and less effective Ca2+ could substitute for Na+ in carrying the inward current. In the presence of Na+, divalent cations such as Ca2+ and Mg2+, and also La3+ exerted an inhibitory influence on the cAMP-induced inward current, and Ca2+ as measured with ion-selective microelectrodes did not contribute significantly to the current. Thus, the inward current was of a non-specific nature. Simultaneously to this cAMP action, the membrane permeability for K+ ions was decreased by cAMP. This effect became particularly obvious when K+ currents were activated by long-lasting, depolarizing voltage steps. In this situation a reduced K+ efflux following cAMP injection was observed by means of K+-selective microelectrodes located near the external membrane surface. Outward K+ currents were less reduced by cAMP if external Ca2+ was replaced by Ni2+. The nearly compensatory increase and decrease of two membrane conductances in the same neuron explained the lack of change in the cell input resistance despite the considerable depolarizing action of intracellularly elevated cAMP.     

Low external NaCl concentration and low osmolarity enhance voltage-gated Ca currents but depress K currents in freshly isolated rat hippocampal neurons

In previous experiments, reducing bath osmolarity (pi o) or external NaCl concentration ([NaCl]o) caused an increase in synaptic currents recorded in whole-cell configuration from pyramidal cells of CA1 region of hippocampal slices. Slow inward current surges, assumed to be calcium currents, were also enhanced. This contrasted with the strong, reversible, generalized depression of voltage-dependent ion currents in isolated neurons, caused by sudden, brief exposure to very low pi o. I have now recorded voltage-dependent whole-cell Na-, K- and Ca-currents from freshly isolated hippocampal CA1 pyramidal neurons during more gradual lowering of pi o or [NaCl]o. Changes in cell size were determined from image areas and changes in intracellular Ca2+ activity were measured as the ratio of the fluorescences of fluo-3/fura-red by confocal microscopy. Iso-osmotic substitution of 40 or 60 mM NaCl by mannitol or sucrose for 5-7 min, or reducing pi o by deleting NaCl from the bath (osmolarity decreased by 69 or 108 mosM/kg) depressed K currents. Na currents were also strongly depressed, but this is in part attributable to reduced driving potential and ionic conductance. The depression of IK varied widely and it was inversely correlated with the degree of hypotonic swelling, suggesting that reduced ion channel conductance also reduces permeability to water. Reducing [NaCl]o by 60 mM, or pi o by 105 mosM/kg consistently and reversibly increased Ca currents. Intracellular Ca2+ level also increased, but the changes of [Ca2+]i and ICa were not correlated. Facilitation of the Ca influx into presynaptic terminals could explain the increase of synaptic currents. Depression of outward currents could also contribute to the irritability of the central nervous system typical of clinical hyponatremia.     

Taurine-induced modulation of voltage-sensitive Na+ channels in rat dorsal root ganglion neurons

The physiological role of taurine, an abundant free amino acid in the neural system, is still poorly understood. The aim of this study was to investigate its effect on TTX-sensitive (TTX-S) and TTX-resistant (TTX-R) Na+ currents in enzymatically dissociated neurons from rat dorsal root ganglion (DRG) with conventional whole-cell recording manner under voltage-clamp conditions. A TTX-S Na+ current was recorded preferentially from large DRG neurons and a TTX-R Na+ current preferentially from small ones. For TTX-S Na+ channel, taurine of the concentration > or = 10 mM shifted the activation curve in the depolarizing direction and the inactivation curve in the hyperpolarizing direction. There was no change in the activation curve for TTX-R Na+ channel and the inactivation curve was shifted in the hyperpolarizing direction slightly in the presence of taurine > or = 20 mM. When the recovery kinetics was examined, the presence of taurine resulted in a slower recovery from inactivation of TTX-S currents and no change of TTX-R ones. All the effects of taurine were weakly concentration-dependent and partly recovered quite slowly after washout. Our data indicate that taurine alters the properties of Na+ currents in intact DRG neurons. These may contribute to the understanding of taurine as a natural neuroprotectant and the potential of taurine as a useful medicine for the treatment of sensory neuropathies.     

Modulation of abnormal synaptic transmission in hippocampal CA3 neurons of spontaneously epileptic rats (SERs) by levetiracetam

Levetiracetam (LEV) inhibits partial refractory epilepsy in human, and both convulsive and absence-like seizures in the spontaneously epileptic rat (SER). Two-thirds of hippocampal CA3 neurons in SER show a long-lasting depolarization shift, with accompanying repetitive firing upon mossy fiber stimulation. This abnormal excitability is probably attributable to abnormalities in the L-type Ca(2+) channels. We performed electrophysiological studies to elucidate the mechanism underlying the antiepileptic effects of LEV via intracellular recording from the hippocampal CA3 neurons in slice preparations of SER and non-epileptic Wistar rats. LEV (100 μM) inhibited the depolarization shift with repetitive firing by mossy fiber stimulation (MFS), without affecting the first spike in SER CA3 neurons. At a higher dose (1mM), LEV suppressed the first spike in all SER neurons (including the CA3 neurons which showed only a single action potential by MFS), while the single action potential of Wistar rat CA3 neurons remained unaffected. SER CA3 neurons with MFS-induced abnormal firing exhibited a higher number of repetitive spikes when a depolarization pulse was applied in the SER CA3 neurons. LEV (100 μM, 1mM) reduced the repetitive firing induced by a depolarization pulse applied without affecting Ca(2+) spike in SER neurons. LEV is known not to bind glutamate and gamma-aminobutyric acid (GABA) receptors. These findings suggest that the therapeutic concentration of LEV inhibits abnormal firing of the CA3 neurons by modulating abnormal synaptic transmission and abnormal Na(+) channels in SER.     

Acetylcholine responses in snail neurons: Increase and decrease in potassium conductance succeeding inward currents

In the identified neurons B1 and B3 of the buccal ganglion of Helix pomatia, the initial acetylcholine (ACh) inward current was succeeded by two types of secondary responses. The secondary responses consisted either in an outward current or in a long-lasting inward current or in a combination of both. The secondary outward current was decreased with membrane hyperpolarization, associated with a decrease of membrane resistance and abolished in Ca2+-free Co2+ solution. It is assumed to be a K+ current activated by an influx of Ca2+. The secondary inward current also decreased with membrane hyperpolarization, but was associated with an increase of the membrane resistance and could be mimicked by an injection of Na+ into the cells. It is suggested to be due to a block of K+ channels by intracellular Na+. When the secondary responses appeared combined, the outward current preceded the inward current.