Actions of Glycine on Non-dopaminergic Neurons of the Rat Substantia Nigra

The effects of glycine on non-dopaminergic cells in rat substantia nigra pars compacta and pars reticulata maintained in vitro were investigated using intracellular recording techniques. Glycine, superfused at a concentration between 30 μM and 1 mM, reversibly blocked the spontaneous firing of these neurons. The inhibition of firing discharge was associated with a hyperpolarization of the membrane (potassium acetate-filled electrodes) and an increase in conductance. Under voltage-clamp experiments (holding potential between -57 and -65 mV), glycine produced an outward response which reversed polarity at about -74 mV. However, when the recording electrodes were filled with KCI, the glycinergic response was mainly depolarizing/inward and reversed at about -43 mV. Thus, it appeared to be due to an increase in chloride permeability. Furthermore, the effects of glycine were reversibly antagonized by strychnine (between 300 nM and 1 μM). Our findings demonstrate that glycine is a potent inhibitory agent on non-dopaminergic cells of the substantia pars compacta and pars reticulata that acts by activating strychnine-sensitive receptors.     

Membrane properties and response to opioids of identified dopamine neurons in the guinea pig hypothalamus

The electrophysiological properties and opioid responsiveness of the dopamine-containing neurons in the arcuate nucleus of the guinea pig hypothalamus were examined. Dopamine-containing neurons, identified immunocytochemically by the presence of tyrosine hydroxylase, had a mean length-to-width profile of 14.9 +/- 4.4 x 11.5 +/- 3.1 microns (N = 14). The Na+ action potential of these neurons was of short duration, and induction of repetitive firing (20-50 Hz) caused an afterhyperpolarization of 6-9 mV in amplitude, with a decay half-time of approximately 1.5 sec. Dopamine-containing cells exhibited a low threshold spike, which induced 1-4 Na+ action potentials. This potential had a threshold close to -65 mV, could not be induced without prior hyperpolarization and was not sensitive to TTX. Dopamine-containing neurons also exhibited a time- and voltage-dependent inward current at potentials negative to -70 mV, and Cs+ blocked this conductance. The mu-opioid agonist Tyr-D-Ala-Gly-mePhe-Gly-ol hyperpolarized (14 +/- 3 mV) dopamine neurons via induction of an outward current (93 +/- 44 pA near the resting membrane potential) which had a reversal potential similar to that expected for a selective potassium conductance. TTX (1 microM) did not block the opioid effects. These results show that dopamine neurons of the arcuate nucleus differ in their intrinsic conductances and their responsiveness to opioids from other CNS dopaminergic neurons. Furthermore, opioid activation of a potassium conductance resulted in a direct hyperpolarization of dopamine neurons of the arcuate nucleus, and we suggest that this mechanism may underlie the effects of opioids on dopamine-mediated prolactin release.     

Ionic conductances underlying the activity of interneurons that control heartbeat in the medicinal leech

Electrical properties of interneurons that control heartbeat in the leech (HN cells) were studied using intracellular recording and stimulation in isolated ganglia bathed by salines of various ionic compositions. Substitution of Na+ ions in the bath by Tris stopped the spontaneous firing of HN cells and led to their gradual hyperpolarization by 15-20 mV. In the absence of Na+, HN neurons produced long-lasting regenerative plateau potentials with thresholds near -55 mV and peaks near -30 mV that were accompanied by an increase in membrane conductance. Elevation of Ca2+ concentration enhanced plateaus, as did replacement of Ca2+ by Ba2+. Plateaus were formed when Sr2+ replaced Ca2+, but were blocked by addition of Mg2+ or Co2+ to the bath, Co2+ being effective at lower concentrations than Mg2+. Hyperpolarization of HN neurons with injected currents revealed a time-dependent change in membrane potential, whereby initial maximum hyperpolarization was followed by a "sag" in potential towards more depolarized values. The sag showed dual voltage dependence, being diminished when HN neurons were hyperpolarized or depolarized outside the normal range of oscillation. The sag was found to depend on the presence of Na+ ions and to be blocked by Cs+ but not by Ba2+. This time-dependent change in membrane potential counters hyperpolarizations of HN neuron membrane potential and may contribute to the escape of these neurons from synaptic inhibition.     

Potassium ions play a role in the glycine-induced inhibition of rat substantia nigra zona compacta neurones

Glycine directly inhibits the firing, it hyperpolarizes and/or depolarizes the dopaminergic neurones and increases the membrane conductance. In voltage clamp experiments (near resting potential) either outward and/or inward currents were produced. These actions were present in tetrodotoxin and in 0-calcium-cobalt-treated slices and were antagonized by strychnine. The hyperpolarization depended on the extracellular concentration of potassium and was prevented by cesium diffusion into the cell. Thus potassium ions participate in the glycine mediated inhibition of the firing of substantia nigra zona compacta cells.     

Opioids act at mu-receptors to hyperpolarize arcuate neurons via an inwardly rectifying potassium conductance

Intracellular recordings were made from 48 hypothalamic arcuate (ARC) neurons under current- and voltage-clamp in slices prepared from female guinea pigs which had been ovariectomized and pretreated with estradiol. Twenty ARC neurons were silent (RMP: -62 +/- 2 mV) and 28 cells were spontaneously active (7.3 +/- 1.1 Hz; threshold -57 +/- 1 mV). The input resistance (Rin), determined in the potential range between -60 and -80 mV, was 358 +/- 30 M omega (n = 38) and ARC neurons showed inward rectification at potentials negative to the equilibrium potential for potassium. The selective mu-opioid agonist Tyr-D-Ala-Gly-MePhe-Gly-ol (DAGO) was applied by pressure pipette application at concentrations of 10 or 20 microM. DAGO decreased spontaneous firing and it hyperpolarized 26 of 31 neurons (9.6 +/- 0.8 mV; range 3-21 mV). Concomitant with the hyperpolarization, DAGO caused a decrease in Rin of 32 +/- 3, and the reversal potential, measured from current-voltage plots, was -94 +/- 2 mV. These effects were mimicked by bath concentrations of 0.5-1.0 microM DAGO. In voltage clamp, DAGO caused an outward current to flow at -60 mV (range 50-185 pA, n = 6). This current reversed at -92 +/- 2 mV (n = 6) and exhibited inward rectification. An additional 6 ARC neurons were tested with DAGO in varying extracellular concentrations of K+ (2.5, 5 and 10 mM) and the reversal potential for the effect of DAGO shifted by 58 mV per decade change in extracellular K+ concentration. DAGO decreased spontaneous postsynaptic potentials in some cells, but TTX (1 microM) had no effect on the ability of DAGO to hyperpolarize the membrane. The hyperpolarization and decrease in Rin induced by DAGO were blocked by the opioid antagonist naloxone (100 nM-1 microM). DAGO responsive cells were unaffected by a kappa-opioid agonist (trans-(+/-)-3,4-dichloro-N-methyl-N-[2-(1- pyrrolidinyl)cyclohexyl]benzeneacetamide methanesulphonate; U50,488H), however, 2 of 5 cells also were hyperpolarized by a selective delta-receptor opioid agonist (Tyr-D-Pen-Gly-Phe-D-Pen; DPDPE). The effects of DPDPE, but not DAGO, were blocked by a delta-antagonist (ICI 174,864; 1 microM). The present results indicate that activation of ARC mu-receptors leads to an increase in an inwardly rectifying potassium conductance and a subsequent hyperpolarization of most ARC neurons. We suggest that this mu-receptor-induced hyperpolarization of ARC neurons may underlie the opioid inhibition of reproductive events in the mammal.     

Alpha1-adrenergic Effects on Dopamine Neurons Recorded Intracellularly in the Rat Midbrain Slice

Previous studies have indicated excitatory adrenergic effects on midbrain dopamine systems. To investigate the cellular mechanisms, intracellular recordings were made from neurons in perfused, oxygenated slices of male rat midbrain. Electrophysiological and pharmacological parameters were used to identify cells as principal (presumably dopaminergic) neurons as opposed to secondary (presumably GABAergic) neurons in the substantia nigra zona compacta and the ventral tegmental area. Noradrenalin (10–100 μM) hyperpolarized 57% of all principal cells and depolarized 36%. Sulpiride (100–1000 nM), a dopamine D₂ receptor antagonist, completely blocked noradrenalin-induced hyperpolarizations (six of six cells). In sulpiride, noradrenalin depolarized 58% of all principal neurons and had no effect in 42%; this effect was mimicked by the α-adrenergic agonist phenylephrine (10–30 μM) which depolarized 43 of 72 cells. The α₁ receptor antagonist prazosin (30–100 nM) completely blocked the membrane depolarization produced by either noradrenalin or phenylephrine in all cells tested, whereas α₂- and β-adrenergic agents had no effect. In voltage clamp, phenylephrine evoked an inward current (at -60 mV) and reduced cord conductance by 0.81 ± 0.14 nS (n= 4). Inward current evoked by phenylephrine became outward at -96 ± 8 mV, which is near the membrane reversal potential for potassium as predicted by the Nernst equation. Phenylephrine also depolarized secondary cells and increased the frequency of spontaneous GABA_A receptor-mediated postsynaptic potentials recorded in both principal and secondary cells. We conclude that stimulation of α₁-adrenergic receptors depolarizes principal (dopamine) neurons by reducing membrane conductance for potassium, but this effect is modulated by the increase in frequency of spontaneous inhibitory postsynaptic potentials evoked by stimulation of α₁-adrenergic receptors located on local interneurons.     

Cerebellar macroneurons in microexplant cell culture. Postsynaptic amino acid pharmacology

Cerebellar neurons derived from 17- to 19-day-old fetal rats have been grown in a monolayer in microexplant cell culture, and intracellular recording coupled with iontophoresis of amino acid neurotransmitters has been employed to characterize their amino acid chemosensitivity. Although these cultures contain at least 3 different neuronal cell types, intracellular recordings were obtained from large neurons (diameter greater than 15 microns) with 1-5 dendritic shafts and fine dendritic arborizations and which could, on morphological grounds, be identified as Purkinje cells. All neurons with resting membrane potentials greater than 25 mV and with action potentials evoked by intracellular stimulation, responded to iontophoretically applied glutamate and GABA. There was essentially no chemosensitivity to glycine, beta-alanine or taurine. Aspartate application evoked only small responses at high iontophoretic currents. GABA reversibly increased membrane conductance and produced hyperpolarization at resting membrane potential with reversal potentials between -50 and -40 mV (5-10 mV more negative than resting membrane potential). Glutamate reversibly increased membrane conductance and produced depolarizing responses with extrapolated reversal potentials between 0 and -10 mV. Aspartate augmented glutamate responses at low iontophoretic currents which did not directly alter membrane potential or conductance. Thus Purkinje cells grown in the absence of parallel fiber and climbing fiber input develop autonomous neuropharmacologic specificity similar to that of Purkinje cells in vivo.     

Ionic mechanism of the outward current induced by extracellular ejection of interleukin-1 onto identified neurons of Aplysia.

The ionic mechanism of the effect of extracellularly ejected recombinant human interleukin-1-beta (rhIL-1) on the membrane of identified neurons R9 and R10 of Aplysia was investigated with voltage-clamp, micropressure-ejection, and ion substitution techniques. Micropressure-ejected rhIL-1 caused a marked hyperpolarization in the unclamped neuron. Clamping the same neuron at its resting potential level (-60 mV) and reejecting rhIL-1 with the same dose produced a slow outward current (I0(IL-1), 20-30 s in duration, 3-5 nA in amplitude) associated with a decrease in input membrane conductance. I0(IL-1) was decreased by depolarization and increased by hyperpolarization. The extrapolated reversal potential of I0(IL-1) was approximately +15 mV. I0(IL-1) was sensitive to changes in the external Na+ concentration but not to changes in K+, Ca2+ and Cl- concentrations, and was resistant to tetraethylammonium (5 mM) and 4-aminopyridine (5 mM). Neither perfusion of the neuron with 50 microM tetrodotoxin nor perfusion with 10 mM Co2+ seawater caused any changes in I0(IL-1). I0(IL-1) was partially reduced by 50 microM ouabain. These results suggest that extracellular IL-1 can induce a slow outward current associated with a decrease in Na+ conductance and the immunomodulator IL-1 can act directly on the nervous system as well as on the immune system.     

Postsynaptic K+ current induced by nociceptin in medullary dorsal horn neurons

The actions of the endogenous ORL1 receptor (opioid receptor-like1) ligand nociceptin on the membrane properties of rat trigeminal nucleus caudalis neurons were examined by use of whole cell and perforated patch clamp recording in brain slices. Nociceptin produced an outward current in all neurons tested (EC50 112 nM). The outward current produced by nociceptin was completely reversed with the addition of the non-peptide ORL1 antagonist J-113397. Outward currents reversed polarity at -99+/-2 mV, close to the potential for K+ of -102 mV, suggesting that they were mediated by an increased K+ conductance. These results suggest that the analgesic action of nociceptin might be mediated by direct postsynaptic inhibition within the dorsal horn.     

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.     

Hyperpolarizing action of enkephalin on neurons in the dorsal motor nucleus of the vagus, in vitro

Intracellular recordings were made from neurons of the dorsomotor vagal nucleus (DMV) in slices of rat medulla oblongata. [D-Ala2, D-Leu5]-enkephalin (DADLE), applied by perfusion (0.01-3 microM) or droplets, dose-dependently hyperpolarized 85% of the DMV neurons tested. The hyperpolarization, associated with a decrease in membrane resistance, persisted after elimination of synaptic activity by perfusion with Ca2(+)-free/high-Mg2+ solution or with 1 microM TTX solution. The opioid antagonist, naloxone, reversibly inhibited DADLE-induced hyperpolarization. The hyperpolarization depended on extracellular K+ concentration and reversed at about -90 mV. DADLE also decreased Ca2(+)-dependent spike duration and after-hyperpolarization (AHP). DAGO (a selective mu-receptor agonist), but not DPLPE (a selective delta-receptor agonist), mimicked DADLE's effects on membrane potential, Ca2(+)-dependent spike duration, and AHP. It is concluded that DADLE, through postsynaptic mu-type opioid receptors, hyperpolarized DMV neurons by increasing K+ conductance, which may have an inhibitory effect on DMV output. DADLE-induced decrease of spike duration and AHP was also mediated by mu-receptors and could have additional effects on functions of the DMV neuron by virtue of reduction in Ca2+ entry.     

Extrasynaptic GABA(A) channels activated by THIP are modulated by diazepam in CA1 pyramidal neurons in the rat brain hippocampal slice

Single-channel currents were activated by THIP (4,5,6,7-tetrahydroisoxazolo[5,4-c]pyridin-3-ol) in cell-attached patches on CA1 pyramidal neurons in the rat hippocampal slice preparation. THIP activated GABA(A) channels after a delay that was concentration-dependent and decreased by 1 microM diazepam. The currents showed outward rectification. Channels activated at depolarized 40 mV relative to the chloride reversal potential had low conductance (<40 pS) but the conductance increased with time, resulting in high-conductance channels (>40 pS). The average maximal-channel conductances for 2 and 100 microM THIP were 59 and 62 pS (-Vp = 40 mV), respectively, whereas in 2 microM THIP plus 1 microM diazepam, it was 71 pS. The results show that in hippocampal neurons THIP activates channels with characteristics similar to those of channels activated by low concentrations (0.5-5 microM ) of GABA. The increase in the inhibitory conductance with membrane depolarization permits gradation of the shunt pathway relative to the level of the excitatory input.     

Electrical membrane properties of rat substantia nigra compacta neurons in an in vitro slice preparation

The electrical membrane properties of rat substantia nigra pars compacta (SNC) neurons were studied in an in vitro slice preparation. Some of the recorded neurons were intracellularly labeled with HRP and were found to have morphological characteristics resembling the presumed SNC dopaminergic neurons, as reported by others. The input resistance of SNC neurons at resting membrane potential ranged between 70 and 250 M omega. The membrane resistance showed strong anomalous rectification when the membrane was hyperpolarized by current injection. The anomalous rectification was decreased by the addition of tetraethylammonium bromide (TEA) to the bathing Ringer solution. Injection of depolarizing current or termination of hyperpolarizing current induced slow depolarizing potentials. Their amplitude was dependent on the membrane potential and the current intensity. In neurons treated with tetrodotoxin (TTX) and TEA, slow action potentials were triggered from the slow depolarizing potentials. Both the slow depolarizing potential and slow action potential were TTX resistant and abolished by superfusion of Ca2+-free medium. Long duration hyperpolarizations were observed following the injection of depolarizing current pulses. The hyperpolarization was abolished by the superfusion of Ca2+-free medium or decreased by addition of TEA to the Ringer solution indicating an involvement of a Ca2+-dependent K+-conductance in generation of the hyperpolarization. The long duration hyperpolarization was also observed following action potentials. The spike after hyperpolarization consisted of an initial short duration fast component and a long lasting component. The amplitude of both components seems to be reduced but not abolished by TEA (up to 10 mM). When hyperpolarizing current pulses were applied to neurons that were held either continuously depolarized or were superfused with Ca2+-free medium, the pattern of the membrane potential after the offset of current pulses consisted of an initial fast and a later slow ramp-shaped phase. The latter was associated with a membrane conductance increase and interpreted to be due to an early K+ current. This early K+ current was relatively resistant to TEA. Injections of strong depolarizing currents triggered action potentials with multiple inflections on their rising phase. The amplitudes of action potentials changed abruptly during current application. These data indicate that SNC neurons have multiple generation sites for action potential.     

Excitatory and inhibitory effects of epinephrine on neonatal rat sympathetic preganglionic neurons in vitro

Current and voltage recordings were made from antidromically identified sympathetic preganglionic neurons (SPNs) in transverse thoracolumbar spinal cord slices removed from neonatal rats. When applied by either pressure ejection or superfusion, epinephrine (Epi) caused a slow depolarization or an inward current in 62 SPNs (42%) and a slow hyperpolarization or an outward current in 21 SPNs (14%). The responses persisted in low calcium- or tetrodotoxin-containing media. The Epi-induced depolarization or inward current was associated with increased membrane resistance; it was reduced by membrane hyperpolarization and nullified at a membrane potential of about -100 mV; a clear reversal however was not observed at more negative potential levels. In a number of SPNs the Epi-induced depolarization was accompanied by small inhibitory postsynaptic potentials. The latter were eliminated by a low calcium solution and by the glycine antagonist strychnine, suggesting that they were caused by glycine or a glycine-like substance released from interneurons subsequent to activation by Epi. The Epi-induced hyperpolarization or outward current was associated with decreased membrane resistance, and nullified around -100 mV. The alpha-adrenergic antagonist, dihydroergotamine, and alpha 1-antagonist, prazosin, reversibly blocked the excitatory, whereas the alpha 2-antagonist, yohimbine, abolished the inhibitory response, respectively. It is concluded that Epi acting on alpha 1- and alpha 2-adrenergic receptors depolarizes and hyperpolarizes the rat SPNs by decreasing or increasing membrane conductances to potassium ions.     

Opiate activation of potassium conductance in myenteric neurons: inhibition by calcium ion

Morphine and enkephalin were applied to myenteric neurons of the guinea pig ileum while recording membrane potential with intracellular electrodes. Both opioids caused a concentration-dependent (1 nM–1 μM) hyperpolarization. The hyperpolarization was usually associated with a fall in input resistance, and it reversed to a depolarization when the cell membrane was held more negative than −100 mV. The amplitude of the hyperpolarization caused by a given concentration of morphine or enkephalin was dependent on the extracellular potassium ion concentration. The amplitude of the hyperpolarization and the conductance increase were inversely dependent on the extracellular calcium ion concentration. The results indicate that opiates activate the resting potassium conductance of myenteric neurons, especially when extracellular calcium concentration is low.     

External ions and membrane potential of leech neuropile glial cells

The ionic mechanism of a membrane effect of 5-hydroxytryptamine (5-HT) on neuropile glial (NG) cells in ganglia of the medicinal leech was investigated with conventional single-barrelled microelectrodes. Control experiments were made with double-barrelled ion-selective microelectrodes. 5-Hydroxytryptamine hyperpolarized the NG-cell membrane and increased the conductance considerably. Methysergide, a potent 5-HT antagonist, blocked the 5-HT-induced hyperpolarization completely. When leech ganglia were superfused with physiological bathing media free of 5-HT, the NG-cell membrane conductance returned to the original value, but the membrane potential recovered only partially from the hyperpolarization in most experiments. In glial membranes artificially depolarized by means of constant-current injection, the amplitude of the 5-HT response increased. The amplitude decreased with membrane hyperpolarization and reversed at —73 mV, close to the potassium equilibrium potential. The reversal potential changed by 52 mV when the extracellular potassium concentration was altered by a factor of 10. We conclude that 5-HT increases the potassium conductance of NG-cell membranes.     

Intracellular [Cl(-)] modulates synchronous electrical activity in rat neocortical neurons in culture by way of GABAergic inputs

The influence of GABAergic neurons on spontaneous electrical activities of neocortical neurons in culture, which was estimated to be about 9.5% of the total neurons by immunohistochemistry, was examined using dual whole-cell recording. Synchronized depolarization or hyperpolarization was observed in recorded neurons with pipettes containing low [Cl(-)] solution, while synchronized bursting of action potentials (APs) was observed with pipettes containing high [Cl(-)] solution. Spontaneous currents (SCs) were synchronous in all pairs tested with either pipettes containing low or high [Cl(-)] solution and spontaneous outward currents (SOCs) observed at around -30 mV were sensitive to the GABA-A receptor antagonist, bicuculline. Their reversal potential (V(rev)) was linearly related to the logarithm of Cl(-) activity in the pipette (-56.9 mV/decade). The intracellular chloride concentration was estimated from the V(rev) of SCs with gramicidin perforated-patch recordings and was between 5.9 and 28.1 mM (mean: 13.0 mM). These results suggest that GABA depolarized some neurons and hyperpolarized others, depending on the E(Cl). Bicuculline decreased the frequency of periodic depolarized potentials and increased their amplitudes. However, perfusion with low [Cl(-)] bath solution did not decrease the frequency. Our data indicate that recurrent subthreshold electrical activities by GABAergic inputs along with glutamatergic inputs take part in deterring synchronized bursting and that intracellular [Cl(-)] can modulate this bursting.     

Inward rectification of resting and opiate-activated potassium currents in rat locus coeruleus neurons

Intracellular recordings were made from rat locus coeruleus neurons in vitro, and membrane currents were measured at potentials from -50 to -130 mV. In the absence of any applied agonists, the slope conductance of the cells increased 3-fold when the cell was hyperpolarized from -60 to -120 mV. This conductance increase was complete within 5 msec of the onset of a hyperpolarizing command and was subsequently independent of time for several seconds. The conductance increase was blocked by cesium chloride (1-2 mM), rubidium chloride (1-2 mM), or barium chloride (1-100 microM). The membrane potential range over which the conductance increased was centered at the potassium equilibrium potential (EK; extracellular potassium concentration, 2.5-10.5 mM): the current/voltage (I/V) relation of the cell could be well described by supposing that there were 2 potassium conductances, one voltage independent (G1) and the other (inward rectifier, Gir) activated according to the expression Gir = Gir,max/(1 + exp[(V - EK)/k]), where k ranged from 15 mV in 2.5 mM potassium to 6 mV in 10.5 mM potassium. The additional membrane potassium conductance that developed when agonists at mu-opioid and alpha 2-adrenoceptors were applied also became larger with membrane hyperpolarization, and this voltage dependence was also reduced or blocked by rubidium, cesium, and barium; in the presence of these agonists the current also reached its final value within 5 msec. However, the conductance increased by the agonists (Gag) was not well expressed by simply increasing the values of G1 and Gir,max. It was best described by a potassium conductance that increased according to Gag,max/(1 + exp[(V - Vm)/k]), where Vm (the potential at which the conductance was half-maximum) was close to the resting potential of the cell.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ionic mechanism of a hyperpolarizing glutamate effect on two identified neurons in the buccal ganglion of Aplysia

The ionic mechanism of a membrane effect of L-glutamate on two identified neurons in the buccal ganglion of Aplysia kurodai was investigated with conventional microelectrode techniques and glutamate iontophoresis. Bath-applied and iontophoresed glutamate hyperpolarized the membrane and increased the membrane conductance. The hyperpolarizing glutamate response decreased in amplitude and finally reversed its polarity by conditioning hyperpolarization. The reversal potential of the hyperpolarizing glutamate response was close to the ECl (-60 mV). The reversal potential changed by 22.4 mV when the external chloride concentration was altered by a factor of 5. The relationship between the iontophoretically applied current and the membrane conductance changes was suggestive of two glutamate molecules reacting with a single receptor site. The hyperpolarizing glutamate response was essentially unaffected by 2-amino-4-phosphonobutyric acid (2-APB), L-proline, and quinuclidinyl benzilate (QNB). It was concluded that the hyperpolarizing glutamate response was generated by an activation of Cl- conductance.     

Interaction of Noradrenergic and Cholinergic Agonists with Ligands Increasing K-conductance of Guinea Pig Hippocampal Neurons,in vitro

Single electrode current clamp and voltage clamp recordings were employed to study the effects of noradrenergic agonists and a cholinergic agonist (carbachol, Cch) on the resting membrane potential of CA3 neurons in guinea pig hippocampal slices. Stimulation of muscarinic and beta-adrenergic receptors depolarized, and stimulation of alpha1-adrenergic receptor hyperpolarized, CA3 neurons but the membrane potential changes were small. Hyperpolarizations or outward currents induced by baclofen, adenosine or serotonin (5-HT) were strongly potentiated by alpha-noradrenergic agonists and suppressed by Cch at concentrations ten times lower than those having any direct effects on membrane potential. Both the enhancement of the baclofen-induced hyperpolarization by phenylephrine and its suppression by Cch were pronounced at low concentrations of baclofen, but diminished at higher concentrations. The modulatory effects persisted after blockade of sodium spikes by tetrodotoxin and after blockade of fast inhibitory and excitatory synaptic transmission by picrotoxin and 6-cyano-7-nitroquinoxaline-2,3-dione. Our data suggest that, through the postsynaptic interaction with ligands activating potassium conductance, noradrenergic and muscarinic receptor stimulation can exert a stronger inhibitory and excitatory effect on CA3 pyramidal neurons at their resting membrane potential than would be expected from the changes in membrane potential induced by these neuromodulators on their own.