Postnatal changes in somatic gamma-aminobutyric acid signalling in the rat hippocampus

During postnatal development of the rat hippocampus, γ-aminobutyric acid (GABA) switches its action on CA3 pyramidal cells from excitatory to inhibitory. To characterize the underlying changes in the GABA reversal potential, we used somatic cell-attached recordings of GABA(A) and N -methyl- d -aspartate channels to monitor the GABA driving force and resting membrane potential, respectively. We found that the GABA driving force is strongly depolarizing during the first postnatal week. The strength of this depolarization rapidly declines with age, although GABA remains slightly depolarizing, by a few millivolts, even in adult neurons. Reduction in the depolarizing GABA driving force was due to a progressive negative shift of the reversal potential of GABA currents. Similar postnatal changes in GABA signalling were also observed using the superfused hippocampus preparation in vivo , and in the hippocampal interneurons in vitro . We also found that in adult pyramidal cells, somatic GABA reversal potential is maintained at a slightly depolarizing level by bicarbonate conductance, chloride-extrusion and chloride-loading systems. Thus, the postnatal excitatory-to-inhibitory switch in somatic GABA signalling is associated with a negative shift of the GABA reversal potential but without a hyperpolarizing switch in the polarity of GABA responses. These results also suggest that in adult CA3 pyramidal cells, somatic GABAergic inhibition takes place essentially through shunting rather than hyperpolarization. Apparent hyperpolarizing GABA responses previously reported in the soma of CA3 pyramidal cells are probably due to cell depolarization during intracellular or whole-cell recordings.     

Electrophysiological evidence for the existence of GABAA receptors in cultured frog melanotrophs

The neurotransmitter GABA exerts a biphasic effect on alpha-melanocyte-stimulating hormone (alpha-MSH) secretion from pars intermedia cells: GABA induces a rapid and transient stimulation followed by a sustained inhibition of alpha-MSH release. In the present study, we have investigated the effect of GABA on the electrophysiological properties of frog melanotrophs in primary culture using the patch-clamp technique in the whole cell configuration. In all cells tested, GABA stimulated an inward current and induced depolarization. A transient period of intense firing was consistently observed at the onset of GABA administration. During the depolarization phase, the membrane potential reached a plateau corresponding to the Cl- equilibrium potential. When repeated hyperpolarizing pulses were applied, an increase of membrane conductance was observed throughout the response evoked by GABA. The effect of GABA was abolished by the chloride channel blocker picrotoxin, and by antagonists of GABAA receptors (bicuculline and SR 95531). The depolarizing action of GABA was mimicked by muscimol, an agonist of GABAA receptors. Taken together, our results indicate that the rapid and transient stimulation of alpha-MSH release induced by GABA can be accounted for by activation of a chloride conductance which causes membrane depolarization. These data support the notion that the transient stimulation of alpha-MSH secretion induced by GABA can be accounted for by membrane depolarization which provokes activation of voltage-operated calcium channels. Since no evidence was found for GABA-induced hyperpolarization, the intracellular mechanisms leading to the strong inhibitory effect of GABA on alpha-MSH secretion remain to be elucidated.     

In vitro studies of the role of gamma-aminobutyric acid in inhibition in the lateral septum of the rat

Focal stimulation, stimulation of the fimbria, and stimulation of the medial septal area result in an inhibitory postsynaptic potential (IPSP) in lateral septal neurons. Increased stimulus intensity results in the appearance of a late hyperpolarizing potential (LHP). Treatment of the slice with bicuculline methiodide or picrotoxin results in blockade of the IPSP. When present, LHPs are enhanced in the presence of bicuculline or picrotoxin. Spontaneous and evoked IPSPs reverse near -70 mV, and LHPs reverse near -90 mV. Iontophoretic application of gamma-amino-butyric acid (GABA) results in hyperpolarizing, depolarizing, or biphasic potentials. Treatment with bicuculline or picrotoxin results in depression of biphasic GABA responses that appears selective for the depolarizing portion of the potential. At high concentrations of bicuculline, a portion of the hyperpolarizing GABA potential persists. The reversal potential of the depolarizing GABA potential is near -30 mV, and the reversal potential of monophasic hyperpolarizing GABA potential is near -70 mV. The bicuculline-resistant hyperpolarizing GABA response has a reversal potential near -90 mV. GABA activates three separate conductances on septal neurons, which are similar to those reported on hippocampal neurons. The resistance of the hyperpolarizing GABA potential to bicuculline appears to be due to the presence of a GABA-activated potassium conductance, which is similar to that activated by baclofen.     

Synaptic Activation of GABAA Receptors Causes a Depolarizing Potential Under Physiological Conditions in Rat Hippocampal Pyramidal Cells

Intracellular recordings with K-acetate-filled microelectrodes were performed in slices of the adult rat hippocampus maintained in vitro at 35 - 36 degrees C to analyse the potentials associated with the orthodromic inhibitory sequence generated by CA1 pyramidal cells. In 43 of 72 cells, stimuli that were delivered in the stratum radiatum induced (i) an initial excitatory postsynaptic potential (EPSP), (ii) an early, hyperpolarizing inhibitory postsynaptic potential (IPSP) (peak latency from the stimulus artefact 20 ms), (iii) an intermediate depolarizing component (peak latency=60 - 120 ms; duration=60 - 150 ms, and (iv) a late, long-lasting hyperpolarizing IPSP (peak latency=120 - 160 ms, duration >400 ms). In the remaining cells the orthodromic inhibitory response lacked the intermediate depolarization. The depolarizing component was selectively blocked by local applications of bicuculline or picrotoxin on the apical dendrites of pyramidal cells. This pharmacological procedure induced an increase in the amplitude of the EPSP that was capable of triggering 2 - 3 action potentials, but no reduction of the recurrent IPSP which is caused by GABAA receptors located close to the soma. The amplitude and duration of the depolarizing component was enhanced by lowering the temperature in the tissue chamber to 29 - 31 degrees C or by application of the GABA uptake blocker nipecotic acid, further indicating that the depolarizing component represented an active phenomenon mediated through GABA. Application of the Cl- pump blocker furosemide reduced and eventually blocked the early IPSP and the depolarizing component. These data demonstrate that under physiological conditions rat hippocampal pyramidal cells generate a depolarization that is presumably caused by an outwardly directed Cl- movement due to the activation of GABAA receptors located on the apical dendrites. This novel mechanism might modulate hippocampal excitability in both physiological and pathophysiological conditions.     

Electrophysiological effects of FLFQPQRF amide, an endogenous brain morphine modulating peptide, on cultured mouse spinal-cord neurons

Intracellular recordings were made from dissociated fetal mouse spinal cord neurones in primary culture. Micropressure application of FLFQPQRFamide (10(-5) M in the delivery pipette), an endogenous mammalian brain morphine modulating peptide, onto the surface of spinal cord neurones induced, in a dose dependent manner, a transitory hyperpolarization followed by a long lasting depolarization of the membrane potential (n = 37). In contrast, no response was observed when the peptide was applied on dorsal root ganglia neurones (n = 30). The depolarizing phase of this response was underlied by an increase of the input resistance. Extrapolated reversal potential for the depolarizing phase was close to -80 mV while it was close to -40 mV for the hyperpolarizing phase. Increasing extracellular K+ concentration raised the reversal potential value of depolarizing phases to more positive values. The amplitude of the depolarizing phase was reduced by application of tetraethylammonium (50 mM) while it was enhanced by application of 4-aminopyridine (3 mM). CaCl2 application (3 mM) reversibly blocked the hyperpolarization and decreased the subsequent depolarization. In presence of Ba2+ the extrapollated reversal potential of the hyperpolarizing phase was dramatically shifted to a more positive value. Finally FLFQPQRFamide induced response can be partially mimicked by FMRFamide application. Our observations indicate that FLFQPQRFamide can have multiple effects on membrane conductance of mammalian spinal cord neurones by acting on a single class of receptor. These effects of FLFQPQRFamide were found to be mainly excitatory.     

Development of sensitivity to GABA and glycine in cultured cerebellar neurons

The effects of iontophoretically applied gamma-aminobutyric acid (GABA) and glycine on developing cerebellar neurons cultured for 7-40 days were intracellularly investigated. All neurons tested dose-dependently responded to both GABA and glycine. In mature neurons (after 25 days in culture) these amino acids inhibited spontaneous spikes, decreased the membrane input resistance and induced either hyperpolarization or depolarization of membrane potential. The mean reversal potential was -47 mV for GABA and -43 mV for glycine. Immature neurons, 7-12 days in culture, which were not spontaneously firing, also behaved in a similar manner as the mature ones, though the membrane resistance was not so largely changed by GABA or glycine and the reversal potential was more positive (-39 mV for GABA, -37 mV for glycine). These reversal potentials were shifted toward 0 mV by lowering the external Cl- concentration in either mature or immature neurons. The effects of GABA and glycine on mature or immature neurons were more or less inhibited by all of picrotoxin, bicuculline and strychnine. The effective concentrations of these antagonists, however, were lower in general in immature neurons. In mature neurons, picrotoxin and bicuculline became more selective to GABA than glycine and strychnine became more selective to glycine than GABA. These results suggest that sensitivities to GABA and glycine differentiate into selective types in the course of maturing of cerebellar cultured neurons.     

Whole-cell patch study of GABAergic inhibition in CA1 neurons of immature rat hippocampal slices

Inhibitory processes mediated by gamma-aminobutyric acid (GABA) were studied in immature rat hippocampal slices using the whole-cell patch clamp technique. Orthodromically evoked hyperpolarizing inhibitory postsynaptic potentials (IPSPs) were observed in CA1 neurons of postnatal 2-5 (P2-5) and 7-13 (P7-13) day old rats under conditions of low internal [Cl-]. In the whole-cell voltage-clamp mode, applications of GABA evoked outwards currents which reversed at -55 mV and -62 mV in P2-5 and P7-13 CA1 neurons, respectively, with comparable reversal potential for the IPSPs for each age. An increase in internal [Cl-] caused a depolarizing shift of the GABA reversal potential which followed the Nernst equation. In both groups of neurons, the IPSPs and GABA currents were blocked with the bath applications of bicuculline (10 microM) and picrotoxin (100 microM). We conclude that the GABAA-mediated inhibitory synaptic process exists in P2-5 CA1 neurons and hypothesize that the absence of such IPSPs noted in previous studies of immature CA1 neurons was likely due to higher internal [Cl-] in the more immature neurons.     

GABA-induced responses in Purkinje cell dendrites of the rabbit cerebellar slice.

Pressure applications of GABA localized to Purkinje cell somas in a rabbit cerebellar slice produced uniphasic hyperpolarizing responses, whereas applications of GABA that were directed at the Purkinje cell dendrites produced complex, triphasic responses with hyperpolarizing and depolarizing components. Both somatic and dendritic application of GABA elicited fast hyperpolarization (GABAhf), but dendritic application also elicited a slower depolarization (GABAd) and a later, long-lasting hyperpolarization (GABAhl). All three types of responses were accompanied by increased conductance. Use of either GABA antagonist, bicuculline or picrotoxin, eliminated the GABAhf and GABAd responses but left the GABAhl response intact. Pressure delivery of the GABA agonist, baclofen, to the dendrites but not the soma elicited a GABAhl response. Application of baclofen paired with membrane depolarization sufficient to elicit local, calcium-dependent dendritic spiking produced a persistent reduction in the GABAhl response, whereas alternating presentations of baclofen and membrane depolarization or presentations of baclofen alone could not. The fact that GABA and baclofen inhibited Purkinje cell activity in the rabbit cerebellar slice and that picrotoxin and bicuculline eliminated some, but not all of the components of the GABA response suggests the presence of both GABAA and GABAB receptors. The ability of baclofen to inhibit Purkinje cells if it was applied to the dendrites but not if applied to the soma suggests that GABAB receptors are located predominantly on Purkinje cell dendrites. The pairing-specific change in the baclofen response suggests the existence of GABAB-mediated modifiability of Purkinje cell dendrites.(ABSTRACT TRUNCATED AT 250 WORDS)     

Contrasting properties of K+ conductances induced by baclofen and gamma-aminobutyric acid in slices of the guinea pig hippocampus

Properties of membrane K+ conductances induced by baclofen and gamma-aminobutyric acid (GABA) in the hippocampus were investigated by using guinea-pig brain slices. Baclofen hyperpolarized the membrane and decreased the input resistance of pyramidal cells through the activation of a membrane K+ conductance. GABA caused a biphasic response in pyramidal cells, consisting of hyperpolarizing and depolarizing components. Combined application of picrotoxin and bicuculline eliminated the major part of the depolarizing component of the biphasic response and produced a relatively pure hyperpolarizing response which was also mediated by an increase in K+ conductance. The K+ conductance change induced by baclofen showed prominent inward rectification. However, the K+ conductance induced by GABA did not show an obvious rectifying property. The K+ conductance activated by baclofen was strongly antagonized by a low concentration (5 x 10(-6) M) of 4-aminopyridine (4-AP). In contrast, the K+ conductance activated by GABA was insensitive to 4-AP even at a high concentration of 10(-3) M. The slow inhibitory postsynaptic potential (slow i.p.s.p.) evoked by stimulation of the mossy fibres was totally suppressed by a low concentration of baclofen (5 x 10(-6) M). Whereas GABA (10(-3) M) decreased the amplitude of the slow i.p.s.p., the reduction of the amplitude was proportional to the decrease in the amplitude of the electrotonic potentials produced by constant inward current injections. These results suggest that the hyperpolarizations induced by GABA and baclofen may be generated by K+ conductances of different kinetic and pharmacologic properties.     

The dendritic response to GABA in CA1 of the hippocampal slice

Application of GABA in the dendritic region of pyramidal cells elicits a depolarization which, in fact, is the sum of a hyperpolarizing and a depolarizing process. At the reversal potential of the depolarizing response (-42 mV) the GABA-induced current fluctuations do not have a minimum. Consequently, a conductance change to more than one ion is involved. Cl- is in part responsible, Ca2+ is not because Mn2+ and Mg2+ do not change the response. Whether Na+ is involved is uncertain. Substitution with choline had no effect but choline may permeate through the membrane during the depolarizing response. Nipecotic acid inhibits a Na+-GABA uptake mechanism but does not change the dendritic response.     

Differential bicuculline-induced epileptogenesis in rat neonatal, juvenile and adult CA3 pyramidal neurons in vitro.

The GABA(A) receptor antagonist bicuculline methiodide (BMI, 10 microM) transformed the evoked synaptic responses, recorded intracellularly from the CA3 area of neonatal (postnatal days 3-7, P3-P7), juvenile (P8-P20) and adult hippocampal slices, into long-lasting paroxysmal depolarizations (PDs), with repetitive action potentials (APs). In the same preparation, GABA(A)-mediated fast-IPSPs were depolarizing at resting membrane potential (RMP), with a reversal potential shifting to a hyperpolarizing direction with age (n=15, P6-P17). BMI provoked also spontaneous PDs in juvenile (20/30) and adult (7/10) but not in neonatal (0/12) neurons. PDs were depressed by either the NMDA receptor antagonist CPP (10 microM) or the non-NMDA antagonist CNQX (10 microM), but were blocked only by the combination of the two (n=6), indicating that activation of either NMDA or non-NMDA receptors can independently sustain PDs in immature hippocampus. In conclusion, these findings show that endogenous GABA tonically inhibits CA3 synaptic responses in neonatal life despite the depolarizing nature of GABA(A)-mediated potentials. Moreover, they suggest that during the 1st postnatal week, disinhibition alone is not sufficient to provoke spontaneous epileptiform discharges in CA3 hippocampal area.     

Local stimulation induced GABAergic response in rat striatal slice preparations: Intracellular recordings on QX-314 injected neurons

Gamma-aminobutyric acid (GABA)ergic responses evoked by electrical stimulation in the neostriatal slice preparation were studied in neurons injected intracellularly with Na-conductance blocker QX-314. Local stimulation elicited depolarizing postsynaptic potentials (DPSPs) in the QX-314-injected neurons when the membrane potential was morenegative than −60 mV. When DPSPs were minimized by depolirizing current injection in the QX-314-injected neuron, hyperpolarization was clearly observed following local stimulation. The maximum duration of the hyperpolarizing response to strong local stimulation was about 130 ms. The hyperpolarizing response was blocked by the addition of bicuculine or picrotoxin to the Ringer solution. Intracellular Cl^- injections produced changes in the pattern of the local stimulations-induced responses; the initial depolarizing response was followed by a relatively large amplitude long duration depolarization. The polarity of the long duration of depolarizing response could not be reversed by depolarizing currents which were normally sufficient to reverse the polarity of DPSPs in the neurons without Cl^- injection. The application of pentobarbital enhanced the amplitude and the duration of the hyperpolarizing responses. The revealed potential of the pentobarbital-enhanced response was estimated to be −60 mV. On the basis of their reversal potential, sensitivity to injected Cl^-, sensitivity to GABA blockers picrotoxin and bicuculine, and the effect of pentobarbital, these hyperpolarizing responses are shown to be GABAergic Cl^- mediated inhibitory postsynaptic potentials (IPSPs).     

Inhibitory potentials in neurons of the deep layers of the in vitro neocortical slice

Neocortical neurons in slices of the rat sensorimotor region maintained in vitro generate postsynaptic potentials (PSPs) in response to focal extracellular stimulation. These PSPs are mainly depolarizing at the resting membrane potential (Vm) but a sequence of depolarizing-hyperpolarizing potentials is often disclosed by depolarizing the Vm. The stimulus-induced hyperpolarization can last up to 1000 ms and show two components: the early one (peak latency 10-20 ms), is inverted by diffusion of Cl- into the cell; the late one is diminished by augmenting [K+]o. The membrane conductance is increased throughout the stimulus-induced hyperpolarization, mainly during the first 10-60 ms. A decrease in excitability results from both the hyperpolarizing trend and the conductance increase. The latter is more effective in decreasing depolarizing than hyperpolarizing pulses of current injected intracellularly.     

Effects of glycine on neurons in the rat substantia nigra zona compacta: in vitro electrophysiological study

The effects of bath-applied glycine to substantia nigra zona compacta neurons of rat were investigated by intracellular recording techniques in vitro. Superfusion of glycine (1 mM) in the medium hyperpolarized 53% of the neurons recorded with KCl electrodes, whereas 32% of the cells were depolarized. The remaining 15% of neurons was hyperpolarized and then depolarized by the amino acid. In spite of these membrane changes, the action potential firing was depressed. Both hyperpolarization and depolarization were correlated to an outward and an inward current, respectively, when recording in single-electrode voltage-clamp mode. In response to bath application of glycine, the neurons showed a concentration-dependent conductance increase. Micromolar concentrations of glycine (100-300 microM) in the superfusion medium produced a membrane hyperpolarization (outward current) in most of the tested cells, whereas millimolar concentration of amino acid could cause depolarization (inward current) in the same neurons. When the recording electrodes contained K acetate, only hyperpolarizations (outward current) were produced. The potential and current changes and the increase in membrane conductance produced by glycine showed little desensitization when neurons were recorded with K acetate electrodes. The mean reversal potential for the membrane hyperpolarization was -80 mV with intracellular electrodes containing KCl and -84 mV with electrodes containing K acetate. The mean null potential for the depolarizing effect was -46 mV. The reversal potential for the glycinergic responses was shifted to less negative values upon lowering the extracellular concentration of chloride or increasing the extracellular concentration of potassium. Strychnine (1-10 microM) reversibly antagonized both the conductance increase and the membrane changes produced by glycine. Bath application of bicuculline (100 microM) and picrotoxin (200 microM) did not affect glycine responses, while depressing the actions of GABA and muscimol. It is concluded the glycine exerts an inhibition on substantia nigra zona compacta neurons by acting on strychnine-sensitive receptors. The membrane effects produced by glycine result from the activation of a chloride current. In addition, the simultaneous involvement of potassium ions may contribute to the overall effects of glycine.     

Mechanisms concerned in the direct effect of isoflurane on rat hippocampal and human neocortical neurons

The effect of isoflurane on postsynaptic neurons was studied by intracellular recordings from rat hippocampus and human neocortex in vitro. Isoflurane caused a hyperpolarization of the cell membrane. The hyperpolarization was reversed (although incompletely in some neurons) by increasing the membrane potential. The reversal potential was -80 +/- 12 mV (mean +/- S.D.) or 12 +/- 6 mV negative to the resting membrane potential. Potassium channel blockers reduced the isoflurane-induced hyperpolarization, while chloride loading was without effect. The transient depolarization preceding the hyperpolarization in some of the neurons was not reversed by hyperpolarization. The action potential was prolonged by 19 +/- 3% due to a slower rate of rise. The rise time was almost doubled. Firing threshold was increased by 4 +/- 3 mV (relative to the reference electrode). Subthreshold inward rectification was reduced or abolished. Some cells showed subthreshold outward rectification during isoflurane administration. These results suggest that isoflurane depressed neuronal excitability by (1) hyperpolarizing the cell membrane, at least partly by an increase in potassium conductance, (2) slowing the rate of rise of the action potential, presumably due to interference with the fast sodium channel, (3) decreasing subthreshold inward rectification and (4) increasing firing threshold.     

Interleukin-1 beta directly excites hypothalamic supraoptic neurons in rats in vitro.

Responses of 42 neurosecretory neurons in the supraoptic nucleus (SON) to human recombinant interleukin-1 beta (IL-1 beta) were examined during intracellular recordings in rat brain slices. IL-1 beta (10(-9)-10(-8) M) depolarized the membrane and caused increased firing in 25 neurons (59.5%). In 11 other neurons (26.6%), depolarization was also seen, followed by membrane hyperpolarization. The IL-induced depolarizing effect remained in the presence of tetrodotoxin (TTX) but was abolished by sodium salicylate. The results suggest that IL-1 beta mainly exerts a direct excitatory effect on SON neurons and further, that prostaglandins may be involved in such an effect.     

Direct muscarinic and nicotinic receptor-mediated excitation of rat medial vestibular nucleus neurons in vitro

We have utilized intracellular recording techniques to investigate the cholinoceptivity of rat medial vestibular nucleus (MVN) neurons in a submerged brain slice preparation. Exogenous application of the mixed cholinergic agonists, acetylcholine (ACh) or carbachol (CCh), produced predominantly membrane depolarization, induction of action potential firing, and decreased input resistance. Application of the selective muscarinic receptor agonist muscarine (MUSC), or the selective nicotinic receptor agonists nicotine (NIC) or 1,1-dimethyl-4-phenylpiperazinium (DMPP) also produced membrane depolarizations. The MUSC-induced depolarization was accompanied by decreased conductance, while an increase in conductance appeared to underlie the NIC- and DMPP-induced depolarizations. The muscarinic and nicotinic receptor mediated depolarizations persisted in tetrodotoxin and/or low Ca²⁺/high Mg²⁺ containing media, suggesting direct postsynaptic receptor activation. The MUSC-induced depolarization could be reversibly blocked by the selective muscarinic-receptor antagonist, atropine, while the DMPP-induced depolarization could be reversibly suppressed by the selective ganglionic nicotinicreceptor antagonist, mecamylamine. Some neurons exhibited a transient membrane hyperpolarization during the depolarizing response to CCh or MUSC application. This transient inhibition could be reversibly blocked by the γ-aminobutyric acid (GABA) antagonist, bicuculline, suggesting that the underlying hyperpolarization results indirectly from the endogenous release of GABA acting at GABA receptors. This study confirms the cholinoceptivity of MVN neurons and establishes that individual MVN cells possess muscarinic as well as nicotinic receptors. The data provide support for a prominent role of cholinergic mechanisms in the direct and indirect regulation of the excitability of MVN neurons.     

Shunting and hyperpolarizing GABAergic inhibition in the high-potassium model of ictogenesis in the developing rat hippocampus

Ontogenesis of GABAergic signaling may play an important role in developmental changes in seizure susceptibility in the high-potassium model of ictogenesis in vitro. The age-dependent effects of [K(+)](o) on the reversal potential of the GABA(A)-mediated responses and membrane potential in hippocampal slices in vitro were compared with the effect of GABA(A)-receptors antagonists and GABA(A) modulators on high-potassium induced seizures in the CA3 pyramidal layer of rat hippocampus in vivo. GABA(A) responses were depolarizing at P8-12 and hyperpolarizing at P17-21. In P8-12 rats, GABA(A) responses switch their polarity from depolarizing to hyperpolarizing upon elevation of extracellular potassium. At approximately 10 mM [K(+)](o), activation of GABA(A) receptors produced an isoelectric, purely shunting response characterized by no changes in the membrane potential but an increase in the membrane conductance. In P17-21 rats, the hyperpolarizing GABA(A) driving force progressively increased with elevation of [K(+)](o). In P8-12 rats in vivo, GABA(A)-receptor antagonists did not affect the occurrence of ictal discharges induced by intrahippocampal injection of 10 mM [K(+)](o), but significantly increased seizure duration. Diazepam and isoguvacine completely prevented seizures induced by 10 mM [K(+)](o). In P17-21 rats, GABA(A)-receptor antagonists strongly increased the occurrence of ictal activity induced both by 10 mM [K(+)](o). Taken together, these results suggest that anticonvulsive effects of GABA are because of the combination of shunting and hyperpolarizing actions of GABA. Although shunting GABA is already efficient in the young age group, a developmental increase in the hyperpolarizing GABA(A) driving force likely contributes to the increase in the GABAergic control of seizures upon maturation.     

Ethanol enhances synaptically evoked GABAA receptor-mediated responses in cerebral cortical neurons in rat brain slices.

Previous intracellular electrophysiological studies on rat hippocampal brain slices have shown very little effect of acute ethanol application on synaptically evoked GABAA receptor-mediated responses recorded in CA1 pyramidal neurons. The present study was designed to compare the effects of ethanol on pyramidal neurons in the hippocampus and cerebral cortex. Using conventional intracellular microelectrodes (60-80 M omega) to impale cortical neurons in brain slices, 80 mM ethanol application did not affect the membrane input impedance nor evoked EPSPs, but significantly affected the resting membrane potential (usually a 2-5 mV hyperpolarization). When stimulus-evoked GABAA-mediated IPSCs were studied using whole-cell recordings from cortical neurons voltage-clamped at depolarizing potentials, monophasic IPSCs were evoked that were blocked by bicuculline, increased by pentobarbital, and enhanced by ethanol superfusion in a dose dependent manner over the range of 20-160 mM. Hippocampal IPSCs recorded under identical conditions were not enhanced by ethanol. Parallel studies of GABA-stimulated 36Cl- flux measurements in microsacs prepared from hippocampal, cerebral cortical and cerebellar tissue demonstrated that ethanol significantly enhanced (30-50%) 36Cl- flux in microsacs derived from the cerebral cortex and cerebellum, but not in microsacs prepared from the hippocampus. These results demonstrate that there are clear brain region-dependent differences in the way that GABAA receptor function is altered by acute ethanol, and that these differences are apparent not only as an enhancement of responses to exogenous GABA, but also as a facilitation of the responses to endogenous GABA released from inhibitory nerve terminals during synaptic activation.     

Angiotensin evokes in polyploid rat glioma cells hyperpolarization-depolarization responses and cross-desensitization with bradykinin

Angiotensins I, II and III induced a hyperpolarizing response of up to 1 min duration followed by a depolarizing response of up to 4 min when applied by pressure pulses or iontophoresis to polyploid rat glioma cells C6-4-2. The hyperpolarization (depolarization) was associated with a 50% decrease (no measurable change) in membrane resistance. The reversal potential (ca. −90 mV) of the hyperpolarization most likely points to an increased K⁺ conductance. Cells desensitized to angiotensins on application of high doses of either angiotensins or bradykinin.