Fluctuation analysis of nonselective cation currents induced by AlF complex in guinea-pig chromaffin cells

Properties of aluminium fluoride (AlF) complex-activated nonselective cation (NS) channels in guinea-pig chromaffin cells were investigated using the patch clamp technique. As the membrane potential was hyperpolarized from the holding potential of −55 mV, the AlF-induced nonselective cation current (I_NS) diminished progressively. With hyperpolarizations to −100 mV or more negative potentials, the AlF I_NS almost instantaneously disappeared. The apparent unit conductance of AlF I_NS was estimated to be 3 pS by fluctuation analysis. The open state probability of AlF-activated NS channels became large with a decrease in concentration of free Mg²⁺ ions inside the cell and was less than 0.5 at 12 μM Mg²⁺. It is concluded that NS channels in the chromaffin cell apparently differ from those in smooth muscle cells.     

Interactions of dextromethorphan with theN-methyl-d-aspartate receptor-channel complex: single channel recordings

The actions of dextromethorphan (DXM) on the 50 pS conductance state of theN-methyl-d-aspartate (NMDA) receptor-operated channel were studied using outside-out patches obtained from cultured rat hippocampal pyramidal neurons. DXM (5–50 μM) had no effect on the amplitudes of unitary currents but caused concentration-dependent reductions in channel mean open times and the frequency of channel openings. Channel open probability was reduced in a concentration-dependent manner by DXM and was one-half of the control value at a DXM concentration of 6 μM, with the patch potential held at −60 mV. An IC₅₀ value of 4 μM was obtained for the reduction by DXM of NMDA-evoked rises in [Ca²⁺]_i in cultured rat hippocampal pyramidal neurons loaded with Fura-2. The results were consistent with drug block of the open NMDA channel with an onward (blocking) rate constant of 7.7 × 10⁶ M⁻¹ · s⁻¹ (at −60 mV). The estimated unblocking rate constant was about 10 s⁻¹, a value considerably higher compared to the off-rate constant found for dizocilpine block of the NMDA channel.     

Voltage Oscillations in Xenopus Spinal Cord Neurons: Developmental Onset and Dependence on Co-activation of NMDA and 5HT Receptors

The development of intrinsic, N-methyl-D-aspartate (NMDA) receptor-mediated voltage oscillations and their dependence on co-activation of 5-hydroxytryptamine (5HT) receptors was explored in motor neurons of late embryonic and early larval Xenopus laevis. Under tetrodotoxin, 100 μM NMDA elicited a membrane depolarization of around 20 mV, but did not lead to voltage oscillations. However, following the addition of 2–5 μM 5HT, oscillations were observed in 12% of embryonic and 70% of larval motor neurons. The voltage oscillations depended upon co-activation of NMDA and 5HT receptors since they were curtailed by selectively blocking NMDA receptors with D-2-amino-5-phosphonovaleric acid (APV) or by excluding Mg²⁺ from the experimental saline. 5HT applied in the absence of NMDA also failed to elicit oscillations. Oscillations could be induced by the non-selective 5HT_1a receptor agonist, 5-carboxamidotryptamine (5CT) and both 5HT- and 5CT-induced oscillations were abolished by pindobind-5HT₁, a selective 5HT_1a receptor antagonist. To test whether 5HT enables voltage oscillations by modulating the voltage-dependent block of NMDA channels by Mg²⁺, membrane conductance was monitored under tetrodotoxin. Although 5HT caused membrane hyperpolarization of 4–8 mV, there was little detectable change in conductance. NMDA application caused an approximate 20 mV depolarization and an ‘apparent’ decrease in conductance, presumably due to the conductance pulse bringing the membrane into a voltage region where Mg²⁺ blocks the NMDA ionophore. 5HT further decreased conductance, which we propose is due to its enhancement of the voltage-dependent Mg²⁺ block. When the membrane potential was depolarized by ～20 mV via depolarizing current injection (to mimic the NMDA-induced depolarization), 5HT increased rather than decreased membrane conductance. Furthermore, 5HT did not affect the increase in membrane conductance following NMDA applications in zero Mg²⁺ saline. The results suggest that intrinsic, NMDA receptor-mediated voltage oscillations develop in a brief period after hatching, and that they depend upon the co-activation of 5HT and NMDA receptors. The enabling function of 5HT may involve the facilitation of the voltage-dependent block of the NMDA ionophore by Mg²⁺ through activation of receptors with 5HT_1a-like pharmacology.     

Macroscopic and single-channel chloride currents in neuropile glial cells of the leech central nervous system

In patch-clamp experiments we characterized four Cl⁻ channels (42 pS, 70 pS, 80 pS and 229 pS) underlying the large Cl⁻ conductance of leech neuropile glial cells. They differed with respect to their gating, their rectification and their activity in the cell-attached configuration, showed the selectivity sequence I⁻>Br⁻≥Cl⁻>F⁻ and were impermeable to SO₄²⁻. The four channels were blocked by NPPB, DPC, niflumic acid and DIDS and exhibited either three or four sublevel states. The outward rectifying 42 pS, 70 pS and 80 pS Cl⁻ channels were classified as intermediate conductance Cl⁻ channels and they could contribute to the high Cl⁻ conductance of the glial membrane, which stabilizes the glial membrane potential. The inward rectifying 229 pS Cl⁻ channel is very similar to vertebrate high conductance Cl⁻ channels, which are assumed to be part of an emergency system that is activated under pathophysiological conditions. In voltage-clamp experiments we calculated that the Cl⁻ conductance amounts to one-third of the total membrane conductance. Reduction of this Cl⁻ conductance by Cl⁻ channel inhibitors markedly depolarized the glial cell membrane. These prominent depolarizations depended on Na⁺ influx and in most cases the glial cells failed to regulate their membrane potential following wash-out of the inhibitors.     

Potassium and sodium channels in human malignant glioma cells

Human malignant glioma cells from 5 different cell lines were voltage clamped and examined for the presence of depolarization-activated ion channels. Outward K-currents were elicited at membrane potentials > 40 mV, which had two main components, one which was delayed and blocked by externally applied tetraethylammonium (TEA, 10 mM), and another which was instantaneous and insensitive to TEA in the outside solution. The proportion of the two K-current components varied between cell lines. An increase in [Ca²⁺] in the range 0–4 mM, decreased the leak conductance and shifted the activation of the instantaneous outward K-current towards more positive potenttials. Mg²⁺, Zn²⁺ and Co²⁺ had qualitatively similar effects. Patch recordings with 150–160 mM K⁺-solution on both sides of the membrane revealed that the delayed outward K-current was carried through large conductance (250–300 pS) channels. Changes in free [Ca²⁺]_i from 0 to 2 × 10⁻⁸ M increased the activation of the large conductance K-channel. Small Na-currents were identified in cells from one cell line (Tp-378MG). The Na-conductance rangedfrom 0.5 to 7.5 nS in 25% of the cells, and was less than 0.5 nS in 75%. The Na-channels were activated and inactivated at 30–40 mV more positive potentials than in the mammalian peripheral nerve. Tetrodotoxin (100 mM) blocked g_Na almost completely.     

Two distinct propagating regenerative potentials in a single ethanol-treated axon

Superfusion of the cockroach (Periplaneta americana) giant axon by ethanol (0.5–2%) produces conditions which allow the generation and active propagation of two kinds of regenerative potentials. (a) The classical action potential with a threshold at about 30 mV above resting potential, an amplitude of about 105 mV, a duration of 1–2 ms, and a conduction velocity of 3–6 m/s. (b) A smaller depolarizing potential (SDP) with a threshold of 5–15 mV above resting level, an amplitude of 10–30 mV, a duration of several hundred ms and a conduction velocity of 0.1–0.6 m/s. The SDP is associated with a small increase in conductance (10–15%), and is abolished by tetrodotoxin (10⁻⁶ M) or by removing extracellular sodium. The amplitude of the SDP slightly increases when the extracellular Ca²⁺ concentration is elevated and is reduced at low (Ca²⁺)₀ concentration; however, it is not blocked in a solution containing high Mg²⁺ (19 mM), low Ca²⁺ (1 mM) concentrations, indicating that inward Ca²⁺ current is not required for the generation of SDP.     

Possible modulatory role of voltage-activated Ca currents determining the membrane properties of isolated pyramidal neurones of the rat dorsal cochlear nucleus

Voltage-activated Ca²⁺ currents have been studied in pyramidal cells isolated enzymatically from the dorsal cochlear nuclei of 6–11-day-old Wistar rats, using whole-cell voltage-clamp. From hyperpolarized membrane potentials, the neurones exhibited a T-type Ca²⁺ current on depolarizations positive to −90 mV (the maximum occurred at about −40 mV). The magnitude of the T-current varied considerably from cell to cell (−56 to −852 pA) while its steady-state inactivation was consistent (E₅₀=−88.2±1.7 mV, s=−6.0±0.4 mV). The maximum of high-voltage activated (HVA) Ca²⁺ currents was observed at about −15 mV. At a membrane potential of −10 mV the L-type Ca²⁺ channel blocker nifedipine (10 μM) inhibited approximately 60% of the HVA current, the N-type channel inhibitor ω-Conotoxin GVIA (2 μM) reduced the current by 25% while the P/Q-type channel blocker ω-Agatoxin IVA (200 nM) blocked a further 10%. The presence of the N- and P/Q-type Ca²⁺ channels was confirmed by immunochemical methods. The metabotropic glutamate receptor agonist (±)-1-aminocyclopentane-trans-1,3-dicarboxylic acid (200 μM) depressed the HVA current in every cell studied (a block of approximately 7% on an average). The GABA_B receptor agonist baclofen (100 μM) reversibly inhibited 25% of the HVA current. Simultaneous application of ω-Conotoxin GVIA and baclofen suggested that this inhibition could be attributed to the nearly complete blockade of the N-type channels. Possible physiological functions of the voltage-activated Ca²⁺ currents reported in this work are discussed.     

Activation of a non-specific cation conductance by intracellular injection of inositol 1,3,4,5-tetrakisphosphate into identified neurons of Aplysia

The ionic mechanism of the effect of intracellulary injected inositol 1,3,4,5-tetrakisphosphate (IP₄) on the membrane of identified neurons (R9–R12) of Aplysia kurodai was investigated with conventional voltage-clamp, pressure injection, and ion-substitution techniques. Intracellular injection of IP₄ into a neuron voltage-clamped at −45 mV reproducibly induced a slow inward current (20–60 s in duration, 3–5 nA in amplitude) associated with a conductance increase. The current was decreased by depolarization and increased by hyperpolarization. The extrapolated reversal potential was −21 mV. The IP₄-induced inward current was sensitive to changes in the external Na⁺, Ca²⁺ and K⁺ concentration but not to changes in Cl⁻ concentration, and was resistant to tetrodotoxin (50 μM). When the cell was perfused with tetraethylammonium (5 mM) but not with 4-aminopyridine (5 mM), the IP₄-induced inward current recorded at −45 mV slightly increased. The IP₄-induced inward current was partially reduced by calcium channel blockers (Co²⁺ and Mn²⁺). These results suggest that intracellularly injected IP₄ can activate a non-specific cation conductance.     

Single potassium channels in neuropile glial cells of the leech central nervous system

We performed patch-clamp experiments to identify distinct K⁺ channels underlying the high K⁺ conductance and K⁺ uptake mechanism of the neuropile glial cell membrane on the single-channel level. In the soma membrane four different types of K⁺ channels were characterized, which were found to be distributed in clusters. Since no other types of K⁺ channels were observed, these appear to be the complete repertoire of K⁺ channels expressed in the soma region of this cell type. The outward rectifying 42 pS K⁺ channel could markedly contribute to the high K⁺ conductance and the maintenance of the membrane potential, since it shows the highest open probability of all channels. The channel gating occurred in bursts and patch excision decreased the open probability. The outward rectifying 74 pS K⁺ channel was rarely active in the cell-attached configuration; however, patch excision enhanced its open probability considerably. This type of channel may be involved in neuron-glial crosstalk, since it is activated by both depolarizations and increases in the intracellular Ca²⁺ concentration, which are known to be induced by neurotransmitter release following the activation of neurons. The 40 pS and 83 pS K⁺ channels showed inward rectifying properties, suggesting their involvement in the regulation of the extracellular K⁺ content. The 40 pS K⁺ channel could only be observed in the inside-out configuration. The 83 pS channel was activated following patch excision. At membrane potentials more negative than −60 mV, flickering events indicated voltage-dependent gating.     

N-methyl-D-aspartate receptors coexist with kainate and quisqualate receptors on single isolated catfish horizontal cells

Horizontal cells enzymatically isolated from catfish retina were exposed to the putative neurotransmitters aspartate (Asp) or N-methyl-D-aspartate (NMDA). Under voltage clamp conditions, inward currents were recorded when the holding potential was more negative than zero and outward currents were recorded when the membrane potential was more positive than zero. The current voltage curve was highly non-linear in the range of membrane potential between −30 and −100 mV. This non-linearity was largely removed in zero magnesium solution. 2-Amino-phosphonovaleric acid selectively blocked Asp and NMDA responses. These response characteristics are consistent with the presence of NMDA receptors in these cells.     

Cation permeability change caused by l-glutamate in cultured rat hippocampal neurons

The ionic mechanism of the membrane permeability changes caused by l-glutamate in hippocampal neurons prepared from 17- to 19-day-old fetal rat in dispersed cell cultures was studied with the whole-cell variation of the patch electrode voltage-clamp technique. The cultured hippocampal neurons became sensitive to glutamate 7 days after plating, and thereafter the sensitivity gradually increased. The conductance increase caused by glutamate was voltage-sensitive, decreasing with membrane hyperpolarization at potentials more negative than -40 mV. The relative permeability of glutamate-activated channels to alkali metal and alkaline earth cations was estimated by reversal potential measurements. The alkali metal cations, Li+, Na+, K+, Rb+ and Cs+ were permeant to the glutamate channels, and the selectively among them was weak. The alkaline earth cations, Ca²⁺, Sr²⁺ and Ba²⁺ were more permeant than the alkali metals. The permeability ratios of these divalent cations relative to Na+ were 2.4 (Ca²⁺), 2.4 (Sr²⁺) and 2.8 (Ba²⁺), respectively. Mg²⁺ was much less permeant and the permeability ratio (P_Mg/P_Na) was only 0.1. Anion conductance made no contribution to the glutamate-induced current. Functional implications of the glutamate-induced increase in Ca²⁺-influx were discussed.     

Evidence forN-methyl-d-aspartic acid receptor-mediated modulation of the commissural input to central vestibular neurons of the frog

We have investigated the role ofN-methyl-d-asparte (NMDA) receptors in the excitatory synaptic transmission to central vestibular neurons in the isolated superfused brainstem of the frog. In superfusate containing 1 mM Mg²⁺ field potentials in the vestibular nuclei evoked by electrical stimulation of either the ipsi- or the contralateral VIIIth nerve were not affected by bath-appliedd-2-amino-5-phosphonovaleric acid (D-APV, 25–50 μM), a selective NMDA antagonist. In a low Mg²⁺ solution postsynaptic field potential components were larger than control but still unaffected by D-APV. Ipsi- and contralaterally evoked excitatory postsynaptic potentials (EPSPs) differed in their shape parameters as well as their pharmacological sensitivity. Ipsilaterally evoked EPSPs were not affected by D-APV and had a rise time that was faster than that of contralaterally evoked EPSPs. The peak amplitude of the latter was reduced by D-APV (25–50 μM) to about 65% of the control value in the presence of 1 mM Mg²⁺. During bath application of NMDA (100 μM) an increased input resistance and repetitive de- and hyperpolarizing membrane potential shifts were observed. Similar events were observed during a reduction of the Mg²⁺ concentration. Bath application of NMDA (0.1–1 μM) resulted in an enhanced size of the recorded EPSPs. Dendritic and somatic EPSPs were stimulated on a computer with the assumption of a constant NMDA receptor activation and a pulse-like non-NMDA receptor activation. The results of these stimulations are consistent with the hypothesis that the efficacy of non-NMDA-mediated vestibular commissural synaptic transmission is modulated through tonically activated NMDA receptors.     

Synaptic contributions to θ rhythm genesis in rat CA1–CA3 hippocampal pyramidal neurons in vivo

The effects of intracellular Cl⁻ diffusion and hyperpolarizing current pulses on inhibitory postsynaptic potentials (IPSPs) and the transmembrane theta rhythm of CA1–CA3 pyramidal neurons were tested in urethanized and curarized rats. Cl⁻ diffusion and hyperpolarizing currents decreased the amplitude of IPSPs evoked by fornix stimulation without modifying the θ rhythm amplitude and phase. The membrane conductance was typically 22–46% higher at the positive than negative intracellular θ peaks. Results indicate that in curarized rats excitatory postsynaptic potentials were the main components of intracellular θ without an important participation of IPSPs in θ rhythm genesis.     

Mg dependence of membrane resistance increases evoked by NMDA in hippocampal neurones

The response of granule cells and CA1 pyramidal neurones to NMDA was studied in the presence of and absence of Mg²⁺ using an in vitro slice preparation. In the absence of Mg²⁺ the depolarizing response of hippocampal neurones to NMDA is accompanied by a decrease in input resistance. In the presence of Mg²⁺ ions, however, the response to NMDA is always associated with an apparent increase in input resistance. These results indicate that the action of NMDA is by a classical mechanism of conductance increase and are in agreement with the suggestion that the apparent increase in input resistance associated with NMDA depolarizations is the result of voltage-dependent channel block by Mg²⁺ of the NMDA evoked current.     

Prostaglandin E2 excites neurons of the nucleus tractus solitarius by activating cation channels

Nucleus tractus solitarius (NTS) has a high density of prostaglandin E₂ (PGE₂)-binding sites. Action of PGE₂ (10⁻⁹–10⁻⁶ M) was tested on neurons in a NTS slice with patch-clamp recording under synaptic blockade. PGE₂ raised the firing rate in approximately half of the neurons in cell-attached patch mode. In whole-cell current clamp, PGE₂ depolarized membrane potential accompanied by an increase in firing rate. In whole-cell voltage clamp (−58 mV), PGE₂ induced the inward current with an increase in conductance. The current was linearly related to voltage from −100 mV to −10 mV and suppressed between −10 mV and 20 mV. The current-voltage curve remained similar under low external Cl⁻ or high internal Cl⁻ conditions and after external Na⁺ was replaced by Cs⁺. It is concluded that PGE₂ excites NTS neurons by activating cation conductance.     

Action potential-like responses in B 104 cells with low Na channel densities

Action potential generation and Na⁺ currents were studied in B104 neuroblastoma cells in vitro using the whole-cell patch-clamp method in voltage-clamp and current-clamp mode. Action potential-like responses were elicited in 38 of 42 cells, with a threshold close to −55 mV for depolarizing stimuli, and −56 mV for anode-break stimuli. Response amplitudes were larger when cells were held at more negative prepulse potentials, and were well fit by a Boltzmann distribution with a midpoint of approx. −75 mV, close to theV_1/2 for Na⁺ current steady-state inactivation in these cells. Cells displaying action potential-like responses exhibited a peak Na⁺ current density of 133 ± 0.14 pA/pF (range, 10.2–296.2 pA/pF) and a lowg_K: g_Na ratio (0.0067 ± 0.0023). Exposure to 0.1 mM Cd²⁺ did not block the generation of action potential-like responses in B104 cells, while 1 μM TTX abolished the responses. We conclude that low densities of Na⁺ channels ( < 3/μm² and < 1/μm² in some cells) can support the generation of action potential-like responses in B104 cells if they are held at hyperpolarized levels to remove inactivation. The low leak and K⁺ conductance of these cells may contribute to their ability to generate action potential-like responses under these circumstances.     

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.     

Inhibition of calcium currents in cultured myenteric neurons by neuropeptide Y: evidence for direct receptor/channel coupling.

Single channel recordings from rat myenteric plexus neurons demonstrated the presence of two categories of Ca2+ channels. One type of Ca channel had a slope conductance of 27 pS and was sensitive to dihydropyridines while the other channel type had a conductance of 14 pS and was dihydropyridine-insensitive. The 14 pS channel was mostly inactivated at a holding potential of -40 mV, while the 27 pS channel was much more resistant to depolarized holding potentials. A majority of whole-cell current was reprimed by the use of negative holding (-90 mV) potentials, when compared to that obtained at a holding potential of -40 mV. These properties are consistent with N- and L-type Ca channels previously described. In general, the inactivating part of the whole-cell Ca2+ current, selectively reprimed by negative holding potentials, was inhibited by neuropeptide Y (NPY). Depolarization-induced [Ca2+]i transients assessed using fura-2 showed that the inhibitory effects of nitrendipine and NPY were additive. The effects of NPY were abolished by pertussis toxin pretreatment. Single-channel experiments showed that neither the 14 nor the 27 pS Ca channel currents were inhibited by the addition of NPY outside the patch pipette. These results suggest that NPY modulates N-type Ca2+ channels selectively in these neurons and that an easily diffusible second messenger does not appear to participate in receptor/channel coupling.     

GABAA receptor stimulation blocks NMDA-induced bursting of dopaminergic neurons in vitro by decreasing input resistance

The effects of the GABA_A agonist, isoguvacine, on NMDA-induced burst firing of substantia nigra dopaminergic neurons were studied with intracellular and whole cell recordings in vitro. NMDA application caused the neurons to fire in rhythmic bursts. Although the NMDA-induced bursty firing pattern was insensitive to hyperpolarization by current injection, it was reversibly abolished by the selective GABA_A agonist, isoguvacine. The block of the rhythmic burst pattern by isoguvacine application occurred regardless of whether the chloride reversal potential was hyperpolarizing (E_Cl⁻=−70 mV) or depolarizing (E_Cl⁻=−40 mV). In either case, the input resistance of the dopaminergic neurons was dramatically decreased by application of isoguvacine. It is concluded that GABA_A receptor activation by isoguvacine disrupts NMDA receptor-mediated burst firing by increasing the input conductance and thereby shunting the effects of NMDA acting at a distally located generator of rhythmic burst firing.