Regulation of spontaneous activity and oscillatory spike firing in rat midbrain dopamine neurons recorded in vitro

Intracellular recordings were obtained from identified dopamine (DA) neurons in rat midbrain slices maintained in vitro. DA neuron membranes exhibited pronounced instantaneous and time-dependent anomalous rectification that showed evidence of maximal activation at average membrane potentials of -63 and -78 mV, respectively. Action potentials were followed by prominent afterhyperpolarizations (AHP) that consisted of two components. The fast component showed evidence of inactivation at -63 mV independent of the initial membrane potential, whereas the longer-duration, later component increased in amplitude at hyperpolarized potentials. Unlike DA neurons recorded in vivo, there was no evidence of spike frequency adaptation or summation of AHPs with prolonged depolarization-induced spike trains. Spontaneous spike discharge occurred via an endogenous pacemaker potential that was dependent on both TTX-sensitive and cobalt-sensitive processes. Hyperpolarizing prepulses could activate rebound pacemaker discharge, but this rebound activity was progressively blocked with larger-amplitude hyperpolarizing prepulses. DA neurons recorded in the anesthetized animal, freely moving animal, and in vitro preparations have been shown to exist in two states of activity: 1) spontaneously discharging action potentials or 2) hyperpolarized, quiescent, and nonfiring. Furthermore, although it is rare to find DA neurons in the untreated animal in transitional states of activity, quiescent neurons can be activated by stimuli that place a demand on the DA system. The evidence presented here is consistent with the hypothesis that the special combination of membrane properties of DA neurons contribute to the segregation of their activity into active or inactive states.     

Single channels of low and high-threshold calcium channels of the membrane of sensory neurons in the mouse

Single calcium channels of cultured dorsal root ganglion cells from mouse embryos were studied using patch clamp method in its cell-attached configuration. Two types of activity of unitary calcium channels were found. The first one which arose at membrane potentials near--50-40 mV was characterized by unitary current amplitude of 0.37 +/- 0.04 pA with 40 mmol/l Ca2+ in the pipette solution, mean open time of 0.6 ms and intraburst mean shut time of 1.2 ms. It displayed voltage- and time-dependent inactivation. The corresponding values for the second one which required much more positive depolarization to be activated (approximately 0 mV) and did not express noticeable inactivation were: 0.53 +/- 0.04 pA, 0.8 ms and 0.8 ms. It is concluded that the recorded types of unitary activity are associated respectively with low- and high-threshold calcium currents which have been found earlier while studying whole cell currents.     

Long-term modifiability of anomalous and delayed rectification in guinea pig inferior olivary neurons

Delayed and anomalous rectification was studied in inferior olivary (I.O.) neurons in guinea pig brain stem slices maintained in vitro. Hyperpolarization of the I.O. cell beyond rest membrane potential was accompanied by anomalous rectification (AR). This consisted of 2 parts: an instantaneous and a time-dependent component. The "instantaneous" component was blocked by bath addition of Ba2+ or Cs+ and demonstrated inactivation following prolonged hyperpolarization. The time-dependent component, referred to as the gK(ol), was blocked by harmaline in concentrations of 0.1 mg/ml or by substitution of Co2+, Cd2+, or Mn2+ for Ca2+ in the bath. The gK(ol) was blocked by extracellular Cs+ but not by Ba2+. Delayed rectification (DR), consisting of 2 distinct components, was observed after membrane depolarization by more than 10 mV with respect to rest (usually at -65 mV). One of the components of the DR was found to be quite similar to the classical gK. It did not demonstrate significant inactivation with membrane potential change and was reduced by Ba2+ or tetraethylammonium (TEA). A second component of the DR demonstrated voltage-dependent inactivation and was thus referred to as gK(inact). This inactivation determined by current-clamp measurements had a sigmoidal time course, with approximately a 1 sec onset latency and a half-time to peak of 7 sec. The inactivation of gK(inact) outlasted current injection for tens of seconds to several minutes, depending on the duration and amplitude of the preceding depolarization. During this period, I.O. neurons could be easily activated and demonstrated full dendritic spikes following current injection or excitatory synaptic input that had previously been subthreshold for spike initiation. The inactivation component of the DR was removed by prolonged membrane hyperpolarization beyond rest. gK(inact) was blocked by 4-aminopyridine (4-AP; 100 microM) but not by Ba2+. This inactivation was dependent on the presence of extracellular Ca2+ or Ba2+. Addition of Co2+ or Cd2+ to the bath did not block gK(inact) but did prevent its inactivation. The modulatory effects of these different membrane conductances on the integrative properties of I.O. neurons are described. The long duration of the inactivation of DR and AR is considered as the basis for a dynamic long-term modulation of the electroresponsive and integrated properties of I.O. neurons.     

Delayed potassium current and non-specific outward current in pyramidal neurones acutely dissociated from rat hippocampus

The electrical property of delayed K+ currents (IKD) was studied in pyramidal neurones freshly isolated from the rat hippocampal CA1 region. The IKD was separated pharmacologically from other membrane currents. Activation and inactivation processes of the IKD were highly voltage-dependent in the potential range between -30 and +20 mV. The steady-state inactivation of IKD was observed at -100 mV or more positive potentials. The potential for half steady-state inactivation was -65 mV. The IKD was fully inactivated around -20 mV. Reactivation of IKD consisted of two exponential components. After pharmacological suppression of IKD, the small amount of residual voltage-dependent outward current (one-fifteenth to one-twentieth of IKD amplitude) was observed. The current kinetics was similar to that of IKD and greatly reduced by substitution of internal K+ with N-methyl-D-glucamine+. It was concluded that the properties of IKD was basically similar to those of IKD in other excitable tissues and that the residual current might be non-specific outward current.     

Two components of calcium channel current in embryonic chick skeletal muscle cells developing in culture

The properties of the Ca channel currents in chick skeletal muscle cells (myoballs) in culture were studied using a suction pipette technique which allows internal perfusion and voltage clamp. The Ca channel currents as carried by Ba ions were recorded, after suppression of currents through ordinary Na, K and Cl channels by absence of Na, K and Cl ions, by external TEA, by internal EGTA and by observing the Ba currents instead of the Ca currents. Two components of Ba current could be distinguished. One was present only if the myoballs were held at relatively negative holding potentials below -50 mV. This component first became detectable at clamp potentials of about -50 mV and reached a maximum between -10 and -20 mV. During long clamp steps, it became inactivated completely. The inactivation process of this component at a clamp potential of -30 mV was well fitted to a single exponential with a time constant of about -20 ms. Half-maximal steady-state inactivation was observed at -63 mV. The other component persisted even at relatively positive holding potentials above -40 mV, was observed during clamp pulses to -20 mV and above, and reached a maximum between +10 and +20 mV. This component inactivated very little; a substantial fraction of this component remained at the end of clamp pulses lasting 1 s. The inactivation process of this component at a clamp potential of -10 mV apparently followed a single exponential with a time constant of about 1 s. Half-maximal steady-state inactivation was attained at -33 mV. Both components of Ba current were blocked by Co ions, but organic Ca channel blocker D600 preferentially blocked the high-threshold, slowly inactivating component. The relationship between the current amplitude and the concentration of the external Ba ions was different between the two components. Furthermore, the two components of Ba current also differed in their developmental profile. These findings demonstrate the existence of two distinct types of Ca channels in the early stages of chick muscle cell development.     

Sodium conductance in cultured myenteric AH-type neurons from guinea-pig small intestine

Whole-cell patch clamp methods were used to investigate sodium conductance in after-hyperpolarization-type (AH) enteric neurons in culture after dissociation from the myenteric plexus of guinea-pig small intestine. Inward current carried by Na+ (I(Na)) was identified and its current-voltage characteristics were compared with those for inward Ca2+ current (I(Ca)). The I(Na) current was a rapidly inactivating current relative to I(Ca). Application of tetrodotoxin (TTX) blocked I(Na) with an EC50 of 10.7 nM. Activation curves for I(Na) showed a rapid decrease in time to peak for test potentials from holding potentials of -80 mV to between -40 and -10 mV. Voltage-dependence of steady-state inactivation curves for I(Na) was fit to the Boltzmann equation with potential for half-inactivation (V(1/2)) = -55.6 mV and slope factor (k) = 6.4 mV. Steady-state inactivation for I(Ca) fit the Boltzmann equation with a V(1/2) = -38.9 mV and k= 14.4 mV. Kinetics for inactivation of I(Na) were voltage dependent at potentials between -70 and -30 mV and accelerated and became less voltage-dependent at more positive potentials. The time constant (tau) for inactivation at -70 mV was tau = 161 +/- 23 ms and decreased to tau = 2.3 +/- 0.2 ms at -30 mV. Rapid acceleration of inactivation occurred between -50 and -40 mV. This was also the range where activation began. Recovery from inactivation with the membrane potential clamped at -100 or -80 mV was rapid and fit by a single exponential with tau = 7.3 +/- 1.1 ms for -100 mV and 21.5 +/- 5.1 ms for -80 mV. The results suggest that AH-type enteric neurons have only one type of Na+ channel that behaves like the "classical" voltage-gated tetrodotoxin-sensitive fast channel. The findings support the hypothesis that I(Na) current is an important factor in determination of excitability and firing behavior in AH neurons. I(Na) and I(Ca) together determine the properties of the rising phase of the spike and thereby contribute to global determinants of excitability as the neurons are exposed to multiple depolarizing and hyperpolarizing stimuli from synaptic inputs and mediators released from enteroparacrine cells.     

Two pharmacologically and kinetically distinct transient potassium currents in cultured embryonic mouse hippocampal neurons.

Transient potassium currents in mammalian central neurons influence both the repolarization of single action potentials and the timing of repetitive action potential generation. How these currents are integrated into neuronal function will depend on their specific properties: channel availability at the resting potential, activation threshold, inactivation rate, and current density. We here report on the voltage-gated transient potassium currents in embryonic mouse hippocampal neurons dissected at embryonic days 15-16 and grown in dissociated cell culture for up to 3 d. Two transient potassium currents, A-current and D-current, were isolated based on steady state inactivation and sensitivity to 4-aminopyridine (4-AP) and dendrotoxin (DTx). A-current had an activation threshold of approximately -50 mV and was half-inactivated at approximately -81 mV. A-current relaxations at voltages between -40 and +40 mV could be fit by single exponential functions with time constants of 20-25 msec; these time constants showed little sensitivity to voltage. In contrast, D-current had an activation threshold of between -40 and -30 mV and was half-inactivated at approximately -22 mV. D-current inactivation was voltage dependent; time constants of fitted exponential functions ranged from approximately 7 sec at -40 mV to 200 msec at +40 mV. A slower component of inactivation was also evident. D-current was preferentially blocked by 4-AP (100 microM) and DTx (1 microM). Operationally, A- and D-currents could be cleanly separated based on conditioning pulse potential and 4-AP sensitivity. Total transient potassium current amplitude increased during the time that neurons were in culture (recordings were made between 2 hr after dissociation and 3 d in culture). When normalized for cell capacitance (an index of membrane area), A-current density (pA/pF) decreased and D-current density increased, even during a period between days 1 and 3 when total transient current density remained constant. This observation suggests that A- and D-currents may be reciprocally modulated. Since blockade of D-current (with 100 microM 4-AP) increased both action potential duration and repetitive firing in response to constant current stimulation, long-term modulation of the A-current:D-current ratio may affect the excitability of hippocampal neurons.     

Electrophysiological properties of neuroendocrine cells of the intact rat pars intermedia: multiple calcium currents

Intracellular recordings for current and voltage clamping were obtained from 130 neuroendocrine cells of the pars intermedia (PI) in intact pituitaries maintained in vitro. Spontaneous and evoked action potentials were blocked by TTX or by intracellular injection of a local anesthetic, QX-222. After potassium (K+) currents were blocked by tetraethylammonium (TEA), 4-aminopyridine, and intracellular cesium (Cs+), 2 distinct calcium (Ca2+) spikes were observed which were differentiated by characteristic thresholds, durations, and amplitudes. Both Ca2+ spikes were blocked by cobalt (Co2+) but were unaffected by TTX or QX-222. The low-threshold spike (LTS) had a smaller amplitude and inactivated when membrane potential was depolarized past -40 mV or when evoked at a fast rate (greater than 0.5 Hz). The high-threshold spike (HTS) typically had a larger amplitude and longer duration, was not inactivated at potentials which inactivated the LTS, and could be evoked at rates of up to 10 Hz. Single-electrode voltage-clamp analysis revealed that 3 distinct components of the Ca2+ current were present in most cells. From a negative holding potential (-90 mV), 2 separate peak inward currents were observed; a low-threshold transient current, similar to a T-type Ca2+ current, activated at -40 mV, whereas a large-amplitude inactivating current activated above -20 mV. This large inactivating Ca2+ current was significantly inactivated at a holding potential of -40 mV or by brief prepulses to positive potentials, and was similar to an N-type Ca2+ current. A sustained Ca2+ current (L-type) was observed which was not altered by different holding potentials.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characteristics of fast Na(+) current of hypoglossal motoneurons in a rat brainstem slice preparation

Whole-cell patch clamp recordings were performed on hypoglossal motoneurons in a brainstem slice preparation from the neonatal rat brain to study the characteristics of the fast Na(+) current (I(Na)) which has not been hitherto investigated in these cells. To aid voltage clamping of I(Na), cells were bathed in low Na(+) solution, loaded intracellularly with Na(+) (to reverse the Na(+) gradient) or treated with a small dose (20 nM) of tetrodotoxin. In low extracellular Na(+) solution (Na(+) was replaced by choline or N-methyl-D-glucamine) I(Na) activated at membrane potentials positive to -45 mV and was half-maximally activated at -30 mV. Similar data were obtained when the Na(+) gradient was reversed or tetrodotoxin was applied. I(Na) rapidly activated (1--3.5 ms time constant) and inactivated (1.6 ms time constant at 0 mV) during membrane depolarization. Inactivation was strongly voltage-dependent (half inactivation at -44 mV) and developed mono-exponentially. Recovery from inactivation was bi-exponential with fast and slow time constants of 14 and 160 ms, respectively, at -58 mV. The rapid turning on of I(Na) was presumably responsible for the upstroke of the fast action potential generated by these cells while the slow phase of recovery from inactivation might modulate the ability to fire repetitively at high rate.     

Ca(2+)- and voltage-dependent inactivation of Ca2+ currents in rat intermediate pituitary.

We used single electrode voltage-clamp methods to investigate the inactivation of Ca2+ currents in melanotrophs of the intermediate lobe of the pituitary. The low threshold transient current was inactivated by brief prepulses to potentials above -30 mV and inhibition remained complete as prepulse potential was increased from 0 to +70 mV. Both the high threshold transient and sustained currents, however, were inhibited to the greatest extent (60%) by prepulses to 0 mV. Prepulses to more positive potentials close to the Ca2+ reversal potential produced much less (15%) inactivation. Buffering intracellular Ca2+ by including BAPTA in the recording electrode or replacing extracellular Ca2+ with Ba2+ reduced the effect of prepulses. Slowing Ca2+ extrusion by reducing the Na+ gradient across the cell increased the duration of the effect of prepulses. We conclude that the low threshold, transient current is inactivated primarily by membrane voltage while both the high threshold currents are inhibited by elevation of intracellular Ca2+ although the two currents display different sensitivities to Ca2+ concentration. Inhibition of the high threshold transient current by the neurotransmitter dopamine, however, acts by a different mechanism not mediated by Ca(2+)-dependent inactivation.     

Postdecentralization plasticity of voltage-gated K+ currents in glandular sympathetic neurons in rats

This paper presents the kinetic and pharmacological properties of voltage-gated K(+) currents in anatomically identified glandular postganglionic sympathetic neurons isolated from the superior cervical ganglia in rats. The neurons were labelled by injecting the fluorescent tracer Fast Blue into the submandibular gland. The first group of neurons remained intact, i.e. innervated by the preganglionic axons until the day of current recordings (control neurons). The second group of neurons was denervated by severing the superior cervical trunk 4-6 weeks prior to current recordings (decentralized neurons). In every control and decentralized neuron three categories of voltage-dependent K(+) currents were found. (i) The I(Af) K(+) current, steady state, inactivated at hyperpolarized membrane potentials. This current was fast activated and fast time-dependently inactivated, insensitive to TEA and partially depressed by 4-AP. (ii) The I(As) K(+) current, which was steady-state inactivated at less hyperpolarized membrane potentials than I(Af). The current activation and time-dependent inactivation kinetics were slower than those of I(Af). I(As) was blocked by TEA and partially inhibited by 4-AP. (iii) The IK K(+) current did not undergo steady-state inactivation. In decentralized compared to control neurons the maximum I(Af) K(+) current density (at +50 mV) increased from 116.9 +/- 8.2 to 189.0 +/- 11.5 pA/pF, the 10-90% current rise time decreased from 2.3 to 0.7 ms and the recovery from inactivation was faster. Similarly, in decentralized compared to control neurons the maximum I(As) K(+) current density (at +50 mV) increased from 49.9 +/- 3.5 to 74.3 +/- 5.0 pA/pF, the 10-90% current rise time shortened from 29 to 16 ms and the recovery from inactivation of the current was also faster. The maximum density (at +50 mV) of I(K) in decentralized compared to control neurons decreased from 76.6 +/- 3.9 to 60.7 +/- 6.3 pA/pF. We suggest that the upregulation of voltage-gated time-dependently-inactivated K(+) currents and their faster recovery from inactivation serve to restrain the activity of glandular sympathetic neurons after decentralization.     

Ionic currents determining the membrane characteristics of type I spiral ganglion neurons of the guinea pig

Enzymatically isolated type I spiral ganglion neurons of the guinea pig have been investigated in the present study. The identity of the cells was confirmed by using anti-neuron-specific enolase immunostaining. The presence and shredding of the myelin sheath was also documented by employing anti-S100 immunoreaction. The membrane characteristics of the cells were studied by using the whole-cell patch-clamp technique. The whole-cell capacitance of the cells was 9 +/- 2 pF (n = 51), while the resting membrane potential of the cells was -62 +/- 9 mV (n = 19). When suprathreshold depolarizing stimuli were applied, the neurons fired a single action potential at the beginning of the stimulation. It was confirmed in this study that type I spiral ganglion cells possess a hyperpolarization-activated nonspecific cationic current (Ih). The major characteristics of this current component were unaffected by the enzyme treatment. Type I spiral ganglion cells also expressed various depolarization-activated K+ current components. A high-threshold outward current was sensitive to 1-10 mm TEA+ application. The ganglion cells also expressed a relatively small, but nevertheless present, transient outward current component which was less sensitive to TEA+ but could be inhibited by 100 micro m 4-aminopyridine. A DTX-I-sensitive current was responsible for some 30% of the total outward current (at 0 mV), showed rapid activation at membrane potentials positive to -50 mV and demonstrated very little inactivation. However, inhibition of the highly 4-AP- or DTX-I-sensitive component did not alter the rapidly inactivating nature of the firing pattern of the cells.     

Membrane currents in identified lactotrophs of rat anterior pituitary

Qualitative features of the primary inward and outward current components of identified lactotrophs of the rat anterior pituitary were examined. Identification of lactotrophs in heterogeneous dissociated anterior pituitary cultures was accomplished by application of the reverse hemolytic plaque assay. Currents in lactotrophs were subsequently examined using whole-cell or patch recording techniques. Two components of inward calcium current were observed: a transient component and a sustained component. The transient component activated at voltages as negative as -50 mV and was the major contributor to total lactotroph calcium current. The sustained component activated at voltages above about -10 mV. The 2 currents could be qualitatively separated by differences in inactivation properties and in sensitivity to cadmium. At least 3 components of outward current were distinguished. Either 30 mM TEA or 0 calcium eliminated a major portion of sustained outward current. This is likely to represent primarily calcium- and voltage-activated potassium current. The remaining current could be further differentiated into a transient current component that could be inactivated with conditioning potentials above -60 mV. A slowly activating and deactivating potassium current remained following inactivation of the transient current. Although the time course of the transient current is reminiscent of "A" current, activation of this current required potentials above -30 mV. Candidates for the single-channel currents that underlie the whole-cell outward currents were observed in cell-attached recordings. When combined with patch-clamp electrophysiological methods, the reverse hemolytic plaque assay promises to be a powerful technique for the electrophysiological characterization of specific cell subtypes in heterogeneous dissociated cell populations.     

Ciguatoxin-induced oscillations in membrane potential and action potential firing in rat parasympathetic neurons

The actions of ciguatoxins from the Pacific (P-CTX-1) and Caribbean (C-CTX-1) regions were investigated in isolated parasympathetic neurons from rat intracardiac ganglia using patch-clamp recording techniques. Under current-clamp conditions, bath application of P-CTX-1 (1-10 nm) or C-CTX-1 (10-30 nm) caused a gradual depolarization that was accompanied by oscillation of the membrane potential leading to tonic action potential firing. Membrane potential oscillations were observed between -45 and -60 mV and had an amplitude of 10-20 mV and a mean frequency of 10 Hz. Oscillation frequency was temperature-dependent with a Q10 of 2.0. Membrane oscillations were temporarily inhibited by hyperpolarizing current pulses and potentiated by weak depolarizing current pulses. The amplitude of oscillations was reduced upon lowering the external Na+ concentration and inhibited by tetrodotoxin (TTX), tetracaine or Zn2+. Tetraethylammonium, 4-aminopyridine, Cs+, Cd2+, Ba2+, 1,4,4'-diothiocyanato-2,2'-stilbenedisulphonic acid (DIDS) and ouabain had no effect on the CTX-1-induced membrane depolarization and oscillations. Brevetoxin (PbTx-3, 100 nm), in contrast to CTX-1, caused a membrane depolarization that was not associated with oscillation of the membrane potential. Under voltage-clamp conditions, P-CTX-1 inhibited the peak amplitude of the voltage-dependent Na+ current and shifted the activation curve to more negative potentials, but membrane oscillations were not seen in this configuration. These results suggest that ciguatoxins cause oscillation of the membrane potential in mammalian autonomic neurons by modifying the activation and inactivation properties of a population of TTX-sensitive Na+ channels.     

Properties of the Hyperpolarization-activated Cation Current lh in Rat Midbrain Dopaminergic Neurons

Intracellular electrophysiological recordings in current- and voltage-clamp mode were obtained from dopaminergic neurons of the rat mesencephalon in an in vitro slice preparation. In current-clamp mode, a time-dependent anomalous rectification (TDR) of the membrane was observed in response to hyperpolarizing current pulses. In single-electrode voltage-clamp mode, a slowly developing inward current (l_h) underlying the TDR was studied by hyperpolarizing voltage commands from a holding potential of -50 to -60 mV. l_h started to be activated at -69 mV, was fully activated at -129 to -141 mV, with half-maximal activation at -87 mV, and showed no inactivation with time. The time course of development of Ih followed a single exponential, and its time constant was voltage-dependent. At -81 mV, l_h activated with a time constant of 379 2 47.6 ms, whereas at -129 mV l_h activated with a time constant of 65 ? 2.2 ms. Its estimated reversal potential was -35 ± 4 mV. Raising the extracellular concentration of K⁺ from 2.5 to 6.5 and to 12.5 mM increased the amplitude of l_h while reducing the extracellular concentration of Na⁺ from 153.2 to 27.2 mM caused a reduction in amplitude of l_h. Bath application of caesium (1–5 mM) reversibly reduced or blocked the TDR/l_h. Perfusion of tetrodotoxin (0.5–1 μM), tetraethylammonium (10–20 mM) or barium (0.3–2 mM) did not significantly affect l_h. l_h was also present in cells impaled with CsCI-filled electrodes. When l_h was substantially reduced by extracellular caesium (1 mM) the firing rate of the dopaminergic cells, which consisted of a spontaneous pacemaker discharge of action potentials, was not clearly changed. In addition, the holding current in voltage-clamp experiments at -50 to -60 mV was not affected by 1 mM caesium. We conclude that although the l_h current is a typical feature of the dopaminergic neurons, it is neither a significant factor underlying the spontaneous pacemaker activity nor does it contribute substantially to the setting of the normal resting potential level of the membrane. On the other hand, since l_h starts at voltages lower than or equal to -69 mV (below firing threshold), it may play a modulatory role in the cell's excitability by limiting the amplitude and duration of any prolonged hyperpolarizing events in the dopaminergic cells.     

Identified glial cells in the early postnatal mouse hippocampus display different types of Ca2+ currents

Based on their typical pattern of membrane currents, four populations of glial cells could be identified in thin brain slices of the postnatal hippocampus. In the present study, we applied the patch-clamp technique to glial cells in the hippocampal CA1 region, which are characterized by a complex pattern of different Na⁺ and K⁻ currents (“complex” cells). These cells were identified as non-neuronal cells, most likely astrocytes, by their glutamine synthetase immunoreactivity. Two types of glial Ca²⁺currents could be identified that differed in their kinetics and pharmacological properties. A low-voltage activated (LVA), fast inactivating component was activated at membrane potentials positive to −60 mV and reached maximum current amplitudes at about −20 mV. This current was sensitive to amiloride and thus displayed properties of neuronal LVA currents. The threshold potential of the second Ca²⁺ current component was at about −40 mV, and peak currents were observed at 0 mV. In contrast to the LVA component, the inactivation of these high-voltage activated (HVA) currents slowed down with increasing depolarizations. This current was sensitive to low concentrations of Cd²⁺ but was not affected by amiloride. A small fraction of the HVA currents was sensitive to nifedipine, and ω-conotoxin GVIA (ω-CgTx) was also found to reduce the glial HVA component. The study provides electrophysiological and pharmacological characterization of different types of Ca²⁺ currents in gray matter glial cells in situ. © 1996 Wiley-Liss, Inc.     

Calcium current in type I hair cells isolated from the semicircular canal crista ampullaris of the rat

The low voltage gain in type I hair cells implies that neurotransmitter release at their afferent synapse should be mediated by low voltage activated calcium channels, or that some peculiar mechanism should be operating in this synapse. With the patch clamp technique, we studied the characteristics of the Ca(2+) current in type I hair cells enzymatically dissociated from rat semicircular canal crista ampullaris. Calcium current in type I hair cells exhibited a slow inactivation (during 2-s depolarizing steps), was sensitive to nimodipine and was blocked by Cd(2+) and Ni(2+). This current was activated at potentials above -60 mV, had a mean half maximal activation of -36 mV, and exhibited no steady-state inactivation at holding potentials between -100 and -60 mV. This data led us to conclude that hair cell Ca(2+) current is most likely of the L type. Thus, other mechanisms participating in neurotransmitter release such as K(+) accumulation in the synaptic cleft, modulation of K(+) currents by nitric oxide, participation of a Na(+) current and possible metabotropic cascades activated by depolarization should be considered.     

The low-threshold Ca current in isolated amygdaloid neurons in the rat

Two types of voltage-dependent Ca currents were recorded from isolated rat amygdaloid neurons under single-electrode voltage-clamp. A low-threshold Ca current was elicited at -60 mV or more positive potentials and inactivated rapidly. At -30 mV or more positive potentials, a high-threshold Ca current was also activated. In steady-state inactivation curve of the low-threshold Ca current, the half-inhibition value (h0.5) was -71 mV. The low-threshold Ca current was inhibited by organic and inorganic Ca blockers in a dose-dependent manner. The inhibitory effect of these Ca blockers was completely reversible while that of flunarizine was partly so. It is concluded that the membrane and pharmacological properties of the low-threshold Ca channel in the rat amygdaloid neurons are quite similar to those in the hypothalamic neurons.     

Low-threshold transient calcium current in rat hippocampal lacunosum-moleculare interneurons: kinetics and modulation by neurotransmitters.

Interneurons from the CA1 lacunosum-moleculare (L-M) region were isolated by trypsin-hyaluronidase treatment and mechanical trituration of the L-M. Interneurons isolated in this manner were multipolar with several dendritic processes and could be distinguished from CA1 pyramidal neurons. The properties of a low-threshold transient (LTT) Ca2+ current were investigated using whole-cell voltage-clamp techniques. The activation threshold of the LTT Ca2+ current was -60 mV, and the peak current, 100 +/- 9 pA (mean +/- SEM; n = 15), was observed at -30 mV. Ca2+ was the predominant charge carrier because the current was not affected by tetrodotoxin and was abolished in Ca(2+)-free external solution. Steady state inactivation was observed when the holding potential was positive to -100 mV, and the current was half-inactivated at -84 mV. Complete inactivation occurred at a holding potential of -60 mV. The time-to-peak of the current was highly voltage dependent and ranged from 10 msec at -60 mV to 4 msec at 0 mV. The time constant of inactivation was also voltage dependent and ranged from 27 msec at -60 mV to 12 msec at greater than -30 mV. Recovery from inactivation to 90% of maximum current occurred within 200 msec. L-M interneurons receive synaptic inputs from the septum that release ACh or GABA and from the raphe nuclei that release 5-HT. Carbachol, a nonhydrolyzable cholinergic agonist, and 5-HT quickly and reversibly increased the amplitude of the LTT Ca2+ current. Carbachol's actions were blocked by atropine, indicating that this effect was mediated by muscarinic receptors.(ABSTRACT TRUNCATED AT 250 WORDS)     

Voltage- and ligand-activated inwardly rectifying currents in dorsal raphe neurons in vitro

Intracellular recordings were made from neurons in rat dorsal raphe in the slice preparation maintained at 37 degrees C. The single-electrode voltage-clamp method was used to measure membrane currents at potentials more negative than rest (-60 mV). Three types of inward rectification were observed: 2 in the absence of any drugs and the third induced by 5-HT 1 and GABA-B receptor agonists. In the absence of any drugs, an inward current activated over 1-2 sec when the membrane potential was stepped to potentials more negative than -70 mV. This current was blocked by cesium (2 mM) and resembles IQ or IH. A second inward current (IIR) occurred at membrane potentials near the potassium equilibrium potential (EK). This inward current activated within the settling time of the clamp and was abolished by both barium (10-100 microM) and cesium (2 mM). 5-HT 1 agonists activated a potassium conductance that hyperpolarized the cells at rest. This potassium conductance was about 2 nS at -60 mV and increased linearly with membrane hyperpolarization to about 4 nS at -120 mV. Baclofen activated a potassium conductance identical in amplitude and voltage dependence to that induced by 5-HT 1 agonists. Both the baclofen- and 5-HT-induced currents were nearly abolished in animals pretreated with pertussis toxin. The results indicate that a common potassium conductance is increased by 5-HT acting on 5-HT 1 receptors and baclofen acting on GABA-B receptors. This potassium conductance rectifies inwardly and is distinct from the Q-current. The ligand-activated potassium conductance also differs from the other form of inward rectification (IIR) in its voltage dependence and sensitivity to pertussis toxin.